68573b936d
Use try_cmpxchg() family of functions instead of cmpxchg (*ptr, old, new) == old. x86 CMPXCHG instruction returns success in ZF flag, so this change saves a compare after cmpxchg (and related move instruction in front of cmpxchg). Also, try_cmpxchg() implicitly assigns old *ptr value to "old" when cmpxchg fails. There is no need to re-read the value in the loop. No functional change intended. Signed-off-by: Uros Bizjak <ubizjak@gmail.com> Cc: Kent Overstreet <kent.overstreet@linux.dev> Cc: Brian Foster <bfoster@redhat.com> Signed-off-by: Kent Overstreet <kent.overstreet@linux.dev>
450 lines
14 KiB
C
450 lines
14 KiB
C
/* SPDX-License-Identifier: GPL-2.0 */
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#ifndef _BCACHEFS_JOURNAL_H
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#define _BCACHEFS_JOURNAL_H
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/*
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* THE JOURNAL:
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*
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* The primary purpose of the journal is to log updates (insertions) to the
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* b-tree, to avoid having to do synchronous updates to the b-tree on disk.
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*
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* Without the journal, the b-tree is always internally consistent on
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* disk - and in fact, in the earliest incarnations bcache didn't have a journal
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* but did handle unclean shutdowns by doing all index updates synchronously
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* (with coalescing).
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*
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* Updates to interior nodes still happen synchronously and without the journal
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* (for simplicity) - this may change eventually but updates to interior nodes
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* are rare enough it's not a huge priority.
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*
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* This means the journal is relatively separate from the b-tree; it consists of
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* just a list of keys and journal replay consists of just redoing those
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* insertions in same order that they appear in the journal.
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*
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* PERSISTENCE:
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*
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* For synchronous updates (where we're waiting on the index update to hit
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* disk), the journal entry will be written out immediately (or as soon as
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* possible, if the write for the previous journal entry was still in flight).
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*
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* Synchronous updates are specified by passing a closure (@flush_cl) to
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* bch2_btree_insert() or bch_btree_insert_node(), which then pass that parameter
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* down to the journalling code. That closure will wait on the journal write to
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* complete (via closure_wait()).
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*
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* If the index update wasn't synchronous, the journal entry will be
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* written out after 10 ms have elapsed, by default (the delay_ms field
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* in struct journal).
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*
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* JOURNAL ENTRIES:
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*
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* A journal entry is variable size (struct jset), it's got a fixed length
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* header and then a variable number of struct jset_entry entries.
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*
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* Journal entries are identified by monotonically increasing 64 bit sequence
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* numbers - jset->seq; other places in the code refer to this sequence number.
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*
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* A jset_entry entry contains one or more bkeys (which is what gets inserted
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* into the b-tree). We need a container to indicate which b-tree the key is
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* for; also, the roots of the various b-trees are stored in jset_entry entries
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* (one for each b-tree) - this lets us add new b-tree types without changing
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* the on disk format.
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*
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* We also keep some things in the journal header that are logically part of the
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* superblock - all the things that are frequently updated. This is for future
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* bcache on raw flash support; the superblock (which will become another
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* journal) can't be moved or wear leveled, so it contains just enough
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* information to find the main journal, and the superblock only has to be
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* rewritten when we want to move/wear level the main journal.
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*
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* JOURNAL LAYOUT ON DISK:
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*
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* The journal is written to a ringbuffer of buckets (which is kept in the
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* superblock); the individual buckets are not necessarily contiguous on disk
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* which means that journal entries are not allowed to span buckets, but also
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* that we can resize the journal at runtime if desired (unimplemented).
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*
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* The journal buckets exist in the same pool as all the other buckets that are
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* managed by the allocator and garbage collection - garbage collection marks
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* the journal buckets as metadata buckets.
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*
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* OPEN/DIRTY JOURNAL ENTRIES:
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*
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* Open/dirty journal entries are journal entries that contain b-tree updates
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* that have not yet been written out to the b-tree on disk. We have to track
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* which journal entries are dirty, and we also have to avoid wrapping around
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* the journal and overwriting old but still dirty journal entries with new
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* journal entries.
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*
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* On disk, this is represented with the "last_seq" field of struct jset;
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* last_seq is the first sequence number that journal replay has to replay.
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*
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* To avoid overwriting dirty journal entries on disk, we keep a mapping (in
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* journal_device->seq) of for each journal bucket, the highest sequence number
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* any journal entry it contains. Then, by comparing that against last_seq we
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* can determine whether that journal bucket contains dirty journal entries or
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* not.
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*
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* To track which journal entries are dirty, we maintain a fifo of refcounts
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* (where each entry corresponds to a specific sequence number) - when a ref
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* goes to 0, that journal entry is no longer dirty.
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*
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* Journalling of index updates is done at the same time as the b-tree itself is
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* being modified (see btree_insert_key()); when we add the key to the journal
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* the pending b-tree write takes a ref on the journal entry the key was added
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* to. If a pending b-tree write would need to take refs on multiple dirty
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* journal entries, it only keeps the ref on the oldest one (since a newer
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* journal entry will still be replayed if an older entry was dirty).
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*
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* JOURNAL FILLING UP:
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*
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* There are two ways the journal could fill up; either we could run out of
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* space to write to, or we could have too many open journal entries and run out
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* of room in the fifo of refcounts. Since those refcounts are decremented
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* without any locking we can't safely resize that fifo, so we handle it the
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* same way.
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*
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* If the journal fills up, we start flushing dirty btree nodes until we can
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* allocate space for a journal write again - preferentially flushing btree
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* nodes that are pinning the oldest journal entries first.
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*/
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#include <linux/hash.h>
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#include "journal_types.h"
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struct bch_fs;
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static inline void journal_wake(struct journal *j)
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{
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wake_up(&j->wait);
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closure_wake_up(&j->async_wait);
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}
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static inline struct journal_buf *journal_cur_buf(struct journal *j)
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{
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return j->buf + j->reservations.idx;
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}
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/* Sequence number of oldest dirty journal entry */
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static inline u64 journal_last_seq(struct journal *j)
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{
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return j->pin.front;
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}
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static inline u64 journal_cur_seq(struct journal *j)
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{
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return atomic64_read(&j->seq);
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}
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static inline u64 journal_last_unwritten_seq(struct journal *j)
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{
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return j->seq_ondisk + 1;
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}
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static inline int journal_state_count(union journal_res_state s, int idx)
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{
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switch (idx) {
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case 0: return s.buf0_count;
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case 1: return s.buf1_count;
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case 2: return s.buf2_count;
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case 3: return s.buf3_count;
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}
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BUG();
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}
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static inline void journal_state_inc(union journal_res_state *s)
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{
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s->buf0_count += s->idx == 0;
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s->buf1_count += s->idx == 1;
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s->buf2_count += s->idx == 2;
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s->buf3_count += s->idx == 3;
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}
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/*
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* Amount of space that will be taken up by some keys in the journal (i.e.
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* including the jset header)
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*/
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static inline unsigned jset_u64s(unsigned u64s)
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{
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return u64s + sizeof(struct jset_entry) / sizeof(u64);
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}
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static inline int journal_entry_overhead(struct journal *j)
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{
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return sizeof(struct jset) / sizeof(u64) + j->entry_u64s_reserved;
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}
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static inline struct jset_entry *
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bch2_journal_add_entry_noreservation(struct journal_buf *buf, size_t u64s)
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{
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struct jset *jset = buf->data;
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struct jset_entry *entry = vstruct_idx(jset, le32_to_cpu(jset->u64s));
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memset(entry, 0, sizeof(*entry));
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entry->u64s = cpu_to_le16(u64s);
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le32_add_cpu(&jset->u64s, jset_u64s(u64s));
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return entry;
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}
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static inline struct jset_entry *
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journal_res_entry(struct journal *j, struct journal_res *res)
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{
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return vstruct_idx(j->buf[res->idx].data, res->offset);
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}
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static inline unsigned journal_entry_init(struct jset_entry *entry, unsigned type,
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enum btree_id id, unsigned level,
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unsigned u64s)
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{
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entry->u64s = cpu_to_le16(u64s);
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entry->btree_id = id;
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entry->level = level;
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entry->type = type;
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entry->pad[0] = 0;
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entry->pad[1] = 0;
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entry->pad[2] = 0;
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return jset_u64s(u64s);
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}
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static inline unsigned journal_entry_set(struct jset_entry *entry, unsigned type,
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enum btree_id id, unsigned level,
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const void *data, unsigned u64s)
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{
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unsigned ret = journal_entry_init(entry, type, id, level, u64s);
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memcpy_u64s_small(entry->_data, data, u64s);
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return ret;
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}
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static inline struct jset_entry *
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bch2_journal_add_entry(struct journal *j, struct journal_res *res,
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unsigned type, enum btree_id id,
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unsigned level, unsigned u64s)
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{
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struct jset_entry *entry = journal_res_entry(j, res);
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unsigned actual = journal_entry_init(entry, type, id, level, u64s);
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EBUG_ON(!res->ref);
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EBUG_ON(actual > res->u64s);
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res->offset += actual;
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res->u64s -= actual;
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return entry;
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}
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static inline bool journal_entry_empty(struct jset *j)
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{
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if (j->seq != j->last_seq)
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return false;
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vstruct_for_each(j, i)
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if (i->type == BCH_JSET_ENTRY_btree_keys && i->u64s)
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return false;
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return true;
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}
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/*
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* Drop reference on a buffer index and return true if the count has hit zero.
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*/
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static inline union journal_res_state journal_state_buf_put(struct journal *j, unsigned idx)
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{
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union journal_res_state s;
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s.v = atomic64_sub_return(((union journal_res_state) {
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.buf0_count = idx == 0,
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.buf1_count = idx == 1,
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.buf2_count = idx == 2,
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.buf3_count = idx == 3,
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}).v, &j->reservations.counter);
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return s;
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}
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bool bch2_journal_entry_close(struct journal *);
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void bch2_journal_do_writes(struct journal *);
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void bch2_journal_buf_put_final(struct journal *, u64);
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static inline void __bch2_journal_buf_put(struct journal *j, unsigned idx, u64 seq)
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{
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union journal_res_state s;
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s = journal_state_buf_put(j, idx);
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if (!journal_state_count(s, idx))
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bch2_journal_buf_put_final(j, seq);
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}
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static inline void bch2_journal_buf_put(struct journal *j, unsigned idx, u64 seq)
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{
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union journal_res_state s;
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s = journal_state_buf_put(j, idx);
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if (!journal_state_count(s, idx)) {
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spin_lock(&j->lock);
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bch2_journal_buf_put_final(j, seq);
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spin_unlock(&j->lock);
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}
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}
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/*
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* This function releases the journal write structure so other threads can
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* then proceed to add their keys as well.
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*/
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static inline void bch2_journal_res_put(struct journal *j,
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struct journal_res *res)
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{
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if (!res->ref)
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return;
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lock_release(&j->res_map, _THIS_IP_);
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while (res->u64s)
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bch2_journal_add_entry(j, res,
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BCH_JSET_ENTRY_btree_keys,
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0, 0, 0);
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bch2_journal_buf_put(j, res->idx, res->seq);
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res->ref = 0;
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}
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int bch2_journal_res_get_slowpath(struct journal *, struct journal_res *,
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unsigned);
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/* First bits for BCH_WATERMARK: */
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enum journal_res_flags {
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__JOURNAL_RES_GET_NONBLOCK = BCH_WATERMARK_BITS,
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__JOURNAL_RES_GET_CHECK,
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};
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#define JOURNAL_RES_GET_NONBLOCK (1 << __JOURNAL_RES_GET_NONBLOCK)
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#define JOURNAL_RES_GET_CHECK (1 << __JOURNAL_RES_GET_CHECK)
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static inline int journal_res_get_fast(struct journal *j,
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struct journal_res *res,
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unsigned flags)
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{
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union journal_res_state old, new;
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old.v = atomic64_read(&j->reservations.counter);
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do {
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new.v = old.v;
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/*
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* Check if there is still room in the current journal
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* entry:
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*/
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if (new.cur_entry_offset + res->u64s > j->cur_entry_u64s)
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return 0;
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EBUG_ON(!journal_state_count(new, new.idx));
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if ((flags & BCH_WATERMARK_MASK) < j->watermark)
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return 0;
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new.cur_entry_offset += res->u64s;
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journal_state_inc(&new);
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/*
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* If the refcount would overflow, we have to wait:
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* XXX - tracepoint this:
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*/
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if (!journal_state_count(new, new.idx))
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return 0;
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if (flags & JOURNAL_RES_GET_CHECK)
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return 1;
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} while (!atomic64_try_cmpxchg(&j->reservations.counter,
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&old.v, new.v));
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res->ref = true;
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res->idx = old.idx;
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res->offset = old.cur_entry_offset;
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res->seq = le64_to_cpu(j->buf[old.idx].data->seq);
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return 1;
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}
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static inline int bch2_journal_res_get(struct journal *j, struct journal_res *res,
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unsigned u64s, unsigned flags)
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{
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int ret;
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EBUG_ON(res->ref);
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EBUG_ON(!test_bit(JOURNAL_running, &j->flags));
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res->u64s = u64s;
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if (journal_res_get_fast(j, res, flags))
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goto out;
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ret = bch2_journal_res_get_slowpath(j, res, flags);
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if (ret)
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return ret;
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out:
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if (!(flags & JOURNAL_RES_GET_CHECK)) {
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lock_acquire_shared(&j->res_map, 0,
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(flags & JOURNAL_RES_GET_NONBLOCK) != 0,
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NULL, _THIS_IP_);
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EBUG_ON(!res->ref);
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}
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return 0;
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}
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/* journal_entry_res: */
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void bch2_journal_entry_res_resize(struct journal *,
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struct journal_entry_res *,
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unsigned);
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int bch2_journal_flush_seq_async(struct journal *, u64, struct closure *);
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void bch2_journal_flush_async(struct journal *, struct closure *);
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int bch2_journal_flush_seq(struct journal *, u64);
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int bch2_journal_flush(struct journal *);
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bool bch2_journal_noflush_seq(struct journal *, u64);
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int bch2_journal_meta(struct journal *);
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void bch2_journal_halt(struct journal *);
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static inline int bch2_journal_error(struct journal *j)
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{
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return j->reservations.cur_entry_offset == JOURNAL_ENTRY_ERROR_VAL
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? -EIO : 0;
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}
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struct bch_dev;
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static inline void bch2_journal_set_replay_done(struct journal *j)
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{
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BUG_ON(!test_bit(JOURNAL_running, &j->flags));
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set_bit(JOURNAL_replay_done, &j->flags);
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}
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void bch2_journal_unblock(struct journal *);
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void bch2_journal_block(struct journal *);
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struct journal_buf *bch2_next_write_buffer_flush_journal_buf(struct journal *j, u64 max_seq);
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void __bch2_journal_debug_to_text(struct printbuf *, struct journal *);
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void bch2_journal_debug_to_text(struct printbuf *, struct journal *);
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void bch2_journal_pins_to_text(struct printbuf *, struct journal *);
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bool bch2_journal_seq_pins_to_text(struct printbuf *, struct journal *, u64 *);
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int bch2_set_nr_journal_buckets(struct bch_fs *, struct bch_dev *,
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unsigned nr);
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int bch2_dev_journal_alloc(struct bch_dev *, bool);
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int bch2_fs_journal_alloc(struct bch_fs *);
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void bch2_dev_journal_stop(struct journal *, struct bch_dev *);
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void bch2_fs_journal_stop(struct journal *);
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int bch2_fs_journal_start(struct journal *, u64);
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void bch2_dev_journal_exit(struct bch_dev *);
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int bch2_dev_journal_init(struct bch_dev *, struct bch_sb *);
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void bch2_fs_journal_exit(struct journal *);
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int bch2_fs_journal_init(struct journal *);
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#endif /* _BCACHEFS_JOURNAL_H */
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