| Message ID | 20241114152743.2381672-2-axboe@kernel.dk (mailing list archive) |
|---|---|
| Headers | show |
| Series | Uncached buffered IO | expand |
On Thu, 2024-11-14 at 08:25 -0700, Jens Axboe wrote: > Hi, > > 5 years ago I posted patches adding support for RWF_UNCACHED, as a way > to do buffered IO that isn't page cache persistent. The approach back > then was to have private pages for IO, and then get rid of them once IO > was done. But that then runs into all the issues that O_DIRECT has, in > terms of synchronizing with the page cache. > > So here's a new approach to the same concent, but using the page cache > as synchronization. That makes RWF_UNCACHED less special, in that it's > just page cache IO, except it prunes the ranges once IO is completed. > > Why do this, you may ask? The tldr is that device speeds are only > getting faster, while reclaim is not. Doing normal buffered IO can be > very unpredictable, and suck up a lot of resources on the reclaim side. > This leads people to use O_DIRECT as a work-around, which has its own > set of restrictions in terms of size, offset, and length of IO. It's > also inherently synchronous, and now you need async IO as well. While > the latter isn't necessarily a big problem as we have good options > available there, it also should not be a requirement when all you want > to do is read or write some data without caching. > > Even on desktop type systems, a normal NVMe device can fill the entire > page cache in seconds. On the big system I used for testing, there's a > lot more RAM, but also a lot more devices. As can be seen in some of the > results in the following patches, you can still fill RAM in seconds even > when there's 1TB of it. Hence this problem isn't solely a "big > hyperscaler system" issue, it's common across the board. > > Common for both reads and writes with RWF_UNCACHED is that they use the > page cache for IO. Reads work just like a normal buffered read would, > with the only exception being that the touched ranges will get pruned > after data has been copied. For writes, the ranges will get writeback > kicked off before the syscall returns, and then writeback completion > will prune the range. Hence writes aren't synchronous, and it's easy to > pipeline writes using RWF_UNCACHED. Folios that aren't instantiated by > RWF_UNCACHED IO are left untouched. This means you that uncached IO > will take advantage of the page cache for uptodate data, but not leave > anything it instantiated/created in cache. > > File systems need to support this. The patches add support for the > generic filemap helpers, and for iomap. Then ext4 and XFS are marked as > supporting it. The last patch adds support for btrfs as well, lightly > tested. The read side is already done by filemap, only the write side > needs a bit of help. The amount of code here is really trivial, and the > only reason the fs opt-in is necessary is to have an RWF_UNCACHED IO > return -EOPNOTSUPP just in case the fs doesn't use either the generic > paths or iomap. Adding "support" to other file systems should be > trivial, most of the time just a one-liner adding FOP_UNCACHED to the > fop_flags in the file_operations struct. > > Performance results are in patch 8 for reads and patch 10 for writes, > with the tldr being that I see about a 65% improvement in performance > for both, with fully predictable IO times. CPU reduction is substantial > as well, with no kswapd activity at all for reclaim when using uncached > IO. > > Using it from applications is trivial - just set RWF_UNCACHED for the > read or write, using pwritev2(2) or preadv2(2). For io_uring, same > thing, just set RWF_UNCACHED in sqe->rw_flags for a buffered read/write > operation. And that's it. > > Patches 1..7 are just prep patches, and should have no functional > changes at all. Patch 8 adds support for the filemap path for > RWF_UNCACHED reads, patch 10 adds support for filemap RWF_UNCACHED > writes, and patches 13..17 adds ext4, xfs/iomap, and btrfs support. > > Passes full xfstests and fsx overnight runs, no issues observed. That > includes the vm running the testing also using RWF_UNCACHED on the host. > I'll post fsstress and fsx patches for RWF_UNCACHED separately. As far > as I'm concerned, no further work needs doing here. Once we're into > the 6.13 merge window, I'll split up this series and aim to get it > landed that way. There are really 4 parts to this - generic mm bits, > ext4 bits, xfs bits, and btrfs bits. > > And git tree for the patches is here: > > https://git.kernel.dk/cgit/linux/log/?h=buffered-uncached.7 > > fs/btrfs/bio.c | 4 +- > fs/btrfs/bio.h | 2 + > fs/btrfs/extent_io.c | 8 ++- > fs/btrfs/file.c | 9 ++- > fs/ext4/ext4.h | 1 + > fs/ext4/file.c | 2 +- > fs/ext4/inline.c | 7 +- > fs/ext4/inode.c | 18 +++++- > fs/ext4/page-io.c | 28 ++++---- > fs/iomap/buffered-io.c | 15 ++++- > fs/xfs/xfs_aops.c | 7 +- > fs/xfs/xfs_file.c | 3 +- > include/linux/fs.h | 21 +++++- > include/linux/iomap.h | 8 ++- > include/linux/page-flags.h | 5 ++ > include/linux/pagemap.h | 14 ++++ > include/trace/events/mmflags.h | 3 +- > include/uapi/linux/fs.h | 6 +- > mm/filemap.c | 114 +++++++++++++++++++++++++++++---- > mm/readahead.c | 22 +++++-- > mm/swap.c | 2 + > mm/truncate.c | 35 ++++++---- > 22 files changed, 271 insertions(+), 63 deletions(-) > > Since v3 > - Use foliop_is_uncached() in ext4 rather than do manual compares with > foliop_uncached. > - Add filemap_fdatawrite_range_kick() helper and use that in > generic_write_sync() to kick off uncached writeback, rather than need > every fs adding a call to generic_uncached_write(). > - Drop generic_uncached_write() helper, not needed anymore. > - Skip folio_unmap_invalidate() if the folio is dirty. > - Move IOMAP_F_UNCACHED to the internal iomap flags section, and add > comment from Darrick to it as well. > - Only kick uncached writeback in generic_write_sync() if > iocb_is_dsync() isn't true. > - Disable RWF_UNCACHED on dax mappings. They require more extensive > invalidation, and as it isn't a likely use case, just disable it > for now. > - Update a few commit messages > Hi, Hello, the simplicity and performance improvement of this patch series are really impressive, and I have no comments on it. I'm just curious about its use cases—under which scenarios should it be used, and under which scenarios should it be avoided? I noticed that the backing device you used for testing can provide at least 92GB/s read performance and 115GB/s write performance. Does this mean that the higher the performance of the backing device, the more noticeable the optimization? How does this patch series perform on low-speed devices? My understanding is that the performance issue this patch is trying to address originates from the page cache being filled up, causing the current IO to wait for write-back or reclamation, correct? From this perspective, it seems that this would be suitable for applications that issue a large amount of IO in a short period of time, and it might not be dependent on the speed of the backing device? Thanks,
On 11/14/24 9:01 PM, Julian Sun wrote: > On Thu, 2024-11-14 at 08:25 -0700, Jens Axboe wrote: >> Hi, >> >> 5 years ago I posted patches adding support for RWF_UNCACHED, as a way >> to do buffered IO that isn't page cache persistent. The approach back >> then was to have private pages for IO, and then get rid of them once IO >> was done. But that then runs into all the issues that O_DIRECT has, in >> terms of synchronizing with the page cache. >> >> So here's a new approach to the same concent, but using the page cache >> as synchronization. That makes RWF_UNCACHED less special, in that it's >> just page cache IO, except it prunes the ranges once IO is completed. >> >> Why do this, you may ask? The tldr is that device speeds are only >> getting faster, while reclaim is not. Doing normal buffered IO can be >> very unpredictable, and suck up a lot of resources on the reclaim side. >> This leads people to use O_DIRECT as a work-around, which has its own >> set of restrictions in terms of size, offset, and length of IO. It's >> also inherently synchronous, and now you need async IO as well. While >> the latter isn't necessarily a big problem as we have good options >> available there, it also should not be a requirement when all you want >> to do is read or write some data without caching. >> >> Even on desktop type systems, a normal NVMe device can fill the entire >> page cache in seconds. On the big system I used for testing, there's a >> lot more RAM, but also a lot more devices. As can be seen in some of the >> results in the following patches, you can still fill RAM in seconds even >> when there's 1TB of it. Hence this problem isn't solely a "big >> hyperscaler system" issue, it's common across the board. >> >> Common for both reads and writes with RWF_UNCACHED is that they use the >> page cache for IO. Reads work just like a normal buffered read would, >> with the only exception being that the touched ranges will get pruned >> after data has been copied. For writes, the ranges will get writeback >> kicked off before the syscall returns, and then writeback completion >> will prune the range. Hence writes aren't synchronous, and it's easy to >> pipeline writes using RWF_UNCACHED. Folios that aren't instantiated by >> RWF_UNCACHED IO are left untouched. This means you that uncached IO >> will take advantage of the page cache for uptodate data, but not leave >> anything it instantiated/created in cache. >> >> File systems need to support this. The patches add support for the >> generic filemap helpers, and for iomap. Then ext4 and XFS are marked as >> supporting it. The last patch adds support for btrfs as well, lightly >> tested. The read side is already done by filemap, only the write side >> needs a bit of help. The amount of code here is really trivial, and the >> only reason the fs opt-in is necessary is to have an RWF_UNCACHED IO >> return -EOPNOTSUPP just in case the fs doesn't use either the generic >> paths or iomap. Adding "support" to other file systems should be >> trivial, most of the time just a one-liner adding FOP_UNCACHED to the >> fop_flags in the file_operations struct. >> >> Performance results are in patch 8 for reads and patch 10 for writes, >> with the tldr being that I see about a 65% improvement in performance >> for both, with fully predictable IO times. CPU reduction is substantial >> as well, with no kswapd activity at all for reclaim when using uncached >> IO. >> >> Using it from applications is trivial - just set RWF_UNCACHED for the >> read or write, using pwritev2(2) or preadv2(2). For io_uring, same >> thing, just set RWF_UNCACHED in sqe->rw_flags for a buffered read/write >> operation. And that's it. >> >> Patches 1..7 are just prep patches, and should have no functional >> changes at all. Patch 8 adds support for the filemap path for >> RWF_UNCACHED reads, patch 10 adds support for filemap RWF_UNCACHED >> writes, and patches 13..17 adds ext4, xfs/iomap, and btrfs support. >> >> Passes full xfstests and fsx overnight runs, no issues observed. That >> includes the vm running the testing also using RWF_UNCACHED on the host. >> I'll post fsstress and fsx patches for RWF_UNCACHED separately. As far >> as I'm concerned, no further work needs doing here. Once we're into >> the 6.13 merge window, I'll split up this series and aim to get it >> landed that way. There are really 4 parts to this - generic mm bits, >> ext4 bits, xfs bits, and btrfs bits. >> >> And git tree for the patches is here: >> >> https://git.kernel.dk/cgit/linux/log/?h=buffered-uncached.7 >> >> fs/btrfs/bio.c | 4 +- >> fs/btrfs/bio.h | 2 + >> fs/btrfs/extent_io.c | 8 ++- >> fs/btrfs/file.c | 9 ++- >> fs/ext4/ext4.h | 1 + >> fs/ext4/file.c | 2 +- >> fs/ext4/inline.c | 7 +- >> fs/ext4/inode.c | 18 +++++- >> fs/ext4/page-io.c | 28 ++++---- >> fs/iomap/buffered-io.c | 15 ++++- >> fs/xfs/xfs_aops.c | 7 +- >> fs/xfs/xfs_file.c | 3 +- >> include/linux/fs.h | 21 +++++- >> include/linux/iomap.h | 8 ++- >> include/linux/page-flags.h | 5 ++ >> include/linux/pagemap.h | 14 ++++ >> include/trace/events/mmflags.h | 3 +- >> include/uapi/linux/fs.h | 6 +- >> mm/filemap.c | 114 +++++++++++++++++++++++++++++---- >> mm/readahead.c | 22 +++++-- >> mm/swap.c | 2 + >> mm/truncate.c | 35 ++++++---- >> 22 files changed, 271 insertions(+), 63 deletions(-) >> >> Since v3 >> - Use foliop_is_uncached() in ext4 rather than do manual compares with >> foliop_uncached. >> - Add filemap_fdatawrite_range_kick() helper and use that in >> generic_write_sync() to kick off uncached writeback, rather than need >> every fs adding a call to generic_uncached_write(). >> - Drop generic_uncached_write() helper, not needed anymore. >> - Skip folio_unmap_invalidate() if the folio is dirty. >> - Move IOMAP_F_UNCACHED to the internal iomap flags section, and add >> comment from Darrick to it as well. >> - Only kick uncached writeback in generic_write_sync() if >> iocb_is_dsync() isn't true. >> - Disable RWF_UNCACHED on dax mappings. They require more extensive >> invalidation, and as it isn't a likely use case, just disable it >> for now. >> - Update a few commit messages >> > > Hi, > > Hello, the simplicity and performance improvement of this patch series are > really impressive, and I have no comments on it. > > I'm just curious about its use cases?under which scenarios should it be > used, and under which scenarios should it be avoided? I noticed that the > backing device you used for testing can provide at least 92GB/s read > performance and 115GB/s write performance. Does this mean that the higher > the performance of the backing device, the more noticeable the > optimization? How does this patch series perform on low-speed devices? It's really more about ratio of device speed to size of RAM. Yes the box I tested on has a lot of drives, but it also has a lot of memory. Hence the ratio to device speeds and memory size isn't that different from a normal desktop box with eg 32G of memory, and a flash drive that does 6GB/sec. Obviously reclaim for that smaller box will not be as bad as the big one, but still. It's really two fold: - You want to kick off writeback sooner rather than later. On devices these days, it's pretty pointless to let a lot of dirty data build up before starting to clean it. Uncached writeback starts when the copy is done, rather than many seconds later when some writeback thread decides the pressure is either too high, or it's been dirty too long. - Don't leave things in cache that aren't going to get reused, only to get pruned later at the point where you need more memory for the cache anyway. > My understanding is that the performance issue this patch is trying to > address originates from the page cache being filled up, causing the current > IO to wait for write-back or reclamation, correct? From this perspective, > it seems that this would be suitable for applications that issue a large > amount of IO in a short period of time, and it might not be dependent on > the speed of the backing device? On the read side, if you're not going to be reusing the data you read, uncached is appropriate. Ditto on the write side, if you're just flushing out a bunch of data with limted reuse, may as well prune the cache regions as soon as the write is done, rather than let some kind of background activity do that when memory becomes scarce.