If set to
The value of this tunable can only be changed by using the |
|
The number of kernel threads that are available for servicing path error handling, path restoration and other DMP administrative tasks. |
|
How long DMP should wait before retrying I/O after an array fails over to a standby path. Some disk arrays are not be capable of accepting I/O requests immediately after failover. |
|
Set to 1 to enable the DMP path restoration thread; set to 0 to disable. The value of this tunable can also be changed by using the See "Configuring DMP path restoration policies" on page 155. |
|
The time limit that DMP waits for a failed I/O request to return before the device is marked as INSANE, I/O is avoided on the path, andany remaining failed I/O requests are returned to the application layer without performing any error analysis. The default value is 57600 seconds (16 hours).
The value of this tunable may be changed by using the |
|
Whether DMP should attempt to obtain SCSI error information directly from the HBA interface.
Setting the value to |
|
DMP detects intermittently failing paths, and prevents I/O requests from being sent on them. The value of The default value is 60 seconds.
A value of 0 prevents DMP from detecting intermittently failing paths. The value of this tunable may be changed by using the |
|
The level of detail that is displayed for DMP console messages. The following level values are defined: 1 — Display all DMP log messages that existed in releases before 5.0. 2 — Display level 1 messages plus messages that relate to I/O throttling, suspected paths, repeated path failures and DMP node migration. 3 — Display level 1 and 2 messages plus messages that relate to I/O errors, I/O error analysis and path media errors. 4 — Display level 1, 2 and 3 messages plus messages that relate to setting or changing attributes on a path. |
|
The time for which an intermittently failing path needs to be monitored as healthy before DMP once again attempts to schedule I/O requests on it. The default value is 300 seconds.
A value of 0 prevents DMP from detecting intermittently failing paths. The value of this tunable may be changed by using the |
|
The default number of contiguous I/O blocks (expressed as the integer exponent of a power of 2; for example 10 represents 1024 blocks) that are sent along a DMP path to an Active/Active array before switching to the next available path. The default value is set to 10 so that 1024 blocks (1MB) of contiguous I/O are sent over a DMP path before switching. For intelligent disk arrays with internal data caches, better throughput may be obtained by increasing the value of this tunable. For example, for the HDS 9960 A/A array, the optimal value is between 14 and 16 for an I/O activity pattern that consists mostly of sequential reads or writes.
This parameter only affects the behavior of the See "Specifying the I/O policy" on page 144.
The value of this tunable may be changed by using the |
|
If DMP statistics gathering is enabled, set to 1 to have the DMP path restoration thread probe idle LUNs, or to 0 to turn off this feature. (Idle LUNs are VM disks on which no I/O requests are scheduled.) The value of this tunable is only interpreted when DMP statistics gathering is enabled. Turning off statistics gathering also disables idle LUN probing.
The value of this tunable may be changed by using the |
|
The maximum number of queued I/O requests on a path during I/O throttling. The default value is 20. The value of this tunable may be changed by using the |
|
If the DMP restore policy is CHECK_PERIODIC, the number of cycles after which the CHECK_ALL policy is called. The value of this tunable can also be changed by using the See "Configuring DMP path restoration policies" on page 155. |
|
The time in seconds between two invocations of the DMP path restoration thread. The value of this tunable can also be changed by using the See "Configuring DMP path restoration policies" on page 155. |
|
The DMP restore policy, which can be set to 0 (CHECK_ALL), 1 (CHECK_DISABLED), 2 (CHECK_PERIODIC), or 3 (CHECK_ALTERNATE). The value of this tunable can also be changed by using the See "Configuring DMP path restoration policies" on page 155. |
|
If an inquiry succeeds on a path, but there is an I/O error, the number of retries to attempt on the path.
The value of this tunable may be changed by using the |
|
The maximum time period for which DMP retries the SCSI-3 Persistent Reserve operation with A/P arrays. The default value is 120 seconds. This parameter has no direct effect on I/O processing by DMP. Disabling a switch port can trigger a fabric reconfiguration, which can take time to stabilize. During this period, attempting to register PGR keys through the secondary path to an array may fail with an error condition, such as unit attention or device reset, or the return of vendor-specific sense data. The retry period allows a fabric reconfiguration (usually a transient condition) to not be seen as an error by DMP. Do not set the value of the retry period too high. This can delay the failover process, and result in I/O sluggishness or suppression of I/O activity during the retry period.
The value of this tunable may be changed by using the |
|
Determines the timeout value to be set for any SCSI command that is sent via DMP. If the HBA does not receive a response for a SCSI command that it has sent to the device within the timeout period, the SCSI command is returned with a failure error code. The default value is 30 seconds.
The value of this tunable may be changed by using the |
|
The interval at which utilities performing recoveries or resynchronization operations load the current offset into the kernel as a checkpoint. A system failure during such operations does not require a full recovery, but can continue from the last reached checkpoint. The default value is 10240 sectors (10MB). Increasing this size reduces the overhead of checkpointing on recovery operations at the expense of additional recovery following a system failure during a recovery. |
|
The count in clock ticks for which utilities pause if they have been directed to reduce the frequency of issuing I/O requests, but have not been given a specific delay time. This tunable is used by utilities performing operations such as resynchronizing mirrors or rebuilding RAID-5 columns. The default value is 50 ticks. Increasing this value results in slower recovery operations and consequently lower system impact while recoveries are being performed. |
|
The maximum size in kilobytes of the bitmap that Non-Persistent FastResync uses to track changed blocks in a volume. The number of blocks in a volume that are mapped to each bit in the bitmap depends on the size of the volume, and this value changes if the size of the volume is changed. For example, if the volume size is 1 gigabyte and the system block size is 1024 bytes, a The larger the bitmap size, the fewer the number of blocks that are mapped to each bit. This can reduce the amount of reading and writing required on resynchronization, at the expense of requiring more non-pageable kernel memory for the bitmap. Additionally, on clustered systems, a larger bitmap size increases the latency in I/O performance, and it also increases the load on the private network between the cluster members. This is because every other member of the cluster must be informed each time a bit in the map is marked.
Since the region size must be the same on all nodes in a cluster for a shared volume, the value of the In configurations which have thousands of mirrors with attached snapshot plexes, the total memory overhead can represent a significantly higher overhead in memory consumption than is usual for VxVM. The default value is 4KB. The maximum and minimum permitted values are 1KB and 8KB. Note The value of this tunable does not have any effect on Persistent FastResync. |
|
The maximum number of volumes that can be created on the system. This value can be set to between 1 and the maximum number of minor numbers representable in the system. |
|
The maximum size of logical I/O operations that can be performed without breaking up the request. I/O requests to VxVM that are larger than this value are broken up and performed synchronously. Physical I/O requests are broken up based on the capabilities of the disk device and are unaffected by changes to this maximum logical request limit. The default value is 256 sectors (256KB).
The value of
If DRL sequential logging is configured, the value of |
|
The maximum size of data that can be passed into VxVM via an |
|
The number of I/O operations that the The default value for this tunable is 256. This value should not be changed. |
|
The maximum size of an I/O request that can be issued by an The default value is 256 sectors (256KB).
Raising this limit can cause difficulties if the size of an I/O request causes the process to take more memory or kernel virtual mapping space than exists and thus deadlock. The maximum limit for
If stripes are larger than This tunable limits the size of an I/O request at a higher level in VxVM than the level of an individual disk. For example, for an 8 by 64KB stripe, a value of 256KB only allows I/O requests that use half the disks in the stripe; thus, it cuts potential throughput in half. If you have more columns or you have used a larger interleave factor, then your relative performance is worse. This tunable must be set, as a minimum, to the size of your largest stripe (RAID-0 or RAID-5). |
|
The maximum number of subdisks that can be attached to a single plex. There is no theoretical limit to this number, but it has been limited to a default value of 4096. This default can be changed, if required. |
|
If set to |
|
The maximum number of dirty regions that can exist on the system for non-sequential DRL on volumes. A larger value may result in improved system performance at the expense of recovery time. This tunable can be used to regulate the worse-case recovery time for the system following a failure. |
|
The maximum number of dirty regions allowed for sequential DRL. This is useful for volumes that are usually written to sequentially, such as database logs. Limiting the number of dirty regions allows for faster recovery if a crash occurs. |
|
The minimum number of sectors for a dirty region logging (DRL) volume region. With DRL, VxVM logically divides a volume into a set of consecutive regions. Larger region sizes tend to cause the cache hit-ratio for regions to improve. This improves the write performance, but it also prolongs the recovery time. The default value is 512 sectors.
If DRL sequential logging is configured, the value of |
|
The granularity of memory chunks used by VxVM when allocating or releasing system memory. A larger granularity reduces CPU overhead due to memory allocation by allowing VxVM to retain hold of a larger amount of memory. |
|
The maximum memory requested from the system by VxVM for internal purposes. This tunable has a direct impact on the performance of VxVM as it prevents one I/O operation from using all the memory in the system.
VxVM allocates two pools that can grow up to
A write request to a RAID-5 volume that is greater than
A write request to a mirrored volume that is greater than The default value for this tunable is 4M.
The value of |
|
The default size of the buffer maintained for error tracing events. This buffer is allocated at driver load time and is not adjustable for size while VxVM is running. The defaultvalue is 16384 bytes (16KB). Increasing this buffer can provide storage for more error events at the expense of system memory. Decreasing the size of the buffer can result in an error not being detected via the tracing device. Applications that depend on error tracing to perform some responsive action are dependent on this buffer. |
|
The default size for the creation of a tracing buffer in the absence of any other specification of desired kernel buffer size as part of the trace The default value is 8192 bytes (8KB). If trace data is often being lost due to this buffer size being too small, then this value can be tuned to a more generous amount. |
|
The upper limit to the size of memory that can be used for storing tracing buffers in the kernel. Tracing buffers are used by the VxVM kernel to store the tracing event records. As trace buffers are requested to be stored in the kernel, the memory for them is drawn from this pool. Increasing this size can allow additional tracing to be performed at the expense of system memory usage. Setting this value to a size greater than can readily be accommodated on the system is inadvisable. |
|
The maximum buffer size that can be used for a single trace buffer. Requests of a buffer larger than this size are silently truncated to this size. A request for a maximal buffer size from the tracing interface results (subject to limits of usage) in a buffer of this size. The default value is 65536 bytes (64KB).
Increasing this buffer can provide for larger traces to be taken without loss for very heavily used volumes. Care should be taken not to increase this value above the value for the |
|
The maximum number of tracing channels that can be open simultaneously. Tracing channels are clone entry points into the tracing device driver. Each The default number of channels is 32. The allocation of each channel takes up approximately 20 bytes even when not in use. |
|
The amount of memory, measured in kilobytes, that is allocated for caching FastResync and cache object metadata. The default value is 6144KB (6MB). The memory allocated for this cache is exclusively dedicated to it. It is not available for other processes or applications.
Setting the value of
If you do not use the FastResync or DRL features that are implemented using a version 20 DCO volume, the value of
where the new value is specified in kilobytes. Using the |
|
The initial amount of memory that is requested from the system by VxVM for RAID-5 operations. The maximum size of this memory pool is limited by the value of |
|
The maximum number of transient reconstruct operations that can be performed in parallel for RAID-5. A transient reconstruct operation is one that occurs on a non-degraded RAID-5 volume that has not been predicted. Limiting the number of these operations that can occur simultaneously removes the possibility of flooding the system with many reconstruct operations, and so reduces the risk of causing memory starvation. Increasing this size improves the initial performance on the system when a failure first occurs and before a detach of a failing object is performed, but can lead to memory starvation. |