[v2 PATCH 0/5] Introduce mempool pages bulk allocator and use it in dm-crypt
From: Yang Shi
Date: Tue Feb 14 2023 - 14:02:41 EST
Changelog:
RFC -> v2:
* Added callback variant for page bulk allocator and mempool bulk allocator
per Mel Gorman.
* Used the callback version in dm-crypt driver.
* Some code cleanup and refactor to reduce duplicate code.
rfc: https://lore.kernel.org/linux-mm/20221005180341.1738796-1-shy828301@xxxxxxxxx/
We have full disk encryption enabled, profiling shows page allocations may
incur a noticeable overhead when writing. The dm-crypt creates an "out"
bio for writing. And fill the "out" bio with the same amount of pages
as "in" bio. But the driver allocates one page at a time in a loop. For
1M bio it means the driver has to call page allocator 256 times. It seems
not that efficient.
Since v5.13 we have page bulk allocator supported, so dm-crypt could use
it to do page allocations more efficiently.
I could just call the page bulk allocator in dm-crypt driver before the
mempool allocator, but it seems ad-hoc and the quick search shows some
others do the similar thing, for example, f2fs compress, block bounce,
g2fs, ufs, etc. So it seems more neat to implement a general bulk allocation
API for mempool.
Currently the bulk allocator just supported list and array to consume the
pages. But neither is the best fit to dm-crypt ussecase. So introduce
a new bulk allocator API, callback, per the suggestion from Mel Gorman.
It consumes the pages by calling a callback with a parameter.
So introduce the mempool page bulk allocator.
The below APIs are introduced:
- mempool_init_pages_bulk()
- mempool_create_pages_bulk()
They initialize the mempool for page bulk allocator. The pool is filled
by alloc_page() in a loop.
- mempool_alloc_pages_bulk_cb()
- mempool_alloc_pages_bulk_array()
They do bulk allocation from mempool. The list version is not implemented
since there is no user for list version bulk allocator so far and it may
be gong soon.
They do the below conceptually:
1. Call bulk page allocator
2. If the allocation is fulfilled then return otherwise try to
allocate the remaining pages from the mempool
3. If it is fulfilled then return otherwise retry from #1 with sleepable
gfp
4. If it is still failed, sleep for a while to wait for the mempool is
refilled, then retry from #1
The populated pages will stay on array until the callers consume them or
free them, or will be consumed by the callback.
Since mempool allocator is guaranteed to success in the sleepable context,
so the two APIs return true for success or false for fail. It is the
caller's responsibility to handle failure case (partial allocation), just
like the page bulk allocator.
The mempool typically is an object agnostic allocator, but bulk allocation
is only supported by pages, so the mempool bulk allocator is for page
allocation only as well.
With the mempool bulk allocator the IOPS of dm-crypt with 1M I/O would get
improved by approxiamately 6%. The test is done on a machine with 80 CPU and
128GB memory with an encrypted ram device (the impact from storage hardware
could be minimized so that we could benchmark the dm-crypt layer more
accurately).
Before the patch:
Jobs: 1 (f=1): [w(1)][100.0%][w=1301MiB/s][w=1301 IOPS][eta 00m:00s]
crypt: (groupid=0, jobs=1): err= 0: pid=48512: Wed Feb 1 18:11:30 2023
write: IOPS=1300, BW=1301MiB/s (1364MB/s)(76.2GiB/60001msec); 0 zone resets
slat (usec): min=724, max=867, avg=765.71, stdev=19.27
clat (usec): min=4, max=196297, avg=195688.86, stdev=6450.50
lat (usec): min=801, max=197064, avg=196454.90, stdev=6450.35
clat percentiles (msec):
| 1.00th=[ 197], 5.00th=[ 197], 10.00th=[ 197], 20.00th=[ 197],
| 30.00th=[ 197], 40.00th=[ 197], 50.00th=[ 197], 60.00th=[ 197],
| 70.00th=[ 197], 80.00th=[ 197], 90.00th=[ 197], 95.00th=[ 197],
| 99.00th=[ 197], 99.50th=[ 197], 99.90th=[ 197], 99.95th=[ 197],
| 99.99th=[ 197]
bw ( MiB/s): min= 800, max= 1308, per=99.69%, avg=1296.94, stdev=46.02, samples=119
iops : min= 800, max= 1308, avg=1296.94, stdev=46.02, samples=119
lat (usec) : 10=0.01%, 1000=0.01%
lat (msec) : 2=0.01%, 4=0.01%, 10=0.01%, 20=0.02%, 50=0.05%
lat (msec) : 100=0.08%, 250=99.83%
cpu : usr=3.88%, sys=96.02%, ctx=69, majf=1, minf=9
IO depths : 1=0.1%, 2=0.1%, 4=0.1%, 8=0.1%, 16=0.1%, 32=0.1%, >=64=99.9%
submit : 0=0.0%, 4=100.0%, 8=0.0%, 16=0.0%, 32=0.0%, 64=0.0%, >=64=0.0%
complete : 0=0.0%, 4=100.0%, 8=0.0%, 16=0.0%, 32=0.0%, 64=0.0%, >=64=0.1%
issued rwts: total=0,78060,0,0 short=0,0,0,0 dropped=0,0,0,0
latency : target=0, window=0, percentile=100.00%, depth=256
Run status group 0 (all jobs):
WRITE: bw=1301MiB/s (1364MB/s), 1301MiB/s-1301MiB/s (1364MB/s-1364MB/s), io=76.2GiB (81.9GB), run=60001-60001msec
After the patch:
Jobs: 1 (f=1): [w(1)][100.0%][w=1401MiB/s][w=1401 IOPS][eta 00m:00s]
crypt: (groupid=0, jobs=1): err= 0: pid=2171: Wed Feb 1 21:08:16 2023
write: IOPS=1401, BW=1402MiB/s (1470MB/s)(82.1GiB/60001msec); 0 zone resets
slat (usec): min=685, max=815, avg=710.77, stdev=13.24
clat (usec): min=4, max=182206, avg=181658.31, stdev=5810.58
lat (usec): min=709, max=182913, avg=182369.36, stdev=5810.67
clat percentiles (msec):
| 1.00th=[ 182], 5.00th=[ 182], 10.00th=[ 182], 20.00th=[ 182],
| 30.00th=[ 182], 40.00th=[ 182], 50.00th=[ 182], 60.00th=[ 182],
| 70.00th=[ 182], 80.00th=[ 182], 90.00th=[ 182], 95.00th=[ 182],
| 99.00th=[ 182], 99.50th=[ 182], 99.90th=[ 182], 99.95th=[ 182],
| 99.99th=[ 182]
bw ( MiB/s): min= 900, max= 1408, per=99.71%, avg=1397.60, stdev=46.04, samples=119
iops : min= 900, max= 1408, avg=1397.60, stdev=46.04, samples=119
lat (usec) : 10=0.01%, 750=0.01%
lat (msec) : 2=0.01%, 4=0.01%, 10=0.01%, 20=0.02%, 50=0.05%
lat (msec) : 100=0.08%, 250=99.83%
cpu : usr=3.66%, sys=96.23%, ctx=76, majf=1, minf=9
IO depths : 1=0.1%, 2=0.1%, 4=0.1%, 8=0.1%, 16=0.1%, 32=0.1%, >=64=99.9%
submit : 0=0.0%, 4=100.0%, 8=0.0%, 16=0.0%, 32=0.0%, 64=0.0%, >=64=0.0%
complete : 0=0.0%, 4=100.0%, 8=0.0%, 16=0.0%, 32=0.0%, 64=0.0%, >=64=0.1%
issued rwts: total=0,84098,0,0 short=0,0,0,0 dropped=0,0,0,0
latency : target=0, window=0, percentile=100.00%, depth=256
Run status group 0 (all jobs):
WRITE: bw=1402MiB/s (1470MB/s), 1402MiB/s-1402MiB/s (1470MB/s-1470MB/s), io=82.1GiB (88.2GB), run=60001-60001msec
And the benchmark with 4K size I/O doesn't show measurable regression.
Yang Shi (5):
mm: page_alloc: add API for bulk allocator with callback
mm: mempool: extract the common initialization and alloc code
mm: mempool: introduce page bulk allocator
md: dm-crypt: move crypt_free_buffer_pages ahead
md: dm-crypt: use mempool page bulk allocator
drivers/md/dm-crypt.c | 95 ++++++++++++++++++++++++++++++---------------------
include/linux/gfp.h | 21 +++++++++---
include/linux/mempool.h | 21 ++++++++++++
mm/mempolicy.c | 12 ++++---
mm/mempool.c | 248 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++-----------------------
mm/page_alloc.c | 21 ++++++++----
6 files changed, 323 insertions(+), 95 deletions(-)