Hewlett Packard Enterprise GlancePlus for Linux
Dictionary of Operating System Performance Metrics

Print Date 08/2017
GlancePlus for Linux Release 12.04    
       
     
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         Copyright Notices
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         ©Copyright 2012-2017 Hewlett Packard Enterprise Development Company, L.P. All rights reserved.
         
    
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    Introduction
    ============
    This dictionary contains definitions of the Linux 
    operating system performance metrics for GlancePlus.
    
    This document is divided into the following sections:
    
    * "Metric Names by Data Class," which lists the metrics
      alphabetically by data class.
    
    * "Metric Definitions," which describes each metric in
       alphabetical order.
    


METRIC NAMES BY DATA CLASS
==========================


Global Metrics 
----------------------------------
GBL_ACTIVE_CPU 
GBL_ACTIVE_CPU_CORE 
GBL_ACTIVE_PROC GBL_ALIVE_PROC 
GBL_BLANK 
GBL_BOOT_TIME 
GBL_COLLECTION_MODE 
GBL_COLLECTOR 
GBL_COMPLETED_PROC 
GBL_CPU_CLOCK 
GBL_CPU_CYCLE_ENTL_MAX 
GBL_CPU_CYCLE_ENTL_MIN 
GBL_CPU_ENTL_MAX 
GBL_CPU_ENTL_MIN 
GBL_CPU_ENTL_UTIL 
GBL_CPU_GUEST_TIME 
GBL_CPU_GUEST_TIME_CUM 
GBL_CPU_GUEST_UTIL 
GBL_CPU_GUEST_UTIL_CUM 
GBL_CPU_GUEST_UTIL_HIGH 
GBL_CPU_IDLE_TIME 
GBL_CPU_IDLE_TIME_CUM 
GBL_CPU_IDLE_UTIL 
GBL_CPU_IDLE_UTIL_CUM 
GBL_CPU_IDLE_UTIL_HIGH 
GBL_CPU_INTERRUPT_TIME 
GBL_CPU_INTERRUPT_TIME_CUM 
GBL_CPU_INTERRUPT_UTIL 
GBL_CPU_INTERRUPT_UTIL_CUM 
GBL_CPU_INTERRUPT_UTIL_HIGH 
GBL_CPU_MT_ENABLED 
GBL_CPU_NICE_TIME 
GBL_CPU_NICE_TIME_CUM 
GBL_CPU_NICE_UTIL 
GBL_CPU_NICE_UTIL_CUM 
GBL_CPU_NICE_UTIL_HIGH 
GBL_CPU_NUM_THREADS 
GBL_CPU_PHYSC 
GBL_CPU_PHYS_TOTAL_UTIL 
GBL_CPU_SHARES_PRIO 
GBL_CPU_STOLEN_TIME 
GBL_CPU_STOLEN_TIME_CUM 
GBL_CPU_STOLEN_UTIL 
GBL_CPU_STOLEN_UTIL_CUM 
GBL_CPU_STOLEN_UTIL_HIGH 
GBL_CPU_SYSCALL_TIME 
GBL_CPU_SYSCALL_TIME_CUM 
GBL_CPU_SYSCALL_UTIL 
GBL_CPU_SYSCALL_UTIL_CUM 
GBL_CPU_SYS_MODE_TIME 
GBL_CPU_SYS_MODE_TIME_CUM 
GBL_CPU_SYS_MODE_UTIL 
GBL_CPU_SYS_MODE_UTIL_CUM 
GBL_CPU_SYS_MODE_UTIL_HIGH 
GBL_CPU_TOTAL_TIME 
GBL_CPU_TOTAL_TIME_CUM 
GBL_CPU_TOTAL_UTIL 
GBL_CPU_TOTAL_UTIL_CUM 
GBL_CPU_TOTAL_UTIL_HIGH 
GBL_CPU_USER_MODE_TIME 
GBL_CPU_USER_MODE_TIME_CUM 
GBL_CPU_USER_MODE_UTIL 
GBL_CPU_USER_MODE_UTIL_CUM 
GBL_CPU_USER_MODE_UTIL_HIGH 
GBL_CPU_WAIT_TIME 
GBL_CPU_WAIT_TIME_CUM 
GBL_CPU_WAIT_UTIL 
GBL_CPU_WAIT_UTIL_CUM 
GBL_CPU_WAIT_UTIL_HIGH 
GBL_CSWITCH_RATE 
GBL_CSWITCH_RATE_CUM 
GBL_CSWITCH_RATE_HIGH 
GBL_DISK_PHYS_BYTE 
GBL_DISK_PHYS_BYTE_RATE 
GBL_DISK_PHYS_IO 
GBL_DISK_PHYS_IO_CUM 
GBL_DISK_PHYS_IO_RATE 
GBL_DISK_PHYS_IO_RATE_CUM 
GBL_DISK_PHYS_READ 
GBL_DISK_PHYS_READ_BYTE 
GBL_DISK_PHYS_READ_BYTE_CUM 
GBL_DISK_PHYS_READ_BYTE_RATE 
GBL_DISK_PHYS_READ_CUM 
GBL_DISK_PHYS_READ_PCT 
GBL_DISK_PHYS_READ_PCT_CUM 
GBL_DISK_PHYS_READ_RATE 
GBL_DISK_PHYS_READ_RATE_CUM 
GBL_DISK_PHYS_WRITE 
GBL_DISK_PHYS_WRITE_BYTE 
GBL_DISK_PHYS_WRITE_BYTE_CUM 
GBL_DISK_PHYS_WRITE_BYTE_RATE 
GBL_DISK_PHYS_WRITE_CUM 
GBL_DISK_PHYS_WRITE_PCT 
GBL_DISK_PHYS_WRITE_PCT_CUM 
GBL_DISK_PHYS_WRITE_RATE 
GBL_DISK_PHYS_WRITE_RATE_CUM 
GBL_DISK_REQUEST_QUEUE 
GBL_DISK_SUBSYSTEM_QUEUE 
GBL_DISK_SUBSYSTEM_WAIT_PCT 
GBL_DISK_SUBSYSTEM_WAIT_TIME 
GBL_DISK_TIME_PEAK 
GBL_DISK_UTIL 
GBL_DISK_UTIL_PEAK 
GBL_DISK_UTIL_PEAK_CUM 
GBL_DISK_UTIL_PEAK_HIGH 
GBL_DISTRIBUTION 
GBL_FS_SPACE_UTIL_PEAK 
GBL_GMTOFFSET 
GBL_IGNORE_MT 
GBL_INTERRUPT 
GBL_INTERRUPT_RATE 
GBL_INTERRUPT_RATE_CUM 
GBL_INTERRUPT_RATE_HIGH 
GBL_INTERVAL 
GBL_INTERVAL_CUM 
GBL_JAVAARG 
GBL_LOADAVG 
GBL_LOADAVG15 
GBL_LOADAVG5 
GBL_LOADAVG_CUM 
GBL_LOADAVG_HIGH 
GBL_LOST_MI_FTRACE_BUFFERS 
GBL_LOST_MI_TRACE_BUFFERS 
GBL_LS_MODE 
GBL_LS_ROLE 
GBL_LS_SHARED 
GBL_LS_TYPE 
GBL_MACHINE 
GBL_MACHINE_MEM_USED 
GBL_MACHINE_MODEL 
GBL_MACHINE_UUID 
GBL_MACHINE_VENDOR 
GBL_MAC_ADDR_LIST 
GBL_MEM_AVAIL 
GBL_MEM_CACHE 
GBL_MEM_CACHE_UTIL 
GBL_MEM_ENTL_MAX 
GBL_MEM_ENTL_MIN 
GBL_MEM_FILE_PAGEIN_RATE 
GBL_MEM_FILE_PAGEOUT_RATE 
GBL_MEM_FILE_PAGE_CACHE 
GBL_MEM_FILE_PAGE_CACHE_UTIL 
GBL_MEM_FREE 
GBL_MEM_FREE_UTIL 
GBL_MEM_OVERHEAD 
GBL_MEM_PAGEIN 
GBL_MEM_PAGEIN_BYTE 
GBL_MEM_PAGEIN_BYTE_CUM 
GBL_MEM_PAGEIN_BYTE_RATE 
GBL_MEM_PAGEIN_BYTE_RATE_CUM 
GBL_MEM_PAGEIN_BYTE_RATE_HIGH 
GBL_MEM_PAGEIN_CUM 
GBL_MEM_PAGEIN_RATE 
GBL_MEM_PAGEIN_RATE_CUM 
GBL_MEM_PAGEIN_RATE_HIGH 
GBL_MEM_PAGEOUT 
GBL_MEM_PAGEOUT_BYTE 
GBL_MEM_PAGEOUT_BYTE_CUM 
GBL_MEM_PAGEOUT_BYTE_RATE 
GBL_MEM_PAGEOUT_BYTE_RATE_CUM 
GBL_MEM_PAGEOUT_BYTE_RATE_HIGH 
GBL_MEM_PAGEOUT_CUM 
GBL_MEM_PAGEOUT_RATE 
GBL_MEM_PAGEOUT_RATE_CUM 
GBL_MEM_PAGEOUT_RATE_HIGH 
GBL_MEM_PAGE_FAULT 
GBL_MEM_PAGE_FAULT_CUM 
GBL_MEM_PAGE_FAULT_RATE 
GBL_MEM_PAGE_FAULT_RATE_CUM 
GBL_MEM_PAGE_FAULT_RATE_HIGH 
GBL_MEM_PAGE_REQUEST 
GBL_MEM_PAGE_REQUEST_CUM 
GBL_MEM_PAGE_REQUEST_RATE 
GBL_MEM_PAGE_REQUEST_RATE_CUM 
GBL_MEM_PAGE_REQUEST_RATE_HIGH 
GBL_MEM_PHYS 
GBL_MEM_PHYS_SWAPPED 
GBL_MEM_SHARES_PRIO 
GBL_MEM_SWAPIN_BYTE 
GBL_MEM_SWAPIN_BYTE_CUM 
GBL_MEM_SWAPIN_BYTE_RATE 
GBL_MEM_SWAPIN_BYTE_RATE_CUM 
GBL_MEM_SWAPIN_BYTE_RATE_HIGH 
GBL_MEM_SWAPOUT_BYTE 
GBL_MEM_SWAPOUT_BYTE_CUM 
GBL_MEM_SWAPOUT_BYTE_RATE 
GBL_MEM_SWAPOUT_BYTE_RATE_CUM 
GBL_MEM_SWAPOUT_BYTE_RATE_HIGH 
GBL_MEM_SYS 
GBL_MEM_SYS_UTIL 
GBL_MEM_USER 
GBL_MEM_USER_UTIL 
GBL_MEM_UTIL 
GBL_MEM_UTIL_CUM 
GBL_MEM_UTIL_HIGH 
GBL_NET_COLLISION 
GBL_NET_COLLISION_1_MIN_RATE 
GBL_NET_COLLISION_CUM 
GBL_NET_COLLISION_PCT 
GBL_NET_COLLISION_PCT_CUM 
GBL_NET_COLLISION_RATE 
GBL_NET_ERROR 
GBL_NET_ERROR_1_MIN_RATE 
GBL_NET_ERROR_CUM 
GBL_NET_ERROR_RATE 
GBL_NET_IN_ERROR 
GBL_NET_IN_ERROR_CUM 
GBL_NET_IN_ERROR_PCT 
GBL_NET_IN_ERROR_PCT_CUM 
GBL_NET_IN_ERROR_RATE 
GBL_NET_IN_ERROR_RATE_CUM 
GBL_NET_IN_PACKET 
GBL_NET_IN_PACKET_CUM 
GBL_NET_IN_PACKET_RATE 
GBL_NET_OUT_ERROR 
GBL_NET_OUT_ERROR_CUM 
GBL_NET_OUT_ERROR_PCT 
GBL_NET_OUT_ERROR_PCT_CUM 
GBL_NET_OUT_ERROR_RATE 
GBL_NET_OUT_ERROR_RATE_CUM 
GBL_NET_OUT_PACKET 
GBL_NET_OUT_PACKET_CUM 
GBL_NET_OUT_PACKET_RATE 
GBL_NET_PACKET 
GBL_NET_PACKET_RATE 
GBL_NET_UTIL_PEAK 
GBL_NFS_CALL 
GBL_NFS_CALL_RATE 
GBL_NFS_CLIENT_BAD_CALL 
GBL_NFS_CLIENT_BAD_CALL_CUM 
GBL_NFS_CLIENT_CALL 
GBL_NFS_CLIENT_CALL_CUM 
GBL_NFS_CLIENT_CALL_RATE 
GBL_NFS_CLIENT_IO 
GBL_NFS_CLIENT_IO_CUM 
GBL_NFS_CLIENT_IO_PCT 
GBL_NFS_CLIENT_IO_PCT_CUM 
GBL_NFS_CLIENT_IO_RATE 
GBL_NFS_CLIENT_IO_RATE_CUM 
GBL_NFS_CLIENT_READ_RATE 
GBL_NFS_CLIENT_READ_RATE_CUM 
GBL_NFS_CLIENT_WRITE_RATE 
GBL_NFS_CLIENT_WRITE_RATE_CUM 
GBL_NFS_SERVER_BAD_CALL 
GBL_NFS_SERVER_BAD_CALL_CUM 
GBL_NFS_SERVER_CALL 
GBL_NFS_SERVER_CALL_CUM 
GBL_NFS_SERVER_CALL_RATE 
GBL_NFS_SERVER_IO 
GBL_NFS_SERVER_IO_CUM 
GBL_NFS_SERVER_IO_PCT 
GBL_NFS_SERVER_IO_PCT_CUM 
GBL_NFS_SERVER_IO_RATE 
GBL_NFS_SERVER_IO_RATE_CUM 
GBL_NFS_SERVER_READ_RATE 
GBL_NFS_SERVER_READ_RATE_CUM 
GBL_NFS_SERVER_WRITE_RATE 
GBL_NFS_SERVER_WRITE_RATE_CUM 
GBL_NODENAME 
GBL_NUM_ACTIVE_LS 
GBL_NUM_APP 
GBL_NUM_CPU 
GBL_NUM_CPU_CORE 
GBL_NUM_DISK 
GBL_NUM_HBA 
GBL_NUM_LS 
GBL_NUM_LV 
GBL_NUM_NETWORK 
GBL_NUM_SOCKET 
GBL_NUM_SWAP 
GBL_NUM_THREAD 
GBL_NUM_THREAD_ACTIVE 
GBL_NUM_THREAD_COMPLETED 
GBL_NUM_THREAD_NEW 
GBL_NUM_TT 
GBL_NUM_USER 
GBL_NUM_VG 
GBL_OSKERNELTYPE 
GBL_OSKERNELTYPE_INT 
GBL_OSNAME 
GBL_OSRELEASE 
GBL_OSVERSION 
GBL_PRI_QUEUE 
GBL_PRI_WAIT_PCT 
GBL_PRI_WAIT_TIME 
GBL_PROC_SAMPLE 
GBL_RUN_QUEUE 
GBL_RUN_QUEUE_CUM 
GBL_RUN_QUEUE_HIGH 
GBL_SAMPLE 
GBL_SERIALNO 
GBL_STARTDATE 
GBL_STARTED_PROC 
GBL_STARTED_PROC_RATE 
GBL_STARTTIME 
GBL_STATDATE 
GBL_STATTIME 
GBL_SWAP_SPACE_AVAIL 
GBL_SWAP_SPACE_AVAIL_KB 
GBL_SWAP_SPACE_DEVICE_AVAIL 
GBL_SWAP_SPACE_DEVICE_UTIL 
GBL_SWAP_SPACE_USED 
GBL_SWAP_SPACE_USED_UTIL 
GBL_SWAP_SPACE_UTIL 
GBL_SWAP_SPACE_UTIL_CUM 
GBL_SWAP_SPACE_UTIL_HIGH 
GBL_SYSCALL 
GBL_SYSCALL_RATE 
GBL_SYSCALL_RATE_CUM 
GBL_SYSCALL_RATE_HIGH 
GBL_SYSCALL_READ 
GBL_SYSCALL_READ_CUM 
GBL_SYSCALL_READ_PCT 
GBL_SYSCALL_READ_RATE 
GBL_SYSCALL_READ_RATE_CUM 
GBL_SYSCALL_WRITE 
GBL_SYSCALL_WRITE_PCT 
GBL_SYSCALL_WRITE_RATE 
GBL_SYSTEM_ID 
GBL_SYSTEM_TYPE 
GBL_SYSTEM_UPTIME_HOURS 
GBL_SYSTEM_UPTIME_SECONDS 
GBL_THRESHOLD_PROCCPU 
GBL_THRESHOLD_PROCDISK 
GBL_THRESHOLD_PROCIO 
GBL_THRESHOLD_PROCMEM 
GBL_TT_OVERFLOW_COUNT 
GBL_ZOMBIE_PROC 

Table Metrics 
----------------------------------
TBL_BUFFER_HEADER_AVAIL 
TBL_BUFFER_HEADER_USED 
TBL_BUFFER_HEADER_USED_HIGH 
TBL_BUFFER_HEADER_UTIL 
TBL_BUFFER_HEADER_UTIL_HIGH 
TBL_FILE_LOCK_AVAIL 
TBL_FILE_LOCK_USED 
TBL_FILE_LOCK_USED_HIGH 
TBL_FILE_LOCK_UTIL 
TBL_FILE_LOCK_UTIL_HIGH 
TBL_FILE_TABLE_AVAIL 
TBL_FILE_TABLE_USED 
TBL_FILE_TABLE_USED_HIGH 
TBL_FILE_TABLE_UTIL 
TBL_FILE_TABLE_UTIL_HIGH 
TBL_INODE_CACHE_AVAIL 
TBL_INODE_CACHE_HIGH 
TBL_INODE_CACHE_USED 
TBL_MSG_BUFFER_ACTIVE 
TBL_MSG_BUFFER_AVAIL 
TBL_MSG_BUFFER_HIGH 
TBL_MSG_BUFFER_USED 
TBL_MSG_TABLE_ACTIVE 
TBL_MSG_TABLE_AVAIL 
TBL_MSG_TABLE_USED 
TBL_MSG_TABLE_UTIL 
TBL_MSG_TABLE_UTIL_HIGH 
TBL_NUM_NFSDS 
TBL_SEM_TABLE_ACTIVE 
TBL_SEM_TABLE_AVAIL 
TBL_SEM_TABLE_USED 
TBL_SEM_TABLE_UTIL 
TBL_SEM_TABLE_UTIL_HIGH 
TBL_SHMEM_ACTIVE 
TBL_SHMEM_AVAIL 
TBL_SHMEM_HIGH 
TBL_SHMEM_TABLE_ACTIVE 
TBL_SHMEM_TABLE_AVAIL 
TBL_SHMEM_TABLE_USED 
TBL_SHMEM_TABLE_UTIL 
TBL_SHMEM_TABLE_UTIL_HIGH 
TBL_SHMEM_USED 

Process Metrics 
----------------------------------
PROC_APP_ID 
PROC_APP_NAME 
PROC_CHILD_CPU_SYS_MODE_UTIL 
PROC_CHILD_CPU_TOTAL_UTIL 
PROC_CHILD_CPU_USER_MODE_UTIL 
PROC_CPU_ALIVE_SYS_MODE_UTIL 
PROC_CPU_ALIVE_TOTAL_UTIL 
PROC_CPU_ALIVE_USER_MODE_UTIL 
PROC_CPU_LAST_USED 
PROC_CPU_SWITCHES 
PROC_CPU_SWITCHES_CUM 
PROC_CPU_SYSCALL_TIME 
PROC_CPU_SYSCALL_TIME_CUM 
PROC_CPU_SYSCALL_UTIL 
PROC_CPU_SYSCALL_UTIL_CUM 
PROC_CPU_SYS_MODE_TIME 
PROC_CPU_SYS_MODE_TIME_CUM 
PROC_CPU_SYS_MODE_UTIL 
PROC_CPU_SYS_MODE_UTIL_CUM 
PROC_CPU_TOTAL_TIME 
PROC_CPU_TOTAL_TIME_CUM 
PROC_CPU_TOTAL_UTIL 
PROC_CPU_TOTAL_UTIL_CUM 
PROC_CPU_USER_MODE_TIME 
PROC_CPU_USER_MODE_TIME_CUM 
PROC_CPU_USER_MODE_UTIL 
PROC_CPU_USER_MODE_UTIL_CUM 
PROC_DISK_PHYS_IO_RATE 
PROC_DISK_PHYS_IO_RATE_CUM 
PROC_DISK_PHYS_READ 
PROC_DISK_PHYS_READ_CUM 
PROC_DISK_PHYS_READ_RATE 
PROC_DISK_PHYS_WRITE 
PROC_DISK_PHYS_WRITE_CUM 
PROC_DISK_PHYS_WRITE_RATE 
PROC_DISK_SUBSYSTEM_WAIT_PCT 
PROC_DISK_SUBSYSTEM_WAIT_PCT_CUM 
PROC_DISK_SUBSYSTEM_WAIT_TIME 
PROC_DISK_SUBSYSTEM_WAIT_TIME_CUM 
PROC_EUID 
PROC_FORCED_CSWITCH 
PROC_FORCED_CSWITCH_CUM 
PROC_GROUP_ID 
PROC_GROUP_NAME 
PROC_INTEREST 
PROC_INTERVAL 
PROC_INTERVAL_ALIVE 
PROC_INTERVAL_CUM 
PROC_IO_BYTE 
PROC_IO_BYTE_CUM 
PROC_IO_BYTE_RATE 
PROC_IO_BYTE_RATE_CUM 
PROC_MAJOR_FAULT 
PROC_MAJOR_FAULT_CUM 
PROC_MEM_DATA_VIRT 
PROC_MEM_LOCKED 
PROC_MEM_RES 
PROC_MEM_RES_HIGH 
PROC_MEM_SHARED_RES 
PROC_MEM_STACK_VIRT 
PROC_MEM_TEXT_VIRT 
PROC_MEM_VIRT 
PROC_MINOR_FAULT 
PROC_MINOR_FAULT_CUM 
PROC_NICE_PRI 
PROC_PAGEFAULT 
PROC_PAGEFAULT_RATE 
PROC_PAGEFAULT_RATE_CUM 
PROC_PARENT_PROC_ID 
PROC_PRI 
PROC_PRI_WAIT_PCT 
PROC_PRI_WAIT_PCT_CUM 
PROC_PRI_WAIT_TIME 
PROC_PRI_WAIT_TIME_CUM 
PROC_PROC_ARGV1 
PROC_PROC_CMD 
PROC_PROC_ID 
PROC_PROC_NAME 
PROC_RUN_TIME 
PROC_SCHEDULER 
PROC_STARTTIME 
PROC_STATE 
PROC_STATE_FLAG 
PROC_STOP_REASON 
PROC_STOP_REASON_FLAG 
PROC_THREAD_COUNT 
PROC_THREAD_ID 
PROC_TIME 
PROC_TOP_CPU_INDEX 
PROC_TOP_DISK_INDEX 
PROC_TTY 
PROC_TTY_DEV 
PROC_UID 
PROC_USER_NAME 
PROC_VOLUNTARY_CSWITCH 
PROC_VOLUNTARY_CSWITCH_CUM 

Application Metrics 
----------------------------------
APP_ACTIVE_APP 
APP_ACTIVE_PROC 
APP_ALIVE_PROC 
APP_COMPLETED_PROC 
APP_CPU_SYS_MODE_TIME 
APP_CPU_SYS_MODE_UTIL 
APP_CPU_TOTAL_TIME 
APP_CPU_TOTAL_UTIL 
APP_CPU_TOTAL_UTIL_CUM 
APP_CPU_USER_MODE_TIME 
APP_CPU_USER_MODE_UTIL 
APP_DISK_PHYS_IO 
APP_DISK_PHYS_IO_RATE 
APP_DISK_PHYS_READ 
APP_DISK_PHYS_READ_RATE 
APP_DISK_PHYS_WRITE 
APP_DISK_PHYS_WRITE_RATE 
APP_DISK_SUBSYSTEM_QUEUE 
APP_DISK_SUBSYSTEM_WAIT_PCT 
APP_INTERVAL 
APP_INTERVAL_CUM 
APP_IO_BYTE 
APP_IO_BYTE_RATE 
APP_MAJOR_FAULT 
APP_MAJOR_FAULT_RATE 
APP_MEM_RES 
APP_MEM_UTIL 
APP_MEM_VIRT 
APP_MINOR_FAULT 
APP_MINOR_FAULT_RATE 
APP_NAME 
APP_NUM 
APP_PRI 
APP_PRI_QUEUE 
APP_PRI_WAIT_PCT 
APP_PROC_RUN_TIME 
APP_SAMPLE 
APP_TIME 

Process By File Metrics 
----------------------------------
PROC_FILE_MODE 
PROC_FILE_NAME 
PROC_FILE_NUMBER 
PROC_FILE_OPEN 
PROC_FILE_TYPE 

By Disk Metrics 
----------------------------------
BYDSK_AVG_REQUEST_QUEUE 
BYDSK_AVG_SERVICE_TIME 
BYDSK_AVG_WAIT_TIME 
BYDSK_BUSY_TIME 
BYDSK_DEVNAME 
BYDSK_DEVNO 
BYDSK_DIRNAME 
BYDSK_ID 
BYDSK_INTERVAL 
BYDSK_INTERVAL_CUM 
BYDSK_PHYS_BYTE 
BYDSK_PHYS_BYTE_RATE 
BYDSK_PHYS_BYTE_RATE_CUM 
BYDSK_PHYS_IO 
BYDSK_PHYS_IO_RATE 
BYDSK_PHYS_IO_RATE_CUM 
BYDSK_PHYS_READ 
BYDSK_PHYS_READ_BYTE 
BYDSK_PHYS_READ_BYTE_RATE 
BYDSK_PHYS_READ_BYTE_RATE_CUM 
BYDSK_PHYS_READ_RATE 
BYDSK_PHYS_READ_RATE_CUM 
BYDSK_PHYS_WRITE 
BYDSK_PHYS_WRITE_BYTE 
BYDSK_PHYS_WRITE_BYTE_RATE 
BYDSK_PHYS_WRITE_BYTE_RATE_CUM 
BYDSK_PHYS_WRITE_RATE 
BYDSK_PHYS_WRITE_RATE_CUM 
BYDSK_QUEUE_0_UTIL 
BYDSK_QUEUE_2_UTIL 
BYDSK_QUEUE_4_UTIL 
BYDSK_QUEUE_8_UTIL 
BYDSK_QUEUE_X_UTIL 
BYDSK_REQUEST_QUEUE 
BYDSK_TIME 
BYDSK_UTIL 

File System Metrics 
----------------------------------
FS_BLOCK_SIZE 
FS_DEVNAME 
FS_DEVNO 
FS_DIRNAME 
FS_FRAG_SIZE 
FS_INODE_UTIL 
FS_IS_LVM 
FS_MAX_INODES 
FS_MAX_SIZE 
FS_PHYS_IO_RATE 
FS_PHYS_IO_RATE_CUM 
FS_PHYS_READ_BYTE_RATE 
FS_PHYS_READ_BYTE_RATE_CUM 
FS_PHYS_READ_RATE 
FS_PHYS_READ_RATE_CUM 
FS_PHYS_WRITE_BYTE_RATE 
FS_PHYS_WRITE_BYTE_RATE_CUM 
FS_PHYS_WRITE_RATE 
FS_PHYS_WRITE_RATE_CUM 
FS_SPACE_RESERVED 
FS_SPACE_USED 
FS_SPACE_UTIL 
FS_TYPE 

Logical Volume Metrics 
----------------------------------
LV_DEVNO 
LV_DIRNAME 
LV_GROUP_NAME 
LV_PHYSLV_SIZE 
LV_READ_BYTE_RATE 
LV_READ_BYTE_RATE_CUM 
LV_READ_RATE 
LV_READ_RATE_CUM 
LV_SPACE_UTIL 
LV_TYPE 
LV_WRITE_BYTE_RATE 
LV_WRITE_BYTE_RATE_CUM 
LV_WRITE_RATE 
LV_WRITE_RATE_CUM 

By Network Interface Metrics 
----------------------------------
BYNETIF_COLLISION 
BYNETIF_COLLISION_1_MIN_RATE 
BYNETIF_COLLISION_RATE 
BYNETIF_COLLISION_RATE_CUM 
BYNETIF_ERROR 
BYNETIF_ERROR_1_MIN_RATE 
BYNETIF_ERROR_RATE 
BYNETIF_ERROR_RATE_CUM 
BYNETIF_ID 
BYNETIF_IN_BYTE 
BYNETIF_IN_BYTE_RATE 
BYNETIF_IN_BYTE_RATE_CUM 
BYNETIF_IN_PACKET 
BYNETIF_IN_PACKET_RATE 
BYNETIF_IN_PACKET_RATE_CUM 
BYNETIF_MAC_ADDR 
BYNETIF_NAME 
BYNETIF_NET_SPEED 
BYNETIF_NET_TYPE 
BYNETIF_OUT_BYTE 
BYNETIF_OUT_BYTE_RATE 
BYNETIF_OUT_BYTE_RATE_CUM 
BYNETIF_OUT_PACKET 
BYNETIF_OUT_PACKET_RATE 
BYNETIF_OUT_PACKET_RATE_CUM 
BYNETIF_PACKET_RATE 
BYNETIF_UTIL 

By Swap Metrics 
----------------------------------
BYSWP_SWAP_PRI 
BYSWP_SWAP_SPACE_AVAIL 
BYSWP_SWAP_SPACE_NAME 
BYSWP_SWAP_SPACE_USED 
BYSWP_SWAP_TYPE 

By CPU Metrics 
----------------------------------
BYCPU_ACTIVE 
BYCPU_CORE_ID 
BYCPU_CPU_CLOCK 
BYCPU_CPU_GUEST_TIME 
BYCPU_CPU_GUEST_TIME_CUM 
BYCPU_CPU_GUEST_UTIL 
BYCPU_CPU_GUEST_UTIL_CUM 
BYCPU_CPU_INTERRUPT_TIME 
BYCPU_CPU_INTERRUPT_TIME_CUM 
BYCPU_CPU_INTERRUPT_UTIL 
BYCPU_CPU_INTERRUPT_UTIL_CUM 
BYCPU_CPU_NICE_TIME 
BYCPU_CPU_NICE_TIME_CUM 
BYCPU_CPU_NICE_UTIL 
BYCPU_CPU_NICE_UTIL_CUM 
BYCPU_CPU_STOLEN_TIME 
BYCPU_CPU_STOLEN_TIME_CUM 
BYCPU_CPU_STOLEN_UTIL 
BYCPU_CPU_STOLEN_UTIL_CUM 
BYCPU_CPU_SYSCALL_TIME 
BYCPU_CPU_SYSCALL_TIME_CUM 
BYCPU_CPU_SYSCALL_UTIL 
BYCPU_CPU_SYSCALL_UTIL_CUM 
BYCPU_CPU_SYS_MODE_TIME 
BYCPU_CPU_SYS_MODE_TIME_CUM 
BYCPU_CPU_SYS_MODE_UTIL 
BYCPU_CPU_SYS_MODE_UTIL_CUM 
BYCPU_CPU_TOTAL_TIME 
BYCPU_CPU_TOTAL_TIME_CUM 
BYCPU_CPU_TOTAL_UTIL 
BYCPU_CPU_TOTAL_UTIL_CUM 
BYCPU_CPU_TYPE 
BYCPU_CPU_USER_MODE_TIME 
BYCPU_CPU_USER_MODE_TIME_CUM 
BYCPU_CPU_USER_MODE_UTIL 
BYCPU_CPU_USER_MODE_UTIL_CUM 
BYCPU_ID 
BYCPU_INTERRUPT 
BYCPU_INTERRUPT_RATE 
BYCPU_STATE 

By CORE Metrics 
----------------------------------
BYCORE_CORE_ID 
BYCORE_IDLE_TIME 
BYCORE_IDLE_TIME_CUM 
BYCORE_IDLE_UTIL 
BYCORE_IDLE_UTIL_CUM 
BYCORE_IDLE_UTIL_HIGH 
BYCORE_INTERRUPT_TIME 
BYCORE_INTERRUPT_TIME_CUM 
BYCORE_INTERRUPT_UTIL 
BYCORE_INTERRUPT_UTIL_CUM 
BYCORE_INTERRUPT_UTIL_HIGH 
BYCORE_NICE_TIME 
BYCORE_NICE_TIME_CUM 
BYCORE_NICE_UTIL 
BYCORE_NICE_UTIL_CUM 
BYCORE_NICE_UTIL_HIGH 
BYCORE_SOCKET_ID 
BYCORE_SYS_MODE_TIME 
BYCORE_SYS_MODE_TIME_CUM 
BYCORE_SYS_MODE_UTIL 
BYCORE_SYS_MODE_UTIL_CUM 
BYCORE_SYS_MODE_UTIL_HIGH 
BYCORE_TOTAL_TIME 
BYCORE_TOTAL_TIME_CUM 
BYCORE_TOTAL_UTIL 
BYCORE_TOTAL_UTIL_CUM 
BYCORE_TOTAL_UTIL_HIGH 
BYCORE_USER_MODE_TIME 
BYCORE_USER_MODE_TIME_CUM 
BYCORE_USER_MODE_UTIL 
BYCORE_USER_MODE_UTIL_CUM 
BYCORE_USER_MODE_UTIL_HIGH 
BYCORE_WAIT_TIME 
BYCORE_WAIT_TIME_CUM 
BYCORE_WAIT_UTIL 
BYCORE_WAIT_UTIL_CUM 
BYCORE_WAIT_UTIL_HIGH 

Process By Memory Region Metrics 
----------------------------------
PROC_REGION_FILENAME 
PROC_REGION_PRIVATE_SHARED_FLAG 
PROC_REGION_PROT_FLAG 
PROC_REGION_TYPE 
PROC_REGION_VIRT 
PROC_REGION_VIRT_ADDRS 
PROC_REGION_VIRT_DATA 
PROC_REGION_VIRT_OTHER 
PROC_REGION_VIRT_SHMEM 
PROC_REGION_VIRT_STACK 
PROC_REGION_VIRT_TEXT 

By Operation Metrics 
----------------------------------
BYOP_CLIENT_COUNT 
BYOP_CLIENT_COUNT_CUM 
BYOP_INTERVAL 
BYOP_INTERVAL_CUM 
BYOP_NAME 
BYOP_SERVER_COUNT 
BYOP_SERVER_COUNT_CUM 

System Call Metrics 
----------------------------------
SYSCALL_ACTIVE_CUM 
SYSCALL_CALL_COUNT 
SYSCALL_CALL_COUNT_CUM 
SYSCALL_CALL_ID 
SYSCALL_CALL_NAME 
SYSCALL_CALL_RATE 
SYSCALL_CALL_RATE_CUM 
SYSCALL_CPU_TOTAL_TIME 
SYSCALL_CPU_TOTAL_TIME_CUM 
SYSCALL_INTERVAL 
SYSCALL_INTERVAL_CUM 

Logical Volume Detail Metrics 
----------------------------------
LVDETAIL_LABEL 
LVDETAIL_NAME 

Transaction Metrics 
----------------------------------
TT_ABORT 
TT_ABORT_CUM 
TT_ABORT_WALL_TIME 
TT_ABORT_WALL_TIME_CUM 
TT_APPNO 
TT_APP_NAME 
TT_CLIENT_CORRELATOR_COUNT 
TT_COUNT 
TT_COUNT_CUM 
TT_FAILED 
TT_FAILED_CUM 
TT_FAILED_WALL_TIME 
TT_FAILED_WALL_TIME_CUM 
TT_INFO 
TT_INPROGRESS_COUNT 
TT_INTERVAL 
TT_INTERVAL_CUM 
TT_MEASUREMENT_COUNT 
TT_NAME 
TT_SLO_COUNT 
TT_SLO_COUNT_CUM 
TT_SLO_PERCENT 
TT_SLO_THRESHOLD 
TT_TRAN_1_MIN_RATE 
TT_TRAN_ID 
TT_UID 
TT_UNAME 
TT_UPDATE 
TT_UPDATE_CUM 
TT_WALL_TIME 
TT_WALL_TIME_CUM 
TT_WALL_TIME_PER_TRAN 
TT_WALL_TIME_PER_TRAN_CUM 

Transaction Measurement Section Metrics 
----------------------------------
TTBIN_TRANS_COUNT 
TTBIN_TRANS_COUNT_CUM 
TTBIN_UPPER_RANGE 

By Process System Call Metrics 
----------------------------------
PROCSYSCALL_CALL_COUNT 
PROCSYSCALL_CALL_COUNT_CUM 
PROCSYSCALL_CALL_ID 
PROCSYSCALL_CALL_NAME 
PROCSYSCALL_CALL_RATE 
PROCSYSCALL_CALL_RATE_CUM 
PROCSYSCALL_INTERVAL 
PROCSYSCALL_INTERVAL_CUM 
PROCSYSCALL_TOTAL_TIME 
PROCSYSCALL_TOTAL_TIME_CUM 

Thread Metrics 
----------------------------------
THREAD_APP_ID 
THREAD_APP_NAME 
THREAD_CHILD_CPU_SYS_MODE_UTIL 
THREAD_CHILD_CPU_TOTAL_UTIL 
THREAD_CHILD_CPU_USER_MODE_UTIL 
THREAD_CPU_ALIVE_SYS_MODE_UTIL 
THREAD_CPU_ALIVE_TOTAL_UTIL 
THREAD_CPU_ALIVE_USER_MODE_UTIL 
THREAD_CPU_LAST_USED 
THREAD_CPU_SWITCHES 
THREAD_CPU_SWITCHES_CUM 
THREAD_CPU_SYSCALL_TIME 
THREAD_CPU_SYSCALL_TIME_CUM 
THREAD_CPU_SYSCALL_UTIL 
THREAD_CPU_SYSCALL_UTIL_CUM 
THREAD_CPU_SYS_MODE_TIME 
THREAD_CPU_SYS_MODE_TIME_CUM 
THREAD_CPU_SYS_MODE_UTIL 
THREAD_CPU_SYS_MODE_UTIL_CUM 
THREAD_CPU_TOTAL_TIME 
THREAD_CPU_TOTAL_TIME_CUM 
THREAD_CPU_TOTAL_UTIL 
THREAD_CPU_TOTAL_UTIL_CUM 
THREAD_CPU_USER_MODE_TIME 
THREAD_CPU_USER_MODE_TIME_CUM 
THREAD_CPU_USER_MODE_UTIL 
THREAD_CPU_USER_MODE_UTIL_CUM 
THREAD_DISK_PHYS_IO_RATE 
THREAD_DISK_PHYS_IO_RATE_CUM 
THREAD_DISK_PHYS_READ 
THREAD_DISK_PHYS_READ_CUM 
THREAD_DISK_PHYS_READ_RATE 
THREAD_DISK_PHYS_WRITE 
THREAD_DISK_PHYS_WRITE_CUM 
THREAD_DISK_PHYS_WRITE_RATE 
THREAD_DISK_SUBSYSTEM_WAIT_PCT 
THREAD_DISK_SUBSYSTEM_WAIT_PCT_CUM 
THREAD_DISK_SUBSYSTEM_WAIT_TIME 
THREAD_DISK_SUBSYSTEM_WAIT_TIME_CUM 
THREAD_EUID 
THREAD_FORCED_CSWITCH 
THREAD_FORCED_CSWITCH_CUM 
THREAD_GROUP_ID 
THREAD_GROUP_NAME 
THREAD_INTEREST 
THREAD_INTERVAL 
THREAD_INTERVAL_ALIVE 
THREAD_INTERVAL_CUM 
THREAD_IO_BYTE 
THREAD_IO_BYTE_CUM 
THREAD_IO_BYTE_RATE 
THREAD_IO_BYTE_RATE_CUM 
THREAD_MAJOR_FAULT 
THREAD_MAJOR_FAULT_CUM 
THREAD_MEM_DATA_VIRT 
THREAD_MEM_LOCKED 
THREAD_MEM_RES 
THREAD_MEM_RES_HIGH 
THREAD_MEM_SHARED_RES 
THREAD_MEM_STACK_VIRT 
THREAD_MEM_TEXT_VIRT 
THREAD_MEM_VIRT 
THREAD_MINOR_FAULT 
THREAD_MINOR_FAULT_CUM 
THREAD_NICE_PRI 
THREAD_PAGEFAULT 
THREAD_PAGEFAULT_RATE 
THREAD_PAGEFAULT_RATE_CUM 
THREAD_PARENT_PROC_ID 
THREAD_PRI 
THREAD_PRI_WAIT_PCT 
THREAD_PRI_WAIT_PCT_CUM 
THREAD_PRI_WAIT_TIME 
THREAD_PRI_WAIT_TIME_CUM 
THREAD_PROC_ARGV1 
THREAD_PROC_CMD 
THREAD_PROC_ID 
THREAD_PROC_NAME 
THREAD_RUN_TIME 
THREAD_SCHEDULER 
THREAD_STARTTIME 
THREAD_STATE 
THREAD_STATE_FLAG 
THREAD_STOP_REASON 
THREAD_STOP_REASON_FLAG 
THREAD_THREAD_COUNT 
THREAD_THREAD_ID 
THREAD_TIME 
THREAD_TOP_CPU_INDEX 
THREAD_TOP_DISK_INDEX 
THREAD_TTY 
THREAD_TTY_DEV 
THREAD_UID 
THREAD_USER_NAME 
THREAD_VOLUNTARY_CSWITCH 
THREAD_VOLUNTARY_CSWITCH_CUM 

Transaction Client Metrics 
----------------------------------
TT_CLIENT_ABORT 
TT_CLIENT_ABORT_CUM 
TT_CLIENT_ABORT_WALL_TIME 
TT_CLIENT_ABORT_WALL_TIME_CUM 
TT_CLIENT_ADDRESS 
TT_CLIENT_ADDRESS_FORMAT 
TT_CLIENT_TRAN_ID 
TT_CLIENT_COUNT 
TT_CLIENT_COUNT_CUM 
TT_CLIENT_FAILED 
TT_CLIENT_FAILED_CUM 
TT_CLIENT_FAILED_WALL_TIME 
TT_CLIENT_FAILED_WALL_TIME_CUM 
TT_CLIENT_INTERVAL 
TT_CLIENT_INTERVAL_CUM 
TT_CLIENT_SLO_COUNT 
TT_CLIENT_SLO_COUNT_CUM 
TT_CLIENT_UPDATE 
TT_CLIENT_UPDATE_CUM 
TT_CLIENT_WALL_TIME 
TT_CLIENT_WALL_TIME_CUM 
TT_CLIENT_WALL_TIME_PER_TRAN 
TT_CLIENT_WALL_TIME_PER_TRAN_CUM 

Transaction Instance Metrics 
----------------------------------
TT_INSTANCE_ID 
TT_INSTANCE_PROC_ID 
TT_INSTANCE_START_TIME 
TT_INSTANCE_STOP_TIME 
TT_INSTANCE_THREAD_ID 
TT_INSTANCE_UPDATE_COUNT 
TT_INSTANCE_UPDATE_TIME 
TT_INSTANCE_WALL_TIME 

Transaction User Defined Measurement Metrics 
----------------------------------
TT_USER_MEASUREMENT_AVG 
TT_USER_MEASUREMENT_MAX 
TT_USER_MEASUREMENT_MIN 
TT_USER_MEASUREMENT_NAME 
TT_USER_MEASUREMENT_STRING1024_VALUE 
TT_USER_MEASUREMENT_STRING32_VALUE 
TT_USER_MEASUREMENT_TYPE 
TT_USER_MEASUREMENT_VALUE 

Transaction Client User Defined Measurement Metrics 
----------------------------------
TT_CLIENT_USER_MEASUREMENT_AVG 
TT_CLIENT_USER_MEASUREMENT_MAX 
TT_CLIENT_USER_MEASUREMENT_MIN 
TT_CLIENT_USER_MEASUREMENT_NAME 
TT_CLIENT_USER_MEASUREMENT_STRING1024_VALUE 
TT_CLIENT_USER_MEASUREMENT_STRING32_VALUE 
TT_CLIENT_USER_MEASUREMENT_TYPE 
TT_CLIENT_USER_MEASUREMENT_VALUE 

Transaction Instance User Defined Measurement Metrics 
----------------------------------
TT_INSTANCE_USER_MEASUREMENT_AVG 
TT_INSTANCE_USER_MEASUREMENT_MAX 
TT_INSTANCE_USER_MEASUREMENT_MIN 
TT_INSTANCE_USER_MEASUREMENT_NAME 
TT_INSTANCE_USER_MEASUREMENT_STRING1024_VALUE 
TT_INSTANCE_USER_MEASUREMENT_STRING32_VALUE 
TT_INSTANCE_USER_MEASUREMENT_TYPE 
TT_INSTANCE_USER_MEASUREMENT_VALUE 

By Hba Metrics 
----------------------------------
BYHBA_BYTE_RATE 
BYHBA_BYTE_RATE_CUM 
BYHBA_CLASS 
BYHBA_DEVNAME 
BYHBA_DEVNO 
BYHBA_DRIVER 
BYHBA_DUMPED_FRAMES 
BYHBA_DUMPED_FRAMES_RATE 
BYHBA_DUMPED_FRAMES_RATE_CUM 
BYHBA_ERR_FRAMES 
BYHBA_ERR_FRAMES_RATE 
BYHBA_ERR_FRAMES_RATE_CUM 
BYHBA_ID 
BYHBA_INTERVAL 
BYHBA_INTERVAL_CUM 
BYHBA_INVALID_CRC 
BYHBA_INVALID_CRC_RATE 
BYHBA_INVALID_CRC_RATE_CUM 
BYHBA_INVALID_TX_WORDS 
BYHBA_INVALID_TX_WORDS_RATE 
BYHBA_INVALID_TX_WORDS_RATE_CUM 
BYHBA_IO_FRAMES 
BYHBA_IO_FRAMES_RATE 
BYHBA_IO_FRAMES_RATE_CUM 
BYHBA_LINK_FAILURE 
BYHBA_LINK_FAILURE_RATE 
BYHBA_LINK_FAILURE_RATE_CUM 
BYHBA_LIP 
BYHBA_LIP_RATE 
BYHBA_LIP_RATE_CUM 
BYHBA_LOSS_OF_SIGNAL 
BYHBA_LOSS_OF_SIGNAL_RATE 
BYHBA_LOSS_OF_SIGNAL_RATE_CUM 
BYHBA_LOSS_OF_SYNC 
BYHBA_LOSS_OF_SYNC_RATE 
BYHBA_LOSS_OF_SYNC_RATE_CUM 
BYHBA_NAME 
BYHBA_NOS 
BYHBA_NOS_RATE 
BYHBA_NOS_RATE_CUM 
BYHBA_PRIM_SEQ_PROTO_ERR 
BYHBA_PRIM_SEQ_PROTO_ERR_RATE 
BYHBA_PRIM_SEQ_PROTO_ERR_RATE_CUM 
BYHBA_READ_BYTE_RATE 
BYHBA_READ_BYTE_RATE_CUM 
BYHBA_RX_FRAMES 
BYHBA_RX_FRAMES_RATE 
BYHBA_RX_FRAMES_RATE_CUM 
BYHBA_STATE 
BYHBA_TIME 
BYHBA_TX_FRAMES 
BYHBA_TX_FRAMES_RATE 
BYHBA_TX_FRAMES_RATE_CUM 
BYHBA_TYPE 
BYHBA_WRITE_BYTE_RATE 
BYHBA_WRITE_BYTE_RATE_CUM
 

METRIC DEFINITIONS
=============================


APP_ACTIVE_APP
----------------------------------
The number of applications that had processes active (consuming cpu 
resources) during the interval.


APP_ACTIVE_PROC
----------------------------------
An active process is one that exists and consumes some CPU time.  
APP_ACTIVE_PROC is the sum of the alive-process-time/interval-time ratios of 
every process belonging to an application that is active (uses any CPU time) 
during an interval.
The following diagram of a four second interval showing two processes, A and 
B, for an application should be used to understand the above definition.  
Note the difference between active processes, which consume CPU time, and 
alive processes which merely exist on the system.

     ----------- Seconds -----------
       1         2         3      4
Proc
---- ----      ----      ----   ----
A    live      live      live   live

B    live/CPU  live/CPU  live   dead

Process A is alive for the entire four second interval, but consumes no CPU.  
A’s contribution to APP_ALIVE_PROC is 4*1/4.  A contributes 0*1/4 to 
APP_ACTIVE_PROC.  B’s contribution to APP_ALIVE_PROC is 3*1/4.  B contributes 
2*1/4 to APP_ACTIVE_PROC.  Thus, for this interval, APP_ACTIVE_PROC equals 
0.5 and APP_ALIVE_PROC equals 1.75.
Because a process may be alive but not active, APP_ACTIVE_PROC will always be 
less than or equal to APP_ALIVE_PROC.
This metric indicates the number of processes in an application group that 
are competing for the CPU.  This metric is useful, along with other metrics, 
for comparing loads placed on the system by different groups of processes.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


APP_ALIVE_PROC
----------------------------------
An alive process is one that exists on the system.  APP_ALIVE_PROC is the sum 
of the alive-process-time/interval-time ratios for every process belonging to 
a given application.
The following diagram of a four second interval showing two processes, A and 
B, for an application should be used to understand the above definition.  
Note the difference between active processes, which consume CPU time, and 
alive processes which merely exist on the system.

     ----------- Seconds -----------
       1         2         3      4
Proc
---- ----      ----      ----   ----
A    live      live      live   live

B    live/CPU  live/CPU  live   dead

Process A is alive for the entire four second interval but consumes no CPU.  
A’s contribution to APP_ALIVE_PROC is 4*1/4.  A contributes 0*1/4 to 
APP_ACTIVE_PROC.  B’s contribution to APP_ALIVE_PROC is 3*1/4.  B contributes 
2*1/4 to APP_ACTIVE_PROC.  Thus, for this interval, APP_ACTIVE_PROC equals 
0.5 and APP_ALIVE_PROC equals 1.75.
Because a process may be alive but not active, APP_ACTIVE_PROC will always be 
less than or equal to APP_ALIVE_PROC.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


APP_COMPLETED_PROC
----------------------------------
The number of processes in this group that completed during the interval.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


APP_CPU_SYS_MODE_TIME
----------------------------------
The time, in seconds, during the interval that the CPU was in system mode for 
processes in this group.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_CPU_SYS_MODE_UTIL
----------------------------------
The percentage of time during the interval that the CPU was used in system 
mode for processes in this group.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
High system CPU utilizations are normal for IO intensive groups.  Abnormally 
high system CPU utilization can indicate that a hardware problem is causing a 
high interrupt rate.  It can also indicate programs that are not making 
efficient system calls.  On platforms other than HPUX, If the ignore_mt flag 
is set(true) in parm file, this metric will report values normalized against 
the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_CPU_TOTAL_TIME
----------------------------------
The total CPU time, in seconds, devoted to processes in this group during the 
interval.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_CPU_TOTAL_UTIL
----------------------------------
The percentage of the total CPU time devoted to processes in this group 
during the interval.  This indicates the relative CPU load placed on the 
system by processes in this group.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
Large values for this metric may indicate that this group is causing a CPU 
bottleneck.  This would be normal in a computation-bound workload, but might 
mean that processes are using excessive CPU time and perhaps looping.
If the “other” application shows significant amounts of CPU, you may want to 
consider tuning your parm file so that process activity is accounted for in 
known applications.

  APP_CPU_TOTAL_UTIL =
    APP_CPU_SYS_MODE_UTIL +
    APP_CPU_USER_MODE_UTIL
NOTE: On Windows, the sum of the APP_CPU_TOTAL_UTIL metrics may not equal 
GBL_CPU_TOTAL_UTIL.  Microsoft states that “this is expected behavior” 
because the GBL_CPU_TOTAL_UTIL metric is taken from the NT performance 
library Processor objects while the APP_CPU_TOTAL_UTIL metrics are taken from 
the Process objects.  Microsoft states that there can be CPU time accounted 
for in the Processor system objects that may not be seen in the Process 
objects.  On platforms other than HPUX, If the ignore_mt flag is set(true) in 
parm file, this metric will report values normalized against the number of 
active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_CPU_TOTAL_UTIL_CUM
----------------------------------
The average CPU time per interval for processes in this group over the 
cumulative collection time, or since the last PRM configuration change on HP-
UX.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_CPU_USER_MODE_TIME
----------------------------------
The time, in seconds, that processes in this group were in user mode during 
the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_CPU_USER_MODE_UTIL
----------------------------------
The percentage of time that processes in this group were using the CPU in 
user mode during the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
High user mode CPU percentages are normal for computation-intensive groups.  
Low values of user CPU utilization compared to relatively high values for 
APP_CPU_SYS_MODE_UTIL can indicate a hardware problem or improperly tuned 
programs in this group.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



APP_DISK_PHYS_IO
----------------------------------
The number of physical IOs for processes in this group during the interval.


APP_DISK_PHYS_IO_RATE
----------------------------------
The number of physical IOs per second for processes in this group during the 
interval.


APP_DISK_PHYS_READ
----------------------------------
The number of physical reads for processes in this group during the interval.


APP_DISK_PHYS_READ_RATE
----------------------------------
The number of physical reads per second for processes in this group during 
the interval.


APP_DISK_PHYS_WRITE
----------------------------------
The number of physical writes for processes in this group during the 
interval.


APP_DISK_PHYS_WRITE_RATE
----------------------------------
The number of physical writes per second for processes in this group during 
the interval.


APP_DISK_SUBSYSTEM_QUEUE
----------------------------------
The average number of processes or kernel threads in this group that were 
blocked on the disk subsystem (waiting for their file system IOs to complete) 
during the interval.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The Application QUEUE metrics, which are based on block states, represent 
the average number of process or kernel thread counts, not actual queues, 
within the context of a specific application.
The Application WAIT PCT metrics, which are also based on block states, 
represent the percentage of processes or kernel threads that were alive on 
the system within the context of a specific application.  These values will 
vary greatly depending on the application.
No direct comparison is reasonable with the Global Queue metrics since they 
represent the average number of all processes or kernel threads that were 
alive on the system.  As such, the Application WAIT PCT metrics cannot be 
summed or compared with global values easily.  In addition, the sum of each 
Application WAIT PCT for all applications will not equal 100% since these 
values will vary greatly depending on the number of processes or kernel 
threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


APP_DISK_SUBSYSTEM_WAIT_PCT
----------------------------------
The percentage of time processes or kernel threads in this group were blocked 
on the disk subsystem (waiting for their file system IOs to complete) during 
the interval.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 A percentage of time spent in a wait state is calculated as the accumulated 
time kernel threads belonging to processes in this group spent waiting in 
this state, divided by accumulated alive time of kernel threads belonging to 
processes in this group during the interval.
For example, assume an application has 20 kernel threads.  During the 
interval, ten kernel threads slept the entire time, while ten kernel threads 
waited on terminal input.  As a result, the application wait percent values 
would be 50% for SLEEP and 50% for TERM (that is, terminal IO).
 The Application QUEUE metrics, which are based on block states, represent 
the average number of process or kernel thread counts, not actual queues, 
within the context of a specific application.
The Application WAIT PCT metrics, which are also based on block states, 
represent the percentage of processes or kernel threads that were alive on 
the system within the context of a specific application.  These values will 
vary greatly depending on the application.
No direct comparison is reasonable with the Global Queue metrics since they 
represent the average number of all processes or kernel threads that were 
alive on the system.  As such, the Application WAIT PCT metrics cannot be 
summed or compared with global values easily.  In addition, the sum of each 
Application WAIT PCT for all applications will not equal 100% since these 
values will vary greatly depending on the number of processes or kernel 
threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


APP_INTERVAL
----------------------------------
The amount of time in the interval.


APP_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


APP_IO_BYTE
----------------------------------
The number of characters (in KB) transferred for processes in this group to 
all devices during the interval.  This includes IO to disk, terminal, tape 
and printers.


APP_IO_BYTE_RATE
----------------------------------
The number of characters (in KB) per second transferred for processes in this 
group to all devices during the interval.  This includes IO to disk, 
terminal, tape and printers.


APP_MAJOR_FAULT
----------------------------------
The number of major page faults that required a disk IO for processes in this 
group during the interval.


APP_MAJOR_FAULT_RATE
----------------------------------
The number of major page faults per second that required a disk IO for 
processes in this group during the interval.


APP_MEM_RES
----------------------------------
On Unix systems, this is the sum of the size (in MB) of resident memory for 
processes in this group that were alive at the end of the interval.  This 
consists of text, data, stack, and shared memory regions.
On HP-UX, since PROC_MEM_RES typically takes shared region references into 
account, this approximates the total resident (physical) memory consumed by 
all processes in this group.
On all other Unix systems, this is the sum of the resident memory region 
sizes for all processes in this group.  When the resident memory size for 
processes includes shared regions, such as shared memory and library text and 
data, the shared regions are counted multiple times in this sum.  For 
example, if the application contains four processes that are attached to a 
500MB shared memory region that is all resident in physical memory, then 
2000MB is contributed towards the sum in this metric.  As such, this metric 
can overestimate the resident memory being used by processes in this group 
when they share memory regions.
Refer to the help text for PROC_MEM_RES for additional information.
On Windows, this is the sum of the size (in MB) of the working sets for 
processes in this group during the interval.  The working set counts memory 
pages referenced recently by the threads making up this group.  Note that the 
size of the working set is often larger than the amount of pagefile space 
consumed.


APP_MEM_UTIL
----------------------------------
On Unix systems, this is the approximate percentage of the system’s physical 
memory used as resident memory by processes in this group that were alive at 
the end of the interval.  This metric summarizes process private and shared 
memory in each application.
On Windows, this is an estimate of the percentage of the system’s physical 
memory allocated for working set memory by processes in this group during the 
interval.
On HP-UX, this consists of text, data, stack, as well the process’ portion of 
shared memory regions (such as, shared libraries, text segments, and shared 
data).  The sum of the shared region pages is typically divided by the number 
of references.


APP_MEM_VIRT
----------------------------------
On Unix systems, this is the sum (in MB) of virtual memory for processes in 
this group that were alive at the end of the interval.  This consists of 
text, data, stack, and shared memory regions.
On HP-UX, since PROC_MEM_VIRT typically takes shared region references into 
account, this approximates the total virtual memory consumed by all processes 
in this group.
On all other Unix systems, this is the sum of the virtual memory region sizes 
for all processes in this group.  When the virtual memory size for processes 
includes shared regions, such as shared memory and library text and data, the 
shared regions are counted multiple times in this sum.  For example, if the 
application contains four processes that are attached to a 500MB shared 
memory region, then 2000MB is reported in this metric.  As such, this metric 
can overestimate the virtual memory being used by processes in this group 
when they share memory regions.
On Windows, this is the sum (in MB) of paging file space used for all 
processes in this group during the interval. Groups of processes may have 
working set sizes (APP_MEM_RES) larger than the size of their pagefile space.


APP_MINOR_FAULT
----------------------------------
The number of minor page faults satisfied in memory (a page was reclaimed 
from one of the free lists) for processes in this group during the interval.


APP_MINOR_FAULT_RATE
----------------------------------
The number of minor page faults per second satisfied in memory (pages were 
reclaimed from one of the free lists) for processes in this group during the 
interval.


APP_NAME
----------------------------------
The name of the application (up to 20 characters).  This comes from the parm 
file where the applications are defined.
The application called “other” captures all processes not aggregated into 
applications specifically defined in the parm file.  In other words, if no 
applications are defined in the parm file, then all process data would be 
reflected in the “other” application.


APP_NUM
----------------------------------
The sequentially assigned number of this application or, on Solaris, the 
project ID when application grouping by project is enabled.


APP_PRI
----------------------------------
On Unix systems, this is the average priority of the processes in this group 
during the interval.
On Windows, this is the average base priority of the processes in this group 
during the interval.


APP_PRI_QUEUE
----------------------------------
The average number of processes or kernel threads in this group blocked on 
PRI (waiting for their priority to become high enough to get the CPU) during 
the interval.
This is calculated as the accumulated time that all processes or kernel 
threads in this group spent blocked on PRI divided by the interval time.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The Application QUEUE metrics, which are based on block states, represent 
the average number of process or kernel thread counts, not actual queues, 
within the context of a specific application.
The Application WAIT PCT metrics, which are also based on block states, 
represent the percentage of processes or kernel threads that were alive on 
the system within the context of a specific application.  These values will 
vary greatly depending on the application.
No direct comparison is reasonable with the Global Queue metrics since they 
represent the average number of all processes or kernel threads that were 
alive on the system.  As such, the Application WAIT PCT metrics cannot be 
summed or compared with global values easily.  In addition, the sum of each 
Application WAIT PCT for all applications will not equal 100% since these 
values will vary greatly depending on the number of processes or kernel 
threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


APP_PRI_WAIT_PCT
----------------------------------
The percentage of time processes or kernel threads in this group were blocked 
on PRI (waiting for their priority to become high enough to get the CPU) 
during the interval.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 A percentage of time spent in a wait state is calculated as the accumulated 
time kernel threads belonging to processes in this group spent waiting in 
this state, divided by accumulated alive time of kernel threads belonging to 
processes in this group during the interval.
For example, assume an application has 20 kernel threads.  During the 
interval, ten kernel threads slept the entire time, while ten kernel threads 
waited on terminal input.  As a result, the application wait percent values 
would be 50% for SLEEP and 50% for TERM (that is, terminal IO).
 The Application QUEUE metrics, which are based on block states, represent 
the average number of process or kernel thread counts, not actual queues, 
within the context of a specific application.
The Application WAIT PCT metrics, which are also based on block states, 
represent the percentage of processes or kernel threads that were alive on 
the system within the context of a specific application.  These values will 
vary greatly depending on the application.
No direct comparison is reasonable with the Global Queue metrics since they 
represent the average number of all processes or kernel threads that were 
alive on the system.  As such, the Application WAIT PCT metrics cannot be 
summed or compared with global values easily.  In addition, the sum of each 
Application WAIT PCT for all applications will not equal 100% since these 
values will vary greatly depending on the number of processes or kernel 
threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


APP_PROC_RUN_TIME
----------------------------------
The average run time for processes in this group that completed during the 
interval.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


APP_SAMPLE
----------------------------------
The number of samples of process data that have been averaged or accumulated 
during this sample.


APP_TIME
----------------------------------
The end time of the measurement interval.


BYCORE_CORE_ID
----------------------------------
The ID number of the core .


BYCORE_IDLE_TIME
----------------------------------
The time consumed by this Core was in idle mode during the interval.


BYCORE_IDLE_TIME_CUM
----------------------------------
The Cumulative time consumed by this Core was in idle mode.


BYCORE_IDLE_UTIL
----------------------------------
The percentage of time that this Core was in idle mode during the interval.


BYCORE_IDLE_UTIL_CUM
----------------------------------
The average percentage of time that this Core was in idle mode over the 
cumulative collection time.


BYCORE_IDLE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the Core was in 
idle mode over the cumulative collection time.


BYCORE_INTERRUPT_TIME
----------------------------------
The time consumed by this Core was in interrupt mode during the interval.


BYCORE_INTERRUPT_TIME_CUM
----------------------------------
The Cumulative time consumed by this Core was in interrupt mode.


BYCORE_INTERRUPT_UTIL
----------------------------------
The percentage of time that this Core was in interrupt mode during the 
interval.


BYCORE_INTERRUPT_UTIL_CUM
----------------------------------
The average percentage of time that this Core was in interrupt mode over the 
cumulative collection time.


BYCORE_INTERRUPT_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the Core was in 
interrupt mode over the cumulative collection time.


BYCORE_NICE_TIME
----------------------------------
The time consumed by this Core was in nice mode during the interval.


BYCORE_NICE_TIME_CUM
----------------------------------
The Cumulative time consumed by this Core was in nice mode.


BYCORE_NICE_UTIL
----------------------------------
The percentage of time that this Core was in nice mode during the interval.


BYCORE_NICE_UTIL_CUM
----------------------------------
The average percentage of time that this Core was in nice mode over the 
cumulative collection time.


BYCORE_NICE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the Core was in 
nice mode over the cumulative collection time.


BYCORE_SOCKET_ID
----------------------------------
The ID number of the socket .


BYCORE_SYS_MODE_TIME
----------------------------------
The time consumed by this Core was in system mode during the interval.


BYCORE_SYS_MODE_TIME_CUM
----------------------------------
The Cumulative time consumed by this Core was in system mode.


BYCORE_SYS_MODE_UTIL
----------------------------------
The percentage of time that this Core was in system mode during the interval.


BYCORE_SYS_MODE_UTIL_CUM
----------------------------------
The average percentage of time that this Core was in system mode over the 
cumulative collection time.


BYCORE_SYS_MODE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the Core was in 
system mode over the cumulative collection time.


BYCORE_TOTAL_TIME
----------------------------------
Total time consumed by this Core in the current interval.


BYCORE_TOTAL_TIME_CUM
----------------------------------
Cumulative total time consumed by this Core .


BYCORE_TOTAL_UTIL
----------------------------------
The percentage of time that this Core was not Idle


BYCORE_TOTAL_UTIL_CUM
----------------------------------
The average percentage of time that this Core was not idle over the 
cumulative collection time.


BYCORE_TOTAL_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the core was not 
idle over the cumulative collection time.


BYCORE_USER_MODE_TIME
----------------------------------
The time consumed by this Core was in user mode during the interval.


BYCORE_USER_MODE_TIME_CUM
----------------------------------
The Cumulative time consumed by this Core was in user mode.


BYCORE_USER_MODE_UTIL
----------------------------------
The percentage of time that this Core was in user mode during the interval.


BYCORE_USER_MODE_UTIL_CUM
----------------------------------
The average percentage of time that this Core was in user mode over the 
cumulative collection time.


BYCORE_USER_MODE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the Core was in 
user mode over the cumulative collection time.


BYCORE_WAIT_TIME
----------------------------------
The time consumed by this Core was in wait mode during the interval.


BYCORE_WAIT_TIME_CUM
----------------------------------
The Cumulative time consumed by this Core was in wait mode.


BYCORE_WAIT_UTIL
----------------------------------
The percentage of time that this Core was in wait mode during the interval.


BYCORE_WAIT_UTIL_CUM
----------------------------------
The average percentage of time that this Core was in wait mode over the 
cumulative collection time.


BYCORE_WAIT_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the Core was in 
wait mode over the cumulative collection time.


BYCPU_ACTIVE
----------------------------------
Indicates whether or not this CPU is online.  A CPU that is online is 
considered active.
For HP-UX and certain versions of Linux, the sar(1M) command allows you to 
check the status of the system CPUs.
For SUN and DEC, the commands psrinfo(1M) and psradm(1M) allow you to check 
or change the status of the system CPUs.
For AIX, the pstat(1) command allows you to check the status of the system 
CPUs.


BYCPU_CORE_ID
----------------------------------
The Core ID is this cpu.


BYCPU_CPU_CLOCK
----------------------------------
The clock speed of the CPU in the current slot.  The clock speed is in MHz 
for the selected CPU.
 The Linux kernel currently doesn’t provide any metadata information for 
disabled CPUs. This means that there is no way to find out types, speeds, as 
well as hardware IDs or any other information that is used to determine the 
number of cores, the number of threads, the HyperThreading state, etc...  If 
the agent (or Glance) is started while some of the CPUs are disabled, some of 
these metrics will be “na”, some will be based on what is visible at startup 
time. All information will be updated if/when additional CPUs are enabled and 
information about them becomes available. The configuration counts will 
remain at the highest discovered level (i.e. if CPUs are then disabled, the 
maximum number of CPUs/cores/etc... will remain at the highest observed 
level). It is recommended that the agent be started with all CPUs enabled.
On Linux, this value is always rounded up to the next MHz.  Note that Linux 
supports dynamic frequency scaling and if it is enabled then there can be a 
change in CPU speed with varying load.


BYCPU_CPU_GUEST_TIME
----------------------------------
The time, in seconds, that this CPU was servicing guests during the interval.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.


BYCPU_CPU_GUEST_TIME_CUM
----------------------------------
The time, in seconds, that this CPU was servicing guests over the cumulative 
collection time.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYCPU_CPU_GUEST_UTIL
----------------------------------
The percentage of time that this CPU was servicing guests during the 
interval.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.


BYCPU_CPU_GUEST_UTIL_CUM
----------------------------------
The percentage of time that this CPU was servicing guests over the cumulative 
collection time.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYCPU_CPU_INTERRUPT_TIME
----------------------------------
The time, in seconds, that this CPU was performing interrupt processing 
during the interval.  On platforms other than HPUX, If the ignore_mt flag is 
set(true) in parm file, this metric will report values normalized against the 
number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_INTERRUPT_TIME_CUM
----------------------------------
The time, in seconds, that this CPU was performing interrupt processing over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_INTERRUPT_UTIL
----------------------------------
The percentage of time that this CPU was performing interrupt processing 
during the interval.  On platforms other than HPUX, If the ignore_mt flag is 
set(true) in parm file, this metric will report values normalized against the 
number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_INTERRUPT_UTIL_CUM
----------------------------------
The percentage of time that this CPU was performing interrupt processing over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_NICE_TIME
----------------------------------
The time, in seconds, that this CPU was in user mode at a nice priority 
during the interval.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.  On platforms other than HPUX, If the ignore_mt flag is set(true) in 
parm file, this metric will report values normalized against the number of 
active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_NICE_TIME_CUM
----------------------------------
The time, in seconds, that this CPU was in user mode at a nice priority over 
the cumulative collection time.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_NICE_UTIL
----------------------------------
The percentage of time that this CPU was in user mode at a nice priority 
during the interval.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.  On platforms other than HPUX, If the ignore_mt flag is set(true) in 
parm file, this metric will report values normalized against the number of 
active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_NICE_UTIL_CUM
----------------------------------
The average percentage of time that this CPU was in user mode at a nice 
priority over the cumulative collection time.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_STOLEN_TIME
----------------------------------
The time, in seconds, that was stolen from this CPU during the interval.
 Stolen (or steal, or involuntary wait) time, on Linux, is the time that the 
CPU had runnable threads, but the Xen hypervisor chose to run something else 
instead. KVM hosts, as of this release, do not update these counters.  Stolen 
CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’.


BYCPU_CPU_STOLEN_TIME_CUM
----------------------------------
The time, in seconds, that was stolen from this CPU over the cumulative 
collection time.  Stolen (or steal, or involuntary wait) time, on Linux, is 
the time that the CPU had runnable threads, but the Xen hypervisor chose to 
run something else instead. KVM hosts, as of this release, do not update 
these counters.  Stolen CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in 
‘vmstat’.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYCPU_CPU_STOLEN_UTIL
----------------------------------
The time, in seconds, that was stolen from this CPU during the interval.  
Stolen (or steal, or involuntary wait) time, on Linux, is the time that the 
CPU had runnable threads, but the Xen hypervisor chose to run something else 
instead. KVM hosts, as of this release, do not update these counters.  Stolen 
CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’.


BYCPU_CPU_STOLEN_UTIL_CUM
----------------------------------
The average percentage of time that was stolen from this CPU over the 
cumulative collection time.  Stolen (or steal, or involuntary wait) time, on 
Linux, is the time that the CPU had runnable threads, but the Xen hypervisor 
chose to run something else instead. KVM hosts, as of this release, do not 
update these counters.  Stolen CPU time is shown as ‘%steal’ in ‘sar’ and 
‘st’ in ‘vmstat’.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYCPU_CPU_SYSCALL_TIME
----------------------------------
The time, in seconds, that this CPU was running in system mode (not including 
interrupt, context switch, trap or vfault CPU) during the last interval.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYSCALL_TIME_CUM
----------------------------------
The time, in seconds, that this CPU was running in system mode (not including 
interrupt, context switch, trap or vfault CPU) over the cumulative collection 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYSCALL_UTIL
----------------------------------
The percentage of time that this CPU was running in system mode (not 
including interrupt, context switch, trap or vfault CPU) during the interval.  
On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYSCALL_UTIL_CUM
----------------------------------
The average percentage of time that this CPU was running in system mode (not 
including interrupt, context switch, trap or vfault CPU) over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYS_MODE_TIME
----------------------------------
The time, in seconds, that this CPU (or logical processor) was in system mode 
during the interval.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.  On platforms other than 
HPUX, If the ignore_mt flag is set(true) in parm file, this metric will 
report values normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYS_MODE_TIME_CUM
----------------------------------
The time, in seconds, that this CPU (or logical processor) was in system mode 
over the cumulative collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYS_MODE_UTIL
----------------------------------
The percentage of time that this CPU (or logical processor) was in system 
mode during the interval.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.  On platforms other than 
HPUX, If the ignore_mt flag is set(true) in parm file, this metric will 
report values normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_SYS_MODE_UTIL_CUM
----------------------------------
The percentage of time that this CPU (or logical processor) was in system 
mode over the cumulative collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_TOTAL_TIME
----------------------------------
The total time, in seconds, that this CPU (or logical processor) was not idle 
during the interval.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_TOTAL_TIME_CUM
----------------------------------
The total time, in seconds, that this CPU (or logical processor) was not idle 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_TOTAL_UTIL
----------------------------------
The percentage of time that this CPU (or logical processor) was not idle 
during the interval.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_TOTAL_UTIL_CUM
----------------------------------
The average percentage of time that this CPU (or logical processor) was not 
idle over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_TYPE
----------------------------------
The type of processor in the current slot.
 The Linux kernel currently doesn’t provide any metadata information for 
disabled CPUs. This means that there is no way to find out types, speeds, as 
well as hardware IDs or any other information that is used to determine the 
number of cores, the number of threads, the HyperThreading state, etc...  If 
the agent (or Glance) is started while some of the CPUs are disabled, some of 
these metrics will be “na”, some will be based on what is visible at startup 
time. All information will be updated if/when additional CPUs are enabled and 
information about them becomes available. The configuration counts will 
remain at the highest discovered level (i.e. if CPUs are then disabled, the 
maximum number of CPUs/cores/etc... will remain at the highest observed 
level). It is recommended that the agent be started with all CPUs enabled.


BYCPU_CPU_USER_MODE_TIME
----------------------------------
The time, in seconds, during the interval that this CPU (or logical 
processor) was in user mode.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_USER_MODE_TIME_CUM
----------------------------------
The time, in seconds, that this CPU (or logical processor) was in user mode 
over the cumulative collection time.  User CPU is the time spent in user mode 
at a normal priority, at real-time priority (on HP-UX, AIX, and Windows 
systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_USER_MODE_UTIL
----------------------------------
The percentage of time that this CPU (or logical processor) was in user mode 
during the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_CPU_USER_MODE_UTIL_CUM
----------------------------------
The average percentage of time that this CPU (or logical processor) was in 
user mode over the cumulative collection time.  User CPU is the time spent in 
user mode at a normal priority, at real-time priority (on HP-UX, AIX, and 
Windows systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



BYCPU_ID
----------------------------------
The ID number of this CPU.  On some Unix systems, such as SUN, CPUs are not 
sequentially numbered.


BYCPU_INTERRUPT
----------------------------------
The number of device interrupts for this CPU during the interval.
On HP-UX, a value of “na” is displayed on a system with multiple CPUs.


BYCPU_INTERRUPT_RATE
----------------------------------
The average number of device interrupts per second for this CPU during the 
interval.
On HP-UX, a value of “na” is displayed on a system with multiple CPUs.


BYCPU_STATE
----------------------------------
A text string indicating the current state of a processor.
On HP-UX, this is either “Enabled”, “Disabled” or “Unknown”.  On AIX, this is 
either “Idle/Offline” or “Online”.  On all other systems, this is either 
“Offline”, “Online” or “Unknown”.


BYDSK_AVG_REQUEST_QUEUE
----------------------------------
The average number of IO requests that were in the wait and service queues 
for this disk device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For example, if 4 intervals have passed with average queue lengths of 0, 2, 
0, and 6, then the average number of IO requests over all intervals would be 
2.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_AVG_SERVICE_TIME
----------------------------------
The average time, in milliseconds, that this disk device spent processing 
each disk request during the interval.  For example, a value of 5.14 would 
indicate that disk requests during the last interval took on average slightly 
longer than five one-thousandths of a second to complete for this device.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.
This is a measure of the speed of the disk, because slower disk devices 
typically show a larger average service time.  Average service time is also 
dependent on factors such as the distribution of I/O requests over the 
interval and their locality.  It can also be influenced by disk driver and 
controller features such as I/O merging and command queueing.  Note that this 
service time is measured from the perspective of the kernel, not the disk 
device itself.  For example, if a disk device can find the requested data in 
its cache, the average service time could be quicker than the speed of the 
physical disk hardware.
This metric can be used to help determine which disk devices are taking more 
time than usual to process requests.


BYDSK_AVG_WAIT_TIME
----------------------------------



BYDSK_BUSY_TIME
----------------------------------
The time, in seconds, that this disk device was busy transferring data during 
the interval.
On HP-UX, this is the time, in seconds, during the interval that the disk 
device had IO in progress from the point of view of the Operating System.  In 
other words, the time, in seconds, the disk was busy servicing requests for 
this device.


BYDSK_DEVNAME
----------------------------------
The name of this disk device.
On HP-UX, the name identifying the specific disk spindle is the hardware path 
which specifies the address of the hardware components leading to the disk 
device.
On SUN, these names are the same disk names displayed by “iostat”.
On AIX, this is the path name string of this disk device.  This is the fsname 
parameter in the mount(1M) command.  If more than one file system is 
contained on a device (that is, the device is partitioned), this is indicated 
by an asterisk (“*”) at the end of the path name.
On OSF1, this is the path name string of this disk device.  This is the file-
system parameter in the mount(1M) command.
On Windows, this is the unit number of this disk device.


BYDSK_DEVNO
----------------------------------
Major / Minor number of the device.


BYDSK_DIRNAME
----------------------------------
The name of the file system directory mounted on this disk device.  If more 
than one file system is mounted on this device, “Multiple FS” is seen.


BYDSK_ID
----------------------------------
The ID of the current disk device.


BYDSK_INTERVAL
----------------------------------
The amount of time in the interval.


BYDSK_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_PHYS_BYTE
----------------------------------
The number of KBs of physical IOs transferred to or from this disk device 
during the interval.
On Unix systems, all types of physical disk IOs are counted, including file 
system, virtual memory, and raw IO.


BYDSK_PHYS_BYTE_RATE
----------------------------------
The average KBs per second transferred to or from this disk device during the 
interval.
On Unix systems, all types of physical disk IOs are counted, including file 
system, virtual memory, and raw IO.


BYDSK_PHYS_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of physical reads and writes to or from 
this disk device over the cumulative collection time.
On Unix systems, this includes all types of physical disk IOs including file 
system, virtual memory, and raw IOs.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_PHYS_IO
----------------------------------
The number of physical IOs for this disk device during the interval.
On Unix systems, all types of physical disk IOs are counted, including file 
system, virtual memory, and raw reads.


BYDSK_PHYS_IO_RATE
----------------------------------
The average number of physical IO requests per second for this disk device 
during the interval.
On Unix systems, all types of physical disk IOs are counted, including file 
system IO, virtual memory and raw IO.


BYDSK_PHYS_IO_RATE_CUM
----------------------------------
The average number of physical reads and writes per second for this disk 
device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_PHYS_READ
----------------------------------
The number of physical reads for this disk device during the interval.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw reads.
On AIX, this is an estimated value based on the ratio of read bytes to total 
bytes transferred.  The actual number of reads is not tracked by the kernel.  
This is calculated as

  BYDSK_PHYS_READ =
    BYDSK_PHYS_IO *
    (BYDSK_PHYS_READ_BYTE /
     BYDSK_PHYS_IO_BYTE)



BYDSK_PHYS_READ_BYTE
----------------------------------
The KBs transferred from this disk device during the interval.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw IO.


BYDSK_PHYS_READ_BYTE_RATE
----------------------------------
The average KBs per second transferred from this disk device during the 
interval.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw IO.


BYDSK_PHYS_READ_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of physical reads from this disk device 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_PHYS_READ_RATE
----------------------------------
The average number of physical reads per second for this disk device during 
the interval.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw reads.
On AIX, this is an estimated value based on the ratio of read bytes to total 
bytes transferred.  The actual number of reads is not tracked by the kernel.  
This is calculated as

  BYDSK_PHYS_READ_RATE =
    BYDSK_PHYS_IO_RATE *
    (BYDSK_PHYS_READ_BYTE /
     BYDSK_PHYS_IO_BYTE)



BYDSK_PHYS_READ_RATE_CUM
----------------------------------
The average number of physical reads per second for this disk device over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_PHYS_WRITE
----------------------------------
The number of physical writes for this disk device during the interval.
On Unix systems, all types of physical disk writes are counted, including 
file system IO, virtual memory IO, and raw writes.
On AIX, this is an estimated value based on the ratio of write bytes to total 
bytes transferred because the actual number of writes is not tracked by the 
kernel.  This is calculated as

  BYDSK_PHYS_WRITE =
    BYDSK_PHYS_IO *
    (BYDSK_PHYS_WRITE_BYTE /
     BYDSK_PHYS_IO_BYTE)



BYDSK_PHYS_WRITE_BYTE
----------------------------------
The KBs transferred to this disk device during the interval.
On Unix systems, all types of physical disk writes are counted, including 
file system, virtual memory, and raw IO.


BYDSK_PHYS_WRITE_BYTE_RATE
----------------------------------
The average KBs per second transferred to this disk device during the 
interval.
On Unix systems, all types of physical disk writes are counted, including 
file system, virtual memory, and raw IO.


BYDSK_PHYS_WRITE_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of physical writes to this disk device 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_PHYS_WRITE_RATE
----------------------------------
The average number of physical writes per second for this disk device during 
the interval.
On Unix systems, all types of physical disk writes are counted, including 
file system IO, virtual memory IO, and raw writes.
On AIX, this is an estimated value based on the ratio of write bytes to total 
bytes transferred.  The actual number of writes is not tracked by the kernel.  
This is calculated as

  BYDSK_PHYS_WRITE_RATE =
    BYDSK_PHYS_IO_RATE *
    (BYDSK_PHYS_WRITE_BYTE /
     BYDSK_PHYS_IO_BYTE)



BYDSK_PHYS_WRITE_RATE_CUM
----------------------------------
The average number of physical writes per second for this disk device over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYDSK_QUEUE_0_UTIL
----------------------------------
The percentage of intervals during which there were no IO requests pending 
for this disk device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For example if 4 intervals have passed (that is, 4 screen updates) and the 
average queue length for these intervals was 0, 1.5, 0, and 3, then the value 
for this metric would be 50% since 50% of the intervals had a zero queue 
length.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_QUEUE_2_UTIL
----------------------------------
The percentage of intervals during which there were 1 or 2 IO requests 
pending for this disk device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For example if 4 intervals have passed (that is, 4 screen updates) and the 
average queue length for these intervals was 0, 1, 0, and 2, then the value 
for this metric would be 50% since 50% of the intervals had a 1-2 queue 
length.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_QUEUE_4_UTIL
----------------------------------
The percentage of intervals during which there were 3 or 4 IO requests 
waiting to use this disk device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For example if 4 intervals have passed (that is, 4 screen updates) and the 
average queue length for these intervals was 0, 3, 0, and 4, then the value 
for this metric would be 50% since 50% of the intervals had a 3-4 queue 
length.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_QUEUE_8_UTIL
----------------------------------
The percentage of intervals during which there were between 5 and 8 IO 
requests pending for this disk device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For example if 4 intervals have passed (that is, 4 screen updates) and the 
average queue length for these intervals was 0, 8, 0, and 5, then the value 
for this metric would be 50% since 50% of the intervals had a 5-8 queue 
length.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_QUEUE_X_UTIL
----------------------------------
The percentage of intervals during which there were more than 8 IO requests 
pending for this disk device over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For example if 4 intervals have passed (that is, 4 screen updates) and the 
average queue length for these intervals was 0, 9, 0, and 10, then the value 
for this metric would be 50% since 50% of the intervals had queue length 
greater than 8.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_REQUEST_QUEUE
----------------------------------
The average number of IO requests that were in the wait queue for this disk 
device during the interval.  These requests are the physical requests (as 
opposed to logical IO requests).
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.


BYDSK_TIME
----------------------------------
The time of day of the interval.


BYDSK_UTIL
----------------------------------
On HP-UX, this is the percentage of the time during the interval that the 
disk device had IO in progress from the point of view of the Operating 
System.  In other words, the utilization or percentage of time busy servicing 
requests for this device.
On the non-HP-UX systems, this is the percentage of the time that this disk 
device was busy transferring data during the interval.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.
This is a measure of the ability of the IO path to meet the transfer demands 
being placed on it.  Slower disk devices may show a higher utilization with 
lower IO rates than faster disk devices such as disk arrays.  A value of 
greater than 50% utilization over time may indicate that this device or its 
IO path is a bottleneck, and the access pattern of the workload, database, or 
files may need reorganizing for better balance of disk IO load.


BYHBA_BYTE_RATE
----------------------------------
The average KBs per second transferred to or from this card during the 
interval.


BYHBA_BYTE_RATE_CUM
----------------------------------
The average KBs per second transferred to or from this card during the 
cumulative collection interval.


BYHBA_CLASS
----------------------------------
The class of the Host Bus Adaptor.


BYHBA_DEVNAME
----------------------------------
The hardware path of the Host Bus Adaptor.


BYHBA_DEVNO
----------------------------------
Major / Minor number of the device.


BYHBA_DRIVER
----------------------------------
Name of driver handling the Host Bus Adaptor.


BYHBA_DUMPED_FRAMES
----------------------------------
Number of dumped Frames for this card during the interval.


BYHBA_DUMPED_FRAMES_RATE
----------------------------------
The rate of dumped frames for this card during the interval.


BYHBA_DUMPED_FRAMES_RATE_CUM
----------------------------------
The average number of dumped frames per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_ERR_FRAMES
----------------------------------
Number of Error Frames for this card during the interval.


BYHBA_ERR_FRAMES_RATE
----------------------------------
The rate of Error frames for this card during the interval.


BYHBA_ERR_FRAMES_RATE_CUM
----------------------------------
The average number of Error frames per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_ID
----------------------------------
The instance number of the Host Bus Adaptor.


BYHBA_INTERVAL
----------------------------------
The amount of time in the interval.


BYHBA_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_INVALID_CRC
----------------------------------
Number of invalid CRC for this card during the interval.


BYHBA_INVALID_CRC_RATE
----------------------------------
The rate of invalid CRC words for this card during the interval.


BYHBA_INVALID_CRC_RATE_CUM
----------------------------------
The average number of invalid CRC words per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_INVALID_TX_WORDS
----------------------------------
Number of invalid TX words for this card during the interval.


BYHBA_INVALID_TX_WORDS_RATE
----------------------------------
The rate of invalid TX words for this card during the interval.


BYHBA_INVALID_TX_WORDS_RATE_CUM
----------------------------------
The average number of invalid TX words per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_IO_FRAMES
----------------------------------
Number of total(Transmitted and received) frames by the HBA in this interval.


BYHBA_IO_FRAMES_RATE
----------------------------------
The average number of total frames per second for this card during the 
interval.


BYHBA_IO_FRAMES_RATE_CUM
----------------------------------
The average number of transmitted and received frames per second for this 
card over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_LINK_FAILURE
----------------------------------
Number of link failures for this card during the interval.


BYHBA_LINK_FAILURE_RATE
----------------------------------
The rate of link failures for this card during the interval.


BYHBA_LINK_FAILURE_RATE_CUM
----------------------------------
The average number of link failures per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_LIP
----------------------------------
Number of Loop Initiation Protocol events that have occoured for this card 
during the interval.


BYHBA_LIP_RATE
----------------------------------
The rate of Loop Initiation Protocol events for this card during the 
interval.


BYHBA_LIP_RATE_CUM
----------------------------------
The average number of Loop Initiation Protocol events per second for this 
card over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_LOSS_OF_SIGNAL
----------------------------------
Number of loss of signals for this card during the interval.


BYHBA_LOSS_OF_SIGNAL_RATE
----------------------------------
The rate of loss of signals for this card during the interval.


BYHBA_LOSS_OF_SIGNAL_RATE_CUM
----------------------------------
The average number of loss of signals per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_LOSS_OF_SYNC
----------------------------------
Number of loss of syncs for this card during the interval.


BYHBA_LOSS_OF_SYNC_RATE
----------------------------------
The rate of loss of syncs for this card during the interval.


BYHBA_LOSS_OF_SYNC_RATE_CUM
----------------------------------
The average number of loss of syncs per second for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_NAME
----------------------------------
The name of the Host Bus Adaptor.


BYHBA_NOS
----------------------------------
Number of Non Operational State events that have occoured for this card 
during the interval.


BYHBA_NOS_RATE
----------------------------------
The rate of Non Operational State events for this card during the interval.


BYHBA_NOS_RATE_CUM
----------------------------------
The average number of Non Operational State events for this card over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_PRIM_SEQ_PROTO_ERR
----------------------------------
Number of primitive sequence protocol errors for this card during the 
interval.


BYHBA_PRIM_SEQ_PROTO_ERR_RATE
----------------------------------
The rate of primitive sequence protocol errors for this card during the 
interval.


BYHBA_PRIM_SEQ_PROTO_ERR_RATE_CUM
----------------------------------
The average number of primitive sequence protocol errors per second for this 
card over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYHBA_READ_BYTE_RATE
----------------------------------
The average KBs per second read from this card during the interval.


BYHBA_READ_BYTE_RATE_CUM
----------------------------------
The average KBs per second read from this card during the cumulative 
collection interval.


BYHBA_RX_FRAMES
----------------------------------
The number of receieved frames for this card during the interval.


BYHBA_RX_FRAMES_RATE
----------------------------------
The rate of receieved frames for this card during the interval.


BYHBA_RX_FRAMES_RATE_CUM
----------------------------------
The average number of received frames per second for this card over the 
cumulative collection time.


BYHBA_STATE
----------------------------------
The state of the Host Bus Adaptor(“Active”/”Closed”).


BYHBA_TIME
----------------------------------
The time of day of the interval.


BYHBA_TX_FRAMES
----------------------------------
The number of transmitted frames for this card during the interval.


BYHBA_TX_FRAMES_RATE
----------------------------------
The rate of transmitted frames for this card during the interval.


BYHBA_TX_FRAMES_RATE_CUM
----------------------------------
The average number of transmitted frames per second for this card over the 
cumulative collection time.


BYHBA_TYPE
----------------------------------
The type of device. “HBA” for HBA card and “TAPE” for tape drives.


BYHBA_WRITE_BYTE_RATE
----------------------------------
The average KBs per second written to this card during the interval.


BYHBA_WRITE_BYTE_RATE_CUM
----------------------------------
The average KBs per second written to this card during the interval.


BYNETIF_COLLISION
----------------------------------
The number of physical collisions that occurred on the network interface 
during the interval.  A rising rate of collisions versus outbound packets is 
an indication that the network is becoming increasingly congested.  This 
metric does not currently include deferred packets.
This data is not collected for non-broadcasting devices, such as loopback 
(lo), and is always zero.
For HP-UX, this will be the same as the sum of the “Single Collision Frames”, 
“Multiple Collision Frames”, “Late Collisions”, and “Excessive Collisions” 
values from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  As of the HP-UX 11.0 
release and beyond, “netstat -i” shows network activity on the logical level 
(IP) only.
For most other Unix systems, this is the same as the sum of the “Coll” column 
from the “netstat -i” command (“collisions” from the “netstat -i -e” command 
on Linux) for a network device.  See also netstat(1).
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.


BYNETIF_COLLISION_1_MIN_RATE
----------------------------------
The number of physical collisions per minute on the network interface during 
the interval.  A rising rate of collisions versus outbound packets is an 
indication that the network is becoming increasingly congested.  This metric 
does not currently include deferred packets.
This data is not collected for non-broadcasting devices, such as loopback 
(lo), and is always zero.
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_COLLISION_RATE
----------------------------------
The number of physical collisions per second on the network interface during 
the interval.  A rising rate of collisions versus outbound packets is an 
indication that the network is becoming increasingly congested.  This metric 
does not currently include deferred packets.
This data is not collected for non-broadcasting devices, such as loopback 
(lo), and is always zero.
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.


BYNETIF_COLLISION_RATE_CUM
----------------------------------
The average number of physical collisions per second on the network interface 
over the cumulative collection time.  A rising rate of collisions versus 
outbound packets is an indication that the network is becoming increasingly 
congested.  This metric does not currently include deferred packets.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
This data is not collected for non-broadcasting devices, such as loopback 
(lo), and is always zero.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_ERROR
----------------------------------
The number of physical errors that occurred on the network interface during 
the interval.  An increasing number of errors may indicate a hardware problem 
in the network.
On Unix systems, this data is not available for loop-back (lo) devices and is 
always zero.
For HP-UX, this will be the same as the sum of the “Inbound Errors” and 
“Outbound Errors” values from the output of the “lanadmin” utility for the 
network interface.  Remember that “lanadmin” reports cumulative counts.  As 
of the HP-UX 11.0 release and beyond, “netstat -i” shows network activity on 
the logical level (IP) only.
For all other Unix systems, this is the same as the sum of “Ierrs” (RX-ERR on 
Linux) and “Oerrs” (TX-ERR on Linux) from the “netstat -i” command for a 
network device.  See also netstat(1).
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.


BYNETIF_ERROR_1_MIN_RATE
----------------------------------
The number of physical errors per minute on the network interface during the 
interval.
On Unix systems, this data is not available for loop-back (lo) devices and is 
always zero.
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_ERROR_RATE
----------------------------------
The number of physical errors per second on the network interface during the 
interval.
On Unix systems, this data is not available for loop-back (lo) devices and is 
always zero.
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.


BYNETIF_ERROR_RATE_CUM
----------------------------------
The average number of physical errors per second on the network interface 
over the cumulative collection time.
On Unix systems, this data is not available for loop-back (lo) devices and is 
always zero.
If BYNETIF_NET_TYPE is “ESXVLan”, then this metric will be N/A.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_ID
----------------------------------
The ID number of the network interface.


BYNETIF_IN_BYTE
----------------------------------
The number of KBs received from the network via this interface during the 
interval.  Only the bytes in packets that carry data are included in this 
rate.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_IN_BYTE_RATE
----------------------------------
The number of KBs per second received from the network via this interface 
during the interval.  Only the bytes in packets that carry data are included 
in this rate.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_IN_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second received from the network via this 
interface over the cumulative collection time.  Only the bytes in packets 
that carry data are included in this rate.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_IN_PACKET
----------------------------------
The number of successful physical packets received through the network 
interface during the interval.  Successful packets are those that have been 
processed without errors or collisions.
For HP-UX, this will be the same as the sum of the “Inbound Unicast Packets” 
and “Inbound Non-Unicast Packets” values from the output of the “lanadmin” 
utility for the network interface.  Remember that “lanadmin” reports 
cumulative counts.  As of the HP-UX 11.0 release and beyond, “netstat -i” 
shows network activity on the logical level (IP) only.
For all other Unix systems, this is the same as the sum of the “Ipkts” column 
(RX-OK on Linux) from the “netstat -i” command for a network device.  See 
also netstat(1).
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_IN_PACKET_RATE
----------------------------------
The number of successful physical packets per second received through the 
network interface during the interval.  Successful packets are those that 
have been processed without errors or collisions.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_IN_PACKET_RATE_CUM
----------------------------------
The average number of physical packets per second received through the 
network interface over the cumulative collection time.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_MAC_ADDR
----------------------------------
The mac address of the network interface.


BYNETIF_NAME
----------------------------------
The name of the network interface.
For HP-UX 11.0 and beyond, these are the same names that appear in the 
“Description” field of the “lanadmin” command output.
On all other Unix systems, these are the same names that appear in the “Name” 
column of the “netstat -i” command.
Some examples of device names are:

  lo  - loop-back driver
  ln  - Standard Ethernet driver
  en  - Standard Ethernet driver
  le  - Lance Ethernet driver
  ie  - Intel Ethernet driver
  tr  - Token-Ring driver
  et  - Ether Twist driver
  bf  - fiber optic driver
All of the device names will have the unit number appended to the name.  For 
example, a loop-back device in unit 0 will be “lo0”.
On vMA for Lan cards which are of type ESXVLan, this metric contains the 
vmnic(number) as first half and the second half is the ESX host name.


BYNETIF_NET_SPEED
----------------------------------
The speed of this interface.  This is the bandwidth in Mega bits/sec.  For 
Loopback interface, this metric returns “na”.  Some AIX systems report a 
speed that is lower than the measured throughput and this can result in 
BYNETIF_UTIL and GBL_NET_UTIL_PEAK showing more than 100% utilization.
On Linux, root permission is required to obtain network interface bandwidth 
so values will be n/a when running in non-root mode. Also, maximum bandwidth 
for virtual interfaces (vnetN) may be reported wrongly on KVM or Xen server 
so, similarly to AIX, utilization may exceed 100%.


BYNETIF_NET_TYPE
----------------------------------
The type of network device the interface communicates through.

Lan     - local area network card
Loop    - software loopback
          interface (not tied to a
          hardware device)
Loop6   - software loopback
          interface IPv6 (not tied
          to a hardware device)
Serial  - serial modem port
Vlan    - virtual lan
Wan     - wide area network card
Tunnel  - tunnel interface
Apa     - HP LinkAggregate Interface (APA)
Other   - hardware network interface
          type is unknown.
ESXVLan - The card type belongs to network cards of ESX hosts which are
            monitored on vMA.



BYNETIF_OUT_BYTE
----------------------------------
The number of KBs sent to the network via this interface during the interval.  
Only the bytes in packets that carry data are included in this rate.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_OUT_BYTE_RATE
----------------------------------
The number of KBs per second sent to the network via this interface during 
the interval.  Only the bytes in packets that carry data are included in this 
rate.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_OUT_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second sent to the network via this interface 
over the cumulative collection time.  Only the bytes in packets that carry 
data are included in this rate.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_OUT_PACKET
----------------------------------
The number of successful physical packets sent through the network interface 
during the interval.  Successful packets are those that have been processed 
without errors or collisions.
For HP-UX, this will be the same as the sum of the “Outbound Unicast Packets” 
and “Outbound Non-Unicast Packets” values from the output of the “lanadmin” 
utility for the network interface.  Remember that “lanadmin” reports 
cumulative counts.  As of the HP-UX 11.0 release and beyond, “netstat -i” 
shows network activity on the logical level (IP) only.
For all other Unix systems, this is the same as the sum of the “Opkts” column 
(TX-OK on Linux) from the “netstat -i” command for a network device.  See 
also netstat(1).
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_OUT_PACKET_RATE
----------------------------------
The number of successful physical packets per second sent through the network 
interface during the interval.  Successful packets are those that have been 
processed without errors or collisions.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_OUT_PACKET_RATE_CUM
----------------------------------
The average number of successful physical packets per second sent through the 
network interface over the cumulative collection time.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_PACKET_RATE
----------------------------------
The number of successful physical packets per second sent and received 
through the network interface during the interval.  Successful packets are 
those that have been processed without errors or collisions.
 If BYNETIF_NET_TYPE is “ESXVLan”, then this metric shows the values for the 
Lan card in the host.
 Physical statistics are packets recorded by the network drivers.  These 
numbers most likely will not be the same as the logical statistics.  The 
values returned for the loopback interface will show “na” for the physical 
statistics since there is no network driver activity.
Logical statistics are packets seen only by the Interface Protocol (IP) layer 
of the networking subsystem.  Not all packets seen by IP will go out and come 
in through a network driver.  An example is the loopback interface 
(127.0.0.1).  Pings or other network generating commands (ftp, rlogin, and so 
forth) to 127.0.0.1 will not change physical driver statistics.  Pings to IP 
addresses on remote systems will change physical driver statistics.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


BYNETIF_UTIL
----------------------------------
The percentage of bandwidth used with respect to the total available 
bandwidth on a given network interface at the end of the interval.
On vMA this value will be N/A for those Lan cards which are of type ESXVLan.
 Some AIX systems report a speed that is lower than the measured throughput 
and this can result in BYNETIF_UTIL and GBL_NET_UTIL_PEAK showing more than 
100% utilization.
On Linux, root permission is required to obtain network interface bandwidth 
so values will be n/a when running in non-root mode. Also, maximum bandwidth 
for virtual interfaces (vnetN) may be reported wrongly on KVM or Xen server 
so, similarly to AIX, utilization may exceed 100%.


BYOP_CLIENT_COUNT
----------------------------------
The number of current NFS operations that the local machine has processed as 
a NFS client during the interval.
A host on the network can act both as a client, or as a server at the same 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYOP_CLIENT_COUNT_CUM
----------------------------------
The number of current NFS operations that the local machine has processed as 
a NFS client over the cumulative collection time.
A host on the network can act both as a client, or as a server at the same 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYOP_INTERVAL
----------------------------------
The amount of time in the interval.


BYOP_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYOP_NAME
----------------------------------
String mnemonic for the NFS operation.  One of the following:

For NFS Version 2

Name        Operation/Action
------------------------------------
getattr     Return the current
            attributes of a file.
setattr     Set the attributes of a
            file and returns the new
            attributes.
lookup      Return the attributes of
            a file.
readlink    Return the string in the
            symbolic link of a file.
read        Return data from a file.
write       Put data into a file.
create      Create a file.
remove      Remove a file.
rename      Give a file a new name.
link        Create a hard link to a
            file.
symlink     Create a symbolic link
            to a file.
mkdir       Create a directory.
rmdir       Remove a directory.
readdir     Read a directory entry.
statfs      Return mounted file
            system information.
null        Verify NFS service
            connections and timing.
            On HP-UX, no actual work
            done.
writecache  Flush the server write
            cache if a special write
            cache exists.  Most
            systems use the file
            buffer cache and not a
            special server cache.
            Not used on HP-UX.
root        Find root file system
            handle (probably
            obsolete).
            Not used on HP-UX.

For NFS Version 3

Name        Operation/Action
------------------------------------
getattr     Return the current
            attributes of a file.
setattr     Set the attributes of a
            file and returns the new
            attributes.
lookup      Return the attributes of
            a file.
access      Check access permissions
            of a user.
readlink    Return the string in the
            symbolic link of a file.
read        Return data from a file.
write       Put data into a file.
create      Create a file.
mkdir       Make a directory.
symlink     Create a symbolic link
            to a file.
mknod       Create a special device.
remove      Remove a file.
rmdir       Remove a directory.
rename      Give a file a new name.
link        Create a hard link to a
            file.
readdir     Read a directory entry.
readdirplus Extended read of a
            directory entry.
fsstat      Get dynamic file
            system information.
fsinfo      Get static file
            system information.
pathconf    Retrieve POSIX
            information.
commit      Commit cached data on
            server to stable
            storage.
null        Verify NFS services.
            No actual work done.



BYOP_SERVER_COUNT
----------------------------------
The number of current NFS operations that the local machine has processed as 
a NFS server during the interval.
A host on the network can act both as a client, or as a server at the same 
time.


BYOP_SERVER_COUNT_CUM
----------------------------------
The number of current NFS operations that the local machine has processed as 
a NFS server over the cumulative collection time.
A host on the network can act both as a client, or as a server at the same 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


BYSWP_SWAP_PRI
----------------------------------
The priority of this swap device.  This value is set by either the swapon(1M) 
command, or by the “pri=“ field in /etc/fstab.
On HP-UX, swap space is used by the lower value priorities first.  Since 
device swap is faster than file system swap, it is advisable to have lower 
values for device swap.  The legal values for priority range from 0 to 10.
On HP-UX, the “memory” swap area has no priority and will be shown as -1.  
This indicates that using memory as a swap area is only done after all other 
swap resources have been exhausted.  This is true in extreme cases of memory 
pressure forcing the kernel to swap the entire process to disk.  In cases of 
process deactivation, the memory pseudo swap actually has the highest 
priority - deactivated pages are not moved - they are simply marked as 
deactivated and the space they occupy is considered pseudo swap.
On Linux, swap space is used by the higher value priorities first.  The legal 
values for priority range from 0 to 32767. The system assigns negative 
priority values if no priority is specified during the creation of swap area. 
See swapon(8) for details.


BYSWP_SWAP_SPACE_AVAIL
----------------------------------
The capacity (in MB) for swapping in this swap area.
On HP-UX, for “device” type swap, this value is constant.  However, for 
“filesys” swap this value grows as needed.  File system swap grows in units 
of “SWCHUNKS” x DEV_BSIZE bytes, which is typically 2MB.  This metric is 
similar to the “AVAIL” parameters returned from /usr/sbin/swapinfo.  For 
“memory” type swap, this value also grows as needed or as possible, given 
that any memory reserved for swap cannot be used for normal virtual memory.  
Note that this is potential swap space.  Since swap is allocated in fixed 
(SWCHUNK) sizes, not all of this space may actually be usable.  For example, 
on a 61 MB disk using 2 MB swap size allocations, 1 MB remains unusable and 
is considered wasted space.
On SUN, this is the same as (blocks * .5)/1024, reported by the “swap -l” 
command.
On AIX, this metric is set to “na” for inactive swap devices.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


BYSWP_SWAP_SPACE_NAME
----------------------------------
On Unix systems, this is the name of the device file or file system where the 
swap space is located.
On HP-UX, part of the system’s physical memory may be allocated as a pseudo-
swap device.  It is enabled by setting the “SWAPMEM_ON” kernel parameter to 
1.
On SunOS 5.X, part of the system’s physical memory may be allocated as a 
pseudo-swap device.  Also note, “/tmp” is usually configured as a memory 
based file system and is not used for swap space.  Therefore, it will not be 
listed with the swap devices.  This is noted because “df” uses the label 
“swap” for the “/tmp” file system which may be confusing.  See tmpfs(7).


BYSWP_SWAP_SPACE_USED
----------------------------------
The amount of swap space (in MB) used in this area.
On HP-UX, this value is similar to the “USED” column returned by the 
/usr/sbin/swapinfo command.
On SUN, “Used” indicates amount written to disk (or locked in memory), rather 
than reserved.  Swap space is reserved (by decrementing a counter) when 
virtual memory for a program is created.  This is the same as (blocks - free) 
* .5/1024, reported by the “swap -l” command.
 On SUN, global swap space is tracked through the operating system.  Device 
swap space is tracked through the devices.  For this reason, the amount of 
swap space used may differ between the global and by-device metrics.  
Sometimes pages that are marked to be swapped to disk by the operating system 
are never swapped.  The operating system records this as used swap space, but 
the devices do not, since no physical IOs occur.  (Metrics with the prefix 
“GBL” are global and metrics with the prefix “BYSWP” are by device.)
On AIX, this metric is set to “na” for inactive swap devices.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


BYSWP_SWAP_TYPE
----------------------------------
The type of swap space allocated on the system.
On HP-UX and SUN, types of swap space are device, file system (“filesys”), or 
memory.  “Device” swap is accessed directly without going through the file 
system, and is therefore faster than “filesys” swap.  “Filesys” swap can be 
to a local or NFS mounted swap file.  “Memory” swap is space in the system’s 
physical memory reserved for pseudo-swap for running processes.  Using 
pseudo-swap means the pages are simply locked in memory rather than copied to 
a swap area.
On SUN, note that “/tmp” is usually configured as a memory based file system 
and is not used for swap space.  Therefore, it will not be listed with the 
swap devices, and “swap” or “tmpfs” will not be swap types.  This is noted 
because “df” uses the label “swap” for the “/tmp” file system which may be 
confusing.  See tmpfs(7).
On AIX, “Device” swap is accessed directly without going through the file 
system.  For “Device” swap, the device is specially allocated for swapping 
purpose only.  The device can be logical volume, “lv” or remote file system, 
“remote fs”. The swap is often referred as paging to paging space.


FS_BLOCK_SIZE
----------------------------------
The maximum block size of this file system, in bytes.
A value of “na” may be displayed if the file system is not mounted.  If the 
product is restarted, these unmounted file systems are not displayed until 
remounted.


FS_DEVNAME
----------------------------------
On Unix systems, this is the path name string of the current device.
On Windows, this is the disk drive string of the current device.
On HP-UX, this is the “fsname” parameter in the mount(1M) command.  For NFS 
devices, this includes the name of the node exporting the file system.  It is 
possible that a process may mount a device using the mount(2) system call.  
This call does not update the “/etc/mnttab” and its name is blank.  This 
situation is rare, and should be corrected by syncer(1M).  Note that once a 
device is mounted, its entry is displayed, even after the device is 
unmounted, until the midaemon process terminates.
On SUN, this is the path name string of the current device, or “tmpfs” for 
memory based file systems.  See tmpfs(7).


FS_DEVNO
----------------------------------
On Unix systems, this is the major and minor number of the file system.
On Windows, this is the unit number of the disk device on which the logical 
disk resides.
The scope collector logs the value of this metric in decimal format.


FS_DIRNAME
----------------------------------
On Unix systems, this is the path name of the mount point of the file system.
On Windows, this is the drive letter associated with the selected disk 
partition.
On HP-UX, this is the path name of the mount point of the file system if the 
logical volume has a mounted file system.  This is the directory parameter of 
the mount(1M) command for most entries.  Exceptions are:

* For lvm swap areas, this field
  contains “lvm swap device”.
* For logical volumes with no
  mounted file systems, this field
  contains “Raw Logical Volume”
  (relevant only to Perf Agent).
On HP-UX, the file names are in the same order as shown in the 
“/usr/sbin/mount -p” command.  File systems are not displayed until they 
exhibit IO activity once the midaemon has been started.  Also, once a device 
is displayed, it continues to be displayed (even after the device is 
unmounted) until the midaemon process terminates.
On SUN, only “UFS”, “HSFS” and “TMPFS” file systems are listed.  See 
mount(1M) and mnttab(4).  “TMPFS” file systems are memory based filesystems 
and are listed here for convenience.  See tmpfs(7).
On AIX, see mount(1M) and filesystems(4).  On OSF1, see mount(2).


FS_FRAG_SIZE
----------------------------------
The fundamental file system block size, in bytes.
A value of “na” may be displayed if the file system is not mounted.  If the 
product is restarted, these unmounted file systems are not displayed until 
remounted.
On Windows, this is the same as FS_BLOCK_SIZE metric.


FS_INODE_UTIL
----------------------------------
Percentage of this file system’s inodes in use during the interval.
A value of “na” may be displayed if the file system is not mounted.  If the 
product is restarted, these unmounted file systems are not displayed until 
remounted.


FS_IS_LVM
----------------------------------
Returns true (1) if this file system is a logical volume or 0 if a hard-
partitioned file system.


FS_MAX_INODES
----------------------------------
Number of configured file system inodes.
A value of “na” may be displayed if the file system is not mounted.  If the 
product is restarted, these unmounted file systems are not displayed until 
remounted.


FS_MAX_SIZE
----------------------------------
Maximum number that this file system could obtain if full, in MB.
Note that this is the user space capacity - it is the file system space 
accessible to non root users.  On most Unix systems, the df command shows the 
total file system capacity which includes the extra file system space 
accessible to root users only.
The equivalent fields to look at are “used” and “avail”.  For the target file 
system, to calculate the maximum size in MB, use

  FS Max Size = (used + avail)/1024
A value of “na” may be displayed if the file system is not mounted.  If the 
product is restarted, these unmounted file systems are not displayed until 
remounted.
On HP-UX, this metric is updated at 4 minute intervals to minimize collection 
overhead.


FS_PHYS_IO_RATE
----------------------------------
The number of physical IOs per second directed to this file system during the 
interval.


FS_PHYS_IO_RATE_CUM
----------------------------------
The average number of physical IOs per second directed to this file system 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


FS_PHYS_READ_BYTE_RATE
----------------------------------
The number of physical KBs per second read from this file system during the 
interval.


FS_PHYS_READ_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of physical reads from this file system 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


FS_PHYS_READ_RATE
----------------------------------
The number of physical reads per second directed to this file system during 
the interval.
On Unix systems, physical reads are generated by user file access, virtual 
memory access (paging), file system management, or raw device access.


FS_PHYS_READ_RATE_CUM
----------------------------------
The average number of physical reads per second directed to this file system 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


FS_PHYS_WRITE_BYTE_RATE
----------------------------------
The number of physical KBs per second written to this file system during the 
interval.


FS_PHYS_WRITE_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of physical writes to this file system 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


FS_PHYS_WRITE_RATE
----------------------------------
The number of physical writes per second directed to this file system during 
the interval.


FS_PHYS_WRITE_RATE_CUM
----------------------------------
The average number of physical writes per second directed to this file system 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


FS_SPACE_RESERVED
----------------------------------
The amount of file system space in MBs reserved for superuser allocation.
On AIX, this metric is typically zero for local filesystems because by 
default AIX does not reserve any file system space for the superuser.


FS_SPACE_USED
----------------------------------
The amount of file system space in MBs that is being used.


FS_SPACE_UTIL
----------------------------------
Percentage of the file system space in use during the interval.
Note that this is the user space capacity - it is the file system space 
accessible to non root users.  On most Unix systems, the df command shows the 
total file system capacity which includes the extra file system space 
accessible to root users only.
A value of “na” may be displayed if the file system is not mounted.  If the 
product is restarted, these unmounted file systems are not displayed until 
remounted.
On HP-UX, this metric is updated at 4 minute intervals to minimize collection 
overhead.


FS_TYPE
----------------------------------
A string indicating the file system type.  On Unix systems, some of the 
possible types are:

  hfs   - user file system
  ufs   - user file system
  ext2  - user file system
  cdfs  - CD-ROM file system
  vxfs  - Veritas (vxfs) file system
  nfs   - network file system
  nfs3  - network file system
          Version 3
On Windows, some of the possible types are:

  NTFS  - New Technology File System
  FAT   - 16-bit File Allocation
          Table
  FAT32 - 32-bit File Allocation
          Table
FAT uses a 16-bit file allocation table entry (216 clusters).
FAT32 uses a 32-bit file allocation table entry.  However, Windows 2000 
reserves the first 4 bits of a FAT32 file allocation table entry, which means 
FAT32 has a theoretical maximum of 228 clusters.  NTFS is native file system 
of Windows NT and beyond.


GBL_ACTIVE_CPU
----------------------------------
The number of CPUs online on the system.
For HP-UX and certain versions of Linux, the sar(1M) command allows you to 
check the status of the system CPUs.
For SUN and DEC, the commands psrinfo(1M) and psradm(1M) allow you to check 
or change the status of the system CPUs.
For AIX, the pstat(1) command allows you to check the status of the system 
CPUs.
On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment if RSET is not configured for the System WPAR. If RSET is 
configured for the System WPAR, this metric value will report the number of 
CPUs in the RSET.
 On Solaris non-global zones with Uncapped CPUs, this metric shows data from 
the global zone.


GBL_ACTIVE_CPU_CORE
----------------------------------
This metric provides the total number of active CPU cores on a physical 
system.


GBL_ACTIVE_PROC
----------------------------------
An active process is one that exists and consumes some CPU time.  
GBL_ACTIVE_PROC is the sum of the alive-process-time/interval-time ratios of 
every process that is active (uses any CPU time) during an interval.
The following diagram of a four second interval during which two processes 
exist on the system should be used to understand the above definition. Note 
the difference between active processes, which consume CPU time, and alive 
processes which merely exist on the system.

     ----------- Seconds -----------
       1         2         3      4
Proc
---- ----      ----      ----   ----
A    live      live      live   live

B    live/CPU  live/CPU  live   dead

Process A is alive for the entire four second interval but consumes no CPU.  
A’s contribution to GBL_ALIVE_PROC is 4*1/4. A contributes 0*1/4 to 
GBL_ACTIVE_PROC.  B’s contribution to GBL_ALIVE_PROC is 3*1/4.  B contributes 
2*1/4 to GBL_ACTIVE_PROC.  Thus, for this interval, GBL_ACTIVE_PROC equals 
0.5 and GBL_ALIVE_PROC equals 1.75.
Because a process may be alive but not active, GBL_ACTIVE_PROC will always be 
less than or equal to GBL_ALIVE_PROC.
This metric is a good overall indicator of the workload of the system.  An 
unusually large number of active processes could indicate a CPU bottleneck.
To determine if the CPU is a bottleneck, compare this metric with 
GBL_CPU_TOTAL_UTIL and GBL_RUN_QUEUE.  If GBL_CPU_TOTAL_UTIL is near 100 
percent and GBL_RUN_QUEUE is greater than one, there is a bottleneck.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


GBL_ALIVE_PROC
----------------------------------
An alive process is one that exists on the system.  GBL_ALIVE_PROC is the sum 
of the alive-process-time/interval-time ratios for every process.
The following diagram of a four second interval during which two processes 
exist on the system should be used to understand the above definition. Note 
the difference between active processes, which consume CPU time, and alive 
processes which merely exist on the system.

     ----------- Seconds -----------
       1         2         3      4
Proc
---- ----      ----      ----   ----
A    live      live      live   live

B    live/CPU  live/CPU  live   dead

Process A is alive for the entire four second interval but consumes no CPU.  
A’s contribution to GBL_ALIVE_PROC is 4*1/4. A contributes 0*1/4 to 
GBL_ACTIVE_PROC.  B’s contribution to GBL_ALIVE_PROC is 3*1/4.  B contributes 
2*1/4 to GBL_ACTIVE_PROC.  Thus, for this interval, GBL_ACTIVE_PROC equals 
0.5 and GBL_ALIVE_PROC equals 1.75.
Because a process may be alive but not active, GBL_ACTIVE_PROC will always be 
less than or equal to GBL_ALIVE_PROC.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


GBL_BLANK
----------------------------------
A string of blanks.


GBL_BOOT_TIME
----------------------------------
The date and time when the system was last booted.


GBL_COLLECTION_MODE
----------------------------------
This metric reports whether the data collection is running as “root” (super-
user) or “non-root” (regular user). Running as non-root results in a loss of 
functionality which varies across Unix platforms. Running non-root is not 
available on HP-UX.
The value is always “admin” on Windows.


GBL_COLLECTOR
----------------------------------
ASCII field containing collector name and version.  This will be shown as 
“Nums” followed by the version information.


GBL_COMPLETED_PROC
----------------------------------
The number of processes that terminated during the interval.
 On non HP-UX systems, this metric is derived from sampled process data.  
Since the data for a process is not available after the process has died on 
this operating system, a process whose life is shorter than the sampling 
interval may not be seen when the samples are taken.  Thus this metric may be 
slightly less than the actual value.  Increasing the sampling frequency 
captures a more accurate count, but the overhead of collection may also rise.


GBL_CPU_CLOCK
----------------------------------
The clock speed of the CPUs in MHz if all of the processors have the same 
clock speed.  Otherwise, “na” is shown if the processors have different clock 
speeds. Note that Linux supports dynamic frequency scaling and if it is 
enabled then there can be a change in CPU speed with varying load.


GBL_CPU_CYCLE_ENTL_MAX
----------------------------------
On a recognized VMware ESX guest, where VMware guest SDK is enabled,, this 
value indicates the maximum processor capacity, in MHz, configured for this 
logical system.  The value is -3 if entitlement is ‘Unlimited’ for this 
logical system.
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”.
On a standalone system, the value is the sum of clock speed of individual 
CPUs.


GBL_CPU_CYCLE_ENTL_MIN
----------------------------------
On a recognized VMware ESX guest, where VMware guest SDK is enabled,, this 
value indicates the minimum processor capacity, in MHz, configured for this 
logical system.
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”.
On a standalone system, the value is the sum of clock speed of individual 
CPUs.


GBL_CPU_ENTL_MAX
----------------------------------
In a virtual environment, this metric indicates the maximum number of 
processing units configured for this logical system.
On AIX SPLPAR, this metric is equivalent to “Maximum Capacity” field of 
‘lparstat -i’ command.
On a recognized VMware ESX guest the value is equivalent to 
GBL_CPU_CYCLE_ENTL_MAX represented in CPU units.
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”.
On a standalone system the value is same as GBL_NUM_CPU.


GBL_CPU_ENTL_MIN
----------------------------------
In a virtual environment, this metric indicates the minimum number of 
processing units configured for this Logical system.
On AIX SPLPAR, this metric is equivalent to “Minimum Capacity” field of 
‘lparstat -i’ command.
On a recognized VMware ESX guest, where VMware guest SDK is enabled, the 
value is equivalent to GBL_CPU_CYCLE_ENTL_MIN represented in CPU units.
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”.
On a standalone system the value is same as GBL_NUM_CPU.


GBL_CPU_ENTL_UTIL
----------------------------------
Percentage of entitled processing units (guaranteed processing units 
allocated to this logical system) consumed by the logical system.
On AIX, this metric is calculated as:
   GBL_CPU_ENTL_UTIL = (GBL_CPU_PHYSC / GBL_CPU_ENTL) * 100
On a recognized VMware ESX guest, where VMware guest SDK is enabled, this 
metric is calculated as:
   GBL_CPU_ENTL_UTIL = (GBL_CPU_PHYSC / GBL_CPU_ENTL_MIN) * 100
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”.
On a standalone system, the value is same as GBL_CPU_TOTAL_UTIL.


GBL_CPU_GUEST_TIME
----------------------------------
The time, in seconds, spent by CPUs to service guests during the interval.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.  On a system with multiple CPUs, this metric is normalized.  That is, 
the CPU used over all processors is divided by the number of processors 
online.  This represents the usage of the total processing capacity 
available.


GBL_CPU_GUEST_TIME_CUM
----------------------------------
The time, in seconds, spent by CPUs to service guests over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.  On a system with multiple CPUs, this metric is normalized.  That is, 
the CPU used over all processors is divided by the number of processors 
online.  This represents the usage of the total processing capacity 
available.


GBL_CPU_GUEST_UTIL
----------------------------------
The percentage of time that the CPUs were used to service guests during the 
interval.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.


GBL_CPU_GUEST_UTIL_CUM
----------------------------------
The percentage of time that the CPUs were used to service guests over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Guest time, on Linux KVM hosts, is the time that is spent servicing guests. 
Xen hosts, as of this release, do not update these counters, neither do other 
OSes.  On a system with multiple CPUs, this metric is normalized.  That is, 
the CPU used over all processors is divided by the number of processors 
online.  This represents the usage of the total processing capacity 
available.


GBL_CPU_GUEST_UTIL_HIGH
----------------------------------
The highest percentage of guest CPU time during any one interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_IDLE_TIME
----------------------------------
The time, in seconds, that the CPU was idle during the interval.  This is the 
total idle time, including waiting for I/O (and stolen time on Linux).
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.
On AIX System WPARs, this metric value is calculated against physical cpu 
time.
 On Solaris non-global zones, this metric is N/A.  On platforms other than 
HPUX, If the ignore_mt flag is set(true) in parm file, this metric will 
report values normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_IDLE_TIME_CUM
----------------------------------
The time, in seconds, that the CPU was idle over the cumulative collection 
time.  This is the total idle time, including waiting for I/O (and stolen 
time on Linux).
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_IDLE_UTIL
----------------------------------
The percentage of time that the CPU was idle during the interval.  This is 
the total idle time, including waiting for I/O (and stolen time on Linux).
On Unix systems, this is the same as the sum of the “%idle” and “%wio” fields 
reported by the “sar -u” command.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.
 On Solaris non-global zones, this metric is N/A.  On platforms other than 
HPUX, If the ignore_mt flag is set(true) in parm file, this metric will 
report values normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_IDLE_UTIL_CUM
----------------------------------
The percentage of time that the CPU was idle over the cumulative collection 
time.  This is the total idle time, including waiting for I/O (and stolen 
time on Linux).
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_IDLE_UTIL_HIGH
----------------------------------
The highest percentage of time that the CPU was idle during any one interval 
over the cumulative collection time.  This is the total idle time, including 
waiting for I/O (and stolen time on Linux).
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_INTERRUPT_TIME
----------------------------------
The time, in seconds, that the CPU spent processing interrupts during the 
interval.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On Hyper-V host, this metric is NA.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_INTERRUPT_TIME_CUM
----------------------------------
The time, in seconds, that the CPU spent processing interrupts over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_INTERRUPT_UTIL
----------------------------------
The percentage of time that the CPU spent processing interrupts during the 
interval.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On Hyper-V host, this metric is NA.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_INTERRUPT_UTIL_CUM
----------------------------------
The percentage of time that the CPU spent processing interrupts over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_INTERRUPT_UTIL_HIGH
----------------------------------
The highest percentage of time that the CPU spent processing interrupts 
during any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_MT_ENABLED
----------------------------------
On AIX, this metric indicates if this (Logical) System has SMT enabled or 
not.
Other platforms, this metric shows either HyperThreading(HT) is Enabled or 
Disabled/Not Supported.
On Linux, this state is dynamic: if HyperThreading is enabled but all the 
CPUs have only one logical processor enabled, this metric will report that HT 
is disabled.
 On AIX System WPARs, this metric is NA.
On Windows, this metric will be “na” on Windows Server 2003 Itanium systems.


GBL_CPU_NICE_TIME
----------------------------------
The time, in seconds, that the CPU was in user mode at a nice priority during 
the interval.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_NICE_TIME_CUM
----------------------------------
The time, in seconds, that the CPU was in user mode at a nice priority over 
the cumulative collection time.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_NICE_UTIL
----------------------------------
The percentage of time that the CPU was in user mode at a nice priority 
during the interval.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_NICE_UTIL_CUM
----------------------------------
The percentage of time that the CPU was in user mode at a nice priority over 
the cumulative collection time.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_NICE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the CPU was in 
user mode at a nice priority over the cumulative collection time.
 On HP-UX, the NICE metrics include positive nice value CPU time only.  
Negative nice value CPU is broken out into NNICE (negative nice) metrics.  
Positive nice values range from 20 to 39.  Negative nice values range from 0 
to 19.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_NUM_THREADS
----------------------------------
The number of active CPU threads supported by the CPU architecture.
 The Linux kernel currently doesn’t provide any metadata information for 
disabled CPUs. This means that there is no way to find out types, speeds, as 
well as hardware IDs or any other information that is used to determine the 
number of cores, the number of threads, the HyperThreading state, etc...  If 
the agent (or Glance) is started while some of the CPUs are disabled, some of 
these metrics will be “na”, some will be based on what is visible at startup 
time. All information will be updated if/when additional CPUs are enabled and 
information about them becomes available. The configuration counts will 
remain at the highest discovered level (i.e. if CPUs are then disabled, the 
maximum number of CPUs/cores/etc... will remain at the highest observed 
level). It is recommended that the agent be started with all CPUs enabled.
 On AIX System WPARs, this metric is NA.


GBL_CPU_PHYSC
----------------------------------
The number of physical processors utilized by the logical system.
On an Uncapped logical system (partition), this value will be equal to the 
physical processor capacity used by the logical system during the interval. 
This can be more than the value entitled for a logical system.
On a standalone system the value is calculated based on GBL_CPU_TOTAL_UTIL


GBL_CPU_PHYS_TOTAL_UTIL
----------------------------------
The percentage of time the available physical CPUs were not idle for this 
logical system during the interval.
On AIX, this metric is calculated as :
GBL_CPU_PHYS_TOTAL_UTIL = GBL_CPU_PHYS_USER_MODE_UTIL + 
GBL_CPU_PHYS_SYS_MODE_UTIL ;
GBL_CPU_PHYS_TOTAL_UTIL + GBL_CPU_PHYS_WAIT_UTIL + GBL_CPU_PHYS_IDLE_UTIL = 
100%
On Power5 based systems, traditional sample based calculations cannot be made 
because the dispatch cycle for each of the virtual CPUs is not same. So 
Power5 processor maintains a per-thread register PURR. The thread is 
dispatching instructions or the thread  that last dispatched an instruction 
will be incremented at every processor clock cycle. This makes the value to 
be distributed between the two threads. Power5 processor also maintains two 
more registers, one is timebase - which gets incremented at every tick and 
decrementer - that provided periodic interrupts.
On a Shared LPAR environment, PURR is equal to the time that a virtual 
processor has spent on a physical processor.  Hypervisor maintains a virtual 
timebase which is same as the sum of two PURRs.
On a Capped Shared logical system (partition), the calculations for the 
metric GBL_CPU_PHYS_USER_MODE_UTIL is as follows:
            (delta PURR in user mode/entitlement) * 100 On an Uncapped Shared 
logical system (partition): (delta PURR in user mode/entitlement consumed) * 
100
The calculations for the other utilizations such as 
GBL_CPU_PHYS_USER_MODE_UTIL, GBL_CPU_PHYS_SYS_MODE_UTIL, and 
GBL_CPU_PHYS_WAIT_UTIL are also similar.
On a standalone system, the value will be equivalent to GBL_CPU_TOTAL_UTIL.
On AIX System WPARs, this metric value is calculated against physical cpu 
time.


GBL_CPU_SHARES_PRIO
----------------------------------
The weightage/priority assigned to a Uncapped logical system. This value 
determines the minimum share of unutilized processing units that this logical 
system can utilize.
On AIX SPLPAR this value is dependent on the available processing units in 
the pool and can range from 0 to 255
On recognized VMware ESX guest, this value can range from 1 to 100000
On a standalone system the value will be “na”.


GBL_CPU_STOLEN_TIME
----------------------------------
The time, in seconds, that was stolen from all the CPUs during the interval.
 Stolen (or steal, or involuntary wait) time, on Linux, is the time that the 
CPU had runnable threads, but the Xen hypervisor chose to run something else 
instead. KVM hosts, as of this release, do not update these counters.  Stolen 
CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.


GBL_CPU_STOLEN_TIME_CUM
----------------------------------
The time, in seconds, that was stolen from all the CPUs over the cumulative 
collection time.
 Stolen (or steal, or involuntary wait) time, on Linux, is the time that the 
CPU had runnable threads, but the Xen hypervisor chose to run something else 
instead. KVM hosts, as of this release, do not update these counters.  Stolen 
CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.


GBL_CPU_STOLEN_UTIL
----------------------------------
The percentage of time that was stolen from all CPUs during the interval.
 Stolen (or steal, or involuntary wait) time, on Linux, is the time that the 
CPU had runnable threads, but the Xen hypervisor chose to run something else 
instead. KVM hosts, as of this release, do not update these counters.  Stolen 
CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.


GBL_CPU_STOLEN_UTIL_CUM
----------------------------------
The percentage of time that was stolen from all CPUs over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Stolen (or steal, or involuntary wait) time, on Linux, is the time that the 
CPU had runnable threads, but the Xen hypervisor chose to run something else 
instead. KVM hosts, as of this release, do not update these counters.  Stolen 
CPU time is shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.


GBL_CPU_STOLEN_UTIL_HIGH
----------------------------------
The highest percentage of stolen CPU time during any one interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_SYSCALL_TIME
----------------------------------
The time, in seconds, that the CPU was in system mode (excluding interrupt, 
context switch, trap, or vfault CPU) during the interval.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_SYSCALL_TIME_CUM
----------------------------------
The time, in seconds, that the CPU was in system mode (excluding interrupt, 
context switch, trap, or vfault CPU) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_SYSCALL_UTIL
----------------------------------
The percentage of time that the CPU was in system mode (excluding interrupt, 
context switch, trap, or vfault CPU) during the interval.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_SYSCALL_UTIL_CUM
----------------------------------
The percentage of time that the CPU was in system mode (excluding interrupt, 
context switch, trap, or vfault CPU) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_SYS_MODE_TIME
----------------------------------
The time, in seconds, that the CPU was in system mode during the interval.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

On AIX System WPARs, this metric value is calculated against physical cpu 
time.
On Hyper-V host, this metric indicates the time spent in Hypervisor code.


GBL_CPU_SYS_MODE_TIME_CUM
----------------------------------
The time, in seconds, that the CPU was in system mode over the cumulative 
collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

On AIX System WPARs, this metric value is calculated against physical cpu 
time.


GBL_CPU_SYS_MODE_UTIL
----------------------------------
Percentage of time the CPU was in system mode during the interval.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
This metric is a subset of the GBL_CPU_TOTAL_UTIL percentage.
This is NOT a measure of the amount of time used by system daemon processes, 
since most system daemons spend part of their time in user mode and part in 
system calls, like any other process.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

High system mode CPU percentages are normal for IO intensive applications.  
Abnormally high system mode CPU percentages can indicate that a hardware 
problem is causing a high interrupt rate.  It can also indicate programs that 
are not calling system calls efficiently.  On a logical system, this metric 
indicates the percentage of time the logical processor was in kernel mode 
during this interval.
On Hyper-V host, this metric indicates the percentage of time spent in 
Hypervisor code.


GBL_CPU_SYS_MODE_UTIL_CUM
----------------------------------
The percentage of time that the CPU was in system mode over the cumulative 
collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_SYS_MODE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the CPU was in 
system mode over the cumulative collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_TOTAL_TIME
----------------------------------
The total time, in seconds, that the CPU was not idle in the interval.
This is calculated as

  GBL_CPU_TOTAL_TIME =
    GBL_CPU_USER_MODE_TIME +
    GBL_CPU_SYS_MODE_TIME
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

On AIX System WPARs, this metric value is calculated against physical cpu 
time.


GBL_CPU_TOTAL_TIME_CUM
----------------------------------
The total time that the CPU was not idle over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

On AIX System WPARs, this metric value is calculated against physical cpu 
time.


GBL_CPU_TOTAL_UTIL
----------------------------------
Percentage of time the CPU was not idle during the interval.
This is calculated as

  GBL_CPU_TOTAL_UTIL =
    GBL_CPU_USER_MODE_UTIL +
    GBL_CPU_SYS_MODE_UTIL
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.

  GBL_CPU_TOTAL_UTIL +
   GBL_CPU_IDLE_UTIL = 100%
This metric varies widely on most systems, depending on the workload.  A 
consistently high CPU utilization can indicate a CPU bottleneck, especially 
when other indicators such as GBL_RUN_QUEUE and GBL_ACTIVE_PROC are also 
high.  High CPU utilization can also occur on systems that are bottlenecked 
on memory, because the CPU spends more time paging and swapping.
NOTE: On Windows, this metric may not equal the sum of the APP_CPU_TOTAL_UTIL 
metrics.  Microsoft states that “this is expected behavior” because this 
GBL_CPU_TOTAL_UTIL metric is taken from the performance library Processor 
objects while the APP_CPU_TOTAL_UTIL metrics are taken from the Process 
objects.  Microsoft states that there can be CPU time accounted for in the 
Processor system objects that may not be seen in the Process objects.  On a 
logical system, this metric indicates the logical utilization with respect to 
number of  processors available for the logical system (GBL_NUM_CPU).
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_TOTAL_UTIL_CUM
----------------------------------
The percentage of total CPU time that the processor was not idle over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_TOTAL_UTIL_HIGH
----------------------------------
The highest percentage of total CPU time during any one interval that the 
processor was not idle over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_USER_MODE_TIME
----------------------------------
The time, in seconds, that the CPU was in user mode during the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

On AIX System WPARs, this metric value is calculated against physical cpu 
time.
On Hyper-V host, this metric indicates the time spent in guest code.


GBL_CPU_USER_MODE_TIME_CUM
----------------------------------
The time, in seconds, that the CPU was in user mode over the cumulative 
collection time.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

On AIX System WPARs, this metric value is calculated against physical cpu 
time.


GBL_CPU_USER_MODE_UTIL
----------------------------------
The percentage of time the CPU was in user mode during the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
This metric is a subset of the GBL_CPU_TOTAL_UTIL percentage.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

High user mode CPU percentages are normal for computation-intensive 
applications.  Low values of user CPU utilization compared to relatively high 
values for GBL_CPU_SYS_MODE_UTIL can indicate an application or hardware 
problem.  On a logical system, this metric indicates the percentage of time 
the logical processor was in user mode during this interval.
On Hyper-V host, this metric indicates the percentage of time spent in guest 
code.


GBL_CPU_USER_MODE_UTIL_CUM
----------------------------------
The percentage of time that the CPU was in user mode over the cumulative 
collection time.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_USER_MODE_UTIL_HIGH
----------------------------------
The highest percentage of time during any one interval that the CPU was in 
user mode over the cumulative collection time.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



GBL_CPU_WAIT_TIME
----------------------------------
The time, in seconds, that the CPU was idle and there were processes waiting 
for physical IOs to complete during the interval.
 IO wait time is included in idle time on all systems.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
On AIX System WPARs, this metric value is calculated against physical cpu 
time.
 On Solaris non-global zones, this metric is N/A.  On platforms other than 
HPUX, If the ignore_mt flag is set(true) in parm file, this metric will 
report values normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

 On Linux, wait time includes CPU steal time.


GBL_CPU_WAIT_TIME_CUM
----------------------------------
The total time since the beginning of measurement, in seconds, that the CPU 
was idle and there were processes waiting for physical IOs to complete
 IO wait time is included in idle time on all systems.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

 On Linux, wait time includes CPU steal time.


GBL_CPU_WAIT_UTIL
----------------------------------
The percentage of time during the interval that the CPU was idle and there 
were processes waiting for physical IOs to complete.
 IO wait time is included in idle time on all systems.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On Solaris non-global zones, this metric is N/A.  On platforms other than 
HPUX, If the ignore_mt flag is set(true) in parm file, this metric will 
report values normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

 On Linux, wait time includes CPU steal time.


GBL_CPU_WAIT_UTIL_CUM
----------------------------------
The percentage of time since the beginning of measurement that the CPU was 
idle and there were processes waiting for physical IOs to complete.
 IO wait time is included in idle time on all systems.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

 On Linux, wait time includes CPU steal time.


GBL_CPU_WAIT_UTIL_HIGH
----------------------------------
The highest percentage of CPU wait time during any one interval over the 
cumulative collection time.
 IO wait time is included in idle time on all systems.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a system with multiple CPUs, this metric is normalized.  That is, the CPU 
used over all processors is divided by the number of processors online.  This 
represents the usage of the total processing capacity available.
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.

 On Linux, wait time includes CPU steal time.


GBL_CSWITCH_RATE
----------------------------------
The average number of context switches per second during the interval.
 On HP-UX, this includes context switches that result in the execution of a 
different process and those caused by a process stopping, then resuming, with 
no other process running in the meantime.
On Windows, this includes switches from one thread to another either inside a 
single process or across processes.  A thread switch can be caused either by 
one thread asking another for information or by a thread being preempted by 
another higher priority thread becoming ready to run.
 On Solaris non-global zones with Uncapped CPUs, this metric shows data from 
the global zone.


GBL_CSWITCH_RATE_CUM
----------------------------------
The average number of context switches per second over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, this includes context switches that result in the execution of a 
different process and those caused by a process stopping, then resuming, with 
no other process running in the meantime.


GBL_CSWITCH_RATE_HIGH
----------------------------------
The highest number of context switches per second during any interval over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, this includes context switches that result in the execution of a 
different process and those caused by a process stopping, then resuming, with 
no other process running in the meantime.


GBL_DISK_PHYS_BYTE
----------------------------------
The number of KBs transferred to and from disks during the interval.  The 
bytes for all types of physical IOs are counted.  Only local disks are 
counted in this measurement.  NFS devices are excluded.
It is not directly related to the number of IOs, since IO requests can be of 
differing lengths.
On Unix systems, this includes file system IO, virtual memory IO, and raw IO.
On Windows, all types of physical IOs are counted.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_BYTE_RATE
----------------------------------
The average number of KBs per second at which data was transferred to and 
from disks during the interval.  The bytes for all types physical IOs are 
counted.  Only local disks are counted in this measurement.  NFS devices are 
excluded.
This is a measure of the physical data transfer rate.  It is not directly 
related to the number of IOs, since IO requests can be of differing lengths.
This is an indicator of how much data is being transferred to and from disk  
devices.  Large spikes in this metric can indicate a disk bottleneck.
On Unix systems, all types of physical disk IOs are counted, including file 
system, virtual memory, and raw reads.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_IO
----------------------------------
The number of physical IOs during the interval.  Only local disks are counted 
in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk IOs are counted, including file 
system IO, virtual memory IO and raw IO.
On HP-UX, this is calculated as

  GBL_DISK_PHYS_IO =
    GBL_DISK_FS_IO +
    GBL_DISK_VM_IO +
    GBL_DISK_SYSTEM_IO +
    GBL_DISK_RAW_IO
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_IO_CUM
----------------------------------
The total number of physical IOs over the cumulative collection time.  Only 
local disks are counted in this measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_IO_RATE
----------------------------------
The number of physical IOs per second during the interval.  Only local disks 
are counted in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk IOs are counted, including file 
system IO, virtual memory IO and raw IO.
On HP-UX, this is calculated as

  GBL_DISK_PHYS_IO_RATE =
    GBL_DISK_FS_IO_RATE +
    GBL_DISK_VM_IO_RATE +
    GBL_DISK_SYSTEM_IO_RATE +
    GBL_DISK_RAW_IO_RATE
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_IO_RATE_CUM
----------------------------------
The number of physical IOs per second over the cumulative collection time.  
Only local disks are counted in this measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_READ
----------------------------------
The number of physical reads during the interval.  Only local disks are 
counted in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw reads.
On HP-UX, there are many reasons why there is not a direct correlation 
between the number of logical IOs and physical IOs.  For example, small 
sequential logical reads may be satisfied from the buffer cache, resulting in 
fewer physical IOs than logical IOs.  Conversely, large logical IOs or small 
random IOs may result in more physical than logical IOs.  Logical volume 
mappings, logical disk mirroring, and disk striping also tend to remove any 
correlation.
On HP-UX, this is calculated as

  GBL_DISK_PHYS_READ =
    GBL_DISK_FS_READ +
    GBL_DISK_VM_READ +
    GBL_DISK_SYSTEM_READ +
    GBL_DISK_RAW_READ
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_READ_BYTE
----------------------------------
The number of KBs physically transferred from the disk during the interval.  
Only local disks are counted in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw reads.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_READ_BYTE_CUM
----------------------------------
The number of KBs (or MBs if specified) physically transferred from the disk 
over the cumulative collection time.  Only local disks are counted in this 
measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_READ_BYTE_RATE
----------------------------------
The average number of KBs transferred from the disk per second during the 
interval.  Only local disks are counted in this measurement.  NFS devices are 
excluded.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_READ_CUM
----------------------------------
The total number of physical reads over the cumulative collection time.  Only 
local disks are counted in this measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_READ_PCT
----------------------------------
The percentage of physical reads of total physical IO during the interval.  
Only local disks are counted in this measurement.  NFS devices are excluded.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_READ_PCT_CUM
----------------------------------
The percentage of physical reads of total physical IO over the cumulative 
collection time.  Only local disks are counted in this measurement.  NFS 
devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_READ_RATE
----------------------------------
The number of physical reads per second during the interval.  Only local 
disks are counted in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk reads are counted, including file 
system, virtual memory, and raw reads.
On HP-UX, this is calculated as

  GBL_DISK_PHYS_READ_RATE =
    GBL_DISK_FS_READ_RATE +
    GBL_DISK_VM_READ_RATE +
    GBL_DISK_SYSTEM_READ_RATE +
    GBL_DISK_RAW_READ_RATE
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_READ_RATE_CUM
----------------------------------
The average number of physical reads per second over the cumulative 
collection time.  Only local disks are counted in this measurement.  NFS 
devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_WRITE
----------------------------------
The number of physical writes during the interval.  Only local disks are 
counted in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk writes are counted, including 
file system IO, virtual memory IO, and raw writes.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
On HP-UX, there are many reasons why there is not a direct correlation 
between logical IOs and physical IOs.  For example, small logical writes may 
end up entirely in the buffer cache, and later generate fewer physical IOs 
when written to disk due to the larger IO size.  Or conversely, small logical 
writes may require physical prefetching of the corresponding disk blocks 
before the data is merged and posted to disk.  Logical volume mappings, 
logical disk mirroring, and disk striping also tend to remove any 
correlation.
On HP-UX, this is calculated as

  GBL_DISK_PHYS_WRITE =
    GBL_DISK_FS_WRITE +
    GBL_DISK_VM_WRITE +
    GBL_DISK_SYSTEM_WRITE +
    GBL_DISK_RAW_WRITE
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_WRITE_BYTE
----------------------------------
The number of KBs (or MBs if specified) physically transferred to the disk 
during the interval.  Only local disks are counted in this measurement.  NFS 
devices are excluded.
On Unix systems, all types of physical disk writes are counted, including 
file system IO, virtual memory IO, and raw writes.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_WRITE_BYTE_CUM
----------------------------------
The number of KBs (or MBs if specified) physically transferred to the disk 
over the cumulative collection time.  Only local disks are counted in this 
measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_WRITE_BYTE_RATE
----------------------------------
The average number of KBs transferred to the disk per second during the 
interval.  Only local disks are counted in this measurement.  NFS devices are 
excluded.
On Unix systems, all types of physical disk writes are counted, including 
file system IO, virtual memory IO, and raw writes.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_WRITE_CUM
----------------------------------
The total number of physical writes over the cumulative collection time.  
Only local disks are counted in this measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_WRITE_PCT
----------------------------------
The percentage of physical writes of total physical IO during the interval.  
Only local disks are counted in this measurement.  NFS devices are excluded.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.


GBL_DISK_PHYS_WRITE_PCT_CUM
----------------------------------
The percentage of physical writes of total physical IO over the cumulative 
collection time.  Only local disks are counted in this measurement.  NFS 
devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_PHYS_WRITE_RATE
----------------------------------
The number of physical writes per second during the interval.  Only local 
disks are counted in this measurement.  NFS devices are excluded.
On Unix systems, all types of physical disk writes are counted, including 
file system IO, virtual memory IO, and raw writes.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
On HP-UX, this is calculated as

  GBL_DISK_PHYS_WRITE_RATE =
    GBL_DISK_FS_WRITE_RATE +
    GBL_DISK_VM_WRITE_RATE +
    GBL_DISK_SYSTEM_WRITE_RATE +
    GBL_DISK_RAW_WRITE_RATE
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_PHYS_WRITE_RATE_CUM
----------------------------------
The number of physical writes per second over the cumulative collection time.  
Only local disks are counted in this measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.


GBL_DISK_REQUEST_QUEUE
----------------------------------
The total length of all of the disk queues at the end of the interval.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.
 On SUN, if a CD drive is powered off, or no CD is inserted in the CD drive 
at boottime, the operating system does not provide performance data for that 
device.  This can be determined by checking the “by-disk” data when provided 
in a product.  If the CD drive has an entry in the list of active disks on a 
system, then data for that device is being collected.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_SUBSYSTEM_QUEUE
----------------------------------
The average number of processes or kernel threads blocked on the disk 
subsystem (in a “queue” waiting for their file system disk IO to complete) 
during the interval.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
This is calculated as the accumulated time mentioned above divided by the 
interval time.
As this number rises, it is an indication of a disk bottleneck.
 The Global QUEUE metrics, which are based on block states, represent the 
average number of process or kernel thread counts, not actual queues.
The Global WAIT PCT metrics, which are also based on block states, represent 
the percentage of all processes or kernel threads that were alive on the 
system.
No direct comparison is reasonable with the Application WAIT PCT metrics 
since they represent percentages within the context of a specific application 
and cannot be summed or compared with global values easily.  In addition, the 
sum of each Application WAIT PCT for all applications will not equal 100% 
since these values will vary greatly depending on the number of processes or 
kernel threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


GBL_DISK_SUBSYSTEM_WAIT_PCT
----------------------------------
The percentage of time processes or kernel threads were blocked on the disk 
subsystem (waiting for their file system IOs to complete) during the 
interval.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
This is calculated as the accumulated time mentioned above divided by the 
accumulated time that all processes or kernel threads were alive during the 
interval.
 The Global QUEUE metrics, which are based on block states, represent the 
average number of process or kernel thread counts, not actual queues.
The Global WAIT PCT metrics, which are also based on block states, represent 
the percentage of all processes or kernel threads that were alive on the 
system.
No direct comparison is reasonable with the Application WAIT PCT metrics 
since they represent percentages within the context of a specific application 
and cannot be summed or compared with global values easily.  In addition, the 
sum of each Application WAIT PCT for all applications will not equal 100% 
since these values will vary greatly depending on the number of processes or 
kernel threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


GBL_DISK_SUBSYSTEM_WAIT_TIME
----------------------------------
On HP-UX, the accumulated time, in seconds, that all processes or kernel 
threads were blocked on the disk subsystem (waiting for their file system IOs 
to complete) during the interval.  This is the sum of processes or kernel 
threads in the DISK, INODE, CACHE and CDFS wait states.
On Linux, the accumulated time, in seconds, that all processes or kernel 
threads were blocked on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.


GBL_DISK_TIME_PEAK
----------------------------------
The time, in seconds, during the interval that the busiest disk was 
performing IO transfers.  This is for the busiest disk only, not all disk 
devices.  This counter is based on an end-to-end measurement for each IO 
transfer updated at queue entry and exit points.
 Only local disks are counted in this measurement.  NFS devices are excluded.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_UTIL
----------------------------------
On HP-UX, this is the average percentage of time during the interval that all 
disks had IO in progress from the point of view of the Operating System.  
This is the average utilization for all disks.
On all other Unix systems, this is the average percentage of disk in use time 
of the total interval (that is, the average utilization).
 Only local disks are counted in this measurement.  NFS devices are excluded.


GBL_DISK_UTIL_PEAK
----------------------------------
The utilization of the busiest disk during the interval.
On HP-UX, this is the percentage of time during the interval that the busiest 
disk device had IO in progress from the point of view of the Operating 
System.
On all other systems, this is the percentage of time during the interval that 
the busiest disk was performing IO transfers.
It is not an average utilization over all the disk devices.  Only local disks 
are counted in this measurement.  NFS devices are excluded.
 Some Linux kernels, typically 2.2 and older kernels, do not support the 
instrumentation needed to provide values for this metric.  This metric will 
be “na” on the affected kernels.  The “sar -d” command will also not be 
present on these systems.  Distributions and OS releases that are known to be 
affected include: TurboLinux 7, SuSE 7.2, and Debian 3.0.
A peak disk utilization of more than 50 percent often indicates a disk IO 
subsystem bottleneck situation.  A bottleneck may not be in the physical disk 
drive itself, but elsewhere in the IO path.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_DISK_UTIL_PEAK_CUM
----------------------------------
The average utilization of the busiest disk in each interval over the 
cumulative collection time.  Utilization is the percentage of time in use 
versus the time in the measurement interval.  For each interval a different 
disk may be the busiest.  Only local disks are counted in this measurement.  
NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_DISK_UTIL_PEAK_HIGH
----------------------------------
The highest utilization of any disk during any interval over the cumulative 
collection time.  Utilization is the percentage of time in use versus the 
time in the measurement interval.  Only local disks are counted in this 
measurement.  NFS devices are excluded.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_DISTRIBUTION
----------------------------------
The software distribution, if available.


GBL_FS_SPACE_UTIL_PEAK
----------------------------------
The percentage of occupied disk space to total disk space for the fullest 
file system found during the interval.  Only locally mounted file systems are 
counted in this metric.
This metric can be used as an indicator that at least one file system on the 
system is running out of disk space.
On Unix systems, CDROM and PC file systems are also excluded.  This metric 
can exceed 100 percent.  This is because a portion of the file system space 
is reserved as a buffer and can only be used by root.  If the root user has 
made the file system grow beyond the reserved buffer, the utilization will be 
greater than 100 percent.  This is a dangerous situation since if the root 
user totally fills the file system, the system may crash.
On Windows, CDROM file systems are also excluded.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_GMTOFFSET
----------------------------------
The difference, in minutes, between local time and GMT (Greenwich Mean Time).


GBL_IGNORE_MT
----------------------------------
This boolean value indicates whether the CPU normalization is on or off.  If 
the metric value is “true”, CPU related metrics in the global class will 
report values which are normalized against the number of active cores on the 
system.
If the metric value is “false”, CPU related metrics in the global class will 
report values which are normalized against the number of CPU threads on the 
system.
If CPU MultiThreading is turned off this configuration option is a no-op and 
the metric value will be “true”.
On Linux, this metric will only report “true” if this configuration is on and 
if the kernel provides enough information to determine whether MultiThreading 
is turned on.
On HP-UX, this metric will report “na” if the processor doesn’t support the 
feature.


GBL_INTERRUPT
----------------------------------
The number of IO interrupts during the interval.
 On Solaris non-global zones with Uncapped CPUs, this metric shows data from 
the global zone.


GBL_INTERRUPT_RATE
----------------------------------
The average number of IO interrupts per second during the interval.
On HP-UX and SUN this value includes clock interrupts.  To get non-clock 
device interrupts, subtract clock interrupts from the value.
 On Solaris non-global zones with Uncapped CPUs, this metric shows data from 
the global zone.


GBL_INTERRUPT_RATE_CUM
----------------------------------
The average number of IO interrupts per second over the cumulative collection 
time.
On HP-UX and SUN this value includes clock interrupts.  To get non-clock 
device interrupts, subtract clock interrupts from the value.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_INTERRUPT_RATE_HIGH
----------------------------------
The highest number of IO interrupts per second during any one interval over 
the cumulative collection time.
On HP-UX and SUN this value includes clock interrupts.  To get non-clock 
device interrupts, subtract clock interrupts from the value.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_INTERVAL
----------------------------------
The amount of time in the interval.
This measured interval is slightly larger than the desired or configured 
interval if the collection program is delayed by a higher priority process 
and cannot sample the data immediately.


GBL_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_JAVAARG
----------------------------------
This boolean value indicates whether the java class overloading mechanism is 
enabled or not. This metric will be set when the javaarg flag in the parm 
file is set. The metric affected by this setting is PROC_PROC_ARGV1.  This 
setting is useful to construct parm file java application definitions using 
the argv1= keyword.


GBL_LOADAVG
----------------------------------
The 1 minute load average of the system obtained at the time of logging.
On windows this is the load average of the system over the interval.  Load 
average on windows is the average number of threads that have been waiting in 
ready state during the interval. This is obtained by checking the number of 
threads in ready state every sub proc interval, accumulating them over the 
interval and averaging over the interval.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_LOADAVG15
----------------------------------
The 15 minute load average of the system obtained at the time of logging.


GBL_LOADAVG5
----------------------------------
The 5 minute load average of the system obtained at the time of logging.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_LOADAVG_CUM
----------------------------------
The average load average of the system over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_LOADAVG_HIGH
----------------------------------
The highest value of the load average during any interval over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_LOST_MI_FTRACE_BUFFERS
----------------------------------
The number of ftrace buffers lost by the measurement processing daemon.


GBL_LOST_MI_TRACE_BUFFERS
----------------------------------
The number of trace buffers lost by the measurement processing daemon.
On HP-UX systems, if this value is > 0, the measurement subsystem is not 
keeping up with the system events that generate traces.
For other Unix systems, if this value is > 0, the measurement subsystem is 
not keeping up with the ARM API calls that generate traces.
Note: The value reported for this metric will roll over to 0 once it crosses 
INTMAX.


GBL_LS_MODE
----------------------------------
Indicates whether the CPU entitlement for the logical system is Capped or 
Uncapped.
On a recognized VMware ESX guest, where VMware guest SDK is enabled, the 
value is “Uncapped” if maximum CPU entitlement (GBL_CPU_ENTL_MAX) is 
unlimited.
Else, the value is always “Capped”.


GBL_LS_ROLE
----------------------------------
Indicates whether Perf Agent is installed on Logical system or host or 
standalone system. This metric will be either “GUEST”, “HOST” or “STAND”.


GBL_LS_SHARED
----------------------------------
In a virtual environment, this metric indicates whether the physical CPUs are 
dedicated to this Logical system or shared.
On AIX SPLPAR, this metric is equivalent to “Type” field of ‘lparstat -i’ 
command.
On a recognized VMware ESX guest, where VMware guest SDK is enabled, the 
value is “Shared”.
On a standalone system the value of this metrics is “Dedicated”.
 On AIX System WPARs, this metric is NA.


GBL_LS_TYPE
----------------------------------
The virtualization technology if applicable. The value of this metric is 
“HPVM” on HP-UX host, “LPAR” on AIX LPAR, “Sys WPAR” on system WPAR, “Zone” 
on Solaris Zones, “VMware” on recognized VMware ESX guest and VMware ESX 
Server console, “Hyper-V” on Hyper-V host, else “NoVM”.
In conjunction with GBL_LS_ROLE this metric could be used to identify the 
environment in which Perf Agent/Glance is running.  For example, if 
GBL_LS_ROLE is “Guest” and GBL_LS_TYPE is “VMware” then Performance 
Collection Component/Glance is running on a VMware Guest.


GBL_MACHINE
----------------------------------
An ASCII string representing the Processor Architecture. And machine hardware 
model is represented by GBL_MACHINE_MODEL metric.


GBL_MACHINE_MEM_USED
----------------------------------
The amount of physical host memory currently consumed for this logical 
system’s physical memory.  On a standalone system, the value will be 
(GBL_MEM_UTIL * GBL_MEM_PHYS) / 100


GBL_MACHINE_MODEL
----------------------------------
The Machine model.  This is similar to the information returned by the 
GBL_MACHINE metric and the uname command(except for Solaris 10 x86/x86_64).  
However, this metric returns more information on some processors.
On HP-UX, this is the same information returned by the model command.
On some Platforms, this Metric value is returned as NA ( not available) for 
non-root environments.


GBL_MACHINE_UUID
----------------------------------
The System Unique Identifier.  This metric returns the System Unique 
Identifier String. This metric is available only on Linux and Windows 
Platforms only.  On some platforms, if metric is not available, SystemID will 
be returned as value for this metric.


GBL_MACHINE_VENDOR
----------------------------------
The Machine Vendor. This metric returns the vendor name for this machine.  On 
some Platforms and virtual environments, this Metric value is returned as NA 
( not available).


GBL_MAC_ADDR_LIST
----------------------------------
This metric indicates the MAC address(es) configured for the system.  If 
there is more than one MAC address, values are seperated by ‘,’.


GBL_MEM_AVAIL
----------------------------------
The amount of physical available memory in the system (in MBs unless 
otherwise specified).
On Windows, memory resident operating system code and data is not included as 
available memory.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_CACHE
----------------------------------
The amount of physical memory (in MBs unless otherwise specified) used by the 
buffer cache during the interval.
On HP-UX 11i v2 and below, the buffer cache is a memory pool used by the 
system to stage disk IO data for the driver.
On HP-UX 11i v3 and above this metric value represents the usage of the file 
system buffer cache which is still being used for file system metadata.
On SUN, this value is obtained by multiplying the system page size times the 
number of buffer headers (nbuf).  For example, on a SPARCstation 10 the 
buffer size is usually (200 (page size buffers) * 4096 (bytes/page) = 800 
KB).
 On SUN, the buffer cache is a memory pool used by the system to cache inode, 
indirect block and cylinder group related disk accesses.  This is different 
from the traditional concept of a buffer cache that also holds file system 
data.  On Solaris 5.X, as file data is cached, accesses to it show up as 
virtual memory IOs.  File data caching occurs through memory mapping managed 
by the virtual memory system, not through the buffer cache.  The “nbuf” value 
is dynamic, but it is very hard to create a situation where the memory cache 
metrics change, since most systems have more than adequate space for inode, 
indirect block, and cylinder group data caching.  This cache is more heavily 
utilized on NFS file servers.
On AIX, this value should be minimal since most disk IOs are done through 
memory mapped files.


GBL_MEM_CACHE_UTIL
----------------------------------
The percentage of physical memory used by the buffer cache during the 
interval.
On HP-UX 11i v2 and below, the buffer cache is a memory pool used by the 
system to stage disk IO data for the driver.
On HP-UX 11i v3 and above this metric value represents the usage of the file 
system buffer cache which is still being used for file system metadata.
On SUN, this percentage is based on calculating the buffer cache size by 
multiplying the system page size times the number of buffer headers (nbuf).  
For example, on a SPARCstation 10 the buffer size is usually (200 (page size 
buffers) * 4096 (bytes/page) = 800 KB).
 On SUN, the buffer cache is a memory pool used by the system to cache inode, 
indirect block and cylinder group related disk accesses.  This is different 
from the traditional concept of a buffer cache that also holds file system 
data.  On Solaris 5.X, as file data is cached, accesses to it show up as 
virtual memory IOs.  File data caching occurs through memory mapping managed 
by the virtual memory system, not through the buffer cache.  The “nbuf” value 
is dynamic, but it is very hard to create a situation where the memory cache 
metrics change, since most systems have more than adequate space for inode, 
indirect block, and cylinder group data caching.  This cache is more heavily 
utilized on NFS file servers.
On AIX, this value should be minimal since most disk IOs are done through 
memory mapped files.  On Windows the value reports ‘copy read hit %’ and ‘Pin 
read hit %’.


GBL_MEM_ENTL_MAX
----------------------------------
In a virtual environment, this metric indicates the maximum amount of memory 
configured for this logical system. The value is -3 if entitlement is 
‘Unlimited’ for this logical system.
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”
On Solaris non-global zones, this metric value is equivalent to ‘capped-
memory’ value for ‘zonecfg -z zonename info’ command.
On a standalone system this metric is equivalent to GBL_MEM_PHYS.


GBL_MEM_ENTL_MIN
----------------------------------
In a virtual environment, this metric indicates the minimum amount of memory 
configured for this logical system.
On a recognized VMware ESX guest, where VMware guest SDK is disabled, the 
value is “na”
On a standalone system, this metrics is equivalent to GBL_MEM_PHYS.


GBL_MEM_FILE_PAGEIN_RATE
----------------------------------
The number of page ins from the file system per second during the interval.
On Solaris, this is the same as the “fpi” value from the “vmstat -p” command, 
divided by page size in KB.
On Linux, the value is reported in kilobytes and matches the ‘io/bi’ values 
from vmstat.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_FILE_PAGEOUT_RATE
----------------------------------
The number of page outs to the file system per second during the interval.
On Solaris, this is the same as the “fpo” value from the “vmstat -p” command, 
divided by page size in KB.
On Linux, the value is reported in kilobytes and matches the ‘io/bo’ values 
from vmstat.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_FILE_PAGE_CACHE
----------------------------------
The amount of physical memory (in MBs unless otherwise specified) used by the 
file cache during the interval. File cache is a memory pool used by the 
system to stage disk IO data for the driver.
 This metric is supported on HP-UX 11iv3 and above. The filecache_min and 
filecache_max tunables control the filecache memory usage on the system. The 
filecache_min tunable specifies the amount of physical memory that is 
guaranteed to be available for filecache on the system.  The filecache memory 
usage can grow beyond filecache_min, up to the limit set by the filecache_max 
tunable. The Virtual Memory(VM) subsystem always pre reserves ‘filecache_min’ 
tunable value worth of pages on the system for filecache, even in the case of  
filecache under utilization (actual filecache utilization less than 
filecache_min value). This preserved memory by the VM is not available for 
the user. In this scenario, this metric will show the ‘filecache_min’ as the 
filecache value, rather than showing the actual filecache utilization.
On Linux, this metric is equal to ‘cached’ value of ‘free -m’ command output.


GBL_MEM_FILE_PAGE_CACHE_UTIL
----------------------------------
The percentage of physical_memory used by the file cache during the interval.  
File cache is a memory pool used by the system to stage disk IO data for the 
driver.
 This metric is supported on HP-UX 11iv3 and above. The filecache_min and 
filecache_max tunables control the filecache memory usage on the system. The 
filecache_min tunable specifies the amount of physical memory that is 
guaranteed to be available for filecache on the system.  The filecache memory 
usage can grow beyond filecache_min, up to the limit set by the filecache_max 
tunable. The Virtual Memory(VM) subsystem always pre reserves ‘filecache_min’ 
tunable value worth of pages on the system for filecache, even in the case of  
filecache under utilization (actual filecache utilization less than 
filecache_min value). This preserved memory by the VM is not available for 
the user. In this scenario, this metric will show the ‘filecache_min’ as the 
filecache value, rather than showing the actual filecache utilization.
On Linux, this metric is derived from ‘cached’ value of ‘free -m’ command 
output.


GBL_MEM_FREE
----------------------------------
The amount of memory not allocated (in MBs unless otherwise specified).  As 
this value drops, the likelihood increases that swapping or paging out to 
disk may occur to satisfy new memory requests.
On SUN, low values for this metric may not indicate a true memory shortage.  
This metric can be influenced by the VMM (Virtual Memory Management) system. 
On uncapped solaris zones, the metric indicates the amount of memory that is 
available across the whole system that is not consumed by the global zone and 
other non-global zones. In case of capped solaris zones, the metric indicates 
the amount of memory that is not consumed by this zone against the memory cap 
set.
On Linux, this metric is sum of ‘free’ and ‘cached’ memory.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.
 Locality Domain metrics are available on HP-UX 11iv2 and above.  
GBL_MEM_FREE and LDOM_MEM_FREE, as well as the memory utilization metrics 
derived from them, may not always fully match.  GBL_MEM_FREE represents free 
memory in the kernel’s reservation layer while LDOM_MEM_FREE shows actual 
free pages. If memory has been reserved but not actually consumed from the 
Locality Domains, the two values won’t match. Because GBL_MEM_FREE includes 
pre-reserved memory, the GBL_MEM_* metrics are a better indicator of actual 
memory consumption in most situations.


GBL_MEM_FREE_UTIL
----------------------------------
The percentage of physical memory that was free at the end of the interval.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_OVERHEAD
----------------------------------
The amount of “overhead” memory associated with this logical system that is 
currently consumed on the host system.  On VMware ESX Server console, the 
value is equivalent to sum of the current overhead memory for all running 
virtual machines On a standalone system, the value will be 0.  On a 
recognized VMware ESX guest, where VMware guest SDK is disabled, the value is 
“na”.


GBL_MEM_PAGEIN
----------------------------------
The total number of page ins from the disk during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.
On HP-UX, this is the same as the “page ins” value from the “vmstat -s” 
command.  On AIX, this is the same as the “paging space page ins” value.  
Remember that “vmstat -s” reports cumulative counts.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGEIN_BYTE
----------------------------------
The number of KBs (or MBs if specified) of page ins during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_BYTE_CUM
----------------------------------
The number of KBs (or MBs if specified) of page ins over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_BYTE_RATE
----------------------------------
The number of KBs per second of page ins during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of page ins over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_BYTE_RATE_HIGH
----------------------------------
The highest number of KBs per second of page ins during any interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_CUM
----------------------------------
The total number of page ins from the disk over the cumulative collection 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_RATE
----------------------------------
The total number of page ins per second from the disk during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.
On HP-UX and AIX, this is the same as the “pi” value from the vmstat command.
On Solaris, this is the same as the sum of the “epi” and “api” values from 
the “vmstat -p” command, divided by the page size in KB.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGEIN_RATE_CUM
----------------------------------
The average number of page ins per second over the cumulative collection 
time.  This includes pages paged in from paging space and, except for AIX, 
from the file system.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEIN_RATE_HIGH
----------------------------------
The highest number of page ins per second from disk during any interval over 
the cumulative collection time.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEOUT
----------------------------------
The total number of page outs to the disk during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.
On HP-UX, this is the same as the “page outs” value from the “vmstat -s” 
command. On HP-UX 11iv3 and above this includes filecache page outs also.  On 
AIX, this is the same as the “paging space page outs” value.  Remember that 
“vmstat -s” reports cumulative counts.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGEOUT_BYTE
----------------------------------
The number of KBs (or MBs if specified) of page outs during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGEOUT_BYTE_CUM
----------------------------------
The number of KBs (or MBs if specified) of page outs over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEOUT_BYTE_RATE
----------------------------------
The number of KBs (or MBs if specified) per second of page outs during the 
interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGEOUT_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second of page outs over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEOUT_BYTE_RATE_HIGH
----------------------------------
The highest number of KBs per second of page outs during any interval over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEOUT_CUM
----------------------------------
The total number of page outs to the disk over the cumulative collection 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEOUT_RATE
----------------------------------
The total number of page outs to the disk per second during the interval.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.
On HP-UX and AIX, this is the same as the “po” value from the vmstat command.
On Solaris, this is the same as the sum of the “epo” and “apo” values from 
the “vmstat -p” command, divided by the page size in KB.
On Windows, this counter also includes paging traffic on behalf of the system 
cache to access file data for applications and so may be high when there is 
no memory pressure.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGEOUT_RATE_CUM
----------------------------------
The average number of page outs to the disk per second over the cumulative 
collection time.  This includes pages paged out to paging space and, except 
for AIX, to the file system.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGEOUT_RATE_HIGH
----------------------------------
The highest number of page outs per second to disk during any interval over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, Solaris, Linux and AIX, this reflects paging activity between 
memory and paging space.  It does not include activity between memory and 
file systems.
On Windows, this includes paging activity for both file systems and paging 
space.


GBL_MEM_PAGE_FAULT
----------------------------------
The number of page faults that occurred during the interval.
On Linux this metric is available only on 2.6 and above kernel versions.


GBL_MEM_PAGE_FAULT_CUM
----------------------------------
The number of page faults that occurred over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_MEM_PAGE_FAULT_RATE
----------------------------------
The number of page faults per second during the interval.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGE_FAULT_RATE_CUM
----------------------------------
The average number of page faults per second over the cumulative collection 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_MEM_PAGE_FAULT_RATE_HIGH
----------------------------------
The highest page fault per second during any interval over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_MEM_PAGE_REQUEST
----------------------------------
The number of page requests to or from the disk during the interval.
On HP-UX, Solaris, and AIX, this includes pages paged to or from the paging 
space and not to the file system.
On Windows, this includes pages paged to or from both paging space and the 
file system.
On HP-UX, this is the same as the sun of the “page ins” and “page outs” 
values from the “vmstat -s” command.  On AIX, this is the same as the sum of 
the “paging space page ins” and “paging space page outs” values.  Remember 
that “vmstat -s” reports cumulative counts.
On Windows, this counter also includes paging traffic on behalf of the system 
cache to access file data for applications and so may be high when there is 
no memory pressure.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGE_REQUEST_CUM
----------------------------------
The total number of page requests to or from the disk over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, Solaris, and AIX, this includes pages paged to or from the paging 
space and not to or from the file system.
On Windows, this includes pages paged to or from both paging space and the 
file system.
On Windows, this counter also includes paging traffic on behalf of the system 
cache to access file data for applications and so may be high when there is 
no memory pressure.


GBL_MEM_PAGE_REQUEST_RATE
----------------------------------
The number of page requests to or from the disk per second during the 
interval.
On HP-UX, Solaris, and AIX, this includes pages paged to or from the paging 
space and not to or from the file system.
On Windows, this includes pages paged to or from both paging space and the 
file system.
On HP-UX and AIX, this is the same as the sum of the “pi” and “po” values 
from the vmstat command.
On Solaris, this is the same as the sum of the “epi”, “epo”, “api”, and “apo” 
values from the “vmstat -p” command, divided by the page size in KB.
Higher than normal rates can indicate either a memory or a disk bottleneck.  
Compare GBL_DISK_UTIL_PEAK and GBL_MEM_UTIL to determine which resource is 
more constrained.  High rates may also indicate memory thrashing caused by a 
particular application or set of applications.  Look for processes with high 
major fault rates to identify the culprits.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PAGE_REQUEST_RATE_CUM
----------------------------------
The average number of page requests to or from the disk per second over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, Solaris, and AIX, this includes pages paged to or from the paging 
space and not to or from the file system.
On Windows, this includes pages paged to or from both paging space and the 
file system.


GBL_MEM_PAGE_REQUEST_RATE_HIGH
----------------------------------
The highest number of page requests per second during any interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, Solaris, and AIX, this includes pages paged to or from the paging 
space and not to or from the file system.
On Windows, this includes pages paged to or from both paging space and the 
file system.


GBL_MEM_PHYS
----------------------------------
The amount of physical memory in the system (in MBs unless otherwise 
specified).
On HP-UX, banks with bad memory are not counted.  Note that on some machines, 
the Processor Dependent Code (PDC) code uses the upper 1MB of memory and thus 
reports less than the actual physical memory of the system.  Thus, on a 
system with 256MB of physical memory, this metric and dmesg(1M) might only 
report 267,386,880 bytes (255MB).  This is all the physical memory that 
software on the machine can access.
On Windows, this is the total memory available, which may be slightly less 
than the total amount of physical memory present in the system.  This value 
is also reported in the Control Panel’s About Windows NT help topic.
On Linux, this is the amount of memory given by dmesg(1M).  If the value is 
not available in kernel ring buffer, then the sum of system memory and 
available memory will be reported as physical memory.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_PHYS_SWAPPED
----------------------------------
On a recognized VMware ESX guest, where VMware guest SDK is enabled, this 
metrics indicates the amount of memory that has been reclaimed by ESX Server 
from this logical system by transparently swapping logical system’s memory to 
disk.  The value is “na” otherwise.


GBL_MEM_SHARES_PRIO
----------------------------------
The weightage/priority for memory assigned to this logical system. This value 
influences the share of unutilized physical Memory that this logical system 
can utilize.  On a recognized VMware ESX guest, where VMware guest SDK is 
enabled, this value can range from 0 to 100000.  The value will be “na” 
otherwise.


GBL_MEM_SWAPIN_BYTE
----------------------------------
The number of KBs transferred in from disk due to swap ins (or reactivations 
on HP-UX) during the interval.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_SWAPIN_BYTE_CUM
----------------------------------
The number of KBs transferred in from disk due to swap ins (or reactivations 
on HP-UX) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.


GBL_MEM_SWAPIN_BYTE_RATE
----------------------------------
The number of KBs per second transferred from disk due to swap ins (or 
reactivations on HP-UX) during the interval.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_SWAPIN_BYTE_RATE_CUM
----------------------------------
The number of KBs per second transferred from disk due to swap ins (or 
reactivations on HP-UX) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.


GBL_MEM_SWAPIN_BYTE_RATE_HIGH
----------------------------------
The highest number of KBs per second transferred from disk due to swap ins 
(or reactivations on HP-UX) during any interval over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.


GBL_MEM_SWAPOUT_BYTE
----------------------------------
The number of KBs (or MBs if specified) transferred out to disk due to swap 
outs (or deactivations on HP-UX) during the interval.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_SWAPOUT_BYTE_CUM
----------------------------------
The number of KBs (or MBs if specified) transferred out to disk due to swap 
outs (or deactivations on HP-UX) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.


GBL_MEM_SWAPOUT_BYTE_RATE
----------------------------------
The number of KBs (or MBs if specified) per second transferred out to disk 
due to swap outs (or deactivations on HP-UX) during the interval.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.
 On Solaris non-global zones with Uncapped Memory scenario, this metric value 
is same as seen in global zone.


GBL_MEM_SWAPOUT_BYTE_RATE_CUM
----------------------------------
The average number of KBs (or MBs if specified) per second transferred out to 
disk due to swap outs (or deactivations on HP-UX) over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.


GBL_MEM_SWAPOUT_BYTE_RATE_HIGH
----------------------------------
The highest number of KBs (or MBs if specified) per second transferred out to 
disk due to swap outs (or deactivations on HP-UX) during any interval over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Linux and AIX, swap metrics are equal to the corresponding page metrics.
 On HP-UX, process swapping was replaced by a combination of paging and 
deactivation.  Process deactivation occurs when the system is thrashing or 
when the amount of free memory falls below a critical level.  The swapper 
then marks certain processes for deactivation and removes them from the run 
queue.  Pages within the associated memory regions are reused or paged out by 
the memory management vhand process in favor of pages belonging to processes 
that are not deactivated.  Unlike traditional process swapping, deactivated 
memory pages may or may not be written out to the swap area, because a 
process could be reactivated before the paging occurs.
To summarize, a process swap-out on HP-UX is a process deactivation.  A swap-
in is a reactivation of a deactivated process.  Swap metrics that report 
swap-out bytes now represent bytes paged out to swap areas from deactivated 
regions.  Because these pages are pushed out over time based on memory 
demands, these counts are much smaller than HP-UX 9.x counts where the entire 
process was written to the swap area when it was swapped-out. Likewise, swap-
in bytes now represent bytes paged in as a result of reactivating a 
deactivated process and reading in any pages that were actually paged out to 
the swap area while the process was deactivated.


GBL_MEM_SYS
----------------------------------
The amount of physical memory (in MBs unless otherwise specified) used by the 
system (kernel) during the interval.  System memory does not include the 
buffer cache.  On HP-UX and Linux this does not include filecache also.
 On HP-UX 11.0, this metric does not include some kinds of dynamically 
allocated kernel memory.  This has always been reported in the GBL_MEM_USER* 
metrics.
On HP-UX 11.11 and beyond, this metric includes some kinds of dynamically 
allocated kernel memory.
 On Solaris non-global zones, this metric shows value as 0.


GBL_MEM_SYS_UTIL
----------------------------------
The percentage of physical memory used by the system during the interval.
System memory does not include the buffer cache.  On HP-UX and Linux this 
does not include filecache also.
 On HP-UX 11.0, this metric does not include some kinds of dynamically 
allocated kernel memory.  This has always been reported in the GBL_MEM_USER* 
metrics.
On HP-UX 11.11 and beyond, this metric includes some kinds of dynamically 
allocated kernel memory.
 On Solaris non-global zones, this metric shows value as 0.


GBL_MEM_USER
----------------------------------
The amount of physical memory (in MBs unless otherwise specified) allocated 
to user code and data at the end of the interval.  User memory regions 
include code, heap, stack, and other data areas including shared memory.  
This does not include memory for buffer cache.  On HP-UX and Linux this does 
not include filecache also.
 On HP-UX 11.0, this metric includes some kinds of dynamically allocated 
kernel memory.
On HP-UX 11.11 and beyond, this metric does not include some kinds of 
dynamically allocated kernel memory.  This is now reported in the 
GBL_MEM_SYS* metrics.
Large fluctuations in this metric can be caused by programs which allocate 
large amounts of memory and then either release the memory or terminate.  A 
slow continual increase in this metric may indicate a program with a memory 
leak.


GBL_MEM_USER_UTIL
----------------------------------
The percent of physical memory allocated to user code and data at the end of 
the interval.  This metric shows the percent of memory owned by user memory 
regions such as user code, heap, stack and other data areas including shared 
memory.  This does not include memory for buffer cache.  On HP-UX and Linux 
this does not include filecache also.  On HP-UX 11.0, this metric includes 
some kinds of dynamically allocated kernel memory.
On HP-UX 11.11 and beyond, this metric does not include some kinds of 
dynamically allocated kernel memory.  This is now reported in the 
GBL_MEM_SYS* metrics.
Large fluctuations in this metric can be caused by programs which allocate 
large amounts of memory and then either release the memory or terminate.  A 
slow continual increase in this metric may indicate a program with a memory 
leak.


GBL_MEM_UTIL
----------------------------------
The percentage of physical memory in use during the interval.  This includes 
system memory (occupied by the kernel), buffer cache and user memory.
On HP-UX 11iv3 and above, this includes file cache.  This excludes file cache 
when cachemem parameter in the parm file is set to free.
On HP-UX, this calculation is done using the byte values for physical memory 
and used memory, and is therefore more accurate than comparing the reported 
kilobyte values for physical memory and used memory.
On Linux, the value of this metric includes file cache when the cachemem 
parameter in the parm file is set to user.
On SUN, high values for this metric may not indicate a true memory shortage.  
This metric can be influenced by the VMM (Virtual Memory Management) system. 
This excludes ZFS ARC cache when cachemem parameter in the parm file is set 
to free.
On AIX, this excludes file cache  when cachemem parameter in the parm file is 
set to free.
 Locality Domain metrics are available on HP-UX 11iv2 and above.  
GBL_MEM_FREE and LDOM_MEM_FREE, as well as the memory utilization metrics 
derived from them, may not always fully match.  GBL_MEM_FREE represents free 
memory in the kernel’s reservation layer while LDOM_MEM_FREE shows actual 
free pages. If memory has been reserved but not actually consumed from the 
Locality Domains, the two values won’t match. Because GBL_MEM_FREE includes 
pre-reserved memory, the GBL_MEM_* metrics are a better indicator of actual 
memory consumption in most situations.


GBL_MEM_UTIL_CUM
----------------------------------
The average percentage of physical memory in use over the cumulative 
collection time.  This includes system memory (occupied by the kernel), 
buffer cache and user memory.
On HP-UX 11iv3 and above, this includes file cache also.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_MEM_UTIL_HIGH
----------------------------------
The highest percentage of physical memory in use in any interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_NET_COLLISION
----------------------------------
The number of collisions that occurred on all network interfaces during the 
interval.  A rising rate of collisions versus outbound packets is an 
indication that the network is becoming increasingly congested.  This metric 
does not include deferred packets.
This does not include data for loopback interface.
For HP-UX, this will be the same as the sum of the “Single Collision Frames”, 
“Multiple Collision Frames”, “Late Collisions”, and “Excessive Collisions” 
values from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  As of the HP-UX 11.0 
release and beyond, “netstat -i” shows network activity on the logical level 
(IP) only.
For all other Unix systems, this is the same as the sum of the “Coll” column 
from the “netstat -i” command (“collisions” from the “netstat -i -e” command 
on Linux) for a network device.  See also netstat(1).
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_COLLISION_1_MIN_RATE
----------------------------------
The number of collisions per minute on all network interfaces during the 
interval.  This metric does not include deferred packets.
This does not include data for loopback interface.
Collisions occur on any busy network, but abnormal collision rates could 
indicate a hardware or software problem.
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_COLLISION_CUM
----------------------------------
The number of collisions that occurred on all network interfaces over the 
cumulative collection time.  A rising rate of collisions versus outbound 
packets is an indication that the network is becoming increasingly congested.  
This metric does not include deferred packets.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For HP-UX, this will be the same as the sum of the “Single Collision Frames”, 
“Multiple Collision Frames”, “Late Collisions”, and “Excessive Collisions” 
values from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  For this release and 
beyond, “netstat -i” shows network activity on the logical level (IP) only.
For other Unix systems, this is the same as the sum of the “Coll” column from 
the “netstat -i” command (“collisions” from the “netstat -i -e” command on 
Linux) for a network device.  See also netstat(1).
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_COLLISION_PCT
----------------------------------
The percentage of collisions to total outbound packet attempts during the 
interval.  Outbound packet attempts include both successful packets and 
collisions.
This does not include data for loopback interface.
A rising rate of collisions versus outbound packets is an indication that the 
network is becoming increasingly congested.
This metric does not currently include deferred packets.
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_COLLISION_PCT_CUM
----------------------------------
The percentage of collisions to total outbound packet attempts over the 
cumulative collection time.  Outbound packet attempts include both successful 
packets and collisions.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
A rising rate of collisions versus outbound packets is an indication that the 
network is becoming increasingly congested.
This metric does not currently include deferred packets.
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_COLLISION_RATE
----------------------------------
The number of collisions per second on all network interfaces during the 
interval.  This metric does not include deferred packets.
This does not include data for loopback interface.
A rising rate of collisions versus outbound packets is an indication that the 
network is becoming increasingly congested.
 AIX does not support the collision count for the ethernet interface.  The 
collision count is supported for the token ring (tr) and loopback (lo) 
interfaces.  For more information, please refer to the netstat(1) man page.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_ERROR
----------------------------------
The number of errors that occurred on all network interfaces during the 
interval.
This does not include data for loopback interface.
For HP-UX, this will be the same as the sum of the “Inbound Errors” and 
“Outbound Errors” values from the output of the “lanadmin” utility for the 
network interface.  Remember that “lanadmin” reports cumulative counts.  As 
of the HP-UX 11.0 release and beyond, “netstat -i” shows network activity on 
the logical level (IP) only.
For all other Unix systems, this is the same as the sum of “Ierrs” (RX-ERR on 
Linux) and “Oerrs” (TX-ERR on Linux) from the “netstat -i” command for a 
network device.  See also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_ERROR_1_MIN_RATE
----------------------------------
The number of errors per minute on all network interfaces during the 
interval.  This rate should normally be zero or very small.  A large error 
rate can indicate a hardware or software problem.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_ERROR_CUM
----------------------------------
The number of errors that occurred on all network interfaces over the 
cumulative collection time.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For HP-UX, this will be the same as the total sum of the “Inbound Errors” and 
“Outbound Errors” values from the output of the “lanadmin” utility for the 
network interface.  Remember that “lanadmin” reports cumulative counts.  As 
of the HP-UX 11.0 release and beyond, “netstat -i” shows network activity on 
the logical level (IP) only.
For all other Unix systems, this is the same as the sum of “Ierrs” (RX-ERR on 
Linux) and “Oerrs” (TX-ERR on Linux) from the “netstat -i” command for a 
network device.  See also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_ERROR_RATE
----------------------------------
The number of errors per second on all network interfaces during the 
interval.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_IN_ERROR
----------------------------------
The number of inbound errors that occurred on all network interfaces during 
the interval.
A large number of errors may indicate a hardware problem on the network.
This does not include data for loopback interface.
For HP-UX, this will be the same as the sum of the “Inbound Errors” values 
from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  As of the HP-UX 11.0 
release and beyond, “netstat -i” shows network activity on the logical level 
(IP) only.
For all other Unix systems, this is the same as the sum of “Ierrs” (RX-ERR on 
Linux) and “Oerrs” (TX-ERR on Linux) from the “netstat -i” command for a 
network device.  See also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_IN_ERROR_CUM
----------------------------------
The number of inbound errors that occurred on all network interfaces over the 
cumulative collection time.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
A large number of errors may indicate a hardware problem on the network.
For HP-UX, this will be the same as the total sum of the “Inbound Errors” 
values from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  As of the HP-UX 11.0 
release and beyond, “netstat -i” shows network activity on the logical level 
(IP) only.
For all other Unix systems, this is the same as the sum of “Ierrs” (RX-ERR on 
Linux) and “Oerrs” (TX-ERR on Linux) from the “netstat -i” command for a 
network device.  See also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_IN_ERROR_PCT
----------------------------------
The percentage of inbound network errors to total inbound packet attempts 
during the interval.  Inbound packet attempts include both packets 
successfully received and those that encountered errors.
This does not include data for loopback interface.
A large number of errors may indicate a hardware problem on the network.  The 
percentage of inbound errors to total packets attempted should remain low.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_IN_ERROR_PCT_CUM
----------------------------------
The percentage of inbound network errors to total inbound packet attempts 
over the cumulative collection time.  Inbound packet attempts include both 
packets successfully received and those that encountered errors.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
A large number of errors may indicate a hardware problem on the network.  The 
percentage of inbound errors to total packets attempted should remain low.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_IN_ERROR_RATE
----------------------------------
The number of inbound errors per second on all network interfaces during the 
interval.
This does not include data for loopback interface.
A large number of errors may indicate a hardware problem on the network.  The 
percentage of inbound errors to total packets attempted should remain low.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_IN_ERROR_RATE_CUM
----------------------------------
The average number of inbound errors per second on all network interfaces 
over the cumulative collection time.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_IN_PACKET
----------------------------------
The number of successful packets received through all network interfaces 
during the interval.  Successful packets are those that have been processed 
without errors or collisions.
This does not include data for loopback interface.
For HP-UX, this will be the same as the sum of the “Inbound Unicast Packets” 
and “Inbound Non-Unicast Packets” values from the output of the “lanadmin” 
utility for the network interface.  Remember that “lanadmin” reports 
cumulative counts.  As of the HP-UX 11.0 release and beyond, “netstat -i” 
shows network activity on the logical level (IP) only.
For all other Unix systems, this is the same as the sum of the “Ipkts” column 
(RX-OK on Linux) from the “netstat -i” command for a network device.  See 
also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On Windows system, the packet size for NBT connections is defined as 1 
Kbyte.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_IN_PACKET_CUM
----------------------------------
The number of successful packets received through all network interfaces over 
the cumulative collection time.  Successful packets are those that have been 
processed without errors or collisions.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For HP-UX, this will be the same as the total sum of the “Inbound Unicast 
Packets” and “Inbound Non-Unicast Packets” values from the output of the 
“lanadmin” utility for the network interface.  Remember that “lanadmin” 
reports cumulative counts.  As of the HP-UX 11.0 release and beyond, “netstat 
-i” shows network activity on the logical level (IP) only.
For all other Unix systems, this is the same as the sum of the “Ipkts” column 
(RX-OK on Linux) from the “netstat -i” command for a network device.  See 
also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_IN_PACKET_RATE
----------------------------------
The number of successful packets per second received through all network 
interfaces during the interval.  Successful packets are those that have been 
processed without errors or collisions.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On Windows system, the packet size for NBT connections is defined as 1 
Kbyte.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_OUT_ERROR
----------------------------------
The number of outbound errors that occurred on all network interfaces during 
the interval.
This does not include data for loopback interface.
For HP-UX, this will be the same as the sum of the “Outbound Errors” values 
from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  As of the HP-UX 11.0 
release and beyond, “netstat -i” shows network activity on the logical level 
(IP) only.
For all other Unix systems, this is the same as the sum of “Oerrs” (TX-ERR on 
Linux) from the “netstat -i” command for a network device.  See also 
netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_OUT_ERROR_CUM
----------------------------------
The number of outbound errors that occurred on all network interfaces over 
the cumulative collection time.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For HP-UX, this will be the same as the total sum of the “Outbound Errors” 
values from the output of the “lanadmin” utility for the network interface.  
Remember that “lanadmin” reports cumulative counts.  As of the HP-UX 11.0 
release and beyond, “netstat -i” shows network activity on the logical level 
(IP) only.
For all other Unix systems, this is the same as the sum of “Oerrs” (TX-ERR on 
Linux) from the “netstat -i” command for a network device.  See also 
netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_OUT_ERROR_PCT
----------------------------------
The percentage of outbound network errors to total outbound packet attempts 
during the interval.  Outbound packet attempts include both packets 
successfully sent and those that encountered errors.
This does not include data for loopback interface.
The percentage of outbound errors to total packets attempted to be 
transmitted should remain low.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_OUT_ERROR_PCT_CUM
----------------------------------
The percentage of outbound network errors to total outbound packet attempts 
over the cumulative collection time.  Outbound packet attempts include both 
packets successfully sent and those that encountered errors.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
The percentage of outbound errors to total packets attempted to be 
transmitted should remain low.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_OUT_ERROR_RATE
----------------------------------
The number of outbound errors per second on all network interfaces during the 
interval.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_OUT_ERROR_RATE_CUM
----------------------------------
The number of outbound errors per second on all network interfaces over the 
cumulative collection time.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_OUT_PACKET
----------------------------------
The number of successful packets sent through all network interfaces during 
the last interval.  Successful packets are those that have been processed 
without errors or collisions.
This does not include data for loopback interface.
For HP-UX, this will be the same as the sum of the “Outbound Unicast Packets” 
and “Outbound Non-Unicast Packets” values from the output of the “lanadmin” 
utility for the network interface.  Remember that “lanadmin” reports 
cumulative counts.  As of the HP-UX 11.0 release and beyond, “netstat -i” 
shows network activity on the logical level (IP) only.
For all other Unix systems, this is the same as the sum of the “Opkts” column 
(TX-OK on Linux) from the “netstat -i” command for a network device.  See 
also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On Windows system, the packet size for NBT connections is defined as 1 
Kbyte.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_OUT_PACKET_CUM
----------------------------------
The number of successful packets sent through all network interfaces over the 
cumulative collection time.  Successful packets are those that have been 
processed without errors or collisions.
This does not include data for loopback interface.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
For HP-UX, this will be the same as the total sum of the “Outbound Unicast 
Packets” and “Outbound Non-Unicast Packets” values from the output of the 
“lanadmin” utility for the network interface.  Remember that “lanadmin” 
reports cumulative counts.  As of the HP-UX 11.0 release and beyond, “netstat 
-i” shows network activity on the logical level (IP) only.
For all other Unix systems, this is the same as the sum of the “Opkts” column 
(TX-OK on Linux) from the “netstat -i” command for a network device.  See 
also netstat(1).
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.


GBL_NET_OUT_PACKET_RATE
----------------------------------
The number of successful packets per second sent through the network 
interfaces during the interval.  Successful packets are those that have been 
processed without errors or collisions.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On Windows system, the packet size for NBT connections is defined as 1 
Kbyte.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_PACKET
----------------------------------
The total number of successful inbound and outbound packets for all network 
interfaces during the interval.  These are the packets that have been 
processed without errors or collisions.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On Windows system, the packet size for NBT connections is defined as 1 
Kbyte.


GBL_NET_PACKET_RATE
----------------------------------
The number of successful packets per second (both inbound and outbound) for 
all network interfaces during the interval.  Successful packets are those 
that have been processed without errors or collisions.
This does not include data for loopback interface.
 This metric is updated at the sampling interval, regardless of the number of 
IP addresses on the system.
 On Windows system, the packet size for NBT connections is defined as 1 
Kbyte.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_NET_UTIL_PEAK
----------------------------------
It is the utilisation of the most used network interfaces at the end of the 
interval.
 Some AIX systems report a speed that is lower than the measured throughput 
and this can result in BYNETIF_UTIL and GBL_NET_UTIL_PEAK showing more than 
100% utilization.
On Linux, root permission is required to obtain network interface bandwidth 
so values will be n/a when running in non-root mode. Also, maximum bandwidth 
for virtual interfaces (vnetN) may be reported wrongly on KVM or Xen server 
so, similarly to AIX, utilization may exceed 100%.


GBL_NFS_CALL
----------------------------------
The number of NFS calls the local system has made as either a NFS client or 
server during the interval.
This includes both successful and unsuccessful calls.  Unsuccessful calls are 
those that cannot be completed due to resource limitations or LAN packet 
errors.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.
 On AIX System WPARs, this metric is NA.


GBL_NFS_CALL_RATE
----------------------------------
The number of NFS calls per second the system made as either a NFS client or 
NFS server during the interval.
Each computer can operate as both a NFS server, and as an NFS client.
This metric includes both successful and unsuccessful calls.  Unsuccessful 
calls are those that cannot be completed due to resource limitations or LAN 
packet errors.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.
 On AIX System WPARs, this metric is NA.


GBL_NFS_CLIENT_BAD_CALL
----------------------------------
The number of failed NFS client calls during the interval.  Calls fail due to 
lack of system resources (lack of virtual memory) as well as network errors.
On linux and some unix platforms we need a soft mount for NFS client to get 
the metric updated. If you mount with hard mount which is default on many 
platforms it doesn’t update the necessary counters atleast on linux.


GBL_NFS_CLIENT_BAD_CALL_CUM
----------------------------------
The number of failed NFS client calls over the cumulative collection time.  
Calls fail due to lack of system resources (lack of virtual memory) as well 
as network errors.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_NFS_CLIENT_CALL
----------------------------------
The number of NFS calls the local machine has processed as a NFS client 
during the interval.  Calls are the system calls used to initiate physical 
NFS operations.  These calls are not always successful due to resource 
constraints or LAN errors, which means that the call rate should exceed the 
IO rate.  This metric includes both successful and unsuccessful calls.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.


GBL_NFS_CLIENT_CALL_CUM
----------------------------------
The number of NFS calls the local machine has processed as a NFS client over 
the cumulative collection time.  Calls are the system calls used to initiate 
physical NFS operations.  These calls are not always successful due to 
resource constraints or LAN errors, which means that the call rate should 
exceed the IO rate.  This metric includes both successful and unsuccessful 
calls.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.


GBL_NFS_CLIENT_CALL_RATE
----------------------------------
The number of NFS calls the local machine has processed as a NFS client per 
second during the interval.  Calls are the system call used to initiate 
physical NFS operations.  These calls are not always successful due to 
resource constraints or LAN errors, which means that the call rate should 
exceed the IO rate.  This metric includes both successful and unsuccessful 
calls.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.


GBL_NFS_CLIENT_IO
----------------------------------
The number of NFS IOs the local machine has completed as an NFS client during 
the interval.  This number represents physical IOs sent by the client in 
contrast to a call which is an attempt to initiate these operations.
Each computer can operate as both an NFS server, and as a NFS client.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_CLIENT_IO_CUM
----------------------------------
The number of NFS IOs the local machine has completed as an NFS client over 
the cumulative collection time.  This number represents physical IOs sent by 
the client in contrast to a call which is an attempt to initiate these 
operations.
Each computer can operate as both an NFS server, and as a NFS client.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_CLIENT_IO_PCT
----------------------------------
The percentage of NFs  IOs the local machine has completed as an NFS client 
versus total NFS IOs completed during the interval.  This number represents 
physical IOs sent by the client in contrast to a call which is an attempt to 
initiate these operations.
Each computer can operate as both an NFS server, and as a NFS client.
A percentage greater than 50 indicates that this machine is acting more as a 
client.  A percentage less than 50 indicates this machine is acting more as a 
server for others.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_CLIENT_IO_PCT_CUM
----------------------------------
The percentage of NFS IOs the local machine has completed as an NFS client 
versus total NFS IOs completed over the cumulative collection time.  This 
number represents physical IOs sent by the client in contrast to a call which 
is an attempt to initiate these operations.
Each computer can operate as both an NFS server, and as a NFS client.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
A percentage greater than 50 indicates that this machine is acting more as a 
client.  A percentage less than 50 indicates this machine is acting more as a 
server for others.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_CLIENT_IO_RATE
----------------------------------
The number of NFS IOs per second the local machine has completed as an NFS 
client during the interval.  This number represents physical IOs sent by the 
client in contrast to a call which is an attempt to initiate these 
operations.
Each computer can operate as both an NFS server, and as a NFS client.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_CLIENT_IO_RATE_CUM
----------------------------------
The number of NFS IOs per second the local machine has completed as an NFS 
client over the cumulative collection time.  This number represents physical 
IOs sent by the client in contrast to a call which is an attempt to initiate 
these operations.
Each computer can operate as both an NFS server, and as a NFS client.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_CLIENT_READ_RATE
----------------------------------
The number of NFS “read” operations per second the system generated as an NFS 
client during the interval.
 NFS Version 2 read operations consist of getattr, lookup, readlink, readdir, 
null, root, statfs, and read.
NFS Version 3 read operations consist of getattr, lookup, access, readlink, 
read, readdir, readdirplus, fsstat, fsinfo, and null.


GBL_NFS_CLIENT_READ_RATE_CUM
----------------------------------
The average number of NFS “read” operations per second the system generated 
as an NFS client over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS Version 2 read operations consist of getattr, lookup, readlink, readdir, 
null, root, statfs, and read.
NFS Version 3 read operations consist of getattr, lookup, access, readlink, 
read, readdir, readdirplus, fsstat, fsinfo, and null.


GBL_NFS_CLIENT_WRITE_RATE
----------------------------------
The number of NFS “write” operations per second the system generated as an 
NFS client during the interval.
 NFS Version 2 write operations consist of setattr, write, writecache, 
create, remove, rename, link, symlink, mkdir, and rmdir.
NFS Version 3 write operations consist of setattr, write, create, mkdir, 
symlink, mknod, remove, rmdir, rename, link, pathconf, and commit.


GBL_NFS_CLIENT_WRITE_RATE_CUM
----------------------------------
The average number of NFS “write” operations per second the system generated 
as an NFS client over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS Version 2 write operations consist of setattr, write, writecache, 
create, remove, rename, link, symlink, mkdir, and rmdir.
NFS Version 3 write operations consist of setattr, write, create, mkdir, 
symlink, mknod, remove, rmdir, rename, link, pathconf, and commit.


GBL_NFS_SERVER_BAD_CALL
----------------------------------
The number of failed NFS server calls during the interval.  Calls fail due to 
lack of system resources (lack of virtual memory) as well as network errors.


GBL_NFS_SERVER_BAD_CALL_CUM
----------------------------------
The number of failed NFS server calls over the cumulative collection time.  
Calls fail due to lack of system resources (lack of virtual memory) as well 
as network errors.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_NFS_SERVER_CALL
----------------------------------
The number of NFS calls the local machine has processed as a NFS server 
during the interval.
Calls are the system calls used to initiate physical NFS operations.  These 
calls are not always successful due to resource constraints or LAN errors, 
which means that the call rate could exceed the IO rate.  This metric 
includes both successful and unsuccessful calls.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.


GBL_NFS_SERVER_CALL_CUM
----------------------------------
The number of NFS calls the local machine has processed as a NFS server over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
Calls are the system calls used to initiate physical NFS operations.  These 
calls are not always successful due to resource constraints or LAN errors, 
which means that the call rate could exceed the IO rate.  This metric 
includes both successful and unsuccessful calls.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.


GBL_NFS_SERVER_CALL_RATE
----------------------------------
The number of NFS calls the local machine has processed per second as a NFS 
server during the interval.
Calls are the system calls used to initiate physical NFS operations.  These 
calls are not always successful due to resource constraints or LAN errors, 
which means that the call rate could exceed the IO rate.  This metric 
includes both successful and unsuccessful calls.
 NFS calls include create, remove, rename, link, symlink, mkdir, rmdir, 
statfs, getattr, setattr, lookup, read, readdir, readlink, write, writecache, 
null and root operations.


GBL_NFS_SERVER_IO
----------------------------------
The number of NFS IOs the local machine has completed as an NFS server during 
the interval.  This number represents physical IOs received by the serverein 
contrast to a call which is an attempt to initiate these operations.
Each computer can operate as both a NFS server, and as an NFS client.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_SERVER_IO_CUM
----------------------------------
The number of NFS IOs the local machine has completed as an NFS server over 
the cumulative collection time.  This number represents physical IOs received 
by the server n contrast to a call which is an attempt to initiate these 
operations.
Each computer can operate as both a NFS server, and as an NFS client.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_SERVER_IO_PCT
----------------------------------
The percentage of NFS IOs the local machine has completed as an NFS server 
versus total NFS IOs completed during the interval.  This number represents 
physical IOs received by the server in contrast to a call which is an attempt 
to initiate these operations.
Each computer can operate as both a NFS server, and as an NFS client.
A percentage greater than 50 indicates that this machine is acting more as a 
server for others.  A percentage less than 50 indicates this machine is 
acting more as a client.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_SERVER_IO_PCT_CUM
----------------------------------
The percentage of NFs IOs the local machine has completed as an NFS server 
versus total NFS IOs completed over the cumulative collection time.  This 
number represents physical IOs received by the server in contrast to a call 
which is an attempt to initiate these operations.
Each computer can operate as both a NFS server, and as an NFS client.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
A percentage greater than 50 indicates that this machine is acting more as a 
server for others.  A percentage less than 50 indicates this machine is 
acting more as a client.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_SERVER_IO_RATE
----------------------------------
The number of NFS IOs per second the local machine has completed as an NFS 
server during the interval.  This number represents physical IOs received by 
the server in contrast to a call which is an attempt to initiate these 
operations.
Each computer can operate as both a NFS server, and as an NFS client.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_SERVER_IO_RATE_CUM
----------------------------------
The number of NFS IOs per second the local machine has completed as an NFS 
server over the cumulative collection time.  This number represents physical 
IOs received by the server in contrast to a call which is an attempt to 
initiate these operations.
Each computer can operate as both a NFS server, and as an NFS client.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS IOs include reads and writes from successful calls to getattr, setattr, 
lookup, read, readdir, readlink, write, and writecache.


GBL_NFS_SERVER_READ_RATE
----------------------------------
The number of NFS “read” operations per second the system processed as an NFS 
server during the interval.
 NFS Version 2 read operations consist of getattr, lookup, readlink, readdir, 
null, root, statfs, and read.
NFS Version 3 read operations consist of getattr, lookup, access, readlink, 
read, readdir, readdirplus, fsstat, fsinfo, and null.


GBL_NFS_SERVER_READ_RATE_CUM
----------------------------------
The average number of NFS “read” operations per second the system processed 
as an NFS server over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS Version 2 read operations consist of getattr, lookup, readlink, readdir, 
null, root, statfs, and read.
NFS Version 3 read operations consist of getattr, lookup, access, readlink, 
read, readdir, readdirplus, fsstat, fsinfo, and null.


GBL_NFS_SERVER_WRITE_RATE
----------------------------------
The number of NFS “write” operations per second the system processed as an 
NFS server during the interval.
 NFS Version 2 write operations consist of setattr, write, writecache, 
create, remove, rename, link, symlink, mkdir, and rmdir.
NFS Version 3 write operations consist of setattr, write, create, mkdir, 
symlink, mknod, remove, rmdir, rename, link, pathconf, and commit.


GBL_NFS_SERVER_WRITE_RATE_CUM
----------------------------------
The average number of NFS “write” operations per second the system processed 
as an NFS server over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 NFS Version 2 write operations consist of setattr, write, writecache, 
create, remove, rename, link, symlink, mkdir, and rmdir.
NFS Version 3 write operations consist of setattr, write, create, mkdir, 
symlink, mknod, remove, rmdir, rename, link, pathconf, and commit.


GBL_NODENAME
----------------------------------
On Unix systems, this is the name of the computer as returned by the command 
“uname -n” (that is, the string returned from the “hostname” program).
On Windows, this is the name of the computer as returned by GetComputerName.


GBL_NUM_ACTIVE_LS
----------------------------------
This indicates the number of LS hosted in a system that are active . If Perf 
Agent is installed in a guest or in a standalone system this value will be 0.
 On Solaris non-global zones, this metric shows value as 0.


GBL_NUM_APP
----------------------------------
The number of applications defined in the parm file plus one (for “other”).
The application called “other” captures all other processes not defined in 
the parm file.
You can define up to 999 applications.


GBL_NUM_CPU
----------------------------------
The number of physical CPUs on the system. This includes all CPUs, either 
online or offline.  For HP-UX and certain versions of Linux, the sar(1M) 
command allows you to check the status of the system CPUs.  For SUN and DEC, 
the commands psrinfo(1M) and psradm(1M) allow you to check or change the 
status of the system CPUs.  For AIX, this metric indicates the maximum number 
of CPUs the system ever had.
On a logical system, this metric indicates the number of virtual CPUs 
configured.  When hardware threads are enabled, this metric indicates the 
number of logical processors.
 On Solaris non-global zones with Uncapped CPUs, this metric shows data from 
the global zone.
 On AIX System WPARs, this metric value is identical to the value on AIX 
Global Environment.
 The Linux kernel currently doesn’t provide any metadata information for 
disabled CPUs. This means that there is no way to find out types, speeds, as 
well as hardware IDs or any other information that is used to determine the 
number of cores, the number of threads, the HyperThreading state, etc...  If 
the agent (or Glance) is started while some of the CPUs are disabled, some of 
these metrics will be “na”, some will be based on what is visible at startup 
time. All information will be updated if/when additional CPUs are enabled and 
information about them becomes available. The configuration counts will 
remain at the highest discovered level (i.e. if CPUs are then disabled, the 
maximum number of CPUs/cores/etc... will remain at the highest observed 
level). It is recommended that the agent be started with all CPUs enabled.


GBL_NUM_CPU_CORE
----------------------------------
This metric provides the total number of CPU cores on a physical system.  On 
VMs, this metric shows information according to resources available on that 
VM.  On non HP-UX system, this metric is equivalent to active CPU cores.  On 
AIX System WPARs, this metric value is identical to the value on AIX Global 
Environment.  On Windows, this metric will be “na” on Windows Server 2003 
Itanium systems.
 The Linux kernel currently doesn’t provide any metadata information for 
disabled CPUs. This means that there is no way to find out types, speeds, as 
well as hardware IDs or any other information that is used to determine the 
number of cores, the number of threads, the HyperThreading state, etc...  If 
the agent (or Glance) is started while some of the CPUs are disabled, some of 
these metrics will be “na”, some will be based on what is visible at startup 
time. All information will be updated if/when additional CPUs are enabled and 
information about them becomes available. The configuration counts will 
remain at the highest discovered level (i.e. if CPUs are then disabled, the 
maximum number of CPUs/cores/etc... will remain at the highest observed 
level). It is recommended that the agent be started with all CPUs enabled.


GBL_NUM_DISK
----------------------------------
The number of disks on the system.  Only local disk devices are counted in 
this metric.
On HP-UX, this is a count of the number of disks on the system that have ever 
had activity over the cumulative collection time.
 On Solaris non-global zones, this metric shows value as 0.
 On AIX System WPARs, this metric shows value as 0.


GBL_NUM_HBA
----------------------------------
The number of Host Bus adaptors on the system.


GBL_NUM_LS
----------------------------------
This indicates the number of LS hosted in a system. If Perf Agent is 
installed in a guest or in a standalone system this value will be 0.
 On Solaris non-global zones, this metric shows value as 0.


GBL_NUM_LV
----------------------------------



GBL_NUM_NETWORK
----------------------------------
The number of network interfaces on the system.  This includes the loopback 
interface.  On certain platforms, this also include FDDI, Hyperfabric, ATM, 
Serial Software interfaces such as SLIP or PPP, and Wide Area Network 
interfaces (WAN) such as ISDN or X.25.  The “netstat -i” command also 
displays the list of network interfaces on the system.


GBL_NUM_SOCKET
----------------------------------
The number of physical cpu sockets on the system.  On VMs, this metric shows 
information according to resources available on that VM.
On Windows, this metric will be “na” on Windows Server 2003 Itanium systems.


GBL_NUM_SWAP
----------------------------------
The number of configured swap areas.


GBL_NUM_THREAD
----------------------------------
The total number of threads present during this interval.


GBL_NUM_THREAD_ACTIVE
----------------------------------
The total number of threads active during this interval.


GBL_NUM_THREAD_COMPLETED
----------------------------------
The total number of new threads completed during this interval.


GBL_NUM_THREAD_NEW
----------------------------------
The total number of new threads spawned during this interval.


GBL_NUM_TT
----------------------------------
The number of unique Transaction Tracker (TT) transactions that have been 
registered on this system.


GBL_NUM_USER
----------------------------------
The number of users logged in at the time of the interval sample.  This is 
the same as the command “who | wc -l”.
For Unix systems, the information for this metric comes from the utmp file 
which is updated by the login command.  For more information, read the man 
page for utmp.  Some applications may create users on the system without 
using login and updating the utmp file.  These users are not reflected in 
this count.
This metric can be a general indicator of system usage.  In a networked 
environment, however, users may maintain inactive logins on several systems.
On Windows, the information for this metric comes from the Server Sessions 
counter in the Performance Libraries Server object.  It is a count of the 
number of users using this machine as a file server.


GBL_NUM_VG
----------------------------------
The number of available volume groups. On disabling the Logical Volume Class 
of metrics, this value will be reported as NA


GBL_OSKERNELTYPE
----------------------------------
This indicates the word size of the current kernel on the system.  Some 
hardware can load the 64-bit kernel or the 32-bit kernel.


GBL_OSKERNELTYPE_INT
----------------------------------
This indicates the word size of the current kernel on the system.  Some 
hardware can load the 64-bit kernel or the 32-bit kernel.


GBL_OSNAME
----------------------------------
A string representing the name of the operating system.  On Unix systems, 
this is the same as the output from the “uname -s” command.


GBL_OSRELEASE
----------------------------------
The current release of the operating system.
On most Unix systems, this is same as the output from the “uname -r” command.
On AIX, this is the actual patch level of the operating system. This is 
similar to what is returned by the command “lslpp -l bos.rte” as the most 
recent level of the COMMITTED Base OS Runtime. For example, “5.2.0”.


GBL_OSVERSION
----------------------------------
A string representing the version of the operating system.  This is the same 
as the output from the “uname -v” command.  This string is limited to 20 
characters, and as a result, the complete version name might be truncated.
On Windows, this is a string representing the service pack installed on the 
operating system.


GBL_PRI_QUEUE
----------------------------------
The average number of processes or kernel threads blocked on PRI (waiting for 
their priority to become high enough to get the CPU) during the interval.
To determine if the CPU is a bottleneck, compare this metric with 
GBL_CPU_TOTAL_UTIL.  If GBL_CPU_TOTAL_UTIL is near 100 percent and 
GBL_PRI_QUEUE is greater than three, there is a high probability of a CPU 
bottleneck.
This is calculated as the accumulated time that all processes or kernel 
threads spent blocked on PRI divided by the interval time.
 HP-UX RUN/PRI/CPU Queue differences for multi-cpu systems:
For example, let’s assume we’re using a system with eight processors.  We 
start eight CPU intensive threads that consume almost all of the CPU 
resources.  The approximate values shown for the CPU related queue metrics 
would be:

  GBL_RUN_QUEUE = 1.0
  GBL_PRI_QUEUE = 0.1
  GBL_CPU_QUEUE = 1.0
Assume we start an additional eight CPU intensive threads.  The approximate 
values now shown are:

  GBL_RUN_QUEUE = 2.0
  GBL_PRI_QUEUE = 8.0
  GBL_CPU_QUEUE = 16.0
At this point, we have sixteen CPU intensive threads running on the eight 
processors.  Keeping the definitions of the three queue metrics in mind, the 
run queue is 2 (that is, 16 / 8); the pri queue is 8 (only half of the 
threads can be active at any given time); and the cpu queue is 16 (half of 
the threads waiting in the cpu queue that are ready to run, plus one for each 
active thread).
This illustrates that the run queue is the average of number of threads 
waiting in the runqueue for all processors; the pri queue is the number of 
threads that are blocked on “PRI” (priority); and the cpu queue is the number 
of threads in the cpu queue that are ready to run, including the threads 
using the CPU.
Note that if the value for GBL_PRI_QUEUE greatly exceeds the value for 
GBL_RUN_QUEUE, this may be a side-effect of the measurement interface having 
lost trace data.  In this case, check the value of the 
GBL_LOST_MI_TRACE_BUFFERS metric.  If there has been buffer loss, you can 
correct the value of GBL_PRI_QUEUE by restarting the midaemon and the 
performance tools.  You can use the /opt/perf/bin/midaemon -T command to 
force immediate shutdown of the measurement interface.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The Global QUEUE metrics, which are based on block states, represent the 
average number of process or kernel thread counts, not actual queues.
The Global WAIT PCT metrics, which are also based on block states, represent 
the percentage of all processes or kernel threads that were alive on the 
system.
No direct comparison is reasonable with the Application WAIT PCT metrics 
since they represent percentages within the context of a specific application 
and cannot be summed or compared with global values easily.  In addition, the 
sum of each Application WAIT PCT for all applications will not equal 100% 
since these values will vary greatly depending on the number of processes or 
kernel threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


GBL_PRI_WAIT_PCT
----------------------------------
The percentage of time processes or kernel threads were blocked on PRI 
(waiting for their priority to become high enough to get the CPU) during the 
interval.
This is calculated as the accumulated time that all processes or kernel 
threads spent blocked on PRI divided by the accumulated time that all 
processes or kernel threads were alive during the interval.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The Global QUEUE metrics, which are based on block states, represent the 
average number of process or kernel thread counts, not actual queues.
The Global WAIT PCT metrics, which are also based on block states, represent 
the percentage of all processes or kernel threads that were alive on the 
system.
No direct comparison is reasonable with the Application WAIT PCT metrics 
since they represent percentages within the context of a specific application 
and cannot be summed or compared with global values easily.  In addition, the 
sum of each Application WAIT PCT for all applications will not equal 100% 
since these values will vary greatly depending on the number of processes or 
kernel threads in each application.
For example, the GBL_DISK_SUBSYSTEM_QUEUE values can be low, while the 
APP_DISK_SUBSYSTEM_WAIT_PCT values can be high.  In this case, there are many 
processes on the system, but there are only a very small number of processes 
in the specific application that is being examined and there is a high 
percentage of those few processes that are blocked on the disk I/O subsystem.


GBL_PRI_WAIT_TIME
----------------------------------
The accumulated time, in seconds, that all processes or kernel threads were 
blocked on PRI (waiting for their priority to become high enough to get the 
CPU) during the interval.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.


GBL_PROC_SAMPLE
----------------------------------
The number of process data samples that have been averaged into global 
metrics (such as GBL_ACTIVE_PROC) that are based on process samples.


GBL_RUN_QUEUE
----------------------------------
On UNIX systems except Linux, this is the average number of threads waiting 
in the runqueue over the interval. The average is computed against the number 
of times the run queue is occupied instead of time. The average is updated by 
the kernel at a fine grain interval, only when the run queue is occupied. It 
is not averaged against the interval and can therefore be misleading for long 
intervals when the run queue is empty most or part of the time. This value 
matches runq-sz reported by the “sar -q” command. The GBL_LOADAVG* metrics 
are better indicators of run queue pressure.
On Linux and Windows, this is instantaneous value obtained at the time of 
logging. On Linux, it shows the number of threads waiting in the runqueue.  
On Windows, it shows the Processor Queue Length.
On Unix systems, GBL_RUN_QUEUE will typically be a small number.  Larger than 
normal values for this metric indicate CPU contention among threads.  This 
CPU bottleneck is also normally indicated by 100 percent GBL_CPU_TOTAL_UTIL.  
It may be OK to have GBL_CPU_TOTAL_UTIL be 100 percent if no other threads 
are waiting for the CPU.  However, if GBL_CPU_TOTAL_UTIL is 100 percent and 
GBL_RUN_QUEUE is greater than the number of processors, it indicates a CPU 
bottleneck.
On Windows, the Processor Queue reflects a count of process threads which are 
ready to execute.  A thread is ready to execute (in the Ready state) when the 
only resource it is waiting on is the processor.  The Windows operating 
system itself has many system threads which intermittently use small amounts 
of processor time.  Several low priority threads intermittently wake up and 
execute for very short intervals.  Depending on when the collection process 
samples this queue, there may be none or several of these low-priority 
threads trying to execute.  Therefore, even on an otherwise quiescent system, 
the Processor Queue Length can be high.  High values for this metric during 
intervals where the overall CPU utilization (gbl_cpu_total_util) is low do 
not indicate a performance bottleneck.  Relatively high values for this 
metric during intervals where the overall CPU utilization is near 100% can 
indicate a CPU performance bottleneck.
 HP-UX RUN/PRI/CPU Queue differences for multi-cpu systems:
For example, let’s assume we’re using a system with eight processors.  We 
start eight CPU intensive threads that consume almost all of the CPU 
resources.  The approximate values shown for the CPU related queue metrics 
would be:

  GBL_RUN_QUEUE = 1.0
  GBL_PRI_QUEUE = 0.1
  GBL_CPU_QUEUE = 1.0
Assume we start an additional eight CPU intensive threads.  The approximate 
values now shown are:

  GBL_RUN_QUEUE = 2.0
  GBL_PRI_QUEUE = 8.0
  GBL_CPU_QUEUE = 16.0
At this point, we have sixteen CPU intensive threads running on the eight 
processors.  Keeping the definitions of the three queue metrics in mind, the 
run queue is 2 (that is, 16 / 8); the pri queue is 8 (only half of the 
threads can be active at any given time); and the cpu queue is 16 (half of 
the threads waiting in the cpu queue that are ready to run, plus one for each 
active thread).
This illustrates that the run queue is the average of number of threads 
waiting in the runqueue for all processors; the pri queue is the number of 
threads that are blocked on “PRI” (priority); and the cpu queue is the number 
of threads in the cpu queue that are ready to run, including the threads 
using the CPU.
 On Solaris non-global zones, this metric shows data from the global zone.


GBL_RUN_QUEUE_CUM
----------------------------------
On UNIX systems except Linux, this is the average number of threads waiting 
in the runqueue over the cumulative collection time.
On Linux, this is approximately the number of threads waiting in the runqueue 
over the cumulative collection time.
On Windows, this is approximately the average Processor Queue Length over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
In this case, this metric is a cumulative average of data that was collected 
as an average.  This metric is derived from GBL_RUN_QUEUE.

 HP-UX RUN/PRI/CPU Queue differences for multi-cpu systems:
For example, let’s assume we’re using a system with eight processors.  We 
start eight CPU intensive threads that consume almost all of the CPU 
resources.  The approximate values shown for the CPU related queue metrics 
would be:

  GBL_RUN_QUEUE = 1.0
  GBL_PRI_QUEUE = 0.1
  GBL_CPU_QUEUE = 1.0
Assume we start an additional eight CPU intensive threads.  The approximate 
values now shown are:

  GBL_RUN_QUEUE = 2.0
  GBL_PRI_QUEUE = 8.0
  GBL_CPU_QUEUE = 16.0
At this point, we have sixteen CPU intensive threads running on the eight 
processors.  Keeping the definitions of the three queue metrics in mind, the 
run queue is 2 (that is, 16 / 8); the pri queue is 8 (only half of the 
threads can be active at any given time); and the cpu queue is 16 (half of 
the threads waiting in the cpu queue that are ready to run, plus one for each 
active thread).
This illustrates that the run queue is the average of number of threads 
waiting in the runqueue for all processors; the pri queue is the number of 
threads that are blocked on “PRI” (priority); and the cpu queue is the number 
of threads in the cpu queue that are ready to run, including the threads 
using the CPU.


GBL_RUN_QUEUE_HIGH
----------------------------------
On UNIX systems except Linux, this is the highest value of average number of 
threads waiting in the runqueue during any interval over the cumulative 
collection time.
On Linux, this is the highest value of number of threads waiting in the 
runqueue during any interval over the cumulative collection time.


GBL_SAMPLE
----------------------------------
The number of data samples (intervals) that have occurred over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_SERIALNO
----------------------------------
On HP-UX, this is the ID number of the computer as returned by the command 
“uname -i”.  If this value is not available, an empty string is returned.
On SUN, this is the ASCII representation of the hardware-specific serial 
number.  This is printed in hexadecimal as presented by the “hostid” command 
when possible.  If that is not possible, the decimal format is provided 
instead.
On AIX, this is the machine ID number as returned by the command “uname -m”.  
This number has the form xxyyyyyymmss.  For the RISC System/6000, “xx” 
position is always 00.  The “yyyyyy” positions contain the unique ID number 
for the central processing unit (cpu).  While “mm” represents the model 
number, and “ss” is the submodel number (always 00).
On Linux, this is the ASCII representation of the hardware-specific serial 
number, as returned by the command “hostid”.


GBL_STARTDATE
----------------------------------
The date that the collector started.


GBL_STARTED_PROC
----------------------------------
The number of processes that started during the interval.


GBL_STARTED_PROC_RATE
----------------------------------
The number of processes that started per second during the interval.


GBL_STARTTIME
----------------------------------
The time of day that the collector started.


GBL_STATDATE
----------------------------------
The date at the end of the interval, based on local time.


GBL_STATTIME
----------------------------------
An ASCII string representing the time at the end of the interval, based on 
local time.


GBL_SWAP_SPACE_AVAIL
----------------------------------
The total amount of potential swap space, in MB.
On HP-UX, this is the sum of the device swap areas enabled by the swapon 
command, the allocated size of any file system swap areas, and the allocated 
size of pseudo swap in memory if enabled.  Note that this is potential swap 
space.  This is the same as (AVAIL: total) as reported by the “swapinfo -mt” 
command.
On SUN, this is the total amount of swap space available from the physical 
backing store devices (disks) plus the amount currently available from main 
memory.  This is the same as (used + available) /1024, reported by the “swap 
-s” command.
On Linux, this is same as (Swap: total) as reported by the “free -m” command.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_SWAP_SPACE_AVAIL_KB
----------------------------------
The total amount of potential swap space, in KB.
On HP-UX, this is the sum of the device swap areas enabled by the swapon 
command, the allocated size of any file system swap areas, and the allocated 
size of pseudo swap in memory if enabled.  Note that this is potential swap 
space.  Since swap is allocated in fixed (SWCHUNK) sizes, not all of this 
space may actually be usable.  For example, on a 61MB disk using 2 MB swap 
size allocations, 1 MB remains unusable and is considered wasted space.
On HP-UX, this is the same as (AVAIL: total) as reported by the “swapinfo -t” 
command.
On SUN, this is the total amount of swap space available from the physical 
backing store devices (disks) plus the amount currently available from main 
memory.  This is the same as (used + available)/1024, reported by the “swap -
s” command.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_SWAP_SPACE_DEVICE_AVAIL
----------------------------------
The amount of swap space configured on disk devices exclusively as swap space 
(in MB).
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.


GBL_SWAP_SPACE_DEVICE_UTIL
----------------------------------
On HP-UX, this is the percentage of device swap space currently in use of the 
total swap space available.  This does not include file system or remote swap 
space.
On HP-UX, note that available swap is only potential swap space.  Since swap 
is allocated in fixed (SWCHUNK) sizes, not all of this space may actually be 
usable.  For example, on a 61 MB disk using 2 MB swap size allocations, 1 MB 
remains unusable and is considered wasted space.  Consequently, 100 percent 
utilization on a single device is not always obtainable.  The wasted swap 
space, and the remainder of allocated SWCHUNKs that have not been used is 
what is reported in the hold field of the /usr/sbin/swapinfo command.
On HP-UX, when compared to the “swapinfo -mt” command results, this is 
calculated as:

  Util = ((USED: dev) sum
    / (AVAIL: total)) * 100
On SUN, this is the percentage of total system device swap space currently in 
use.  This metric only gives the percentage of swap space used from the 
available physical swap device space, and does not include the memory that 
can be used for swap.  (On SunOS 5.X, the virtual swap swapfs can allocate 
swap space from memory.)
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.


GBL_SWAP_SPACE_USED
----------------------------------
The amount of swap space used, in MB.
On HP-UX, “Used” indicates written to disk (or locked in memory), rather than 
reserved.  This is the same as (USED: total - reserve) as reported by the 
“swapinfo -mt” command.
On SUN, “Used” indicates amount written to disk (or locked in memory), rather 
than reserved.  Swap space is reserved (by decrementing a counter) when 
virtual memory for a program is created.  This is the same as (bytes 
allocated)/1024, reported by the “swap -s” command.
On Linux, this is same as (Swap: used) as reported by the “free -m” command.
 On AIX System WPARs, this metric is NA.
 On Solaris non-global zones, this metric is N/A.  On Unix systems, this 
metric is updated every 30 seconds or the sampling interval, whichever is 
greater.


GBL_SWAP_SPACE_USED_UTIL
----------------------------------
This is the percentage of swap space used.
On HP-UX, “Used %” indicates percentage of swap space written to disk (or 
locked in memory), rather than reserved. This is the same as percentage of 
((USED: total - reserve)/total)*100, as reported by the “swapinfo -mt” 
command.
On SUN, “Used %” indicates percentage of swap space written to disk (or 
locked in memory), rather than reserved. Swap space is reserved (by 
decrementing a counter) when virtual memory for a program is created.  This 
is the same as  percentage of ((bytes allocated)/total)*100, reported by the 
“swap -s” command.
 On SUN, global swap space is tracked through the operating system.  Device 
swap space is tracked through the devices.  For this reason, the amount of 
swap space used may differ between the global and by-device metrics.  
Sometimes pages that are marked to be swapped to disk by the operating system 
are never swapped.  The operating system records this as used swap space, but 
the devices do not, since no physical IOs occur.  (Metrics with the prefix 
“GBL” are global and metrics with the prefix “BYSWP” are by device.)
On Linux, this is same as percentage of ((Swap: used)/total)*100, as reported 
by the “free -m” command.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.


GBL_SWAP_SPACE_UTIL
----------------------------------
The percent of available swap space that was being used by running processes 
in the interval.
On Windows, this is the percentage of virtual memory, which is available to 
user processes, that is in use at the end of the interval.  It is not an 
average over the entire interval.  It reflects the ratio of committed memory 
to the current commit limit.  The limit may be increased by the operating 
system if the paging file is extended.  This is the same as (Committed Bytes 
/ Commit Limit) * 100 when comparing the results to Performance Monitor.
On HP-UX, swap space must be reserved (but not allocated) before virtual 
memory can be created.  If all of available swap is reserved, then no new 
processes or virtual memory can be created.  Swap space locations are 
actually assigned (used) when a page is actually written to disk or locked in 
memory (pseudo swap in memory).  This is the same as (PCT USED: total) as 
reported by the “swapinfo -mt” command.
On Unix systems, this metric is a measure of capacity rather than 
performance.  As this metric nears 100 percent, processes are not able to 
allocate any more memory and new processes may not be able to run.  Very low 
swap utilization values may indicate that too much area has been allocated to 
swap, and better use of disk space could be made by reallocating some swap 
partitions to be user filesystems.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.
 On AIX System WPARs, this metric is NA.


GBL_SWAP_SPACE_UTIL_CUM
----------------------------------
The average percentage of available swap space currently in use (has memory 
belonging to processes paged or swapped out on it) over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, note that available swap is only potential swap space.  Since swap 
is allocated in fixed (SWCHUNK) sizes, not all of this space may actually be 
usable.  For example, on a 61 MB disk using 2 MB swap size allocations, 1 MB 
remains unusable and is considered wasted space.  Consequently, 100 percent 
utilization on a single device is not always obtainable.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


GBL_SWAP_SPACE_UTIL_HIGH
----------------------------------
The highest average percentage of available swap space currently in use (has 
memory belonging to processes paged or swapped out on it) in any interval 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, note that available swap is only potential swap space.  Since swap 
is allocated in fixed (SWCHUNK) sizes, not all of this space may actually be 
usable.  For example, on a 61 MB disk using 2 MB swap size allocations, 1 MB 
remains unusable and is considered wasted space.  Consequently, 100 percent 
utilization on a single device is not always obtainable.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


GBL_SYSCALL
----------------------------------
The number of system calls during the interval.
High system call rates are normal on busy systems, especially with IO 
intensive applications.  Abnormally high system call rates may indicate 
problems such as a “hung” terminal that is stuck in a loop generating read 
system calls.


GBL_SYSCALL_RATE
----------------------------------
The average number of system calls per second during the interval.
High system call rates are normal on busy systems, especially with IO 
intensive applications.  Abnormally high system call rates may indicate 
problems such as a “hung” terminal that is stuck in a loop generating read 
system calls.
On HP-UX, system call rates affect the overhead of the midaemon.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.
On HP-UX, compare this metric to GBL_DISK_LOGL_IO_RATE to see if high system 
callrates correspond to high disk IO.  GBL_CPU_SYSCALL_UTIL shows the CPU 
utilization due to processing system calls.


GBL_SYSCALL_RATE_CUM
----------------------------------
The average number of system calls per second over the cumulative collection 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


GBL_SYSCALL_RATE_HIGH
----------------------------------
The highest number of system calls per second during any interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


GBL_SYSCALL_READ
----------------------------------
The number of read system calls made during the interval.
This includes reads to all devices including disks, terminals and tapes.


GBL_SYSCALL_READ_CUM
----------------------------------
The total number of read system calls made over the cumulative collection 
time. This includes reads to all devices including disks, terminals and 
tapes.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_SYSCALL_READ_PCT
----------------------------------
The percentage of read system calls of the total system read and write system 
calls during the interval.


GBL_SYSCALL_READ_RATE
----------------------------------
The average number of read system calls per second made during the interval.
This includes reads to all devices including disks, terminals and tapes.  
This is the same as “sread/s” reported by the sar -c command.


GBL_SYSCALL_READ_RATE_CUM
----------------------------------
The average number of read system calls per second made over the cumulative 
collection time.  This includes reads to all devices including disks, 
terminals, and tapes.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


GBL_SYSCALL_WRITE
----------------------------------
The number of write system calls made during the interval.


GBL_SYSCALL_WRITE_PCT
----------------------------------
The percentage of write system calls of the total system read and write 
system calls during the interval.


GBL_SYSCALL_WRITE_RATE
----------------------------------
The average number of write system calls per second made during the interval.
This includes writes to all devices including disks, terminals and tapes.


GBL_SYSTEM_ID
----------------------------------
The network node hostname of the system.  This is the same as the output from 
the “uname -n” command.
On Windows, the name obtained from GetComputerName.


GBL_SYSTEM_TYPE
----------------------------------
On Unix systems, this is either the model of the system or the instruction 
set architecture of the system.
On Windows, this is the processor architecture of the system.


GBL_SYSTEM_UPTIME_HOURS
----------------------------------
The time, in hours, since the last system reboot.


GBL_SYSTEM_UPTIME_SECONDS
----------------------------------
The time, in seconds, since the last system reboot.


GBL_THRESHOLD_PROCCPU
----------------------------------
The process CPU threshold specified in the parm file.


GBL_THRESHOLD_PROCDISK
----------------------------------
The process disk threshold specified in the parm file.


GBL_THRESHOLD_PROCIO
----------------------------------
The process IO threshold specified in the parm file.


GBL_THRESHOLD_PROCMEM
----------------------------------
The process memory threshold specified in the parm file.


GBL_TT_OVERFLOW_COUNT
----------------------------------
The number of new transactions that could not be measured because the 
Measurement Processing Daemon’s (midaemon) Measurement Performance Database 
is full.  If this happens, the default Measurement Performance Database size 
is not large enough to hold all of the registered transactions on this 
system.  This can be remedied by stopping and restarting the midaemon process 
using the -smdvss option to specify a larger Measurement Performance Database 
size.  The current Measurement Performance Database size can be checked using 
the midaemon -sizes option.


GBL_ZOMBIE_PROC
----------------------------------
The total number of zombie process present during the interval.


LVDETAIL_LABEL
----------------------------------
The type of entry this volume group or logical volume is associated with, 
which can be a device, partition, file system, logical volume, or volume 
group.


LVDETAIL_NAME
----------------------------------
The name of the device, partition, file system, logical volume, or volume 
group this volume group or logical volume is associated with.


LV_DEVNO
----------------------------------
Major / Minor number of this logical volume.


LV_DIRNAME
----------------------------------
The path name of this logical volume or volume/disk group.


LV_GROUP_NAME
----------------------------------
On HP-UX, this is the name of this volume/disk group associated with a 
logical volume.
On SUN and AIX, this is the name of this volume group associated with a 
logical volume.  On SUN, this metric is applicable only for the Veritas LVM.
 On HP-UX 11i and beyond, data is available from VERITAS Volume Manager 
(VxVM).  LVM (Logical Volume Manager) uses the terminology “volume group” to 
describe a set of related volumes.  VERITAS Volume Manager uses the 
terminology “disk group” to describe a collection of VM disks.  For 
additional information on VERITAS Volume Manager, see vxintro(1M).


LV_PHYSLV_SIZE
----------------------------------
On SUN, this is the physical size in MBs of this logical volume or 
metadevice.  This metric is reported as “na” for volume groups since it is 
not applicable.
On AIX, this is the physical size in MBs of this logical volume.


LV_READ_BYTE_RATE
----------------------------------
The number of physical KBs per second read from this logical volume during 
the interval.
Note that bytes read from the buffer cache are not included in this 
calculation.  The number of physical KBs per second read from this logical 
volume during the interval.


LV_READ_BYTE_RATE_CUM
----------------------------------
The average number of physical KBs per second read from this logical volume 
over the cumulative collection time, or since the last configuration change.
Note that bytes read from the buffer cache are not included in this 
calculation.
On SUN, DiskSuite metadevices are not supported.  This metric is reported as 
“na” for volume groups since it is not applicable.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


LV_READ_RATE
----------------------------------
The number of physical reads per second for this logical volume during the 
interval.


LV_READ_RATE_CUM
----------------------------------
The average number of physical reads per second for this volume over the 
cumulative collection time, or since the last configuration change.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


LV_SPACE_UTIL
----------------------------------
Percentage of the logical volume file system space in use during the 
interval.
A value of “na” is displayed for volume groups and logical volumes which have 
no mounted filesystem.


LV_TYPE
----------------------------------
Either “G” or “V”, indicating either a volume/disk group (“G”) or a logical 
volume (“V”).  On SUN, it can also be a Disk Suite meta device (“S”).
 On HP-UX 11i and beyond, data is available from VERITAS Volume Manager 
(VxVM).  LVM (Logical Volume Manager) uses the terminology “volume group” to 
describe a set of related volumes.  VERITAS Volume Manager uses the 
terminology “disk group” to describe a collection of VM disks.  For 
additional information on VERITAS Volume Manager, see vxintro(1M).


LV_WRITE_BYTE_RATE
----------------------------------
The number of KBs per second written to this logical volume during the 
interval.  The number of KBs per second written to this logical volume during 
the interval.


LV_WRITE_BYTE_RATE_CUM
----------------------------------
The average number of KBs per second written to this logical volume over the 
cumulative collection time, or since the last configuration change.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
The average number of KBs per second written to this logical volume over the 
cumulative collection time, or since the last configuration change.


LV_WRITE_RATE
----------------------------------
The number of physical writes per second to this logical volume during the 
interval.


LV_WRITE_RATE_CUM
----------------------------------
The average number of physical writes per second to this volume over the 
cumulative collection time, or since the last configuration change.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


PROCSYSCALL_CALL_COUNT
----------------------------------
The number of system calls made to this function by this process during the 
interval.


PROCSYSCALL_CALL_COUNT_CUM
----------------------------------
The number of system calls made by this process to this function during the 
time it has been enabled for system call profiling.


PROCSYSCALL_CALL_ID
----------------------------------
The ID number of the system call.  System calls are sequentially numbered 
starting with one.


PROCSYSCALL_CALL_NAME
----------------------------------
The system call name.


PROCSYSCALL_CALL_RATE
----------------------------------
The number of system calls per second made by this process to this function 
during the last interval.


PROCSYSCALL_CALL_RATE_CUM
----------------------------------
The average number of system calls per second made by this process to this 
function during the time it has been enabled for system call profiling.


PROCSYSCALL_INTERVAL
----------------------------------
The amount of time in the interval.


PROCSYSCALL_INTERVAL_CUM
----------------------------------
The time, in seconds, system call data has been collected for this process.


PROCSYSCALL_TOTAL_TIME
----------------------------------
The elapsed time, in seconds, this process was in this system call.  This 
value maybe greater then the interval time since the system call may have 
been started before the interval started.


PROCSYSCALL_TOTAL_TIME_CUM
----------------------------------
The total elapsed time, in seconds, that this process was in this system 
call.  This value maybe greater than the cumulative interval time since the 
system call may have been started before data collection.


PROC_APP_ID 
THREAD_APP_ID
----------------------------------
The ID number of the application to which the process (or kernel thread, if 
HP-UX/Linux Kernel 2.6 and above) belonged during the interval.
Application “other” always has an ID of 1.  There can be up to 999 user-
defined applications, which are defined in the parm file.


PROC_APP_NAME 
THREAD_APP_NAME
----------------------------------
The application name of a process (or kernel thread, if HP-UX/Linux Kernel 
2.6 and above).
Processes (or kernel threads, if HP-UX/Linux Kernel 2.6 and above) are 
assigned into application groups based upon rules in the parm file.  If a 
process does not fit any rules in this file, it is assigned to the 
application “other.”
The rules include decisions based upon pathname, user ID, priority, and so 
forth.  As these values change during the life of a process (or kernel 
thread, if HP-UX/Linux Kernel 2.6 and above), it is re-assigned to another 
application. This re-evaluation is done every measurement interval.


PROC_CHILD_CPU_SYS_MODE_UTIL 
THREAD_CHILD_CPU_SYS_MODE_UTIL
----------------------------------
The percentage of system time accumulated by this process’s children 
processes during the interval.
 On Unix systems, when a process terminates, its CPU counters (user and 
system) are accumulated in the parent’s “children times” counters. This 
occurs when the parent waits for (or reaps) the child. See getrusage(2).  If 
the process is an orphan process, its parent becomes the init(1m) process, 
and its CPU times will be accumulated to the init process upon termination. 
The PROC*_CHILD_* metrics attempt to report these counters in a meaningful 
way. If these counters were reported unconditionally as they are incremented, 
they would be misleading. For example, consider a shell process that forks 
another process and that process accumulates 100 minutes of CPU time. When 
that process terminates, the shell would report a huge child time utilization 
for that interval even though it was generally idle, waiting for that child 
to terminate. The child process was most likely already reported in previous 
intervals as it used the CPU time, and therefore it would be confusing to 
report this time in the parent. If, on the other hand, a process was 
continuously forking short-lived processes during the interval, it would be 
useful to report the CPU time used by those children processes. The simple 
algorithm chosen is to only report children times when their total CPU time 
is less than the process alive interval, and zero otherwise. It is not fool-
proof but it generally yields the right results, i.e., if a process reports 
high child time utilization for several intervals in a row, it could be a 
runaway forking process. An example of such a runaway process (or “fork 
bomb”) is:
    while true ; do ps -ef | grep something done
Moderate children times are also a useful way to identify daemons that rely 
on child processes, or, in the case of the init process it may indicate that 
many short-lived orphan processes are being created.
Note that this metric is only valid at the process level. It reports CPU time 
of processes forked and does not report on threads created by processes. The 
PROC*_CHILD* metrics have no meaning at the thread level, therefore the 
thread metric of the same name, on systems that report per-thread data, will 
show “na”.


PROC_CHILD_CPU_TOTAL_UTIL 
THREAD_CHILD_CPU_TOTAL_UTIL
----------------------------------
The percentage of system + user time accumulated by this process’s children 
processes during the interval.
 On Unix systems, when a process terminates, its CPU counters (user and 
system) are accumulated in the parent’s “children times” counters. This 
occurs when the parent waits for (or reaps) the child. See getrusage(2).  If 
the process is an orphan process, its parent becomes the init(1m) process, 
and its CPU times will be accumulated to the init process upon termination. 
The PROC*_CHILD_* metrics attempt to report these counters in a meaningful 
way. If these counters were reported unconditionally as they are incremented, 
they would be misleading. For example, consider a shell process that forks 
another process and that process accumulates 100 minutes of CPU time. When 
that process terminates, the shell would report a huge child time utilization 
for that interval even though it was generally idle, waiting for that child 
to terminate. The child process was most likely already reported in previous 
intervals as it used the CPU time, and therefore it would be confusing to 
report this time in the parent. If, on the other hand, a process was 
continuously forking short-lived processes during the interval, it would be 
useful to report the CPU time used by those children processes. The simple 
algorithm chosen is to only report children times when their total CPU time 
is less than the process alive interval, and zero otherwise. It is not fool-
proof but it generally yields the right results, i.e., if a process reports 
high child time utilization for several intervals in a row, it could be a 
runaway forking process. An example of such a runaway process (or “fork 
bomb”) is:
    while true ; do ps -ef | grep something done
Moderate children times are also a useful way to identify daemons that rely 
on child processes, or, in the case of the init process it may indicate that 
many short-lived orphan processes are being created.
Note that this metric is only valid at the process level. It reports CPU time 
of processes forked and does not report on threads created by processes. The 
PROC*_CHILD* metrics have no meaning at the thread level, therefore the 
thread metric of the same name, on systems that report per-thread data, will 
show “na”.


PROC_CHILD_CPU_USER_MODE_UTIL 
THREAD_CHILD_CPU_USER_MODE_UTIL
----------------------------------
The percentage of user time accumulated by this process’s children processes 
during the interval.
 On Unix systems, when a process terminates, its CPU counters (user and 
system) are accumulated in the parent’s “children times” counters. This 
occurs when the parent waits for (or reaps) the child. See getrusage(2).  If 
the process is an orphan process, its parent becomes the init(1m) process, 
and its CPU times will be accumulated to the init process upon termination. 
The PROC*_CHILD_* metrics attempt to report these counters in a meaningful 
way. If these counters were reported unconditionally as they are incremented, 
they would be misleading. For example, consider a shell process that forks 
another process and that process accumulates 100 minutes of CPU time. When 
that process terminates, the shell would report a huge child time utilization 
for that interval even though it was generally idle, waiting for that child 
to terminate. The child process was most likely already reported in previous 
intervals as it used the CPU time, and therefore it would be confusing to 
report this time in the parent. If, on the other hand, a process was 
continuously forking short-lived processes during the interval, it would be 
useful to report the CPU time used by those children processes. The simple 
algorithm chosen is to only report children times when their total CPU time 
is less than the process alive interval, and zero otherwise. It is not fool-
proof but it generally yields the right results, i.e., if a process reports 
high child time utilization for several intervals in a row, it could be a 
runaway forking process. An example of such a runaway process (or “fork 
bomb”) is:
    while true ; do ps -ef | grep something done
Moderate children times are also a useful way to identify daemons that rely 
on child processes, or, in the case of the init process it may indicate that 
many short-lived orphan processes are being created.
Note that this metric is only valid at the process level. It reports CPU time 
of processes forked and does not report on threads created by processes. The 
PROC*_CHILD* metrics have no meaning at the thread level, therefore the 
thread metric of the same name, on systems that report per-thread data, will 
show “na”.


PROC_CPU_ALIVE_SYS_MODE_UTIL 
THREAD_CPU_ALIVE_SYS_MODE_UTIL
----------------------------------
The total CPU time consumed by a process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) in system mode as a percentage of the time it is alive 
during the interval.  On platforms other than HPUX, If the ignore_mt flag is 
set(true) in parm file, this metric will report values normalized against the 
number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_ALIVE_TOTAL_UTIL 
THREAD_CPU_ALIVE_TOTAL_UTIL
----------------------------------
The total CPU time consumed by a process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) as a percentage of the time it is alive during the 
interval.  On platforms other than HPUX, If the ignore_mt flag is set(true) 
in parm file, this metric will report values normalized against the number of 
active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_ALIVE_USER_MODE_UTIL 
THREAD_CPU_ALIVE_USER_MODE_UTIL
----------------------------------
The total CPU time consumed by a process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) in user mode as a percentage of the time it is alive 
during the interval.  On platforms other than HPUX, If the ignore_mt flag is 
set(true) in parm file, this metric will report values normalized against the 
number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_LAST_USED 
THREAD_CPU_LAST_USED
----------------------------------
The ID number of the processor that last ran the process (or kernel thread, 
if HP-UX/Linux Kernel 2.6 and above).  For uni-processor systems, this value 
is always zero.
 On a threaded operating system, such as HP-UX 11.0 and beyond, this metric 
represents a kernel thread characteristic.  If this metric is reported for a 
process, the value for its last executing kernel thread is given.  For 
example, if a process has multiple kernel threads and kernel thread one is 
the last to execute during the interval, the metric value for kernel thread 
one is assigned to the process.


PROC_CPU_SWITCHES 
THREAD_CPU_SWITCHES
----------------------------------
The number of times the process or kernel thread was switched to another 
processor during the interval.  For uni-processor systems, this value is 
always zero.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.


PROC_CPU_SWITCHES_CUM 
THREAD_CPU_SWITCHES_CUM
----------------------------------
The number of times the process or kernel thread was switched to another 
processor over the cumulative collection time. For uni-processor systems, 
this value is always zero.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.


PROC_CPU_SYSCALL_TIME 
THREAD_CPU_SYSCALL_TIME
----------------------------------
The time, in seconds, that this process or kernel thread spent executing 
system calls in system mode, excluding interrupt or context processing, 
during the interval.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYSCALL_TIME_CUM 
THREAD_CPU_SYSCALL_TIME_CUM
----------------------------------
The time, in seconds, that this process or kernel thread spent executing 
system calls in system mode, excluding interrupt or context processing, over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYSCALL_UTIL 
THREAD_CPU_SYSCALL_UTIL
----------------------------------
The percentage of the total CPU time this process or kernel thread spent in 
system mode (excluding interrupt, context switch, trap, or vfault CPU) during 
the interval.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYSCALL_UTIL_CUM 
THREAD_CPU_SYSCALL_UTIL_CUM
----------------------------------
The average percentage of the total CPU time this process or kernel thread 
spent in system mode (excluding interrupt, context switch, trap, or vfault 
CPU) during the interval.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYS_MODE_TIME 
THREAD_CPU_SYS_MODE_TIME
----------------------------------
The CPU time in system mode in the context of the process (or kernel thread, 
if HP-UX/Linux Kernel 2.6 and above) during the interval.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYS_MODE_TIME_CUM 
THREAD_CPU_SYS_MODE_TIME_CUM
----------------------------------
The CPU time in system mode in the context of the process (or kernel thread, 
if HP-UX/Linux Kernel 2.6 and above) over the cumulative collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYS_MODE_UTIL 
THREAD_CPU_SYS_MODE_UTIL
----------------------------------
The percentage of time that the CPU was in system mode in the context of the 
process (or kernel thread, if HP-UX/Linux Kernel 2.6 and above) during the 
interval.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
High system mode CPU utilizations are normal for IO intensive programs.  
Abnormally high system CPU utilization can indicate that a hardware problem 
is causing a high interrupt rate.  It can also indicate programs that are not 
using system calls efficiently.
A classic “hung shell” shows up with very high system mode CPU because it 
gets stuck in a loop doing terminal reads (a system call) to a device that 
never responds.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_SYS_MODE_UTIL_CUM 
THREAD_CPU_SYS_MODE_UTIL_CUM
----------------------------------
The average percentage of time that the CPU was in system mode in the context 
of the process (or kernel thread, if HP-UX/Linux Kernel 2.6 and above) over 
the cumulative collection time.
 A process operates in either system mode (also called kernel mode on Unix or 
privileged mode on Windows) or user mode.  When a process requests services 
from the operating system with a system call, it switches into the machine’s 
privileged protection mode and runs in system mode.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_TOTAL_TIME 
THREAD_CPU_TOTAL_TIME
----------------------------------
The total CPU time, in seconds, consumed by a process (or kernel thread, if 
HP-UX/Linux Kernel 2.6 and above) during the interval.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
On HP-UX, the total CPU time is the sum of the CPU time components for a 
process or kernel thread, including system, user, context switch, interrupts 
processing, realtime, and nice utilization values.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_TOTAL_TIME_CUM 
THREAD_CPU_TOTAL_TIME_CUM
----------------------------------
The total CPU time consumed by a process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) over the cumulative collection time.  CPU time is in 
seconds unless otherwise specified.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
This is calculated as

  PROC_CPU_TOTAL_TIME_CUM =
    PROC_CPU_SYS_MODE_TIME_CUM +
    PROC_CPU_USER_MODE_TIME_CUM
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_TOTAL_UTIL 
THREAD_CPU_TOTAL_UTIL
----------------------------------
The total CPU time consumed by a process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) as a percentage of the total CPU time available during 
the interval.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
On HP-UX, the total CPU utilization is the sum of the CPU utilization 
components for a process or kernel thread, including system, user, context 
switch, interrupts processing, realtime, and nice utilization values.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).
 On platforms other than HPUX, If the ignore_mt flag is set(true) in parm 
file, this metric will report values normalized against the number of active 
cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_TOTAL_UTIL_CUM 
THREAD_CPU_TOTAL_UTIL_CUM
----------------------------------
The total CPU time consumed by a process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) as a percentage of the total CPU time available over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
On HP-UX, the total CPU utilization is the sum of the CPU utilization 
components for a process or kernel thread, including system, user, context 
switch, interrupts processing, realtime, and nice utilization values.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_USER_MODE_TIME 
THREAD_CPU_USER_MODE_TIME
----------------------------------
The time, in seconds, the process (or kernel threads, if HP-UX/Linux Kernel 
2.6 and above) was using the CPU in user mode during the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_USER_MODE_TIME_CUM 
THREAD_CPU_USER_MODE_TIME_CUM
----------------------------------
The time, in seconds, the process (or kernel thread, if HP-UX/Linux Kernel 
2.6 and above) was using the CPU in user mode over the cumulative collection 
time.  collection time.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.  On platforms other than HPUX, If the ignore_mt 
flag is set(true) in parm file, this metric will report values normalized 
against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_USER_MODE_UTIL 
THREAD_CPU_USER_MODE_UTIL
----------------------------------
The percentage of time the process (or kernel thread, if HP-UX/Linux Kernel 
2.6 and above) was using the CPU in user mode during the interval.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_CPU_USER_MODE_UTIL_CUM 
THREAD_CPU_USER_MODE_UTIL_CUM
----------------------------------
The average percentage of time the process (or kernel thread, if HP_UX/Linux 
Kernel 2.6 and above) was using the CPU in user mode over the cumulative 
collection time.
 User CPU is the time spent in user mode at a normal priority, at real-time 
priority (on HP-UX, AIX, and Windows systems), and at a nice priority.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Unlike the global and application CPU metrics, process CPU is not averaged 
over the number of processors on systems with multiple CPUs.  Single-threaded 
processes can use only one CPU at a time and never exceed 100% CPU 
utilization.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On multi-processor systems, processes which have component kernel threads 
executing simultaneously on different processors could have resource 
utilization sums over 100%.  If there is no CPU multi-threading, the maximum 
percentage is 100% times the number of Cores on the system. On a system with 
multi-threaded CPUs,  the maximum percentage is : 100 % times the number of 
cores X 2. ( i.e the total number of logical CPUs on the system).  On 
platforms other than HPUX, If the ignore_mt flag is set(true) in parm file, 
this metric will report values normalized against the number of active cores 
in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



PROC_DISK_PHYS_IO_RATE 
THREAD_DISK_PHYS_IO_RATE
----------------------------------
The average number of physical disk IOs per second made by the process or 
kernel thread during the interval.
 For processes which run for less than the measurement interval, this metric 
is normalized over the measurement interval.  For example, a process ran for 
1 second and did 50 IOs during its life.  If the measurement interval is 5 
seconds, it is reported as having done 10 IOs per second.  If the measurement 
interval is 60 seconds, it is reported as having done 50/60 or 0.83 IOs per 
second.
 “Disk” in this instance refers to any locally attached physical disk drives 
(that is, “spindles”) that may hold file systems and/or swap.  NFS mounted 
disks are not included in this list.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_IO_RATE_CUM 
THREAD_DISK_PHYS_IO_RATE_CUM
----------------------------------
The number of physical disk IOs per second made by the selected process or 
kernel thread over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 “Disk” in this instance refers to any locally attached physical disk drives 
(that is, “spindles”) that may hold file systems and/or swap.  NFS mounted 
disks are not included in this list.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_READ 
THREAD_DISK_PHYS_READ
----------------------------------
The number of physical reads made by (or for) a process or kernel thread 
during the last interval.
 “Disk” refers to a physical drive (that is, “spindle”), not a partition on a 
drive (unless the partition occupies the entire physical disk).  NFS mounted 
disks are not included in this list.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_READ_CUM 
THREAD_DISK_PHYS_READ_CUM
----------------------------------
The number of physical reads made by (or for) a process or kernel thread over 
the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 “Disk” refers to a physical drive (that is, “spindle”), not a partition on a 
drive (unless the partition occupies the entire physical disk).  NFS mounted 
disks are not included in this list.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_READ_RATE 
THREAD_DISK_PHYS_READ_RATE
----------------------------------
The number of physical reads per second made by (or for) a process or kernel 
thread during the interval.
 “Disk” refers to a physical drive (that is, “spindle”), not a partition on a 
drive (unless the partition occupies the entire physical disk).  NFS mounted 
disks are not included in this list.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_WRITE 
THREAD_DISK_PHYS_WRITE
----------------------------------
The number of physical writes made by (or for) a process or kernel thread 
during the last interval.
 “Disk” in this instance refers to any locally attached physical disk drives 
(that is, “spindles”) that may hold file systems and/or swap.  NFS mounted 
disks are not included in this list.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_WRITE_CUM 
THREAD_DISK_PHYS_WRITE_CUM
----------------------------------
The number of physical writes made by (or for) a process or kernel thread 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 “Disk” in this instance refers to any locally attached physical disk drives 
(that is, “spindles”) that may hold file systems and/or swap.  NFS mounted 
disks are not included in this list.
 On HP-UX, since this value is reported by the drivers, multiple physical 
requests that have been collapsed to a single physical operation (due to 
driver IO merging) are only counted once.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_PHYS_WRITE_RATE 
THREAD_DISK_PHYS_WRITE_RATE
----------------------------------
The number of physical writes per second made by (or for) a process or kernel 
thread during the interval.
 “Disk” refers to a physical drive (that is, “spindle”), not a partition on a 
drive (unless the partition occupies the entire physical disk).  NFS mounted 
disks are not included in this list.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_DISK_SUBSYSTEM_WAIT_PCT 
THREAD_DISK_SUBSYSTEM_WAIT_PCT
----------------------------------
The percentage of time the process or kernel thread was blocked on the disk 
subsystem (waiting for its file system IOs to complete) during the interval.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
A percentage of time spent in a wait state is calculated as the time a kernel 
thread (or all kernel threads of a process) spent waiting in this state, 
divided by the alive time of the kernel thread (or all kernel threads of the 
process) during the interval.
If this metric is reported for a kernel thread, the percentage value is for 
that single kernel thread.  If this metric is reported for a process, the 
percentage value is calculated with the sum of the wait and alive times of 
all of its kernel threads.
For example, if a process has 2 kernel threads, one sleeping for the entire 
interval and one waiting on terminal input for the interval, the process wait 
percent values will be 50% on Sleep and 50% on Terminal.  The kernel thread 
wait values will be 100% on Sleep for the first kernel thread and 100% on 
Terminal for the second kernel thread.
For another example, consider the same process as above, with 2 kernel 
threads, one of which was created half-way through the interval, and which 
then slept for the remainder of the interval.  The other kernel thread was 
waiting for terminal input for half the interval, then used the CPU actively 
for the remainder of the interval.  The process wait percent values will be 
33% on Sleep and 33% on Terminal (each one third of the total alive time).  
The kernel thread wait values will be 100% on Sleep for the first kernel 
thread and 50% on Terminal for the second kernel thread.


PROC_DISK_SUBSYSTEM_WAIT_PCT_CUM 
THREAD_DISK_SUBSYSTEM_WAIT_PCT_CUM
----------------------------------
The percentage of time the process or kernel thread was blocked on the disk 
subsystem (waiting for its file system IOs to complete) over the cumulative 
collection time.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
A percentage of time spent in a wait state is calculated as the time a kernel 
thread (or all kernel threads of a process) spent waiting in this state, 
divided by the alive time of the kernel thread (or all kernel threads of the 
process) during the interval.
If this metric is reported for a kernel thread, the percentage value is for 
that single kernel thread.  If this metric is reported for a process, the 
percentage value is calculated with the sum of the wait and alive times of 
all of its kernel threads.
For example, if a process has 2 kernel threads, one sleeping for the entire 
interval and one waiting on terminal input for the interval, the process wait 
percent values will be 50% on Sleep and 50% on Terminal.  The kernel thread 
wait values will be 100% on Sleep for the first kernel thread and 100% on 
Terminal for the second kernel thread.
For another example, consider the same process as above, with 2 kernel 
threads, one of which was created half-way through the interval, and which 
then slept for the remainder of the interval.  The other kernel thread was 
waiting for terminal input for half the interval, then used the CPU actively 
for the remainder of the interval.  The process wait percent values will be 
33% on Sleep and 33% on Terminal (each one third of the total alive time).  
The kernel thread wait values will be 100% on Sleep for the first kernel 
thread and 50% on Terminal for the second kernel thread.


PROC_DISK_SUBSYSTEM_WAIT_TIME 
THREAD_DISK_SUBSYSTEM_WAIT_TIME
----------------------------------
The time, in seconds, that the process or kernel thread was blocked on the 
disk subsystem (waiting for its file system IOs to complete) during the 
interval.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  If this 
metric is reported for a kernel thread, the value is the wait time of that 
single kernel thread.  If this metric is reported for a process, the value is 
the sum of the wait times of all of its kernel threads.  Alive kernel threads 
and kernel threads that have died during the interval are included in the 
summation.  For multi-threaded processes, the wait times can exceed the 
length of the measurement interval.


PROC_DISK_SUBSYSTEM_WAIT_TIME_CUM 
THREAD_DISK_SUBSYSTEM_WAIT_TIME_CUM
----------------------------------
The time, in seconds, that the process or kernel thread was blocked on the 
disk subsystem (waiting for its file system IOs to complete) over the 
cumulative collection time.
 On HP-UX, this is based on the sum of processes or kernel threads in the 
DISK, INODE, CACHE and CDFS wait states. Processes or kernel threads doing 
raw IO to a disk are not included in this measurement.
On Linux, this is based on the sum of all processes or kernel threads blocked 
on disk.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  If this 
metric is reported for a kernel thread, the value is the wait time of that 
single kernel thread.  If this metric is reported for a process, the value is 
the sum of the wait times of all of its kernel threads.  Alive kernel threads 
and kernel threads that have died during the interval are included in the 
summation.  For multi-threaded processes, the wait times can exceed the 
length of the measurement interval.


PROC_EUID 
THREAD_EUID
----------------------------------
The Effective User ID of a process(or kernel thread, if HP-UX/Linux Kernel 
2.6 and above).
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_FILE_MODE
----------------------------------
A text string summarizing the type of open mode:

  rd/wr  Opened for input & output
  read   Opened for input only
  write  Opened for output only



PROC_FILE_NAME
----------------------------------
The path name or identifying information about the open file descriptor.  If 
the path name string exceeds 40 characters in length, the beginning and the 
end of the path is shown and the middle of the name is replaced by “...”.
An attempt is made to obtain the file path name by either searching the 
current cylinder group to find directory entries that point to the currently 
opened inode, or by searching the kernel name cache.  Since looking up file 
path names would require high disk overhead, some names may not be resolved.  
If the path name can not be resolved, a string is returned indicating the 
type and inode number of the file.
For the string format including an inode number, you may use the ncheck(1M) 
program to display the file path name relative to the mount point.  Sometimes 
files may be deleted before they are closed.  In these cases, the process 
file table may still have the inode even though the file is not actually 
present and as a result, ncheck will fail.


PROC_FILE_NUMBER
----------------------------------
The file number of the current open file.


PROC_FILE_OPEN
----------------------------------
Number of files the current process has remaining open as of the end of the 
interval.


PROC_FILE_TYPE
----------------------------------
A text string describing the type of the current file.  This is one of:

  block   Block special device
  char    Character device
  dir     Directory
  fifo    A pipe or named pipe
  file    Simple file
  link    Symbolic file link
  other   An unknown file type



PROC_FORCED_CSWITCH 
THREAD_FORCED_CSWITCH
----------------------------------
The number of times that the process (or kernel thread, if HP-UX) was 
preempted by an external event and another process (or kernel thread, if HP-
UX) was allowed to execute during the interval.
Examples of reasons for a forced switch include expiration of a time slice or 
returning from a system call with a higher priority process (or kernel 
thread, if HP-UX) ready to run.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.


PROC_FORCED_CSWITCH_CUM 
THREAD_FORCED_CSWITCH_CUM
----------------------------------
The number of times the process (or kernel thread, if HP-UX) was preempted by 
an external event and another process (or kernel thread, if HP-UX) was 
allowed to execute over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
Examples of reasons for a forced switch include expiration of a time slice or 
returning from a system call with a higher priority process (or kernel 
thread, if HP-UX) ready to run.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.


PROC_GROUP_ID 
THREAD_GROUP_ID
----------------------------------
On most systems, this is the real group ID number of the process (or kernel 
thread, if HP-UX/Linux Kernel 2.6 and above).  On AIX, this is the effective 
group ID number of the process.
On HP-UX, this is the effective group ID number of the process if not in 
setgid mode.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_GROUP_NAME 
THREAD_GROUP_NAME
----------------------------------
The group name (from /etc/group) of a process(or kernel thread, if HP-
UX/Linux Kernel 2.6 and above).
The group identifier is obtained from searching the /etc/passwd file using 
the user ID (uid) as a key.  Therefore, if more than one account is listed in 
/etc/passwd with the same user ID (uid) field, the first one is used.  If no 
entry can be found for the user ID in /etc/passwd, the group name is the uid 
number.  If no matching entry in /etc/group can be found, the group ID is 
returned as the group name.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_INTEREST 
THREAD_INTEREST
----------------------------------
A string containing the reason(s) why the process or thread is of interest, 
based on the thresholds specified in the parm file.
An ‘A’ indicates that the process or thread exceeds the process CPU 
threshold, computed using the actual time the process or thread was alive 
during the interval.
A ‘C’ indicates that the process or thread exceeds the process CPU threshold, 
computed using the collection interval. Currently, the same CPU threshold is 
used for both CPU interest reasons.
A ‘D’ indicates that the process or thread exceeds the process disk IO 
threshold.
An ‘I’ indicates that the process or thread exceeds the IO threshold.
An ‘M’ indicates that the process exceeds the process memory threshold.  This 
interest reason is only meaningful for processes and therefore not shown for 
threads.
New processes or threads are identified with an ‘N’, terminated processes or 
threads are identified with a ‘K’.
Note that the parm file ‘nonew’, ‘nokill’ and ‘shortlived’ settings are 
logging only options and therefore ignored in Glance components.


PROC_INTERVAL 
THREAD_INTERVAL
----------------------------------
The amount of time in the interval.  This is the same value for all processes 
(and kernel threads, if HP-UX/Linux Kernel 2.6 and above), regardless of 
whether they were alive for the entire interval.
Note, calculations such as utilizations or rates are calculated using this 
standardized process interval (PROC_INTERVAL), rather than the actual alive 
time during the interval (PROC_INTERVAL_ALIVE).  Thus, if a process was only 
alive for 1 second and used the CPU during its entire life (1 second), but 
the process sample interval was 5 seconds, it would be reported as using 1/5 
or 20% CPU utilization, rather than 100% CPU utilization.


PROC_INTERVAL_ALIVE 
THREAD_INTERVAL_ALIVE
----------------------------------
The number of seconds that the process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) was alive during the interval.  This may be less than 
the time of the interval if the process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above) was new or died during the interval.


PROC_INTERVAL_CUM 
THREAD_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On SUN, AIX, and OSF1, this differs from PROC_RUN_TIME in that PROC_RUN_TIME 
may not include all of the first and last sample interval times and 
PROC_INTERVAL_CUM does.


PROC_IO_BYTE 
THREAD_IO_BYTE
----------------------------------
On HP-UX, this is the total number of physical IO KBs (unless otherwise 
specified) that was used by this process or kernel thread, either directly or 
indirectly, during the interval.
On all other systems, this is the total number of physical IO KBs (unless 
otherwise specified) that was used by this process during the interval.  IOs 
include disk, terminal, tape and network IO.
On HP-UX, indirect IOs include paging and deactivation/reactivation activity 
done by the kernel on behalf of the process or kernel thread.  Direct IOs 
include disk, terminal, tape, and network IO, but exclude all NFS traffic.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
On SUN, counts in the MB ranges in general can be attributed to disk accesses 
and counts in the KB ranges can be attributed to terminal IO.  This is useful 
when looking for processes with heavy disk IO activity.  This may vary 
depending on the sample interval length.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_IO_BYTE_CUM 
THREAD_IO_BYTE_CUM
----------------------------------
On HP-UX, this is the total number of physical IO KBs (unless otherwise 
specified) that was used by this process or kernel thread, either directly or 
indirectly, over the cumulative collection time.
On all other systems, this is the total number of physical IO KBs (unless 
otherwise specified) that was used by this process over the cumulative 
collection time.  IOs include disk, terminal, tape and network IO.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, indirect IOs include paging and deactivation/reactivation activity 
done by the kernel on behalf of the process or kernel thread.  Direct IOs 
include disk, terminal, tape, and network IO, but exclude all NFS traffic.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_IO_BYTE_RATE 
THREAD_IO_BYTE_RATE
----------------------------------
On HP-UX, this is the number of physical IO KBs per second that was used by 
this process or kernel thread, either directly or indirectly, during the 
interval.
On all other systems, this is the number of physical IO KBs per second that 
was used by this process during the interval.  IOs include disk, terminal, 
tape and network IO.
On HP-UX, indirect IOs include paging and deactivation/reactivation activity 
done by the kernel on behalf of the process or kernel thread.  Direct IOs 
include disk, terminal, tape, and network IO, but exclude all NFS traffic.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
On SUN, counts in the MB ranges in general can be attributed to disk accesses 
and counts in the KB ranges can be attributed to terminal IO.  This is useful 
when looking for processes with heavy disk IO activity.  This may vary 
depending on the sample interval length.
Certain types of disk IOs are not counted by AIX at the process level, so 
they are excluded from this metric.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_IO_BYTE_RATE_CUM 
THREAD_IO_BYTE_RATE_CUM
----------------------------------
On HP-UX, this is the average number of physical IO KBs per second that was 
used by this process or kernel thread, either directly or indirectly, over 
the cumulative collection time.
On all other systems, this is the average number of physical IO KBs per 
second that was used by this process over the cumulative collection time.  
IOs include disk, terminal, tape and network IO.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, indirect IOs include paging and deactivation/reactivation activity 
done by the kernel on behalf of the process or kernel thread.  Direct IOs 
include disk, terminal, tape, and network IO, but exclude all NFS traffic.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
On SUN, counts in the MB ranges in general can be attributed to disk accesses 
and counts in the KB ranges can be attributed to terminal IO.  This is useful 
when looking for processes with heavy disk IO activity.  This may vary 
depending on the sample interval length.
 Linux release versions vary with regards to the amount of process-level IO 
statistics that are available. Some kernels instrument only disk IO, while 
some provide statistics for all devices together (including tty and other 
devices with disk IO).
When it is available from your specific release of Linux, the PROC_DISK_PHYS* 
metrics will report pages of disk IO specifically.  The PROC_IO* metrics will 
report the sum of all types of IO including disk IO, in Kilobytes or KB 
rates. These metrics will have “na” values on kernels that do not support the 
instrumentation.
For multi-threaded processes, some Linux kernels only report IO statistics 
for the main thread. In that case, patches are available that will allow the 
process instrumentation to report the sum of all thread’s IOs, and will also 
enable per-thread reporting.
Starting with 2.6.3X, at least some kernels will include IO data from the 
children of the process in the process data. This results in misleading 
inflated IO metrics for processes that fork a lot of children, such as 
shells, or the init(1m) process.


PROC_MAJOR_FAULT 
THREAD_MAJOR_FAULT
----------------------------------
Number of major page faults for this process (or kernel thread, if HP-
UX/Linux Kernel 2.6 and above) during the interval.
 On HP-UX, major page faults and minor page faults are a subset of vfaults 
(virtual faults).  Stack and heap accesses can cause vfaults, but do not 
result in a disk page having to be loaded into memory.


PROC_MAJOR_FAULT_CUM 
THREAD_MAJOR_FAULT_CUM
----------------------------------
Number of major page faults for this process (or kernel thread, if HP-
UX/Linux Kernel 2.6 and above) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, major page faults and minor page faults are a subset of vfaults 
(virtual faults).  Stack and heap accesses can cause vfaults, but do not 
result in a disk page having to be loaded into memory.


PROC_MEM_DATA_VIRT 
THREAD_MEM_DATA_VIRT
----------------------------------
On SUN, this is the virtual set size (in KB) of the heap memory for this 
process.  Note that heap can reside partially in BSS and partially in the 
data segment, so its value will not be the same as PROC_REGION_VIRT of the 
data segment or PROC_REGION_VIRT_DATA, which is the sum of all data segments 
for the process.
On the other non HP-UX systems, this is the virtual set size (in KB) of the 
data segment for this process(or kernel thread, if Linux Kernel 2.6 and 
above).
A value of “na” is displayed when this information is unobtainable.
On AIX, this is the same as the SIZE value reported by “ps v”.
On Linux this value is rounded to PAGESIZE.


PROC_MEM_LOCKED 
THREAD_MEM_LOCKED
----------------------------------
The number of KBs of virtual memory allocated by the process, marked as 
locked memory.
On Windows, this is the non-paged pool memory of the process. This memory is 
allocated from the system-wide non-paged pool, and is not affected by the 
pageout process.  Device drivers may allocate memory from the non-paged pool, 
charging quota against the current (caller) thread.
The kernel and driver code use the non-paged pool for data that should always 
be in the physical memory.  The size of the non-paged pool is limited to 
approximately 128 MB on Windows NT systems and to 256 MB on Windows 2000 
systems.  The failure to allocate memory from the non-paged pool can cause a 
system crash.


PROC_MEM_RES 
THREAD_MEM_RES
----------------------------------
The size (in KB) of resident memory allocated for the process(or kernel 
thread, if HP-UX/Linux Kernel 2.6 and above).
On HP-UX, the calculation of this metric differs depending on whether this 
process has used any CPU time since the midaemon process was started. This 
metric is less accurate and does not include shared memory regions in its 
calculation when the process has been idle since the midaemon was started.
On HP-UX, for processes that use CPU time subsequent to midaemon startup, the 
resident memory is calculated as

RSS = sum of private region pages +
      (sum of shared region pages /
       number of references)
 The number of references is a count of the number of attachments to the 
memory region.  Attachments, for shared regions, may come from several 
processes sharing the same memory, a single process with multiple 
attachments, or combinations of these.
This value is only updated when a process uses CPU.  Thus, under memory 
pressure, this value may be higher than the actual amount of resident memory 
for processes which are idle because their memory pages may no longer be 
resident or the reference count for shared segments may have changed.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.
A value of “na” is displayed when this information is unobtainable.  This 
information may not be obtainable for some system (kernel) processes. It may 
also not be available for defunct processes.
On AIX, this is the same as the RSS value shown by “ps v”.
On Windows, this is the number of KBs in the working set of this process.  
The working set includes the memory pages touched recently by the threads of 
the process.  If free memory in the system is above a threshold, then pages 
are left in the working set even if they are not in use.  When free memory 
falls below a threshold, pages are trimmed from the working set, but not 
necessarily paged out to disk from memory.  If those pages are subsequently 
referenced, they will be page faulted back into the working set.  Therefore, 
the working set is a general indicator of the memory resident set size of 
this process, but it will vary depending on the overall status of memory on 
the system.  Note that the size of the working set is often larger than the 
amount of pagefile space consumed (PROC_MEM_VIRT).


PROC_MEM_RES_HIGH 
THREAD_MEM_RES_HIGH
----------------------------------
The largest value of resident memory (in KB) during its lifetime.
See the description for PROC_MEM_RES for details about how resident memory is 
determined.
A value of “na” is displayed when this information is unobtainable.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_MEM_SHARED_RES 
THREAD_MEM_SHARED_RES
----------------------------------
The size (in KB) of resident memory of shared regions only, such as shared 
text, shared memory, and shared libraries.
On HP-UX, this value is not affected by the reference count.  A value of “na” 
is displayed when this information is unobtainable.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_MEM_STACK_VIRT 
THREAD_MEM_STACK_VIRT
----------------------------------
Size (in KB) of the stack for this process(or kernel thread, if Linux Kernel 
2.6 and above).
On SUN, the stack is initialized to 8K bytes.
On Linux this value is rounded to PAGESIZE.


PROC_MEM_TEXT_VIRT 
THREAD_MEM_TEXT_VIRT
----------------------------------
Size (in KB) of the private text for this process(or kernel thread, if Linux 
Kernel 2.6 and above).
On AIX, this is the same as the TSIZ field shown by “ps v”.
On Linux this value is rounded to PAGESIZE.


PROC_MEM_VIRT 
THREAD_MEM_VIRT
----------------------------------
The size (in KB) of virtual memory allocated for the process(or kernel 
thread, if HP-UX/Linux Kernel 2.6 and above).
On HP-UX, this consists of the sum of the virtual set size of all private 
memory regions used by this process, plus this process’ share of memory 
regions which are shared by multiple processes.  For processes that use CPU 
time, the value is divided by the reference count for those regions which are 
shared.
On HP-UX, this metric is less accurate and does not reflect the reference 
count for shared regions for processes that were started prior to the 
midaemon process and have not used any CPU time since the midaemon was 
started.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.
On all other Unix systems, this consists of private text, private data, 
private stack and shared memory. The reference count for shared memory is not 
taken into account, so the value of this metric represents the total virtual 
size of all regions regardless of the number of processes sharing access.
Note also that lazy swap algorithms, sparse address space malloc calls, and 
memory-mapped file access can result in large VSS values. On systems that 
provide Glance memory regions detail reports, the drilldown detail per memory 
region is useful to understand the nature of memory allocations for the 
process.
A value of “na” is displayed when this information is unobtainable.  This 
information may not be obtainable for some system (kernel) processes. It may 
also not be available for defunct processes.
On Windows, this is the number of KBs the process has used in the paging 
file(s).  Paging files are used to store pages of memory used by the process, 
such as local data, that are not contained in other files.  Examples of 
memory pages which are contained in other files include pages storing a 
program’s .EXE and .DLL files.  These would not be kept in pagefile space.  
Thus, often programs will have a memory working set size (PROC_MEM_RES) 
larger than the size of its pagefile space.
On Linux this value is rounded to PAGESIZE.


PROC_MINOR_FAULT 
THREAD_MINOR_FAULT
----------------------------------
Number of minor page faults for this process (or kernel thread, if HP-
UX/Linux Kernel 2.6 and above) during the interval.
 On HP-UX, major page faults and minor page faults are a subset of vfaults 
(virtual faults).  Stack and heap accesses can cause vfaults, but do not 
result in a disk page having to be loaded into memory.


PROC_MINOR_FAULT_CUM 
THREAD_MINOR_FAULT_CUM
----------------------------------
Number of minor page faults for this process (or kernel thread, if HP-
UX/Linux Kernel 2.6 and above) over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On HP-UX, major page faults and minor page faults are a subset of vfaults 
(virtual faults).  Stack and heap accesses can cause vfaults, but do not 
result in a disk page having to be loaded into memory.


PROC_NICE_PRI 
THREAD_NICE_PRI
----------------------------------
The nice priority for the process (or kernel thread, if HP-UX/Linux Kernel 
2.6 and above) when it was last dispatched.  The value is a bias used to 
adjust the priority for the process.
On AIX, the nice user value, makes a process less favored than it otherwise 
would be, has a range of 0-40 with a default value of 20.  The value of PUSER 
is always added to the value of nice to weight the user process down below 
the range of priorities expected to be in use by system jobs like the 
scheduler and special wait queues.
On all other Unix systems, the value ranges from 0 to 39.  A higher value 
causes a process (or kernel thread, if HP-UX/Linux Kernel 2.6 and above) to 
be dispatched less.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_PAGEFAULT 
THREAD_PAGEFAULT
----------------------------------
The number of page faults that occurred during the interval for the 
process(or kernel threads, if HP-UX/Linux Kernel 2.6 and above).


PROC_PAGEFAULT_RATE 
THREAD_PAGEFAULT_RATE
----------------------------------
The number of page faults per second that occurred during the interval for 
the process(or kernel threads, if HP-UX/Linux Kernel 2.6 and above).


PROC_PAGEFAULT_RATE_CUM 
THREAD_PAGEFAULT_RATE_CUM
----------------------------------
The average number of page faults per second that occurred over the 
cumulative collection time for the process(or kernel threads, if HP-UX/Linux 
Kernel 2.6 and above).


PROC_PARENT_PROC_ID 
THREAD_PARENT_PROC_ID
----------------------------------
The parent process’ PID number.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_PRI 
THREAD_PRI
----------------------------------
On Unix systems, this is the dispatch priority of a process (or kernel 
thread, if HP-UX/Linux Kernel 2.6 and above) at the end of the interval.  The 
lower the value, the more likely the process is to be dispatched.
On Windows, this is the current base priority of this process.
On HP-UX, whenever the priority is changed for the selected process or kernel 
thread, the new value will not be reflected until the process or kernel 
thread is reactivated if it is currently idle (for example, SLEEPing).
On HP-UX, the lower the value, the more the process or kernel thread is 
likely to be dispatched.  Values between zero and 127 are considered to be 
“real-time” priorities, which the kernel does not adjust.  Values above 127 
are normal priorities and are modified by the kernel for load balancing.  
Some special priorities are used in the HP-UX kernel and subsystems for 
different activities.  These values are described in 
/usr/include/sys/param.h.  Priorities less than PZERO 153 are not signalable.
Note that on HP-UX, many network-related programs such as inetd, biod, and 
rlogind run at priority 154 which is PPIPE.  Just because they run at this 
priority does not mean they are using pipes.  By examining the open files, 
you can determine if a process or kernel thread is using pipes.
For HP-UX 10.0 and later releases, priorities between -32 and -1 can be seen 
for processes or kernel threads using the Posix Real-time Schedulers.  When 
specifying a Posix priority, the value entered must be in the range from 0 
through 31, which the system then remaps to a negative number in the range of 
-1 through -32.  Refer to the rtsched man pages for more information.
 On a threaded operating system, such as HP-UX 11.0 and beyond, this metric 
represents a kernel thread characteristic.  If this metric is reported for a 
process, the value for its last executing kernel thread is given.  For 
example, if a process has multiple kernel threads and kernel thread one is 
the last to execute during the interval, the metric value for kernel thread 
one is assigned to the process.
On AIX, values for priority range from 0 to 127.  Processes running at 
priorities less than PZERO (40) are not signalable.
On Windows, the higher the value the more likely the process or thread is to 
be dispatched.  Values for priority range from 0 to 31.  Values of 16 and 
above are considered to be “realtime” priorities.  Threads within a process 
can raise and lower their own base priorities relative to the process’s base 
priority.


PROC_PRI_WAIT_PCT 
THREAD_PRI_WAIT_PCT
----------------------------------
The percentage of time during the interval the process or kernel thread was 
blocked on priority (waiting for its priority to become high enough to get 
the CPU).  On Linux this metric indicates the total time the process or 
kernel thread was blocked on priority (waiting for its priority to become 
high enough to get the CPU) as a percentage of the total CPU time available 
during the interval.
On multi-threaded Linux system this metric may exceed 100%.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
A percentage of time spent in a wait state is calculated as the time a kernel 
thread (or all kernel threads of a process) spent waiting in this state, 
divided by the alive time of the kernel thread (or all kernel threads of the 
process) during the interval.
If this metric is reported for a kernel thread, the percentage value is for 
that single kernel thread.  If this metric is reported for a process, the 
percentage value is calculated with the sum of the wait and alive times of 
all of its kernel threads.
For example, if a process has 2 kernel threads, one sleeping for the entire 
interval and one waiting on terminal input for the interval, the process wait 
percent values will be 50% on Sleep and 50% on Terminal.  The kernel thread 
wait values will be 100% on Sleep for the first kernel thread and 100% on 
Terminal for the second kernel thread.
For another example, consider the same process as above, with 2 kernel 
threads, one of which was created half-way through the interval, and which 
then slept for the remainder of the interval.  The other kernel thread was 
waiting for terminal input for half the interval, then used the CPU actively 
for the remainder of the interval.  The process wait percent values will be 
33% on Sleep and 33% on Terminal (each one third of the total alive time).  
The kernel thread wait values will be 100% on Sleep for the first kernel 
thread and 50% on Terminal for the second kernel thread.


PROC_PRI_WAIT_PCT_CUM 
THREAD_PRI_WAIT_PCT_CUM
----------------------------------
The percentage of time the process or kernel thread was blocked on priority 
over the cumulative collection time.
On Linux this metric indicates the total time the process or kernel thread 
was blocked on priority (waiting for its priority to become high enough to 
get the CPU) as a percentage of the total CPU time available over the 
cumulative collection time.
On multi-threaded Linux system this metric may exceed 100%.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
A percentage of time spent in a wait state is calculated as the time a kernel 
thread (or all kernel threads of a process) spent waiting in this state, 
divided by the alive time of the kernel thread (or all kernel threads of the 
process) during the interval.
If this metric is reported for a kernel thread, the percentage value is for 
that single kernel thread.  If this metric is reported for a process, the 
percentage value is calculated with the sum of the wait and alive times of 
all of its kernel threads.
For example, if a process has 2 kernel threads, one sleeping for the entire 
interval and one waiting on terminal input for the interval, the process wait 
percent values will be 50% on Sleep and 50% on Terminal.  The kernel thread 
wait values will be 100% on Sleep for the first kernel thread and 100% on 
Terminal for the second kernel thread.
For another example, consider the same process as above, with 2 kernel 
threads, one of which was created half-way through the interval, and which 
then slept for the remainder of the interval.  The other kernel thread was 
waiting for terminal input for half the interval, then used the CPU actively 
for the remainder of the interval.  The process wait percent values will be 
33% on Sleep and 33% on Terminal (each one third of the total alive time).  
The kernel thread wait values will be 100% on Sleep for the first kernel 
thread and 50% on Terminal for the second kernel thread.


PROC_PRI_WAIT_TIME 
THREAD_PRI_WAIT_TIME
----------------------------------
The time, in seconds, that the process or kernel thread was blocked on PRI 
(waiting for its priority to become high enough to get the CPU) during the 
interval.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  If this 
metric is reported for a kernel thread, the value is the wait time of that 
single kernel thread.  If this metric is reported for a process, the value is 
the sum of the wait times of all of its kernel threads.  Alive kernel threads 
and kernel threads that have died during the interval are included in the 
summation.  For multi-threaded processes, the wait times can exceed the 
length of the measurement interval.


PROC_PRI_WAIT_TIME_CUM 
THREAD_PRI_WAIT_TIME_CUM
----------------------------------
The time, in seconds, that the process or kernel thread was blocked on PRI 
(waiting for its priority to become high enough to get the CPU) over the 
cumulative collection time.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On a threaded operating system, such as HP-UX 11.0 and beyond, process wait 
time is calculated by summing the wait times of its kernel threads.  If this 
metric is reported for a kernel thread, the value is the wait time of that 
single kernel thread.  If this metric is reported for a process, the value is 
the sum of the wait times of all of its kernel threads.  Alive kernel threads 
and kernel threads that have died during the interval are included in the 
summation.  For multi-threaded processes, the wait times can exceed the 
length of the measurement interval.


PROC_PROC_ARGV1 
THREAD_PROC_ARGV1
----------------------------------
The first argument (argv[1]) of the process argument list or the second word 
of the command line, if present. (For kernel threads, if HP-UX/Linux Kernel 
2.6 and above this metric returns the value of the associated process).  The 
HP Performance Agent logs the first 32 characters of this metric.
For releases that support the parm file javaarg flag, this metric may not be 
the first argument. When javaarg=true, the value of this metric is replaced 
(for java processes only) by the java class or jar name. This can then be 
useful to construct parm file java application definitions using the argv1= 
keyword.


PROC_PROC_CMD 
THREAD_PROC_CMD
----------------------------------
The full command line with which the process was initiated. (For kernel 
threads, if HP-UX/Linux Kernel 2.6 and above this metric returns the value of 
the associated process).
On HP-UX, the maximum length returned depends upon the version of the OS, but 
typically up to 1020 characters are available.
On other Unix systems, the maximum length is 4095 characters.
On Linux, if the command string exceeds 4096 characters, the kernel 
instrumentation may not report any value.
If the command line contains special characters, such as carriage return and 
tab, these characters will be converted to , , and so on.


PROC_PROC_ID 
THREAD_PROC_ID
----------------------------------
The process ID number (or PID) of this process(or associated process for 
kernel threads, if HP-UX/Linux Kernel 2.6 and above) that is used by the 
kernel to uniquely identify the process.  Process numbers are reused, so they 
only identify a process for its lifetime.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_PROC_NAME 
THREAD_PROC_NAME
----------------------------------
The process(or kernel thread, if HP-UX/Linux Kernel 2.6 and above) program 
name.  It is limited to 16 characters.
On Unix systems, this is derived from the 1st parameter to the exec(2) system 
call.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.
On Windows, the “System Idle Process” is not reported by Perf Agent since 
Idle is a process that runs to occupy the processors when they are not 
executing other threads. Idle has one thread per processor.


PROC_REGION_FILENAME
----------------------------------
The file path that corresponds to the front store file of a memory region.  
For text and data regions, this is the name of the program; for shared 
libraries it is the library name.
Certain “special” names are displayed if there is no actual “front store” for 
a memory region.  These special names correspond to the region type (for 
example, <stack>).  If the name is “<mmap>“, then this is a memory region 
without “front store,” created by the system call mmap(2).
If the file format includes an inode number, use the program ncheck (1M) to 
display the filename relative to the mount point.  Sometimes files may be 
deleted before they are closed.  In these cases, the process file table may 
still have the inode even though the file is not actually present and as a 
result, ncheck will fail.


PROC_REGION_PRIVATE_SHARED_FLAG
----------------------------------
A text indicator of either private memory (Priv) or shared (Shared) for this 
memory region.  Private memory is only being used by the current process.  
Shared memory is mapped into the address space of other processes.


PROC_REGION_PROT_FLAG
----------------------------------
The protection mode of the process memory segment.  It represents 
Read/Write/eXecute permissions in the same way as ls(1) does for files.  This 
metric is available only for regions that have global protection mode.  It is 
not available (“na”) for regions that use per-page protection.


PROC_REGION_TYPE
----------------------------------
A text name for the type of this memory region.  It can be one of the 
following:

DATA    Data region
LIBDAT  Shared Library data
LIBTXT  Shared Library text
STACK   Stack region
TEXT    Text (that is, code)
On HP-UX, it can also be one of the following:

GRAPH   Frame buffer lock page
IOMAP   IO region (iomap)
MEMMAP  Memory-mapped file,
        which includes shared
        libraries (text and
        data), or memory
        created by calls to
        mmap(2)
NULLDR  Null pointer dereference
        shared page (see below)
RSESTA  Itanium Registered stack
        engine region
SIGSTK  Signal stack region
UAREA   User Area region
UNKNWN  Region of unknown type
On HP-UX, a whole page is allocated for NULL pointer dereferencing, which is 
reported as the NULLDR area.  If the program is compiled with the “-z” option 
(which disallows NULL dereferencing), this area is missing.  Shared libraries 
are accessed as memory mapped files, so that the code will show up as 
“MEMMAP/Shared” and data will show up as “MEMMAP/Priv”.
On SUN, it can also be one of the following:

BSS     Static initialized data
MEMMAP  Memory mapped files
NULLDR  Null pointer dereference
        shared page (see below).
SHMEM   Shared memory
UNKNWN  Region of unknown type
On SUN, programs might have an area for NULL pointer dereferencing, which is 
reported as the NULLDR area.  Special segment types that are supported by the 
kernel that are used for frame buffer devices or other purposes are typed as 
UNKNWN.  The following kernel processes are examples of this: sched, pageout, 
and fsflush.
On AIX, as of mid-2010, the OS only provides information for text and data.


PROC_REGION_VIRT
----------------------------------
The size (in KBs unless otherwise indicated) of the virtual memory occupied 
by this memory region.
This value is not affected by the reference count.
 The number of references is a count of the number of attachments to the 
memory region.  Attachments, for shared regions, may come from several 
processes sharing the same memory, a single process with multiple 
attachments, or combinations of these.
 On AIX, as of mid-2010, the OS only provides information for text and data. 
Other sizes will always be zero. Note also that the total virtual size may 
not match the sum of the regions due to inconsistencies in the AIX 
measurement interfaces.


PROC_REGION_VIRT_ADDRS
----------------------------------
The virtual address of this memory region displayed in hexadecimal showing 
the space and offset of the region.
On HP-UX, this is a 64-bit (96-bit on a 64-bit OS) hexadecimal value 
indicating the space and space offset of the region.


PROC_REGION_VIRT_DATA
----------------------------------
The size (in KBs unless otherwise indicated) of the total virtual memory 
occupied by data regions of this process.  This value is not affected by the 
reference count since all data regions are private.
 This metric is specific to the process as a whole and will not change its 
value.  If this metric is used in a glance adviser script, only pick up one 
value.  Do not sum the values since the same value is shown for all regions.
 On AIX, as of mid-2010, the OS only provides information for text and data. 
Other sizes will always be zero. Note also that the total virtual size may 
not match the sum of the regions due to inconsistencies in the AIX 
measurement interfaces.


PROC_REGION_VIRT_OTHER
----------------------------------
The size (in KBs unless otherwise indicated) of the total virtual memory 
occupied by regions of this process that are not text, data, stack, or shared 
memory.
This value is not affected by the reference count.
 This metric is specific to the process as a whole and will not change its 
value.  If this metric is used in a glance adviser script, only pick up one 
value.  Do not sum the values since the same value is shown for all regions.
 The number of references is a count of the number of attachments to the 
memory region.  Attachments, for shared regions, may come from several 
processes sharing the same memory, a single process with multiple 
attachments, or combinations of these.
 On AIX, as of mid-2010, the OS only provides information for text and data. 
Other sizes will always be zero. Note also that the total virtual size may 
not match the sum of the regions due to inconsistencies in the AIX 
measurement interfaces.


PROC_REGION_VIRT_SHMEM
----------------------------------
The size (in KBs unless otherwise indicated) of the total virtual memory 
occupied by shared memory regions of this process.
Note that this memory is shared by other processes and this figure is 
reported in their metrics also.
This value is not affected by the reference count.
 This metric is specific to the process as a whole and will not change its 
value.  If this metric is used in a glance adviser script, only pick up one 
value.  Do not sum the values since the same value is shown for all regions.
 The number of references is a count of the number of attachments to the 
memory region.  Attachments, for shared regions, may come from several 
processes sharing the same memory, a single process with multiple 
attachments, or combinations of these.
 On AIX, as of mid-2010, the OS only provides information for text and data. 
Other sizes will always be zero. Note also that the total virtual size may 
not match the sum of the regions due to inconsistencies in the AIX 
measurement interfaces.


PROC_REGION_VIRT_STACK
----------------------------------
The size (in KBs unless otherwise indicated) of the total virtual memory 
occupied by stack regions of this process.
Stack regions are always private and will have a reference count of one.
 This metric is specific to the process as a whole and will not change its 
value.  If this metric is used in a glance adviser script, only pick up one 
value.  Do not sum the values since the same value is shown for all regions.
 On AIX, as of mid-2010, the OS only provides information for text and data. 
Other sizes will always be zero. Note also that the total virtual size may 
not match the sum of the regions due to inconsistencies in the AIX 
measurement interfaces.


PROC_REGION_VIRT_TEXT
----------------------------------
The size (in KBs unless otherwise indicated) of the total virtual memory 
occupied by text regions of this process.  This value is not affected by the 
reference count.
 This metric is specific to the process as a whole and will not change its 
value.  If this metric is used in a glance adviser script, only pick up one 
value.  Do not sum the values since the same value is shown for all regions.
 On AIX, as of mid-2010, the OS only provides information for text and data. 
Other sizes will always be zero. Note also that the total virtual size may 
not match the sum of the regions due to inconsistencies in the AIX 
measurement interfaces.


PROC_RUN_TIME 
THREAD_RUN_TIME
----------------------------------
The elapsed time since a process (or kernel thread, if HP-UX/Linux Kernel 2.6 
and above) started, in seconds.
This metric is less than the interval time if the process (or kernel thread, 
if HP-UX/Linux Kernel 2.6 and above) was not alive during the entire first or 
last interval.
 On a threaded operating system such as HP-UX 11.0 and beyond, this metric is 
available for a process or kernel thread.


PROC_SCHEDULER 
THREAD_SCHEDULER
----------------------------------
The scheduling policy for this process or kernel thread.
On HP-UX, the available scheduling policies are:

HPUX   - Normal timeshare
NOAGE  - Timeshare without usage
         decay
RTPRIO - HP-UX Real-time
FIFO   - Posix First In/First Out
RR     - Posix Round-Robin
RR2    - Posix Round-Robin with a
         per-priority time slice
         interval
On Linux, they are:

TS     - Normal timeshare
FF     - Posix First In/First Out
RR     - Posix Round-Robin
B      - Batch
ISO    - Reserved
IDL    - Idle
 On a threaded operating system, such as HP-UX 11.0 and beyond, this metric 
represents a kernel thread characteristic.  If this metric is reported for a 
process, the value for its last executing kernel thread is given.  For 
example, if a process has multiple kernel threads and kernel thread one is 
the last to execute during the interval, the metric value for kernel thread 
one is assigned to the process.


PROC_STARTTIME 
THREAD_STARTTIME
----------------------------------
The creation date and time of the process (or kernel thread, if HP-UX/Linux 
Kernel 2.6 and above).


PROC_STATE 
THREAD_STATE
----------------------------------
A text string summarizing the current state of a process (or kernel thread, 
if HP-UX/Linux Kernel 2.6 and above), either:

new      This is the first interval
         the process has been
         displayed.
active   Process is continuing.
died     Process expired during
         the interval.



PROC_STATE_FLAG 
THREAD_STATE_FLAG
----------------------------------
The Unix STATE flag of the process(or kernel thread, if Linux Kernel 2.6 and 
above) during the interval.


PROC_STOP_REASON 
THREAD_STOP_REASON
----------------------------------
A text string describing what caused the process (or kernel thread, if HP-
UX/Linux Kernel 2.6 and above) to stop executing.  For example, if the 
process is waiting for a CPU while higher priority processes are executing, 
then its block reason is PRI.  A complete list of block reasons follows:


String   Reason for Process Block
------------------------------------

died    Process terminated during
        the interval.
new     Process was created (via the
        exec() system call) during
        the interval.
NONE    Process is ready to run.  It
        is not apparent that the
        process is blocked.
OTHER   Waiting for a reason not
        decipherable by the
        measurement software.
PRI     Process is on the run queue.
SLEEP   Waiting for an event to
        complete.
TRACE   Received a signal to stop
        because parent is tracing
        this process.
ZOMB    Process has terminated and
        the parent is not waiting.



PROC_STOP_REASON_FLAG 
THREAD_STOP_REASON_FLAG
----------------------------------
A numeric value for the stop reason.  This is used by scopeux instead of the 
ASCII string returned by PROC_STOP_REASON in order to conserve space in the 
log file.
 On a threaded operating system, such as HP-UX 11.0 and beyond, this metric 
represents a kernel thread characteristic.  If this metric is reported for a 
process, the value for its last executing kernel thread is given.  For 
example, if a process has multiple kernel threads and kernel thread one is 
the last to execute during the interval, the metric value for kernel thread 
one is assigned to the process.


PROC_THREAD_COUNT 
THREAD_THREAD_COUNT
----------------------------------
The total number of kernel threads for the current process.
On Linux systems with Kernel 2.5 and below, every thread has its own process 
ID so this metric will always be 1.
On Solaris systems, this metric reflects the total number of Light Weight 
Processes (LWPs) associated with the process.


PROC_THREAD_ID 
THREAD_THREAD_ID
----------------------------------
The thread ID number of this kernel thread, used to uniquely identify it.  On 
Linux systems this metric shall be available from Linux Kernel 2.6 onwards.


PROC_TIME 
THREAD_TIME
----------------------------------
The time the data for the process (or kernel threads, if HP-UX/Linux Kernel 
2.6 and above) was collected, in local time.


PROC_TOP_CPU_INDEX 
THREAD_TOP_CPU_INDEX
----------------------------------
The index of the process which consumed the most CPU during the interval.  
From this index, the process PID, process name, and CPU utilization can be 
obtained. (Even for kernel threads if HP-UX/Linux Kernel 2.6 and above this 
metric returns the index of the process)
This metric is used by the Performance Tools to index into the Data 
collection interface’s internal table.  This is not a metric that will be 
interesting to Tool users.


PROC_TOP_DISK_INDEX 
THREAD_TOP_DISK_INDEX
----------------------------------
The index of the process which did the most physical IOs during the last 
interval.
On HP-UX, note that NFS mounted disks are not considered in this calculation.
With this index, the PID, process name, and IOs per second can be obtained.
This metric is used by the Performance Tools to index into the Data 
collection interface’s internal table.  This is not a metric that will be 
interesting to Tool’s users.


PROC_TTY 
THREAD_TTY
----------------------------------
The controlling terminal for a process(or kernel threads, if HP-UX/Linux 
Kernel 2.6 and above).  This field is blank if there is no controlling 
terminal.  On HP-UX, Linux, and AIX, this is the same as the “TTY” field of 
the ps command.
On all other Unix systems, the controlling terminal name is found by 
searching the directories provided in the /etc/ttysrch file.  See man page 
ttysrch(4) for details.  The matching criteria field (“M”, “F” or “I” values) 
of the ttysrch file is ignored.  If a terminal is not found in one of the 
ttysrch file directories, the following directories are searched in the order 
here: “/dev”, “/dev/pts”, “/dev/term” and “dev/xt”.  When a match is found in 
one of the “/dev” subdirectories, “/dev/” is not displayed as part of the 
terminal name.  If no match is found in the directory searches, the major and 
minor numbers of the controlling terminal are displayed.  In most cases, this 
value is the same as the “TTY” field of the ps command.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_TTY_DEV 
THREAD_TTY_DEV
----------------------------------
The device number of the controlling terminal for a process(or kernel 
threads, if HP-UX/Linux Kernel 2.6 and above).
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_UID 
THREAD_UID
----------------------------------
The real UID (user ID number) of a process(or kernel threads, if HP-UX/Linux 
Kernel 2.6 and above).  This is the UID returned from the getuid system call.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_USER_NAME 
THREAD_USER_NAME
----------------------------------
On Unix systems, this is real user name of a process or the login account 
(from /etc/passwd) of a process (or kernel thread, if HP-UX/Linux Kernel 2.6 
and above). If more than one account is listed in /etc/passwd with the same 
user ID (uid) field, the first one is used.  If an account cannot be found 
that matches the uid field, then the uid number is returned.  This would 
occur if the account was removed after a process was started.
On Windows, this is the process owner account name, without the domain name 
this account resides in.
 On HP-UX, this metric is specific to a process.  If this metric is reported 
for a kernel thread, the value for its associated process is given.


PROC_VOLUNTARY_CSWITCH 
THREAD_VOLUNTARY_CSWITCH
----------------------------------
The number of times a process (or kernel thread, if HP-UX) has given up the 
CPU before an external event preempted it during the interval.  Examples of 
voluntary switches include calls to sleep(2) and select(2).
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.


PROC_VOLUNTARY_CSWITCH_CUM 
THREAD_VOLUNTARY_CSWITCH_CUM
----------------------------------
The number of times a process (or kernel thread, if HP-UX) has given up the 
CPU before an external event preempted it over the cumulative collection 
time.  Examples of voluntary switches include calls to sleep(2) and 
select(2).
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On multi-threaded operating systems,  process usage of a resource is 
calculated by summing the usage of that resource by its kernel threads.  If 
this metric is reported for a kernel thread, the value is the resource usage 
by that single kernel thread.  If this metric is reported for a process, the 
value is the sum of the resource usage by all of its kernel threads.  Alive 
kernel threads and kernel threads that have died during the interval are 
included in the summation.
 On Linux, if thread collection is disabled, only the first thread of each 
multi-threaded process is taken into account. This metric will be NA on 
kernels older than 2.6.23 or kernels not including CFS, the Completely Fair 
Scheduler.


SYSCALL_ACTIVE_CUM
----------------------------------
The number of system calls used on the system.  All calls used over the 
cumulative collection time are included in this count.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


SYSCALL_CALL_COUNT
----------------------------------
The number of system calls made to this function during the interval.
They are assessed when the system call stub returns control back to the 
calling program/routine.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


SYSCALL_CALL_COUNT_CUM
----------------------------------
The number of system calls made to this function over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


SYSCALL_CALL_ID
----------------------------------
The ID number of this system call.  System calls are sequentially numbered 
starting with one.


SYSCALL_CALL_NAME
----------------------------------
The system call name.


SYSCALL_CALL_RATE
----------------------------------
The number of system calls per second made to this function during the last 
interval.
They are assessed when the system call stub returns control back to the 
calling program/routine.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


SYSCALL_CALL_RATE_CUM
----------------------------------
The average number of system calls per second made to this function over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 Due to the system call instrumentation on HP-UX, the fork and vfork system 
calls are double counted.  In the case of fork and vfork, one process starts 
the system call, but two processes exit.
HP-UX lightweight system calls, such as umask, do not show up in the Glance 
System Calls display, but will get added to the global system call rates.  If 
a process is being traced (debugged) using standard debugging tools (such as 
adb or xdb), all system calls used by that process will show up in the System 
Calls display while being traced.


SYSCALL_CPU_TOTAL_TIME
----------------------------------
The CPU time, in seconds, during the interval spent executing this system 
calls.  On platforms other than HPUX, If the ignore_mt flag is set(true) in 
parm file, this metric will report values normalized against the number of 
active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



SYSCALL_CPU_TOTAL_TIME_CUM
----------------------------------
The CPU time, in seconds, over the cumulative collection time spent executing 
this system calls.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.  On platforms other than HPUX, If 
the ignore_mt flag is set(true) in parm file, this metric will report values 
normalized against the number of active cores in the system.
If the ignore_mt flag is not set(false) in parm file, this metric will report 
values normalized against the number of threads in the system. This flag will 
be a no-op if Multithreading is turned off.
On HPUX, CPU utilization normalization is controlled by the “-ignore_mt” 
option of the midaemon(1m). To change normalization from core-based to 
logical-cpu-based, or vice-versa, all performance components (scopeux, 
glance, perfd) must be shut down and the midaemon restarted in the desired 
mode. To start the midaemon with “-ignore_mt” by default, this option should 
be added in the /etc/rc.config.d/ovpa control file. Refer to the 
documentation regarding ovpa startup. Note that, on HPUX, unlike other 
platforms, specifying core-based normalization affects CPU, application, 
process and thread metrics.



SYSCALL_INTERVAL
----------------------------------
The amount of time in the interval.


SYSCALL_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TBL_BUFFER_HEADER_AVAIL
----------------------------------
This is the maximum number of headers pointing to buffers in the file system 
buffer cache.
On HP-UX, this is the configured number, not the maximum number.  This can be 
set by the “nbuf” kernel configuration parameter.  nbuf is used to determine 
the maximum total number of buffers on the system.
On HP-UX, these are used to manage the buffer cache, which is used for all 
block IO operations.  When nbuf is zero, this value depends on the “bufpages” 
size of memory (see System Administration Tasks manual).  A value of “na” 
indicates either a dynamic buffer cache configuration, or the nbuf kernel 
parameter has been left unconfigured and allowed to “float” with the bufpages 
parameter.  This is not a maximum available value in a fixed buffer cache 
configuration.  Instead, it is the initial configured value.  The actual 
number of used buffer headers can grow beyond this initial value.
On SUN, this value is “nbuf”.
 On SUN, the buffer cache is a memory pool used by the system to cache inode, 
indirect block and cylinder group related disk accesses.  This is different 
from the traditional concept of a buffer cache that also holds file system 
data.  On Solaris 5.X, as file data is cached, accesses to it show up as 
virtual memory IOs.  File data caching occurs through memory mapping managed 
by the virtual memory system, not through the buffer cache.  The “nbuf” value 
is dynamic, but it is very hard to create a situation where the memory cache 
metrics change, since most systems have more than adequate space for inode, 
indirect block, and cylinder group data caching.  This cache is more heavily 
utilized on NFS file servers.


TBL_BUFFER_HEADER_USED
----------------------------------
The number of buffer headers currently in use.
On HP-UX, this dynamic value will rarely change once the system boots.  
During the system bootup, the kernel allocates a large number of buffer 
headers and the count is likely to stay at that value after the bootup 
completes.  If the value increases beyond the initial boot value, it will not 
decrease.  Buffer headers are allocated in kernel memory, not user memory, 
and therefore, will not decrease.  This value can exceed the available or 
configured number of buffer headers in a fixed buffer cache configuration.
 On SUN, the buffer cache is a memory pool used by the system to cache inode, 
indirect block and cylinder group related disk accesses.  This is different 
from the traditional concept of a buffer cache that also holds file system 
data.  On Solaris 5.X, as file data is cached, accesses to it show up as 
virtual memory IOs.  File data caching occurs through memory mapping managed 
by the virtual memory system, not through the buffer cache.  The “nbuf” value 
is dynamic, but it is very hard to create a situation where the memory cache 
metrics change, since most systems have more than adequate space for inode, 
indirect block, and cylinder group data caching.  This cache is more heavily 
utilized on NFS file servers.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_BUFFER_HEADER_USED_HIGH
----------------------------------
The largest number of buffer headers used in any one interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On SUN, the buffer cache is a memory pool used by the system to cache inode, 
indirect block and cylinder group related disk accesses.  This is different 
from the traditional concept of a buffer cache that also holds file system 
data.  On Solaris 5.X, as file data is cached, accesses to it show up as 
virtual memory IOs.  File data caching occurs through memory mapping managed 
by the virtual memory system, not through the buffer cache.  The “nbuf” value 
is dynamic, but it is very hard to create a situation where the memory cache 
metrics change, since most systems have more than adequate space for inode, 
indirect block, and cylinder group data caching.  This cache is more heavily 
utilized on NFS file servers.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_BUFFER_HEADER_UTIL
----------------------------------
The percentage of buffer headers currently used.
On HP-UX, a value of “na” indicates either a dynamic buffer cache 
configuration, or the nbuf kernel parameter has been left unconfigured and 
allowed to “float” with the bufpages parameter.
 On SUN, the buffer cache is a memory pool used by the system to cache inode, 
indirect block and cylinder group related disk accesses.  This is different 
from the traditional concept of a buffer cache that also holds file system 
data.  On Solaris 5.X, as file data is cached, accesses to it show up as 
virtual memory IOs.  File data caching occurs through memory mapping managed 
by the virtual memory system, not through the buffer cache.  The “nbuf” value 
is dynamic, but it is very hard to create a situation where the memory cache 
metrics change, since most systems have more than adequate space for inode, 
indirect block, and cylinder group data caching.  This cache is more heavily 
utilized on NFS file servers.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_BUFFER_HEADER_UTIL_HIGH
----------------------------------
The highest percentage of buffer header used in any one interval over the 
cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
On HP-UX, a value of “na” indicates either a dynamic buffer cache 
configuration, or the nbuf kernel parameter has been left unconfigured and 
allowed to “float” with the bufpages parameter.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_LOCK_AVAIL
----------------------------------
The configured number of file or record locks that can be allocated on the 
system.  Files and/or records are locked by calls to lockf(2). On Linux 
kernel versions 2.4 and above, available file orrecord locks is a dynamic 
value which can grow up to   max unsigned long.


TBL_FILE_LOCK_USED
----------------------------------
The number of file or record locks currently in use.  One file can have 
multiple locks.  Files and/or records are locked by calls to lockf(2).
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.
 On Solaris non-global zones, this metric is N/A.


TBL_FILE_LOCK_USED_HIGH
----------------------------------
The highest number of file locks used by the file system in any one interval 
over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_LOCK_UTIL
----------------------------------
The percentage of configured file or record locks currently in use. On Linux 
2.4 and above kernel versions, this may not give correct picture as file or 
record locks  available may change dynamically and can grow up to max 
unsigned long.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_LOCK_UTIL_HIGH
----------------------------------
The highest percentage of configured file or record locks that have been in 
use during any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_TABLE_AVAIL
----------------------------------
The number of entries in the file table.
On HP-UX and AIX, this is the configured maximum number of the file table 
entries used by the kernel to manage open file descriptors.
On HP-UX, this is the sum of the “nfile” and “file_pad” values used in kernel 
generation.
On SUN, this is the number of entries in the file cache.  This is a size.  
All entries are not always in use.  The cache size is dynamic.  Entries in 
this cache are used to manage open file descriptors.  They are reused as 
files are closed and new ones are opened.  The size of the cache will go up 
or down in chunks as more or less space is required in the cache.
On AIX, the file table entries are dynamically allocated by the kernel if 
there is no entry available.  These entries are allocated in chunks.


TBL_FILE_TABLE_USED
----------------------------------
The number of entries in the file table currently used by file descriptors.
On SUN, this is the number of file cache entries currently used by file 
descriptors.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_TABLE_USED_HIGH
----------------------------------
The highest number of entries in the file table that is used by file 
descriptors in any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_TABLE_UTIL
----------------------------------
The percentage of file table entries currently used by file descriptors.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_FILE_TABLE_UTIL_HIGH
----------------------------------
The highest percentage of entries in the file table used by file descriptors 
in any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_INODE_CACHE_AVAIL
----------------------------------
On HP-UX, this is the configured total number of entries for the incore inode 
tables on the system.  For HP-UX releases prior to 11.2x, this value reflects 
only the HFS inode table.  For subsequent HP-UX releases, this value is the 
sum of inode tables for both HFS and VxFS file systems (ninode plus 
vxfs_ninode).
 On HP-UX, file system directory activity is done through inodes that are 
stored on disk.  The kernel keeps a memory cache of active and recently 
accessed inodes to reduce disk IOs.  When a file is opened through a 
pathname, the kernel converts the pathname to an inode number and attempts to 
obtain the inode information from the cache based on the filesystem type.  If 
the inode entry is not in the cache, the inode is read from disk into the 
inode cache.
On HP-UX, the number of used entries in the inode caches are usually at or 
near the capacity.  This does not necessarily indicate that the configured 
sizes are too small because the tables may contain recently used inodes and 
inodes referenced by entries in the directory name lookup cache.  When a new 
inode cache entry is required and a free entry does not exist, inactive 
entries referenced by the directory name cache are used.  If after freeing 
inode entries only referenced by the directory name cache does not create 
enough free space, the message “inode: table is full” message may appear on 
the console.  If this occurs, increase the size of the kernel parameter, 
ninode.  Low directory name cache hit ratios may also indicate an 
underconfigured inode cache.
On HP-UX, the default formula for the ninode size is:

  ninode = ((nproc+16+maxusers)+32+
           (2*npty)+(4*num_clients))

On all other Unix systems, this is the number of entries in the inode cache.  
This is a size.  All entries are not always in use.  The cache size is 
dynamic.
Entries in this cache are reused as files are closed and new ones are opened.  
The size of the cache will go up or down in chunks as more or less space is 
required in the cache.
 Inodes are used to store information about files within the file system.  
Every file has at least two inodes associated with it (one for the directory 
and one for the file itself).  The information stored in an inode includes 
the owners, timestamps, size, and an array of indices used to translate 
logical block numbers to physical sector numbers.  There is a separate inode 
maintained for every view of a file, so if two processes have the same file 
open, they both use the same directory inode, but separate inodes for the 
file.


TBL_INODE_CACHE_HIGH
----------------------------------
On HP-UX and OSF1, this is the highest number of inodes that have been used 
in any one interval over the cumulative collection time.
 On HP-UX, file system directory activity is done through inodes that are 
stored on disk.  The kernel keeps a memory cache of active and recently 
accessed inodes to reduce disk IOs.  When a file is opened through a 
pathname, the kernel converts the pathname to an inode number and attempts to 
obtain the inode information from the cache based on the filesystem type.  If 
the inode entry is not in the cache, the inode is read from disk into the 
inode cache.
On HP-UX, the number of used entries in the inode caches are usually at or 
near the capacity.  This does not necessarily indicate that the configured 
sizes are too small because the tables may contain recently used inodes and 
inodes referenced by entries in the directory name lookup cache.  When a new 
inode cache entry is required and a free entry does not exist, inactive 
entries referenced by the directory name cache are used.  If after freeing 
inode entries only referenced by the directory name cache does not create 
enough free space, the message “inode: table is full” message may appear on 
the console.  If this occurs, increase the size of the kernel parameter, 
ninode.  Low directory name cache hit ratios may also indicate an 
underconfigured inode cache.
On HP-UX, the default formula for the ninode size is:

  ninode = ((nproc+16+maxusers)+32+
           (2*npty)+(4*num_clients))

On all other Unix systems, this is the largest size of the inode cache in any 
one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_INODE_CACHE_USED
----------------------------------
The number of inode cache entries currently in use.
On HP-UX, this is the number of “non-free” inodes currently used.  Since the 
inode table contains recently closed inodes as well as open inodes, the table 
often appears to be fully utilized.  When a new entry is needed, one can 
usually be found by reusing one of the recently closed inode entries.
 On HP-UX, file system directory activity is done through inodes that are 
stored on disk.  The kernel keeps a memory cache of active and recently 
accessed inodes to reduce disk IOs.  When a file is opened through a 
pathname, the kernel converts the pathname to an inode number and attempts to 
obtain the inode information from the cache based on the filesystem type.  If 
the inode entry is not in the cache, the inode is read from disk into the 
inode cache.
On HP-UX, the number of used entries in the inode caches are usually at or 
near the capacity.  This does not necessarily indicate that the configured 
sizes are too small because the tables may contain recently used inodes and 
inodes referenced by entries in the directory name lookup cache.  When a new 
inode cache entry is required and a free entry does not exist, inactive 
entries referenced by the directory name cache are used.  If after freeing 
inode entries only referenced by the directory name cache does not create 
enough free space, the message “inode: table is full” message may appear on 
the console.  If this occurs, increase the size of the kernel parameter, 
ninode.  Low directory name cache hit ratios may also indicate an 
underconfigured inode cache.
On HP-UX, the default formula for the ninode size is:

  ninode = ((nproc+16+maxusers)+32+
           (2*npty)+(4*num_clients))

 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_BUFFER_ACTIVE
----------------------------------
The current active total size (in KBs unless otherwise specified) of all IPC 
message buffers.  These buffers are created by msgsnd(2) calls and released 
by msgrcv(2) calls.  This metric only counts the active message queue 
buffers, which means that a msgsnd(2) call has been made and the msgrcv(2) 
has not yet been done on the queue entry or a msgrcv(2) call is waiting on a 
message queue entry.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_BUFFER_AVAIL
----------------------------------
The maximum achievable size (in KBs unless otherwise specified) of the 
message queue buffer pool on the system.
Each message queue can contain many buffers which are created whenever a 
program issues a msgsnd(2) call.  Each of these buffers is allocated from 
this buffer pool.
Refer to the ipcs(1) man page for more information.
This value is determined by taking the product of the three kernel 
configuration variables “msgseg”, “msgssz” and “msgmni”. If the value adds up 
to a value > 2048GB, “o/f” may be reported on some platforms.
 On SUN, the InterProcess Communication facilities are dynamically loadable.  
If the amount available is zero, this facility was not loaded when data 
collection began, and its data is not obtainable.  The data collector is 
unable to determine that a facility has been loaded once data collection has 
started.  If you know a new facility has been loaded, restart the data 
collection, and the data for that facility will be collected.  See ipcs(1) to 
report on interprocess communication resources.


TBL_MSG_BUFFER_HIGH
----------------------------------
The largest size (in KBs unless otherwise specified) of the message queues in 
any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_BUFFER_USED
----------------------------------
The current total size (in KBs unless otherwise specified) of all IPC message 
buffers.  These buffers are created by msgsnd(2) calls and released by 
msgrcv(2) calls.
On HP-UX and OSF1, this field corresponds to the CBYTES field of the “ipcs -
qo” command.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_TABLE_ACTIVE
----------------------------------
The number of message queues currently active.  A message queue is allocated 
by a program using the msgget(2) call.  This metric returns only the entries 
in the message queue currently active.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_TABLE_AVAIL
----------------------------------
The configured maximum number of message queues that can be allocated on the 
system.  A message queue is allocated by a program using the msgget(2) call.
Refer to the ipcs(1) man page for more information.
 On SUN, the InterProcess Communication facilities are dynamically loadable.  
If the amount available is zero, this facility was not loaded when data 
collection began, and its data is not obtainable.  The data collector is 
unable to determine that a facility has been loaded once data collection has 
started.  If you know a new facility has been loaded, restart the data 
collection, and the data for that facility will be collected.  See ipcs(1) to 
report on interprocess communication resources.


TBL_MSG_TABLE_USED
----------------------------------
On HP-UX, this is the number of message queues currently in use.
On all other Unix systems, this is the number of message queues that have 
been built.
A message queue is allocated by a program using the msgget(2) call.  See 
ipcs(1) to list the message queues.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_TABLE_UTIL
----------------------------------
The percentage of configured message queues currently in use.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_MSG_TABLE_UTIL_HIGH
----------------------------------
The highest percentage of configured message queues that have been in use 
during any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_NUM_NFSDS
----------------------------------
The number of NFS servers configured.  This is the value “nservers” passed to 
nfsd (the NFS daemon) upon startup.  If no value is specified, the default is 
one.  This value determines the maximum number of concurrent NFS requests 
that the server can handle.  See man page for “nfsd”.


TBL_SEM_TABLE_ACTIVE
----------------------------------
The number of semaphore identifiers currently active.  This means that the 
semaphores are currently locked by processes.  Any new process requesting 
this semaphore is blocked if IPC_NOWAIT flag is not set.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SEM_TABLE_AVAIL
----------------------------------
The configured number of semaphore identifiers (sets) that can be allocated 
on the system.
 On SUN, the InterProcess Communication facilities are dynamically loadable.  
If the amount available is zero, this facility was not loaded when data 
collection began, and its data is not obtainable.  The data collector is 
unable to determine that a facility has been loaded once data collection has 
started.  If you know a new facility has been loaded, restart the data 
collection, and the data for that facility will be collected.  See ipcs(1) to 
report on interprocess communication resources.


TBL_SEM_TABLE_USED
----------------------------------
On HP-UX, this is the number of semaphore identifiers currently in use.
On all other Unix systems, this is the number of semaphore identifiers that 
have been built.
A semaphore identifier is allocated by a program using the semget(2) call.  
See ipcs(1) to list semaphores.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SEM_TABLE_UTIL
----------------------------------
The percentage of configured semaphores identifiers currently in use.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SEM_TABLE_UTIL_HIGH
----------------------------------
The highest percentage of configured semaphore identifiers that have been in 
use during any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_ACTIVE
----------------------------------
The size (in KBs unless otherwise specified) of the shared memory segments 
that have running processes attached to them.  This may be less than the 
amount of shared memory used on the system because a shared memory segment 
may exist and not have any process attached to it.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_AVAIL
----------------------------------
The maximum achievable size (in MB unless otherwise specified) of the shared 
memory pool on the system.
This is a theoretical maximum determined by multiplying the configured 
maximum number of shared memory entries (shmmni) by the maximum size of each 
shared memory segment (shmmax).  Your system may not have enough virtual 
memory to actually reach this theoretical limit - one cannot allocate more 
shared memory than the available reserved space configured for virtual 
memory.
It should be noted that this value does not include any architectural 
limitations.  (For example, on a 32-bit kernel, there is an addressing limit 
of 1.75 GB.). If the value adds up to a value > 2048TB, “o/f” may be reported 
on some platforms.
 On SUN, the InterProcess Communication facilities are dynamically loadable.  
If the amount available is zero, this facility was not loaded when data 
collection began, and its data is not obtainable.  The data collector is 
unable to determine that a facility has been loaded once data collection has 
started.  If you know a new facility has been loaded, restart the data 
collection, and the data for that facility will be collected.  See ipcs(1) to 
report on interprocess communication resources.


TBL_SHMEM_HIGH
----------------------------------
The highest size (in KBs unless otherwise specified) of shared memory used in 
any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_TABLE_ACTIVE
----------------------------------
The number of shared memory segments that have running processes attached to 
them.  This may be less than the number of shared memory segments that have 
been allocated.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_TABLE_AVAIL
----------------------------------
The configured number of shared memory segments that can be allocated on the 
system.
 On SUN, the InterProcess Communication facilities are dynamically loadable.  
If the amount available is zero, this facility was not loaded when data 
collection began, and its data is not obtainable.  The data collector is 
unable to determine that a facility has been loaded once data collection has 
started.  If you know a new facility has been loaded, restart the data 
collection, and the data for that facility will be collected.  See ipcs(1) to 
report on interprocess communication resources.


TBL_SHMEM_TABLE_USED
----------------------------------
On HP-UX, this is the number of shared memory segments currently in use.
On all other Unix systems, this is the number of shared memory segments that 
have been built.  This includes shared memory segments with no processes 
attached to them.
A shared memory segment is allocated by a program using the shmget(2) call.  
Also refer to ipcs(1).
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_TABLE_UTIL
----------------------------------
The percentage of configured shared memory segments currently in use.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_TABLE_UTIL_HIGH
----------------------------------
The highest percentage of configured shared memory segments that have been in 
use during any one interval over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


TBL_SHMEM_USED
----------------------------------
The size (in KBs unless otherwise specified) of the shared memory segments.
Additionally, it includes memory segments to which no processes are attached.  
If a shared memory segment has zero attachments, the space may not always be 
allocated in memory.  See ipcs(1) to list shared memory segments.
 On Unix systems, this metric is updated every 30 seconds or the sampling 
interval, whichever is greater.


THREADSYSCALL_ACTIVE_CUM
----------------------------------
The number of different system calls called by this thread during the time it 
has been enabled for system call profiling.


THREADSYSCALL_CALL_COUNT
----------------------------------
The number of system calls made to this function by this thread during the 
interval.


THREADSYSCALL_CALL_COUNT_CUM
----------------------------------
The number of system calls made by this thread to this function during the 
time it has been enabled for system call profiling.


THREADSYSCALL_CALL_ID
----------------------------------
The ID number of the system call.  System calls are sequentially numbered 
starting with one.


THREADSYSCALL_CALL_NAME
----------------------------------
The system call name.


THREADSYSCALL_CALL_RATE
----------------------------------
The number of system calls per second made by this thread to this function 
during the last interval.


THREADSYSCALL_CALL_RATE_CUM
----------------------------------
The average number of system calls per second made by this thread to this 
function during the time it has been enabled for system call profiling.


THREADSYSCALL_INTERVAL
----------------------------------
The amount of time in the interval.


THREADSYSCALL_INTERVAL_CUM
----------------------------------
The time, in seconds, system call data has been collected for this thread.


THREADSYSCALL_TOTAL_TIME
----------------------------------
The elapsed time, in seconds, this thread was in this system call.  This 
value maybe greater then the interval time since the system call may have 
been started before the interval started.


THREADSYSCALL_TOTAL_TIME_CUM
----------------------------------
The total elapsed time, in seconds, that this thread was in this system call.  
This value maybe greater than the cumulative interval time since the system 
call may have been started before data collection.


TTBIN_TRANS_COUNT 
TT_CLIENT_BIN_TRANS_COUNT
----------------------------------
The number of completed transactions in this range during the last interval.


TTBIN_TRANS_COUNT_CUM 
TT_CLIENT_BIN_TRANS_COUNT_CUM
----------------------------------
The number of completed transactions in this range over the cumulative 
collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TTBIN_UPPER_RANGE
----------------------------------
The upper range (transaction time) for this TT bin.
 There are a maximum of nine user-defined transaction response time bins 
(TTBIN_UPPER_RANGE).  The last bin, which is not specified in the transaction 
configuration file (ttdconf.mwc on Windows or ttd.conf on UNIX platforms), is 
the overflow bin and will always have a value of -2 (overflow).  Note that 
the values specified in the transaction configuration file cannot exceed 
2147483.6, which is the number of seconds in 24.85 days.  If the user 
specifies any values greater than 2147483.6, the numbers reported for those 
bins or Service Level Objectives (SLO) will be -2.


TT_ABORT 
TT_CLIENT_ABORT
----------------------------------
The number of aborted transactions during the last interval for this 
transaction.


TT_ABORT_CUM 
TT_CLIENT_ABORT_CUM
----------------------------------
The number of aborted transactions over the cumulative collection time for 
this transaction.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_ABORT_WALL_TIME 
TT_CLIENT_ABORT_WALL_TIME
----------------------------------
The total time, in seconds, of all aborted transactions during the last 
interval for this transaction.


TT_ABORT_WALL_TIME_CUM 
TT_CLIENT_ABORT_WALL_TIME_CUM
----------------------------------
The total time, in seconds, of all aborted transactions over the cumulative 
collection time for this transaction class.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_APPNO
----------------------------------
The registered ARM Application/User ID for this transaction class.


TT_APP_NAME
----------------------------------
The registered ARM Application name.


TT_CLIENT_ADDRESS 
TT_INSTANCE_CLIENT_ADDRESS
----------------------------------
The correlator address.  This is the address where the child transaction 
originated.


TT_CLIENT_ADDRESS_FORMAT 
TT_INSTANCE_CLIENT_ADDRESS_FORMAT
----------------------------------
The correlator address format.  This shows the protocol family for the client 
network address.  Refer to the ARM API Guide for the list and description of 
supported address formats.


TT_CLIENT_CORRELATOR_COUNT
----------------------------------
The number of client or child transaction correlators this transaction has 
started over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_CLIENT_TRAN_ID 
TT_INSTANCE_CLIENT_TRAN_ID
----------------------------------
A numerical ID that uniquely identifies the transaction class in this 
correlator.


TT_COUNT 
TT_CLIENT_COUNT
----------------------------------
The number of completed transactions during the last interval for this 
transaction.


TT_COUNT_CUM 
TT_CLIENT_COUNT_CUM
----------------------------------
The number of completed transactions over the cumulative collection time for 
this transaction.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_FAILED 
TT_CLIENT_FAILED
----------------------------------
The number of Failed transactions during the last interval for this 
transaction name.


TT_FAILED_CUM 
TT_CLIENT_FAILED_CUM
----------------------------------
The number of failed transactions over the cumulative collection time for 
this transaction name.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_FAILED_WALL_TIME 
TT_CLIENT_FAILED_WALL_TIME
----------------------------------
The total time, in seconds, of all failed transactions during the last 
interval for this transaction name.


TT_FAILED_WALL_TIME_CUM 
TT_CLIENT_FAILED_WALL_TIME_CUM
----------------------------------
The total time, in seconds, of all failed transactions over the cumulative 
collection time for this transaction name.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_INFO
----------------------------------
The registered ARM Transaction Information for this transaction.


TT_INPROGRESS_COUNT
----------------------------------
The number of transactions in progress (started, but not stopped) at the end 
of the interval for this transaction class.


TT_INSTANCE_ID
----------------------------------
A numerical ID that uniquely identifies this transaction instance at the end 
of the interval.


TT_INSTANCE_PROC_ID
----------------------------------
The ID of the process that started or last updated the transaction instance.


TT_INSTANCE_START_TIME
----------------------------------
The time this transaction instance started.


TT_INSTANCE_STOP_TIME
----------------------------------
The time this transaction instance stopped.  If the transaction instance is 
currently active, the value returned will be -1.  It will be shown as “na” in 
Glance and GPM to indicate that the transaction instance did not stop during 
the interval.


TT_INSTANCE_THREAD_ID
----------------------------------
The ID of the kernel thread that started or last updated the transaction 
instance.


TT_INSTANCE_UPDATE_COUNT
----------------------------------
The number of times this transaction instance called update since the start 
of this transaction instance.


TT_INSTANCE_UPDATE_TIME
----------------------------------
The time this transaction instance last called update.  If the transaction 
instance is currently active, the value returned will be -1.  It will be 
shown as “na” in Glance and GPM to indicate that a call to update did not 
occur during the interval.


TT_INSTANCE_WALL_TIME
----------------------------------
The elapsed time since this transaction instance was started.


TT_INTERVAL 
TT_CLIENT_INTERVAL
----------------------------------
The amount of time in the collection interval.


TT_INTERVAL_CUM 
TT_CLIENT_INTERVAL_CUM
----------------------------------
The amount of time over the cumulative collection time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_MEASUREMENT_COUNT
----------------------------------
The number of user defined measurements for this transaction class.


TT_NAME
----------------------------------
The registered transaction name for this transaction.


TT_SLO_COUNT 
TT_CLIENT_SLO_COUNT
----------------------------------
The number of completed transactions that violated the defined Service Level 
Objective (SLO) by exceeding the SLO threshold time during the interval.


TT_SLO_COUNT_CUM 
TT_CLIENT_SLO_COUNT_CUM
----------------------------------
The number of completed transactions that violated the defined Service Level 
Objective by exceeding the SLO threshold time over the cumulative collection 
time.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_SLO_PERCENT
----------------------------------
The percentage of transactions which violate service level objectives.


TT_SLO_THRESHOLD
----------------------------------
The upper range (transaction time) of the Service Level Objective (SLO) 
threshold value.  This value is used to count the number of transactions that 
exceed this user-supplied transaction time value.


TT_TRAN_1_MIN_RATE
----------------------------------
For this transaction name, the number of completed transactions calculated to 
a 1 minute rate.  For example, if you completed five of these transactions in 
a 5 minute window, the rate is one transaction per minute.


TT_TRAN_ID
----------------------------------
The registered ARM Transaction ID for this transaction class as returned by 
arm_getid().   A unique transaction id is returned for a unique application 
id (returned by arm_init), tran name, and meta data buffer contents.


TT_UID
----------------------------------
The registered ARM Transaction User ID for this transaction name.


TT_UNAME
----------------------------------
The registered ARM Transaction User Name for this transaction.
If the arm_init function has NULL for the appl_user_id field, then the user 
name is blank.  Otherwise, if “*” was specified, then the user name is 
displayed.
For example, to show the user name for the armsample1 program, use:

appl_id = arm_init(“armsample1”,”*”,0,0,0);
To ignore the user name for the armsample1 program, use:

appl_id = arm_init(“armsample1”,NULL,0,0,0);



TT_UPDATE 
TT_CLIENT_UPDATE
----------------------------------
The number of updates during the last interval for this transaction class.  
This count includes update calls for completed and in progress transactions.


TT_UPDATE_CUM 
TT_CLIENT_UPDATE_CUM
----------------------------------
The number of updates over the cumulative collection time for this 
transaction class.  This count includes update calls for completed and in 
progress transactions.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_USER_MEASUREMENT_AVG 
TT_INSTANCE_USER_MEASUREMENT_AVG 
TT_CLIENT_USER_MEASUREMENT_AVG
----------------------------------
If the measurement type is a numeric or a string, this metric returns “na”.
If the measurement type is a counter, this metric returns the average counter 
differences of the transaction or transaction instance during the last 
interval.  The counter value is the difference observed from a counter 
between the start and the stop (or last update) of a transaction.
If the measurement type is a gauge, this returns the average of the values 
passed on any ARM call for the transaction or transaction instance during the 
last interval.


TT_USER_MEASUREMENT_MAX 
TT_INSTANCE_USER_MEASUREMENT_MAX 
TT_CLIENT_USER_MEASUREMENT_MAX
----------------------------------
If the measurement type is a numeric or a string, this metric returns “na”.
If the measurement type is a counter, this metric returns the highest 
measured counter value over the life of the transaction or transaction 
instance.  The counter value is the difference observed from a counter 
between the start and the stop (or last update) of a transaction.
If the measurement type is a gauge, this metric returns the highest value 
passed on any ARM call over the life of the transaction or transaction 
instance.


TT_USER_MEASUREMENT_MIN 
TT_INSTANCE_USER_MEASUREMENT_MIN 
TT_CLIENT_USER_MEASUREMENT_MIN
----------------------------------
If the measurement type is a numeric or a string, this metric returns “na”.
If the measurement type is a counter, this metric returns the lowest measured 
counter value over the life of the transaction or transaction instance.  The 
counter value is the difference observed from a counter between the start and 
the stop (or last update) of a transaction.
If the measurement type is a gauge, this metric returns the lowest value 
passed on any ARM call over the life of the transaction or transaction 
instance.


TT_USER_MEASUREMENT_NAME 
TT_INSTANCE_USER_MEASUREMENT_NAME 
TT_CLIENT_USER_MEASUREMENT_NAME
----------------------------------
The name of the user defined transactional measurement.  The length of the 
string complies with the ARM 2.0 standard, which is 44 characters long (there 
are 43 usable characters since this is a NULL terminated character string).


TT_USER_MEASUREMENT_STRING1024_VALUE 
TT_INSTANCE_USER_MEASUREMENT_STRING1024_VALUE 
TT_CLIENT_USER_MEASUREMENT_STRING1024_VALUE
----------------------------------
The last value of the user defined measurement of type string 1024.  This 
type is not implemented and the value is always “na”.


TT_USER_MEASUREMENT_STRING32_VALUE 
TT_INSTANCE_USER_MEASUREMENT_STRING32_VALUE 
TT_CLIENT_USER_MEASUREMENT_STRING32_VALUE
----------------------------------
The last value of the user defined measurement of type string 32.


TT_USER_MEASUREMENT_TYPE 
TT_INSTANCE_USER_MEASUREMENT_TYPE 
TT_CLIENT_USER_MEASUREMENT_TYPE
----------------------------------
The type of the user defined transactional measurement.

  1 = ARM_COUNTER32
  2 = ARM_COUNTER64
  3 = ARM_CNTRDIVR32
  4 = ARM_GAUGE32
  5 = ARM_GAUGE64
  6 = ARM_GAUGEDIVR32
  7 = ARM_NUMERICID32
  8 = ARM_NUMERICID64
  9 = ARM_STRING8    (max 8 chars)
 10 = ARM_STRING32   (max 32 chars)
 11 = ARM_STRING1024 (max 1024 char -- not implemented)



TT_USER_MEASUREMENT_VALUE 
TT_INSTANCE_USER_MEASUREMENT_VALUE 
TT_CLIENT_USER_MEASUREMENT_VALUE
----------------------------------
The last value of the user defined measurement of type counter, gauge, 
numeric ID, or string 8.  Both 32 and 64 bit numeric types are returned as 64 
bit values.


TT_WALL_TIME 
TT_CLIENT_WALL_TIME
----------------------------------
The total time, in seconds, of all transactions completed during the last 
interval for this transaction.


TT_WALL_TIME_CUM 
TT_CLIENT_WALL_TIME_CUM
----------------------------------
The total time, in seconds, of all transactions completed over the cumulative 
collection time for this transaction.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.


TT_WALL_TIME_PER_TRAN 
TT_CLIENT_WALL_TIME_PER_TRAN
The average transaction time, in seconds, during the last interval for this 
transaction.


TT_WALL_TIME_PER_TRAN_CUM 
TT_CLIENT_WALL_TIME_PER_TRAN_CUM
----------------------------------
The average transaction time, in seconds, over the cumulative collection time 
for this transaction.
 The cumulative collection time is defined from the point in time when 
either:  a) the process (or thread) was first started, or b) the performance 
tool was first started, or c) the cumulative counters were reset (relevant 
only to Glance, if available for the given platform), whichever occurred 
last.
On HP-UX, all cumulative collection times and intervals start when the 
midaemon starts. On other Unix systems, non-process collection time starts 
from the start of the performance tool, process collection time starts from 
the start time of the process or measurement start time, which ever is older. 
Regardless of the process start time, application cumulative intervals start 
from the time the performance tool is started.
On systems where the performance components are 32-bit or where the 64-bit 
model is LLP64 (Windows), all INTERVAL_CUM metrics will start reporting “o/f” 
(overflow) after the performance agent (or the midaemon on HPUX) has been up 
for 466 days and the cumulative metrics will fail to report accurate data 
after 497 days. On Linux, Solaris and AIX, if measurement is started after 
the system has been up for more than 466 days, cumulative process CPU data 
won’t include times accumulated prior to the performance tool’s start and a 
message will be logged to indicate this.