On Mon, Aug 31, 2020 at 12:01:07PM +0800, Ming Lei wrote: > On Tue, Aug 25, 2020 at 10:49:17AM -0400, Brian Foster wrote: > > cc Ming > > > > On Tue, Aug 25, 2020 at 10:42:03AM +1000, Dave Chinner wrote: > > > On Mon, Aug 24, 2020 at 11:48:41AM -0400, Brian Foster wrote: > > > > On Mon, Aug 24, 2020 at 04:04:17PM +0100, Christoph Hellwig wrote: > > > > > On Mon, Aug 24, 2020 at 10:28:23AM -0400, Brian Foster wrote: > > > > > > Do I understand the current code (__bio_try_merge_page() -> > > > > > > page_is_mergeable()) correctly in that we're checking for physical page > > > > > > contiguity and not necessarily requiring a new bio_vec per physical > > > > > > page? > > > > > > > > > > > > > > > Yes. > > > > > > > > > > > > > Ok. I also realize now that this occurs on a kernel without commit > > > > 07173c3ec276 ("block: enable multipage bvecs"). That is probably a > > > > contributing factor, but it's not clear to me whether it's feasible to > > > > backport whatever supporting infrastructure is required for that > > > > mechanism to work (I suspect not). > > > > > > > > > > With regard to Dave's earlier point around seeing excessively sized bio > > > > > > chains.. If I set up a large memory box with high dirty mem ratios and > > > > > > do contiguous buffered overwrites over a 32GB range followed by fsync, I > > > > > > can see upwards of 1GB per bio and thus chains on the order of 32+ bios > > > > > > for the entire write. If I play games with how the buffered overwrite is > > > > > > submitted (i.e., in reverse) however, then I can occasionally reproduce > > > > > > a ~32GB chain of ~32k bios, which I think is what leads to problems in > > > > > > I/O completion on some systems. Granted, I don't reproduce soft lockup > > > > > > issues on my system with that behavior, so perhaps there's more to that > > > > > > particular issue. > > > > > > > > > > > > Regardless, it seems reasonable to me to at least have a conservative > > > > > > limit on the length of an ioend bio chain. Would anybody object to > > > > > > iomap_ioend growing a chain counter and perhaps forcing into a new ioend > > > > > > if we chain something like more than 1k bios at once? > > > > > > > > > > So what exactly is the problem of processing a long chain in the > > > > > workqueue vs multiple small chains? Maybe we need a cond_resched() > > > > > here and there, but I don't see how we'd substantially change behavior. > > > > > > > > > > > > > The immediate problem is a watchdog lockup detection in bio completion: > > > > > > > > NMI watchdog: Watchdog detected hard LOCKUP on cpu 25 > > > > > > > > This effectively lands at the following segment of iomap_finish_ioend(): > > > > > > > > ... > > > > /* walk each page on bio, ending page IO on them */ > > > > bio_for_each_segment_all(bv, bio, iter_all) > > > > iomap_finish_page_writeback(inode, bv->bv_page, error); > > > > > > > > I suppose we could add a cond_resched(), but is that safe directly > > > > inside of a ->bi_end_io() handler? Another option could be to dump large > > > > chains into the completion workqueue, but we may still need to track the > > > > length to do that. Thoughts? > > > > > > We have ioend completion merging that will run the compeltion once > > > for all the pending ioend completions on that inode. IOWs, we do not > > > need to build huge chains at submission time to batch up completions > > > efficiently. However, huge bio chains at submission time do cause > > > issues with writeback fairness, pinning GBs of ram as unreclaimable > > > for seconds because they are queued for completion while we are > > > still submitting the bio chain and submission is being throttled by > > > the block layer writeback throttle, etc. Not to mention the latency > > > of stable pages in a situation like this - a mmap() write fault > > > could stall for many seconds waiting for a huge bio chain to finish > > > submission and run completion processing even when the IO for the > > > given page we faulted on was completed before the page fault > > > occurred... > > > > > > Hence I think we really do need to cap the length of the bio > > > chains here so that we start completing and ending page writeback on > > > large writeback ranges long before the writeback code finishes > > > submitting the range it was asked to write back. > > > > > > > Ming pointed out separately that limiting the bio chain itself might not > > be enough because with multipage bvecs, we can effectively capture the > > same number of pages in much fewer bios. Given that, what do you think > > about something like the patch below to limit ioend size? This > > effectively limits the number of pages per ioend regardless of whether > > in-core state results in a small chain of dense bios or a large chain of > > smaller bios, without requiring any new explicit page count tracking. > > Hello Brian, > > This patch looks fine. > > However, I am wondering why iomap has to chain bios in one ioend, and why not > submit each bio in usual way just like what fs/direct-io.c does? Then each bio > can complete the pages in its own .bi_end_io(). > I think it's mainly for efficiency and code simplicity reasons. The ioend describes a contiguous range of blocks with the same io type (written, unwritten, append, etc.), so whatever post-completion action might be required for a particular ioend (i.e. unwritten conversion) shouldn't execute until I/O completes on the entire range. I believe this goes back to XFS commit 0e51a8e191db ("xfs: optimize bio handling in the buffer writeback path"), which basically reimplemented similar, custom ioend behavior to rely on bio chains and was eventually lifted from XFS into iomap. Brian > > thanks, > Ming >