Message ID | 20211211022115.1547617-1-mfo@canonical.com (mailing list archive) |
---|---|
State | New, archived |
Headers | show |
Series | mm: fix race between MADV_FREE reclaim and blkdev direct IO read | expand |
On Fri, Dec 10, 2021 at 11:21:15PM -0300, Mauricio Faria de Oliveira wrote: > Problem: > ======= > > Userspace might read the zero-page instead of actual data from a > direct IO read on a block device if the buffers have been called > madvise(MADV_FREE) on earlier (this is discussed below) due to a > race between page reclaim on MADV_FREE and blkdev direct IO read. > > Race condition: > ============== > > During page reclaim, the MADV_FREE page check in try_to_unmap_one() > checks if the page is not dirty, then discards its PTE (vs remap it > back if the page is dirty). > > However, after try_to_unmap_one() returns to shrink_page_list(), it > might keep the page _anyway_ if page_ref_freeze() fails (it expects > a single page ref from the isolation). > > Well, blkdev_direct_IO() gets references for all pages, and on READ > operations it sets them dirty later. > > So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more > later) for direct IO read from block devices and page reclaim runs > during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() > but BEFORE it sets pages dirty, that situation happens. > > The direct IO read eventually completes. Now, when userspace reads > the buffers, the PTE is no longer there and the page fault handler > do_anonymous_page() services that with the zero-page, NOT the data! > > A synthetic reproducer is provided. > > Page faults: > =========== > > The data read from the block device probably won't generate faults > due to DMA (no MMU) but even in the case it wouldn't use DMA, that > happens on different virtual addresses (not user-mapped addresses) > because `struct bio_vec` stores `struct page` to figure addresses > out (which are different from/unrelated to user-mapped addresses) > for the data read. > > Thus userspace reads (to user-mapped addresses) still fault, then > do_anonymous_page() gets another `struct page` that would address/ > map to other memory than the `struct page` used by `struct bio_vec` > for the read (which runs correctly as the page wasn't freed due to > page_ref_freeze(), and is reclaimed later) -- but even if the page > addresses matched, that handler maps the zero-page in the PTE, not > that page's memory (on read faults.) > > If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue > doesn't happen, because that faults-in all pages as writeable, so > do_anonymous_page() sets up a new page/rmap/PTE, and that is used > by direct IO. The userspace reads don't fault as the PTE is there > (thus zero-page is not used.) > > Solution: > ======== > > One solution is to check for the expected page reference count in > try_to_unmap_one() too, which should be exactly two: one from the > isolation (checked by shrink_page_list()), and the other from the > rmap (dropped by the discard: label). If that doesn't match, then > remap the PTE back, just like page dirty does. > > The new check in try_to_unmap_one() should be safe in races with > bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, > as it's done under the PTE lock. The fast path doesn't take that > lock but it checks the PTE has changed, then drops the reference > and leaves the page for the slow path (which does take that lock). > > - try_to_unmap_one() > - page_vma_mapped_walk() > - map_pte() # see pte_offset_map_lock(): > pte_offset_map() > spin_lock() > - page_ref_count() # new check > - page_vma_mapped_walk_done() # see pte_unmap_unlock(): > pte_unmap() > spin_unlock() > > - bio_iov_iter_get_pages() > - __bio_iov_iter_get_pages() > - iov_iter_get_pages() > - get_user_pages_fast() > - internal_get_user_pages_fast() > > # fast path > - lockless_pages_from_mm() > - gup_{pgd,p4d,pud,pmd,pte}_range() > ptep = pte_offset_map() # not _lock() > pte = ptep_get_lockless(ptep) > page = pte_page(pte) > try_grab_compound_head(page) # get ref > if (pte_val(pte) != pte_val(*ptep)) > put_compound_head(page) # put ref > # leave page for slow path > # slow path > - __gup_longterm_unlocked() > - get_user_pages_unlocked() > - __get_user_pages_locked() > - __get_user_pages() > - follow_{page,p4d,pud,pmd}_mask() > - follow_page_pte() > ptep = pte_offset_map_lock() > pte = *ptep > page = vm_normal_page(pte) > try_grab_page(page) # get ref > pte_unmap_unlock() > > Regarding transparent hugepages, that number shouldn't change, as > MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() > (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) > thus should reach shrink_page_list() -> split_huge_page_to_list() > before try_to_unmap[_one](), so it deals with normal pages only. > > (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() > happens, which it should not or be rare, the page refcount is not > two, as the head page counts tail pages, and tail pages have zero. > That also prevents checking the head `page` then incorrectly call > page_remove_rmap(subpage) for a tail page, that isn't even in the > shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), > as it might happen today in this unlikely scenario.) > > MADV_FREE'd buffers: > =================== > > So, back to the "if MADV_FREE pages are used as buffers" note. > The case is arguable, and subject to multiple interpretations. > > The madvise(2) manual page on the MADV_FREE advice value says: > - 'After a successful MADV_FREE ... data will be lost when > the kernel frees the pages.' > - 'the free operation will be canceled if the caller writes > into the page' / 'subsequent writes ... will succeed and > then [the] kernel cannot free those dirtied pages' > - 'If there is no subsequent write, the kernel can free the > pages at any time.' > > Thoughts, questions, considerations... > - Since the kernel didn't actually free the page (page_ref_freeze() > failed), should the data not have been lost? (on userspace read.) > - Should writes performed by the direct IO read be able to cancel > the free operation? > - Should the direct IO read be considered as 'the caller' too, > as it's been requested by 'the caller'? > - Should the bio technique to dirty pages on return to userspace > (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) > be considered in another/special way here? > - Should an upcoming write from a previously requested direct IO > read be considered as a subsequent write, so the kernel should > not free the pages? (as it's known at the time of page reclaim.) > > Technically, the last point would seem a reasonable consideration > and balance, as the madvise(2) manual page apparently (and fairly) > seem to assume that 'writes' are memory access from the userspace > process (not explicitly considering writes from the kernel or its > corner cases; again, fairly).. plus the kernel fix implementation > for the corner case of the largely 'non-atomic write' encompassed > by a direct IO read operation, is relatively simple; and it helps. > > Reproducer: > ========== > > @ test.c (simplified, but works) > > #define _GNU_SOURCE > #include <fcntl.h> > #include <stdio.h> > #include <unistd.h> > #include <sys/mman.h> > > int main() { > int fd, i; > char *buf; > > fd = open(DEV, O_RDONLY | O_DIRECT); > > buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, > MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); > > for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) > buf[i] = 1; // init to non-zero > > madvise(buf, BUF_SIZE, MADV_FREE); > > read(fd, buf, BUF_SIZE); > > for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) > printf("%p: 0x%x\n", &buf[i], buf[i]); > > return 0; > } > > @ block/fops.c (formerly fs/block_dev.c) > > +#include <linux/swap.h> > ... > ... __blkdev_direct_IO[_simple](...) > { > ... > + if (!strcmp(current->comm, "good")) > + shrink_all_memory(ULONG_MAX); > + > ret = bio_iov_iter_get_pages(...); > + > + if (!strcmp(current->comm, "bad")) > + shrink_all_memory(ULONG_MAX); > ... > } > > @ shell > > # yes | dd of=test.img bs=1k count=16 > # DEV=$(losetup -f --show test.img) > # gcc -DDEV=\"$DEV\" -DBUF_SIZE=16384 -DPAGE_SIZE=4096 test.c -o test > > # od -tx1 $DEV > 0000000 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a > * > 0040000 > > # mv test good > # ./good > 0x7f1509206000: 0x79 > 0x7f1509207000: 0x79 > 0x7f1509208000: 0x79 > 0x7f1509209000: 0x79 > > # mv good bad > # ./bad > 0x7fd87272f000: 0x0 > 0x7fd872730000: 0x0 > 0x7fd872731000: 0x0 > 0x7fd872732000: 0x0 > > Ceph/TCMalloc: > ============= > > For documentation purposes, the use case driving the analysis/fix > is Ceph on Ubuntu 18.04, as the TCMalloc library there still uses > MADV_FREE to release unused memory to the system from the mmap'ed > page heap (might be committed back/used again; it's not munmap'ed.) > - PageHeap::DecommitSpan() -> TCMalloc_SystemRelease() -> madvise() > - PageHeap::CommitSpan() -> TCMalloc_SystemCommit() -> do nothing. > > Note: TCMalloc switched back to MADV_DONTNEED a few commits after > the release in Ubuntu 18.04 (google-perftools/gperftools 2.5), so > the issue just 'disappeared' on Ceph on later Ubuntu releases but > is still present in the kernel, and can be hit by other use cases. > > The observed issue seems to be the old Ceph bug #22464 [1], where > checksum mismatches are observed (and instrumentation with buffer > dumps shows zero-pages read from mmap'ed/MADV_FREE'd page ranges). > > The issue in Ceph was reasonably deemed a kernel bug (comment #50) > and mostly worked around with a retry mechanism, but other parts > of Ceph could still hit that (rocksdb). Anyway, it's less likely > to be hit again as TCMalloc switched out of MADV_FREE by default. > > (Some kernel versions/reports from the Ceph bug, and relation with > the MADV_FREE introduction/changes; TCMalloc versions not checked.) > - 4.4 good > - 4.5 (madv_free: introduction) > - 4.9 bad > - 4.10 good? maybe a swapless system > - 4.12 (madv_free: no longer free instantly on swapless systems) > - 4.13 bad > > [1] https://tracker.ceph.com/issues/22464 > > Thanks: > ====== > > Several people contributed to analysis/discussions/tests/reproducers > in the first stages when drilling down on ceph/tcmalloc/linux kernel: > > - Dan Hill <daniel.hill@canonical.com> > - Dan Streetman <dan.streetman@canonical.com> > - Dongdong Tao <dongdong.tao@canonical.com> > - Gavin Guo <gavin.guo@canonical.com> > - Gerald Yang <gerald.yang@canonical.com> > - Heitor Alves de Siqueira <halves@canonical.com> > - Ioanna Alifieraki <ioanna-maria.alifieraki@canonical.com> > - Jay Vosburgh <jay.vosburgh@canonical.com> > - Matthew Ruffell <matthew.ruffell@canonical.com> > - Ponnuvel Palaniyappan <ponnuvel.palaniyappan@canonical.com> > > Signed-off-by: Mauricio Faria de Oliveira <mfo@canonical.com> > --- Hi Mauricio, Thanks for catching the bug. There is some comment before I would look the problem in more detail. Please see below. > > P.S.: sorry for the very long commit message; hopefully it might > provide enough context and considerations on the problem and fix > approach to help reviewers. Tested on v5.16-rc4. > > mm/rmap.c | 13 ++++++++++++- > mm/vmscan.c | 2 +- > 2 files changed, 13 insertions(+), 2 deletions(-) > > diff --git a/mm/rmap.c b/mm/rmap.c > index 163ac4e6bcee..f04151aae03b 100644 > --- a/mm/rmap.c > +++ b/mm/rmap.c > @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, > > /* MADV_FREE page check */ > if (!PageSwapBacked(page)) { > - if (!PageDirty(page)) { > + int refcount = page_ref_count(page); > + > + /* > + * The only page refs must be from the isolation > + * (checked by the caller shrink_page_list() too) > + * and the (single) rmap (dropped by discard:). > + * > + * Check the reference count before dirty flag > + * with memory barrier; see __remove_mapping(). > + */ > + smp_rmb(); > + if (refcount == 2 && !PageDirty(page)) { A madv_free marked page could be mapped at several processes so it wouldn't be refcount two all the time, I think. Shouldn't we check it with page_mapcount with page_refcount? page_ref_count(page) - 1 > page_mapcount(page) > /* Invalidate as we cleared the pte */ > mmu_notifier_invalidate_range(mm, > address, address + PAGE_SIZE); > diff --git a/mm/vmscan.c b/mm/vmscan.c > index fb9584641ac7..c1ea4e14f510 100644 > --- a/mm/vmscan.c > +++ b/mm/vmscan.c > @@ -1688,7 +1688,7 @@ static unsigned int shrink_page_list(struct list_head *page_list, > mapping = page_mapping(page); > } > } else if (unlikely(PageTransHuge(page))) { > - /* Split file THP */ > + /* Split file/lazyfree THP */ > if (split_huge_page_to_list(page, page_list)) > goto keep_locked; > } > -- > 2.32.0 >
Minchan Kim <minchan@kernel.org> writes: > On Fri, Dec 10, 2021 at 11:21:15PM -0300, Mauricio Faria de Oliveira wrote: >> Problem: >> ======= >> >> Userspace might read the zero-page instead of actual data from a >> direct IO read on a block device if the buffers have been called >> madvise(MADV_FREE) on earlier (this is discussed below) due to a >> race between page reclaim on MADV_FREE and blkdev direct IO read. >> >> Race condition: >> ============== >> >> During page reclaim, the MADV_FREE page check in try_to_unmap_one() >> checks if the page is not dirty, then discards its PTE (vs remap it >> back if the page is dirty). >> >> However, after try_to_unmap_one() returns to shrink_page_list(), it >> might keep the page _anyway_ if page_ref_freeze() fails (it expects >> a single page ref from the isolation). >> >> Well, blkdev_direct_IO() gets references for all pages, and on READ >> operations it sets them dirty later. >> >> So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more >> later) for direct IO read from block devices and page reclaim runs >> during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() >> but BEFORE it sets pages dirty, that situation happens. >> >> The direct IO read eventually completes. Now, when userspace reads >> the buffers, the PTE is no longer there and the page fault handler >> do_anonymous_page() services that with the zero-page, NOT the data! >> >> A synthetic reproducer is provided. >> >> Page faults: >> =========== >> >> The data read from the block device probably won't generate faults >> due to DMA (no MMU) but even in the case it wouldn't use DMA, that >> happens on different virtual addresses (not user-mapped addresses) >> because `struct bio_vec` stores `struct page` to figure addresses >> out (which are different from/unrelated to user-mapped addresses) >> for the data read. >> >> Thus userspace reads (to user-mapped addresses) still fault, then >> do_anonymous_page() gets another `struct page` that would address/ >> map to other memory than the `struct page` used by `struct bio_vec` >> for the read (which runs correctly as the page wasn't freed due to >> page_ref_freeze(), and is reclaimed later) -- but even if the page >> addresses matched, that handler maps the zero-page in the PTE, not >> that page's memory (on read faults.) >> >> If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue >> doesn't happen, because that faults-in all pages as writeable, so >> do_anonymous_page() sets up a new page/rmap/PTE, and that is used >> by direct IO. The userspace reads don't fault as the PTE is there >> (thus zero-page is not used.) >> >> Solution: >> ======== >> >> One solution is to check for the expected page reference count in >> try_to_unmap_one() too, which should be exactly two: one from the >> isolation (checked by shrink_page_list()), and the other from the >> rmap (dropped by the discard: label). If that doesn't match, then >> remap the PTE back, just like page dirty does. >> >> The new check in try_to_unmap_one() should be safe in races with >> bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, >> as it's done under the PTE lock. The fast path doesn't take that >> lock but it checks the PTE has changed, then drops the reference >> and leaves the page for the slow path (which does take that lock). >> >> - try_to_unmap_one() >> - page_vma_mapped_walk() >> - map_pte() # see pte_offset_map_lock(): >> pte_offset_map() >> spin_lock() >> - page_ref_count() # new check >> - page_vma_mapped_walk_done() # see pte_unmap_unlock(): >> pte_unmap() >> spin_unlock() >> >> - bio_iov_iter_get_pages() >> - __bio_iov_iter_get_pages() >> - iov_iter_get_pages() >> - get_user_pages_fast() >> - internal_get_user_pages_fast() >> >> # fast path >> - lockless_pages_from_mm() >> - gup_{pgd,p4d,pud,pmd,pte}_range() >> ptep = pte_offset_map() # not _lock() >> pte = ptep_get_lockless(ptep) >> page = pte_page(pte) >> try_grab_compound_head(page) # get ref >> if (pte_val(pte) != pte_val(*ptep)) >> put_compound_head(page) # put ref >> # leave page for slow path >> # slow path >> - __gup_longterm_unlocked() >> - get_user_pages_unlocked() >> - __get_user_pages_locked() >> - __get_user_pages() >> - follow_{page,p4d,pud,pmd}_mask() >> - follow_page_pte() >> ptep = pte_offset_map_lock() >> pte = *ptep >> page = vm_normal_page(pte) >> try_grab_page(page) # get ref >> pte_unmap_unlock() >> >> Regarding transparent hugepages, that number shouldn't change, as >> MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() >> (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) >> thus should reach shrink_page_list() -> split_huge_page_to_list() >> before try_to_unmap[_one](), so it deals with normal pages only. >> >> (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() >> happens, which it should not or be rare, the page refcount is not >> two, as the head page counts tail pages, and tail pages have zero. >> That also prevents checking the head `page` then incorrectly call >> page_remove_rmap(subpage) for a tail page, that isn't even in the >> shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), >> as it might happen today in this unlikely scenario.) >> >> MADV_FREE'd buffers: >> =================== >> >> So, back to the "if MADV_FREE pages are used as buffers" note. >> The case is arguable, and subject to multiple interpretations. >> >> The madvise(2) manual page on the MADV_FREE advice value says: >> - 'After a successful MADV_FREE ... data will be lost when >> the kernel frees the pages.' >> - 'the free operation will be canceled if the caller writes >> into the page' / 'subsequent writes ... will succeed and >> then [the] kernel cannot free those dirtied pages' >> - 'If there is no subsequent write, the kernel can free the >> pages at any time.' >> >> Thoughts, questions, considerations... >> - Since the kernel didn't actually free the page (page_ref_freeze() >> failed), should the data not have been lost? (on userspace read.) >> - Should writes performed by the direct IO read be able to cancel >> the free operation? >> - Should the direct IO read be considered as 'the caller' too, >> as it's been requested by 'the caller'? >> - Should the bio technique to dirty pages on return to userspace >> (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) >> be considered in another/special way here? >> - Should an upcoming write from a previously requested direct IO >> read be considered as a subsequent write, so the kernel should >> not free the pages? (as it's known at the time of page reclaim.) >> >> Technically, the last point would seem a reasonable consideration >> and balance, as the madvise(2) manual page apparently (and fairly) >> seem to assume that 'writes' are memory access from the userspace >> process (not explicitly considering writes from the kernel or its >> corner cases; again, fairly).. plus the kernel fix implementation >> for the corner case of the largely 'non-atomic write' encompassed >> by a direct IO read operation, is relatively simple; and it helps. >> >> Reproducer: >> ========== >> >> @ test.c (simplified, but works) >> >> #define _GNU_SOURCE >> #include <fcntl.h> >> #include <stdio.h> >> #include <unistd.h> >> #include <sys/mman.h> >> >> int main() { >> int fd, i; >> char *buf; >> >> fd = open(DEV, O_RDONLY | O_DIRECT); >> >> buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, >> MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); >> >> for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) >> buf[i] = 1; // init to non-zero >> >> madvise(buf, BUF_SIZE, MADV_FREE); >> >> read(fd, buf, BUF_SIZE); >> >> for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) >> printf("%p: 0x%x\n", &buf[i], buf[i]); >> >> return 0; >> } >> >> @ block/fops.c (formerly fs/block_dev.c) >> >> +#include <linux/swap.h> >> ... >> ... __blkdev_direct_IO[_simple](...) >> { >> ... >> + if (!strcmp(current->comm, "good")) >> + shrink_all_memory(ULONG_MAX); >> + >> ret = bio_iov_iter_get_pages(...); >> + >> + if (!strcmp(current->comm, "bad")) >> + shrink_all_memory(ULONG_MAX); >> ... >> } >> >> @ shell >> >> # yes | dd of=test.img bs=1k count=16 >> # DEV=$(losetup -f --show test.img) >> # gcc -DDEV=\"$DEV\" -DBUF_SIZE=16384 -DPAGE_SIZE=4096 test.c -o test >> >> # od -tx1 $DEV >> 0000000 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a >> * >> 0040000 >> >> # mv test good >> # ./good >> 0x7f1509206000: 0x79 >> 0x7f1509207000: 0x79 >> 0x7f1509208000: 0x79 >> 0x7f1509209000: 0x79 >> >> # mv good bad >> # ./bad >> 0x7fd87272f000: 0x0 >> 0x7fd872730000: 0x0 >> 0x7fd872731000: 0x0 >> 0x7fd872732000: 0x0 >> >> Ceph/TCMalloc: >> ============= >> >> For documentation purposes, the use case driving the analysis/fix >> is Ceph on Ubuntu 18.04, as the TCMalloc library there still uses >> MADV_FREE to release unused memory to the system from the mmap'ed >> page heap (might be committed back/used again; it's not munmap'ed.) >> - PageHeap::DecommitSpan() -> TCMalloc_SystemRelease() -> madvise() >> - PageHeap::CommitSpan() -> TCMalloc_SystemCommit() -> do nothing. >> >> Note: TCMalloc switched back to MADV_DONTNEED a few commits after >> the release in Ubuntu 18.04 (google-perftools/gperftools 2.5), so >> the issue just 'disappeared' on Ceph on later Ubuntu releases but >> is still present in the kernel, and can be hit by other use cases. >> >> The observed issue seems to be the old Ceph bug #22464 [1], where >> checksum mismatches are observed (and instrumentation with buffer >> dumps shows zero-pages read from mmap'ed/MADV_FREE'd page ranges). >> >> The issue in Ceph was reasonably deemed a kernel bug (comment #50) >> and mostly worked around with a retry mechanism, but other parts >> of Ceph could still hit that (rocksdb). Anyway, it's less likely >> to be hit again as TCMalloc switched out of MADV_FREE by default. >> >> (Some kernel versions/reports from the Ceph bug, and relation with >> the MADV_FREE introduction/changes; TCMalloc versions not checked.) >> - 4.4 good >> - 4.5 (madv_free: introduction) >> - 4.9 bad >> - 4.10 good? maybe a swapless system >> - 4.12 (madv_free: no longer free instantly on swapless systems) >> - 4.13 bad >> >> [1] https://tracker.ceph.com/issues/22464 >> >> Thanks: >> ====== >> >> Several people contributed to analysis/discussions/tests/reproducers >> in the first stages when drilling down on ceph/tcmalloc/linux kernel: >> >> - Dan Hill <daniel.hill@canonical.com> >> - Dan Streetman <dan.streetman@canonical.com> >> - Dongdong Tao <dongdong.tao@canonical.com> >> - Gavin Guo <gavin.guo@canonical.com> >> - Gerald Yang <gerald.yang@canonical.com> >> - Heitor Alves de Siqueira <halves@canonical.com> >> - Ioanna Alifieraki <ioanna-maria.alifieraki@canonical.com> >> - Jay Vosburgh <jay.vosburgh@canonical.com> >> - Matthew Ruffell <matthew.ruffell@canonical.com> >> - Ponnuvel Palaniyappan <ponnuvel.palaniyappan@canonical.com> >> >> Signed-off-by: Mauricio Faria de Oliveira <mfo@canonical.com> >> --- > > Hi Mauricio, > > Thanks for catching the bug. There is some comment before I would > look the problem in more detail. Please see below. > >> >> P.S.: sorry for the very long commit message; hopefully it might >> provide enough context and considerations on the problem and fix >> approach to help reviewers. Tested on v5.16-rc4. >> >> mm/rmap.c | 13 ++++++++++++- >> mm/vmscan.c | 2 +- >> 2 files changed, 13 insertions(+), 2 deletions(-) >> >> diff --git a/mm/rmap.c b/mm/rmap.c >> index 163ac4e6bcee..f04151aae03b 100644 >> --- a/mm/rmap.c >> +++ b/mm/rmap.c >> @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, >> >> /* MADV_FREE page check */ >> if (!PageSwapBacked(page)) { >> - if (!PageDirty(page)) { >> + int refcount = page_ref_count(page); >> + >> + /* >> + * The only page refs must be from the isolation >> + * (checked by the caller shrink_page_list() too) >> + * and the (single) rmap (dropped by discard:). >> + * >> + * Check the reference count before dirty flag >> + * with memory barrier; see __remove_mapping(). >> + */ >> + smp_rmb(); >> + if (refcount == 2 && !PageDirty(page)) { > > A madv_free marked page could be mapped at several processes so > it wouldn't be refcount two all the time, I think. > Shouldn't we check it with page_mapcount with page_refcount? > > page_ref_count(page) - 1 > page_mapcount(page) > And should we consider page_count() too in madvise_free_pte_range()? That is, if the page has been used by GUP, we needn't to make its PTE clean? Best Regards, Huang, Ying > >> /* Invalidate as we cleared the pte */ >> mmu_notifier_invalidate_range(mm, >> address, address + PAGE_SIZE); >> diff --git a/mm/vmscan.c b/mm/vmscan.c >> index fb9584641ac7..c1ea4e14f510 100644 >> --- a/mm/vmscan.c >> +++ b/mm/vmscan.c >> @@ -1688,7 +1688,7 @@ static unsigned int shrink_page_list(struct list_head *page_list, >> mapping = page_mapping(page); >> } >> } else if (unlikely(PageTransHuge(page))) { >> - /* Split file THP */ >> + /* Split file/lazyfree THP */ >> if (split_huge_page_to_list(page, page_list)) >> goto keep_locked; >> } >> -- >> 2.32.0 >>
On Fri, Dec 10, 2021 at 6:22 PM Mauricio Faria de Oliveira <mfo@canonical.com> wrote: > > Problem: > ======= > > Userspace might read the zero-page instead of actual data from a > direct IO read on a block device if the buffers have been called > madvise(MADV_FREE) on earlier (this is discussed below) due to a > race between page reclaim on MADV_FREE and blkdev direct IO read. > > Race condition: > ============== > > During page reclaim, the MADV_FREE page check in try_to_unmap_one() > checks if the page is not dirty, then discards its PTE (vs remap it > back if the page is dirty). > > However, after try_to_unmap_one() returns to shrink_page_list(), it > might keep the page _anyway_ if page_ref_freeze() fails (it expects > a single page ref from the isolation). > > Well, blkdev_direct_IO() gets references for all pages, and on READ > operations it sets them dirty later. > > So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more > later) for direct IO read from block devices and page reclaim runs > during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() > but BEFORE it sets pages dirty, that situation happens. > > The direct IO read eventually completes. Now, when userspace reads > the buffers, the PTE is no longer there and the page fault handler > do_anonymous_page() services that with the zero-page, NOT the data! > > A synthetic reproducer is provided. > > Page faults: > =========== > > The data read from the block device probably won't generate faults > due to DMA (no MMU) but even in the case it wouldn't use DMA, that > happens on different virtual addresses (not user-mapped addresses) > because `struct bio_vec` stores `struct page` to figure addresses > out (which are different from/unrelated to user-mapped addresses) > for the data read. > > Thus userspace reads (to user-mapped addresses) still fault, then > do_anonymous_page() gets another `struct page` that would address/ > map to other memory than the `struct page` used by `struct bio_vec` > for the read (which runs correctly as the page wasn't freed due to > page_ref_freeze(), and is reclaimed later) -- but even if the page > addresses matched, that handler maps the zero-page in the PTE, not > that page's memory (on read faults.) > > If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue > doesn't happen, because that faults-in all pages as writeable, so > do_anonymous_page() sets up a new page/rmap/PTE, and that is used > by direct IO. The userspace reads don't fault as the PTE is there > (thus zero-page is not used.) > > Solution: > ======== > > One solution is to check for the expected page reference count in > try_to_unmap_one() too, which should be exactly two: one from the > isolation (checked by shrink_page_list()), and the other from the > rmap (dropped by the discard: label). If that doesn't match, then > remap the PTE back, just like page dirty does. > > The new check in try_to_unmap_one() should be safe in races with > bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, > as it's done under the PTE lock. The fast path doesn't take that > lock but it checks the PTE has changed, then drops the reference > and leaves the page for the slow path (which does take that lock). > > - try_to_unmap_one() > - page_vma_mapped_walk() > - map_pte() # see pte_offset_map_lock(): > pte_offset_map() > spin_lock() > - page_ref_count() # new check > - page_vma_mapped_walk_done() # see pte_unmap_unlock(): > pte_unmap() > spin_unlock() > > - bio_iov_iter_get_pages() > - __bio_iov_iter_get_pages() > - iov_iter_get_pages() > - get_user_pages_fast() > - internal_get_user_pages_fast() > > # fast path > - lockless_pages_from_mm() > - gup_{pgd,p4d,pud,pmd,pte}_range() > ptep = pte_offset_map() # not _lock() > pte = ptep_get_lockless(ptep) > page = pte_page(pte) > try_grab_compound_head(page) # get ref > if (pte_val(pte) != pte_val(*ptep)) > put_compound_head(page) # put ref > # leave page for slow path > # slow path > - __gup_longterm_unlocked() > - get_user_pages_unlocked() > - __get_user_pages_locked() > - __get_user_pages() > - follow_{page,p4d,pud,pmd}_mask() > - follow_page_pte() > ptep = pte_offset_map_lock() > pte = *ptep > page = vm_normal_page(pte) > try_grab_page(page) # get ref > pte_unmap_unlock() > > Regarding transparent hugepages, that number shouldn't change, as > MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() > (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) > thus should reach shrink_page_list() -> split_huge_page_to_list() > before try_to_unmap[_one](), so it deals with normal pages only. > > (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() > happens, which it should not or be rare, the page refcount is not > two, as the head page counts tail pages, and tail pages have zero. > That also prevents checking the head `page` then incorrectly call > page_remove_rmap(subpage) for a tail page, that isn't even in the > shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), > as it might happen today in this unlikely scenario.) > > MADV_FREE'd buffers: > =================== > > So, back to the "if MADV_FREE pages are used as buffers" note. > The case is arguable, and subject to multiple interpretations. > > The madvise(2) manual page on the MADV_FREE advice value says: > - 'After a successful MADV_FREE ... data will be lost when > the kernel frees the pages.' > - 'the free operation will be canceled if the caller writes > into the page' / 'subsequent writes ... will succeed and > then [the] kernel cannot free those dirtied pages' > - 'If there is no subsequent write, the kernel can free the > pages at any time.' > > Thoughts, questions, considerations... > - Since the kernel didn't actually free the page (page_ref_freeze() > failed), should the data not have been lost? (on userspace read.) > - Should writes performed by the direct IO read be able to cancel > the free operation? > - Should the direct IO read be considered as 'the caller' too, > as it's been requested by 'the caller'? > - Should the bio technique to dirty pages on return to userspace > (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) > be considered in another/special way here? > - Should an upcoming write from a previously requested direct IO > read be considered as a subsequent write, so the kernel should > not free the pages? (as it's known at the time of page reclaim.) > > Technically, the last point would seem a reasonable consideration > and balance, as the madvise(2) manual page apparently (and fairly) > seem to assume that 'writes' are memory access from the userspace > process (not explicitly considering writes from the kernel or its > corner cases; again, fairly).. plus the kernel fix implementation > for the corner case of the largely 'non-atomic write' encompassed > by a direct IO read operation, is relatively simple; and it helps. > > Reproducer: > ========== > > @ test.c (simplified, but works) > > #define _GNU_SOURCE > #include <fcntl.h> > #include <stdio.h> > #include <unistd.h> > #include <sys/mman.h> > > int main() { > int fd, i; > char *buf; > > fd = open(DEV, O_RDONLY | O_DIRECT); > > buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, > MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); > > for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) > buf[i] = 1; // init to non-zero > > madvise(buf, BUF_SIZE, MADV_FREE); IIUC, you are expecting to get the old data after MADV_FREE? TBH, you should not expect so at all after MADV_FREE since those pages may get freed at any time. > > read(fd, buf, BUF_SIZE); > > for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) > printf("%p: 0x%x\n", &buf[i], buf[i]); > > return 0; > } > > @ block/fops.c (formerly fs/block_dev.c) > > +#include <linux/swap.h> > ... > ... __blkdev_direct_IO[_simple](...) > { > ... > + if (!strcmp(current->comm, "good")) > + shrink_all_memory(ULONG_MAX); > + > ret = bio_iov_iter_get_pages(...); > + > + if (!strcmp(current->comm, "bad")) > + shrink_all_memory(ULONG_MAX); > ... > } > > @ shell > > # yes | dd of=test.img bs=1k count=16 > # DEV=$(losetup -f --show test.img) > # gcc -DDEV=\"$DEV\" -DBUF_SIZE=16384 -DPAGE_SIZE=4096 test.c -o test > > # od -tx1 $DEV > 0000000 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a > * > 0040000 > > # mv test good > # ./good > 0x7f1509206000: 0x79 > 0x7f1509207000: 0x79 > 0x7f1509208000: 0x79 > 0x7f1509209000: 0x79 > > # mv good bad > # ./bad > 0x7fd87272f000: 0x0 > 0x7fd872730000: 0x0 > 0x7fd872731000: 0x0 > 0x7fd872732000: 0x0 > > Ceph/TCMalloc: > ============= > > For documentation purposes, the use case driving the analysis/fix > is Ceph on Ubuntu 18.04, as the TCMalloc library there still uses > MADV_FREE to release unused memory to the system from the mmap'ed > page heap (might be committed back/used again; it's not munmap'ed.) > - PageHeap::DecommitSpan() -> TCMalloc_SystemRelease() -> madvise() > - PageHeap::CommitSpan() -> TCMalloc_SystemCommit() -> do nothing. > > Note: TCMalloc switched back to MADV_DONTNEED a few commits after > the release in Ubuntu 18.04 (google-perftools/gperftools 2.5), so > the issue just 'disappeared' on Ceph on later Ubuntu releases but > is still present in the kernel, and can be hit by other use cases. > > The observed issue seems to be the old Ceph bug #22464 [1], where > checksum mismatches are observed (and instrumentation with buffer > dumps shows zero-pages read from mmap'ed/MADV_FREE'd page ranges). > > The issue in Ceph was reasonably deemed a kernel bug (comment #50) > and mostly worked around with a retry mechanism, but other parts > of Ceph could still hit that (rocksdb). Anyway, it's less likely > to be hit again as TCMalloc switched out of MADV_FREE by default. > > (Some kernel versions/reports from the Ceph bug, and relation with > the MADV_FREE introduction/changes; TCMalloc versions not checked.) > - 4.4 good > - 4.5 (madv_free: introduction) > - 4.9 bad > - 4.10 good? maybe a swapless system > - 4.12 (madv_free: no longer free instantly on swapless systems) > - 4.13 bad > > [1] https://tracker.ceph.com/issues/22464 > > Thanks: > ====== > > Several people contributed to analysis/discussions/tests/reproducers > in the first stages when drilling down on ceph/tcmalloc/linux kernel: > > - Dan Hill <daniel.hill@canonical.com> > - Dan Streetman <dan.streetman@canonical.com> > - Dongdong Tao <dongdong.tao@canonical.com> > - Gavin Guo <gavin.guo@canonical.com> > - Gerald Yang <gerald.yang@canonical.com> > - Heitor Alves de Siqueira <halves@canonical.com> > - Ioanna Alifieraki <ioanna-maria.alifieraki@canonical.com> > - Jay Vosburgh <jay.vosburgh@canonical.com> > - Matthew Ruffell <matthew.ruffell@canonical.com> > - Ponnuvel Palaniyappan <ponnuvel.palaniyappan@canonical.com> > > Signed-off-by: Mauricio Faria de Oliveira <mfo@canonical.com> > --- > > P.S.: sorry for the very long commit message; hopefully it might > provide enough context and considerations on the problem and fix > approach to help reviewers. Tested on v5.16-rc4. > > mm/rmap.c | 13 ++++++++++++- > mm/vmscan.c | 2 +- > 2 files changed, 13 insertions(+), 2 deletions(-) > > diff --git a/mm/rmap.c b/mm/rmap.c > index 163ac4e6bcee..f04151aae03b 100644 > --- a/mm/rmap.c > +++ b/mm/rmap.c > @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, > > /* MADV_FREE page check */ > if (!PageSwapBacked(page)) { > - if (!PageDirty(page)) { > + int refcount = page_ref_count(page); > + > + /* > + * The only page refs must be from the isolation > + * (checked by the caller shrink_page_list() too) > + * and the (single) rmap (dropped by discard:). > + * > + * Check the reference count before dirty flag > + * with memory barrier; see __remove_mapping(). > + */ > + smp_rmb(); > + if (refcount == 2 && !PageDirty(page)) { > /* Invalidate as we cleared the pte */ > mmu_notifier_invalidate_range(mm, > address, address + PAGE_SIZE); > diff --git a/mm/vmscan.c b/mm/vmscan.c > index fb9584641ac7..c1ea4e14f510 100644 > --- a/mm/vmscan.c > +++ b/mm/vmscan.c > @@ -1688,7 +1688,7 @@ static unsigned int shrink_page_list(struct list_head *page_list, > mapping = page_mapping(page); > } > } else if (unlikely(PageTransHuge(page))) { > - /* Split file THP */ > + /* Split file/lazyfree THP */ > if (split_huge_page_to_list(page, page_list)) > goto keep_locked; > } > -- > 2.32.0 > >
On Thu, Dec 16, 2021 at 3:17 PM Minchan Kim <minchan@kernel.org> wrote: ... > Hi Mauricio, > > Thanks for catching the bug. There is some comment before I would > look the problem in more detail. Please see below. > Hey! Thanks for looking into this. Sorry for the delay; I've been out a few weeks. > > diff --git a/mm/rmap.c b/mm/rmap.c > > index 163ac4e6bcee..f04151aae03b 100644 > > --- a/mm/rmap.c > > +++ b/mm/rmap.c > > @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, > > > > /* MADV_FREE page check */ > > if (!PageSwapBacked(page)) { > > - if (!PageDirty(page)) { > > + int refcount = page_ref_count(page); > > + > > + /* > > + * The only page refs must be from the isolation > > + * (checked by the caller shrink_page_list() too) > > + * and the (single) rmap (dropped by discard:). > > + * > > + * Check the reference count before dirty flag > > + * with memory barrier; see __remove_mapping(). > > + */ > > + smp_rmb(); > > + if (refcount == 2 && !PageDirty(page)) { > > A madv_free marked page could be mapped at several processes so > it wouldn't be refcount two all the time, I think. > Shouldn't we check it with page_mapcount with page_refcount? > > page_ref_count(page) - 1 > page_mapcount(page) > It's the other way around, isn't it? The madvise(MADV_FREE) call only clears the page dirty flag if page_mapcount() == 1 (ie not mapped by more processes). @ madvise_free_pte_range() /* * If page is shared with others, we couldn't clear * PG_dirty of the page. */ if (page_mapcount(page) != 1) { unlock_page(page); continue; } ... ClearPageDirty(page); unlock_page(page); If that's right, the refcount of 2 should be OK (one from the isolation, another one from the single map/one process.) Does that make sense? I might be missing something. Thanks!
On Thu, Dec 16, 2021 at 11:10 PM Huang, Ying <ying.huang@intel.com> wrote: > > Minchan Kim <minchan@kernel.org> writes: ... > > > > A madv_free marked page could be mapped at several processes so > > it wouldn't be refcount two all the time, I think. > > Shouldn't we check it with page_mapcount with page_refcount? > > > > page_ref_count(page) - 1 > page_mapcount(page) > > > > And should we consider page_count() too in madvise_free_pte_range()? > That is, if the page has been used by GUP, we needn't to make its PTE > clean? Hey, thanks for reviewing! That might not be sufficient time-wise, I guess, because the page can be used by GUP after the madvise() call (e.g., this case), thus checking for it during the call wouldn't catch it -- this may apply to other cases too, where there's no guarantee/ordering between both operations. cheers,
On Fri, Dec 17, 2021 at 3:51 PM Yang Shi <shy828301@gmail.com> wrote: > > On Fri, Dec 10, 2021 at 6:22 PM Mauricio Faria de Oliveira > <mfo@canonical.com> wrote: ... > > MADV_FREE'd buffers: > > =================== > > > > So, back to the "if MADV_FREE pages are used as buffers" note. > > The case is arguable, and subject to multiple interpretations. > > > > The madvise(2) manual page on the MADV_FREE advice value says: > > - 'After a successful MADV_FREE ... data will be lost when > > the kernel frees the pages.' > > - 'the free operation will be canceled if the caller writes > > into the page' / 'subsequent writes ... will succeed and > > then [the] kernel cannot free those dirtied pages' > > - 'If there is no subsequent write, the kernel can free the > > pages at any time.' > > > > Thoughts, questions, considerations... > > - Since the kernel didn't actually free the page (page_ref_freeze() > > failed), should the data not have been lost? (on userspace read.) > > - Should writes performed by the direct IO read be able to cancel > > the free operation? > > - Should the direct IO read be considered as 'the caller' too, > > as it's been requested by 'the caller'? > > - Should the bio technique to dirty pages on return to userspace > > (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) > > be considered in another/special way here? > > - Should an upcoming write from a previously requested direct IO > > read be considered as a subsequent write, so the kernel should > > not free the pages? (as it's known at the time of page reclaim.) > > > > Technically, the last point would seem a reasonable consideration > > and balance, as the madvise(2) manual page apparently (and fairly) > > seem to assume that 'writes' are memory access from the userspace > > process (not explicitly considering writes from the kernel or its > > corner cases; again, fairly).. plus the kernel fix implementation > > for the corner case of the largely 'non-atomic write' encompassed > > by a direct IO read operation, is relatively simple; and it helps. ... > IIUC, you are expecting to get the old data after MADV_FREE? TBH, you > should not expect so at all after MADV_FREE since those pages may get > freed at any time. Hey, thanks for checking this. Correct; the discussion behind this is covered in the text above. It's indeed arguable, but the fix makes the behavior more consistent for the case of a direct IO read (rather than potentially returning zero-pages a bit randomly.) cheers,
On Tue, Jan 04, 2022 at 08:46:17AM -0300, Mauricio Faria de Oliveira wrote: > On Thu, Dec 16, 2021 at 3:17 PM Minchan Kim <minchan@kernel.org> wrote: > ... > > Hi Mauricio, > > > > Thanks for catching the bug. There is some comment before I would > > look the problem in more detail. Please see below. > > > > Hey! Thanks for looking into this. Sorry for the delay; I've been out > a few weeks. > > > > diff --git a/mm/rmap.c b/mm/rmap.c > > > index 163ac4e6bcee..f04151aae03b 100644 > > > --- a/mm/rmap.c > > > +++ b/mm/rmap.c > > > @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, > > > > > > /* MADV_FREE page check */ > > > if (!PageSwapBacked(page)) { > > > - if (!PageDirty(page)) { > > > + int refcount = page_ref_count(page); > > > + > > > + /* > > > + * The only page refs must be from the isolation > > > + * (checked by the caller shrink_page_list() too) > > > + * and the (single) rmap (dropped by discard:). > > > + * > > > + * Check the reference count before dirty flag > > > + * with memory barrier; see __remove_mapping(). > > > + */ > > > + smp_rmb(); > > > + if (refcount == 2 && !PageDirty(page)) { > > > > A madv_free marked page could be mapped at several processes so > > it wouldn't be refcount two all the time, I think. > > Shouldn't we check it with page_mapcount with page_refcount? > > > > page_ref_count(page) - 1 > page_mapcount(page) > > > > It's the other way around, isn't it? The madvise(MADV_FREE) call only clears > the page dirty flag if page_mapcount() == 1 (ie not mapped by more processes). > > @ madvise_free_pte_range() > > /* > * If page is shared with others, we couldn't clear > * PG_dirty of the page. > */ > if (page_mapcount(page) != 1) { > unlock_page(page); > continue; > } > ... > ClearPageDirty(page); > unlock_page(page); > > > If that's right, the refcount of 2 should be OK (one from the isolation, > another one from the single map/one process.) > > Does that make sense? I might be missing something. A child process could be forked from parent after madvise so the page mapcount of the hinted page could have elevated refcount.
On Tue, Jan 4, 2022 at 8:06 PM Minchan Kim <minchan@kernel.org> wrote: > > On Tue, Jan 04, 2022 at 08:46:17AM -0300, Mauricio Faria de Oliveira wrote: > > On Thu, Dec 16, 2021 at 3:17 PM Minchan Kim <minchan@kernel.org> wrote: > > ... > > > Hi Mauricio, > > > > > > Thanks for catching the bug. There is some comment before I would > > > look the problem in more detail. Please see below. > > > > > > > Hey! Thanks for looking into this. Sorry for the delay; I've been out > > a few weeks. > > > > > > diff --git a/mm/rmap.c b/mm/rmap.c > > > > index 163ac4e6bcee..f04151aae03b 100644 > > > > --- a/mm/rmap.c > > > > +++ b/mm/rmap.c > > > > @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, > > > > > > > > /* MADV_FREE page check */ > > > > if (!PageSwapBacked(page)) { > > > > - if (!PageDirty(page)) { > > > > + int refcount = page_ref_count(page); > > > > + > > > > + /* > > > > + * The only page refs must be from the isolation > > > > + * (checked by the caller shrink_page_list() too) > > > > + * and the (single) rmap (dropped by discard:). > > > > + * > > > > + * Check the reference count before dirty flag > > > > + * with memory barrier; see __remove_mapping(). > > > > + */ > > > > + smp_rmb(); > > > > + if (refcount == 2 && !PageDirty(page)) { > > > > > > A madv_free marked page could be mapped at several processes so > > > it wouldn't be refcount two all the time, I think. > > > Shouldn't we check it with page_mapcount with page_refcount? > > > > > > page_ref_count(page) - 1 > page_mapcount(page) > > > > > > > It's the other way around, isn't it? The madvise(MADV_FREE) call only clears > > the page dirty flag if page_mapcount() == 1 (ie not mapped by more processes). > > > > @ madvise_free_pte_range() > > > > /* > > * If page is shared with others, we couldn't clear > > * PG_dirty of the page. > > */ > > if (page_mapcount(page) != 1) { > > unlock_page(page); > > continue; > > } > > ... > > ClearPageDirty(page); > > unlock_page(page); > > > > > > If that's right, the refcount of 2 should be OK (one from the isolation, > > another one from the single map/one process.) > > > > Does that make sense? I might be missing something. > > A child process could be forked from parent after madvise so the page > mapcount of the hinted page could have elevated refcount. Thanks for clarifying. I was indeed missing something. :) I revisited your commit 854e9ed09ded ("mm: support madvise(MADV_FREE)"), and now realized that the restriction for map count == 1 is only for _cleaning_ the dirty flag, not for discarding the (clean) page mapping later on. """ To solve the problem, this patch clears PG_dirty if only the page is owned exclusively by current process when madvise is called because PG_dirty represents ptes's dirtiness in several processes so we could clear it only if we own it exclusively. """ I'll look at this tomorrow and submit a v2. Thanks!
Yang Shi <shy828301@gmail.com> writes: > On Fri, Dec 10, 2021 at 6:22 PM Mauricio Faria de Oliveira > <mfo@canonical.com> wrote: >> >> Problem: >> ======= >> >> Userspace might read the zero-page instead of actual data from a >> direct IO read on a block device if the buffers have been called >> madvise(MADV_FREE) on earlier (this is discussed below) due to a >> race between page reclaim on MADV_FREE and blkdev direct IO read. >> >> Race condition: >> ============== >> >> During page reclaim, the MADV_FREE page check in try_to_unmap_one() >> checks if the page is not dirty, then discards its PTE (vs remap it >> back if the page is dirty). >> >> However, after try_to_unmap_one() returns to shrink_page_list(), it >> might keep the page _anyway_ if page_ref_freeze() fails (it expects >> a single page ref from the isolation). >> >> Well, blkdev_direct_IO() gets references for all pages, and on READ >> operations it sets them dirty later. >> >> So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more >> later) for direct IO read from block devices and page reclaim runs >> during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() >> but BEFORE it sets pages dirty, that situation happens. >> >> The direct IO read eventually completes. Now, when userspace reads >> the buffers, the PTE is no longer there and the page fault handler >> do_anonymous_page() services that with the zero-page, NOT the data! >> >> A synthetic reproducer is provided. >> >> Page faults: >> =========== >> >> The data read from the block device probably won't generate faults >> due to DMA (no MMU) but even in the case it wouldn't use DMA, that >> happens on different virtual addresses (not user-mapped addresses) >> because `struct bio_vec` stores `struct page` to figure addresses >> out (which are different from/unrelated to user-mapped addresses) >> for the data read. >> >> Thus userspace reads (to user-mapped addresses) still fault, then >> do_anonymous_page() gets another `struct page` that would address/ >> map to other memory than the `struct page` used by `struct bio_vec` >> for the read (which runs correctly as the page wasn't freed due to >> page_ref_freeze(), and is reclaimed later) -- but even if the page >> addresses matched, that handler maps the zero-page in the PTE, not >> that page's memory (on read faults.) >> >> If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue >> doesn't happen, because that faults-in all pages as writeable, so >> do_anonymous_page() sets up a new page/rmap/PTE, and that is used >> by direct IO. The userspace reads don't fault as the PTE is there >> (thus zero-page is not used.) >> >> Solution: >> ======== >> >> One solution is to check for the expected page reference count in >> try_to_unmap_one() too, which should be exactly two: one from the >> isolation (checked by shrink_page_list()), and the other from the >> rmap (dropped by the discard: label). If that doesn't match, then >> remap the PTE back, just like page dirty does. >> >> The new check in try_to_unmap_one() should be safe in races with >> bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, >> as it's done under the PTE lock. The fast path doesn't take that >> lock but it checks the PTE has changed, then drops the reference >> and leaves the page for the slow path (which does take that lock). >> >> - try_to_unmap_one() >> - page_vma_mapped_walk() >> - map_pte() # see pte_offset_map_lock(): >> pte_offset_map() >> spin_lock() >> - page_ref_count() # new check >> - page_vma_mapped_walk_done() # see pte_unmap_unlock(): >> pte_unmap() >> spin_unlock() >> >> - bio_iov_iter_get_pages() >> - __bio_iov_iter_get_pages() >> - iov_iter_get_pages() >> - get_user_pages_fast() >> - internal_get_user_pages_fast() >> >> # fast path >> - lockless_pages_from_mm() >> - gup_{pgd,p4d,pud,pmd,pte}_range() >> ptep = pte_offset_map() # not _lock() >> pte = ptep_get_lockless(ptep) >> page = pte_page(pte) >> try_grab_compound_head(page) # get ref >> if (pte_val(pte) != pte_val(*ptep)) >> put_compound_head(page) # put ref >> # leave page for slow path >> # slow path >> - __gup_longterm_unlocked() >> - get_user_pages_unlocked() >> - __get_user_pages_locked() >> - __get_user_pages() >> - follow_{page,p4d,pud,pmd}_mask() >> - follow_page_pte() >> ptep = pte_offset_map_lock() >> pte = *ptep >> page = vm_normal_page(pte) >> try_grab_page(page) # get ref >> pte_unmap_unlock() >> >> Regarding transparent hugepages, that number shouldn't change, as >> MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() >> (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) >> thus should reach shrink_page_list() -> split_huge_page_to_list() >> before try_to_unmap[_one](), so it deals with normal pages only. >> >> (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() >> happens, which it should not or be rare, the page refcount is not >> two, as the head page counts tail pages, and tail pages have zero. >> That also prevents checking the head `page` then incorrectly call >> page_remove_rmap(subpage) for a tail page, that isn't even in the >> shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), >> as it might happen today in this unlikely scenario.) >> >> MADV_FREE'd buffers: >> =================== >> >> So, back to the "if MADV_FREE pages are used as buffers" note. >> The case is arguable, and subject to multiple interpretations. >> >> The madvise(2) manual page on the MADV_FREE advice value says: >> - 'After a successful MADV_FREE ... data will be lost when >> the kernel frees the pages.' >> - 'the free operation will be canceled if the caller writes >> into the page' / 'subsequent writes ... will succeed and >> then [the] kernel cannot free those dirtied pages' >> - 'If there is no subsequent write, the kernel can free the >> pages at any time.' >> >> Thoughts, questions, considerations... >> - Since the kernel didn't actually free the page (page_ref_freeze() >> failed), should the data not have been lost? (on userspace read.) >> - Should writes performed by the direct IO read be able to cancel >> the free operation? >> - Should the direct IO read be considered as 'the caller' too, >> as it's been requested by 'the caller'? >> - Should the bio technique to dirty pages on return to userspace >> (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) >> be considered in another/special way here? >> - Should an upcoming write from a previously requested direct IO >> read be considered as a subsequent write, so the kernel should >> not free the pages? (as it's known at the time of page reclaim.) >> >> Technically, the last point would seem a reasonable consideration >> and balance, as the madvise(2) manual page apparently (and fairly) >> seem to assume that 'writes' are memory access from the userspace >> process (not explicitly considering writes from the kernel or its >> corner cases; again, fairly).. plus the kernel fix implementation >> for the corner case of the largely 'non-atomic write' encompassed >> by a direct IO read operation, is relatively simple; and it helps. >> >> Reproducer: >> ========== >> >> @ test.c (simplified, but works) >> >> #define _GNU_SOURCE >> #include <fcntl.h> >> #include <stdio.h> >> #include <unistd.h> >> #include <sys/mman.h> >> >> int main() { >> int fd, i; >> char *buf; >> >> fd = open(DEV, O_RDONLY | O_DIRECT); >> >> buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, >> MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); >> >> for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) >> buf[i] = 1; // init to non-zero >> >> madvise(buf, BUF_SIZE, MADV_FREE); > > IIUC, you are expecting to get the old data after MADV_FREE? TBH, you > should not expect so at all after MADV_FREE since those pages may get > freed at any time. > Per my understanding, if direct IO reading is done after MADV_FREE, I think we want to get the new data instead of old data. Best Regards, Huang, Ying
On Tue, Jan 4, 2022 at 4:32 PM Huang, Ying <ying.huang@intel.com> wrote: > > Yang Shi <shy828301@gmail.com> writes: > > > On Fri, Dec 10, 2021 at 6:22 PM Mauricio Faria de Oliveira > > <mfo@canonical.com> wrote: > >> > >> Problem: > >> ======= > >> > >> Userspace might read the zero-page instead of actual data from a > >> direct IO read on a block device if the buffers have been called > >> madvise(MADV_FREE) on earlier (this is discussed below) due to a > >> race between page reclaim on MADV_FREE and blkdev direct IO read. > >> > >> Race condition: > >> ============== > >> > >> During page reclaim, the MADV_FREE page check in try_to_unmap_one() > >> checks if the page is not dirty, then discards its PTE (vs remap it > >> back if the page is dirty). > >> > >> However, after try_to_unmap_one() returns to shrink_page_list(), it > >> might keep the page _anyway_ if page_ref_freeze() fails (it expects > >> a single page ref from the isolation). > >> > >> Well, blkdev_direct_IO() gets references for all pages, and on READ > >> operations it sets them dirty later. > >> > >> So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more > >> later) for direct IO read from block devices and page reclaim runs > >> during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() > >> but BEFORE it sets pages dirty, that situation happens. > >> > >> The direct IO read eventually completes. Now, when userspace reads > >> the buffers, the PTE is no longer there and the page fault handler > >> do_anonymous_page() services that with the zero-page, NOT the data! > >> > >> A synthetic reproducer is provided. > >> > >> Page faults: > >> =========== > >> > >> The data read from the block device probably won't generate faults > >> due to DMA (no MMU) but even in the case it wouldn't use DMA, that > >> happens on different virtual addresses (not user-mapped addresses) > >> because `struct bio_vec` stores `struct page` to figure addresses > >> out (which are different from/unrelated to user-mapped addresses) > >> for the data read. > >> > >> Thus userspace reads (to user-mapped addresses) still fault, then > >> do_anonymous_page() gets another `struct page` that would address/ > >> map to other memory than the `struct page` used by `struct bio_vec` > >> for the read (which runs correctly as the page wasn't freed due to > >> page_ref_freeze(), and is reclaimed later) -- but even if the page > >> addresses matched, that handler maps the zero-page in the PTE, not > >> that page's memory (on read faults.) > >> > >> If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue > >> doesn't happen, because that faults-in all pages as writeable, so > >> do_anonymous_page() sets up a new page/rmap/PTE, and that is used > >> by direct IO. The userspace reads don't fault as the PTE is there > >> (thus zero-page is not used.) > >> > >> Solution: > >> ======== > >> > >> One solution is to check for the expected page reference count in > >> try_to_unmap_one() too, which should be exactly two: one from the > >> isolation (checked by shrink_page_list()), and the other from the > >> rmap (dropped by the discard: label). If that doesn't match, then > >> remap the PTE back, just like page dirty does. > >> > >> The new check in try_to_unmap_one() should be safe in races with > >> bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, > >> as it's done under the PTE lock. The fast path doesn't take that > >> lock but it checks the PTE has changed, then drops the reference > >> and leaves the page for the slow path (which does take that lock). > >> > >> - try_to_unmap_one() > >> - page_vma_mapped_walk() > >> - map_pte() # see pte_offset_map_lock(): > >> pte_offset_map() > >> spin_lock() > >> - page_ref_count() # new check > >> - page_vma_mapped_walk_done() # see pte_unmap_unlock(): > >> pte_unmap() > >> spin_unlock() > >> > >> - bio_iov_iter_get_pages() > >> - __bio_iov_iter_get_pages() > >> - iov_iter_get_pages() > >> - get_user_pages_fast() > >> - internal_get_user_pages_fast() > >> > >> # fast path > >> - lockless_pages_from_mm() > >> - gup_{pgd,p4d,pud,pmd,pte}_range() > >> ptep = pte_offset_map() # not _lock() > >> pte = ptep_get_lockless(ptep) > >> page = pte_page(pte) > >> try_grab_compound_head(page) # get ref > >> if (pte_val(pte) != pte_val(*ptep)) > >> put_compound_head(page) # put ref > >> # leave page for slow path > >> # slow path > >> - __gup_longterm_unlocked() > >> - get_user_pages_unlocked() > >> - __get_user_pages_locked() > >> - __get_user_pages() > >> - follow_{page,p4d,pud,pmd}_mask() > >> - follow_page_pte() > >> ptep = pte_offset_map_lock() > >> pte = *ptep > >> page = vm_normal_page(pte) > >> try_grab_page(page) # get ref > >> pte_unmap_unlock() > >> > >> Regarding transparent hugepages, that number shouldn't change, as > >> MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() > >> (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) > >> thus should reach shrink_page_list() -> split_huge_page_to_list() > >> before try_to_unmap[_one](), so it deals with normal pages only. > >> > >> (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() > >> happens, which it should not or be rare, the page refcount is not > >> two, as the head page counts tail pages, and tail pages have zero. > >> That also prevents checking the head `page` then incorrectly call > >> page_remove_rmap(subpage) for a tail page, that isn't even in the > >> shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), > >> as it might happen today in this unlikely scenario.) > >> > >> MADV_FREE'd buffers: > >> =================== > >> > >> So, back to the "if MADV_FREE pages are used as buffers" note. > >> The case is arguable, and subject to multiple interpretations. > >> > >> The madvise(2) manual page on the MADV_FREE advice value says: > >> - 'After a successful MADV_FREE ... data will be lost when > >> the kernel frees the pages.' > >> - 'the free operation will be canceled if the caller writes > >> into the page' / 'subsequent writes ... will succeed and > >> then [the] kernel cannot free those dirtied pages' > >> - 'If there is no subsequent write, the kernel can free the > >> pages at any time.' > >> > >> Thoughts, questions, considerations... > >> - Since the kernel didn't actually free the page (page_ref_freeze() > >> failed), should the data not have been lost? (on userspace read.) > >> - Should writes performed by the direct IO read be able to cancel > >> the free operation? > >> - Should the direct IO read be considered as 'the caller' too, > >> as it's been requested by 'the caller'? > >> - Should the bio technique to dirty pages on return to userspace > >> (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) > >> be considered in another/special way here? > >> - Should an upcoming write from a previously requested direct IO > >> read be considered as a subsequent write, so the kernel should > >> not free the pages? (as it's known at the time of page reclaim.) > >> > >> Technically, the last point would seem a reasonable consideration > >> and balance, as the madvise(2) manual page apparently (and fairly) > >> seem to assume that 'writes' are memory access from the userspace > >> process (not explicitly considering writes from the kernel or its > >> corner cases; again, fairly).. plus the kernel fix implementation > >> for the corner case of the largely 'non-atomic write' encompassed > >> by a direct IO read operation, is relatively simple; and it helps. > >> > >> Reproducer: > >> ========== > >> > >> @ test.c (simplified, but works) > >> > >> #define _GNU_SOURCE > >> #include <fcntl.h> > >> #include <stdio.h> > >> #include <unistd.h> > >> #include <sys/mman.h> > >> > >> int main() { > >> int fd, i; > >> char *buf; > >> > >> fd = open(DEV, O_RDONLY | O_DIRECT); > >> > >> buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, > >> MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); > >> > >> for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) > >> buf[i] = 1; // init to non-zero > >> > >> madvise(buf, BUF_SIZE, MADV_FREE); > > > > IIUC, you are expecting to get the old data after MADV_FREE? TBH, you > > should not expect so at all after MADV_FREE since those pages may get > > freed at any time. > > > > Per my understanding, if direct IO reading is done after MADV_FREE, I > think we want to get the new data instead of old data. Here "old data" means the data written by "buf[i] = 1;" before MADV_FREE in that test code. > > Best Regards, > Huang, Ying
Yang Shi <shy828301@gmail.com> writes: > On Tue, Jan 4, 2022 at 4:32 PM Huang, Ying <ying.huang@intel.com> wrote: >> >> Yang Shi <shy828301@gmail.com> writes: >> >> > On Fri, Dec 10, 2021 at 6:22 PM Mauricio Faria de Oliveira >> > <mfo@canonical.com> wrote: >> >> >> >> Problem: >> >> ======= >> >> >> >> Userspace might read the zero-page instead of actual data from a >> >> direct IO read on a block device if the buffers have been called >> >> madvise(MADV_FREE) on earlier (this is discussed below) due to a >> >> race between page reclaim on MADV_FREE and blkdev direct IO read. >> >> >> >> Race condition: >> >> ============== >> >> >> >> During page reclaim, the MADV_FREE page check in try_to_unmap_one() >> >> checks if the page is not dirty, then discards its PTE (vs remap it >> >> back if the page is dirty). >> >> >> >> However, after try_to_unmap_one() returns to shrink_page_list(), it >> >> might keep the page _anyway_ if page_ref_freeze() fails (it expects >> >> a single page ref from the isolation). >> >> >> >> Well, blkdev_direct_IO() gets references for all pages, and on READ >> >> operations it sets them dirty later. >> >> >> >> So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more >> >> later) for direct IO read from block devices and page reclaim runs >> >> during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() >> >> but BEFORE it sets pages dirty, that situation happens. >> >> >> >> The direct IO read eventually completes. Now, when userspace reads >> >> the buffers, the PTE is no longer there and the page fault handler >> >> do_anonymous_page() services that with the zero-page, NOT the data! >> >> >> >> A synthetic reproducer is provided. >> >> >> >> Page faults: >> >> =========== >> >> >> >> The data read from the block device probably won't generate faults >> >> due to DMA (no MMU) but even in the case it wouldn't use DMA, that >> >> happens on different virtual addresses (not user-mapped addresses) >> >> because `struct bio_vec` stores `struct page` to figure addresses >> >> out (which are different from/unrelated to user-mapped addresses) >> >> for the data read. >> >> >> >> Thus userspace reads (to user-mapped addresses) still fault, then >> >> do_anonymous_page() gets another `struct page` that would address/ >> >> map to other memory than the `struct page` used by `struct bio_vec` >> >> for the read (which runs correctly as the page wasn't freed due to >> >> page_ref_freeze(), and is reclaimed later) -- but even if the page >> >> addresses matched, that handler maps the zero-page in the PTE, not >> >> that page's memory (on read faults.) >> >> >> >> If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue >> >> doesn't happen, because that faults-in all pages as writeable, so >> >> do_anonymous_page() sets up a new page/rmap/PTE, and that is used >> >> by direct IO. The userspace reads don't fault as the PTE is there >> >> (thus zero-page is not used.) >> >> >> >> Solution: >> >> ======== >> >> >> >> One solution is to check for the expected page reference count in >> >> try_to_unmap_one() too, which should be exactly two: one from the >> >> isolation (checked by shrink_page_list()), and the other from the >> >> rmap (dropped by the discard: label). If that doesn't match, then >> >> remap the PTE back, just like page dirty does. >> >> >> >> The new check in try_to_unmap_one() should be safe in races with >> >> bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, >> >> as it's done under the PTE lock. The fast path doesn't take that >> >> lock but it checks the PTE has changed, then drops the reference >> >> and leaves the page for the slow path (which does take that lock). >> >> >> >> - try_to_unmap_one() >> >> - page_vma_mapped_walk() >> >> - map_pte() # see pte_offset_map_lock(): >> >> pte_offset_map() >> >> spin_lock() >> >> - page_ref_count() # new check >> >> - page_vma_mapped_walk_done() # see pte_unmap_unlock(): >> >> pte_unmap() >> >> spin_unlock() >> >> >> >> - bio_iov_iter_get_pages() >> >> - __bio_iov_iter_get_pages() >> >> - iov_iter_get_pages() >> >> - get_user_pages_fast() >> >> - internal_get_user_pages_fast() >> >> >> >> # fast path >> >> - lockless_pages_from_mm() >> >> - gup_{pgd,p4d,pud,pmd,pte}_range() >> >> ptep = pte_offset_map() # not _lock() >> >> pte = ptep_get_lockless(ptep) >> >> page = pte_page(pte) >> >> try_grab_compound_head(page) # get ref >> >> if (pte_val(pte) != pte_val(*ptep)) >> >> put_compound_head(page) # put ref >> >> # leave page for slow path >> >> # slow path >> >> - __gup_longterm_unlocked() >> >> - get_user_pages_unlocked() >> >> - __get_user_pages_locked() >> >> - __get_user_pages() >> >> - follow_{page,p4d,pud,pmd}_mask() >> >> - follow_page_pte() >> >> ptep = pte_offset_map_lock() >> >> pte = *ptep >> >> page = vm_normal_page(pte) >> >> try_grab_page(page) # get ref >> >> pte_unmap_unlock() >> >> >> >> Regarding transparent hugepages, that number shouldn't change, as >> >> MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() >> >> (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) >> >> thus should reach shrink_page_list() -> split_huge_page_to_list() >> >> before try_to_unmap[_one](), so it deals with normal pages only. >> >> >> >> (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() >> >> happens, which it should not or be rare, the page refcount is not >> >> two, as the head page counts tail pages, and tail pages have zero. >> >> That also prevents checking the head `page` then incorrectly call >> >> page_remove_rmap(subpage) for a tail page, that isn't even in the >> >> shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), >> >> as it might happen today in this unlikely scenario.) >> >> >> >> MADV_FREE'd buffers: >> >> =================== >> >> >> >> So, back to the "if MADV_FREE pages are used as buffers" note. >> >> The case is arguable, and subject to multiple interpretations. >> >> >> >> The madvise(2) manual page on the MADV_FREE advice value says: >> >> - 'After a successful MADV_FREE ... data will be lost when >> >> the kernel frees the pages.' >> >> - 'the free operation will be canceled if the caller writes >> >> into the page' / 'subsequent writes ... will succeed and >> >> then [the] kernel cannot free those dirtied pages' >> >> - 'If there is no subsequent write, the kernel can free the >> >> pages at any time.' >> >> >> >> Thoughts, questions, considerations... >> >> - Since the kernel didn't actually free the page (page_ref_freeze() >> >> failed), should the data not have been lost? (on userspace read.) >> >> - Should writes performed by the direct IO read be able to cancel >> >> the free operation? >> >> - Should the direct IO read be considered as 'the caller' too, >> >> as it's been requested by 'the caller'? >> >> - Should the bio technique to dirty pages on return to userspace >> >> (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) >> >> be considered in another/special way here? >> >> - Should an upcoming write from a previously requested direct IO >> >> read be considered as a subsequent write, so the kernel should >> >> not free the pages? (as it's known at the time of page reclaim.) >> >> >> >> Technically, the last point would seem a reasonable consideration >> >> and balance, as the madvise(2) manual page apparently (and fairly) >> >> seem to assume that 'writes' are memory access from the userspace >> >> process (not explicitly considering writes from the kernel or its >> >> corner cases; again, fairly).. plus the kernel fix implementation >> >> for the corner case of the largely 'non-atomic write' encompassed >> >> by a direct IO read operation, is relatively simple; and it helps. >> >> >> >> Reproducer: >> >> ========== >> >> >> >> @ test.c (simplified, but works) >> >> >> >> #define _GNU_SOURCE >> >> #include <fcntl.h> >> >> #include <stdio.h> >> >> #include <unistd.h> >> >> #include <sys/mman.h> >> >> >> >> int main() { >> >> int fd, i; >> >> char *buf; >> >> >> >> fd = open(DEV, O_RDONLY | O_DIRECT); >> >> >> >> buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, >> >> MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); >> >> >> >> for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) >> >> buf[i] = 1; // init to non-zero >> >> >> >> madvise(buf, BUF_SIZE, MADV_FREE); >> > >> > IIUC, you are expecting to get the old data after MADV_FREE? TBH, you >> > should not expect so at all after MADV_FREE since those pages may get >> > freed at any time. >> > >> >> Per my understanding, if direct IO reading is done after MADV_FREE, I >> think we want to get the new data instead of old data. > > Here "old data" means the data written by "buf[i] = 1;" before > MADV_FREE in that test code. OK. I found that the expected data isn't "1", but "0x79", which is read from disk image after MADV_FREE. Re-paste as below, # mv test good # ./good 0x7f1509206000: 0x79 0x7f1509207000: 0x79 0x7f1509208000: 0x79 0x7f1509209000: 0x79 Best Regards, Huang, Ying
On Tue, Jan 4, 2022 at 5:42 PM Huang, Ying <ying.huang@intel.com> wrote: > > Yang Shi <shy828301@gmail.com> writes: > > > On Tue, Jan 4, 2022 at 4:32 PM Huang, Ying <ying.huang@intel.com> wrote: > >> > >> Yang Shi <shy828301@gmail.com> writes: > >> > >> > On Fri, Dec 10, 2021 at 6:22 PM Mauricio Faria de Oliveira > >> > <mfo@canonical.com> wrote: > >> >> > >> >> Problem: > >> >> ======= > >> >> > >> >> Userspace might read the zero-page instead of actual data from a > >> >> direct IO read on a block device if the buffers have been called > >> >> madvise(MADV_FREE) on earlier (this is discussed below) due to a > >> >> race between page reclaim on MADV_FREE and blkdev direct IO read. > >> >> > >> >> Race condition: > >> >> ============== > >> >> > >> >> During page reclaim, the MADV_FREE page check in try_to_unmap_one() > >> >> checks if the page is not dirty, then discards its PTE (vs remap it > >> >> back if the page is dirty). > >> >> > >> >> However, after try_to_unmap_one() returns to shrink_page_list(), it > >> >> might keep the page _anyway_ if page_ref_freeze() fails (it expects > >> >> a single page ref from the isolation). > >> >> > >> >> Well, blkdev_direct_IO() gets references for all pages, and on READ > >> >> operations it sets them dirty later. > >> >> > >> >> So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more > >> >> later) for direct IO read from block devices and page reclaim runs > >> >> during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() > >> >> but BEFORE it sets pages dirty, that situation happens. > >> >> > >> >> The direct IO read eventually completes. Now, when userspace reads > >> >> the buffers, the PTE is no longer there and the page fault handler > >> >> do_anonymous_page() services that with the zero-page, NOT the data! > >> >> > >> >> A synthetic reproducer is provided. > >> >> > >> >> Page faults: > >> >> =========== > >> >> > >> >> The data read from the block device probably won't generate faults > >> >> due to DMA (no MMU) but even in the case it wouldn't use DMA, that > >> >> happens on different virtual addresses (not user-mapped addresses) > >> >> because `struct bio_vec` stores `struct page` to figure addresses > >> >> out (which are different from/unrelated to user-mapped addresses) > >> >> for the data read. > >> >> > >> >> Thus userspace reads (to user-mapped addresses) still fault, then > >> >> do_anonymous_page() gets another `struct page` that would address/ > >> >> map to other memory than the `struct page` used by `struct bio_vec` > >> >> for the read (which runs correctly as the page wasn't freed due to > >> >> page_ref_freeze(), and is reclaimed later) -- but even if the page > >> >> addresses matched, that handler maps the zero-page in the PTE, not > >> >> that page's memory (on read faults.) > >> >> > >> >> If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue > >> >> doesn't happen, because that faults-in all pages as writeable, so > >> >> do_anonymous_page() sets up a new page/rmap/PTE, and that is used > >> >> by direct IO. The userspace reads don't fault as the PTE is there > >> >> (thus zero-page is not used.) > >> >> > >> >> Solution: > >> >> ======== > >> >> > >> >> One solution is to check for the expected page reference count in > >> >> try_to_unmap_one() too, which should be exactly two: one from the > >> >> isolation (checked by shrink_page_list()), and the other from the > >> >> rmap (dropped by the discard: label). If that doesn't match, then > >> >> remap the PTE back, just like page dirty does. > >> >> > >> >> The new check in try_to_unmap_one() should be safe in races with > >> >> bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, > >> >> as it's done under the PTE lock. The fast path doesn't take that > >> >> lock but it checks the PTE has changed, then drops the reference > >> >> and leaves the page for the slow path (which does take that lock). > >> >> > >> >> - try_to_unmap_one() > >> >> - page_vma_mapped_walk() > >> >> - map_pte() # see pte_offset_map_lock(): > >> >> pte_offset_map() > >> >> spin_lock() > >> >> - page_ref_count() # new check > >> >> - page_vma_mapped_walk_done() # see pte_unmap_unlock(): > >> >> pte_unmap() > >> >> spin_unlock() > >> >> > >> >> - bio_iov_iter_get_pages() > >> >> - __bio_iov_iter_get_pages() > >> >> - iov_iter_get_pages() > >> >> - get_user_pages_fast() > >> >> - internal_get_user_pages_fast() > >> >> > >> >> # fast path > >> >> - lockless_pages_from_mm() > >> >> - gup_{pgd,p4d,pud,pmd,pte}_range() > >> >> ptep = pte_offset_map() # not _lock() > >> >> pte = ptep_get_lockless(ptep) > >> >> page = pte_page(pte) > >> >> try_grab_compound_head(page) # get ref > >> >> if (pte_val(pte) != pte_val(*ptep)) > >> >> put_compound_head(page) # put ref > >> >> # leave page for slow path > >> >> # slow path > >> >> - __gup_longterm_unlocked() > >> >> - get_user_pages_unlocked() > >> >> - __get_user_pages_locked() > >> >> - __get_user_pages() > >> >> - follow_{page,p4d,pud,pmd}_mask() > >> >> - follow_page_pte() > >> >> ptep = pte_offset_map_lock() > >> >> pte = *ptep > >> >> page = vm_normal_page(pte) > >> >> try_grab_page(page) # get ref > >> >> pte_unmap_unlock() > >> >> > >> >> Regarding transparent hugepages, that number shouldn't change, as > >> >> MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() > >> >> (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) > >> >> thus should reach shrink_page_list() -> split_huge_page_to_list() > >> >> before try_to_unmap[_one](), so it deals with normal pages only. > >> >> > >> >> (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() > >> >> happens, which it should not or be rare, the page refcount is not > >> >> two, as the head page counts tail pages, and tail pages have zero. > >> >> That also prevents checking the head `page` then incorrectly call > >> >> page_remove_rmap(subpage) for a tail page, that isn't even in the > >> >> shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), > >> >> as it might happen today in this unlikely scenario.) > >> >> > >> >> MADV_FREE'd buffers: > >> >> =================== > >> >> > >> >> So, back to the "if MADV_FREE pages are used as buffers" note. > >> >> The case is arguable, and subject to multiple interpretations. > >> >> > >> >> The madvise(2) manual page on the MADV_FREE advice value says: > >> >> - 'After a successful MADV_FREE ... data will be lost when > >> >> the kernel frees the pages.' > >> >> - 'the free operation will be canceled if the caller writes > >> >> into the page' / 'subsequent writes ... will succeed and > >> >> then [the] kernel cannot free those dirtied pages' > >> >> - 'If there is no subsequent write, the kernel can free the > >> >> pages at any time.' > >> >> > >> >> Thoughts, questions, considerations... > >> >> - Since the kernel didn't actually free the page (page_ref_freeze() > >> >> failed), should the data not have been lost? (on userspace read.) > >> >> - Should writes performed by the direct IO read be able to cancel > >> >> the free operation? > >> >> - Should the direct IO read be considered as 'the caller' too, > >> >> as it's been requested by 'the caller'? > >> >> - Should the bio technique to dirty pages on return to userspace > >> >> (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) > >> >> be considered in another/special way here? > >> >> - Should an upcoming write from a previously requested direct IO > >> >> read be considered as a subsequent write, so the kernel should > >> >> not free the pages? (as it's known at the time of page reclaim.) > >> >> > >> >> Technically, the last point would seem a reasonable consideration > >> >> and balance, as the madvise(2) manual page apparently (and fairly) > >> >> seem to assume that 'writes' are memory access from the userspace > >> >> process (not explicitly considering writes from the kernel or its > >> >> corner cases; again, fairly).. plus the kernel fix implementation > >> >> for the corner case of the largely 'non-atomic write' encompassed > >> >> by a direct IO read operation, is relatively simple; and it helps. > >> >> > >> >> Reproducer: > >> >> ========== > >> >> > >> >> @ test.c (simplified, but works) > >> >> > >> >> #define _GNU_SOURCE > >> >> #include <fcntl.h> > >> >> #include <stdio.h> > >> >> #include <unistd.h> > >> >> #include <sys/mman.h> > >> >> > >> >> int main() { > >> >> int fd, i; > >> >> char *buf; > >> >> > >> >> fd = open(DEV, O_RDONLY | O_DIRECT); > >> >> > >> >> buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, > >> >> MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); > >> >> > >> >> for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) > >> >> buf[i] = 1; // init to non-zero > >> >> > >> >> madvise(buf, BUF_SIZE, MADV_FREE); > >> > > >> > IIUC, you are expecting to get the old data after MADV_FREE? TBH, you > >> > should not expect so at all after MADV_FREE since those pages may get > >> > freed at any time. > >> > > >> > >> Per my understanding, if direct IO reading is done after MADV_FREE, I > >> think we want to get the new data instead of old data. > > > > Here "old data" means the data written by "buf[i] = 1;" before > > MADV_FREE in that test code. > > OK. I found that the expected data isn't "1", but "0x79", which is read > from disk image after MADV_FREE. Re-paste as below, Err, sorry for the confusion. Yes, the "old data" means the data on disk. "buf[i] = 1" should be used to allocate pages for the buffer in that test code IIUC. Just came back from holiday, need to refresh my brain :-( > > # mv test good > # ./good > 0x7f1509206000: 0x79 > 0x7f1509207000: 0x79 > 0x7f1509208000: 0x79 > 0x7f1509209000: 0x79 > > Best Regards, > Huang, Ying
diff --git a/mm/rmap.c b/mm/rmap.c index 163ac4e6bcee..f04151aae03b 100644 --- a/mm/rmap.c +++ b/mm/rmap.c @@ -1570,7 +1570,18 @@ static bool try_to_unmap_one(struct page *page, struct vm_area_struct *vma, /* MADV_FREE page check */ if (!PageSwapBacked(page)) { - if (!PageDirty(page)) { + int refcount = page_ref_count(page); + + /* + * The only page refs must be from the isolation + * (checked by the caller shrink_page_list() too) + * and the (single) rmap (dropped by discard:). + * + * Check the reference count before dirty flag + * with memory barrier; see __remove_mapping(). + */ + smp_rmb(); + if (refcount == 2 && !PageDirty(page)) { /* Invalidate as we cleared the pte */ mmu_notifier_invalidate_range(mm, address, address + PAGE_SIZE); diff --git a/mm/vmscan.c b/mm/vmscan.c index fb9584641ac7..c1ea4e14f510 100644 --- a/mm/vmscan.c +++ b/mm/vmscan.c @@ -1688,7 +1688,7 @@ static unsigned int shrink_page_list(struct list_head *page_list, mapping = page_mapping(page); } } else if (unlikely(PageTransHuge(page))) { - /* Split file THP */ + /* Split file/lazyfree THP */ if (split_huge_page_to_list(page, page_list)) goto keep_locked; }
Problem: ======= Userspace might read the zero-page instead of actual data from a direct IO read on a block device if the buffers have been called madvise(MADV_FREE) on earlier (this is discussed below) due to a race between page reclaim on MADV_FREE and blkdev direct IO read. Race condition: ============== During page reclaim, the MADV_FREE page check in try_to_unmap_one() checks if the page is not dirty, then discards its PTE (vs remap it back if the page is dirty). However, after try_to_unmap_one() returns to shrink_page_list(), it might keep the page _anyway_ if page_ref_freeze() fails (it expects a single page ref from the isolation). Well, blkdev_direct_IO() gets references for all pages, and on READ operations it sets them dirty later. So, if MADV_FREE pages (i.e., not dirty) are used as buffers (more later) for direct IO read from block devices and page reclaim runs during __blkdev_direct_IO[_simple]() AFTER bio_iov_iter_get_pages() but BEFORE it sets pages dirty, that situation happens. The direct IO read eventually completes. Now, when userspace reads the buffers, the PTE is no longer there and the page fault handler do_anonymous_page() services that with the zero-page, NOT the data! A synthetic reproducer is provided. Page faults: =========== The data read from the block device probably won't generate faults due to DMA (no MMU) but even in the case it wouldn't use DMA, that happens on different virtual addresses (not user-mapped addresses) because `struct bio_vec` stores `struct page` to figure addresses out (which are different from/unrelated to user-mapped addresses) for the data read. Thus userspace reads (to user-mapped addresses) still fault, then do_anonymous_page() gets another `struct page` that would address/ map to other memory than the `struct page` used by `struct bio_vec` for the read (which runs correctly as the page wasn't freed due to page_ref_freeze(), and is reclaimed later) -- but even if the page addresses matched, that handler maps the zero-page in the PTE, not that page's memory (on read faults.) If page reclaim happens BEFORE bio_iov_iter_get_pages() the issue doesn't happen, because that faults-in all pages as writeable, so do_anonymous_page() sets up a new page/rmap/PTE, and that is used by direct IO. The userspace reads don't fault as the PTE is there (thus zero-page is not used.) Solution: ======== One solution is to check for the expected page reference count in try_to_unmap_one() too, which should be exactly two: one from the isolation (checked by shrink_page_list()), and the other from the rmap (dropped by the discard: label). If that doesn't match, then remap the PTE back, just like page dirty does. The new check in try_to_unmap_one() should be safe in races with bio_iov_iter_get_pages() in get_user_pages() fast and slow paths, as it's done under the PTE lock. The fast path doesn't take that lock but it checks the PTE has changed, then drops the reference and leaves the page for the slow path (which does take that lock). - try_to_unmap_one() - page_vma_mapped_walk() - map_pte() # see pte_offset_map_lock(): pte_offset_map() spin_lock() - page_ref_count() # new check - page_vma_mapped_walk_done() # see pte_unmap_unlock(): pte_unmap() spin_unlock() - bio_iov_iter_get_pages() - __bio_iov_iter_get_pages() - iov_iter_get_pages() - get_user_pages_fast() - internal_get_user_pages_fast() # fast path - lockless_pages_from_mm() - gup_{pgd,p4d,pud,pmd,pte}_range() ptep = pte_offset_map() # not _lock() pte = ptep_get_lockless(ptep) page = pte_page(pte) try_grab_compound_head(page) # get ref if (pte_val(pte) != pte_val(*ptep)) put_compound_head(page) # put ref # leave page for slow path # slow path - __gup_longterm_unlocked() - get_user_pages_unlocked() - __get_user_pages_locked() - __get_user_pages() - follow_{page,p4d,pud,pmd}_mask() - follow_page_pte() ptep = pte_offset_map_lock() pte = *ptep page = vm_normal_page(pte) try_grab_page(page) # get ref pte_unmap_unlock() Regarding transparent hugepages, that number shouldn't change, as MADV_FREE (aka lazyfree) pages are PageAnon() && !PageSwapBacked() (madvise_free_pte_range() -> mark_page_lazyfree() -> lru_lazyfree_fn()) thus should reach shrink_page_list() -> split_huge_page_to_list() before try_to_unmap[_one](), so it deals with normal pages only. (And in case unlikely/TTU_SPLIT_HUGE_PMD/split_huge_pmd_address() happens, which it should not or be rare, the page refcount is not two, as the head page counts tail pages, and tail pages have zero. That also prevents checking the head `page` then incorrectly call page_remove_rmap(subpage) for a tail page, that isn't even in the shrink_page_list()'s page_list (an effect of split huge pmd/pmvw), as it might happen today in this unlikely scenario.) MADV_FREE'd buffers: =================== So, back to the "if MADV_FREE pages are used as buffers" note. The case is arguable, and subject to multiple interpretations. The madvise(2) manual page on the MADV_FREE advice value says: - 'After a successful MADV_FREE ... data will be lost when the kernel frees the pages.' - 'the free operation will be canceled if the caller writes into the page' / 'subsequent writes ... will succeed and then [the] kernel cannot free those dirtied pages' - 'If there is no subsequent write, the kernel can free the pages at any time.' Thoughts, questions, considerations... - Since the kernel didn't actually free the page (page_ref_freeze() failed), should the data not have been lost? (on userspace read.) - Should writes performed by the direct IO read be able to cancel the free operation? - Should the direct IO read be considered as 'the caller' too, as it's been requested by 'the caller'? - Should the bio technique to dirty pages on return to userspace (bio_check_pages_dirty() is called/used by __blkdev_direct_IO()) be considered in another/special way here? - Should an upcoming write from a previously requested direct IO read be considered as a subsequent write, so the kernel should not free the pages? (as it's known at the time of page reclaim.) Technically, the last point would seem a reasonable consideration and balance, as the madvise(2) manual page apparently (and fairly) seem to assume that 'writes' are memory access from the userspace process (not explicitly considering writes from the kernel or its corner cases; again, fairly).. plus the kernel fix implementation for the corner case of the largely 'non-atomic write' encompassed by a direct IO read operation, is relatively simple; and it helps. Reproducer: ========== @ test.c (simplified, but works) #define _GNU_SOURCE #include <fcntl.h> #include <stdio.h> #include <unistd.h> #include <sys/mman.h> int main() { int fd, i; char *buf; fd = open(DEV, O_RDONLY | O_DIRECT); buf = mmap(NULL, BUF_SIZE, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) buf[i] = 1; // init to non-zero madvise(buf, BUF_SIZE, MADV_FREE); read(fd, buf, BUF_SIZE); for (i = 0; i < BUF_SIZE; i += PAGE_SIZE) printf("%p: 0x%x\n", &buf[i], buf[i]); return 0; } @ block/fops.c (formerly fs/block_dev.c) +#include <linux/swap.h> ... ... __blkdev_direct_IO[_simple](...) { ... + if (!strcmp(current->comm, "good")) + shrink_all_memory(ULONG_MAX); + ret = bio_iov_iter_get_pages(...); + + if (!strcmp(current->comm, "bad")) + shrink_all_memory(ULONG_MAX); ... } @ shell # yes | dd of=test.img bs=1k count=16 # DEV=$(losetup -f --show test.img) # gcc -DDEV=\"$DEV\" -DBUF_SIZE=16384 -DPAGE_SIZE=4096 test.c -o test # od -tx1 $DEV 0000000 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a 79 0a * 0040000 # mv test good # ./good 0x7f1509206000: 0x79 0x7f1509207000: 0x79 0x7f1509208000: 0x79 0x7f1509209000: 0x79 # mv good bad # ./bad 0x7fd87272f000: 0x0 0x7fd872730000: 0x0 0x7fd872731000: 0x0 0x7fd872732000: 0x0 Ceph/TCMalloc: ============= For documentation purposes, the use case driving the analysis/fix is Ceph on Ubuntu 18.04, as the TCMalloc library there still uses MADV_FREE to release unused memory to the system from the mmap'ed page heap (might be committed back/used again; it's not munmap'ed.) - PageHeap::DecommitSpan() -> TCMalloc_SystemRelease() -> madvise() - PageHeap::CommitSpan() -> TCMalloc_SystemCommit() -> do nothing. Note: TCMalloc switched back to MADV_DONTNEED a few commits after the release in Ubuntu 18.04 (google-perftools/gperftools 2.5), so the issue just 'disappeared' on Ceph on later Ubuntu releases but is still present in the kernel, and can be hit by other use cases. The observed issue seems to be the old Ceph bug #22464 [1], where checksum mismatches are observed (and instrumentation with buffer dumps shows zero-pages read from mmap'ed/MADV_FREE'd page ranges). The issue in Ceph was reasonably deemed a kernel bug (comment #50) and mostly worked around with a retry mechanism, but other parts of Ceph could still hit that (rocksdb). Anyway, it's less likely to be hit again as TCMalloc switched out of MADV_FREE by default. (Some kernel versions/reports from the Ceph bug, and relation with the MADV_FREE introduction/changes; TCMalloc versions not checked.) - 4.4 good - 4.5 (madv_free: introduction) - 4.9 bad - 4.10 good? maybe a swapless system - 4.12 (madv_free: no longer free instantly on swapless systems) - 4.13 bad [1] https://tracker.ceph.com/issues/22464 Thanks: ====== Several people contributed to analysis/discussions/tests/reproducers in the first stages when drilling down on ceph/tcmalloc/linux kernel: - Dan Hill <daniel.hill@canonical.com> - Dan Streetman <dan.streetman@canonical.com> - Dongdong Tao <dongdong.tao@canonical.com> - Gavin Guo <gavin.guo@canonical.com> - Gerald Yang <gerald.yang@canonical.com> - Heitor Alves de Siqueira <halves@canonical.com> - Ioanna Alifieraki <ioanna-maria.alifieraki@canonical.com> - Jay Vosburgh <jay.vosburgh@canonical.com> - Matthew Ruffell <matthew.ruffell@canonical.com> - Ponnuvel Palaniyappan <ponnuvel.palaniyappan@canonical.com> Signed-off-by: Mauricio Faria de Oliveira <mfo@canonical.com> --- P.S.: sorry for the very long commit message; hopefully it might provide enough context and considerations on the problem and fix approach to help reviewers. Tested on v5.16-rc4. mm/rmap.c | 13 ++++++++++++- mm/vmscan.c | 2 +- 2 files changed, 13 insertions(+), 2 deletions(-)