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linux-stable/fs/bcachefs/io_write.c
Darrick J. Wong 273960b8f3 bcachefs: time_stats: split stats-with-quantiles into a separate structure 
Currently, struct time_stats has the optional ability to quantize the
information that it collects.  This is /probably/ useful for callers who
want to see quantized information, but it more than doubles the size of
the structure from 224 bytes to 464.  For users who don't care about
that (e.g. upcoming xfs patches) and want to avoid wasting 240 bytes per
counter, split the two into separate pieces.

Signed-off-by: Darrick J. Wong <djwong@kernel.org>
Signed-off-by: Kent Overstreet <kent.overstreet@linux.dev>
2024-03-13 21:38:01 -04:00

1668 lines
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// SPDX-License-Identifier: GPL-2.0
/*
* Copyright 2010, 2011 Kent Overstreet <kent.overstreet@gmail.com>
* Copyright 2012 Google, Inc.
*/
#include "bcachefs.h"
#include "alloc_foreground.h"
#include "bkey_buf.h"
#include "bset.h"
#include "btree_update.h"
#include "buckets.h"
#include "checksum.h"
#include "clock.h"
#include "compress.h"
#include "debug.h"
#include "ec.h"
#include "error.h"
#include "extent_update.h"
#include "inode.h"
#include "io_write.h"
#include "journal.h"
#include "keylist.h"
#include "move.h"
#include "nocow_locking.h"
#include "rebalance.h"
#include "subvolume.h"
#include "super.h"
#include "super-io.h"
#include "trace.h"
#include <linux/blkdev.h>
#include <linux/prefetch.h>
#include <linux/random.h>
#include <linux/sched/mm.h>
#ifndef CONFIG_BCACHEFS_NO_LATENCY_ACCT
static inline void bch2_congested_acct(struct bch_dev *ca, u64 io_latency,
u64 now, int rw)
{
u64 latency_capable =
ca->io_latency[rw].quantiles.entries[QUANTILE_IDX(1)].m;
/* ideally we'd be taking into account the device's variance here: */
u64 latency_threshold = latency_capable << (rw == READ ? 2 : 3);
s64 latency_over = io_latency - latency_threshold;
if (latency_threshold && latency_over > 0) {
/*
* bump up congested by approximately latency_over * 4 /
* latency_threshold - we don't need much accuracy here so don't
* bother with the divide:
*/
if (atomic_read(&ca->congested) < CONGESTED_MAX)
atomic_add(latency_over >>
max_t(int, ilog2(latency_threshold) - 2, 0),
&ca->congested);
ca->congested_last = now;
} else if (atomic_read(&ca->congested) > 0) {
atomic_dec(&ca->congested);
}
}
void bch2_latency_acct(struct bch_dev *ca, u64 submit_time, int rw)
{
atomic64_t *latency = &ca->cur_latency[rw];
u64 now = local_clock();
u64 io_latency = time_after64(now, submit_time)
? now - submit_time
: 0;
u64 old, new, v = atomic64_read(latency);
do {
old = v;
/*
* If the io latency was reasonably close to the current
* latency, skip doing the update and atomic operation - most of
* the time:
*/
if (abs((int) (old - io_latency)) < (old >> 1) &&
now & ~(~0U << 5))
break;
new = ewma_add(old, io_latency, 5);
} while ((v = atomic64_cmpxchg(latency, old, new)) != old);
bch2_congested_acct(ca, io_latency, now, rw);
__bch2_time_stats_update(&ca->io_latency[rw].stats, submit_time, now);
}
#endif
/* Allocate, free from mempool: */
void bch2_bio_free_pages_pool(struct bch_fs *c, struct bio *bio)
{
struct bvec_iter_all iter;
struct bio_vec *bv;
bio_for_each_segment_all(bv, bio, iter)
if (bv->bv_page != ZERO_PAGE(0))
mempool_free(bv->bv_page, &c->bio_bounce_pages);
bio->bi_vcnt = 0;
}
static struct page *__bio_alloc_page_pool(struct bch_fs *c, bool *using_mempool)
{
struct page *page;
if (likely(!*using_mempool)) {
page = alloc_page(GFP_NOFS);
if (unlikely(!page)) {
mutex_lock(&c->bio_bounce_pages_lock);
*using_mempool = true;
goto pool_alloc;
}
} else {
pool_alloc:
page = mempool_alloc(&c->bio_bounce_pages, GFP_NOFS);
}
return page;
}
void bch2_bio_alloc_pages_pool(struct bch_fs *c, struct bio *bio,
size_t size)
{
bool using_mempool = false;
while (size) {
struct page *page = __bio_alloc_page_pool(c, &using_mempool);
unsigned len = min_t(size_t, PAGE_SIZE, size);
BUG_ON(!bio_add_page(bio, page, len, 0));
size -= len;
}
if (using_mempool)
mutex_unlock(&c->bio_bounce_pages_lock);
}
/* Extent update path: */
int bch2_sum_sector_overwrites(struct btree_trans *trans,
struct btree_iter *extent_iter,
struct bkey_i *new,
bool *usage_increasing,
s64 *i_sectors_delta,
s64 *disk_sectors_delta)
{
struct bch_fs *c = trans->c;
struct btree_iter iter;
struct bkey_s_c old;
unsigned new_replicas = bch2_bkey_replicas(c, bkey_i_to_s_c(new));
bool new_compressed = bch2_bkey_sectors_compressed(bkey_i_to_s_c(new));
int ret = 0;
*usage_increasing = false;
*i_sectors_delta = 0;
*disk_sectors_delta = 0;
bch2_trans_copy_iter(&iter, extent_iter);
for_each_btree_key_upto_continue_norestart(iter,
new->k.p, BTREE_ITER_SLOTS, old, ret) {
s64 sectors = min(new->k.p.offset, old.k->p.offset) -
max(bkey_start_offset(&new->k),
bkey_start_offset(old.k));
*i_sectors_delta += sectors *
(bkey_extent_is_allocation(&new->k) -
bkey_extent_is_allocation(old.k));
*disk_sectors_delta += sectors * bch2_bkey_nr_ptrs_allocated(bkey_i_to_s_c(new));
*disk_sectors_delta -= new->k.p.snapshot == old.k->p.snapshot
? sectors * bch2_bkey_nr_ptrs_fully_allocated(old)
: 0;
if (!*usage_increasing &&
(new->k.p.snapshot != old.k->p.snapshot ||
new_replicas > bch2_bkey_replicas(c, old) ||
(!new_compressed && bch2_bkey_sectors_compressed(old))))
*usage_increasing = true;
if (bkey_ge(old.k->p, new->k.p))
break;
}
bch2_trans_iter_exit(trans, &iter);
return ret;
}
static inline int bch2_extent_update_i_size_sectors(struct btree_trans *trans,
struct btree_iter *extent_iter,
u64 new_i_size,
s64 i_sectors_delta)
{
struct btree_iter iter;
struct bkey_i *k;
struct bkey_i_inode_v3 *inode;
/*
* Crazy performance optimization:
* Every extent update needs to also update the inode: the inode trigger
* will set bi->journal_seq to the journal sequence number of this
* transaction - for fsync.
*
* But if that's the only reason we're updating the inode (we're not
* updating bi_size or bi_sectors), then we don't need the inode update
* to be journalled - if we crash, the bi_journal_seq update will be
* lost, but that's fine.
*/
unsigned inode_update_flags = BTREE_UPDATE_NOJOURNAL;
int ret;
k = bch2_bkey_get_mut_noupdate(trans, &iter, BTREE_ID_inodes,
SPOS(0,
extent_iter->pos.inode,
extent_iter->snapshot),
BTREE_ITER_CACHED);
ret = PTR_ERR_OR_ZERO(k);
if (unlikely(ret))
return ret;
if (unlikely(k->k.type != KEY_TYPE_inode_v3)) {
k = bch2_inode_to_v3(trans, k);
ret = PTR_ERR_OR_ZERO(k);
if (unlikely(ret))
goto err;
}
inode = bkey_i_to_inode_v3(k);
if (!(le64_to_cpu(inode->v.bi_flags) & BCH_INODE_i_size_dirty) &&
new_i_size > le64_to_cpu(inode->v.bi_size)) {
inode->v.bi_size = cpu_to_le64(new_i_size);
inode_update_flags = 0;
}
if (i_sectors_delta) {
le64_add_cpu(&inode->v.bi_sectors, i_sectors_delta);
inode_update_flags = 0;
}
if (inode->k.p.snapshot != iter.snapshot) {
inode->k.p.snapshot = iter.snapshot;
inode_update_flags = 0;
}
ret = bch2_trans_update(trans, &iter, &inode->k_i,
BTREE_UPDATE_INTERNAL_SNAPSHOT_NODE|
inode_update_flags);
err:
bch2_trans_iter_exit(trans, &iter);
return ret;
}
int bch2_extent_update(struct btree_trans *trans,
subvol_inum inum,
struct btree_iter *iter,
struct bkey_i *k,
struct disk_reservation *disk_res,
u64 new_i_size,
s64 *i_sectors_delta_total,
bool check_enospc)
{
struct bpos next_pos;
bool usage_increasing;
s64 i_sectors_delta = 0, disk_sectors_delta = 0;
int ret;
/*
* This traverses us the iterator without changing iter->path->pos to
* search_key() (which is pos + 1 for extents): we want there to be a
* path already traversed at iter->pos because
* bch2_trans_extent_update() will use it to attempt extent merging
*/
ret = __bch2_btree_iter_traverse(iter);
if (ret)
return ret;
ret = bch2_extent_trim_atomic(trans, iter, k);
if (ret)
return ret;
next_pos = k->k.p;
ret = bch2_sum_sector_overwrites(trans, iter, k,
&usage_increasing,
&i_sectors_delta,
&disk_sectors_delta);
if (ret)
return ret;
if (disk_res &&
disk_sectors_delta > (s64) disk_res->sectors) {
ret = bch2_disk_reservation_add(trans->c, disk_res,
disk_sectors_delta - disk_res->sectors,
!check_enospc || !usage_increasing
? BCH_DISK_RESERVATION_NOFAIL : 0);
if (ret)
return ret;
}
/*
* Note:
* We always have to do an inode update - even when i_size/i_sectors
* aren't changing - for fsync to work properly; fsync relies on
* inode->bi_journal_seq which is updated by the trigger code:
*/
ret = bch2_extent_update_i_size_sectors(trans, iter,
min(k->k.p.offset << 9, new_i_size),
i_sectors_delta) ?:
bch2_trans_update(trans, iter, k, 0) ?:
bch2_trans_commit(trans, disk_res, NULL,
BCH_TRANS_COMMIT_no_check_rw|
BCH_TRANS_COMMIT_no_enospc);
if (unlikely(ret))
return ret;
if (i_sectors_delta_total)
*i_sectors_delta_total += i_sectors_delta;
bch2_btree_iter_set_pos(iter, next_pos);
return 0;
}
static int bch2_write_index_default(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
struct bkey_buf sk;
struct keylist *keys = &op->insert_keys;
struct bkey_i *k = bch2_keylist_front(keys);
struct btree_trans *trans = bch2_trans_get(c);
struct btree_iter iter;
subvol_inum inum = {
.subvol = op->subvol,
.inum = k->k.p.inode,
};
int ret;
BUG_ON(!inum.subvol);
bch2_bkey_buf_init(&sk);
do {
bch2_trans_begin(trans);
k = bch2_keylist_front(keys);
bch2_bkey_buf_copy(&sk, c, k);
ret = bch2_subvolume_get_snapshot(trans, inum.subvol,
&sk.k->k.p.snapshot);
if (bch2_err_matches(ret, BCH_ERR_transaction_restart))
continue;
if (ret)
break;
bch2_trans_iter_init(trans, &iter, BTREE_ID_extents,
bkey_start_pos(&sk.k->k),
BTREE_ITER_SLOTS|BTREE_ITER_INTENT);
ret = bch2_bkey_set_needs_rebalance(c, sk.k, &op->opts) ?:
bch2_extent_update(trans, inum, &iter, sk.k,
&op->res,
op->new_i_size, &op->i_sectors_delta,
op->flags & BCH_WRITE_CHECK_ENOSPC);
bch2_trans_iter_exit(trans, &iter);
if (bch2_err_matches(ret, BCH_ERR_transaction_restart))
continue;
if (ret)
break;
if (bkey_ge(iter.pos, k->k.p))
bch2_keylist_pop_front(&op->insert_keys);
else
bch2_cut_front(iter.pos, k);
} while (!bch2_keylist_empty(keys));
bch2_trans_put(trans);
bch2_bkey_buf_exit(&sk, c);
return ret;
}
/* Writes */
void bch2_submit_wbio_replicas(struct bch_write_bio *wbio, struct bch_fs *c,
enum bch_data_type type,
const struct bkey_i *k,
bool nocow)
{
struct bkey_ptrs_c ptrs = bch2_bkey_ptrs_c(bkey_i_to_s_c(k));
struct bch_write_bio *n;
BUG_ON(c->opts.nochanges);
bkey_for_each_ptr(ptrs, ptr) {
BUG_ON(!bch2_dev_exists2(c, ptr->dev));
struct bch_dev *ca = bch_dev_bkey_exists(c, ptr->dev);
if (to_entry(ptr + 1) < ptrs.end) {
n = to_wbio(bio_alloc_clone(NULL, &wbio->bio,
GFP_NOFS, &ca->replica_set));
n->bio.bi_end_io = wbio->bio.bi_end_io;
n->bio.bi_private = wbio->bio.bi_private;
n->parent = wbio;
n->split = true;
n->bounce = false;
n->put_bio = true;
n->bio.bi_opf = wbio->bio.bi_opf;
bio_inc_remaining(&wbio->bio);
} else {
n = wbio;
n->split = false;
}
n->c = c;
n->dev = ptr->dev;
n->have_ioref = nocow || bch2_dev_get_ioref(ca,
type == BCH_DATA_btree ? READ : WRITE);
n->nocow = nocow;
n->submit_time = local_clock();
n->inode_offset = bkey_start_offset(&k->k);
n->bio.bi_iter.bi_sector = ptr->offset;
if (likely(n->have_ioref)) {
this_cpu_add(ca->io_done->sectors[WRITE][type],
bio_sectors(&n->bio));
bio_set_dev(&n->bio, ca->disk_sb.bdev);
if (type != BCH_DATA_btree && unlikely(c->opts.no_data_io)) {
bio_endio(&n->bio);
continue;
}
submit_bio(&n->bio);
} else {
n->bio.bi_status = BLK_STS_REMOVED;
bio_endio(&n->bio);
}
}
}
static void __bch2_write(struct bch_write_op *);
static void bch2_write_done(struct closure *cl)
{
struct bch_write_op *op = container_of(cl, struct bch_write_op, cl);
struct bch_fs *c = op->c;
EBUG_ON(op->open_buckets.nr);
bch2_time_stats_update(&c->times[BCH_TIME_data_write], op->start_time);
bch2_disk_reservation_put(c, &op->res);
if (!(op->flags & BCH_WRITE_MOVE))
bch2_write_ref_put(c, BCH_WRITE_REF_write);
bch2_keylist_free(&op->insert_keys, op->inline_keys);
EBUG_ON(cl->parent);
closure_debug_destroy(cl);
if (op->end_io)
op->end_io(op);
}
static noinline int bch2_write_drop_io_error_ptrs(struct bch_write_op *op)
{
struct keylist *keys = &op->insert_keys;
struct bch_extent_ptr *ptr;
struct bkey_i *src, *dst = keys->keys, *n;
for (src = keys->keys; src != keys->top; src = n) {
n = bkey_next(src);
if (bkey_extent_is_direct_data(&src->k)) {
bch2_bkey_drop_ptrs(bkey_i_to_s(src), ptr,
test_bit(ptr->dev, op->failed.d));
if (!bch2_bkey_nr_ptrs(bkey_i_to_s_c(src)))
return -EIO;
}
if (dst != src)
memmove_u64s_down(dst, src, src->k.u64s);
dst = bkey_next(dst);
}
keys->top = dst;
return 0;
}
/**
* __bch2_write_index - after a write, update index to point to new data
* @op: bch_write_op to process
*/
static void __bch2_write_index(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
struct keylist *keys = &op->insert_keys;
unsigned dev;
int ret = 0;
if (unlikely(op->flags & BCH_WRITE_IO_ERROR)) {
ret = bch2_write_drop_io_error_ptrs(op);
if (ret)
goto err;
}
if (!bch2_keylist_empty(keys)) {
u64 sectors_start = keylist_sectors(keys);
ret = !(op->flags & BCH_WRITE_MOVE)
? bch2_write_index_default(op)
: bch2_data_update_index_update(op);
BUG_ON(bch2_err_matches(ret, BCH_ERR_transaction_restart));
BUG_ON(keylist_sectors(keys) && !ret);
op->written += sectors_start - keylist_sectors(keys);
if (ret && !bch2_err_matches(ret, EROFS)) {
struct bkey_i *insert = bch2_keylist_front(&op->insert_keys);
bch_err_inum_offset_ratelimited(c,
insert->k.p.inode, insert->k.p.offset << 9,
"%s write error while doing btree update: %s",
op->flags & BCH_WRITE_MOVE ? "move" : "user",
bch2_err_str(ret));
}
if (ret)
goto err;
}
out:
/* If some a bucket wasn't written, we can't erasure code it: */
for_each_set_bit(dev, op->failed.d, BCH_SB_MEMBERS_MAX)
bch2_open_bucket_write_error(c, &op->open_buckets, dev);
bch2_open_buckets_put(c, &op->open_buckets);
return;
err:
keys->top = keys->keys;
op->error = ret;
op->flags |= BCH_WRITE_DONE;
goto out;
}
static inline void __wp_update_state(struct write_point *wp, enum write_point_state state)
{
if (state != wp->state) {
u64 now = ktime_get_ns();
if (wp->last_state_change &&
time_after64(now, wp->last_state_change))
wp->time[wp->state] += now - wp->last_state_change;
wp->state = state;
wp->last_state_change = now;
}
}
static inline void wp_update_state(struct write_point *wp, bool running)
{
enum write_point_state state;
state = running ? WRITE_POINT_running :
!list_empty(&wp->writes) ? WRITE_POINT_waiting_io
: WRITE_POINT_stopped;
__wp_update_state(wp, state);
}
static CLOSURE_CALLBACK(bch2_write_index)
{
closure_type(op, struct bch_write_op, cl);
struct write_point *wp = op->wp;
struct workqueue_struct *wq = index_update_wq(op);
unsigned long flags;
if ((op->flags & BCH_WRITE_DONE) &&
(op->flags & BCH_WRITE_MOVE))
bch2_bio_free_pages_pool(op->c, &op->wbio.bio);
spin_lock_irqsave(&wp->writes_lock, flags);
if (wp->state == WRITE_POINT_waiting_io)
__wp_update_state(wp, WRITE_POINT_waiting_work);
list_add_tail(&op->wp_list, &wp->writes);
spin_unlock_irqrestore (&wp->writes_lock, flags);
queue_work(wq, &wp->index_update_work);
}
static inline void bch2_write_queue(struct bch_write_op *op, struct write_point *wp)
{
op->wp = wp;
if (wp->state == WRITE_POINT_stopped) {
spin_lock_irq(&wp->writes_lock);
__wp_update_state(wp, WRITE_POINT_waiting_io);
spin_unlock_irq(&wp->writes_lock);
}
}
void bch2_write_point_do_index_updates(struct work_struct *work)
{
struct write_point *wp =
container_of(work, struct write_point, index_update_work);
struct bch_write_op *op;
while (1) {
spin_lock_irq(&wp->writes_lock);
op = list_first_entry_or_null(&wp->writes, struct bch_write_op, wp_list);
if (op)
list_del(&op->wp_list);
wp_update_state(wp, op != NULL);
spin_unlock_irq(&wp->writes_lock);
if (!op)
break;
op->flags |= BCH_WRITE_IN_WORKER;
__bch2_write_index(op);
if (!(op->flags & BCH_WRITE_DONE))
__bch2_write(op);
else
bch2_write_done(&op->cl);
}
}
static void bch2_write_endio(struct bio *bio)
{
struct closure *cl = bio->bi_private;
struct bch_write_op *op = container_of(cl, struct bch_write_op, cl);
struct bch_write_bio *wbio = to_wbio(bio);
struct bch_write_bio *parent = wbio->split ? wbio->parent : NULL;
struct bch_fs *c = wbio->c;
struct bch_dev *ca = bch_dev_bkey_exists(c, wbio->dev);
if (bch2_dev_inum_io_err_on(bio->bi_status, ca, BCH_MEMBER_ERROR_write,
op->pos.inode,
wbio->inode_offset << 9,
"data write error: %s",
bch2_blk_status_to_str(bio->bi_status))) {
set_bit(wbio->dev, op->failed.d);
op->flags |= BCH_WRITE_IO_ERROR;
}
if (wbio->nocow)
set_bit(wbio->dev, op->devs_need_flush->d);
if (wbio->have_ioref) {
bch2_latency_acct(ca, wbio->submit_time, WRITE);
percpu_ref_put(&ca->io_ref);
}
if (wbio->bounce)
bch2_bio_free_pages_pool(c, bio);
if (wbio->put_bio)
bio_put(bio);
if (parent)
bio_endio(&parent->bio);
else
closure_put(cl);
}
static void init_append_extent(struct bch_write_op *op,
struct write_point *wp,
struct bversion version,
struct bch_extent_crc_unpacked crc)
{
struct bkey_i_extent *e;
op->pos.offset += crc.uncompressed_size;
e = bkey_extent_init(op->insert_keys.top);
e->k.p = op->pos;
e->k.size = crc.uncompressed_size;
e->k.version = version;
if (crc.csum_type ||
crc.compression_type ||
crc.nonce)
bch2_extent_crc_append(&e->k_i, crc);
bch2_alloc_sectors_append_ptrs_inlined(op->c, wp, &e->k_i, crc.compressed_size,
op->flags & BCH_WRITE_CACHED);
bch2_keylist_push(&op->insert_keys);
}
static struct bio *bch2_write_bio_alloc(struct bch_fs *c,
struct write_point *wp,
struct bio *src,
bool *page_alloc_failed,
void *buf)
{
struct bch_write_bio *wbio;
struct bio *bio;
unsigned output_available =
min(wp->sectors_free << 9, src->bi_iter.bi_size);
unsigned pages = DIV_ROUND_UP(output_available +
(buf
? ((unsigned long) buf & (PAGE_SIZE - 1))
: 0), PAGE_SIZE);
pages = min(pages, BIO_MAX_VECS);
bio = bio_alloc_bioset(NULL, pages, 0,
GFP_NOFS, &c->bio_write);
wbio = wbio_init(bio);
wbio->put_bio = true;
/* copy WRITE_SYNC flag */
wbio->bio.bi_opf = src->bi_opf;
if (buf) {
bch2_bio_map(bio, buf, output_available);
return bio;
}
wbio->bounce = true;
/*
* We can't use mempool for more than c->sb.encoded_extent_max
* worth of pages, but we'd like to allocate more if we can:
*/
bch2_bio_alloc_pages_pool(c, bio,
min_t(unsigned, output_available,
c->opts.encoded_extent_max));
if (bio->bi_iter.bi_size < output_available)
*page_alloc_failed =
bch2_bio_alloc_pages(bio,
output_available -
bio->bi_iter.bi_size,
GFP_NOFS) != 0;
return bio;
}
static int bch2_write_rechecksum(struct bch_fs *c,
struct bch_write_op *op,
unsigned new_csum_type)
{
struct bio *bio = &op->wbio.bio;
struct bch_extent_crc_unpacked new_crc;
int ret;
/* bch2_rechecksum_bio() can't encrypt or decrypt data: */
if (bch2_csum_type_is_encryption(op->crc.csum_type) !=
bch2_csum_type_is_encryption(new_csum_type))
new_csum_type = op->crc.csum_type;
ret = bch2_rechecksum_bio(c, bio, op->version, op->crc,
NULL, &new_crc,
op->crc.offset, op->crc.live_size,
new_csum_type);
if (ret)
return ret;
bio_advance(bio, op->crc.offset << 9);
bio->bi_iter.bi_size = op->crc.live_size << 9;
op->crc = new_crc;
return 0;
}
static int bch2_write_decrypt(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
struct nonce nonce = extent_nonce(op->version, op->crc);
struct bch_csum csum;
int ret;
if (!bch2_csum_type_is_encryption(op->crc.csum_type))
return 0;
/*
* If we need to decrypt data in the write path, we'll no longer be able
* to verify the existing checksum (poly1305 mac, in this case) after
* it's decrypted - this is the last point we'll be able to reverify the
* checksum:
*/
csum = bch2_checksum_bio(c, op->crc.csum_type, nonce, &op->wbio.bio);
if (bch2_crc_cmp(op->crc.csum, csum) && !c->opts.no_data_io)
return -EIO;
ret = bch2_encrypt_bio(c, op->crc.csum_type, nonce, &op->wbio.bio);
op->crc.csum_type = 0;
op->crc.csum = (struct bch_csum) { 0, 0 };
return ret;
}
static enum prep_encoded_ret {
PREP_ENCODED_OK,
PREP_ENCODED_ERR,
PREP_ENCODED_CHECKSUM_ERR,
PREP_ENCODED_DO_WRITE,
} bch2_write_prep_encoded_data(struct bch_write_op *op, struct write_point *wp)
{
struct bch_fs *c = op->c;
struct bio *bio = &op->wbio.bio;
if (!(op->flags & BCH_WRITE_DATA_ENCODED))
return PREP_ENCODED_OK;
BUG_ON(bio_sectors(bio) != op->crc.compressed_size);
/* Can we just write the entire extent as is? */
if (op->crc.uncompressed_size == op->crc.live_size &&
op->crc.uncompressed_size <= c->opts.encoded_extent_max >> 9 &&
op->crc.compressed_size <= wp->sectors_free &&
(op->crc.compression_type == bch2_compression_opt_to_type(op->compression_opt) ||
op->incompressible)) {
if (!crc_is_compressed(op->crc) &&
op->csum_type != op->crc.csum_type &&
bch2_write_rechecksum(c, op, op->csum_type) &&
!c->opts.no_data_io)
return PREP_ENCODED_CHECKSUM_ERR;
return PREP_ENCODED_DO_WRITE;
}
/*
* If the data is compressed and we couldn't write the entire extent as
* is, we have to decompress it:
*/
if (crc_is_compressed(op->crc)) {
struct bch_csum csum;
if (bch2_write_decrypt(op))
return PREP_ENCODED_CHECKSUM_ERR;
/* Last point we can still verify checksum: */
csum = bch2_checksum_bio(c, op->crc.csum_type,
extent_nonce(op->version, op->crc),
bio);
if (bch2_crc_cmp(op->crc.csum, csum) && !c->opts.no_data_io)
return PREP_ENCODED_CHECKSUM_ERR;
if (bch2_bio_uncompress_inplace(c, bio, &op->crc))
return PREP_ENCODED_ERR;
}
/*
* No longer have compressed data after this point - data might be
* encrypted:
*/
/*
* If the data is checksummed and we're only writing a subset,
* rechecksum and adjust bio to point to currently live data:
*/
if ((op->crc.live_size != op->crc.uncompressed_size ||
op->crc.csum_type != op->csum_type) &&
bch2_write_rechecksum(c, op, op->csum_type) &&
!c->opts.no_data_io)
return PREP_ENCODED_CHECKSUM_ERR;
/*
* If we want to compress the data, it has to be decrypted:
*/
if ((op->compression_opt ||
bch2_csum_type_is_encryption(op->crc.csum_type) !=
bch2_csum_type_is_encryption(op->csum_type)) &&
bch2_write_decrypt(op))
return PREP_ENCODED_CHECKSUM_ERR;
return PREP_ENCODED_OK;
}
static int bch2_write_extent(struct bch_write_op *op, struct write_point *wp,
struct bio **_dst)
{
struct bch_fs *c = op->c;
struct bio *src = &op->wbio.bio, *dst = src;
struct bvec_iter saved_iter;
void *ec_buf;
unsigned total_output = 0, total_input = 0;
bool bounce = false;
bool page_alloc_failed = false;
int ret, more = 0;
BUG_ON(!bio_sectors(src));
ec_buf = bch2_writepoint_ec_buf(c, wp);
switch (bch2_write_prep_encoded_data(op, wp)) {
case PREP_ENCODED_OK:
break;
case PREP_ENCODED_ERR:
ret = -EIO;
goto err;
case PREP_ENCODED_CHECKSUM_ERR:
goto csum_err;
case PREP_ENCODED_DO_WRITE:
/* XXX look for bug here */
if (ec_buf) {
dst = bch2_write_bio_alloc(c, wp, src,
&page_alloc_failed,
ec_buf);
bio_copy_data(dst, src);
bounce = true;
}
init_append_extent(op, wp, op->version, op->crc);
goto do_write;
}
if (ec_buf ||
op->compression_opt ||
(op->csum_type &&
!(op->flags & BCH_WRITE_PAGES_STABLE)) ||
(bch2_csum_type_is_encryption(op->csum_type) &&
!(op->flags & BCH_WRITE_PAGES_OWNED))) {
dst = bch2_write_bio_alloc(c, wp, src,
&page_alloc_failed,
ec_buf);
bounce = true;
}
saved_iter = dst->bi_iter;
do {
struct bch_extent_crc_unpacked crc = { 0 };
struct bversion version = op->version;
size_t dst_len = 0, src_len = 0;
if (page_alloc_failed &&
dst->bi_iter.bi_size < (wp->sectors_free << 9) &&
dst->bi_iter.bi_size < c->opts.encoded_extent_max)
break;
BUG_ON(op->compression_opt &&
(op->flags & BCH_WRITE_DATA_ENCODED) &&
bch2_csum_type_is_encryption(op->crc.csum_type));
BUG_ON(op->compression_opt && !bounce);
crc.compression_type = op->incompressible
? BCH_COMPRESSION_TYPE_incompressible
: op->compression_opt
? bch2_bio_compress(c, dst, &dst_len, src, &src_len,
op->compression_opt)
: 0;
if (!crc_is_compressed(crc)) {
dst_len = min(dst->bi_iter.bi_size, src->bi_iter.bi_size);
dst_len = min_t(unsigned, dst_len, wp->sectors_free << 9);
if (op->csum_type)
dst_len = min_t(unsigned, dst_len,
c->opts.encoded_extent_max);
if (bounce) {
swap(dst->bi_iter.bi_size, dst_len);
bio_copy_data(dst, src);
swap(dst->bi_iter.bi_size, dst_len);
}
src_len = dst_len;
}
BUG_ON(!src_len || !dst_len);
if (bch2_csum_type_is_encryption(op->csum_type)) {
if (bversion_zero(version)) {
version.lo = atomic64_inc_return(&c->key_version);
} else {
crc.nonce = op->nonce;
op->nonce += src_len >> 9;
}
}
if ((op->flags & BCH_WRITE_DATA_ENCODED) &&
!crc_is_compressed(crc) &&
bch2_csum_type_is_encryption(op->crc.csum_type) ==
bch2_csum_type_is_encryption(op->csum_type)) {
u8 compression_type = crc.compression_type;
u16 nonce = crc.nonce;
/*
* Note: when we're using rechecksum(), we need to be
* checksumming @src because it has all the data our
* existing checksum covers - if we bounced (because we
* were trying to compress), @dst will only have the
* part of the data the new checksum will cover.
*
* But normally we want to be checksumming post bounce,
* because part of the reason for bouncing is so the
* data can't be modified (by userspace) while it's in
* flight.
*/
if (bch2_rechecksum_bio(c, src, version, op->crc,
&crc, &op->crc,
src_len >> 9,
bio_sectors(src) - (src_len >> 9),
op->csum_type))
goto csum_err;
/*
* rchecksum_bio sets compression_type on crc from op->crc,
* this isn't always correct as sometimes we're changing
* an extent from uncompressed to incompressible.
*/
crc.compression_type = compression_type;
crc.nonce = nonce;
} else {
if ((op->flags & BCH_WRITE_DATA_ENCODED) &&
bch2_rechecksum_bio(c, src, version, op->crc,
NULL, &op->crc,
src_len >> 9,
bio_sectors(src) - (src_len >> 9),
op->crc.csum_type))
goto csum_err;
crc.compressed_size = dst_len >> 9;
crc.uncompressed_size = src_len >> 9;
crc.live_size = src_len >> 9;
swap(dst->bi_iter.bi_size, dst_len);
ret = bch2_encrypt_bio(c, op->csum_type,
extent_nonce(version, crc), dst);
if (ret)
goto err;
crc.csum = bch2_checksum_bio(c, op->csum_type,
extent_nonce(version, crc), dst);
crc.csum_type = op->csum_type;
swap(dst->bi_iter.bi_size, dst_len);
}
init_append_extent(op, wp, version, crc);
if (dst != src)
bio_advance(dst, dst_len);
bio_advance(src, src_len);
total_output += dst_len;
total_input += src_len;
} while (dst->bi_iter.bi_size &&
src->bi_iter.bi_size &&
wp->sectors_free &&
!bch2_keylist_realloc(&op->insert_keys,
op->inline_keys,
ARRAY_SIZE(op->inline_keys),
BKEY_EXTENT_U64s_MAX));
more = src->bi_iter.bi_size != 0;
dst->bi_iter = saved_iter;
if (dst == src && more) {
BUG_ON(total_output != total_input);
dst = bio_split(src, total_input >> 9,
GFP_NOFS, &c->bio_write);
wbio_init(dst)->put_bio = true;
/* copy WRITE_SYNC flag */
dst->bi_opf = src->bi_opf;
}
dst->bi_iter.bi_size = total_output;
do_write:
*_dst = dst;
return more;
csum_err:
bch_err(c, "%s writ error: error verifying existing checksum while rewriting existing data (memory corruption?)",
op->flags & BCH_WRITE_MOVE ? "move" : "user");
ret = -EIO;
err:
if (to_wbio(dst)->bounce)
bch2_bio_free_pages_pool(c, dst);
if (to_wbio(dst)->put_bio)
bio_put(dst);
return ret;
}
static bool bch2_extent_is_writeable(struct bch_write_op *op,
struct bkey_s_c k)
{
struct bch_fs *c = op->c;
struct bkey_s_c_extent e;
struct extent_ptr_decoded p;
const union bch_extent_entry *entry;
unsigned replicas = 0;
if (k.k->type != KEY_TYPE_extent)
return false;
e = bkey_s_c_to_extent(k);
extent_for_each_ptr_decode(e, p, entry) {
if (crc_is_encoded(p.crc) || p.has_ec)
return false;
replicas += bch2_extent_ptr_durability(c, &p);
}
return replicas >= op->opts.data_replicas;
}
static inline void bch2_nocow_write_unlock(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
for_each_keylist_key(&op->insert_keys, k) {
struct bkey_ptrs_c ptrs = bch2_bkey_ptrs_c(bkey_i_to_s_c(k));
bkey_for_each_ptr(ptrs, ptr)
bch2_bucket_nocow_unlock(&c->nocow_locks,
PTR_BUCKET_POS(c, ptr),
BUCKET_NOCOW_LOCK_UPDATE);
}
}
static int bch2_nocow_write_convert_one_unwritten(struct btree_trans *trans,
struct btree_iter *iter,
struct bkey_i *orig,
struct bkey_s_c k,
u64 new_i_size)
{
if (!bch2_extents_match(bkey_i_to_s_c(orig), k)) {
/* trace this */
return 0;
}
struct bkey_i *new = bch2_bkey_make_mut_noupdate(trans, k);
int ret = PTR_ERR_OR_ZERO(new);
if (ret)
return ret;
bch2_cut_front(bkey_start_pos(&orig->k), new);
bch2_cut_back(orig->k.p, new);
struct bkey_ptrs ptrs = bch2_bkey_ptrs(bkey_i_to_s(new));
bkey_for_each_ptr(ptrs, ptr)
ptr->unwritten = 0;
/*
* Note that we're not calling bch2_subvol_get_snapshot() in this path -
* that was done when we kicked off the write, and here it's important
* that we update the extent that we wrote to - even if a snapshot has
* since been created. The write is still outstanding, so we're ok
* w.r.t. snapshot atomicity:
*/
return bch2_extent_update_i_size_sectors(trans, iter,
min(new->k.p.offset << 9, new_i_size), 0) ?:
bch2_trans_update(trans, iter, new,
BTREE_UPDATE_INTERNAL_SNAPSHOT_NODE);
}
static void bch2_nocow_write_convert_unwritten(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
struct btree_trans *trans = bch2_trans_get(c);
for_each_keylist_key(&op->insert_keys, orig) {
int ret = for_each_btree_key_upto_commit(trans, iter, BTREE_ID_extents,
bkey_start_pos(&orig->k), orig->k.p,
BTREE_ITER_INTENT, k,
NULL, NULL, BCH_TRANS_COMMIT_no_enospc, ({
bch2_nocow_write_convert_one_unwritten(trans, &iter, orig, k, op->new_i_size);
}));
if (ret && !bch2_err_matches(ret, EROFS)) {
struct bkey_i *insert = bch2_keylist_front(&op->insert_keys);
bch_err_inum_offset_ratelimited(c,
insert->k.p.inode, insert->k.p.offset << 9,
"%s write error while doing btree update: %s",
op->flags & BCH_WRITE_MOVE ? "move" : "user",
bch2_err_str(ret));
}
if (ret) {
op->error = ret;
break;
}
}
bch2_trans_put(trans);
}
static void __bch2_nocow_write_done(struct bch_write_op *op)
{
bch2_nocow_write_unlock(op);
if (unlikely(op->flags & BCH_WRITE_IO_ERROR)) {
op->error = -EIO;
} else if (unlikely(op->flags & BCH_WRITE_CONVERT_UNWRITTEN))
bch2_nocow_write_convert_unwritten(op);
}
static CLOSURE_CALLBACK(bch2_nocow_write_done)
{
closure_type(op, struct bch_write_op, cl);
__bch2_nocow_write_done(op);
bch2_write_done(cl);
}
struct bucket_to_lock {
struct bpos b;
unsigned gen;
struct nocow_lock_bucket *l;
};
static void bch2_nocow_write(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
struct btree_trans *trans;
struct btree_iter iter;
struct bkey_s_c k;
DARRAY_PREALLOCATED(struct bucket_to_lock, 3) buckets;
u32 snapshot;
struct bucket_to_lock *stale_at;
int ret;
if (op->flags & BCH_WRITE_MOVE)
return;
darray_init(&buckets);
trans = bch2_trans_get(c);
retry:
bch2_trans_begin(trans);
ret = bch2_subvolume_get_snapshot(trans, op->subvol, &snapshot);
if (unlikely(ret))
goto err;
bch2_trans_iter_init(trans, &iter, BTREE_ID_extents,
SPOS(op->pos.inode, op->pos.offset, snapshot),
BTREE_ITER_SLOTS);
while (1) {
struct bio *bio = &op->wbio.bio;
buckets.nr = 0;
k = bch2_btree_iter_peek_slot(&iter);
ret = bkey_err(k);
if (ret)
break;
/* fall back to normal cow write path? */
if (unlikely(k.k->p.snapshot != snapshot ||
!bch2_extent_is_writeable(op, k)))
break;
if (bch2_keylist_realloc(&op->insert_keys,
op->inline_keys,
ARRAY_SIZE(op->inline_keys),
k.k->u64s))
break;
/* Get iorefs before dropping btree locks: */
struct bkey_ptrs_c ptrs = bch2_bkey_ptrs_c(k);
bkey_for_each_ptr(ptrs, ptr) {
struct bpos b = PTR_BUCKET_POS(c, ptr);
struct nocow_lock_bucket *l =
bucket_nocow_lock(&c->nocow_locks, bucket_to_u64(b));
prefetch(l);
if (unlikely(!bch2_dev_get_ioref(bch_dev_bkey_exists(c, ptr->dev), WRITE)))
goto err_get_ioref;
/* XXX allocating memory with btree locks held - rare */
darray_push_gfp(&buckets, ((struct bucket_to_lock) {
.b = b, .gen = ptr->gen, .l = l,
}), GFP_KERNEL|__GFP_NOFAIL);
if (ptr->unwritten)
op->flags |= BCH_WRITE_CONVERT_UNWRITTEN;
}
/* Unlock before taking nocow locks, doing IO: */
bkey_reassemble(op->insert_keys.top, k);
bch2_trans_unlock(trans);
bch2_cut_front(op->pos, op->insert_keys.top);
if (op->flags & BCH_WRITE_CONVERT_UNWRITTEN)
bch2_cut_back(POS(op->pos.inode, op->pos.offset + bio_sectors(bio)), op->insert_keys.top);
darray_for_each(buckets, i) {
struct bch_dev *ca = bch_dev_bkey_exists(c, i->b.inode);
__bch2_bucket_nocow_lock(&c->nocow_locks, i->l,
bucket_to_u64(i->b),
BUCKET_NOCOW_LOCK_UPDATE);
rcu_read_lock();
bool stale = gen_after(*bucket_gen(ca, i->b.offset), i->gen);
rcu_read_unlock();
if (unlikely(stale)) {
stale_at = i;
goto err_bucket_stale;
}
}
bio = &op->wbio.bio;
if (k.k->p.offset < op->pos.offset + bio_sectors(bio)) {
bio = bio_split(bio, k.k->p.offset - op->pos.offset,
GFP_KERNEL, &c->bio_write);
wbio_init(bio)->put_bio = true;
bio->bi_opf = op->wbio.bio.bi_opf;
} else {
op->flags |= BCH_WRITE_DONE;
}
op->pos.offset += bio_sectors(bio);
op->written += bio_sectors(bio);
bio->bi_end_io = bch2_write_endio;
bio->bi_private = &op->cl;
bio->bi_opf |= REQ_OP_WRITE;
closure_get(&op->cl);
bch2_submit_wbio_replicas(to_wbio(bio), c, BCH_DATA_user,
op->insert_keys.top, true);
bch2_keylist_push(&op->insert_keys);
if (op->flags & BCH_WRITE_DONE)
break;
bch2_btree_iter_advance(&iter);
}
out:
bch2_trans_iter_exit(trans, &iter);
err:
if (bch2_err_matches(ret, BCH_ERR_transaction_restart))
goto retry;
if (ret) {
bch_err_inum_offset_ratelimited(c,
op->pos.inode, op->pos.offset << 9,
"%s: btree lookup error %s", __func__, bch2_err_str(ret));
op->error = ret;
op->flags |= BCH_WRITE_DONE;
}
bch2_trans_put(trans);
darray_exit(&buckets);
/* fallback to cow write path? */
if (!(op->flags & BCH_WRITE_DONE)) {
closure_sync(&op->cl);
__bch2_nocow_write_done(op);
op->insert_keys.top = op->insert_keys.keys;
} else if (op->flags & BCH_WRITE_SYNC) {
closure_sync(&op->cl);
bch2_nocow_write_done(&op->cl.work);
} else {
/*
* XXX
* needs to run out of process context because ei_quota_lock is
* a mutex
*/
continue_at(&op->cl, bch2_nocow_write_done, index_update_wq(op));
}
return;
err_get_ioref:
darray_for_each(buckets, i)
percpu_ref_put(&bch_dev_bkey_exists(c, i->b.inode)->io_ref);
/* Fall back to COW path: */
goto out;
err_bucket_stale:
darray_for_each(buckets, i) {
bch2_bucket_nocow_unlock(&c->nocow_locks, i->b, BUCKET_NOCOW_LOCK_UPDATE);
if (i == stale_at)
break;
}
/* We can retry this: */
ret = -BCH_ERR_transaction_restart;
goto err_get_ioref;
}
static void __bch2_write(struct bch_write_op *op)
{
struct bch_fs *c = op->c;
struct write_point *wp = NULL;
struct bio *bio = NULL;
unsigned nofs_flags;
int ret;
nofs_flags = memalloc_nofs_save();
if (unlikely(op->opts.nocow && c->opts.nocow_enabled)) {
bch2_nocow_write(op);
if (op->flags & BCH_WRITE_DONE)
goto out_nofs_restore;
}
again:
memset(&op->failed, 0, sizeof(op->failed));
do {
struct bkey_i *key_to_write;
unsigned key_to_write_offset = op->insert_keys.top_p -
op->insert_keys.keys_p;
/* +1 for possible cache device: */
if (op->open_buckets.nr + op->nr_replicas + 1 >
ARRAY_SIZE(op->open_buckets.v))
break;
if (bch2_keylist_realloc(&op->insert_keys,
op->inline_keys,
ARRAY_SIZE(op->inline_keys),
BKEY_EXTENT_U64s_MAX))
break;
/*
* The copygc thread is now global, which means it's no longer
* freeing up space on specific disks, which means that
* allocations for specific disks may hang arbitrarily long:
*/
ret = bch2_trans_do(c, NULL, NULL, 0,
bch2_alloc_sectors_start_trans(trans,
op->target,
op->opts.erasure_code && !(op->flags & BCH_WRITE_CACHED),
op->write_point,
&op->devs_have,
op->nr_replicas,
op->nr_replicas_required,
op->watermark,
op->flags,
(op->flags & (BCH_WRITE_ALLOC_NOWAIT|
BCH_WRITE_ONLY_SPECIFIED_DEVS))
? NULL : &op->cl, &wp));
if (unlikely(ret)) {
if (bch2_err_matches(ret, BCH_ERR_operation_blocked))
break;
goto err;
}
EBUG_ON(!wp);
bch2_open_bucket_get(c, wp, &op->open_buckets);
ret = bch2_write_extent(op, wp, &bio);
bch2_alloc_sectors_done_inlined(c, wp);
err:
if (ret <= 0) {
op->flags |= BCH_WRITE_DONE;
if (ret < 0) {
if (!(op->flags & BCH_WRITE_ALLOC_NOWAIT))
bch_err_inum_offset_ratelimited(c,
op->pos.inode,
op->pos.offset << 9,
"%s(): %s error: %s", __func__,
op->flags & BCH_WRITE_MOVE ? "move" : "user",
bch2_err_str(ret));
op->error = ret;
break;
}
}
bio->bi_end_io = bch2_write_endio;
bio->bi_private = &op->cl;
bio->bi_opf |= REQ_OP_WRITE;
closure_get(bio->bi_private);
key_to_write = (void *) (op->insert_keys.keys_p +
key_to_write_offset);
bch2_submit_wbio_replicas(to_wbio(bio), c, BCH_DATA_user,
key_to_write, false);
} while (ret);
/*
* Sync or no?
*
* If we're running asynchronously, wne may still want to block
* synchronously here if we weren't able to submit all of the IO at
* once, as that signals backpressure to the caller.
*/
if ((op->flags & BCH_WRITE_SYNC) ||
(!(op->flags & BCH_WRITE_DONE) &&
!(op->flags & BCH_WRITE_IN_WORKER))) {
closure_sync(&op->cl);
__bch2_write_index(op);
if (!(op->flags & BCH_WRITE_DONE))
goto again;
bch2_write_done(&op->cl);
} else {
bch2_write_queue(op, wp);
continue_at(&op->cl, bch2_write_index, NULL);
}
out_nofs_restore:
memalloc_nofs_restore(nofs_flags);
}
static void bch2_write_data_inline(struct bch_write_op *op, unsigned data_len)
{
struct bio *bio = &op->wbio.bio;
struct bvec_iter iter;
struct bkey_i_inline_data *id;
unsigned sectors;
int ret;
op->flags |= BCH_WRITE_WROTE_DATA_INLINE;
op->flags |= BCH_WRITE_DONE;
bch2_check_set_feature(op->c, BCH_FEATURE_inline_data);
ret = bch2_keylist_realloc(&op->insert_keys, op->inline_keys,
ARRAY_SIZE(op->inline_keys),
BKEY_U64s + DIV_ROUND_UP(data_len, 8));
if (ret) {
op->error = ret;
goto err;
}
sectors = bio_sectors(bio);
op->pos.offset += sectors;
id = bkey_inline_data_init(op->insert_keys.top);
id->k.p = op->pos;
id->k.version = op->version;
id->k.size = sectors;
iter = bio->bi_iter;
iter.bi_size = data_len;
memcpy_from_bio(id->v.data, bio, iter);
while (data_len & 7)
id->v.data[data_len++] = '\0';
set_bkey_val_bytes(&id->k, data_len);
bch2_keylist_push(&op->insert_keys);
__bch2_write_index(op);
err:
bch2_write_done(&op->cl);
}
/**
* bch2_write() - handle a write to a cache device or flash only volume
* @cl: &bch_write_op->cl
*
* This is the starting point for any data to end up in a cache device; it could
* be from a normal write, or a writeback write, or a write to a flash only
* volume - it's also used by the moving garbage collector to compact data in
* mostly empty buckets.
*
* It first writes the data to the cache, creating a list of keys to be inserted
* (if the data won't fit in a single open bucket, there will be multiple keys);
* after the data is written it calls bch_journal, and after the keys have been
* added to the next journal write they're inserted into the btree.
*
* If op->discard is true, instead of inserting the data it invalidates the
* region of the cache represented by op->bio and op->inode.
*/
CLOSURE_CALLBACK(bch2_write)
{
closure_type(op, struct bch_write_op, cl);
struct bio *bio = &op->wbio.bio;
struct bch_fs *c = op->c;
unsigned data_len;
EBUG_ON(op->cl.parent);
BUG_ON(!op->nr_replicas);
BUG_ON(!op->write_point.v);
BUG_ON(bkey_eq(op->pos, POS_MAX));
op->nr_replicas_required = min_t(unsigned, op->nr_replicas_required, op->nr_replicas);
op->start_time = local_clock();
bch2_keylist_init(&op->insert_keys, op->inline_keys);
wbio_init(bio)->put_bio = false;
if (bio->bi_iter.bi_size & (c->opts.block_size - 1)) {
bch_err_inum_offset_ratelimited(c,
op->pos.inode,
op->pos.offset << 9,
"%s write error: misaligned write",
op->flags & BCH_WRITE_MOVE ? "move" : "user");
op->error = -EIO;
goto err;
}
if (c->opts.nochanges) {
op->error = -BCH_ERR_erofs_no_writes;
goto err;
}
if (!(op->flags & BCH_WRITE_MOVE) &&
!bch2_write_ref_tryget(c, BCH_WRITE_REF_write)) {
op->error = -BCH_ERR_erofs_no_writes;
goto err;
}
this_cpu_add(c->counters[BCH_COUNTER_io_write], bio_sectors(bio));
bch2_increment_clock(c, bio_sectors(bio), WRITE);
data_len = min_t(u64, bio->bi_iter.bi_size,
op->new_i_size - (op->pos.offset << 9));
if (c->opts.inline_data &&
data_len <= min(block_bytes(c) / 2, 1024U)) {
bch2_write_data_inline(op, data_len);
return;
}
__bch2_write(op);
return;
err:
bch2_disk_reservation_put(c, &op->res);
closure_debug_destroy(&op->cl);
if (op->end_io)
op->end_io(op);
}
static const char * const bch2_write_flags[] = {
#define x(f) #f,
BCH_WRITE_FLAGS()
#undef x
NULL
};
void bch2_write_op_to_text(struct printbuf *out, struct bch_write_op *op)
{
prt_str(out, "pos: ");
bch2_bpos_to_text(out, op->pos);
prt_newline(out);
printbuf_indent_add(out, 2);
prt_str(out, "started: ");
bch2_pr_time_units(out, local_clock() - op->start_time);
prt_newline(out);
prt_str(out, "flags: ");
prt_bitflags(out, bch2_write_flags, op->flags);
prt_newline(out);
prt_printf(out, "ref: %u", closure_nr_remaining(&op->cl));
prt_newline(out);
printbuf_indent_sub(out, 2);
}
void bch2_fs_io_write_exit(struct bch_fs *c)
{
mempool_exit(&c->bio_bounce_pages);
bioset_exit(&c->bio_write);
}
int bch2_fs_io_write_init(struct bch_fs *c)
{
if (bioset_init(&c->bio_write, 1, offsetof(struct bch_write_bio, bio),
BIOSET_NEED_BVECS))
return -BCH_ERR_ENOMEM_bio_write_init;
if (mempool_init_page_pool(&c->bio_bounce_pages,
max_t(unsigned,
c->opts.btree_node_size,
c->opts.encoded_extent_max) /
PAGE_SIZE, 0))
return -BCH_ERR_ENOMEM_bio_bounce_pages_init;
return 0;
}
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