From 6042419e9dbfe7ca21ceda5c07572dbf93997aff Mon Sep 17 00:00:00 2001 From: Linda Bebernes Date: Thu, 11 Jul 2013 10:35:48 -0700 Subject: [PATCH] LUDOC-144 LustreProc: Also LUDOC-143. Bug fixes and formatting. Updated content, corrected errors, fixed mis-aligned tables. Signed-off-by: Linda Bebernes Change-Id: I258df4809026ac6e53b95205eb8a1da869d6af58 Reviewed-on: http://review.whamcloud.com/6941 Tested-by: Hudson Reviewed-by: Richard Henwood --- LustreProc.xml | 2276 ++++++++++++++++++++++++++++++++++++++------------------ 1 file changed, 1542 insertions(+), 734 deletions(-) diff --git a/LustreProc.xml b/LustreProc.xml index ab7e5db..2baf720 100644 --- a/LustreProc.xml +++ b/LustreProc.xml @@ -1,8 +1,11 @@ - + + LustreProc - The /proc file system acts as an interface to internal data structures in the kernel. The /proc variables can be used to control aspects of Lustre performance and provide information. - This chapter describes Lustre /proc entries and includes the following sections: + The /proc file system acts as an interface to internal data structures in + the kernel. This chapter describes entries in /proc that are useful for + tuning and monitoring aspects of a Lustre file system. It includes these sections: @@ -12,33 +15,48 @@ + The /proc directory provides a file-system like interface to internal + data structures in the kernel. These data structures include settings and metrics for + components such as memory, networking, file systems, and kernel housekeeping routines, which + are available throughout the hierarchical file layout in /proc. + Typically, metrics are accessed by reading from /proc files and settings + are changed by writing to /proc files. + The /proc directory contains files that allow an operator to + interface with the Lustre file system to tune and monitor many aspects of system and + application performance.
- <indexterm><primary>proc</primary></indexterm>Proc Entries for Lustre + <indexterm> + <primary>proc</primary> + </indexterm> Lustre Entries in /proc This section describes /proc entries for Lustre.
Locating Lustre File Systems and Servers - Use the proc files on the MGS to locate the following: + Use the /proc files on the MGS to locate the following: All known file systems mgs# cat /proc/fs/lustre/mgs/MGS/filesystems -spfs +testfs lustre - The server names participating in a file system (for each file system that has at least one server running) - mgs# cat /proc/fs/lustre/mgs/MGS/live/spfs -fsname: spfs + The names of the servers in a file system (for a file system that has at least one + server running) + mgs# cat /proc/fs/lustre/mgs/MGS/live/testfs +fsname: testfs flags: 0x0 gen: 7 -spfs-MDT0000 -spfs-OST0000 +testfs-MDT0000 +testfs-OST0000 - All servers are named according to this convention: fsname-MDT|OSTnumber. This can be shown for live servers under /proc/fs/lustre/devices: + All servers are named according to the convention + fsname-MDT|OSTnumber. + Server names for live servers are listed under + /proc/fs/lustre/devices: mds# cat /proc/fs/lustre/devices 0 UP mgs MGS MGS 11 1 UP mgc MGC192.168.10.34@tcp 1f45bb57-d9be-2ddb-c0b0-5431a49226705 @@ -51,57 +69,126 @@ spfs-OST0000 8 UP mdc lustre-MDT0000-mdc-ce63ca00 08ac6584-6c4a-3536-2c6d-b36cf9cbdaa05 9 UP osc lustre-OST0000-osc-ce63ca00 08ac6584-6c4a-3536-2c6d-b36cf9cbdaa05 10 UP osc lustre-OST0001-osc-ce63ca00 08ac6584-6c4a-3536-2c6d-b36cf9cbdaa05 - Or from the device label at any time: + A server name can also be displayed by viewing the device label at any time. mds# e2label /dev/sda lustre-MDT0000
- <indexterm><primary>proc</primary><secondary>timeouts</secondary></indexterm>Lustre Timeouts - Lustre uses two types of timeouts. + <indexterm> + <primary>proc</primary> + <secondary>timeouts</secondary> + </indexterm>Timeouts in a Lustre File System + Two types of timeouts are used in a Lustre file system. - LND timeouts that ensure point-to-point communications complete in finite time in the presence of failures. These timeouts are logged with the S_LND flag set. They may not be printed as console messages, so you should check the Lustre log for D_NETERROR messages, or enable printing of D_NETERROR messages to the console (lctl set_param printk=+neterror). + LND timeouts - LND timeouts ensure that + point-to-point communications complete in a finite time in the presence of failures. + These timeouts are logged with the S_LND flag set. They are not + printed as console messages, so you should check the Lustre log for + D_NETERROR messages or enable printing of + D_NETERROR messages to the console (lctl set_param + printk=+neterror). + Congested routers can be a source of spurious LND timeouts. To avoid this situation, + increase the number of LNET router buffers to reduce back-pressure and/or increase LND + timeouts on all nodes on all connected networks. Also consider increasing the total + number of LNET router nodes in the system so that the aggregate router bandwidth matches + the aggregate server bandwidth. - Congested routers can be a source of spurious LND timeouts. To avoid this, increase the number of LNET router buffers to reduce back-pressure and/or increase LND timeouts on all nodes on all connected networks. You should also consider increasing the total number of LNET router nodes in the system so that the aggregate router bandwidth matches the aggregate server bandwidth. - Lustre timeouts that ensure Lustre RPCs complete in finite time in the presence of failures. These timeouts should always be printed as console messages. If Lustre timeouts are not accompanied by LNET timeouts, then you need to increase the lustre timeout on both servers and clients. + Lustre timeouts - Lustre timeouts ensure that + Lustre RPCs complete in a finite time in the presence of failures. These timeouts are + always printed as console messages. If Lustre timeouts are not accompanied by LNET + timeouts, then increase the Lustre timeout on both servers and clients. + + + Specific Lustre timeouts include: + + + /proc/sys/lustre/timeout - The time period that a client waits + for a server to complete an RPC (default is 100s). Servers wait half of this time for a + normal client RPC to complete and a quarter of this time for a single bulk request (read + or write of up to 4 MB) to complete. The client pings recoverable targets (MDS and OSTs) + at one quarter of the timeout, and the server waits one and a half times the timeout + before evicting a client for being "stale." + + A Lustre client sends periodic 'ping' messages to servers with which it + has had no communication for a specified period of time. Any network activity between + a client and a server in the file system also serves as a ping. + + + + /proc/sys/lustre/ldlm_timeout - The time period for which a + server will wait for a client to reply to an initial AST (lock cancellation request), + where the default is 20s for an OST and 6s for an MDS. If the client replies to the AST, + the server will give it a normal timeout (half the client timeout) to flush any dirty + data and release the lock. + + + /proc/sys/lustre/fail_loc - The internal debugging failure hook. + See lustre/include/linux/obd_support.h for the definitions of + individual failure locations. The default value is 0 (zero). + + + /proc/sys/lustre/dump_on_timeout - Triggers dumps of the Lustre + debug log when timeouts occur. The default value is 0 (zero). + + + /proc/sys/lustre/dump_on_eviction - Triggers dumps of the Lustre + debug log when an eviction occurs. The default value is 0 (zero). - Specific Lustre timeouts are described below. - /proc/sys/lustre/timeout - This is the time period that a client waits for a server to complete an RPC (default is 100s). Servers wait half of this time for a normal client RPC to complete and a quarter of this time for a single bulk request (read or write of up to 4 MB) to complete. The client pings recoverable targets (MDS and OSTs) at one quarter of the timeout, and the server waits one and a half times the timeout before evicting a client for being "stale." - - Lustre sends periodic 'PING' messages to servers with which it had no communication for a specified period of time. Any network activity on the file system that triggers network traffic toward servers also works as a health check. - - /proc/sys/lustre/ldlm_timeout - This is the time period for which a server will wait for a client to reply to an initial AST (lock cancellation request) where default is 20s for an OST and 6s for an MDS. If the client replies to the AST, the server will give it a normal timeout (half of the client timeout) to flush any dirty data and release the lock. - /proc/sys/lustre/fail_loc - This is the internal debugging failure hook. - See lustre/include/linux/obd_support.h for the definitions of individual failure locations. The default value is 0 (zero). - sysctl -w lustre.fail_loc=0x80000122 # drop a single reply - /proc/sys/lustre/dump_on_timeout - This triggers dumps of the Lustre debug log when timeouts occur. The default value is 0 (zero). - /proc/sys/lustre/dump_on_eviction - This triggers dumps of the Lustre debug log when an eviction occurs. The default value is 0 (zero). By default, debug logs are dumped to the /tmp folder; this location can be changed via /proc.
- <indexterm><primary>proc</primary><secondary>adaptive timeouts</secondary></indexterm>Adaptive Timeouts - Lustre offers an adaptive mechanism to set RPC timeouts. The adaptive timeouts feature (enabled, by default) causes servers to track actual RPC completion times, and to report estimated completion times for future RPCs back to clients. The clients use these estimates to set their future RPC timeout values. If server request processing slows down for any reason, the RPC completion estimates increase, and the clients allow more time for RPC completion. - If RPCs queued on the server approach their timeouts, then the server sends an early reply to the client, telling the client to allow more time. In this manner, clients avoid RPC timeouts and disconnect/reconnect cycles. Conversely, as a server speeds up, RPC timeout values decrease, allowing faster detection of non-responsive servers and faster attempts to reconnect to a server's failover partner. - In previous Lustre versions, the static obd_timeout (/proc/sys/lustre/timeout) value was used as the maximum completion time for all RPCs; this value also affected the client-server ping interval and initial recovery timer. Now, with adaptive timeouts, obd_timeout is only used for the ping interval and initial recovery estimate. When a client reconnects during recovery, the server uses the client's timeout value to reset the recovery wait period; i.e., the server learns how long the client had been willing to wait, and takes this into account when adjusting the recovery period. + <indexterm> + <primary>proc</primary> + <secondary>adaptive timeouts</secondary> + </indexterm>Adaptive Timeouts + In a Lustre file system, an adaptive mechanism is used to set RPC timeouts. The adaptive + timeouts feature (enabled, by default) causes servers to track actual RPC completion times + and to report estimated completion times for future RPCs back to clients. The clients use + these estimates to set their future RPC timeout values. If server request processing slows + down for any reason, the RPC completion estimates increase, and the clients allow more time + for RPC completion. + If RPCs queued on the server approach their timeouts, then the server sends an early + reply to the client, telling the client to allow more time. In this manner, clients avoid + RPC timeouts and disconnect/reconnect cycles. Conversely, as a server speeds up, RPC timeout + values decrease, allowing faster detection of non-responsive servers and faster attempts to + reconnect to the failover partner of the server. + Adaptive timeouts were introduced in the Lustre 1.8.0.1 release. Prior to this release, + the static obd_timeout (/proc/sys/lustre/timeout) + value was used as the maximum completion time for all RPCs; this value also affected the + client-server ping interval and initial recovery timer. With adaptive timeouts, + obd_timeout is only used for the ping interval and initial recovery + estimate. When a client reconnects during recovery, the server uses the client's + timeout value to reset the recovery wait period; i.e., the server learns how long the client + had been willing to wait, and takes this into account when adjusting the recovery + period.
- <indexterm><primary>proc</primary><secondary>configuring adaptive timeouts</secondary></indexterm><indexterm><primary>configuring</primary><secondary>adaptive timeouts</secondary></indexterm>Configuring Adaptive Timeouts - One of the goals of adaptive timeouts is to relieve users from having to tune the obd_timeout value. In general, obd_timeout should no longer need to be changed. However, there are several parameters related to adaptive timeouts that users can set. In most situations, the default values should be used. - The following parameters can be set persistently system-wide using lctl conf_param on the MGS. For example, lctl conf_param work1.sys.at_max=1500 sets the at_max value for all servers and clients using the work1 file system. + <indexterm> + <primary>proc</primary> + <secondary>configuring adaptive timeouts</secondary> + </indexterm><indexterm> + <primary>configuring</primary> + <secondary>adaptive timeouts</secondary> + </indexterm>Configuring Adaptive Timeouts + A goal of adaptive timeouts is to relieve users from having to tune the + obd_timeout value. In general, obd_timeout should + no longer need to be changed. However, several parameters related to adaptive timeouts can + be set by users. In most situations, the default values should be used. + The following parameters can be set persistently system-wide using lctl + conf_param on the MGS. For example, lctl conf_param + testfs.sys.at_max=1500 sets the at_max value for all + servers and clients using the testfs file system. - Nodes using multiple Lustre file systems must use the same at_* values for all file systems.) + Nodes using multiple Lustre file systems must use the same at_* + values for all file systems.) - - + + @@ -115,92 +202,151 @@ lustre-MDT0000 - at_min + + at_min - Sets the minimum adaptive timeout (in seconds). Default value is 0. The at_min parameter is the minimum processing time that a server will report. Clients base their timeouts on this value, but they do not use this value directly. If you experience cases in which, for unknown reasons, the adaptive timeout value is too short and clients time out their RPCs (usually due to temporary network outages), then you can increase the at_min value to compensate for this. Ideally, users should leave at_min set to its default. + Sets the minimum adaptive timeout (in seconds). Default value is 0. The + at_min parameter is the minimum processing time that a + server will report. Clients base their timeouts on this value, but they do not + use this value directly. If you experience cases in which, for unknown reasons, + the adaptive timeout value is too short and clients time out their RPCs (usually + due to temporary network outages), then you can increase the + at_min value to compensate for this. Ideally, users should + leave at_min set to its default. - at_max + + at_max - Sets the maximum adaptive timeout (in seconds). The at_max parameter is an upper-limit on the service time estimate, and is used as a 'failsafe' in case of rogue/bad/buggy code that would lead to never-ending estimate increases. If at_max is reached, an RPC request is considered 'broken' and should time out. - Setting at_max to 0 causes adaptive timeouts to be disabled and the old fixed-timeout method (obd_timeout) to be used. + Sets the maximum adaptive timeout (in seconds). The + at_max parameter is an upper-limit on the service time + estimate and is used as a 'failsafe' in case of rogue/bad/buggy code + that would lead to never-ending estimate increases. If at_max + is reached, an RPC request is considered 'broken' and will time + out. + Setting at_max to 0 causes adaptive timeouts to be + disabled and the static fixed-timeout method (obd_timeout) to + be used. - It is possible that slow hardware might validly cause the service estimate to increase beyond the default value of at_max. In this case, you should increase at_max to the maximum time you are willing to wait for an RPC completion. + It is possible that slow hardware might validly cause the service estimate + to increase beyond the default value of at_max. In this + case, you should increase at_max to the maximum time you + are willing to wait for an RPC completion. - at_history + + at_history - Sets a time period (in seconds) within which adaptive timeouts remember the slowest event that occurred. Default value is 600. + Sets a time period (in seconds) within which adaptive timeouts remember the + slowest event that occurred. Default value is 600. - at_early_margin + + at_early_margin - Sets how far before the deadline Lustre sends an early reply. Default value is 5 - This default was chosen as a reasonable time in which to send a reply from the point at which it was sent. + Sets how far before the deadline the Lustre client sends an early reply. + Default value is 5 + This default was chosen as a reasonable time in which to send a reply + from the point at which it was sent. . - at_extra + + at_extra - Sets the incremental amount of time that a server asks for, with each early reply. The server does not know how much time the RPC will take, so it asks for a fixed value. Default value is 30 - This default was chosen as a balance between sending too many early replies for the same RPC and overestimating the actual completion time - . When a server finds a queued request about to time out (and needs to send an early reply out), the server adds the at_extra value. If the time expires, the Lustre client enters recovery status and reconnects to restore it to normal status. - If you see multiple early replies for the same RPC asking for multiple 30-second increases, change the at_extra value to a larger number to cut down on early replies sent and, therefore, network load. + Sets the incremental amount of time that a server asks for, with each early + reply. The server does not know how much time the RPC will take, so it asks for + a fixed value. Default value is 30 + This default was chosen as a balance between sending too many early + replies for the same RPC and overestimating the actual completion + time. + . When a server finds a queued request about to time out (and needs + to send an early reply out), the server adds the at_extra + value. If the time expires, the Lustre client enters recovery status and + reconnects to restore it to normal status. + If you see multiple early replies for the same RPC asking for multiple + 30-second increases, change the at_extra value to a larger + number to cut down on early replies sent and, therefore, network load. - ldlm_enqueue_min + + ldlm_enqueue_min - Sets the minimum lock enqueue time. Default value is 100. The ldlm_enqueue time is the maximum of the measured enqueue estimate (influenced by at_min and at_max parameters), multiplied by a weighting factor, and the ldlm_enqueue_min setting. LDLM lock enqueues were based on the obd_timeout value; now they have a dedicated minimum value. Lock enqueues increase as the measured enqueue times increase (similar to adaptive timeouts). + Sets the minimum lock enqueue time. Default value is 100. The + ldlm_enqueue time is the maximum of the measured enqueue + estimate (influenced by at_min and at_max + parameters), multiplied by a weighting factor, and the + ldlm_enqueue_min setting. LDLM lock enqueues were based on + the obd_timeout value; now they have a dedicated minimum + value. Lock enqueues increase as the measured enqueue times increase (similar to + adaptive timeouts). - Adaptive timeouts are enabled, by default. To disable adaptive timeouts, at run time, set at_max to 0. On the MGS, run: + Adaptive timeouts are enabled by default. To disable adaptive timeouts, at run time, + set at_max to 0. On the MGS, run: $ lctl conf_param fsname.sys.at_max=0 - Changing adaptive timeouts status at runtime may cause transient timeout, reconnect, recovery, etc. + Changing the status of adaptive timeouts at runtime may cause a transient client + timeout, recovery, and reconnection.
- <indexterm><primary>proc</primary><secondary>interpreting adaptive timeouts</secondary></indexterm>Interpreting Adaptive Timeouts Information - Adaptive timeouts information can be read from /proc/fs/lustre/*/timeouts files (for each service and client) or with the lctl command. - This is an example from the /proc/fs/lustre/*/timeouts files: + <indexterm> + <primary>proc</primary> + <secondary>interpreting adaptive timeouts</secondary> + </indexterm>Interpreting Adaptive Timeout Information + Adaptive timeout information can be read from the timeouts files in + /proc/fs/lustre/*/ for each server and client or by using the + lctl command. + To read information from timeouts file, enter a command similar to: cfs21:~# cat /proc/fs/lustre/ost/OSS/ost_io/timeouts - This is an example using the lctl command: + To use the lctl command, enter a command similar to: $ lctl get_param -n ost.*.ost_io.timeouts - This is the sample output: + Example output: service : cur 33 worst 34 (at 1193427052, 0d0h26m40s ago) 1 1 33 2 - The ost_io service on this node is currently reporting an estimate of 33 seconds. The worst RPC service time was 34 seconds, and it happened 26 minutes ago. - The output also provides a history of service times. In the example, there are 4 "bins" of adaptive_timeout_history, with the maximum RPC time in each bin reported. In 0-150 seconds, the maximum RPC time was 1, with the same result in 150-300 seconds. From 300-450 seconds, the worst (maximum) RPC time was 33 seconds, and from 450-600s the worst time was 2 seconds. The current estimated service time is the maximum value of the 4 bins (33 seconds in this example). + In this example, the ost_io service on this node is currently + reporting an estimate of 33 seconds. The worst RPC service time was 34 seconds, and it + happened 26 minutes ago. + The output also provides a history of service times. In this example, four + "bins" of adaptive_timeout_history are shown, with the + maximum RPC time in each bin reported. In 0-150 seconds, the maximum RPC time was 1, with + the same result in 150-300 seconds. From 300-450 seconds, the worst (maximum) RPC time was + 33 seconds, and from 450-600s the worst time was 2 seconds. The current estimated service + time is the maximum value of the four bins (33 seconds in this example). Service times (as reported by the servers) are also tracked in the client OBDs: cfs21:# lctl get_param osc.*.timeouts last reply : 1193428639, 0d0h00m00s ago -network : cur 1 worst 2 (at 1193427053, 0d0h26m26s ago) 1 1 1 1 -portal 6 : cur 33 worst 34 (at 1193427052, 0d0h26m27s ago) 33 33 33 2 -portal 28 : cur 1 worst 1 (at 1193426141, 0d0h41m38s ago) 1 1 1 1 -portal 7 : cur 1 worst 1 (at 1193426141, 0d0h41m38s ago) 1 0 1 1 -portal 17 : cur 1 worst 1 (at 1193426177, 0d0h41m02s ago) 1 0 0 1 +network : cur 1 worst 2 (at 1193427053, 0d0h26m26s ago) 1 1 1 1 +portal 6 : cur 33 worst 34 (at 1193427052, 0d0h26m27s ago) 33 33 33 2 +portal 28 : cur 1 worst 1 (at 1193426141, 0d0h41m38s ago) 1 1 1 1 +portal 7 : cur 1 worst 1 (at 1193426141, 0d0h41m38s ago) 1 0 1 1 +portal 17 : cur 1 worst 1 (at 1193426177, 0d0h41m02s ago) 1 0 0 1 - In this case, RPCs to portal 6, the OST_IO_PORTAL (see lustre/include/lustre/lustre_idl.h), shows the history of what the ost_io portal has reported as the service estimate. - Server statistic files also show the range of estimates in the normal min/max/sum/sumsq manner. + In this case, RPCs to portal 6, the OST_IO_PORTAL (see + lustre/include/lustre/lustre_idl.h), shows the history of what the + ost_io portal has reported as the service estimate. + Server statistic files also show the range of estimates in the order + min/max/sum/sumsq. cfs21:~# lctl get_param mdt.*.mdt.stats ... req_timeout 6 samples [sec] 1 10 15 105 @@ -209,258 +355,336 @@ req_timeout 6 samples [sec] 1 10 15 105
- <indexterm><primary>proc</primary><secondary>LNET</secondary></indexterm><indexterm><primary>LNET</primary><secondary>proc</secondary></indexterm>LNET Information - This section describes /proc entries for LNET information. - /proc/sys/lnet/peers - Shows all NIDs known to this node and also gives information on the queue state. - # cat /proc/sys/lnet/peers -nid refs state max rtr min tx min queue -0@lo 1 ~rtr 0 0 0 0 0 0 -192.168.10.35@tcp 1 ~rtr 8 8 8 8 6 0 -192.168.10.36@tcp 1 ~rtr 8 8 8 8 6 0 -192.168.10.37@tcp 1 ~rtr 8 8 8 8 6 0 - The fields are explained below: - - - - - - - - Field - - - Description - - - - - - - + <indexterm> + <primary>proc</primary> + <secondary>LNET</secondary> + </indexterm><indexterm> + <primary>LNET</primary> + <secondary>proc</secondary> + </indexterm>LNET Information + This section describes /proc entries containing LNET information. + These entries include: + + /proc/sys/lnet/peers - Shows all NIDs known to this node and + provides information on the queue state. + Example: + # cat /proc/sys/lnet/peers +nid refs state max rtr min tx min queue +0@lo 1 ~rtr 0 0 0 0 0 0 +192.168.10.35@tcp 1 ~rtr 8 8 8 8 6 0 +192.168.10.36@tcp 1 ~rtr 8 8 8 8 6 0 +192.168.10.37@tcp 1 ~rtr 8 8 8 8 6 0 + The fields are explained in the table below: + + + + + + + + Field + + + Description + + + + + + + - refs - - - - - A reference count (principally used for debugging) - - - - - + refs + + + + + A reference count (principally used for debugging). + + + + + - state - - - - - Only valid to refer to routers. Possible values: - - - ~ rtr (indicates this node is not a router) - - - up/down (indicates this node is a router) - - - auto_fail must be enabled - - - - - - - max - - - Maximum number of concurrent sends from this peer - - - - - rtr - - - Routing buffer credits. - - - - - min - - - Minimum routing buffer credits seen. - - - - - tx - - - Send credits. - - - - - min - - - Minimum send credits seen. - - - - - queue - - - Total bytes in active/queued sends. - - - - - - Credits work like a semaphore. At start they are initialized to allow a certain number of operations (8 in this example). LNET keeps a track of the minimum value so that you can see how congested a resource was. - If rtr/tx is less than max, there are operations in progress. The number of operations is equal to rtr or tx subtracted from max. - If rtr/tx is greater that max, there are operations blocking. - LNET also limits concurrent sends and router buffers allocated to a single peer so that no peer can occupy all these resources. - /proc/sys/lnet/nis - # cat /proc/sys/lnet/nis -nid refs peer max tx min -0@lo 3 0 0 0 0 -192.168.10.34@tcp 4 8 256 256 252 + state + + + + + Only valid to refer to routers. Possible values: + + + ~rtr (indicates this node is not a router) + + + up/down (indicates this node is a router) + + + auto_fail (if enabled) + + + + + + + + max + + + Maximum number of concurrent sends from this peer. + + + + + + rtr + + + Routing buffer credits. + + + + + + min + + + Minimum routing buffer credits seen. + + + + + + tx + + + Send credits. + + + + + + min + + + Minimum send credits seen. + + + + + + queue + + + Total bytes in active/queued sends. + + + + + + Credits work like a semaphore. They are initialized to allow a certain number of + operations (8 in the example above). LNET keeps a track of the minimum value so that + you can see how congested a resource is. + A value of rtr/tx less than max indicates + operations are in progress. The number of operations is equal to + rtr or tx subtracted from + max. + A value of rtr/tx greater that max indicates + operations are blocking. + LNET also limits concurrent sends and router buffers allocated to a single peer so + that no peer can occupy all these resources. + + + + /proc/sys/lnet/nis - Shows the current queue health on this + node. + Example: + # cat /proc/sys/lnet/nis +nid refs peer max tx min +0@lo 3 0 0 0 0 +192.168.10.34@tcp 4 8 256 256 252 - Shows the current queue health on this node. The fields are explained below: - - - - - - - - Field - - - Description - - - - - - - nid - - - Network interface - - - - - refs - - - Internal reference counter - - - - - peer - - - Number of peer-to-peer send credits on this NID. Credits are used to size buffer pools - - - - - max - - - Total number of send credits on this NID. - - - - - tx - - - Current number of send credits available on this NID. - - - - - min - - - Lowest number of send credits available on this NID. - - - - - queue - - - Total bytes in active/queued sends. - - - - - - Subtracting max - tx yields the number of sends currently active. A large or increasing number of active sends may indicate a problem. - # cat /proc/sys/lnet/nis -nid refs peer max tx min -0@lo 2 0 0 0 0 -10.67.73.173@tcp 4 8 256 256 253 + The fields are explained below: + + + + + + + + Field + + + Description + + + + + + + + nid + + + Network interface. + + + + + + refs + + + Internal reference counter. + + + + + + peer + + + Number of peer-to-peer send credits on this NID. Credits are used to + size buffer pools. + + + + + + max + + + Total number of send credits on this NID. + + + + + + tx + + + Current number of send credits available on this NID. + + + + + + min + + + Lowest number of send credits available on this NID. + + + + + + queue + + + Total bytes in active/queued sends. + + + + + + Subtracting max - tx yields the number of + sends currently active. A large or increasing number of active sends may indicate a + problem. + Example: + # cat /proc/sys/lnet/nis +nid refs peer max tx min +0@lo 2 0 0 0 0 +10.67.73.173@tcp 4 8 256 256 253 + +
- <indexterm><primary>proc</primary><secondary>free space</secondary></indexterm>Free Space Distribution - Free-space stripe weighting, as set, gives a priority of "0" to free space (versus trying to place the stripes "widely" -- nicely distributed across OSSs and OSTs to maximize network balancing). To adjust this priority (as a percentage), use the qos_prio_free proc tunable: + <indexterm> + <primary>proc</primary> + <secondary>free space</secondary> + </indexterm>Free Space Distribution + Free-space stripe weighting, as set, gives a priority of "0" to free space + (versus trying to place the stripes "widely" -- nicely distributed across OSSs and + OSTs to maximize network balancing). To adjust this priority as a percentage, use the + /proc tunableqos_prio_free: $ cat /proc/fs/lustre/lov/fsname-mdtlov/qos_prio_free - Currently, the default is 90%. You can permanently set this value by running this command on the MGS: + The default is 90%. You can permanently set this value by running this command on the + MGS: $ lctl conf_param fsname-MDT0000.lov.qos_prio_free=90 - Setting the priority to 100% means that OSS distribution does not count in the weighting, but the stripe assignment is still done via weighting. If OST 2 has twice as much free space as OST 1, it is twice as likely to be used, but it is NOT guaranteed to be used. - Also note that free-space stripe weighting does not activate until two OSTs are imbalanced by more than 20%. Until then, a faster round-robin stripe allocator is used. (The new round-robin order also maximizes network balancing.) + Setting the priority to 100% means that OSS distribution does not count in the + weighting, but the stripe assignment is still done via weighting. If OST 2 has twice as much + free space as OST 1, it is twice as likely to be used, but it is NOT guaranteed to be + used. + Also note that free-space stripe weighting does not activate until two OSTs are + imbalanced by more than 20%. Until then, a faster round-robin stripe allocator is used. (The + round-robin order also maximizes network balancing.)
- <indexterm><primary>proc</primary><secondary>striping</secondary></indexterm>Managing Stripe Allocation - The MDS uses two methods to manage stripe allocation and determine which OSTs to use for file object storage: + <indexterm> + <primary>proc</primary> + <secondary>striping</secondary> + </indexterm>Managing Stripe Allocation + The MDS uses two methods to manage stripe allocation and determine which OSTs to use + for file object storage: QOS - Quality of Service (QOS) considers an OST's available blocks, speed, and the number of existing objects, etc. Using these criteria, the MDS selects OSTs with more free space more often than OSTs with less free space. + Quality of Service (QOS) considers an OST's available blocks, speed, and the + number of existing objects, etc. Using these criteria, the MDS selects OSTs with more + free space more often than OSTs with less free space. RR - Round-Robin (RR) allocates objects evenly across all OSTs. The RR stripe allocator is faster than QOS, and used often because it distributes space usage/load best in most situations, maximizing network balancing and improving performance. + Round-Robin (RR) allocates objects evenly across all OSTs. The RR stripe allocator + is faster than QOS, and used often because it distributes space usage/load best in + most situations, maximizing network balancing and improving performance. - Whether QOS or RR is used depends on the setting of the qos_threshold_rr proc tunable. The qos_threshold_rr variable specifies a percentage threshold where the use of QOS or RR becomes more/less likely. The qos_threshold_rr tunable can be set as an integer, from 0 to 100, and results in this stripe allocation behavior: + Whether QOS or RR is used depends on the setting of the + qos_threshold_rr proc tunable. The + qos_threshold_rr variable specifies a percentage threshold where the + use of QOS or RR becomes more/less likely. The qos_threshold_rr tunable + can be set as an integer, from 0 to 100, and results in this stripe allocation + behavior: - If qos_threshold_rr is set to 0, then QOS is always used + If qos_threshold_rr is set to 0, then QOS is always + used - If qos_threshold_rr is set to 100, then RR is always used + If qos_threshold_rr is set to 100, then RR is always + used - The larger the qos_threshold_rr setting, the greater the possibility that RR is used instead of QOS + The larger the qos_threshold_rr setting, the greater the + possibility that RR is used instead of QOS
- <indexterm><primary>proc</primary><secondary>I/O tunables</secondary></indexterm>Lustre I/O Tunables - The section describes I/O tunables. + <indexterm> + <primary>proc</primary> + <secondary>I/O tunables</secondary> + </indexterm>Lustre I/O Tunables + This section describes I/O tunables. llite.fsname-instance/max_cache_mb client# lctl get_param llite.lustre-ce63ca00.max_cached_mb 128 - This tunable is the maximum amount of inactive data cached by the client (default is 3/4 of RAM). + This tunable is the maximum amount of inactive data cached by the client (default is 3/4 + of RAM).
- <indexterm><primary>proc</primary><secondary>RPC tunables</secondary></indexterm>Client I/O RPC Stream Tunables - The Lustre engine always attempts to pack an optimal amount of data into each I/O RPC and attempts to keep a consistent number of issued RPCs in progress at a time. Lustre exposes several tuning variables to adjust behavior according to network conditions and cluster size. Each OSC has its own tree of these tunables. For example: + <indexterm> + <primary>proc</primary> + <secondary>RPC tunables</secondary> + </indexterm>Client I/O RPC Stream Tunables + The Lustre engine always attempts to pack an optimal amount of data into each I/O RPC + and attempts to keep a consistent number of issued RPCs in progress at a time. Lustre + exposes several tuning variables to adjust behavior according to network conditions and + cluster size. Each OSC has its own tree of these tunables. For example: $ ls -d /proc/fs/lustre/osc/OSC_client_ost1_MNT_client_2 /localhost /proc/fs/lustre/osc/OSC_uml0_ost1_MNT_localhost /proc/fs/lustre/osc/OSC_uml0_ost2_MNT_localhost @@ -469,49 +693,131 @@ $ ls /proc/fs/lustre/osc/OSC_uml0_ost1_MNT_localhost blocksizefilesfree max_dirty_mb ost_server_uuid stats ... and so on. RPC stream tunables are described below. - osc.osc_instance.max_dirty_mb - This tunable controls how many MBs of dirty data can be written and queued up in the OSC. POSIX file writes that are cached contribute to this count. When the limit is reached, additional writes stall until previously-cached writes are written to the server. This may be changed by writing a single ASCII integer to the file. Only values between 0 and 2048 or 1/4 of RAM are allowable. If 0 is given, no writes are cached. Performance suffers noticeably unless you use large writes (1 MB or more). - osc.osc_instance.cur_dirty_bytes - This tunable is a read-only value that returns the current amount of bytes written and cached on this OSC. - osc.osc_instance.max_pages_per_rpc - This tunable is the maximum number of pages that will undergo I/O in a single RPC to the OST. The minimum is a single page and the maximum for this setting is 1024 (for systems with 4kB PAGE_SIZE), with the default maximum of 1MB in the RPC. It is also possible to specify a units suffix (e.g. 4M), so that the RPC size can be specified independently of the client PAGE_SIZE. - osc.osc_instance.max_rpcs_in_flight - This tunable is the maximum number of concurrent RPCs in flight from an OSC to its OST. If the OSC tries to initiate an RPC but finds that it already has the same number of RPCs outstanding, it will wait to issue further RPCs until some complete. The minimum setting is 1 and maximum setting is 256. If you are looking to improve small file I/O performance, increase the max_rpcs_in_flight value. - To maximize performance, the value for max_dirty_mb is recommended to be 4 * max_pages_per_rpc * max_rpcs_in_flight. + + + + osc.osc_instance.max_dirty_mb - This + tunable controls how many MBs of dirty data can be written and queued up in the + OSC. POSIX file writes that are cached contribute to this count. + When the limit is reached, additional writes stall until previously-cached writes are + written to the server. This may be changed by writing a single ASCII integer to the + file. Only values between 0 and 2048 or 1/4 of RAM are allowable. If 0 is given, no + writes are cached. Performance suffers noticeably unless you use large writes (1 MB or + more). + + + osc.osc_instance.cur_dirty_bytes - + This tunable is a read-only value that returns the current amount of bytes written and + cached on this OSC. + + + osc.osc_instance.max_pages_per_rpc - + This tunable is the maximum number of pages that will undergo I/O in a single RPC to + the OST. The minimum is a single page and the maximum for this setting is 1024 (for + systems with 4kB PAGE_SIZE), with the default maximum of 1MB in the + RPC. It is also possible to specify a units suffix (e.g. 4M), so + that the RPC size can be specified independently of the client + PAGE_SIZE. + + + osc.osc_instance.max_rpcs_in_flight + - This tunable is the maximum number of concurrent RPCs in flight from an OSC to its + OST. If the OSC tries to initiate an RPC but finds that it already has the same number + of RPCs outstanding, it will wait to issue further RPCs until some complete. The + minimum setting is 1 and maximum setting is 256. If you are looking to improve small + file I/O performance, increase the max_rpcs_in_flight value. + + + + To maximize performance, the value for max_dirty_mb is recommended to + be 4 * max_pages_per_rpc * max_rpcs_in_flight. - The - - osc_instance - - is typically fsname-OSTost_index-osc-mountpoint_instance. The mountpoint_instance is a unique value per mountpoint to allow associating osc, mdc, lov, lmv, and llite parameters for the same mountpoint. For osc_instance examples, refer to the sample command output. + The osc_instance is typically + fsname-OSTost_index-osc-mountpoint_instance. + The mountpoint_instance is a unique value + per mount point to allow associating osc, mdc, lov, lmv, and llite parameters for the same + mount point. For osc_instance examples, + refer to the sample command output.
- <indexterm><primary>proc</primary><secondary>watching RPC</secondary></indexterm>Watching the Client RPC Stream - The same directory contains a rpc_stats file with a histogram showing the composition of previous RPCs. The histogram can be cleared by writing any value into the rpc_stats file. - # cat /proc/fs/lustre/osc/spfs-OST0000-osc-c45f9c00/rpc_stats -snapshot_time: 1174867307.156604 (secs.usecs) -read RPCs in flight: 0 -write RPCs in flight: 0 -pending write pages: 0 -pending read pages: 0 - read write -pages per rpc rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 + <indexterm> + <primary>proc</primary> + <secondary>watching RPC</secondary> + </indexterm>Watching the Client RPC Stream + The same directory contains an rpc_stats file with a histogram + showing the composition of previous RPCs. The histogram can be cleared by writing any value + into the rpc_stats file. + # cat /proc/fs/lustre/osc/testfs-OST0000-osc-c45f9c00/rpc_stats +snapshot_time: 1174867307.156604 (secs.usecs) +read RPCs in flight: 0 +write RPCs in flight: 0 +pending write pages: 0 +pending read pages: 0 + read write +pages per rpc rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 - read write -rpcs in flight rpcs % cum % | rpcs % cum % -0: 0 0 0 | 0 0 0 + read write +rpcs in flight rpcs % cum % | rpcs % cum % +0: 0 0 0 | 0 0 0 - read write -offset rpcs % cum % | rpcs % cum % -0: 0 0 0 | 0 0 0 + read write +offset rpcs % cum % | rpcs % cum % +0: 0 0 0 | 0 0 0 + + +# cat /proc/fs/lustre/osc/testfs-OST0000-osc-ffff810058d2f800/rpc_stats +snapshot_time: 1372786692.389858 (secs.usecs) +read RPCs in flight: 0 +write RPCs in flight: 1 +dio read RPCs in flight: 0 +dio write RPCs in flight: 0 +pending write pages: 256 +pending read pages: 0 + + read write +pages per rpc rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 +2: 0 0 0 | 1 0 0 +4: 0 0 0 | 0 0 0 +8: 0 0 0 | 0 0 0 +16: 0 0 0 | 0 0 0 +32: 0 0 0 | 2 0 0 +64: 0 0 0 | 2 0 0 +128: 0 0 0 | 5 0 0 +256: 850 100 100 | 18346 99 100 + + read write +rpcs in flight rpcs % cum % | rpcs % cum % +0: 691 81 81 | 1740 9 9 +1: 48 5 86 | 938 5 14 +2: 29 3 90 | 1059 5 20 +3: 17 2 92 | 1052 5 26 +4: 13 1 93 | 920 5 31 +5: 12 1 95 | 425 2 33 +6: 10 1 96 | 389 2 35 +7: 30 3 100 | 11373 61 97 +8: 0 0 100 | 460 2 100 + + read write +offset rpcs % cum % | rpcs % cum % +0: 850 100 100 | 18347 99 99 +1: 0 0 100 | 0 0 99 +2: 0 0 100 | 0 0 99 +4: 0 0 100 | 0 0 99 +8: 0 0 100 | 0 0 99 +16: 0 0 100 | 1 0 99 +32: 0 0 100 | 1 0 99 +64: 0 0 100 | 3 0 99 +128: 0 0 100 | 4 0 100 + Where: - - + + @@ -525,40 +831,56 @@ offset rpcs % cum % | rpcs % - {read,write} RPCs in flight + {read,write} RPCs in flight - Number of read/write RPCs issued by the OSC, but not complete at the time of the snapshot. This value should always be less than or equal to max_rpcs_in_flight. + Number of read/write RPCs issued by the OSC, but not complete at the time of + the snapshot. This value should always be less than or equal to + max_rpcs_in_flight. - pending {read,write} pages + pending {read,write} pages - Number of pending read/write pages that have been queued for I/O in the OSC. + Number of pending read/write pages that have been queued for I/O in the + OSC. + dio {read,write} RPCs in flight + Direct I/O (as opposed to block I/O) read/write RPCs issued but not completed + at the time of the snapshot. + + - pages per RPC + pages per RPC - When an RPC is sent, the number of pages it consists of is recorded (in order). A single page RPC increments the 0: row. + When an RPC is sent, the number of pages it consists of is recorded (in + order). A single page RPC increments the 0: row. - RPCs in flight + RPCs in flight - When an RPC is sent, the number of other RPCs that are pending is recorded. When the first RPC is sent, the 0: row is incremented. If the first RPC is sent while another is pending, the 1: row is incremented and so on. As each RPC *completes*, the number of pending RPCs is not tabulated. - This table is a good way to visualize the concurrency of the RPC stream. Ideally, you will see a large clump around the max_rpcs_in_flight value, which shows that the network is being kept busy. + When an RPC is sent, the number of other RPCs that are pending is recorded. + When the first RPC is sent, the 0: row is incremented. If the + first RPC is sent while another is pending, the 1: row is + incremented and so on. As each RPC *completes*, the number of pending RPCs is not + tabulated. + This table is a good way to visualize the concurrency of the RPC stream. + Ideally, you will see a large clump around the + max_rpcs_in_flight value, which shows that the network is + being kept busy. - offset + offset @@ -567,21 +889,31 @@ offset rpcs % cum % | rpcs % + Each row in the table shows the number of reads or writes occurring for the statistic + (ios), the relative percentage of total reads or writes (%), and the cumulative percentage + to that point in the table for the statistic (cum %).
- <indexterm><primary>proc</primary><secondary>read/write survey</secondary></indexterm>Client Read-Write Offset Survey - The offset_stats parameter maintains statistics for occurrences where a series of read or write calls from a process did not access the next sequential location. The offset field is reset to 0 (zero) whenever a different file is read/written. - Read/write offset statistics are off, by default. The statistics can be activated by writing anything into the offset_stats file. + <indexterm> + <primary>proc</primary> + <secondary>read/write survey</secondary> + </indexterm>Client Read-Write Offset Survey + The offset_stats parameter maintains statistics for occurrences where + a series of read or write calls from a process did not access the next sequential location. + The offset field is reset to 0 (zero) whenever a different file is read/written. + Read/write offset statistics are off by default. The statistics can be activated by + writing anything into the offset_stats file. Example: # cat /proc/fs/lustre/llite/lustre-f57dee00/rw_offset_stats snapshot_time: 1155748884.591028 (secs.usecs) -R/W PID RANGE START RANGE END SMALLEST EXTENT LARGEST EXTENT OFFSET -R 8385 0 128 128 128 0 -R 8385 0 224 224 224 -128 -W 8385 0 250 50 100 0 -W 8385 100 1110 10 500 -150 -W 8384 0 5233 5233 5233 0 -R 8385 500 600 100 100 -610 + RANGE RANGE SMALLEST LARGEST +R/W PID START END EXTENT EXTENT OFFSET +R 8385 0 128 128 128 0 +R 8385 0 224 224 224 -128 +W 8385 0 250 50 100 0 +W 8385 100 1110 10 500 -150 +W 8384 0 5233 5233 5233 0 +R 8385 500 600 100 100 -610 Where: @@ -600,7 +932,7 @@ R 8385 500 600 100 - R/W + R/W Whether the non-sequential call was a read or write @@ -608,7 +940,7 @@ R 8385 500 600 100 - PID + PID Process ID which made the read/write call. @@ -616,7 +948,7 @@ R 8385 500 600 100 - Range Start/Range End + Range Start/Range End Range in which the read/write calls were sequential. @@ -624,7 +956,7 @@ R 8385 500 600 100 - Smallest Extent + Smallest Extent Smallest extent (single read/write) in the corresponding range. @@ -632,7 +964,7 @@ R 8385 500 600 100 - Largest Extent + Largest Extent Largest extent (single read/write) in the corresponding range. @@ -640,13 +972,18 @@ R 8385 500 600 100 - Offset + Offset - Difference from the previous range end to the current range start. - For example, Smallest-Extent indicates that the writes in the range 100 to 1110 were sequential, with a minimum write of 10 and a maximum write of 500. This range was started with an offset of -150. That means this is the difference between the last entry's range-end and this entry's range-start for the same file. - The rw_offset_stats file can be cleared by writing to it: - lctl set_param llite.*.rw_offset_stats=0 + Difference between the previous range end and the current range start. + For example, Smallest-Extent indicates that the writes in the range 100 to + 1110 were sequential, with a minimum write of 10 and a maximum write of 500. This + range was started with an offset of -150. That means this is the difference + between the last entry's range-end and this entry's range-start for the + same file. + The rw_offset_stats file can be cleared by writing to + it: + lctl set_param llite.*.rw_offset_stats=0 @@ -654,26 +991,38 @@ R 8385 500 600 100
- <indexterm><primary>proc</primary><secondary>client stats</secondary></indexterm>Client stats - The stats parameter maintains statistics of activity across the VFS interface of the Lustre file system. Only non-zero parameters are displayed in the file. This section of the manual covers the statistics that will accumulate during typical operation of a client. - Client statistics are enabled by default. The statistics can be cleared by echoing an empty string into the stats file or with the command: lctl set_param llite.*.stats=0. Statistics for an individual file system can be displayed, for example: + <indexterm> + <primary>proc</primary> + <secondary>client stats</secondary> + </indexterm>Client Statistics + The stats parameter maintains statistics of activity across the VFS + interface of the Lustre file system. Only non-zero parameters are displayed in the file. + This section describes the statistics that accumulate during typical operation of a + client. + Client statistics are enabled by default. The statistics can be cleared by echoing an + empty string into the stats file or by using the command: lctl + set_param llite.*.stats=0. Statistics for an individual file system can be + displayed, for example, as shown below: client# lctl get_param llite.*.stats -snapshot_time 1308343279.169704 secs.usecs -dirty_pages_hits 14819716 samples [regs] -dirty_pages_misses 81473472 samples [regs] -read_bytes 36502963 samples [bytes] 1 26843582 55488794 -write_bytes 22985001 samples [bytes] 0 125912 3379002 -brw_read 2279 samples [pages] 1 1 2270 -ioctl 186749 samples [regs] -open 3304805 samples [regs] -close 3331323 samples [regs] -seek 48222475 samples [regs] -fsync 963 samples [regs] -truncate 9073 samples [regs] -setxattr 19059 samples [regs] -getxattr 61169 samples [regs] +snapshot_time 1308343279.169704 secs.usecs +dirty_pages_hits 14819716 samples [regs] +dirty_pages_misses 81473472 samples [regs] +read_bytes 36502963 samples [bytes] 1 26843582 55488794 +write_bytes 22985001 samples [bytes] 0 125912 3379002 +brw_read 2279 samples [pages] 1 1 2270 +ioctl 186749 samples [regs] +open 3304805 samples [regs] +close 3331323 samples [regs] +seek 48222475 samples [regs] +fsync 963 samples [regs] +truncate 9073 samples [regs] +setxattr 19059 samples [regs] +getxattr 61169 samples [regs] -Statistics for all mounted file systems can be discovered by issuing the lctl command: lctl get_param llite.*.stats + + Statistics for all mounted file systems can be discovered by issuing the + lctl command lctl get_param llite.*.stats + @@ -691,114 +1040,152 @@ getxattr 61169 samples [regs] - snapshot_time - - - Unix epoch instant the stats file was read. - - - - - dirty_page_hits + + snapshot_time - A count of the number of write operations that have been satisfied by the dirty page cache. See for dirty cache behavior in Lustre. + UNIX* epoch instant the stats file was read. - dirty_page_misses + + dirty_page_hits - A count of the number of write operations that were not satisfied by the dirty page cache. + A count of the number of write operations that have been satisfied by the + dirty page cache. See for dirty cache behavior in a Lustre file + system. - read_bytes + + dirty_page_misses - A count of the number of read operations that have occurred (samples). Three additional parameters are given: - - - min - The minimum number of bytes read in a single request since the counter was reset. - - - - max - The maximum number of bytes read in a single request since the counter was reset. - - - - sum - The accumulated sum of bytes of all read requests since the counter was reset. - - - + A count of the number of write operations that were not satisfied by the dirty + page cache. - write_bytes + + read_bytes - A count of the number of write operations that have occurred (samples). Three additional parameters are given: - - - min - The minimum number of bytes written in a single request since the counter was reset. - - - - max - The maximum number of bytes written in a single request since the counter was reset. - - - - sum - The accumulated sum of bytes of all write requests since the counter was reset. - - - + A count of the number of read operations that have occurred (samples). Three + additional parameters are given: + + + min + + The minimum number of bytes read in a single request since the counter + was reset. + + + + max + + The maximum number of bytes read in a single request since the counter + was reset. + + + + sum + + The accumulated sum of bytes of all read requests since the counter was + reset. + + + - brw_read + + write_bytes - A count of the number of pages that have been read. brw_ stats are only tallied when the lloop device driver is present. lloop device is not currently supported.Three additional parameters are given: - - - min - The minimum number of bytes read in a single brw read requests since the counter was reset. - - - - max - The maximum number of bytes read in a single brw read requests since the counter was reset. - - - - sum - The accumulated sum of bytes of all brw read requests since the counter was reset. - - - + A count of the number of write operations that have occurred (samples). Three + additional parameters are given: + + + min + + The minimum number of bytes written in a single request since the + counter was reset. + + + + max + + The maximum number of bytes written in a single request since the + counter was reset. + + + + sum + + The accumulated sum of bytes of all write requests since the counter was + reset. + + + - ioctl - - - A count of the number of the combined file and directory ioctl operations. + + brw_read - - - open + A count of the number of pages that have been read. + + brw_ stats are only tallied when the lloop device driver + is present. lloop device is not currently supported. + + Three additional parameters are given: + + + min + + The minimum number of bytes read in a single brw read requests since the + counter was reset. + + + + max + + The maximum number of bytes read in a single brw read requests since the + counter was reset. + + + + sum + + The accumulated sum of bytes of all brw read requests since the counter + was reset. + + + + + + + + + ioctl + + + A count of the number of the combined file and directory ioctl + operations. + + + + + + open A count of the number of open operations that have succeeded. @@ -806,7 +1193,8 @@ getxattr 61169 samples [regs] - close + + close A count of the number of close operations that have succeeded. @@ -814,42 +1202,51 @@ getxattr 61169 samples [regs] - seek + + seek - A count of the number of times seek has been called. + A count of the number of times seek has been called. - fsync + + fsync - A count of the number of times fsync has been called. + A count of the number of times fsync has been + called. - truncate + + truncate - A count of the total number of calls to both locked and lockless truncate. + A count of the total number of calls to both locked and lockless + truncate. - setxattr + + setxattr - A count of the number of times ll_setxattr has been called. + A count of the number of times ll_setxattr has been + called. - getxattr + + getxattr - A count of the number of times ll_getxattr has been called. + A count of the number of times ll_getxattr has been + called. @@ -857,96 +1254,182 @@ getxattr 61169 samples [regs]
- <indexterm><primary>proc</primary><secondary>read/write survey</secondary></indexterm>Client Read-Write Extents Survey + <indexterm> + <primary>proc</primary> + <secondary>read/write survey</secondary> + </indexterm>Client Read-Write Extents Survey Client-Based I/O Extent Size Survey - The rw_extent_stats histogram in the llite directory shows you the statistics for the sizes of the read-write I/O extents. This file does not maintain the per-process statistics. + The rw_extent_stats histogram in the llite + directory shows you the statistics for the sizes of the read-write I/O extents. This file + does not maintain the per-process statistics. Example: client# lctl get_param llite.testfs-*.extents_stats snapshot_time: 1213828728.348516 (secs.usecs) - read | write -extents calls % cum% | calls % cum% + read | write +extents calls % cum% | calls % cum% -0K - 4K : 0 0 0 | 2 2 2 -4K - 8K : 0 0 0 | 0 0 2 -8K - 16K : 0 0 0 | 0 0 2 -16K - 32K : 0 0 0 | 20 23 26 -32K - 64K : 0 0 0 | 0 0 26 -64K - 128K : 0 0 0 | 51 60 86 -128K - 256K : 0 0 0 | 0 0 86 -256K - 512K : 0 0 0 | 0 0 86 -512K - 1024K : 0 0 0 | 0 0 86 -1M - 2M : 0 0 0 | 11 13 100 +0K - 4K : 0 0 0 | 2 2 2 +4K - 8K : 0 0 0 | 0 0 2 +8K - 16K : 0 0 0 | 0 0 2 +16K - 32K : 0 0 0 | 20 23 26 +32K - 64K : 0 0 0 | 0 0 26 +64K - 128K : 0 0 0 | 51 60 86 +128K - 256K : 0 0 0 | 0 0 86 +256K - 512K : 0 0 0 | 0 0 86 +512K - 1024K : 0 0 0 | 0 0 86 +1M - 2M : 0 0 0 | 11 13 100 The file can be cleared by issuing the following command: client# lctl set_param llite.testfs-*.extents_stats=0 Per-Process Client I/O Statistics - The extents_stats_per_process file maintains the I/O extent size statistics on a per-process basis. So you can track the per-process statistics for the last MAX_PER_PROCESS_HIST processes. + The extents_stats_per_process file maintains the I/O extent size + statistics on a per-process basis. So you can track the per-process statistics for the last + MAX_PER_PROCESS_HIST processes. Example: lctl get_param llite.testfs-*.extents_stats_per_process snapshot_time: 1213828762.204440 (secs.usecs) - read | write -extents calls % cum% | calls % cum% + read | write +extents calls % cum% | calls % cum% PID: 11488 - 0K - 4K : 0 0 0 | 0 0 0 - 4K - 8K : 0 0 0 | 0 0 0 - 8K - 16K : 0 0 0 | 0 0 0 - 16K - 32K : 0 0 0 | 0 0 0 - 32K - 64K : 0 0 0 | 0 0 0 - 64K - 128K : 0 0 0 | 0 0 0 - 128K - 256K : 0 0 0 | 0 0 0 - 256K - 512K : 0 0 0 | 0 0 0 - 512K - 1024K : 0 0 0 | 0 0 0 - 1M - 2M : 0 0 0 | 10 100 100 + 0K - 4K : 0 0 0 | 0 0 0 + 4K - 8K : 0 0 0 | 0 0 0 + 8K - 16K : 0 0 0 | 0 0 0 + 16K - 32K : 0 0 0 | 0 0 0 + 32K - 64K : 0 0 0 | 0 0 0 + 64K - 128K : 0 0 0 | 0 0 0 + 128K - 256K : 0 0 0 | 0 0 0 + 256K - 512K : 0 0 0 | 0 0 0 + 512K - 1024K : 0 0 0 | 0 0 0 + 1M - 2M : 0 0 0 | 10 100 100 PID: 11491 - 0K - 4K : 0 0 0 | 0 0 0 - 4K - 8K : 0 0 0 | 0 0 0 - 8K - 16K : 0 0 0 | 0 0 0 - 16K - 32K : 0 0 0 | 20 100 100 + 0K - 4K : 0 0 0 | 0 0 0 + 4K - 8K : 0 0 0 | 0 0 0 + 8K - 16K : 0 0 0 | 0 0 0 + 16K - 32K : 0 0 0 | 20 100 100 PID: 11424 - 0K - 4K : 0 0 0 | 0 0 0 - 4K - 8K : 0 0 0 | 0 0 0 - 8K - 16K : 0 0 0 | 0 0 0 - 16K - 32K : 0 0 0 | 0 0 0 - 32K - 64K : 0 0 0 | 0 0 0 - 64K - 128K : 0 0 0 | 16 100 100 + 0K - 4K : 0 0 0 | 0 0 0 + 4K - 8K : 0 0 0 | 0 0 0 + 8K - 16K : 0 0 0 | 0 0 0 + 16K - 32K : 0 0 0 | 0 0 0 + 32K - 64K : 0 0 0 | 0 0 0 + 64K - 128K : 0 0 0 | 16 100 100 PID: 11426 - 0K - 4K : 0 0 0 | 1 100 100 + 0K - 4K : 0 0 0 | 1 100 100 PID: 11429 - 0K - 4K : 0 0 0 | 1 100 100 + 0K - 4K : 0 0 0 | 1 100 100 + Each row in the table shows the number of reads or writes occurring for the statistic + (ios), the relative percentage of total reads or writes (%), and the cumulative percentage + to that point in the table for the statistic (cum %).
- <indexterm><primary>proc</primary><secondary>block I/O</secondary></indexterm>Watching the OST Block I/O Stream - Similarly, there is a brw_stats histogram in the obdfilter directory which shows you the statistics for number of I/O requests sent to the disk, their size and whether they are contiguous on the disk or not. + <indexterm> + <primary>proc</primary> + <secondary>block I/O</secondary> + </indexterm>Watching the OST Block I/O Stream + Similarly, a brw_stats histogram in the obdfilter directory shows the + statistics for number of I/O requests sent to the disk, their size, and whether they are + contiguous on the disk or not. oss# lctl get_param obdfilter.testfs-OST0000.brw_stats snapshot_time: 1174875636.764630 (secs:usecs) - read write -pages per brw brws % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write -discont pages rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write -discont blocks rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write -dio frags rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write -disk ios in flight rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write -io time (1/1000s) rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write -disk io size rpcs % cum % | rpcs % cum % -1: 0 0 0 | 0 0 0 - read write + read write +pages per brw brws % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write +discont pages rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write +discont blocks rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write +dio frags rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write +disk ios in flight rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write +io time (1/1000s) rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write +disk io size rpcs % cum % | rpcs % cum % +1: 0 0 0 | 0 0 0 + read write + +# cat ./obdfilter/testfs-OST0000/brw_stats +snapshot_time: 1372775039.769045 (secs.usecs) + + read | write +pages per bulk r/w rpcs % cum % | rpcs % cum % +1: 108 100 100 | 39 0 0 +2: 0 0 100 | 6 0 0 +4: 0 0 100 | 1 0 0 +8: 0 0 100 | 0 0 0 +16: 0 0 100 | 4 0 0 +32: 0 0 100 | 17 0 0 +64: 0 0 100 | 12 0 0 +128: 0 0 100 | 24 0 0 +256: 0 0 100 | 23142 99 100 + + read | write +discontiguous pages rpcs % cum % | rpcs % cum % +0: 108 100 100 | 23245 100 100 + + read | write +discontiguous blocks rpcs % cum % | rpcs % cum % +0: 108 100 100 | 23243 99 99 +1: 0 0 100 | 2 0 100 + + read | write +disk fragmented I/Os ios % cum % | ios % cum % +0: 94 87 87 | 0 0 0 +1: 14 12 100 | 23243 99 99 +2: 0 0 100 | 2 0 100 + + read | write +disk I/Os in flight ios % cum % | ios % cum % +1: 14 100 100 | 20896 89 89 +2: 0 0 100 | 1071 4 94 +3: 0 0 100 | 573 2 96 +4: 0 0 100 | 300 1 98 +5: 0 0 100 | 166 0 98 +6: 0 0 100 | 108 0 99 +7: 0 0 100 | 81 0 99 +8: 0 0 100 | 47 0 99 +9: 0 0 100 | 5 0 100 + + read | write +I/O time (1/1000s) ios % cum % | ios % cum % +1: 94 87 87 | 0 0 0 +2: 0 0 87 | 7 0 0 +4: 14 12 100 | 27 0 0 +8: 0 0 100 | 14 0 0 +16: 0 0 100 | 31 0 0 +32: 0 0 100 | 38 0 0 +64: 0 0 100 | 18979 81 82 +128: 0 0 100 | 943 4 86 +256: 0 0 100 | 1233 5 91 +512: 0 0 100 | 1825 7 99 +1K: 0 0 100 | 99 0 99 +2K: 0 0 100 | 0 0 99 +4K: 0 0 100 | 0 0 99 +8K: 0 0 100 | 49 0 100 + + read | write +disk I/O size ios % cum % | ios % cum % +4K: 14 100 100 | 41 0 0 +8K: 0 0 100 | 6 0 0 +16K: 0 0 100 | 1 0 0 +32K: 0 0 100 | 0 0 0 +64K: 0 0 100 | 4 0 0 +128K: 0 0 100 | 17 0 0 +256K: 0 0 100 | 12 0 0 +512K: 0 0 100 | 24 0 0 +1M: 0 0 100 | 23142 99 100 The fields are explained below: @@ -966,31 +1449,72 @@ disk io size rpcs % cum % | rpcs % cum % - pages per brw + + pages per bulk r/w + + + Number of pages per RPC request, which should match aggregate client + rpc_stats. + + + + + + discontiguous pages + + + Number of discontinuities in the logical file offset of each page in a single + RPC. + + + + + + discontiguous blocks + + + Number of discontinuities in the physical block allocation in the file system + for a single RPC. + + + + + disk fragmented I/Os + + + Number of I/Os that were not written entirely sequentially. + + + + + disk I/Os in flight - Number of pages per RPC request, which should match aggregate client rpc_stats. + Number of disk I/Os currently pending. - discont pages + I/O time (1/1000s) - Number of discontinuities in the logical file offset of each page in a single RPC. + Amount of time for each I/O operation to complete. - discont blocks + disk I/O size - Number of discontinuities in the physical block allocation in the file system for a single RPC. + Size of each I/O operation. + Each row in the table shows the number of reads or writes occurring for the statistic + (ios), the relative percentage of total reads or writes (%), and the cumulative percentage + to that point in the table for the statistic (cum %). For each Lustre service, the following information is provided: @@ -1014,31 +1538,62 @@ disk io size rpcs % cum % | rpcs % cum %
- <indexterm><primary>proc</primary><secondary>readahead</secondary></indexterm>Using File Readahead and Directory Statahead - Lustre 1.6.5.1 introduced file readahead and directory statahead functionality that read data into memory in anticipation of a process actually requesting the data. File readahead functionality reads file content data into memory. Directory statahead functionality reads metadata into memory. When readahead and/or statahead work well, a data-consuming process finds that the information it needs is available when requested, and it is unnecessary to wait for network I/O. - Since Lustre 2.2.0, the directory statahead feature has been improved to enhance directory traversal performance. The improvements have concentrated on two main issues: + <indexterm> + <primary>proc</primary> + <secondary>readahead</secondary> + </indexterm>Using File Readahead and Directory Statahead + Lustre 1.6.5.1 introduced file readahead and directory statahead functionality that read + data into memory in anticipation of a process actually requesting the data. File readahead + functionality reads file content data into memory. Directory statahead functionality reads + metadata into memory. When readahead and/or statahead work well, a data-consuming process + finds that the information it needs is available when requested, and it is unnecessary to + wait for network I/O. + Since Lustre 2.2.0, the directory statahead feature has been improved to enhance + directory traversal performance. The improvements have concentrated on two main + issues: - A race condition between statahead thread and other VFS operations while processing asynchronous getattr RPC replies. + A race condition between statahead thread and other VFS operations while processing + asynchronous getattr RPC replies. - There is no file size/block attributes pre-fetching and the traversing thread has to send synchronous glimpse size RPCs to OST(s). + There is no file size/block attributes pre-fetching and the traversing thread has to + send synchronous glimpse size RPCs to OST(s). - The first issue is resolved by using statahead local dcache, and the second one is resolved by using asynchronous glimpse lock (AGL) RPCs for pre-fetching file size/block attributes from OST(s). + The first issue is resolved by using statahead local dcache, and the second one is + resolved by using asynchronous glimpse lock (AGL) RPCs for pre-fetching file size/block + attributes from OST(s).
Tuning File Readahead - File readahead is triggered when two or more sequential reads by an application fail to be satisfied by the Linux buffer cache. The size of the initial readahead is 1 MB. Additional readaheads grow linearly, and increment until the readahead cache on the client is full at 40 MB. - llite.fsname-instance.max_read_ahead_mb - This tunable controls the maximum amount of data readahead on a file. Files are read ahead in RPC-sized chunks (1 MB or the size of read() call, if larger) after the second sequential read on a file descriptor. Random reads are done at the size of the read() call only (no readahead). Reads to non-contiguous regions of the file reset the readahead algorithm, and readahead is not triggered again until there are sequential reads again. To disable readahead, set this tunable to 0. The default value is 40 MB. - llite.fsname-instance.max_read_ahead_whole_mb - This tunable controls the maximum size of a file that is read in its entirety, regardless of the size of the read(). + File readahead is triggered when two or more sequential reads by an application fail + to be satisfied by the Linux buffer cache. The size of the initial readahead is 1 MB. + Additional readaheads grow linearly, and increment until the readahead cache on the client + is full at 40 MB. + llite.fsname-instance.max_read_ahead_mb + + This tunable controls the maximum amount of data readahead on a file. Files are read + ahead in RPC-sized chunks (1 MB or the size of read() call, if larger) after the second + sequential read on a file descriptor. Random reads are done at the size of the read() call + only (no readahead). Reads to non-contiguous regions of the file reset the readahead + algorithm, and readahead is not triggered again until there are sequential reads again. To + disable readahead, set this tunable to 0. The default value is 40 MB. + llite.fsname-instance.max_read_ahead_whole_mb + + This tunable controls the maximum size of a file that is read in its entirety, + regardless of the size of the read().
Tuning Directory Statahead and AGL - Many system commands, like ls –l, du, find, etc., will traverse directory sequentially. To make these commands run efficiently, the directory statahead and AGL (asynchronous glimpse lock) can be enabled to improve the performance of traversing. + Many system commands, like ls –l, du, + find, etc., will traverse directory sequentially. To make these + commands run efficiently, the directory statahead and AGL (asynchronous glimpse lock) can + be enabled to improve the performance of traversing. /proc/fs/lustre/llite/*/statahead_max - This proc interface controls whether directory statahead is enabled and the maximum statahead windows size (which means how many files can be pre-fetched by the statahead thread). By default, statahead is enabled and the value of statahead_max is 32. + This proc interface controls whether directory statahead is enabled and the maximum + statahead windows size (which means how many files can be pre-fetched by the statahead + thread). By default, statahead is enabled and the value of + statahead_max is 32. To disable statahead, run: lctl set_param llite.*.statahead_max=0 To set the maximum statahead windows size (n), run: @@ -1048,22 +1603,33 @@ disk io size rpcs % cum % | rpcs % cum % lctl set_param llite.*.statahead_agl=n If "n" is 0, then the AGL is disabled, else the AGL is enabled. /proc/fs/lustre/llite/*/statahead_stats - This is a read-only interface that indicates the current statahead and AGL status. + This is a read-only interface that indicates the current statahead and AGL + status. - The AGL is affected by statahead because the inodes processed by AGL are built by the statahead thread, which means the statahead thread is the input of AGL pipeline. So if statahead is disabled, then the AGL is disabled by force. + The AGL is affected by statahead because the inodes processed by AGL are built by + the statahead thread, which means the statahead thread is the input of AGL pipeline. So + if statahead is disabled, then the AGL is disabled by force.
- <indexterm><primary>proc</primary><secondary>read cache</secondary></indexterm>OSS Read Cache - The OSS read cache feature provides read-only caching of data on an OSS. This functionality uses the regular Linux page cache to store the data. Just like caching from a regular filesystem in Linux, OSS read cache uses as much physical memory as is allocated. + <indexterm> + <primary>proc</primary> + <secondary>read cache</secondary> + </indexterm>OSS Read Cache + The OSS read cache feature provides read-only caching of data on an OSS. This + functionality uses the regular Linux page cache to store the data. Just like caching from a + regular filesystem in Linux, OSS read cache uses as much physical memory as is + allocated. OSS read cache improves Lustre performance in these situations: - Many clients are accessing the same data set (as in HPC applications and when diskless clients boot from Lustre) + Many clients are accessing the same data set (as in HPC applications and when + diskless clients boot from Lustre) - One client is storing data while another client is reading it (essentially exchanging data via the OST) + One client is storing data while another client is reading it (essentially + exchanging data via the OST) A client has very limited caching of its own @@ -1083,15 +1649,29 @@ disk io size rpcs % cum % | rpcs % cum %
Using OSS Read Cache - OSS read cache is implemented on the OSS, and does not require any special support on the client side. Since OSS read cache uses the memory available in the Linux page cache, you should use I/O patterns to determine the appropriate amount of memory for the cache; if the data is mostly reads, then more cache is required than for writes. + OSS read cache is implemented on the OSS, and does not require any special support on + the client side. Since OSS read cache uses the memory available in the Linux page cache, + you should use I/O patterns to determine the appropriate amount of memory for the cache; + if the data is mostly reads, then more cache is required than for writes. OSS read cache is enabled, by default, and managed by the following tunables: - read_cache_enable controls whether data read from disk during a read request is kept in memory and available for later read requests for the same data, without having to re-read it from disk. By default, read cache is enabled (read_cache_enable = 1). + read_cache_enable controls whether data read from disk during a + read request is kept in memory and available for later read requests for the same + data, without having to re-read it from disk. By default, read cache is enabled + (read_cache_enable = 1). - When the OSS receives a read request from a client, it reads data from disk into its memory and sends the data as a reply to the requests. If read cache is enabled, this data stays in memory after the client's request is finished, and the OSS skips reading data from disk when subsequent read requests for the same are received. The read cache is managed by the Linux kernel globally across all OSTs on that OSS, and the least recently used cache pages will be dropped from memory when the amount of free memory is running low. - If read cache is disabled (read_cache_enable = 0), then the OSS will discard the data after the client's read requests are serviced and, for subsequent read requests, the OSS must read the data from disk. + When the OSS receives a read request from a client, it reads data from disk into its + memory and sends the data as a reply to the requests. If read cache is enabled, this data + stays in memory after the client's request is finished, and the OSS skips reading + data from disk when subsequent read requests for the same are received. The read cache is + managed by the Linux kernel globally across all OSTs on that OSS, and the least recently + used cache pages will be dropped from memory when the amount of free memory is running + low. + If read cache is disabled (read_cache_enable = 0), then the OSS + will discard the data after the client's read requests are serviced and, for + subsequent read requests, the OSS must read the data from disk. To disable read cache on all OSTs of an OSS, run: root@oss1# lctl set_param obdfilter.*.read_cache_enable=0 To re-enable read cache on one OST, run: @@ -1100,87 +1680,153 @@ disk io size rpcs % cum % | rpcs % cum % root@oss1# lctl get_param obdfilter.*.read_cache_enable - writethrough_cache_enable controls whether data sent to the OSS as a write request is kept in the read cache and available for later reads, or if it is discarded from cache when the write is completed. By default, writethrough cache is enabled (writethrough_cache_enable = 1). + writethrough_cache_enable controls whether data sent to the OSS + as a write request is kept in the read cache and available for later reads, or if it + is discarded from cache when the write is completed. By default, writethrough cache is + enabled (writethrough_cache_enable = 1). - When the OSS receives write requests from a client, it receives data from the client into its memory and writes the data to disk. If writethrough cache is enabled, this data stays in memory after the write request is completed, allowing the OSS to skip reading this data from disk if a later read request, or partial-page write request, for the same data is received. - If writethrough cache is disabled (writethrough_cache_enabled = 0), then the OSS discards the data after the client's write request is completed, and for subsequent read request, or partial-page write request, the OSS must re-read the data from disk. - Enabling writethrough cache is advisable if clients are doing small or unaligned writes that would cause partial-page updates, or if the files written by one node are immediately being accessed by other nodes. Some examples where this might be useful include producer-consumer I/O models or shared-file writes with a different node doing I/O not aligned on 4096-byte boundaries. Disabling writethrough cache is advisable in the case where files are mostly written to the file system but are not re-read within a short time period, or files are only written and re-read by the same node, regardless of whether the I/O is aligned or not. + When the OSS receives write requests from a client, it receives data from the client + into its memory and writes the data to disk. If writethrough cache is enabled, this data + stays in memory after the write request is completed, allowing the OSS to skip reading + this data from disk if a later read request, or partial-page write request, for the same + data is received. + If writethrough cache is disabled (writethrough_cache_enabled = 0), + then the OSS discards the data after the client's write request is completed, and for + subsequent read request, or partial-page write request, the OSS must re-read the data from + disk. + Enabling writethrough cache is advisable if clients are doing small or unaligned + writes that would cause partial-page updates, or if the files written by one node are + immediately being accessed by other nodes. Some examples where this might be useful + include producer-consumer I/O models or shared-file writes with a different node doing I/O + not aligned on 4096-byte boundaries. Disabling writethrough cache is advisable in the case + where files are mostly written to the file system but are not re-read within a short time + period, or files are only written and re-read by the same node, regardless of whether the + I/O is aligned or not. To disable writethrough cache on all OSTs of an OSS, run: root@oss1# lctl set_param obdfilter.*.writethrough_cache_enable=0 To re-enable writethrough cache on one OST, run: - root@oss1# lctl set_param \ -obdfilter.{OST_name}.writethrough_cache_enable=1 + root@oss1# lctl set_param obdfilter.{OST_name}.writethrough_cache_enable=1 To check if writethrough cache is root@oss1# lctl set_param obdfilter.*.writethrough_cache_enable=1 - readcache_max_filesize controls the maximum size of a file that both the read cache and writethrough cache will try to keep in memory. Files larger than readcache_max_filesize will not be kept in cache for either reads or writes. + readcache_max_filesize controls the maximum size of a file that + both the read cache and writethrough cache will try to keep in memory. Files larger + than readcache_max_filesize will not be kept in cache for either + reads or writes. - This can be very useful for workloads where relatively small files are repeatedly accessed by many clients, such as job startup files, executables, log files, etc., but large files are read or written only once. By not putting the larger files into the cache, it is much more likely that more of the smaller files will remain in cache for a longer time. - When setting readcache_max_filesize, the input value can be specified in bytes, or can have a suffix to indicate other binary units such as Kilobytes, Megabytes, Gigabytes, Terabytes, or Petabytes. + This can be very useful for workloads where relatively small files are repeatedly + accessed by many clients, such as job startup files, executables, log files, etc., but + large files are read or written only once. By not putting the larger files into the cache, + it is much more likely that more of the smaller files will remain in cache for a longer + time. + When setting readcache_max_filesize, the input value can be + specified in bytes, or can have a suffix to indicate other binary units such as Kilobytes, Megabytes, Gigabytes, Terabytes, or + Petabytes. To limit the maximum cached file size to 32MB on all OSTs of an OSS, run: root@oss1# lctl set_param obdfilter.*.readcache_max_filesize=32M To disable the maximum cached file size on an OST, run: - root@oss1# lctl set_param \ -obdfilter.{OST_name}.readcache_max_filesize=-1 + root@oss1# lctl set_param obdfilter.{OST_name}.readcache_max_filesize=-1 To check the current maximum cached file size on all OSTs of an OSS, run: root@oss1# lctl get_param obdfilter.*.readcache_max_filesize
- <indexterm><primary>proc</primary><secondary>OSS journal</secondary></indexterm>OSS Asynchronous Journal Commit - The OSS asynchronous journal commit feature synchronously writes data to disk without forcing a journal flush. This reduces the number of seeks and significantly improves performance on some hardware. + <indexterm> + <primary>proc</primary> + <secondary>OSS journal</secondary> + </indexterm>OSS Asynchronous Journal Commit + The OSS asynchronous journal commit feature synchronously writes data to disk without + forcing a journal flush. This reduces the number of seeks and significantly improves + performance on some hardware. - Asynchronous journal commit cannot work with O_DIRECT writes, a journal flush is still forced. + Asynchronous journal commit cannot work with O_DIRECT writes, a journal flush is still + forced. - When asynchronous journal commit is enabled, client nodes keep data in the page cache (a page reference). Lustre clients monitor the last committed transaction number (transno) in messages sent from the OSS to the clients. When a client sees that the last committed transno reported by the OSS is at least the bulk write transno, it releases the reference on the corresponding pages. To avoid page references being held for too long on clients after a bulk write, a 7 second ping request is scheduled (jbd commit time is 5 seconds) after the bulk write reply is received, so the OSS has an opportunity to report the last committed transno. - If the OSS crashes before the journal commit occurs, then the intermediate data is lost. However, new OSS recovery functionality (introduced in the asynchronous journal commit feature), causes clients to replay their write requests and compensate for the missing disk updates by restoring the state of the file system. - To enable asynchronous journal commit, set the sync_journal parameter to zero (sync_journal=0): + When asynchronous journal commit is enabled, client nodes keep data in the page cache (a + page reference). Lustre clients monitor the last committed transaction number (transno) in + messages sent from the OSS to the clients. When a client sees that the last committed + transno reported by the OSS is at least the bulk write transno, it releases the reference on + the corresponding pages. To avoid page references being held for too long on clients after a + bulk write, a 7 second ping request is scheduled (jbd commit time is 5 seconds) after the + bulk write reply is received, so the OSS has an opportunity to report the last committed + transno. + If the OSS crashes before the journal commit occurs, then the intermediate data is lost. + However, new OSS recovery functionality (introduced in the asynchronous journal commit + feature), causes clients to replay their write requests and compensate for the missing disk + updates by restoring the state of the file system. + To enable asynchronous journal commit, set the sync_journal parameter + to zero (sync_journal=0): $ lctl set_param obdfilter.*.sync_journal=0 obdfilter.lol-OST0001.sync_journal=0 - By default, sync_journal is disabled (sync_journal=1), which forces a journal flush after every bulk write. - When asynchronous journal commit is used, clients keep a page reference until the journal transaction commits. This can cause problems when a client receives a blocking callback, because pages need to be removed from the page cache, but they cannot be removed because of the extra page reference. - This problem is solved by forcing a journal flush on lock cancellation. When this happens, the client is granted the metadata blocks that have hit the disk, and it can safely release the page reference before processing the blocking callback. The parameter which controls this action is sync_on_lock_cancel, which can be set to the following values: + By default, sync_journal is disabled + (sync_journal=1), which forces a journal flush after every bulk + write. + When asynchronous journal commit is used, clients keep a page reference until the + journal transaction commits. This can cause problems when a client receives a blocking + callback, because pages need to be removed from the page cache, but they cannot be removed + because of the extra page reference. + This problem is solved by forcing a journal flush on lock cancellation. When this + happens, the client is granted the metadata blocks that have hit the disk, and it can safely + release the page reference before processing the blocking callback. The parameter which + controls this action is sync_on_lock_cancel, which can be set to the + following values: always: Always force a journal flush on lock cancellation - blocking: Force a journal flush only when the local cancellation is due to a blocking callback + blocking: Force a journal flush only when the local cancellation + is due to a blocking callback never: Do not force any journal flush - Here is an example of sync_on_lock_cancel being set not to force a journal flush: + Here is an example of sync_on_lock_cancel being set not to force a + journal flush: $ lctl get_param obdfilter.*.sync_on_lock_cancel obdfilter.lol-OST0001.sync_on_lock_cancel=never - By default, sync_on_lock_cancel is set to never, because asynchronous journal commit is disabled by default. - When asynchronous journal commit is enabled (sync_journal=0), sync_on_lock_cancel is automatically set to always, if it was previously set to never. - Similarly, when asynchronous journal commit is disabled, (sync_journal=1), sync_on_lock_cancel is enforced to never. + By default, sync_on_lock_cancel is set to never, because asynchronous + journal commit is disabled by default. + When asynchronous journal commit is enabled (sync_journal=0), + sync_on_lock_cancel is automatically set to always, if it was + previously set to never. + Similarly, when asynchronous journal commit is disabled, + (sync_journal=1), sync_on_lock_cancel is enforced to + never.
- <indexterm><primary>proc</primary><secondary>mballoc history</secondary></indexterm><literal>mballoc</literal> History + <indexterm> + <primary>proc</primary> + <secondary>mballoc history</secondary> + </indexterm><literal>mballoc</literal> History /proc/fs/ldiskfs/sda/mb_history - Multi-Block-Allocate (mballoc), enables Lustre to ask ldiskfs to allocate multiple blocks with a single request to the block allocator. Typically, an ldiskfs file system allocates only one block per time. Each mballoc-enabled partition has this file. This is sample output: - pid inode goal result found grps cr \ merge tail broken -2838 139267 17/12288/1 17/12288/1 1 0 0 \ M 1 8192 -2838 139267 17/12289/1 17/12289/1 1 0 0 \ M 0 0 -2838 139267 17/12290/1 17/12290/1 1 0 0 \ M 1 2 -2838 24577 3/12288/1 3/12288/1 1 0 0 \ M 1 8192 -2838 24578 3/12288/1 3/771/1 1 1 1 \ 0 0 -2838 32769 4/12288/1 4/12288/1 1 0 0 \ M 1 8192 -2838 32770 4/12288/1 4/12289/1 13 1 1 \ 0 0 -2838 32771 4/12288/1 5/771/1 26 2 1 \ 0 0 -2838 32772 4/12288/1 5/896/1 31 2 1 \ 1 128 -2838 32773 4/12288/1 5/897/1 31 2 1 \ 0 0 -2828 32774 4/12288/1 5/898/1 31 2 1 \ 1 2 -2838 32775 4/12288/1 5/899/1 31 2 1 \ 0 0 -2838 32776 4/12288/1 5/900/1 31 2 1 \ 1 4 -2838 32777 4/12288/1 5/901/1 31 2 1 \ 0 0 -2838 32778 4/12288/1 5/902/1 31 2 1 \ 1 2 + Multi-Block-Allocate (mballoc), enables Lustre to ask + ldiskfs to allocate multiple blocks with a single request to the block + allocator. Typically, an ldiskfs file system allocates only one block per + time. Each mballoc-enabled partition has this file. This is sample + output: + pid inode goal result found grps cr merge tail broken +2838 139267 17/12288/1 17/12288/1 1 0 0 M 1 8192 +2838 139267 17/12289/1 17/12289/1 1 0 0 M 0 0 +2838 139267 17/12290/1 17/12290/1 1 0 0 M 1 2 +2838 24577 3/12288/1 3/12288/1 1 0 0 M 1 8192 +2838 24578 3/12288/1 3/771/1 1 1 1 0 0 +2838 32769 4/12288/1 4/12288/1 1 0 0 M 1 8192 +2838 32770 4/12288/1 4/12289/1 13 1 1 0 0 +2838 32771 4/12288/1 5/771/1 26 2 1 0 0 +2838 32772 4/12288/1 5/896/1 31 2 1 1 128 +2838 32773 4/12288/1 5/897/1 31 2 1 0 0 +2828 32774 4/12288/1 5/898/1 31 2 1 1 2 +2838 32775 4/12288/1 5/899/1 31 2 1 0 0 +2838 32776 4/12288/1 5/900/1 31 2 1 1 4 +2838 32777 4/12288/1 5/901/1 31 2 1 0 0 +2838 32778 4/12288/1 5/902/1 31 2 1 1 2 The parameters are described below: @@ -1199,7 +1845,8 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - + + pid @@ -1209,7 +1856,8 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - + + inode @@ -1219,17 +1867,20 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - + + goal - Initial request that came to mballoc (group/block-in-group/number-of-blocks) + Initial request that came to mballoc + (group/block-in-group/number-of-blocks) - + + result @@ -1239,41 +1890,52 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - + + found - Number of free chunks mballoc found and measured before the final decision. + Number of free chunks mballoc found and measured before the + final decision. - + + grps - Number of groups mballoc scanned to satisfy the request. + Number of groups mballoc scanned to satisfy the + request. - + + cr Stage at which mballoc found the result: - 0 - best in terms of resource allocation. The request was 1MB or larger and was satisfied directly via the kernel buddy allocator. - 1 - regular stage (good at resource consumption) - 2 - fs is quite fragmented (not that bad at resource consumption) - 3 - fs is very fragmented (worst at resource consumption) + 0 - best in terms of resource allocation. The + request was 1MB or larger and was satisfied directly via the kernel buddy + allocator. + 1 - regular stage (good at resource + consumption) + 2 - fs is quite fragmented (not that bad at + resource consumption) + 3 - fs is very fragmented (worst at resource + consumption) - + + queue @@ -1283,27 +1945,33 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - + + merge - Whether the request hit the goal. This is good as extents code can now merge new blocks to existing extent, eliminating the need for extents tree growth. + Whether the request hit the goal. This is good as extents code can now merge + new blocks to existing extent, eliminating the need for extents tree + growth. - + + tail - Number of blocks left free after the allocation breaks large free chunks. + Number of blocks left free after the allocation breaks large free + chunks. - + + broken @@ -1314,19 +1982,33 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - Most users are probably interested in found/cr. If cr is 0 1 and found is less than 100, then mballoc is doing quite well. - Also, number-of-blocks-in-request (third number in the goal triple) can tell the number of blocks requested by the obdfilter. If the obdfilter is doing a lot of small requests (just few blocks), then either the client is processing input/output to a lot of small files, or something may be wrong with the client (because it is better if client sends large input/output requests). This can be investigated with the OSC rpc_stats or OST brw_stats mentioned above. - Number of groups scanned (grps column) should be small. If it reaches a few dozen often, then either your disk file system is pretty fragmented or mballoc is doing something wrong in the group selection part. + Most users are probably interested in found/cr. If cr is 0 1 and found is less than 100, + then mballoc is doing quite well. + Also, number-of-blocks-in-request (third number in the goal triple) can tell the number + of blocks requested by the obdfilter. If the obdfilter + is doing a lot of small requests (just few blocks), then either the client is processing + input/output to a lot of small files, or something may be wrong with the client (because it + is better if client sends large input/output requests). This can be investigated with the + OSC rpc_stats or OST brw_stats mentioned above. + Number of groups scanned (grps column) should be small. If it reaches + a few dozen often, then either your disk file system is pretty fragmented or + mballoc is doing something wrong in the group selection part.
- <indexterm><primary>proc</primary><secondary>mballoc tunables</secondary></indexterm><literal>mballoc</literal> Tunables - Lustre ldiskfs includes a multi-block allocation for ldiskfs to improve the efficiency of space allocation in the OST storage. Multi-block allocation adds the following features: + <indexterm> + <primary>proc</primary> + <secondary>mballoc tunables</secondary> + </indexterm><literal>mballoc</literal> Tunables + Lustre ldiskfs includes a multi-block allocation for ldiskfs to improve the efficiency + of space allocation in the OST storage. Multi-block allocation adds the following + features: Pre-allocation for single files (helps to resist fragmentation) - Pre-allocation for a group of files (helps to pack small files into large, contiguous chunks) + Pre-allocation for a group of files (helps to pack small files into large, + contiguous chunks) Stream allocation (helps to decrease the seek rate) @@ -1350,59 +2032,75 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - mb_max_to_scan + + mb_max_to_scan - Maximum number of free chunks that mballoc finds before a final decision to avoid livelock. + Maximum number of free chunks that mballoc finds before a + final decision to avoid livelock. - mb_min_to_scan + + mb_min_to_scan - Minimum number of free chunks that mballoc searches before picking the best chunk for allocation. This is useful for a very small request, to resist fragmentation of big free chunks. + Minimum number of free chunks that mballoc searches before + picking the best chunk for allocation. This is useful for a very small request, to + resist fragmentation of big free chunks. - mb_order2_req + + mb_order2_req - For requests equal to 2^N (where N >= order2_req), a very fast search via buddy structures is used. + For requests equal to 2^N (where N >= order2_req), a + very fast search via buddy structures is used. - mb_small_req + + mb_small_req All requests are divided into 3 categories: < small_req (packed together to form large, aggregated requests) < large_req (allocated mostly in linearly) > large_req (very large requests so the arm seek does not matter) - The idea is that we try to pack small requests to form large requests, and then place all large requests (including compound from the small ones) close to one another, causing as few arm seeks as possible. + The idea is that we try to pack small requests to form large requests, and + then place all large requests (including compound from the small ones) close to + one another, causing as few arm seeks as possible. - mb_large_req + + mb_large_req - mb_prealloc_table + + mb_prealloc_table - The amount of space to preallocate depends on the current file size. The idea is that for small files we do not need 1 MB preallocations and for large files, 1 MB preallocations are not large enough; it is better to preallocate 4 MB. + The amount of space to preallocate depends on the current file size. The idea + is that for small files we do not need 1 MB preallocations and for large files, 1 + MB preallocations are not large enough; it is better to preallocate 4 MB. - mb_group_prealloc + + mb_group_prealloc - The amount of space (in kilobytes) preallocated for groups of small requests. + The amount of space (in kilobytes) preallocated for groups of small + requests. @@ -1410,23 +2108,44 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never
- <indexterm><primary>proc</primary><secondary>locking</secondary></indexterm>Locking - ldlm.namespaces.osc_name|mdc_name.lru_size - The lru_size parameter is used to control the number of client-side locks in an LRU queue. LRU size is dynamic, based on load. This optimizes the number of locks available to nodes that have different workloads (e.g., login/build nodes vs. compute nodes vs. backup nodes). - The total number of locks available is a function of the server's RAM. The default limit is 50 locks/1 MB of RAM. If there is too much memory pressure, then the LRU size is shrunk. The number of locks on the server is limited to targets_on_server * client_count * client_lru_size. + <indexterm> + <primary>proc</primary> + <secondary>locking</secondary> + </indexterm>Locking + ldlm.namespaces.osc_name|mdc_name.lru_size + + The lru_size parameter is used to control the number of client-side + locks in an LRU queue. LRU size is dynamic, based on load. This optimizes the number of + locks available to nodes that have different workloads (e.g., login/build nodes vs. compute + nodes vs. backup nodes). + The total number of locks available is a function of the server's RAM. The default + limit is 50 locks/1 MB of RAM. If there is too much memory pressure, then the LRU size is + shrunk. The number of locks on the server is limited to + targets_on_server * client_count * + client_lru_size. - To enable automatic LRU sizing, set the lru_size parameter to 0. In this case, the lru_size parameter shows the current number of locks being used on the export. LRU sizing is enabled by default starting with Lustre 1.6.5.1. + To enable automatic LRU sizing, set the lru_size parameter to 0. + In this case, the lru_size parameter shows the current number of + locks being used on the export. LRU sizing is enabled by default starting with Lustre + 1.6.5.1. - To specify a maximum number of locks, set the lru_size parameter to a value other than 0 (former numbers are okay, 100 * core_count). We recommend that you only increase the LRU size on a few login nodes where users access the file system interactively. + To specify a maximum number of locks, set the lru_size parameter to a value other + than 0 (former numbers are okay, 100 * core_count). We + recommend that you only increase the LRU size on a few login nodes where users access + the file system interactively. - To clear the LRU on a single client, and as a result flush client cache, without changing the lru_size value: + To clear the LRU on a single client, and as a result flush client cache, without + changing the lru_size value: $ lctl set_param ldlm.namespaces.osc_name|mdc_name.lru_size=clear - If you shrink the LRU size below the number of existing unused locks, then the unused locks are canceled immediately. Use echo clear to cancel all locks without changing the value. + If you shrink the LRU size below the number of existing unused locks, then the unused + locks are canceled immediately. Use echo clear to cancel all locks without changing the + value. - Currently, the lru_size parameter can only be set temporarily with lctl set_param; it cannot be set permanently. + Currently, the lru_size parameter can only be set temporarily with lctl + set_param; it cannot be set permanently. To disable LRU sizing, run this command on the Lustre clients: $ lctl set_param ldlm.namespaces.*osc*.lru_size=$((NR_CPU*100)) @@ -1435,8 +2154,16 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never $ lctl get_param ldlm.namespaces.*.pool.limit
- <indexterm><primary>proc</primary><secondary>thread counts</secondary></indexterm>Setting MDS and OSS Thread Counts - MDS and OSS thread counts (minimum and maximum) can be set via the {min,max}_thread_count tunable. For each service, a new /proc/fs/lustre/{service}/*/thread_{min,max,started} entry is created. The tunable, {service}.thread_{min,max,started}, can be used to set the minimum and maximum thread counts or get the current number of running threads for the following services. + <indexterm> + <primary>proc</primary> + <secondary>thread counts</secondary> + </indexterm>Setting MDS and OSS Thread Counts + MDS and OSS thread counts (minimum and maximum) can be set via the + {min,max}_thread_count tunable. For each service, a new + /proc/fs/lustre/{service}/*/thread_{min,max,started} entry is created. + The tunable, {service}.thread_{min,max,started}, can be used to set the + minimum and maximum thread counts or get the current number of running threads for the + following services. @@ -1444,10 +2171,12 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - Service + + Service - Description + + Description @@ -1527,7 +2256,8 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never To permanently set this tunable, run: # lctl conf_param {service}.thread_{min,max,started} - The following examples show how to set thread counts and get the number of running threads for the ost_io service. + The following examples show how to set thread counts and get the number of running + threads for the ost_io service. @@ -1548,7 +2278,8 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - To set the maximum thread count to 256 instead of 512 (to avoid overloading the storage or for an array with requests), run: + To set the maximum thread count to 256 instead of 512 (to avoid overloading the + storage or for an array with requests), run: # lctl set_param ost.OSS.ost_io.threads_max=256 The command output will be: ost.OSS.ost_io.threads_max=256 @@ -1563,23 +2294,38 @@ obdfilter.lol-OST0001.sync_on_lock_cancel=never - Currently, the maximum thread count setting is advisory because Lustre does not reduce the number of service threads in use, even if that number exceeds the threads_max value. Lustre does not stop service threads once they are started. + Currently, the maximum thread count setting is advisory because Lustre does not reduce + the number of service threads in use, even if that number exceeds the + threads_max value. Lustre does not stop service threads once they are + started.
- <indexterm><primary>proc</primary><secondary>debug</secondary></indexterm>Debug + <indexterm> + <primary>proc</primary> + <secondary>debug</secondary> + </indexterm>Debug /proc/sys/lnet/debug - By default, Lustre generates a detailed log of all operations to aid in debugging. The level of debugging can affect the performance or speed you achieve with Lustre. Therefore, it is useful to reduce this overhead by turning down the debug level - This controls the level of Lustre debugging kept in the internal log buffer. It does not alter the level of debugging that goes to syslog. - to improve performance. Raise the debug level when you need to collect the logs for debugging problems. The debugging mask can be set with "symbolic names" instead of the numerical values that were used in prior releases. The new symbolic format is shown in the examples below. + By default, Lustre generates a detailed log of all operations to aid in debugging. The + level of debugging can affect the performance or speed you achieve with Lustre. Therefore, it + is useful to reduce this overhead by turning down the debug level + This controls the level of Lustre debugging kept in the internal log buffer. It does + not alter the level of debugging that goes to syslog. + to improve performance. Raise the debug level when you need to collect the logs + for debugging problems. The debugging mask can be set with "symbolic names" instead + of the numerical values that were used in prior releases. The new symbolic format is shown in + the examples below. - All of the commands below must be run as root; note the # nomenclature. + All of the commands below must be run as root; note the # + nomenclature. - To verify the debug level used by examining the sysctl that controls debugging, run: + To verify the debug level used by examining the sysctl that controls + debugging, run: # sysctl lnet.debug lnet.debug = ioctl neterror warning error emerg ha config console - To turn off debugging (except for network error debugging), run this command on all concerned nodes: + To turn off debugging (except for network error debugging), run this command on all + concerned nodes: # sysctl -w lnet.debug="neterror" lnet.debug = neterror To turn off debugging completely, run this command on all concerned nodes: @@ -1588,11 +2334,13 @@ lnet.debug = 0 To set an appropriate debug level for a production environment, run: # sysctl -w lnet.debug="warning dlmtrace error emerg ha rpctrace vfstrace" lnet.debug = warning dlmtrace error emerg ha rpctrace vfstrace - The flags above collect enough high-level information to aid debugging, but they do not cause any serious performance impact. + The flags above collect enough high-level information to aid debugging, but they do not + cause any serious performance impact. To clear all flags and set new ones, run: # sysctl -w lnet.debug="warning" lnet.debug = warning - To add new flags to existing ones, prefix them with a "+": + To add new flags to existing ones, prefix them with a + "+": # sysctl -w lnet.debug="+neterror +ha" lnet.debug = +neterror +ha # sysctl lnet.debug @@ -1602,7 +2350,8 @@ lnet.debug = neterror warning ha lnet.debug = -ha # sysctl lnet.debug lnet.debug = neterror warning - You can verify and change the debug level using the /proc interface in Lustre. To use the flags with /proc, run: + You can verify and change the debug level using the /proc interface in + Lustre. To use the flags with /proc, run: # lctl get_param debug debug= neterror warning @@ -1615,20 +2364,32 @@ neterror warning ha debug= neterror ha /proc/sys/lnet/subsystem_debug - This controls the debug logs for subsystems (see S_* definitions). + This controls the debug logs for subsystems (see S_* + definitions). /proc/sys/lnet/debug_path - This indicates the location where debugging symbols should be stored for gdb. The default is set to /r/tmp/lustre-log-localhost.localdomain. + This indicates the location where debugging symbols should be stored for + gdb. The default is set to + /r/tmp/lustre-log-localhost.localdomain. These values can also be set via sysctl -w lnet.debug={value} The above entries only exist when Lustre has already been loaded. /proc/sys/lnet/panic_on_lbug - This causes Lustre to call ''panic'' when it detects an internal problem (an LBUG); panic crashes the node. This is particularly useful when a kernel crash dump utility is configured. The crash dump is triggered when the internal inconsistency is detected by Lustre. + This causes Lustre to call ''panic'' when it detects an internal + problem (an LBUG); panic crashes the node. This is particularly useful when + a kernel crash dump utility is configured. The crash dump is triggered when the internal + inconsistency is detected by Lustre. /proc/sys/lnet/upcall - This allows you to specify the path to the binary which will be invoked when an LBUG is encountered. This binary is called with four parameters. The first one is the string ''LBUG''. The second one is the file where the LBUG occurred. The third one is the function name. The fourth one is the line number in the file. + This allows you to specify the path to the binary which will be invoked when an + LBUG is encountered. This binary is called with four parameters. The + first one is the string ''LBUG''. The second one is the + file where the LBUG occurred. The third one is the function name. The + fourth one is the line number in the file.
RPC Information for Other OBD Devices - Some OBD devices maintain a count of the number of RPC events that they process. Sometimes these events are more specific to operations of the device, like llite, than actual raw RPC counts. + Some OBD devices maintain a count of the number of RPC events that they process. + Sometimes these events are more specific to operations of the device, like llite, than + actual raw RPC counts. $ find /proc/fs/lustre/ -name stats /proc/fs/lustre/osc/lustre-OST0001-osc-ce63ca00/stats /proc/fs/lustre/osc/lustre-OST0000-osc-ce63ca00/stats @@ -1637,56 +2398,74 @@ neterror ha /proc/fs/lustre/mdt/MDS/mds_readpage/stats /proc/fs/lustre/mdt/MDS/mds_setattr/stats /proc/fs/lustre/mdt/MDS/mds/stats -/proc/fs/lustre/mds/lustre-MDT0000/exports/ab206805-0630-6647-8543-d24265c91a3d/stats -/proc/fs/lustre/mds/lustre-MDT0000/exports/08ac6584-6c4a-3536-2c6d-b36cf9cbdaa0/stats +/proc/fs/lustre/mds/lustre-MDT0000/exports/ + ab206805-0630-6647-8543-d24265c91a3d/stats +/proc/fs/lustre/mds/lustre-MDT0000/exports/ + 08ac6584-6c4a-3536-2c6d-b36cf9cbdaa0/stats /proc/fs/lustre/mds/lustre-MDT0000/stats /proc/fs/lustre/ldlm/services/ldlm_canceld/stats /proc/fs/lustre/ldlm/services/ldlm_cbd/stats /proc/fs/lustre/llite/lustre-ce63ca00/stats
- <indexterm><primary>proc</primary><secondary>statistics</secondary></indexterm>Interpreting OST Statistics + <indexterm> + <primary>proc</primary> + <secondary>statistics</secondary> + </indexterm>Interpreting OST Statistics - See also (llobdstat) and (CollectL). + See also (llobdstat) + and (collectl). - The OST .../stats files can be used to track client statistics (client activity) for each OST. It is possible to get a periodic dump of values from these file (for example, every 10 seconds), that show the RPC rates (similar to iostat) by using the llstat.pl tool: + The OST .../stats files can be used to track client statistics + (client activity) for each OST. It is possible to get a periodic dump of values from these + file (for example, every 10 seconds), that show the RPC rates (similar to + iostat) by using the llstat tool: # llstat /proc/fs/lustre/osc/lustre-OST0000-osc/stats -/usr/bin/llstat: STATS on 09/14/07 /proc/fs/lustre/osc/lustre-OST0000-osc/stats on 192.168.10.34@tcp +/usr/bin/llstat: STATS on 09/14/07 + /proc/fs/lustre/osc/lustre-OST0000-osc/ stats on 192.168.10.34@tcp snapshot_time 1189732762.835363 ost_create 1 -ost_get_info 1 -ost_connect 1 -ost_set_info 1 +ost_get_info 1 +ost_connect 1 +ost_set_info 1 obd_ping 212 - To clear the statistics, give the -c option to llstat.pl. To specify how frequently the statistics should be cleared (in seconds), use an integer for the -i option. This is sample output with -c and -i10 options used, providing statistics every 10s): - $ llstat -c -i10 /proc/fs/lustre/ost/OSS/ost_io/stats + To clear the statistics, give the -c option to + llstat. To specify how frequently the statistics should be cleared + (in seconds), use an integer for the -i option. This is sample output + with -c and -i10 options used, providing statistics + every 10s): + $ llstat -c -i10 /proc/fs/lustre/ost/OSS/ost_io/stats -/usr/bin/llstat: STATS on 06/06/07 /proc/fs/lustre/ost/OSS/ost_io/ stats on 192.168.16.35@tcp +/usr/bin/llstat: STATS on 06/06/07 + /proc/fs/lustre/ost/OSS/ost_io/ stats on 192.168.16.35@tcp snapshot_time 1181074093.276072 /proc/fs/lustre/ost/OSS/ost_io/stats @ 1181074103.284895 -Name Cur.Count Cur.Rate #Events Unit \last min avg max stddev -req_waittime 8 0 8 [usec] 2078\ 34 259.75 868 317.49 -req_qdepth 8 0 8 [reqs] 1\ 0 0.12 1 0.35 -req_active 8 0 8 [reqs] 11\ 1 1.38 2 0.52 -reqbuf_avail 8 0 8 [bufs] 511\ 63 63.88 64 0.35 -ost_write 8 0 8 [bytes] 1697677\ 72914 212209.62 387579 91874.29 +Name Cur. Cur. # + Count Rate Events Unit last min avg max stddev +req_waittime 8 0 8 [usec] 2078 34 259.75 868 317.49 +req_qdepth 8 0 8 [reqs] 1 0 0.12 1 0.35 +req_active 8 0 8 [reqs] 11 1 1.38 2 0.52 +reqbuf_avail 8 0 8 [bufs] 511 63 63.88 64 0.35 +ost_write 8 0 8 [bytes] 169767 72914 212209.62 387579 91874.29 /proc/fs/lustre/ost/OSS/ost_io/stats @ 1181074113.290180 -Name Cur.Count Cur.Rate #Events Unit \last min avg max stddev -req_waittime 31 3 39 [usec] 30011\ 34 822.79 12245 2047.71 -req_qdepth 31 3 39 [reqs] 0\ 0 0.03 1 0.16 -req_active 31 3 39 [reqs] 58\ 1 1.77 3 0.74 -reqbuf_avail 31 3 39 [bufs] 1977\ 63 63.79 64 0.41 -ost_write 30 3 38 [bytes] 10284679\ 15019 315325.16 910694 197776.51 +Name Cur. Cur. # + Count Rate Events Unit last min avg max stddev +req_waittime 31 3 39 [usec] 30011 34 822.79 12245 2047.71 +req_qdepth 31 3 39 [reqs] 0 0 0.03 1 0.16 +req_active 31 3 39 [reqs] 58 1 1.77 3 0.74 +reqbuf_avail 31 3 39 [bufs] 1977 63 63.79 64 0.41 +ost_write 30 3 38 [bytes] 1028467 15019 315325.16 910694 197776.51 /proc/fs/lustre/ost/OSS/ost_io/stats @ 1181074123.325560 -Name Cur.Count Cur.Rate #Events Unit \last min avg max stddev -req_waittime 21 2 60 [usec] 14970\ 34 784.32 12245 1878.66 -req_qdepth 21 2 60 [reqs] 0\ 0 0.02 1 0.13 -req_active 21 2 60 [reqs] 33\ 1 1.70 3 0.70 -reqbuf_avail 21 2 60 [bufs] 1341\ 63 63.82 64 0.39 -ost_write 21 2 59 [bytes] 7648424\ 15019 332725.08 910694 180397.87 +Name Cur. Cur. # + Count Rate Events Unit last min avg max stddev +req_waittime 21 2 60 [usec] 14970 34 784.32 12245 1878.66 +req_qdepth 21 2 60 [reqs] 0 0 0.02 1 0.13 +req_active 21 2 60 [reqs] 33 1 1.70 3 0.70 +reqbuf_avail 21 2 60 [bufs] 1341 63 63.82 64 0.39 +ost_write 21 2 59 [bytes] 7648424 15019 332725.08 910694 180397.87 Where: @@ -1706,15 +2485,18 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - Cur. Count + + Cur. Count - Number of events of each type sent in the last interval (in this example, 10s) + Number of events of each type sent in the last interval (in this example, + 10s) - Cur. Rate + + Cur. Rate Number of events per second in the last interval @@ -1722,7 +2504,8 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - #Events + + #Events Total number of such events since the system started @@ -1730,23 +2513,30 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - Unit + + Unit - Unit of measurement for that statistic (microseconds, requests, buffers) + Unit of measurement for that statistic (microseconds, requests, + buffers) - last + + last - Average rate of these events (in units/event) for the last interval during which they arrived. For instance, in the above mentioned case of ost_destroy it took an average of 736 microseconds per destroy for the 400 object destroys in the previous 10 seconds. + Average rate of these events (in units/event) for the last interval during + which they arrived. For instance, in the above mentioned case of + ost_destroy it took an average of 736 microseconds per + destroy for the 400 object destroys in the previous 10 seconds. - min + + min Minimum rate (in units/events) since the service started @@ -1754,7 +2544,8 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - avg + + avg Average rate @@ -1762,7 +2553,8 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - max + + max Maximum rate @@ -1770,7 +2562,8 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - stddev + + stddev Standard deviation (not measured in all cases) @@ -1797,23 +2590,28 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - req_waittime + + req_waittime - Amount of time a request waited in the queue before being handled by an available server thread. + Amount of time a request waited in the queue before being handled by an + available server thread. - req_qdepth + + req_qdepth - Number of requests waiting to be handled in the queue for this service. + Number of requests waiting to be handled in the queue for this + service. - req_active + + req_active Number of requests currently being handled. @@ -1821,7 +2619,8 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - reqbuf_avail + + reqbuf_avail Number of unsolicited lnet request buffers for this service. @@ -1848,7 +2647,8 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - ldlm_enqueue + + ldlm_enqueue Time it takes to enqueue a lock (this includes file open on the MDS) @@ -1856,10 +2656,13 @@ ost_write 21 2 59 [bytes] 7648424\ 1 - mds_reint + + mds_reint - Time it takes to process an MDS modification record (includes create, mkdir, unlink, rename and setattr) + Time it takes to process an MDS modification record (includes create, + mkdir, unlink, rename + and setattr) @@ -1867,24 +2670,29 @@ ost_write 21 2 59 [bytes] 7648424\ 1
- <indexterm><primary>proc</primary><secondary>statistics</secondary></indexterm>Interpreting MDT Statistics + <indexterm> + <primary>proc</primary> + <secondary>statistics</secondary> + </indexterm>Interpreting MDT Statistics - See also (llobdstat) and (CollectL). + See also (llobdstat) and (CollectL). - The MDT .../stats files can be used to track MDT statistics for the MDS. Here is sample output for an MDT stats file: + The MDT .../stats files can be used to track MDT statistics for the MDS. Here is + sample output for an MDT stats file: # cat /proc/fs/lustre/mds/*-MDT0000/stats -snapshot_time 1244832003.676892 secs.usecs -open 2 samples [reqs] -close 1 samples [reqs] -getxattr 3 samples [reqs] -process_config 1 samples [reqs] -connect 2 samples [reqs] -disconnect 2 samples [reqs] -statfs 3 samples [reqs] -setattr 1 samples [reqs] -getattr 3 samples [reqs] -llog_init 6 samples [reqs] -notify 16 samples [reqs] +snapshot_time 1244832003.676892 secs.usecs +open 2 samples [reqs] +close 1 samples [reqs] +getxattr 3 samples [reqs] +process_config 1 samples [reqs] +connect 2 samples [reqs] +disconnect 2 samples [reqs] +statfs 3 samples [reqs] +setattr 1 samples [reqs] +getattr 3 samples [reqs] +llog_init 6 samples [reqs] +notify 16 samples [reqs]
-- 1.8.3.1