Resent this time without HTML formatting which lkml doesn't like. Sorry.
On 08/09/2014 03:58 PM, Thomas Hellstrom wrote:
On 08/09/2014 03:33 PM, Konrad Rzeszutek Wilk wrote:
On August 9, 2014 1:39:39 AM EDT, Thomas Hellstrom<thellst...@vmware.com>
wrote:
Hi.
Hey Thomas!
IIRC I don't think the TTM DMA pool allocates coherent pages more than
one page at a time, and _if that's true_ it's pretty unnecessary for
the
dma subsystem to route those allocations to CMA. Maybe Konrad could
shed
some light over this?
It should allocate in batches and keep them in the TTM DMA pool for some time
to be reused.
The pages that it gets are in 4kb granularity though.
Then I feel inclined to say this is a DMA subsystem bug. Single page
allocations shouldn't get routed to CMA.
/Thomas
Yes, seems you're both right. I read through the code a bit more and
indeed the TTM DMA pool allocates only one page during each
dma_alloc_coherent() call, so it doesn't need CMA memory. The current
allocators don't check for single page CMA allocations and therefore try
to get it from the CMA area anyway, instead of skipping to the much
cheaper fallback.
So the callers of dma_alloc_from_contiguous() could need that little
optimization of skipping it if only one page is requested. For
dma_generic_alloc_coherent
<http://lxr.free-electrons.com/ident?i=dma_generic_alloc_coherent>
andintel_alloc_coherent <http://lxr.free-electrons.com/ident?i=intel_alloc_coherent>
this seems easy to do. Looking at the arm arch variants, e.g.,
http://lxr.free-electrons.com/source/arch/arm/mm/dma-mapping.c#L1194
and
http://lxr.free-electrons.com/source/arch/arm64/mm/dma-mapping.c#L44
i'm not sure if it is that easily done, as there aren't any fallbacks
for such a case and the code looks to me as if that's at least somewhat
intentional.
As far as TTM goes, one quick one-line fix to prevent it from using the
CMA at least on SWIOTLB, NOMMU and Intel IOMMU (when using the above
methods) would be to clear the __GFP_WAIT
<http://lxr.free-electrons.com/ident?i=__GFP_WAIT> flag from the passed
gfp_t flags. That would trigger the well working fallback. So, is
__GFP_WAIT <http://lxr.free-electrons.com/ident?i=__GFP_WAIT> needed for those
single page allocations that go through__ttm_dma_alloc_page
<http://lxr.free-electrons.com/ident?i=__ttm_dma_alloc_page>?
It would be nice to have such a simple, non-intrusive one-line patch
that we still could get into 3.17 and then backported to older stable
kernels to avoid the same desktop hangs there if CMA is enabled. It
would be also nice for actual users of CMA to not use up lots of CMA
space for gpu's which don't need it. I think DMA_CMA was introduced
around 3.12.
The other problem is that probably TTM does not reuse pages from the DMA
pool. If i trace the __ttm_dma_alloc_page
<http://lxr.free-electrons.com/ident?i=__ttm_dma_alloc_page> and
__ttm_dma_free_page
<http://lxr.free-electrons.com/ident?i=__ttm_dma_alloc_page> calls for
those single page allocs/frees, then over a 20 second interval of
tracing and switching tabs in firefox, scrolling things around etc. i
find about as many alloc's as i find free's, e.g., 1607 allocs vs. 1648
frees.
This bit of code fromttm_dma_unpopulate
<http://lxr.free-electrons.com/ident?i=ttm_dma_unpopulate>() (line 954
in 3.16) looks suspicious:
http://lxr.free-electrons.com/source/drivers/gpu/drm/ttm/ttm_page_alloc_dma.c#L954
Alloc's from a tt_cached cached pool ( if (is_cached)...) always get
freed and are not given back to the cached pool. But in the uncached
case, there's logic to make sure the pool doesn't grow forever (line
955, checking against _manager->options.max_size), but before that check
in line 954 there's an uncoditional assignment of npages = count; which
seems to force freeing all pages as well, instead of recycling? Is this
some debug code left over, or intentional and just me not understanding
what happens there?
thanks,
-mario
/Thomas
On 08/08/2014 07:42 PM, Mario Kleiner wrote:
Hi all,
there is a rather severe performance problem i accidentally found
when
trying to give Linux 3.16.0 a final test on a x86_64 MacBookPro under
Ubuntu 14.04 LTS with nouveau as graphics driver.
I was lazy and just installed the Ubuntu precompiled mainline kernel.
That kernel happens to have CONFIG_DMA_CMA=y set, with a default CMA
(contiguous memory allocator) size of 64 MB. Older Ubuntu kernels
weren't compiled with CMA, so i only observed this on 3.16, but
previous kernels would likely be affected too.
After a few minutes of regular desktop use like switching workspaces,
scrolling text in a terminal window, Firefox with multiple tabs open,
Thunderbird etc. (tested with KDE/Kwin, with/without desktop
composition), i get chunky desktop updates, then multi-second
freezes,
after a few minutes the desktop hangs for over a minute on almost any
GUI action like switching windows etc. --> Unuseable.
ftrace'ing shows the culprit being this callchain (typical good/bad
example ftrace snippets at the end of this mail):
...ttm dma coherent memory allocations, e.g., from
__ttm_dma_alloc_page() ... --> dma_alloc_coherent() --> platform
specific hooks ... -> dma_generic_alloc_coherent() [on x86_64] -->
dma_alloc_from_contiguous()
dma_alloc_from_contiguous() is a no-op without CONFIG_DMA_CMA, or
when
the machine is booted with kernel boot cmdline parameter "cma=0", so
it triggers the fast alloc_pages_node() fallback at least on x86_64.
With CMA, this function becomes progressively more slow with every
minute of desktop use, e.g., runtimes going up from < 0.3 usecs to
hundreds or thousands of microseconds (before it gives up and
alloc_pages_node() fallback is used), so this causes the
multi-second/minute hangs of the desktop.
So it seems ttm memory allocations quickly fragment and/or exhaust
the
CMA memory area, and dma_alloc_from_contiguous() tries very hard to
find a fitting hole big enough to satisfy allocations with a retry
loop (see
https://urldefense.proofpoint.com/v1/url?u=http://lxr.free-electrons.com/source/drivers/base/dma-contiguous.c%23L339&k=oIvRg1%2BdGAgOoM1BIlLLqw%3D%3D%0A&r=l5Ago9ekmVFZ3c4M6eauqrJWGwjf6fTb%2BP3CxbBFkVM%3D%0A&m=6cy0madhpBCtEyOKu95ucqhzU%2FjAHPP7ODVTc47UYQs%3D%0A&s=42356aad2ff181236f4704283dc058fdd7b7e213cdea7378665094b35ee0dfdf)
that takes forever.
I am curious why it does not end up using the pool. As in use the TTM DMA pool
to pick pages instead of allocating (and freeing) new ones?
This is not good, also not for other devices which actually need a
non-fragmented CMA for DMA, so what to do? I doubt most current gpus
still need physically contiguous dma memory, maybe with exception of
some embedded gpus?
Oh. If I understood you correctly - the CMA ends up giving huge chunks of
contiguous area. But if the sizes are 4kb I wonder why it would do that?
The modern GPUs on x86 can deal with scatter gather and as you surmise don't
need contiguous physical contiguous areas.
My naive approach would be to add a new gfp_t flag a la
___GFP_AVOIDCMA, and make callers of dma_alloc_from_contiguous()
refrain from doing so if they have some fallback for getting memory.
And then add that flag to ttm's ttm_dma_populate() gfp_flags, e.g.,
around here:
https://urldefense.proofpoint.com/v1/url?u=http://lxr.free-electrons.com/source/drivers/gpu/drm/ttm/ttm_page_alloc_dma.c%23L884&k=oIvRg1%2BdGAgOoM1BIlLLqw%3D%3D%0A&r=l5Ago9ekmVFZ3c4M6eauqrJWGwjf6fTb%2BP3CxbBFkVM%3D%0A&m=6cy0madhpBCtEyOKu95ucqhzU%2FjAHPP7ODVTc47UYQs%3D%0A&s=0c2a37c8bac57e0ab7333a9580eb5114e09566d1d34ab43be7a80de8316bdcdd
However i'm not familiar enough with memory management, so likely
greater minds here have much better ideas on how to deal with this?
That is a bit of hack to deal with CMA being slow.
Hmm. Let's first figure out why TTM DMA pool is not reusing pages.
thanks,
-mario
Typical snippet from an example trace of a badly stalling desktop
with
CMA (alloc_pages_node() fallback may have been missing in this traces
ftrace_filter settings):
1) | ttm_dma_pool_get_pages
[ttm]() {
1) | ttm_dma_page_pool_fill_locked [ttm]() {
1) | ttm_dma_pool_alloc_new_pages [ttm]() {
1) | __ttm_dma_alloc_page [ttm]() {
1) | dma_generic_alloc_coherent() {
1) ! 1873.071 us | dma_alloc_from_contiguous();
1) ! 1874.292 us | }
1) ! 1875.400 us | }
1) | __ttm_dma_alloc_page [ttm]() {
1) | dma_generic_alloc_coherent() {
1) ! 1868.372 us | dma_alloc_from_contiguous();
1) ! 1869.586 us | }
1) ! 1870.053 us | }
1) | __ttm_dma_alloc_page [ttm]() {
1) | dma_generic_alloc_coherent() {
1) ! 1871.085 us | dma_alloc_from_contiguous();
1) ! 1872.240 us | }
1) ! 1872.669 us | }
1) | __ttm_dma_alloc_page [ttm]() {
1) | dma_generic_alloc_coherent() {
1) ! 1888.934 us | dma_alloc_from_contiguous();
1) ! 1890.179 us | }
1) ! 1890.608 us | }
1) 0.048 us | ttm_set_pages_caching [ttm]();
1) ! 7511.000 us | }
1) ! 7511.306 us | }
1) ! 7511.623 us | }
The good case (with cma=0 kernel cmdline, so
dma_alloc_from_contiguous() no-ops,)
0) | ttm_dma_pool_get_pages
[ttm]() {
0) | ttm_dma_page_pool_fill_locked [ttm]() {
0) | ttm_dma_pool_alloc_new_pages [ttm]() {
0) | __ttm_dma_alloc_page [ttm]() {
0) | dma_generic_alloc_coherent() {
0) 0.171 us | dma_alloc_from_contiguous();
0) 0.849 us | __alloc_pages_nodemask();
0) 3.029 us | }
0) 3.882 us | }
0) | __ttm_dma_alloc_page [ttm]() {
0) | dma_generic_alloc_coherent() {
0) 0.037 us | dma_alloc_from_contiguous();
0) 0.163 us | __alloc_pages_nodemask();
0) 1.408 us | }
0) 1.719 us | }
0) | __ttm_dma_alloc_page [ttm]() {
0) | dma_generic_alloc_coherent() {
0) 0.035 us | dma_alloc_from_contiguous();
0) 0.153 us | __alloc_pages_nodemask();
0) 1.454 us | }
0) 1.720 us | }
0) | __ttm_dma_alloc_page [ttm]() {
0) | dma_generic_alloc_coherent() {
0) 0.036 us | dma_alloc_from_contiguous();
0) 0.112 us | __alloc_pages_nodemask();
0) 1.211 us | }
0) 1.541 us | }
0) 0.035 us | ttm_set_pages_caching [ttm]();
0) + 10.902 us | }
0) + 11.577 us | }
0) + 11.988 us | }
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