HP Operations Agent - Performance Collection Component for Linux Dictionary of Operating System Performance Metrics Print Date 10/2011 HP Operations Agent for Linux Release 11.00 ************************************************************* Legal Notices ============= Warranty -------- The only warranties for HP products and services are set forth in the express warranty statements accompanying such products and services. Nothing herein should be construed as constituting an additional warranty. HP shall not be liable for technical or editorial errors or omissions contained herein. The information contained herein is subject to change without notice. Restricted Rights Legend ------------------------ Confidential computer software. Valid license from HP required for possession, use or copying. Consistent with FAR 12.211 and 12.212, Commercial Computer Software, Computer Software Documentation, and Technical Data for Commercial Items are licensed to the U.S. Government under vendor's standard commercial license. Copyright Notices ----------------- ©Copyright 2010 - 2011 Hewlett-Packard Development Company, L.P. All rights reserved. ***************************************************************** Introduction ============ This dictionary contains definitions of the Linux operating system performance metrics for the Performance Collection Component. This document is divided into the following sections: * "Metric Names by Data Class," which lists the metrics alphabetically by data class. Use these metric names for exporting data with the extract utility. You can also use these metric names in defining alarm conditions in your alarmdef file. * "Metric Definitions," which describes each metric in alphabetical order. Please note that the metric help has been put in a more generic format and references are made to the other platforms that also support each of the metrics. Metric Names by Data Class ========================== Linux Global Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR GBL_ACTIVE_CPU GBL_ACTIVE_PROC GBL_ALIVE_PROC GBL_CPU_CLOCK GBL_CPU_ENTL_UTIL GBL_CPU_IDLE_TIME GBL_CPU_IDLE_UTIL GBL_CPU_MT_ENABLED GBL_CPU_NICE_TIME GBL_CPU_NICE_UTIL GBL_CPU_NUM_THREADS GBL_CPU_PHYSC GBL_CPU_PHYS_TOTAL_UTIL GBL_CPU_SYS_MODE_TIME GBL_CPU_SYS_MODE_UTIL GBL_CPU_TOTAL_TIME GBL_CPU_TOTAL_UTIL GBL_CPU_USER_MODE_TIME GBL_CPU_USER_MODE_UTIL GBL_CPU_WAIT_UTIL GBL_CSWITCH_RATE GBL_DISK_PHYS_BYTE GBL_DISK_PHYS_BYTE_RATE GBL_DISK_PHYS_IO GBL_DISK_PHYS_IO_RATE GBL_DISK_PHYS_READ GBL_DISK_PHYS_READ_BYTE_RATE GBL_DISK_PHYS_READ_PCT GBL_DISK_PHYS_READ_RATE GBL_DISK_PHYS_WRITE GBL_DISK_PHYS_WRITE_BYTE_RATE GBL_DISK_PHYS_WRITE_RATE GBL_DISK_REQUEST_QUEUE GBL_DISK_TIME_PEAK GBL_DISK_UTIL GBL_DISK_UTIL_PEAK GBL_FS_SPACE_UTIL_PEAK GBL_INTERRUPT GBL_INTERRUPT_RATE GBL_INTERVAL GBL_LOADAVG GBL_LOADAVG15 GBL_LOADAVG5 GBL_LOST_MI_TRACE_BUFFERS GBL_MACHINE_MEM_USED GBL_MEM_CACHE GBL_MEM_CACHE_UTIL 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_RATE GBL_MEM_PAGEIN_RATE GBL_MEM_PAGEOUT GBL_MEM_PAGEOUT_BYTE GBL_MEM_PAGEOUT_BYTE_RATE GBL_MEM_PAGEOUT_RATE GBL_MEM_PAGE_FAULT_RATE GBL_MEM_PAGE_REQUEST GBL_MEM_PAGE_REQUEST_RATE GBL_MEM_PHYS_SWAPPED GBL_MEM_SWAPIN_BYTE GBL_MEM_SWAPIN_BYTE_RATE GBL_MEM_SWAPOUT_BYTE GBL_MEM_SWAPOUT_BYTE_RATE GBL_MEM_SYS GBL_MEM_SYS_UTIL GBL_MEM_USER GBL_MEM_USER_UTIL GBL_MEM_UTIL GBL_NET_COLLISION GBL_NET_COLLISION_1_MIN_RATE GBL_NET_COLLISION_PCT GBL_NET_COLLISION_RATE GBL_NET_ERROR GBL_NET_ERROR_1_MIN_RATE GBL_NET_ERROR_RATE GBL_NET_IN_ERROR_PCT GBL_NET_IN_ERROR_RATE GBL_NET_IN_PACKET GBL_NET_IN_PACKET_RATE GBL_NET_OUT_ERROR_PCT GBL_NET_OUT_ERROR_RATE GBL_NET_OUT_PACKET GBL_NET_OUT_PACKET_RATE GBL_NET_PACKET_RATE GBL_NFS_CALL GBL_NFS_CALL_RATE GBL_NUM_DISK GBL_NUM_NETWORK GBL_NUM_USER GBL_PROC_SAMPLE GBL_RUN_QUEUE GBL_STARTED_PROC GBL_STARTED_PROC_RATE GBL_STATTIME GBL_SWAP_SPACE_DEVICE_AVAIL GBL_SWAP_SPACE_USED GBL_SWAP_SPACE_USED_UTIL GBL_SWAP_SPACE_UTIL GBL_SYSTEM_UPTIME_HOURS GBL_SYSTEM_UPTIME_SECONDS GBL_TT_OVERFLOW_COUNT STATDATE STATTIME TBL_FILE_LOCK_USED TBL_FILE_LOCK_UTIL TBL_FILE_TABLE_USED TBL_FILE_TABLE_UTIL TBL_INODE_CACHE_USED TBL_MSG_TABLE_USED TBL_MSG_TABLE_UTIL TBL_SEM_TABLE_USED TBL_SEM_TABLE_UTIL TBL_SHMEM_ACTIVE TBL_SHMEM_TABLE_USED TBL_SHMEM_TABLE_UTIL TBL_SHMEM_USED Linux Application Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR 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_USER_MODE_TIME APP_CPU_USER_MODE_UTIL 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_PROC_RUN_TIME APP_SAMPLE Linux Process Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR PROC_APP_ID PROC_CPU_ALIVE_SYS_MODE_UTIL PROC_CPU_ALIVE_TOTAL_UTIL PROC_CPU_ALIVE_USER_MODE_UTIL PROC_CPU_SYS_MODE_TIME PROC_CPU_SYS_MODE_UTIL 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_UTIL PROC_EUID PROC_GROUP_ID PROC_INTEREST PROC_INTERVAL_ALIVE PROC_MAJOR_FAULT PROC_MEM_RES PROC_MEM_VIRT PROC_MINOR_FAULT PROC_PAGEFAULT PROC_PAGEFAULT_RATE PROC_PARENT_PROC_ID PROC_PRI PROC_PROC_ARGV1 PROC_PROC_CMD PROC_PROC_ID PROC_PROC_NAME PROC_RUN_TIME PROC_STARTTIME PROC_STOP_REASON PROC_THREAD_COUNT PROC_TTY PROC_USER_NAME Linux Transaction Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR TTBIN_TRANS_COUNT_1 TTBIN_TRANS_COUNT_10 TTBIN_TRANS_COUNT_2 TTBIN_TRANS_COUNT_3 TTBIN_TRANS_COUNT_4 TTBIN_TRANS_COUNT_5 TTBIN_TRANS_COUNT_6 TTBIN_TRANS_COUNT_7 TTBIN_TRANS_COUNT_8 TTBIN_TRANS_COUNT_9 TTBIN_UPPER_RANGE_1 TTBIN_UPPER_RANGE_10 TTBIN_UPPER_RANGE_2 TTBIN_UPPER_RANGE_3 TTBIN_UPPER_RANGE_4 TTBIN_UPPER_RANGE_5 TTBIN_UPPER_RANGE_6 TTBIN_UPPER_RANGE_7 TTBIN_UPPER_RANGE_8 TTBIN_UPPER_RANGE_9 TT_ABORT TT_ABORT_WALL_TIME_PER_TRAN TT_APP_NAME TT_APP_TRAN_NAME TT_CLIENT_ADDRESS TT_CLIENT_ADDRESS_FORMAT TT_CLIENT_TRAN_ID TT_COUNT TT_FAILED TT_INFO TT_NAME TT_NUM_BINS TT_SLO_COUNT TT_SLO_PERCENT TT_SLO_THRESHOLD TT_TRAN_1_MIN_RATE TT_TRAN_ID TT_UNAME TT_USER_MEASUREMENT_AVG TT_USER_MEASUREMENT_AVG_2 TT_USER_MEASUREMENT_AVG_3 TT_USER_MEASUREMENT_AVG_4 TT_USER_MEASUREMENT_AVG_5 TT_USER_MEASUREMENT_AVG_6 TT_USER_MEASUREMENT_MAX TT_USER_MEASUREMENT_MAX_2 TT_USER_MEASUREMENT_MAX_3 TT_USER_MEASUREMENT_MAX_4 TT_USER_MEASUREMENT_MAX_5 TT_USER_MEASUREMENT_MAX_6 TT_USER_MEASUREMENT_MIN TT_USER_MEASUREMENT_MIN_2 TT_USER_MEASUREMENT_MIN_3 TT_USER_MEASUREMENT_MIN_4 TT_USER_MEASUREMENT_MIN_5 TT_USER_MEASUREMENT_MIN_6 TT_USER_MEASUREMENT_NAME TT_USER_MEASUREMENT_NAME_2 TT_USER_MEASUREMENT_NAME_3 TT_USER_MEASUREMENT_NAME_4 TT_USER_MEASUREMENT_NAME_5 TT_USER_MEASUREMENT_NAME_6 TT_WALL_TIME_PER_TRAN Linux Disk Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR BYDSK_AVG_REQUEST_QUEUE BYDSK_AVG_SERVICE_TIME BYDSK_DEVNAME BYDSK_DIRNAME BYDSK_PHYS_BYTE BYDSK_PHYS_BYTE_RATE BYDSK_PHYS_IO BYDSK_PHYS_IO_RATE BYDSK_PHYS_READ BYDSK_PHYS_READ_BYTE BYDSK_PHYS_READ_BYTE_RATE BYDSK_PHYS_READ_RATE BYDSK_PHYS_WRITE BYDSK_PHYS_WRITE_BYTE BYDSK_PHYS_WRITE_BYTE_RATE BYDSK_PHYS_WRITE_RATE BYDSK_REQUEST_QUEUE BYDSK_UTIL Linux Network Interface Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR BYNETIF_COLLISION BYNETIF_COLLISION_1_MIN_RATE BYNETIF_COLLISION_RATE BYNETIF_ERROR BYNETIF_ERROR_1_MIN_RATE BYNETIF_ERROR_RATE BYNETIF_ID BYNETIF_IN_BYTE BYNETIF_IN_BYTE_RATE BYNETIF_IN_BYTE_RATE_CUM BYNETIF_IN_PACKET BYNETIF_IN_PACKET_RATE BYNETIF_NAME BYNETIF_NET_TYPE BYNETIF_OUT_BYTE BYNETIF_OUT_BYTE_RATE BYNETIF_OUT_BYTE_RATE_CUM BYNETIF_OUT_PACKET BYNETIF_OUT_PACKET_RATE BYNETIF_PACKET_RATE Linux CPU Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR BYCPU_CPU_CLOCK BYCPU_CPU_SYS_MODE_TIME BYCPU_CPU_SYS_MODE_UTIL BYCPU_CPU_TOTAL_TIME BYCPU_CPU_TOTAL_UTIL BYCPU_CPU_USER_MODE_TIME BYCPU_CPU_USER_MODE_UTIL BYCPU_ID BYCPU_INTERRUPT BYCPU_INTERRUPT_RATE BYCPU_STATE Linux Filesystem Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR FS_BLOCK_SIZE FS_DEVNAME FS_DEVNO FS_DIRNAME FS_FRAG_SIZE FS_INODE_UTIL FS_MAX_INODES FS_MAX_SIZE FS_SPACE_RESERVED FS_SPACE_USED FS_SPACE_UTIL FS_TYPE Linux Configuration Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR GBL_ACTIVE_CPU_CORE GBL_APP_THRESHOLD GBL_BOOT_TIME GBL_BYCPU_THRESHOLD GBL_BYDSK_THRESHOLD GBL_BYFS_THRESHOLD GBL_BYNETIF_THRESHOLD GBL_COLLECTOR GBL_COLLECT_INTERVAL GBL_COLLECT_INTERVAL_PROC GBL_CPU_CYCLE_ENTL_MAX GBL_CPU_CYCLE_ENTL_MIN GBL_CPU_ENTL_MAX GBL_CPU_ENTL_MIN GBL_CPU_SHARES_PRIO GBL_DISTRIBUTION GBL_FLUSH GBL_GMTOFFSET GBL_IGNORE_MT GBL_JAVAARG GBL_LOGFILE_VERSION GBL_LOGGING_TYPES GBL_LS_MODE GBL_LS_ROLE GBL_LS_SHARED GBL_LS_TYPE GBL_MACHINE GBL_MACHINE_MODEL GBL_MEM_AVAIL GBL_MEM_ENTL_MAX GBL_MEM_ENTL_MIN GBL_MEM_PHYS GBL_MEM_SHARES_PRIO GBL_NUM_ACTIVE_LS GBL_NUM_APP GBL_NUM_CPU GBL_NUM_CPU_CORE GBL_NUM_LS GBL_NUM_SOCKET GBL_OSKERNELTYPE_INT GBL_OSNAME GBL_OSRELEASE GBL_OSVERSION GBL_SUBPROCSAMPLEINTERVAL GBL_SWAP_SPACE_AVAIL GBL_SWAP_SPACE_AVAIL_KB GBL_SYSTEM_ID GBL_THRESHOLD_CPU GBL_THRESHOLD_NOKILLED GBL_THRESHOLD_NONEW GBL_THRESHOLD_PROCMEM TBL_FILE_LOCK_AVAIL TBL_FILE_TABLE_AVAIL TBL_INODE_CACHE_AVAIL TBL_MSG_TABLE_AVAIL TBL_SEM_TABLE_AVAIL TBL_SHMEM_TABLE_AVAIL Linux Logical System Metrics ---------------------------------- BLANK DATE DATE_SECONDS DAY INTERVAL RECORD_TYPE TIME YEAR BYLS_BOOT_TIME BYLS_CLUSTER_NAME BYLS_CPU_CLOCK BYLS_CPU_CYCLE_ENTL_MAX BYLS_CPU_CYCLE_ENTL_MIN BYLS_CPU_CYCLE_TOTAL_USED BYLS_CPU_ENTL_EMIN BYLS_CPU_ENTL_MAX BYLS_CPU_ENTL_MIN BYLS_CPU_ENTL_UTIL BYLS_CPU_MT_ENABLED BYLS_CPU_PHYSC BYLS_CPU_PHYS_READY_UTIL BYLS_CPU_PHYS_SYS_MODE_UTIL BYLS_CPU_PHYS_TOTAL_TIME BYLS_CPU_PHYS_TOTAL_UTIL BYLS_CPU_PHYS_USER_MODE_UTIL BYLS_CPU_PHYS_WAIT_UTIL BYLS_CPU_SHARES_PRIO BYLS_CPU_SYS_MODE_UTIL BYLS_CPU_TOTAL_UTIL BYLS_CPU_UNRESERVED BYLS_CPU_USER_MODE_UTIL BYLS_DATACENTER_NAME BYLS_DISK_PHYS_BYTE BYLS_DISK_PHYS_BYTE_RATE BYLS_DISK_PHYS_READ BYLS_DISK_PHYS_READ_BYTE_RATE BYLS_DISK_PHYS_READ_RATE BYLS_DISK_PHYS_WRITE BYLS_DISK_PHYS_WRITE_BYTE_RATE BYLS_DISK_PHYS_WRITE_RATE BYLS_DISK_UTIL BYLS_DISK_UTIL_PEAK BYLS_DISPLAY_NAME BYLS_IP_ADDRESS BYLS_LS_HOSTNAME BYLS_LS_HOST_HOSTNAME BYLS_LS_ID BYLS_LS_MODE BYLS_LS_NAME BYLS_LS_OSTYPE BYLS_LS_PARENT_TYPE BYLS_LS_PARENT_UUID BYLS_LS_PATH BYLS_LS_ROLE BYLS_LS_SHARED BYLS_LS_STATE BYLS_LS_TYPE BYLS_LS_UUID BYLS_MACHINE_MODEL BYLS_MEM_ACTIVE BYLS_MEM_AVAIL BYLS_MEM_BALLOON_USED BYLS_MEM_BALLOON_UTIL BYLS_MEM_ENTL BYLS_MEM_ENTL_MAX BYLS_MEM_ENTL_MIN BYLS_MEM_ENTL_UTIL BYLS_MEM_FREE BYLS_MEM_FREE_UTIL BYLS_MEM_HEALTH BYLS_MEM_OVERHEAD BYLS_MEM_PHYS BYLS_MEM_PHYS_UTIL BYLS_MEM_SHARES_PRIO BYLS_MEM_SWAPIN BYLS_MEM_SWAPOUT BYLS_MEM_SWAPPED BYLS_MEM_SWAPTARGET BYLS_MEM_SWAP_UTIL BYLS_MEM_SYS BYLS_MEM_UNRESERVED BYLS_MEM_USED BYLS_NET_BYTE_RATE BYLS_NET_IN_BYTE BYLS_NET_IN_PACKET BYLS_NET_IN_PACKET_RATE BYLS_NET_OUT_BYTE BYLS_NET_OUT_PACKET BYLS_NET_OUT_PACKET_RATE BYLS_NET_PACKET_RATE BYLS_NUM_ACTIVE_LS BYLS_NUM_CPU BYLS_NUM_CPU_CORE BYLS_NUM_DISK BYLS_NUM_LS BYLS_NUM_NETIF BYLS_NUM_SOCKET BYLS_UPTIME_HOURS BYLS_UPTIME_SECONDS BYLS_VC_IP_ADDRESS Metric Definitions ================== 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_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_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. On Unix systems, each application’s total resident memory is summed. This value is then divided by the summed total of all applications resident memory and then multiplied by the ratio of available user memory versus total physical memory to arrive at a calculated percentage of the total physical memory. It must be remembered, however, that this is a calculated metric that shows the approximate percentage of the physical memory used as resident memory by the processes in this application during the interval. On Windows, the sum of the working set sizes for each process in this group is kept as APP_MEM_RES. This value is divided by the sum of APP_MEM_RES for all applications defined on the system to come up with a ratio of this application’s working set size to the total. This value is then multiplied by the ratio of available user memory versus total physical memory to arrive at a calculated percent of total physical memory. 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. 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_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. BLANK ---------------------------------- An empty field used for spacing reports. For example, this field can be used to create a blank column in a spreadsheet that may be used to sum several items. 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. BYCPU_CPU_SYS_MODE_TIME ---------------------------------- The time, in seconds, that this 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 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 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_TOTAL_TIME ---------------------------------- The total time, in seconds, that this CPU 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 ---------------------------------- The percentage of time that this CPU 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_USER_MODE_TIME ---------------------------------- The time, in seconds, during the interval that this CPU 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_UTIL ---------------------------------- The percentage of time that this 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 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 kernel thread, if HP-UX) was first started, or b) the performance tool was first started, or c) the cumulative counters were reset (relevant only to GlancePlus, if available for the given platform), whichever occurred last. 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_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_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_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_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_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_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_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_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_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_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. BYLS_BOOT_TIME ---------------------------------- On vMA, for a host and logical system the metric is the date and time when the system was last booted. The value is NA for resource pool. Note that this date is obtained from the VMware API as an already formatted string and may not conform to the expected localization. BYLS_CLUSTER_NAME ---------------------------------- On vMA, for a host and resource pool it is the name of the cluster to which the host belongs to when it is managed by virtual centre. For a logical system, the value is NA. BYLS_CPU_CLOCK ---------------------------------- On vMA, for a host and logical system, it is the clock speed of the CPUs in MHz if all of the processors have the same clock speed. For a resource pool the value is NA. BYLS_CPU_CYCLE_ENTL_MAX ---------------------------------- On vMA, for a host, logical system and resource pool this value indicates the maximum processor capacity, in MHz, configured for the entity. If the maximum processor capacity is not configured for the entity, a value of “-3” will be displayed in PA and “ul”( unlimited ) in other clients. On HPUX, the maximum processor capacity, in MHz, configured for this logical system. BYLS_CPU_CYCLE_ENTL_MIN ---------------------------------- On vMA, for a host, logical system and resource pool this value indicates the minimum processor capacity, in MHz, configured for the entity. On HPUX, the minimum processor capacity, in MHz, configured for this logical system. BYLS_CPU_CYCLE_TOTAL_USED ---------------------------------- On vMA, for host, resource pool and logical system, it is the total time the physical CPUs were utilized during the interval, represented in cpu cycles. BYLS_CPU_ENTL_EMIN ---------------------------------- On vMA, for host, logical system and resource pool the value is “na”. BYLS_CPU_ENTL_MAX ---------------------------------- The maximum CPU units configured for a logical system. On HP-UX HPVM, this metric indicates the maximum percentage of physical CPU that a virtual CPU of this logical system can get. On AIX SPLPAR, this metric is equivalent to “Maximum Capacity” field of ‘lparstat -i’ command. For WPARs, it is the maximum percentage of CPU that a WPAR can have even if there is no contention for CPU. WPAR shares CPU units of its global environment. On Hyper-V host, for Root partition, this metric is NA. On vMA, for a host, the metric is equivalent to total number of cores on the host. For a resource pool and a logical system, this metrics indicates the maximum CPU units configured for it. BYLS_CPU_ENTL_MIN ---------------------------------- The minimum CPU units configured for this logical system. On HP-UX HPVM, this metric indicates the minimum percentage of physical CPU that a virtual CPU of this logical system is guaranteed. On AIX SPLPAR, this metric is equivalent to “Minimum Capacity” field of ‘lparstat -i’ command. For WPARs, it is the minimum CPU share assigned to a WPAR that is guaranteed. WPAR shares CPU units of its global environment. On Hyper-V host, for Root partition, this metric is NA. On vMA, for a host, the metric is equivalent to total number of cores on the host. For a resource pool and a logical system, this metrics indicates the guranteed minimum CPU units configured for it. On Solaris Zones, this metrics indicates the configured minimum CPU percentage reserved for a logical system. For Solaris Zones, this metric is calculated as: BYLS_CPU_ENTL_MIN = ( BYLS_CPU_SHARES_PRIO / Pool-Cpu-Shares ) where, Pool-Cpu-Shares is the total CPU shares available with CPU pool the zone is associated with. Pool-Cpu-Shares is addition of BYLS_CPU_SHARES_PRIO values for all active zones associated with this pool. BYLS_CPU_ENTL_UTIL ---------------------------------- Percentage of entitled processing units (guaranteed processing units allocated to this logical system) consumed by the logical system. On a HP-UX HPVM host the metric indicates the logical system’s CPU utilization with respect to minimum CPU entitlement. On HP-UX HPVM host, this metric is calculated as: BYLS_CPU_ENTL_UTIL = (BYLS_CPU_PHYSC / (BYLS_CPU_ENTL_MIN * BYLS_NUM_CPU)) * 100 On AIX, this metric is calculated as: BYLS_CPU_ENTL_UTIL = (BYLS_CPU_PHYSC / BYLS_CPU_ENTL) * 100 On WPAR, this metric is calculated as: BYLS_CPU_ENTL_UTIL = (BYLS_CPU_PHYSC / BYLS_CPU_ENTL_MAX) * 100 This metric matches “%Resc” of topas command (inside WPAR) On Solaris Zones, the metric indicates the logical system’s CPU utilization with respect to minimum CPU entitlement. This metric is calculated as: BYLS_CPU_ENTL_UTIL = (BYLS_CPU_TOTAL_UTIL / BYLS_CPU_SHARES_PRIO) * 100 If a Solaris zone is not assigned a CPU entitlement value then a CPU entitlement value is derived for this zone based on total CPU entitlement associated with the CPU pool this zone is attached to. On Hyper-V host, for Root partition, this metric is NA. On vMA, for a host the value is same as BYLS_CPU_PHYS_TOTAL_UTIL while for logical system and resource pool the value is the percentage of processing units consumed w.r.t minimum CPU entitlement. BYLS_CPU_MT_ENABLED ---------------------------------- Indicates whether the CPU hardware threads are enabled(“On”) or not(“Off”) for a logical system. For AIX wpars, the metric will be “na”. On vMA, this metric indicates whether the CPU hardware threads are enabled or not for a host while for a resource pool and a logical system the value is not available(“na”). BYLS_CPU_PHYSC ---------------------------------- This metric indicates the number of CPU units utilized by the logical system. On an Uncapped logical system, this value will be equal to the CPU units capacity used by the logical system during the interval. This can be more than the value entitled for a logical system. BYLS_CPU_PHYS_READY_UTIL ---------------------------------- On vMA, for a logical system it is the percentage of time, during the interval, that the CPU was in ready state. For a host and resource pool the value is NA. BYLS_CPU_PHYS_SYS_MODE_UTIL ---------------------------------- The percentage of time the physical CPUs were in system mode (kernel mode) for the logical system during the interval. On AIX LPAR, this value is equivalent to “%sys” field reported by the “lparstat” command. On Hyper-V host, this metric indicates the percentage of time spent in Hypervisor code. On vMA, the metric indicates the percentage of time the physical CPUs were in system mode during the interval for the host or logical system. On vMA, for a resource pool, this metric is “na”. BYLS_CPU_PHYS_TOTAL_TIME ---------------------------------- Total time in seconds, spent by the logical system on the physical CPUs. On vMA, the value indicates the time spent in seconds on the physical CPU. by logical system or host or resource pool, BYLS_CPU_PHYS_TOTAL_UTIL ---------------------------------- Percentage of total time the physical CPUs were utilized by this logical system during the interval. On vMA, the value indicates percentage of total time the physical CPUs were utilized by logical system or host or resource pool, BYLS_CPU_PHYS_USER_MODE_UTIL ---------------------------------- The percentage of time the physical CPUs were in user mode for the logical system during the interval. On AIX LPAR, this value is equivalent to “%user” field reported by the “lparstat” command. On Hyper-V host, this metric indicates the percentage of time spent in guest code. On vMA, the metrics indicates the percentage of time the physical CPUs were in user mode during the interval for the host or logical system. On vMA, for a resource pool, this metric is “na”. BYLS_CPU_PHYS_WAIT_UTIL ---------------------------------- On vMA, for a logical system it is the percentage of time, during the interval, that the virtual CPU was waiting for the IOs to complete. For a host and resource pool the value is NA. BYLS_CPU_SHARES_PRIO ---------------------------------- This metric indicates 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. For WPARs, this metric represents how much of a particular resource a WPAR receives relative to the other WPARs. On vMA, for logical system and resource pool this value can range from 1 to 1000000 while for host the value is NA. On Solaris Zones, this metric sets a limit on the number of fair share scheduler (FSS) CPU shares for a zone. On Hyper-V host, this metric specifies allocation of CPU resources when more than one virtual machine is running and competing for resources. This value can range from 0 to 10000. For Root partition, this metric is NA. BYLS_CPU_SYS_MODE_UTIL ---------------------------------- On vMA, for a host and a logical system, this metric indicates the percentage of time the CPU was in system mode. On vMA, for a resource pool, this metric is “na”. during the interval. BYLS_CPU_TOTAL_UTIL ---------------------------------- Percentage of total time the logical CPUs were not idle during this interval. This metric is calculated against the number of logical CPUs configured for this logical system. For AIX wpars, the metric represents the percentage of time the physical CPUs were not idle during this interval. BYLS_CPU_UNRESERVED ---------------------------------- On vMA, for host, it is the number of CPU cycles that are available for creating a new logical system. For a logical system and resource pool the value is NA. BYLS_CPU_USER_MODE_UTIL ---------------------------------- On vMA, for a host and a logical system, this metric indicates the percentage of time the CPU was in user mode during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DATACENTER_NAME ---------------------------------- On vMA, for a host it is the name of the datacenter to which the host belongs to when it is managed by virtual center. To uniquely identify datacenter in a virtual center, datacenter name is appended with the folder names in bottom up order. For a logical system and resource pool, the value is NA. BYLS_DISK_PHYS_BYTE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of KBs transferred to and from disks during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_BYTE_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the average number of KBs per second at which data was transferred to and from disks during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_READ ---------------------------------- On vMA, for a host and a logical system this metric indicates the number of physical reads during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_READ_BYTE_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the average number of KBs transferred from the disk per second during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_READ_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of physical reads per second during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_WRITE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of physical writes during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_WRITE_BYTE_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the average number of KBs transferred to the disk per second during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_PHYS_WRITE_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of physical writes per second during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_DISK_UTIL ---------------------------------- On vMA, for a host, it is the average percentage of time during the interval (average utilization) that all the disks had IO in progress. For logical system and resource pool the value is NA. BYLS_DISK_UTIL_PEAK ---------------------------------- On vMA, for a host, it is the utilization of the busiest disk during the interval. For a logical system and resource pool the value is NA. BYLS_DISPLAY_NAME ---------------------------------- On vMA, this metric indicates the name of the host or logical system or resource pool. On HPVM, this metric indicates the Virtual Machine name of the logical systemand is equivalent to “Virtual Machine Name” field of ‘hpvmstatus’ command. On AIX the value is as returned by the command “uname -n” (that is, the string returned from the “hostname” program). On Solaris Zones, this metric indicates the zone name and is equivalent to ‘NAME’ field of ‘zoneadm list -vc’ command. On Hyper-V host, this metric indicates the Virtual Machine name of the logical systemand is equivalent to the Name displayed in Hyper-V Manager. For Root partition, the value is always “Root”. BYLS_IP_ADDRESS ---------------------------------- This metric indicates IP Address of the particular logical system. On vMA, this metric indicates the IP Address for a host and a logical system while for a resource pool the value is NA. BYLS_LS_HOSTNAME ---------------------------------- This is the DNS registered name of the system. On Hyper-V host, this metric is NA if the logical system is not active or Hyper-V Integration Components are not installed on it. On vMA, for a host and logical system the metric is the Fully Qualified Domain Name, while for resource pool the value is NA. BYLS_LS_HOST_HOSTNAME ---------------------------------- On vMA, for logical system and resource pool, it is the FQDN of the host on which they are hosted. For a host, the value is NA. BYLS_LS_ID ---------------------------------- An unique identifier of the logical system. On HPVM, this metric is a numeric id and is equivalent to “VM # “ field of ‘hpvmstatus’ command. On AIX LPAR, this metric indicates partition number and is equivalent to “Partition Number” field of ‘lparstat -i’ command. For aix wpar, this metric represents the partition number and is equivalent to “uname -W” from inside wpar. On Solaris Zones, this metric indicates the zone id and is equivalent to ‘ID’ field of ‘zoneadm list -vc’ command. On Hyper-V host, this metric indicates the PID of the process corresponding to this logical system. For Root partition, this metric is NA. On vMA, this metric is a unique identifier for a host, resource pool and a logical system. The value of this metric may change for an instance across collection intervals. BYLS_LS_MODE ---------------------------------- This metric indicates whether the CPU entitlement for the logical system is Capped or Uncapped. On AIX SPLPAR, this metric is same as “Mode” field of ‘lparstat -i’ command. For WPARs, this metric is always CAPPED. On vMA, the value is Capped for a host and Uncapped for a logical system. For resource pool, the value is Uncapped or Capped depending on whether the reservation is expandable or not for it. On Solaris Zones, this metric is “Capped” when the zone is assigned CPU shares and is attached to a valid CPU pool. BYLS_LS_NAME ---------------------------------- This is the name of the computer. On HPVM, this metric indicates the Virtual Machine name of the logical systemand is equivalent to “Virtual Machine Name” field of ‘hpvmstatus’ command. On AIX the value is as returned by the command “uname -n” (that is, the string returned from the “hostname” program). On vMA, this metric is a unique identifier for host, resource pool and a logical system. The value of this metric remains the same, for an instance, across collection intervals. On Solaris Zones, this metric indicates the zone name and is equivalent to ‘NAME’ field of ‘zoneadm list -vc’ command. On Hyper-V host, this metric indicates the name of the XML file which has configuration information of the logical system. This file will be present under the logical system’s installation directory indicated by BYLS_LS_PATH. For Root partition, the value is always “Root”. BYLS_LS_OSTYPE ---------------------------------- The Guest OS this logical system is hosting. On HPVM, the metric can have following values: HP-UX Linux Windows OpenVMS Other Unknown On Hyper-V host, the metric can have following values: Windows Other On Hyper-V host, this metric is NA if the logical system is not active or Hyper-V Integration Components are not installed on it. On vMA, the metric can have the following values for host and logical system: ESX-Serv (applicable only for a host) Linux Windows Solaris Unknown The value is NA for resource pool BYLS_LS_PARENT_TYPE ---------------------------------- On vMA, the metric indicates the type of parent entity. The value is HOST if the parent is a host, RESPOOL if the parent is resource pool. For a host, the value is NA. BYLS_LS_PARENT_UUID ---------------------------------- On vMA, the metric indicates the UUID of the parent entity. For logical system and resource pool this metric could indicate the UUID of a host or resource pool as as they can be created under a host or resource pool. For a host, the value is NA. BYLS_LS_PATH ---------------------------------- This metric indicates the installation path for the logical system. On Hyper-V host, for Root partition, this metric is NA. On vMA, the metric indicates the installation path for host or logical system. On vMA, for a resource pool and a host, this metric is “na”. BYLS_LS_ROLE ---------------------------------- On vMA, for a host the metric is HOST. For a logical system the value is GUEST and for a resource pool the value is RESPOOL. For logical system which is a vMA, the value is PROXY. BYLS_LS_SHARED ---------------------------------- This metric indicates whether the physical CPUs are dedicated to this logical system or shared. On HPUX HPVM, and Hyper-V host,this metric is always “Shared”. On vMA, the value is “Dedicated” for host, and “Shared” for logical system and resource pool. On AIX SPLPAR, this metric is equivalent to “Type” field of ‘lparstat -i’ command. For AIX wpars,this metric will be always “Shared”. On Solaris Zones, this metric is “Dedicated” when this zone is attached to a CPU pool not shared by any other zone. BYLS_LS_STATE ---------------------------------- The state of this logical system. On HPVM, the logical systems can have one of the following states: Unknown Other invalid Up Down Boot Crash Shutdown Hung On vMA, this metric can have one of the following states for a host: on off The values for a logical system can be one of the following: on off suspended The value is NA for resource pool. On Solaris Zones, the logical systems can have one of the following states: configured incomplete installed ready running shutting down mounted On AIX lpars, the logical system will be always active. On AIX wpars, the logical systems can have one of the following states: Broken Transitional Defined Active Loaded Paused Frozen Error A logical system on a Hyper-V host can have the following states: unknown enabled disabled paused suspended starting snapshtng migrating saving stopping deleted pausing resuming BYLS_LS_TYPE ---------------------------------- The type of this logical system. On AIX, the logical systems can have one of the following types: lpar sys wpar app wpar On vMA, the value of this metric is “VMware”. BYLS_LS_UUID ---------------------------------- UUID of this logical system. This Id uniquely identifies this logical system across multiple hosts. On Hyper-V host, for Root partition, this metric is NA. On vMA, for a logical system or a host, the value indicates the UUID of the system. For a resource pool the value is hostname of the host where resource pool is hosted followed by the unique id of resource pool. BYLS_MACHINE_MODEL ---------------------------------- On vMA, for a host, it is the CPU model of the host system. For a logical system and resource pool the value is “na”. BYLS_MEM_ACTIVE ---------------------------------- On vMA, for a logical system it is the amount of memory, that is actively used. For a host and resource pool the value is NA. BYLS_MEM_AVAIL ---------------------------------- On vMA, for a host, the amount of physical available memory in the host system (in MBs unless otherwise specified). For a logical system and resource pool the value is NA. BYLS_MEM_BALLOON_USED ---------------------------------- On vMA, for logical system, it is the amount of memory held by memory control for ballooning. The value is represented in KB. For a host and resource pool the value is NA. BYLS_MEM_BALLOON_UTIL ---------------------------------- On vMA, for logical system, it is the amount of memory held by memory control for ballooning. It is represented as a percentage of BYLS_MEM_ENTL. For a host, and resource pool the value is NA. BYLS_MEM_ENTL ---------------------------------- The minimum memory configured for this logical system (in MB). On Hyper-V host, for Root partition, this metric is NA. On vMA, for host the value is the physical memory available in the system and for logical system this metric indicates the minimum memory configured while for resource pool the value is NA. BYLS_MEM_ENTL_MAX ---------------------------------- In a virtual environment, this metric indicates the maximum amount of memory configured for a logical system (in MB). The value of this metric will be “- 3” in PA and “ul” in other clients if entitlement is ‘Unlimited’ for a logical system. On AIX LPARs, this metric will be “na”. On vMA, this metric indicates the maximum amount of memory configured, in MB, for resource pool and a logical system. For a host, the value is the amount of physical memory available in the system. BYLS_MEM_ENTL_MIN ---------------------------------- In a virtual environment, this metric indicates the minimum amount of memory configured for a logical system (in MB). On AIX LPARs, this metric will be “na”. On vMA, this metric indicates the reserved amount of memory configured, in MB, for a host, resource pool and a logical system. BYLS_MEM_ENTL_UTIL ---------------------------------- The percentage of entitled memory in use during the interval. This includes system memory (occupied by the kernel), buffer cache and user memory. On vMA, for a logical system or a host, the value indicates percentage of entitled memory in use during the interval by it. On vMA, for a resource pool, this metric is “na”. BYLS_MEM_FREE ---------------------------------- On vMA, for a host and logical system, it is the amount of memory not allocated (in MBs unless otherwise specified). For a resource pool the value is NA. BYLS_MEM_FREE_UTIL ---------------------------------- On vMA, for a host and logical system, it is the percentage of physical memory that was free at the end of the interval. For a resource pool the value is NA. BYLS_MEM_HEALTH ---------------------------------- On vMA, for a host, it is a number that indicates the state of the memory. Low number indicates system is not under memory pressure. For a logical system and resource pool the value is “na”. The possible free memory thresholds that are applicable are : 0 - High - indicates free memory is available and no memory pressure. 1 - Soft 2 - Hard 3 - Low - indicates there is a pressure for free memory. BYLS_MEM_OVERHEAD ---------------------------------- The amount of memory associated with a logical system, that is currently consumed on the host system, due to virtualization. On vMA, this metric indicates the amount of overhead memory associated with a host, logical system and resource pool. BYLS_MEM_PHYS ---------------------------------- On vMA, for host the value is the physical memory available in the system and for logical system this metric indicates the minimum memory configured. On vMA, for a resource pool, this metric is “na”. BYLS_MEM_PHYS_UTIL ---------------------------------- On vMA, the metric indicates the percentage of physical memory used during the interval by a host, logical system. On vMA, for a resource pool, this metric is “na”. BYLS_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 AIX LPARs, this metric will be “na”. On vMA, this metric indicates the share of memory configured to a resource pool and a logical system. For a host the value is NA. BYLS_MEM_SWAPIN ---------------------------------- On vMA, for a logical system the value indicates the amount of memory that is swapped in during the interval. For a host and resource pool the value is NA. BYLS_MEM_SWAPOUT ---------------------------------- On vMA, for a logical system the value indicates the amount of memory that is swapped out during the interval. For a host and resource pool the value is NA. BYLS_MEM_SWAPPED ---------------------------------- On vMA, for a host, logical system and resource pool, this metrics indicates the amount of memory that has been transparently swapped to and from the disk. BYLS_MEM_SWAPTARGET ---------------------------------- On vMA, for a logical system the value indicates the amount of memory that can be swapped. For a host and resource pool the value is “na”. BYLS_MEM_SWAP_UTIL ---------------------------------- On Solaris, this metric indicates the percentage of swap memory consumed by the zone with respect to total configured swap memory (BYLS_MEM_SWAP). This metric is calculated as : BYLS_MEM_SWAP_UTIL = (BYLS_MEM_SWAP_USED ) / (BYLS_MEM_SWAP) * 100 On vMA, for a logical system, it is the percentage of swap memory utilized w.r.t the amount of swap memory available for a logical system. For host and resource pool the value is NA. For a logical system this metric is calculated using the below formula: (BYLS_MEM_SWAPPED * 100)/(BYLS_MEM_ENTL - BYLS_MEM_ENTL_MIN) BYLS_MEM_SYS ---------------------------------- On vMA, for a host, it is the amount of physical memory (in MBs unless otherwise specified) used by the system (kernel) during the interval. For logical system and resource pool the value is NA. BYLS_MEM_UNRESERVED ---------------------------------- On vMA, for a host it is the amount of memory, that is unreserved. For a logical system and resource pool the value is “na”. Memory reservation not used by the Service Console, VMkernel, vSphere services and other powered on VMs user-specified memory reservations and overhead memory. BYLS_MEM_USED ---------------------------------- On vMA, for host, resource pool and logical system the value indicates the amount of memory used represented in MB. On vMA, for a resource pool, this metric is “na”. BYLS_NET_BYTE_RATE ---------------------------------- On vMA, for a host and logical system, it is the sum of data transmitted and received for all the NIC instances of the host and virtual machine. It is represented in KBps. For a resource pool the value is NA. BYLS_NET_IN_BYTE ---------------------------------- On vMA, for a host and logical system, it is number of bytes, in MB, received during the interval. For a resource pool the value is NA. BYLS_NET_IN_PACKET ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of successful packets received through all network interfaces during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_NET_IN_PACKET_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of successful packets per second received through all network interfaces during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_NET_OUT_BYTE ---------------------------------- On vMA, for a host and logical system, it is the number of bytes, in MB, transmitted during the interval. For a resource pool the value is NA. BYLS_NET_OUT_PACKET ---------------------------------- On vMA, for a host and a logical system, it is the number of successful packets sent through all network interfaces during the last interval. On vMA, for a resource pool, this metric is “na”. BYLS_NET_OUT_PACKET_RATE ---------------------------------- On vMA, for a host and a logical system, this metric indicates the number of successful packets per second sent through the network interfaces during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_NET_PACKET_RATE ---------------------------------- On vMA, for a host and a logical system, it is the number of successful packets per second, both sent and received, for all network interfaces during the interval. On vMA, for a resource pool, this metric is “na”. BYLS_NUM_ACTIVE_LS ---------------------------------- On vMA, for a host, this indicates the number of logical systems hosted in a system that are active. For a logical system and resource pool the value is NA. BYLS_NUM_CPU ---------------------------------- The number of virtual CPUs configured for this logical system. This metric is equivalent to GBL_NUM_CPU on the corresponding logical system. On HPVM, the maximum CPUs a logical system can have is 4 with respect to HPVM 3.x. On AIX SPLPAR, the number of CPUs can be configured irrespective of the available physical CPUs in the pool this logical system belongs to. For AIX wpars, this metric represents the logical CPUs of the global environment. On vMA, for a host the metric is the number of physical CPU threads on the host. For a logical system, the metric is the number of virtual cpus configured.For a resource pool the metric is NA. On Solaris Zones, this metric represents number of CPUs in the CPU pool this zone is attached to. This metric value is equivalent to GBL_NUM_CPU inside corresponding non-global zone. BYLS_NUM_CPU_CORE ---------------------------------- On vMA, for a host this metric provides the toal number of CPU cores on the system. For a logical system or a resource pool the value is NA. BYLS_NUM_DISK ---------------------------------- The number of disks configured for this logical system. Only local disk devices and optical devices present on the system are counted in this metric. On vMA, for a host the metric is the number of disks configured for the host . For a logical system, the metric is the number of logical disk devices present on the logical system. For a resource pool the metric is NA. For AIX wpars, this metric will be “na”. On Hyper-V host, this metric value is equivalent to GBL_NUM_DISK inside corresponding Hyper-V guest. On Hyper-V host, this metric is NA if the logical system is not active. BYLS_NUM_LS ---------------------------------- On vMA, for a host, this indicates the number of logical systems hosted in a system. For a logical system and resource pool the value is NA. BYLS_NUM_NETIF ---------------------------------- The number of network interfaces configured for this logical system. On LPAR, this metric includes the loopback interface. On Hyper-V host, this metric value is equivalent to GBL_NUM_NETWORK inside corresponding Hyper-V guest. On Solaris Zones, this metric value is equivalent to GBL_NUM_NETWORK inside corresponding non-global zone. On Hyper-V host, this metric is NA if the logical system is not active. On vMA, for a host the metric is the number of network adapters on the host. For a logical system, the metric is the number of network interfaces configured for the logical system. For a resource pool the metric is NA. BYLS_NUM_SOCKET ---------------------------------- On vMA, for a host, this metrics indicates the number of physical cpu sockets on the system. For a logical system or a resource pool the value is NA. BYLS_UPTIME_HOURS ---------------------------------- On vMA, for a host and logical system the metrics is the time, in hours, since the last system reboot. For a resource pool the value is NA. BYLS_UPTIME_SECONDS ---------------------------------- The uptime of this logical system in seconds. On AIX LPARs, this metric will be “na”. On vMA, for a host and logical system the metric is the uptime in seconds while for a resource pool the metric is NA. BYLS_VC_IP_ADDRESS ---------------------------------- On vMA, for a host, the metric indicates the IP address of the Virtual Centre that the host is managed by. For a resource pool and logical system the value is NA. 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_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_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 kernel thread, if HP-UX) was first started, or b) the performance tool was first started, or c) the cumulative counters were reset (relevant only to GlancePlus, if available for the given platform), whichever occurred last. 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_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 as first half and the second half is the ESX host name. 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 kernel thread, if HP-UX) was first started, or b) the performance tool was first started, or c) the cumulative counters were reset (relevant only to GlancePlus, if available for the given platform), whichever occurred last. 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_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. DATE ---------------------------------- The date the information in this record was captured, based on local time. The date is an ASCII field in mm/dd/yyyy format unless localized. If localized, the separators may be different and the subfield may be in a different sequence. In ASCII files this field will always contain 10 characters. Each subfield (mm, dd, yyyy) will contain a leading zero if the value is less than 10. This metric is extracted from GBL_STATTIME, which is obtained using the time() system call at the time of data collection. This field responds to language localization. For example, in Italy the field would appear as dd/mm/yyyy and in Japan it would be yyyy/mm/dd. In binary files this field is in MPE CALENDAR format in the least significant 16 bits of the field. The most significant 16 bits should all be zero. Dividing the field by 512 will isolate the year (that is, 94). This field MOD 512 will isolate the day of the year. DATE_SECONDS ---------------------------------- The time that the data in this record was captured, expressed in seconds since January 1, 1970, based on local time. This is related to the standard time- stamp returned by the unix system call time(), but has had the local time zone correction applied. DAY ---------------------------------- The julian day of the year that the data in this record was captured. This metric is extracted from GBL_STATTIME. 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. 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. 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_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_SPACE_RESERVED ---------------------------------- The amount of file system space in MBs reserved for superuser allocation. On AIX, this metric is typically zero 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_APP_THRESHOLD ---------------------------------- appthreshold specifies the thresholds for APPLICATION class. This is the percentage of cpu being utilized by an application (APP_CPU_TOTAL_UTIL) during the interval. This threshold value is supplied by the parm file. An application must exceed this threshold value in any given interval before it will be considered interesting to be logged. GBL_BOOT_TIME ---------------------------------- The date and time when the system was last booted. GBL_BYCPU_THRESHOLD ---------------------------------- bycputhreshold specifies the thresholds for CPU class. This is the percentage of time a cpu was busy (BYCPU_CPU_TOTAL_UTIL) during the interval. This threshold value is supplied by the parm file. A cpu must exceed this threshold value in any given interval before it will be considered interesting to be logged. GBL_BYDSK_THRESHOLD ---------------------------------- diskthreshold specifies the threshold for DISK class. This is the percentage of time that a disk busy in performing IO (BYDSK_UTIL) during the interval. This threshold value is supplied by the parm file. A disk must exceed this threshold value in any given interval before it will be considered interesting and be logged. GBL_BYFS_THRESHOLD ---------------------------------- fsthreshold specifies the thresholds for FILESYSTEM class. This is the percentage of space used (FS_SPACE_UTIL) of the filesystem. This threshold value is supplied by the parm file. A filesystem must exceed this threshold value in any given interval before it will be considered interesting to be logged. GBL_BYNETIF_THRESHOLD ---------------------------------- bynetifthreshold specifies the thresholds for NETIF class. This is the number of packets transferred per second during the interval(BYNETIF_PACKET_RATE). This threshold value is supplied by the parm file. A network interface must exceed this threshold value in any given interval before it will be considered interesting to be logged. GBL_COLLECTOR ---------------------------------- ASCII field containing collector name and version. The collector name will appear as either “SCOPE/xx V.UU.FF.LF” or “Coda RV.UU.FF.LF”. xx identifies the platform; V = version, UU = update level, FF = fix level, and LF = lab fix id. For example, SCOPE/UX C.04.00.00; or Coda A.07.10.04. GBL_COLLECT_INTERVAL ---------------------------------- The interval, in seconds, at which non-process metrics are collected. Collection intervals are set in parm file. GBL_COLLECT_INTERVAL_PROC ---------------------------------- The interval, in seconds, at which process metrics are collected. Collection intervals are set in parm file. 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_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. 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_UTIL ---------------------------------- The percentage of time that the CPU was idle during the interval. This is the total idle time, including waiting for I/O. 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_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_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_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_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_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_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_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_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_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_WAIT_UTIL ---------------------------------- The percentage of time during the interval that the CPU was idle and there were processes waiting for physical IOs to complete. 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, this includes CPU steal time (shown as ‘%steal’ in ‘sar’ and ‘st’ in ‘vmstat’). 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_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_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_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_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_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_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_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_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_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_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_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_DISTRIBUTION ---------------------------------- The software distribution, if available. GBL_FLUSH ---------------------------------- Flush specifies the interval, in seconds, at which scope logs the application and device data classes even though the data does not meet the threshold conditions being set. Flush parameter is set in parm file. 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 HPUX, 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 HPUX 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_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_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_LOGFILE_VERSION ---------------------------------- Three byte ASCII field containing the log file version number. The log file version is assigned by scopeux and is incremented when changes to the log file causes the layout to be different from previous versions. The current version is “ D”. Every effort is made to protect the information investment maintained in historical log files by providing forward compatibility and/or conversion utilities when log files change. GBL_LOGGING_TYPES ---------------------------------- A 13-byte field indicating the types of data logged by the collector. This is controlled by the LOG statement in the parm file. Each position will contain either a space or the characters as shown below. Note that positions two (all applications) and four (all processes) were implemented for HP internal use only and are not normally used outside of HP. An @ in position two indicates that all applications are logged each five minute interval even if they had no activity during the interval. An @ in position four indicates that all processes, not just the interesting ones, are logged each one minute interval. This can result in very large log files.An @ in position 6 indicates all devices( File System Device,Disk,CPU,LAN,Logical Volume) are logged. Position Char Meaning 1 G Global data 2 @ All applications 3 A Applications 4 @ All processes 5 P Interesting processes 6 @ All Devices 7 F File System Device 8 D Disk 9 C CPU 10 L LAN 11 V Logical Volume 12 T Transaction data 13 space Not used 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 virtulization 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 PA/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 CPU 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. 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 < 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 < 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 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_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_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_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_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_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_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_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_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_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_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_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_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_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 also. 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 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. 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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_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_STATTIME ---------------------------------- An ASCII string representing the time at the end of the interval, based on local time. GBL_SUBPROCSAMPLEINTERVAL ---------------------------------- The SubProcSampleInterval parameter sets the internal sampling interval of process data. This option only changes the frequency of how often the operating system process table is scanned in order to accumulate process statistics during a log interval and does not change the logging interval for process data logging. If, for example, the CPU utilization is higher than expected (possibly due to a large operating system process table), you can decrease the utilization by increasing the sampling interval. Note: Increasing the SUBPROC sample interval (SUBPROC can be used interchangeably with SUBPROCSAMPLEINTERVAL) parameter may decrease the accuracy of application data and process data since short-lived processes (those completing within a sample interval) cannot be captured and hence logged by scopeux. To set process subintervals to 5 (default), 10, 15, 20, 30, or 60 seconds (these are the only values allowed), you will have to enter the SUBPROC or SUBPROCSAMPLEINTERVAL sample interval parameter in your parm file. You cannot input a value lower than 5. For example, to set the interval to 15 seconds, add one of the following lines in your parm file: SUBPROC=15 or SUBPROCSAMPLEINTERVAL=15 Changes made to the parm file are logged every time the Performance Agent is restarted. To check changes made to the SUBPROC sample interval parameter in your parm file, you can use the following command: # utility -xs -D |grep -i sub 04/23/99 13:04 Process Collection Sample SubInterval 5 seconds -> 5 seconds 04/23/99 14:31 Process Collection Sample SubInterval 5 seconds -> 15 seconds 04/23/99 14:43 Process Collection Sample SubInterval 15 seconds -> 30 seconds Specify the full pathname of the performance tool bin directory as needed. You can also export the GBL_SUBPROCSAMPLEINTERVAL metric from the Configuration data. 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_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_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_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_CPU ---------------------------------- The percent of CPU that a process must use to become interesting during an interval. The default for this threshold is “5.0”, which means a process must have a value of at least 5.0% for PROC_CPU_TOTAL_UTIL to exceed this threshold. All threshold values are supplied by the parm file. A process must exceed at least one threshold value in any given interval before it will be considered interesting and be logged. GBL_THRESHOLD_NOKILLED ---------------------------------- This is a flag specifying that terminating processes are not interesting. The flag is set by the THRESHOLD NOKILLED statement in the parm file. If this flag is set, then the process will be logged only if it exceeds at least one of the thresholds. The default (blank) is for the flag to be turned off, which means a terminating process will be logged in the interval it exits even if it did not exceed any thresholds during that interval. This is so that the death of a process is recorded even if it does not exceed any of the thresholds. On HP-UX, an exception to this is short-lived processes that are alive for less than one second. By default, short-lived processes are not considered interesting. However, there is a flag (THRESHOLD_SHORTLIVED) to turn on the logging of short-lived processes. GBL_THRESHOLD_NONEW ---------------------------------- This is a flag specifying that newly created processes are not interesting. The flag is set by the THRESHOLD NONEW statement in the parm file. If this flag is set, then the process will be logged only if it exceeds at least one of the thresholds. The default (blank) is for the flag to be turned off, which means a new process will be logged in the interval it was created even if it did not exceed any thresholds during that interval. This is so that the existence of a process is recorded even if it does not exceed any of the thresholds. On HP-UX, an exception to this is short-lived processes that are alive for less than one second. By default, short-lived processes are not considered interesting. However, there is a flag (THRESHOLD_SHORTLIVED) to turn on the logging of short-lived processes. 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. INTERVAL ---------------------------------- The number of seconds in the measurement interval. For the process data class, this is the number of seconds the process was alive during the interval. PROC_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_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 ---------------------------------- 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 ---------------------------------- 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_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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 ---------------------------------- 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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 HP-UX systems, processes which have component kernel threads executing simultaneously on different processors could have resource utilization sums over 100%. The maximum percentage is 100% times the number of CPUs 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. PROC_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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 HP-UX systems, processes which have component kernel threads executing simultaneously on different processors could have resource utilization sums over 100%. The maximum percentage is 100% times the number of CPUs 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. PROC_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 kernel thread, if HP-UX) was first started, or b) the performance tool was first started, or c) the cumulative counters were reset (relevant only to GlancePlus, if available for the given platform), whichever occurred last. This is calculated as PROC_CPU_TOTAL_TIME_CUM = PROC_CPU_SYS_MODE_TIME_CUM + PROC_CPU_USER_MODE_TIME_CUM On a threaded operating system, such as HP-UX 11.0 and beyond, 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 ---------------------------------- 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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 HP-UX systems, processes which have component kernel threads executing simultaneously on different processors could have resource utilization sums over 100%. The maximum percentage is 100% times the number of CPUs 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. PROC_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 kernel thread, if HP-UX) was first started, or b) the performance tool was first started, or c) the cumulative counters were reset (relevant only to GlancePlus, if available for the given platform), whichever occurred last. 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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 HP-UX systems, processes which have component kernel threads executing simultaneously on different processors could have resource utilization sums over 100%. The maximum percentage is 100% times the number of CPUs 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. PROC_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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 ---------------------------------- 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 a threaded operating system, such as HP-UX 11.0 and beyond, 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 HP-UX systems, processes which have component kernel threads executing simultaneously on different processors could have resource utilization sums over 100%. The maximum percentage is 100% times the number of CPUs 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. PROC_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_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_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_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_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_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 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_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 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 ---------------------------------- 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_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 ---------------------------------- 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_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 ---------------------------------- 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_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 ---------------------------------- 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 ---------------------------------- The process ID number (or PID) of this process(or associated process for kernel threads, if HPUX/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 ---------------------------------- 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_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_STARTTIME ---------------------------------- The creation date and time of the process (or kernel thread, if HP-UX/Linux Kernel 2.6 and above). PROC_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_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_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_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. RECORD_TYPE ---------------------------------- ASCII string that identifies the record. Possibilities include: GLOB for global 5 minute detail GSUM for global hourly summary APPL for application 5 minute detail ASUM for application hourly summary CONF for configuration TRAN for transaction tracker detail TSUM for transaction tracker summary Except for Windows Desktop, this also includes: PROC for process 1 minute detail DISK for disk device 5 minute detail DSUM for disk device summary On HP-UX, this also includes: VOLS for logical volume disk detail VSUM for logical volume disk summary STATDATE ---------------------------------- The end date timestamp of the interval for which the information in this record was captured, based on local time. The date is an ASCII field in mm/dd/yyyy format unless localized. If localized, the separators may be different and the subfield may be in a different sequence. In ASCII files this field will always contain 10 characters. Each subfield (mm, dd, yyyy) will contain a leading zero if the value is less than 10. This metric is extracted from GBL_STATTIME, which is obtained using the time() system call at the time of data collection. This field responds to language localization. For example, in Italy the field would appear as dd/mm/yyyy and in Japan it would be yyyy/mm/dd. In binary files this field is in MPE CALENDAR format in the least significant 16 bits of the field. The most significant 16 bits should all be zero. Dividing the field by 512 will isolate the year (that is, 94). This field MOD 512 will isolate the day of the year. STATTIME ---------------------------------- The local time of day for the end of the interval. The time is an ASCII field in hh:mm:ss 24-hour format. This field will always contain 8 characters in ASCII files. The three subfields (hh, mm, ss) will contain a leading zero if the value is less than 10. This metric is extracted from GBL_STATTIME, which is obtained using the time() system call at the end of the interval. This field responds to language localization. In binary files this field contains four byte size subfields. The most significant byte contains the hour, the next most significant byte contains the minute, then the seconds and finally the tenths of a second. The left two bytes can be isolated by dividing by 65536. HHMM = TIME/65536. Then HOUR = HHMM/256 and MINUTE = HHMM mod 256. SSTS = TIME mod 65536. Then SECOND = SSTS/256. 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 upto 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_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 upto max unsigned long. 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_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_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_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_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_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_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_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_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. TIME ---------------------------------- The local time of day for the start of the interval. The time is an ASCII field in hh:mm:ss 24-hour format. This field will always contain 8 characters in ASCII files. The three subfields (hh, mm, ss) will contain a leading zero if the value is less than 10. This metric is extracted from GBL_STATTIME, which is obtained using the time() system call at the start of the interval. This field responds to language localization. In binary files this field contains four byte size subfields. The most significant byte contains the hour, the next most significant byte contains the minute, then the seconds and finally the tenths of a second. The left two bytes can be isolated by dividing by 65536. HHMM = TIME/65536. Then HOUR = HHMM/256 and MINUTE = HHMM mod 256. SSTS = TIME mod 65536. Then SECOND = SSTS/256. TTBIN_TRANS_COUNT_1 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_10 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_2 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_3 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_4 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_5 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_6 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_7 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_8 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_TRANS_COUNT_9 ---------------------------------- The number of completed transactions in this range during the last interval. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_1 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_10 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_2 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_3 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_4 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_5 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_6 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_7 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_8 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TTBIN_UPPER_RANGE_9 ---------------------------------- The upper range (transaction time) for this 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. On SUN systems, this metric is only available on 5.X or later. TT_ABORT ---------------------------------- The number of aborted transactions during the last interval for this transaction. TT_ABORT_WALL_TIME_PER_TRAN ---------------------------------- The average time, in seconds, per aborted transaction during the last interval. On SUN systems, this metric is only available on 5.X or later. TT_APP_NAME ---------------------------------- The registered ARM Application name. TT_APP_TRAN_NAME ---------------------------------- A concatenation of TT_APP_NAME and TT_NAME. This provides a way to uniquely identify a specific transaction. The field is limited to 60 characters. TT_CLIENT_ADDRESS ---------------------------------- The correlator address. This is the address where the child transaction originated. TT_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_TRAN_ID ---------------------------------- A numerical ID that uniquely identifies the transaction class in this correlator. TT_COUNT ---------------------------------- The number of completed transactions during the last interval for this transaction. TT_FAILED ---------------------------------- The number of Failed transactions during the last interval for this transaction name. TT_INFO ---------------------------------- The registered ARM Transaction Information for this transaction. TT_NAME ---------------------------------- The registered transaction name for this transaction. TT_NUM_BINS ---------------------------------- The number of distribution ranges. On SUN systems, this metric is only available on 5.X or later. TT_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_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_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_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_AVG_2 ---------------------------------- If the measurement type is a numeric or a string, this metric returns “na”. TT_USER_MEASUREMENT_AVG_3 ---------------------------------- 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_AVG_4 ---------------------------------- 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_AVG_5 ---------------------------------- 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_AVG_6 ---------------------------------- 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 ---------------------------------- 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_MAX_2 ---------------------------------- 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_MAX_3 ---------------------------------- 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_MAX_4 ---------------------------------- 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_MAX_5 ---------------------------------- 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_MAX_6 ---------------------------------- 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 ---------------------------------- 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_MIN_2 ---------------------------------- 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_MIN_3 ---------------------------------- 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_MIN_4 ---------------------------------- 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_MIN_5 ---------------------------------- 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_MIN_6 ---------------------------------- 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 ---------------------------------- 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_NAME_2 ---------------------------------- 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_NAME_3 ---------------------------------- 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_NAME_4 ---------------------------------- 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_NAME_5 ---------------------------------- 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_NAME_6 ---------------------------------- 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_WALL_TIME_PER_TRAN ---------------------------------- The average transaction time, in seconds, during the last interval for this transaction. YEAR ---------------------------------- The year, including the century, the data in this record was captured. This metric will contain 4 digits, such as 2002.