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as-iosched.txt: o Changed IO scheduler selection text to a reference to the switching-sched.txt file. o Fixed typo: 'for up time...' -> 'for up to...' o Added short description of the est_time file. deadline-iosched.txt: o Changed IO scheduler selection text to a reference to the switching-sched.txt file. o Removed references to non-existent seek-cost and stream_unit. o Fixed typo: 'write_starved' -> 'writes_starved' switching-sched.txt: o Added in boot-time argument to set the default IO scheduler. (From as-iosched.txt) o Added in sysfs mount instructions. (From deadline-iosched.txt) Signed-off-by: Alan D. Brunelle <Alan.Brunelle@hp.com> Signed-off-by: Jens Axboe <jens.axboe@oracle.com>
172 lines
8.5 KiB
Text
172 lines
8.5 KiB
Text
Anticipatory IO scheduler
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-------------------------
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Nick Piggin <piggin@cyberone.com.au> 13 Sep 2003
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Attention! Database servers, especially those using "TCQ" disks should
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investigate performance with the 'deadline' IO scheduler. Any system with high
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disk performance requirements should do so, in fact.
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If you see unusual performance characteristics of your disk systems, or you
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see big performance regressions versus the deadline scheduler, please email
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me. Database users don't bother unless you're willing to test a lot of patches
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from me ;) its a known issue.
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Also, users with hardware RAID controllers, doing striping, may find
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highly variable performance results with using the as-iosched. The
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as-iosched anticipatory implementation is based on the notion that a disk
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device has only one physical seeking head. A striped RAID controller
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actually has a head for each physical device in the logical RAID device.
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However, setting the antic_expire (see tunable parameters below) produces
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very similar behavior to the deadline IO scheduler.
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Selecting IO schedulers
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-----------------------
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Refer to Documentation/block/switching-sched.txt for information on
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selecting an io scheduler on a per-device basis.
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Anticipatory IO scheduler Policies
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----------------------------------
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The as-iosched implementation implements several layers of policies
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to determine when an IO request is dispatched to the disk controller.
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Here are the policies outlined, in order of application.
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1. one-way Elevator algorithm.
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The elevator algorithm is similar to that used in deadline scheduler, with
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the addition that it allows limited backward movement of the elevator
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(i.e. seeks backwards). A seek backwards can occur when choosing between
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two IO requests where one is behind the elevator's current position, and
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the other is in front of the elevator's position. If the seek distance to
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the request in back of the elevator is less than half the seek distance to
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the request in front of the elevator, then the request in back can be chosen.
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Backward seeks are also limited to a maximum of MAXBACK (1024*1024) sectors.
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This favors forward movement of the elevator, while allowing opportunistic
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"short" backward seeks.
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2. FIFO expiration times for reads and for writes.
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This is again very similar to the deadline IO scheduler. The expiration
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times for requests on these lists is tunable using the parameters read_expire
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and write_expire discussed below. When a read or a write expires in this way,
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the IO scheduler will interrupt its current elevator sweep or read anticipation
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to service the expired request.
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3. Read and write request batching
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A batch is a collection of read requests or a collection of write
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requests. The as scheduler alternates dispatching read and write batches
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to the driver. In the case a read batch, the scheduler submits read
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requests to the driver as long as there are read requests to submit, and
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the read batch time limit has not been exceeded (read_batch_expire).
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The read batch time limit begins counting down only when there are
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competing write requests pending.
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In the case of a write batch, the scheduler submits write requests to
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the driver as long as there are write requests available, and the
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write batch time limit has not been exceeded (write_batch_expire).
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However, the length of write batches will be gradually shortened
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when read batches frequently exceed their time limit.
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When changing between batch types, the scheduler waits for all requests
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from the previous batch to complete before scheduling requests for the
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next batch.
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The read and write fifo expiration times described in policy 2 above
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are checked only when in scheduling IO of a batch for the corresponding
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(read/write) type. So for example, the read FIFO timeout values are
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tested only during read batches. Likewise, the write FIFO timeout
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values are tested only during write batches. For this reason,
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it is generally not recommended for the read batch time
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to be longer than the write expiration time, nor for the write batch
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time to exceed the read expiration time (see tunable parameters below).
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When the IO scheduler changes from a read to a write batch,
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it begins the elevator from the request that is on the head of the
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write expiration FIFO. Likewise, when changing from a write batch to
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a read batch, scheduler begins the elevator from the first entry
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on the read expiration FIFO.
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4. Read anticipation.
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Read anticipation occurs only when scheduling a read batch.
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This implementation of read anticipation allows only one read request
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to be dispatched to the disk controller at a time. In
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contrast, many write requests may be dispatched to the disk controller
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at a time during a write batch. It is this characteristic that can make
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the anticipatory scheduler perform anomalously with controllers supporting
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TCQ, or with hardware striped RAID devices. Setting the antic_expire
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queue parameter (see below) to zero disables this behavior, and the
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anticipatory scheduler behaves essentially like the deadline scheduler.
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When read anticipation is enabled (antic_expire is not zero), reads
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are dispatched to the disk controller one at a time.
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At the end of each read request, the IO scheduler examines its next
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candidate read request from its sorted read list. If that next request
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is from the same process as the request that just completed,
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or if the next request in the queue is "very close" to the
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just completed request, it is dispatched immediately. Otherwise,
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statistics (average think time, average seek distance) on the process
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that submitted the just completed request are examined. If it seems
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likely that that process will submit another request soon, and that
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request is likely to be near the just completed request, then the IO
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scheduler will stop dispatching more read requests for up to (antic_expire)
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milliseconds, hoping that process will submit a new request near the one
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that just completed. If such a request is made, then it is dispatched
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immediately. If the antic_expire wait time expires, then the IO scheduler
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will dispatch the next read request from the sorted read queue.
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To decide whether an anticipatory wait is worthwhile, the scheduler
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maintains statistics for each process that can be used to compute
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mean "think time" (the time between read requests), and mean seek
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distance for that process. One observation is that these statistics
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are associated with each process, but those statistics are not associated
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with a specific IO device. So for example, if a process is doing IO
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on several file systems on separate devices, the statistics will be
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a combination of IO behavior from all those devices.
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Tuning the anticipatory IO scheduler
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------------------------------------
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When using 'as', the anticipatory IO scheduler there are 5 parameters under
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/sys/block/*/queue/iosched/. All are units of milliseconds.
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The parameters are:
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* read_expire
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Controls how long until a read request becomes "expired". It also controls the
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interval between which expired requests are served, so set to 50, a request
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might take anywhere < 100ms to be serviced _if_ it is the next on the
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expired list. Obviously request expiration strategies won't make the disk
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go faster. The result basically equates to the timeslice a single reader
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gets in the presence of other IO. 100*((seek time / read_expire) + 1) is
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very roughly the % streaming read efficiency your disk should get with
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multiple readers.
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* read_batch_expire
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Controls how much time a batch of reads is given before pending writes are
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served. A higher value is more efficient. This might be set below read_expire
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if writes are to be given higher priority than reads, but reads are to be
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as efficient as possible when there are no writes. Generally though, it
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should be some multiple of read_expire.
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* write_expire, and
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* write_batch_expire are equivalent to the above, for writes.
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* antic_expire
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Controls the maximum amount of time we can anticipate a good read (one
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with a short seek distance from the most recently completed request) before
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giving up. Many other factors may cause anticipation to be stopped early,
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or some processes will not be "anticipated" at all. Should be a bit higher
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for big seek time devices though not a linear correspondence - most
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processes have only a few ms thinktime.
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In addition to the tunables above there is a read-only file named est_time
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which, when read, will show:
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- The probability of a task exiting without a cooperating task
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submitting an anticipated IO.
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- The current mean think time.
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- The seek distance used to determine if an incoming IO is better.
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