| .. _gfp_mask_from_fs_io: |
| |
| ================================= |
| GFP masks used from FS/IO context |
| ================================= |
| |
| :Date: May, 2018 |
| :Author: Michal Hocko <mhocko@kernel.org> |
| |
| Introduction |
| ============ |
| |
| Code paths in the filesystem and IO stacks must be careful when |
| allocating memory to prevent recursion deadlocks caused by direct |
| memory reclaim calling back into the FS or IO paths and blocking on |
| already held resources (e.g. locks - most commonly those used for the |
| transaction context). |
| |
| The traditional way to avoid this deadlock problem is to clear __GFP_FS |
| respectively __GFP_IO (note the latter implies clearing the first as well) in |
| the gfp mask when calling an allocator. GFP_NOFS respectively GFP_NOIO can be |
| used as shortcut. It turned out though that above approach has led to |
| abuses when the restricted gfp mask is used "just in case" without a |
| deeper consideration which leads to problems because an excessive use |
| of GFP_NOFS/GFP_NOIO can lead to memory over-reclaim or other memory |
| reclaim issues. |
| |
| New API |
| ======== |
| |
| Since 4.12 we do have a generic scope API for both NOFS and NOIO context |
| ``memalloc_nofs_save``, ``memalloc_nofs_restore`` respectively ``memalloc_noio_save``, |
| ``memalloc_noio_restore`` which allow to mark a scope to be a critical |
| section from a filesystem or I/O point of view. Any allocation from that |
| scope will inherently drop __GFP_FS respectively __GFP_IO from the given |
| mask so no memory allocation can recurse back in the FS/IO. |
| |
| .. kernel-doc:: include/linux/sched/mm.h |
| :functions: memalloc_nofs_save memalloc_nofs_restore |
| .. kernel-doc:: include/linux/sched/mm.h |
| :functions: memalloc_noio_save memalloc_noio_restore |
| |
| FS/IO code then simply calls the appropriate save function before |
| any critical section with respect to the reclaim is started - e.g. |
| lock shared with the reclaim context or when a transaction context |
| nesting would be possible via reclaim. The restore function should be |
| called when the critical section ends. All that ideally along with an |
| explanation what is the reclaim context for easier maintenance. |
| |
| Please note that the proper pairing of save/restore functions |
| allows nesting so it is safe to call ``memalloc_noio_save`` or |
| ``memalloc_noio_restore`` respectively from an existing NOIO or NOFS |
| scope. |
| |
| What about __vmalloc(GFP_NOFS) |
| ============================== |
| |
| vmalloc doesn't support GFP_NOFS semantic because there are hardcoded |
| GFP_KERNEL allocations deep inside the allocator which are quite non-trivial |
| to fix up. That means that calling ``vmalloc`` with GFP_NOFS/GFP_NOIO is |
| almost always a bug. The good news is that the NOFS/NOIO semantic can be |
| achieved by the scope API. |
| |
| In the ideal world, upper layers should already mark dangerous contexts |
| and so no special care is required and vmalloc should be called without |
| any problems. Sometimes if the context is not really clear or there are |
| layering violations then the recommended way around that is to wrap ``vmalloc`` |
| by the scope API with a comment explaining the problem. |
