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This adds another disk accounting counter to track usage per inode number (any snapshot ID). This will be used for a couple things: - It'll give us a way to tell the user how much space a given file ista consuming in all snapshots; i.e. how much extra space it's consuming due to snapshot versioning. - It counts number of extents and total size of extents (both in btree keyspace sectors and actual disk usage), meaning it gives us average extent size: that is, it'll let us cheaply find fragmented files that should be defragmented. Signed-off-by: Kent Overstreet <kent.overstreet@linux.dev>
168 lines
4.2 KiB
C
168 lines
4.2 KiB
C
/* SPDX-License-Identifier: GPL-2.0 */
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#ifndef _BCACHEFS_DISK_ACCOUNTING_FORMAT_H
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#define _BCACHEFS_DISK_ACCOUNTING_FORMAT_H
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#include "replicas_format.h"
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/*
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* Disk accounting - KEY_TYPE_accounting - on disk format:
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*
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* Here, the key has considerably more structure than a typical key (bpos); an
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* accounting key is 'struct disk_accounting_pos', which is a union of bpos.
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*
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* More specifically: a key is just a muliword integer (where word endianness
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* matches native byte order), so we're treating bpos as an opaque 20 byte
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* integer and mapping bch_accounting_key to that.
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*
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* This is a type-tagged union of all our various subtypes; a disk accounting
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* key can be device counters, replicas counters, et cetera - it's extensible.
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*
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* The value is a list of u64s or s64s; the number of counters is specific to a
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* given accounting type.
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*
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* Unlike with other key types, updates are _deltas_, and the deltas are not
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* resolved until the update to the underlying btree, done by btree write buffer
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* flush or journal replay.
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*
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* Journal replay in particular requires special handling. The journal tracks a
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* range of entries which may possibly have not yet been applied to the btree
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* yet - it does not know definitively whether individual entries are dirty and
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* still need to be applied.
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*
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* To handle this, we use the version field of struct bkey, and give every
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* accounting update a unique version number - a total ordering in time; the
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* version number is derived from the key's position in the journal. Then
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* journal replay can compare the version number of the key from the journal
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* with the version number of the key in the btree to determine if a key needs
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* to be replayed.
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*
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* For this to work, we must maintain this strict time ordering of updates as
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* they are flushed to the btree, both via write buffer flush and via journal
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* replay. This has complications for the write buffer code while journal replay
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* is still in progress; the write buffer cannot flush any accounting keys to
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* the btree until journal replay has finished replaying its accounting keys, or
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* the (newer) version number of the keys from the write buffer will cause
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* updates from journal replay to be lost.
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*/
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struct bch_accounting {
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struct bch_val v;
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__u64 d[];
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};
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#define BCH_ACCOUNTING_MAX_COUNTERS 3
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#define BCH_DATA_TYPES() \
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x(free, 0) \
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x(sb, 1) \
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x(journal, 2) \
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x(btree, 3) \
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x(user, 4) \
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x(cached, 5) \
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x(parity, 6) \
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x(stripe, 7) \
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x(need_gc_gens, 8) \
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x(need_discard, 9) \
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x(unstriped, 10)
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enum bch_data_type {
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#define x(t, n) BCH_DATA_##t,
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BCH_DATA_TYPES()
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#undef x
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BCH_DATA_NR
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};
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static inline bool data_type_is_empty(enum bch_data_type type)
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{
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switch (type) {
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case BCH_DATA_free:
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case BCH_DATA_need_gc_gens:
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case BCH_DATA_need_discard:
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return true;
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default:
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return false;
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}
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}
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static inline bool data_type_is_hidden(enum bch_data_type type)
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{
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switch (type) {
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case BCH_DATA_sb:
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case BCH_DATA_journal:
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return true;
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default:
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return false;
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}
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}
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#define BCH_DISK_ACCOUNTING_TYPES() \
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x(nr_inodes, 0) \
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x(persistent_reserved, 1) \
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x(replicas, 2) \
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x(dev_data_type, 3) \
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x(compression, 4) \
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x(snapshot, 5) \
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x(btree, 6) \
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x(rebalance_work, 7) \
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x(inum, 8)
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enum disk_accounting_type {
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#define x(f, nr) BCH_DISK_ACCOUNTING_##f = nr,
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BCH_DISK_ACCOUNTING_TYPES()
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#undef x
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BCH_DISK_ACCOUNTING_TYPE_NR,
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};
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struct bch_nr_inodes {
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};
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struct bch_persistent_reserved {
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__u8 nr_replicas;
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};
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struct bch_dev_data_type {
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__u8 dev;
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__u8 data_type;
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};
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struct bch_acct_compression {
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__u8 type;
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};
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struct bch_acct_snapshot {
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__u32 id;
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} __packed;
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struct bch_acct_btree {
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__u32 id;
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} __packed;
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struct bch_acct_inum {
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__u64 inum;
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} __packed;
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struct bch_acct_rebalance_work {
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};
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struct disk_accounting_pos {
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union {
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struct {
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__u8 type;
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union {
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struct bch_nr_inodes nr_inodes;
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struct bch_persistent_reserved persistent_reserved;
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struct bch_replicas_entry_v1 replicas;
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struct bch_dev_data_type dev_data_type;
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struct bch_acct_compression compression;
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struct bch_acct_snapshot snapshot;
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struct bch_acct_btree btree;
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struct bch_acct_rebalance_work rebalance_work;
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struct bch_acct_inum inum;
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} __packed;
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} __packed;
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struct bpos _pad;
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};
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};
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#endif /* _BCACHEFS_DISK_ACCOUNTING_FORMAT_H */
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