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    writeback: IO-less balance_dirty_pages() · 143dfe86
    Wu Fengguang 提交于
    As proposed by Chris, Dave and Jan, don't start foreground writeback IO
    inside balance_dirty_pages(). Instead, simply let it idle sleep for some
    time to throttle the dirtying task. In the mean while, kick off the
    per-bdi flusher thread to do background writeback IO.
    
    RATIONALS
    =========
    
    - disk seeks on concurrent writeback of multiple inodes (Dave Chinner)
    
      If every thread doing writes and being throttled start foreground
      writeback, it leads to N IO submitters from at least N different
      inodes at the same time, end up with N different sets of IO being
      issued with potentially zero locality to each other, resulting in
      much lower elevator sort/merge efficiency and hence we seek the disk
      all over the place to service the different sets of IO.
      OTOH, if there is only one submission thread, it doesn't jump between
      inodes in the same way when congestion clears - it keeps writing to
      the same inode, resulting in large related chunks of sequential IOs
      being issued to the disk. This is more efficient than the above
      foreground writeback because the elevator works better and the disk
      seeks less.
    
    - lock contention and cache bouncing on concurrent IO submitters (Dave Chinner)
    
      With this patchset, the fs_mark benchmark on a 12-drive software RAID0 goes
      from CPU bound to IO bound, freeing "3-4 CPUs worth of spinlock contention".
    
      * "CPU usage has dropped by ~55%", "it certainly appears that most of
        the CPU time saving comes from the removal of contention on the
        inode_wb_list_lock" (IMHO at least 10% comes from the reduction of
        cacheline bouncing, because the new code is able to call much less
        frequently into balance_dirty_pages() and hence access the global
        page states)
    
      * the user space "App overhead" is reduced by 20%, by avoiding the
        cacheline pollution by the complex writeback code path
    
      * "for a ~5% throughput reduction", "the number of write IOs have
        dropped by ~25%", and the elapsed time reduced from 41:42.17 to
        40:53.23.
    
      * On a simple test of 100 dd, it reduces the CPU %system time from 30% to 3%,
        and improves IO throughput from 38MB/s to 42MB/s.
    
    - IO size too small for fast arrays and too large for slow USB sticks
    
      The write_chunk used by current balance_dirty_pages() cannot be
      directly set to some large value (eg. 128MB) for better IO efficiency.
      Because it could lead to more than 1 second user perceivable stalls.
      Even the current 4MB write size may be too large for slow USB sticks.
      The fact that balance_dirty_pages() starts IO on itself couples the
      IO size to wait time, which makes it hard to do suitable IO size while
      keeping the wait time under control.
    
      Now it's possible to increase writeback chunk size proportional to the
      disk bandwidth. In a simple test of 50 dd's on XFS, 1-HDD, 3GB ram,
      the larger writeback size dramatically reduces the seek count to 1/10
      (far beyond my expectation) and improves the write throughput by 24%.
    
    - long block time in balance_dirty_pages() hurts desktop responsiveness
    
      Many of us may have the experience: it often takes a couple of seconds
      or even long time to stop a heavy writing dd/cp/tar command with
      Ctrl-C or "kill -9".
    
    - IO pipeline broken by bumpy write() progress
    
      There are a broad class of "loop {read(buf); write(buf);}" applications
      whose read() pipeline will be under-utilized or even come to a stop if
      the write()s have long latencies _or_ don't progress in a constant rate.
      The current threshold based throttling inherently transfers the large
      low level IO completion fluctuations to bumpy application write()s,
      and further deteriorates with increasing number of dirtiers and/or bdi's.
    
      For example, when doing 50 dd's + 1 remote rsync to an XFS partition,
      the rsync progresses very bumpy in legacy kernel, and throughput is
      improved by 67% by this patchset. (plus the larger write chunk size,
      it will be 93% speedup).
    
      The new rate based throttling can support 1000+ dd's with excellent
      smoothness, low latency and low overheads.
    
    For the above reasons, it's much better to do IO-less and low latency
    pauses in balance_dirty_pages().
    
    Jan Kara, Dave Chinner and me explored the scheme to let
    balance_dirty_pages() wait for enough writeback IO completions to
    safeguard the dirty limit. However it's found to have two problems:
    
    - in large NUMA systems, the per-cpu counters may have big accounting
      errors, leading to big throttle wait time and jitters.
    
    - NFS may kill large amount of unstable pages with one single COMMIT.
      Because NFS server serves COMMIT with expensive fsync() IOs, it is
      desirable to delay and reduce the number of COMMITs. So it's not
      likely to optimize away such kind of bursty IO completions, and the
      resulted large (and tiny) stall times in IO completion based throttling.
    
    So here is a pause time oriented approach, which tries to control the
    pause time in each balance_dirty_pages() invocations, by controlling
    the number of pages dirtied before calling balance_dirty_pages(), for
    smooth and efficient dirty throttling:
    
    - avoid useless (eg. zero pause time) balance_dirty_pages() calls
    - avoid too small pause time (less than   4ms, which burns CPU power)
    - avoid too large pause time (more than 200ms, which hurts responsiveness)
    - avoid big fluctuations of pause times
    
    It can control pause times at will. The default policy (in a followup
    patch) will be to do ~10ms pauses in 1-dd case, and increase to ~100ms
    in 1000-dd case.
    
    BEHAVIOR CHANGE
    ===============
    
    (1) dirty threshold
    
    Users will notice that the applications will get throttled once crossing
    the global (background + dirty)/2=15% threshold, and then balanced around
    17.5%. Before patch, the behavior is to just throttle it at 20% dirtyable
    memory in 1-dd case.
    
    Since the task will be soft throttled earlier than before, it may be
    perceived by end users as performance "slow down" if his application
    happens to dirty more than 15% dirtyable memory.
    
    (2) smoothness/responsiveness
    
    Users will notice a more responsive system during heavy writeback.
    "killall dd" will take effect instantly.
    Signed-off-by: NWu Fengguang <fengguang.wu@intel.com>
    143dfe86
writeback.h 8.9 KB