Matthew Wilcox <willy@xxxxxxxxxxxxx> writes: > On Fri, Apr 26, 2024 at 10:55:23PM +0530, Ritesh Harjani wrote: >> Ritesh Harjani (IBM) <ritesh.list@xxxxxxxxx> writes: >> >> > "Darrick J. Wong" <djwong@xxxxxxxxxx> writes: >> > >> >> On Thu, Apr 25, 2024 at 06:58:51PM +0530, Ritesh Harjani (IBM) wrote: >> >>> This patch optimizes the data access patterns for filesystems with >> >>> indirect block mapping by implementing BH_Boundary handling within >> >>> iomap. >> >>> >> >>> Currently the bios for reads within iomap are only submitted at >> >>> 2 places - >> >>> 1. If we cannot merge the new req. with previous bio, only then we >> >>> submit the previous bio. >> >>> 2. Submit the bio at the end of the entire read processing. >> >>> >> >>> This means for filesystems with indirect block mapping, we call into >> >>> ->iomap_begin() again w/o submitting the previous bios. That causes >> >>> unoptimized data access patterns for blocks which are of BH_Boundary type. >> >>> >> >>> For e.g. consider the file mapping >> >>> logical block(4k) physical block(4k) >> >>> 0-11 1000-1011 >> >>> 12-15 1013-1016 >> >>> >> >>> In above physical block 1012 is an indirect metadata block which has the >> >>> mapping information for next set of indirect blocks (1013-1016). >> >>> With iomap buffered reads for reading 1st 16 logical blocks of a file >> >>> (0-15), we get below I/O pattern >> >>> - submit a bio for 1012 >> >>> - complete the bio for 1012 >> >>> - submit a bio for 1000-1011 >> >>> - submit a bio for 1013-1016 >> >>> - complete the bios for 1000-1011 >> >>> - complete the bios for 1013-1016 >> >>> >> >>> So as we can see, above is an non-optimal I/O access pattern and also we >> >>> get 3 bio completions instead of 2. >> >>> >> >>> This patch changes this behavior by doing submit_bio() if there are any >> >>> bios already processed, before calling ->iomap_begin() again. >> >>> That means if there are any blocks which are already processed, gets >> >>> submitted for I/O earlier and then within ->iomap_begin(), if we get a >> >>> request for reading an indirect metadata block, then block layer can merge >> >>> those bios with the already submitted read request to reduce the no. of bio >> >>> completions. >> >>> >> >>> Now, for bs < ps or for large folios, this patch requires proper handling >> >>> of "ifs->read_bytes_pending". In that we first set ifs->read_bytes_pending >> >>> to folio_size. Then handle all the cases where we need to subtract >> >>> ifs->read_bytes_pending either during the submission side >> >>> (if we don't need to submit any I/O - for e.g. for uptodate sub blocks), >> >>> or during an I/O error, or at the completion of an I/O. >> >>> >> >>> Here is the ftrace output of iomap and block layer with ext2 iomap >> >>> conversion patches - >> >>> >> >>> root# filefrag -b512 -v /mnt1/test/f1 >> >>> Filesystem type is: ef53 >> >>> Filesystem cylinder groups approximately 32 >> >>> File size of /mnt1/test/f1 is 65536 (128 blocks of 512 bytes) >> >>> ext: logical_offset: physical_offset: length: expected: flags: >> >>> 0: 0.. 95: 98304.. 98399: 96: merged >> >>> 1: 96.. 127: 98408.. 98439: 32: 98400: last,merged,eof >> >>> /mnt1/test/f1: 2 extents found >> >>> >> >>> root# #This reads 4 blocks starting from lblk 10, 11, 12, 13 >> >>> root# xfs_io -c "pread -b$((4*4096)) $((10*4096)) $((4*4096))" /mnt1/test/f1 >> >>> >> >>> w/o this patch - (indirect block is submitted before and does not get merged, resulting in 3 bios completion) >> >>> xfs_io-907 [002] ..... 185.608791: iomap_readahead: dev 8:16 ino 0xc nr_pages 4 >> >>> xfs_io-907 [002] ..... 185.608819: iomap_iter: dev 8:16 ino 0xc pos 0xa000 length 0x4000 processed 0 flags (0x0) ops 0xffffffff82242160 caller iomap_readahead+0x9d/0x2c0 >> >>> xfs_io-907 [002] ..... 185.608823: iomap_iter_dstmap: dev 8:16 ino 0xc bdev 8:16 addr 0x300a000 offset 0xa000 length 0x2000 type MAPPED flags MERGED >> >>> xfs_io-907 [002] ..... 185.608831: iomap_iter: dev 8:16 ino 0xc pos 0xa000 length 0x2000 processed 8192 flags (0x0) ops 0xffffffff82242160 caller iomap_readahead+0x1e1/0x2c0 >> >>> xfs_io-907 [002] ..... 185.608859: block_bio_queue: 8,16 R 98400 + 8 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.608865: block_getrq: 8,16 R 98400 + 8 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.608867: block_io_start: 8,16 R 4096 () 98400 + 8 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.608869: block_plug: [xfs_io] >> >>> xfs_io-907 [002] ..... 185.608872: block_unplug: [xfs_io] 1 >> >>> xfs_io-907 [002] ..... 185.608874: block_rq_insert: 8,16 R 4096 () 98400 + 8 [xfs_io] >> >>> kworker/2:1H-198 [002] ..... 185.608908: block_rq_issue: 8,16 R 4096 () 98400 + 8 [kworker/2:1H] >> >>> <idle>-0 [002] d.h2. 185.609579: block_rq_complete: 8,16 R () 98400 + 8 [0] >> >>> <idle>-0 [002] dNh2. 185.609631: block_io_done: 8,16 R 0 () 98400 + 0 [swapper/2] >> >>> xfs_io-907 [002] ..... 185.609694: iomap_iter_dstmap: dev 8:16 ino 0xc bdev 8:16 addr 0x300d000 offset 0xc000 length 0x2000 type MAPPED flags MERGED >> >>> xfs_io-907 [002] ..... 185.609704: block_bio_queue: 8,16 RA 98384 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609718: block_getrq: 8,16 RA 98384 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609721: block_io_start: 8,16 RA 8192 () 98384 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609726: block_plug: [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609735: iomap_iter: dev 8:16 ino 0xc pos 0xc000 length 0x2000 processed 8192 flags (0x0) ops 0xffffffff82242160 caller iomap_readahead+0x1e1/0x2c0 >> >>> xfs_io-907 [002] ..... 185.609736: block_bio_queue: 8,16 RA 98408 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609740: block_getrq: 8,16 RA 98408 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609741: block_io_start: 8,16 RA 8192 () 98408 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609756: block_rq_issue: 8,16 RA 8192 () 98408 + 16 [xfs_io] >> >>> xfs_io-907 [002] ..... 185.609769: block_rq_issue: 8,16 RA 8192 () 98384 + 16 [xfs_io] >> >>> <idle>-0 [002] d.H2. 185.610280: block_rq_complete: 8,16 RA () 98408 + 16 [0] >> >>> <idle>-0 [002] d.H2. 185.610289: block_io_done: 8,16 RA 0 () 98408 + 0 [swapper/2] >> >>> <idle>-0 [002] d.H2. 185.610292: block_rq_complete: 8,16 RA () 98384 + 16 [0] >> >>> <idle>-0 [002] dNH2. 185.610301: block_io_done: 8,16 RA 0 () 98384 + 0 [swapper/2] >> >> >> >> Could this be shortened to ... the iomap calls and >> >> block_bio_queue/backmerge? It's a bit difficult to see the point you're >> >> getting at with all the other noise. >> > >> > I will remove this log and move it to cover letter and will just extend >> > the simple example I considered before in this commit message, >> > to show the difference with and w/o patch. >> > >> >> >> >> I think you're trying to say that the access pattern here is 98400 -> >> >> 98408 -> 98384, which is not sequential? >> >> >> > >> > it's (98400,8 ==> metadata block) -> (98384,16 == lblk 10 & 11) -> (98408,16 ==> lblk 12 & 13) >> > ... w/o the patch >> > >> >>> v/s with the patch - (optimzed I/O access pattern and bio gets merged resulting in only 2 bios completion) >> >>> xfs_io-944 [005] ..... 99.926187: iomap_readahead: dev 8:16 ino 0xc nr_pages 4 >> >>> xfs_io-944 [005] ..... 99.926208: iomap_iter: dev 8:16 ino 0xc pos 0xa000 length 0x4000 processed 0 flags (0x0) ops 0xffffffff82242160 caller iomap_readahead+0x9d/0x2c0 >> >>> xfs_io-944 [005] ..... 99.926211: iomap_iter_dstmap: dev 8:16 ino 0xc bdev 8:16 addr 0x300a000 offset 0xa000 length 0x2000 type MAPPED flags MERGED >> >>> xfs_io-944 [005] ..... 99.926222: block_bio_queue: 8,16 RA 98384 + 16 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926232: block_getrq: 8,16 RA 98384 + 16 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926233: block_io_start: 8,16 RA 8192 () 98384 + 16 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926234: block_plug: [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926235: iomap_iter: dev 8:16 ino 0xc pos 0xa000 length 0x2000 processed 8192 flags (0x0) ops 0xffffffff82242160 caller iomap_readahead+0x1f9/0x2c0 >> >>> xfs_io-944 [005] ..... 99.926261: block_bio_queue: 8,16 R 98400 + 8 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926266: block_bio_backmerge: 8,16 R 98400 + 8 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926271: block_unplug: [xfs_io] 1 >> >>> xfs_io-944 [005] ..... 99.926272: block_rq_insert: 8,16 RA 12288 () 98384 + 24 [xfs_io] >> >>> kworker/5:1H-234 [005] ..... 99.926314: block_rq_issue: 8,16 RA 12288 () 98384 + 24 [kworker/5:1H] >> >>> <idle>-0 [005] d.h2. 99.926905: block_rq_complete: 8,16 RA () 98384 + 24 [0] >> >>> <idle>-0 [005] dNh2. 99.926931: block_io_done: 8,16 RA 0 () 98384 + 0 [swapper/5] >> >>> xfs_io-944 [005] ..... 99.926971: iomap_iter_dstmap: dev 8:16 ino 0xc bdev 8:16 addr 0x300d000 offset 0xc000 length 0x2000 type MAPPED flags MERGED >> >>> xfs_io-944 [005] ..... 99.926981: block_bio_queue: 8,16 RA 98408 + 16 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926989: block_getrq: 8,16 RA 98408 + 16 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926989: block_io_start: 8,16 RA 8192 () 98408 + 16 [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926991: block_plug: [xfs_io] >> >>> xfs_io-944 [005] ..... 99.926993: iomap_iter: dev 8:16 ino 0xc pos 0xc000 length 0x2000 processed 8192 flags (0x0) ops 0xffffffff82242160 caller iomap_readahead+0x1f9/0x2c0 >> >>> xfs_io-944 [005] ..... 99.927001: block_rq_issue: 8,16 RA 8192 () 98408 + 16 [xfs_io] >> >>> <idle>-0 [005] d.h2. 99.927397: block_rq_complete: 8,16 RA () 98408 + 16 [0] >> >>> <idle>-0 [005] dNh2. 99.927414: block_io_done: 8,16 RA 0 () 98408 + 0 [swapper/5] >> >>> >> >>> Suggested-by: Matthew Wilcox <willy@xxxxxxxxxxxxx> >> >>> Signed-off-by: Ritesh Harjani (IBM) <ritesh.list@xxxxxxxxx> >> >>> cc: Ojaswin Mujoo <ojaswin@xxxxxxxxxxxxx> >> >>> --- >> >>> fs/iomap/buffered-io.c | 112 +++++++++++++++++++++++++++++++---------- >> >>> 1 file changed, 85 insertions(+), 27 deletions(-) >> >>> >> >>> diff --git a/fs/iomap/buffered-io.c b/fs/iomap/buffered-io.c >> >>> index 0a4269095ae2..a1d50086a3f5 100644 >> >>> --- a/fs/iomap/buffered-io.c >> >>> +++ b/fs/iomap/buffered-io.c >> >>> @@ -30,7 +30,7 @@ typedef int (*iomap_punch_t)(struct inode *inode, loff_t offset, loff_t length); >> >>> */ >> >>> struct iomap_folio_state { >> >>> spinlock_t state_lock; >> >>> - unsigned int read_bytes_pending; >> >>> + size_t read_bytes_pending; >> >>> atomic_t write_bytes_pending; >> >>> >> >>> /* >> >>> @@ -380,6 +380,7 @@ static loff_t iomap_readpage_iter(const struct iomap_iter *iter, >> >>> loff_t orig_pos = pos; >> >>> size_t poff, plen; >> >>> sector_t sector; >> >>> + bool rbp_finished = false; >> >> >> >> What is "rbp"? My assembly programmer brain says x64 frame pointer, but >> >> that's clearly wrong here. Maybe I'm confused... >> >> >> > >> > rbp == read_bytes_pending ;) >> > >> >>> if (iomap->type == IOMAP_INLINE) >> >>> return iomap_read_inline_data(iter, folio); >> >>> @@ -387,21 +388,39 @@ static loff_t iomap_readpage_iter(const struct iomap_iter *iter, >> >>> /* zero post-eof blocks as the page may be mapped */ >> >>> ifs = ifs_alloc(iter->inode, folio, iter->flags); >> >>> iomap_adjust_read_range(iter->inode, folio, &pos, length, &poff, &plen); >> >>> + >> >>> + if (ifs) { >> >>> + loff_t to_read = min_t(loff_t, iter->len - offset, >> >>> + folio_size(folio) - offset_in_folio(folio, orig_pos)); >> >>> + size_t padjust; >> >>> + >> >>> + spin_lock_irq(&ifs->state_lock); >> >>> + if (!ifs->read_bytes_pending) >> >>> + ifs->read_bytes_pending = to_read; >> >>> + padjust = pos - orig_pos; >> >>> + ifs->read_bytes_pending -= padjust; >> >>> + if (!ifs->read_bytes_pending) >> >>> + rbp_finished = true; >> >>> + spin_unlock_irq(&ifs->state_lock); >> >>> + } >> >>> + >> >>> if (plen == 0) >> >>> goto done; >> >>> >> >>> if (iomap_block_needs_zeroing(iter, pos)) { >> >>> + if (ifs) { >> >>> + spin_lock_irq(&ifs->state_lock); >> >>> + ifs->read_bytes_pending -= plen; >> >>> + if (!ifs->read_bytes_pending) >> >>> + rbp_finished = true; >> >>> + spin_unlock_irq(&ifs->state_lock); >> >>> + } >> >>> folio_zero_range(folio, poff, plen); >> >>> iomap_set_range_uptodate(folio, poff, plen); >> >>> goto done; >> >>> } >> >>> >> >>> ctx->cur_folio_in_bio = true; >> >>> - if (ifs) { >> >>> - spin_lock_irq(&ifs->state_lock); >> >>> - ifs->read_bytes_pending += plen; >> >>> - spin_unlock_irq(&ifs->state_lock); >> >>> - } >> >>> >> >>> sector = iomap_sector(iomap, pos); >> >>> if (!ctx->bio || >> >>> @@ -435,6 +454,14 @@ static loff_t iomap_readpage_iter(const struct iomap_iter *iter, >> >>> } >> >>> >> >>> done: >> >>> + /* >> >>> + * If there is no bio prepared and if rbp is finished and >> >>> + * this was the last offset within this folio then mark >> >>> + * cur_folio_in_bio to false. >> >>> + */ >> >>> + if (!ctx->bio && rbp_finished && >> >>> + offset_in_folio(folio, pos + plen) == 0) >> >>> + ctx->cur_folio_in_bio = false; >> >> >> >> ...yes, I think I am confused. When would ctx->bio be NULL but >> >> cur_folio_in_bio is true? >> > >> > Previously we had the bio submitted and so we make it null, but we still >> > have ctx->cur_folio & ctx->cur_folio_in_bio to true, since we haven't >> > completely processed the folio. >> > >> >> >> >> I /think/ what you're doing here is using read_bytes_pending to figure >> >> out if you've processed the folio up to the end of the mapping? But >> >> then you submit the bio unconditionally below for each readpage_iter >> >> call? >> >> >> > >> > yes, that's right. >> > >> >> Why not add an IOMAP_BOUNDARY flag that means "I will have to do some IO >> >> if you call ->iomap_begin again"? Then if we get to this point in >> >> readpage_iter with a ctx->bio, we can submit the bio, clear >> >> cur_folio_in_bio, and return? And then you don't need this machinery? >> > >> > TBH, I initially didn't think the approach taken in the patch would >> > require such careful handling of r_b_p. It was because of all of this >> > corner cases when we don't need to read the update blocks and/or in case >> > of an error we need to ensure we reduce r_b_p carefully so that we could >> > unlock the folio and when extent spans beyond i_size. >> > >> > So it's all about how do we know if we could unlock the folio and that it's >> > corresponding blocks/mapping has been all processed or submitted for >> > I/O. >> > >> > Assume we have a folio which spans over multiple extents. In such a >> > case, >> > -> we process a bio for 1st extent, >> > -> then we go back to iomap_iter() to get new extent mapping, >> > -> We now increment the r_b_p with this new plen to be processed. >> > -> We then submit the previous bio, since this new mapping couldn't be >> > merged due to discontinuous extents. >> > So by first incrementing the r_b_p before doing submit_bio(), we don't >> > unlock the folio at bio completion. >> > >> > Maybe, it would be helpful if we have an easy mechanism to keep some state >> > from the time of submit_bio() till the bio completion to know that the >> > corresponding folio is still being processed and it shouldn't be >> > unlocked. >> > -> This currently is what we are doing by making r_b_p to the value of >> > folio_size() and then carefully reducing r_b_p for all the cases I >> > mentioned above. >> > >> > Let me think if adding a IOMAP_BH_BOUNDARY flag could be helpful or not. >> > Say if we have a pagesize of 64k that means all first 16 blocks belongs >> > to same page. So even with IOMAP_BH_BOUNDARY flag the problem that still >> > remains is that, even if we submit the bio at block 11 (bh_boundary >> > block), how will the bio completion side know that the folio is not >> > completely processed and so we shouldn't unlock the folio? >> >> Maybe one way could be if we could add another state flag to ifs for >> BH_BOUNDARY block and read that at the bio completion. >> We can then also let the completion side know if it should unlock the >> folio or whether it still needs processing at the submission side. > > The approach I suggested was to initialise read_bytes_pending to > folio_size() at the start. Then subtract off blocksize for each > uptodate block, whether you find it already uptodate, or as the > completion handler runs. > > Is there a reason that doesn't work? That is what this patch series does right. The current patch does work as far as my testing goes. For e.g. This is what initializes the r_b_p for the first time when ifs->r_b_p is 0. + loff_t to_read = min_t(loff_t, iter->len - offset, + folio_size(folio) - offset_in_folio(folio, orig_pos)); <..> + if (!ifs->read_bytes_pending) + ifs->read_bytes_pending = to_read; Then this is where we subtract r_b_p for blocks which are uptodate. + padjust = pos - orig_pos; + ifs->read_bytes_pending -= padjust; This is when we adjust r_b_p when we directly zero the folio. if (iomap_block_needs_zeroing(iter, pos)) { + if (ifs) { + spin_lock_irq(&ifs->state_lock); + ifs->read_bytes_pending -= plen; + if (!ifs->read_bytes_pending) + rbp_finished = true; + spin_unlock_irq(&ifs->state_lock); + } But as you see this requires surgery throughout read paths. What if we add a state flag to ifs only for BH_BOUNDARY. Maybe that could result in a more simplified approach? Because all we require is to know whether the folio should be unlocked or not at the time of completion. Do you think we should try that part or you think the current approach looks ok? -ritesh