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Currently we abuse the extent_map structure for two purposes: 1) To actually represent extents for inodes; 2) To represent chunk mappings. This is odd and has several disadvantages: 1) To create a chunk map, we need to do two memory allocations: one for an extent_map structure and another one for a map_lookup structure, so more potential for an allocation failure and more complicated code to manage and link two structures; 2) For a chunk map we actually only use 3 fields (24 bytes) of the respective extent map structure: the 'start' field to have the logical start address of the chunk, the 'len' field to have the chunk's size, and the 'orig_block_len' field to contain the chunk's stripe size. Besides wasting a memory, it's also odd and not intuitive at all to have the stripe size in a field named 'orig_block_len'. We are also using 'block_len' of the extent_map structure to contain the chunk size, so we have 2 fields for the same value, 'len' and 'block_len', which is pointless; 3) When an extent map is associated to a chunk mapping, we set the bit EXTENT_FLAG_FS_MAPPING on its flags and then make its member named 'map_lookup' point to the associated map_lookup structure. This means that for an extent map associated to an inode extent, we are not using this 'map_lookup' pointer, so wasting 8 bytes (on a 64 bits platform); 4) Extent maps associated to a chunk mapping are never merged or split so it's pointless to use the existing extent map infrastructure. So add a dedicated data structure named 'btrfs_chunk_map' to represent chunk mappings, this is basically the existing map_lookup structure with some extra fields: 1) 'start' to contain the chunk logical address; 2) 'chunk_len' to contain the chunk's length; 3) 'stripe_size' for the stripe size; 4) 'rb_node' for insertion into a rb tree; 5) 'refs' for reference counting. This way we do a single memory allocation for chunk mappings and we don't waste memory for them with unused/unnecessary fields from an extent_map. We also save 8 bytes from the extent_map structure by removing the 'map_lookup' pointer, so the size of struct extent_map is reduced from 144 bytes down to 136 bytes, and we can now have 30 extents map per 4K page instead of 28. Reviewed-by: Josef Bacik <josef@toxicpanda.com> Signed-off-by: Filipe Manana <fdmanana@suse.com> Reviewed-by: David Sterba <dsterba@suse.com> Signed-off-by: David Sterba <dsterba@suse.com>
202 lines
5.2 KiB
C
202 lines
5.2 KiB
C
/* SPDX-License-Identifier: GPL-2.0 */
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/*
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* Copyright (C) 2012 Fusion-io All rights reserved.
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* Copyright (C) 2012 Intel Corp. All rights reserved.
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*/
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#ifndef BTRFS_RAID56_H
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#define BTRFS_RAID56_H
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#include <linux/workqueue.h>
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#include "volumes.h"
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enum btrfs_rbio_ops {
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BTRFS_RBIO_WRITE,
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BTRFS_RBIO_READ_REBUILD,
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BTRFS_RBIO_PARITY_SCRUB,
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};
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struct btrfs_raid_bio {
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struct btrfs_io_context *bioc;
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/*
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* While we're doing RMW on a stripe we put it into a hash table so we
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* can lock the stripe and merge more rbios into it.
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*/
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struct list_head hash_list;
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/* LRU list for the stripe cache */
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struct list_head stripe_cache;
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/* For scheduling work in the helper threads */
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struct work_struct work;
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/*
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* bio_list and bio_list_lock are used to add more bios into the stripe
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* in hopes of avoiding the full RMW
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*/
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struct bio_list bio_list;
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spinlock_t bio_list_lock;
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/*
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* Also protected by the bio_list_lock, the plug list is used by the
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* plugging code to collect partial bios while plugged. The stripe
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* locking code also uses it to hand off the stripe lock to the next
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* pending IO.
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*/
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struct list_head plug_list;
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/* Flags that tell us if it is safe to merge with this bio. */
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unsigned long flags;
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/*
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* Set if we're doing a parity rebuild for a read from higher up, which
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* is handled differently from a parity rebuild as part of RMW.
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*/
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enum btrfs_rbio_ops operation;
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/* How many pages there are for the full stripe including P/Q */
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u16 nr_pages;
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/* How many sectors there are for the full stripe including P/Q */
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u16 nr_sectors;
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/* Number of data stripes (no p/q) */
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u8 nr_data;
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/* Number of all stripes (including P/Q) */
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u8 real_stripes;
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/* How many pages there are for each stripe */
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u8 stripe_npages;
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/* How many sectors there are for each stripe */
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u8 stripe_nsectors;
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/* Stripe number that we're scrubbing */
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u8 scrubp;
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/*
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* Size of all the bios in the bio_list. This helps us decide if the
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* rbio maps to a full stripe or not.
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*/
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int bio_list_bytes;
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refcount_t refs;
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atomic_t stripes_pending;
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wait_queue_head_t io_wait;
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/* Bitmap to record which horizontal stripe has data */
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unsigned long dbitmap;
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/* Allocated with stripe_nsectors-many bits for finish_*() calls */
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unsigned long finish_pbitmap;
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/*
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* These are two arrays of pointers. We allocate the rbio big enough
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* to hold them both and setup their locations when the rbio is
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* allocated.
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*/
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/*
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* Pointers to pages that we allocated for reading/writing stripes
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* directly from the disk (including P/Q).
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*/
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struct page **stripe_pages;
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/* Pointers to the sectors in the bio_list, for faster lookup */
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struct sector_ptr *bio_sectors;
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/*
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* For subpage support, we need to map each sector to above
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* stripe_pages.
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*/
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struct sector_ptr *stripe_sectors;
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/* Allocated with real_stripes-many pointers for finish_*() calls */
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void **finish_pointers;
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/*
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* The bitmap recording where IO errors happened.
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* Each bit is corresponding to one sector in either bio_sectors[] or
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* stripe_sectors[] array.
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*
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* The reason we don't use another bit in sector_ptr is, we have two
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* arrays of sectors, and a lot of IO can use sectors in both arrays.
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* Thus making it much harder to iterate.
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*/
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unsigned long *error_bitmap;
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/*
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* Checksum buffer if the rbio is for data. The buffer should cover
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* all data sectors (excluding P/Q sectors).
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*/
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u8 *csum_buf;
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/*
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* Each bit represents if the corresponding sector has data csum found.
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* Should only cover data sectors (excluding P/Q sectors).
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*/
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unsigned long *csum_bitmap;
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};
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/*
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* For trace event usage only. Records useful debug info for each bio submitted
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* by RAID56 to each physical device.
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*
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* No matter signed or not, (-1) is always the one indicating we can not grab
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* the proper stripe number.
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*/
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struct raid56_bio_trace_info {
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u64 devid;
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/* The offset inside the stripe. (<= STRIPE_LEN) */
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u32 offset;
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/*
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* Stripe number.
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* 0 is the first data stripe, and nr_data for P stripe,
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* nr_data + 1 for Q stripe.
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* >= real_stripes for
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*/
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u8 stripe_nr;
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};
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static inline int nr_data_stripes(const struct btrfs_chunk_map *map)
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{
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return map->num_stripes - btrfs_nr_parity_stripes(map->type);
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}
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static inline int nr_bioc_data_stripes(const struct btrfs_io_context *bioc)
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{
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return bioc->num_stripes - btrfs_nr_parity_stripes(bioc->map_type);
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}
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#define RAID5_P_STRIPE ((u64)-2)
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#define RAID6_Q_STRIPE ((u64)-1)
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#define is_parity_stripe(x) (((x) == RAID5_P_STRIPE) || \
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((x) == RAID6_Q_STRIPE))
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struct btrfs_device;
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void raid56_parity_recover(struct bio *bio, struct btrfs_io_context *bioc,
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int mirror_num);
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void raid56_parity_write(struct bio *bio, struct btrfs_io_context *bioc);
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struct btrfs_raid_bio *raid56_parity_alloc_scrub_rbio(struct bio *bio,
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struct btrfs_io_context *bioc,
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struct btrfs_device *scrub_dev,
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unsigned long *dbitmap, int stripe_nsectors);
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void raid56_parity_submit_scrub_rbio(struct btrfs_raid_bio *rbio);
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void raid56_parity_cache_data_pages(struct btrfs_raid_bio *rbio,
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struct page **data_pages, u64 data_logical);
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int btrfs_alloc_stripe_hash_table(struct btrfs_fs_info *info);
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void btrfs_free_stripe_hash_table(struct btrfs_fs_info *info);
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#endif
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