On Mon 29-01-24 14:41:56, Matthew Wilcox wrote:
On Mon, Jan 29, 2024 at 10:11:24AM +0100, Jan Kara wrote:
On Thu 25-01-24 14:06:58, Matthew Wilcox wrote:
On Thu, Jan 25, 2024 at 01:09:46PM +0000, Roman Smirnov wrote:
Syzkaller reports warning in ext4_set_page_dirty() in 5.10 and 5.15 stable releases. It happens because invalidate_inode_page() frees pages that are needed for the system. To fix this we need to add additional checks to the function. page_mapped() checks if a page exists in the page tables, but this is not enough. The page can be used in other places: https://elixir.bootlin.com/linux/v6.8-rc1/source/include/linux/page_ref.h#L7...
Kernel outputs an error line related to direct I/O: https://syzkaller.appspot.com/text?tag=CrashLog&x=14ab52dac80000
OK, this is making a lot more sense.
The invalidate_inode_page() path (after the page_mapped check) calls try_to_release_page() which strips the buffers from the page. __remove_mapping() tries to freeze the page and presuambly fails.
Yep, likely.
ext4 is checking there are still buffer heads attached to the page. I'm not sure why it's doing that; it's legitimate to strip the bufferheads from a page and then reattach them later (if they're attached to a dirty page, they are created dirty).
Well, we really need to track dirtiness on per fs-block basis in ext4 (which makes a difference when blocksize < page size). For example for delayed block allocation we reserve exactly as many blocks as we need (which need not be all the blocks in the page e.g. when writing just one block in the middle of a large hole). So when all buffers would be marked as dirty we would overrun our reservation. Hence at the moment of dirtying we really need buffers to be attached to the page and stay there until the page is written back.
Thanks for the clear explanation!
Isn't the correct place to ensure that this is true in ext4_release_folio()? I think all paths to remove buffer_heads from a folio go through ext4_release_folio() and so it can be prohibited here if the folio is part of a delalloc extent?
OK, I tried to keep it simple but now I have to go into more intricate details of GUP and the IO path so please bear with me. Normally, how things happen on write or page_mkwrite time is:
lock_page(page) check we have buffers, create if not do stuff with page mark appropriate buffers (and thus the page) dirty unlock_page(page)
Now the page and buffers are dirty so nothing can be freed as reclaim doesn't touch such pages (and neither does try_to_free_buffers()). So we are safe until page writeback time.
But GUP users such as direct IO are different. They do the page_mkwrite() dance at GUP time so we are fine at that moment. But on direct IO completion they recheck page dirty bits and call set_page_dirty() *again* if they find the page has been cleaned in the mean time. And this is where the problem really happens. If writeback of the pages serving as direct IO buffer happen while the IO is running, buffers get cleaned, and can be reclaimed, and we then hit the warning in ext4_set_page_dirty().
So what we really need is "don't reclaim page buffers if the page is pinned by GUP". This is what MM checks in recent kernels (since d824ec2a15467 "mm: do not reclaim private data from pinned page") and the patch discussed here is effectively an equivalent of it for stable. So AFAICT it really closes all the problematic paths. Sure we could implement that check in ext4_release_folio() but I don't think there's a great reason for that.
And yes, technically I assume we could reconstruct the buffer state from other data structures if we find the buffers are missing. But in ext4_set_page_dirty() that is not easily possible as it may be called in softirq context. And elsewhere it is prone to hiding other bugs we may introduce. So just not stripping the buffer heads when the page is pinned is by far the easiest solution for ext4, in particular for stable...
Honza