linux/fs/btrfs/delayed-inode.c
Boris Burkov 71537e35c3 btrfs: record delayed inode root in transaction
When running delayed inode updates, we do not record the inode's root in
the transaction, but we do allocate PREALLOC and thus converted PERTRANS
space for it. To be sure we free that PERTRANS meta rsv, we must ensure
that we record the root in the transaction.

Fixes: 4f5427ccce ("btrfs: delayed-inode: Use new qgroup meta rsv for delayed inode and item")
CC: stable@vger.kernel.org # 6.1+
Reviewed-by: Qu Wenruo <wqu@suse.com>
Signed-off-by: Boris Burkov <boris@bur.io>
Signed-off-by: David Sterba <dsterba@suse.com>
2024-04-02 19:18:33 +02:00

2213 lines
62 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2011 Fujitsu. All rights reserved.
* Written by Miao Xie <miaox@cn.fujitsu.com>
*/
#include <linux/slab.h>
#include <linux/iversion.h>
#include "ctree.h"
#include "fs.h"
#include "messages.h"
#include "misc.h"
#include "delayed-inode.h"
#include "disk-io.h"
#include "transaction.h"
#include "qgroup.h"
#include "locking.h"
#include "inode-item.h"
#include "space-info.h"
#include "accessors.h"
#include "file-item.h"
#define BTRFS_DELAYED_WRITEBACK 512
#define BTRFS_DELAYED_BACKGROUND 128
#define BTRFS_DELAYED_BATCH 16
static struct kmem_cache *delayed_node_cache;
int __init btrfs_delayed_inode_init(void)
{
delayed_node_cache = KMEM_CACHE(btrfs_delayed_node, 0);
if (!delayed_node_cache)
return -ENOMEM;
return 0;
}
void __cold btrfs_delayed_inode_exit(void)
{
kmem_cache_destroy(delayed_node_cache);
}
void btrfs_init_delayed_root(struct btrfs_delayed_root *delayed_root)
{
atomic_set(&delayed_root->items, 0);
atomic_set(&delayed_root->items_seq, 0);
delayed_root->nodes = 0;
spin_lock_init(&delayed_root->lock);
init_waitqueue_head(&delayed_root->wait);
INIT_LIST_HEAD(&delayed_root->node_list);
INIT_LIST_HEAD(&delayed_root->prepare_list);
}
static inline void btrfs_init_delayed_node(
struct btrfs_delayed_node *delayed_node,
struct btrfs_root *root, u64 inode_id)
{
delayed_node->root = root;
delayed_node->inode_id = inode_id;
refcount_set(&delayed_node->refs, 0);
delayed_node->ins_root = RB_ROOT_CACHED;
delayed_node->del_root = RB_ROOT_CACHED;
mutex_init(&delayed_node->mutex);
INIT_LIST_HEAD(&delayed_node->n_list);
INIT_LIST_HEAD(&delayed_node->p_list);
}
static struct btrfs_delayed_node *btrfs_get_delayed_node(
struct btrfs_inode *btrfs_inode)
{
struct btrfs_root *root = btrfs_inode->root;
u64 ino = btrfs_ino(btrfs_inode);
struct btrfs_delayed_node *node;
node = READ_ONCE(btrfs_inode->delayed_node);
if (node) {
refcount_inc(&node->refs);
return node;
}
spin_lock(&root->inode_lock);
node = xa_load(&root->delayed_nodes, ino);
if (node) {
if (btrfs_inode->delayed_node) {
refcount_inc(&node->refs); /* can be accessed */
BUG_ON(btrfs_inode->delayed_node != node);
spin_unlock(&root->inode_lock);
return node;
}
/*
* It's possible that we're racing into the middle of removing
* this node from the xarray. In this case, the refcount
* was zero and it should never go back to one. Just return
* NULL like it was never in the xarray at all; our release
* function is in the process of removing it.
*
* Some implementations of refcount_inc refuse to bump the
* refcount once it has hit zero. If we don't do this dance
* here, refcount_inc() may decide to just WARN_ONCE() instead
* of actually bumping the refcount.
*
* If this node is properly in the xarray, we want to bump the
* refcount twice, once for the inode and once for this get
* operation.
*/
if (refcount_inc_not_zero(&node->refs)) {
refcount_inc(&node->refs);
btrfs_inode->delayed_node = node;
} else {
node = NULL;
}
spin_unlock(&root->inode_lock);
return node;
}
spin_unlock(&root->inode_lock);
return NULL;
}
/* Will return either the node or PTR_ERR(-ENOMEM) */
static struct btrfs_delayed_node *btrfs_get_or_create_delayed_node(
struct btrfs_inode *btrfs_inode)
{
struct btrfs_delayed_node *node;
struct btrfs_root *root = btrfs_inode->root;
u64 ino = btrfs_ino(btrfs_inode);
int ret;
void *ptr;
again:
node = btrfs_get_delayed_node(btrfs_inode);
if (node)
return node;
node = kmem_cache_zalloc(delayed_node_cache, GFP_NOFS);
if (!node)
return ERR_PTR(-ENOMEM);
btrfs_init_delayed_node(node, root, ino);
/* Cached in the inode and can be accessed. */
refcount_set(&node->refs, 2);
/* Allocate and reserve the slot, from now it can return a NULL from xa_load(). */
ret = xa_reserve(&root->delayed_nodes, ino, GFP_NOFS);
if (ret == -ENOMEM) {
kmem_cache_free(delayed_node_cache, node);
return ERR_PTR(-ENOMEM);
}
spin_lock(&root->inode_lock);
ptr = xa_load(&root->delayed_nodes, ino);
if (ptr) {
/* Somebody inserted it, go back and read it. */
spin_unlock(&root->inode_lock);
kmem_cache_free(delayed_node_cache, node);
node = NULL;
goto again;
}
ptr = xa_store(&root->delayed_nodes, ino, node, GFP_ATOMIC);
ASSERT(xa_err(ptr) != -EINVAL);
ASSERT(xa_err(ptr) != -ENOMEM);
ASSERT(ptr == NULL);
btrfs_inode->delayed_node = node;
spin_unlock(&root->inode_lock);
return node;
}
/*
* Call it when holding delayed_node->mutex
*
* If mod = 1, add this node into the prepared list.
*/
static void btrfs_queue_delayed_node(struct btrfs_delayed_root *root,
struct btrfs_delayed_node *node,
int mod)
{
spin_lock(&root->lock);
if (test_bit(BTRFS_DELAYED_NODE_IN_LIST, &node->flags)) {
if (!list_empty(&node->p_list))
list_move_tail(&node->p_list, &root->prepare_list);
else if (mod)
list_add_tail(&node->p_list, &root->prepare_list);
} else {
list_add_tail(&node->n_list, &root->node_list);
list_add_tail(&node->p_list, &root->prepare_list);
refcount_inc(&node->refs); /* inserted into list */
root->nodes++;
set_bit(BTRFS_DELAYED_NODE_IN_LIST, &node->flags);
}
spin_unlock(&root->lock);
}
/* Call it when holding delayed_node->mutex */
static void btrfs_dequeue_delayed_node(struct btrfs_delayed_root *root,
struct btrfs_delayed_node *node)
{
spin_lock(&root->lock);
if (test_bit(BTRFS_DELAYED_NODE_IN_LIST, &node->flags)) {
root->nodes--;
refcount_dec(&node->refs); /* not in the list */
list_del_init(&node->n_list);
if (!list_empty(&node->p_list))
list_del_init(&node->p_list);
clear_bit(BTRFS_DELAYED_NODE_IN_LIST, &node->flags);
}
spin_unlock(&root->lock);
}
static struct btrfs_delayed_node *btrfs_first_delayed_node(
struct btrfs_delayed_root *delayed_root)
{
struct list_head *p;
struct btrfs_delayed_node *node = NULL;
spin_lock(&delayed_root->lock);
if (list_empty(&delayed_root->node_list))
goto out;
p = delayed_root->node_list.next;
node = list_entry(p, struct btrfs_delayed_node, n_list);
refcount_inc(&node->refs);
out:
spin_unlock(&delayed_root->lock);
return node;
}
static struct btrfs_delayed_node *btrfs_next_delayed_node(
struct btrfs_delayed_node *node)
{
struct btrfs_delayed_root *delayed_root;
struct list_head *p;
struct btrfs_delayed_node *next = NULL;
delayed_root = node->root->fs_info->delayed_root;
spin_lock(&delayed_root->lock);
if (!test_bit(BTRFS_DELAYED_NODE_IN_LIST, &node->flags)) {
/* not in the list */
if (list_empty(&delayed_root->node_list))
goto out;
p = delayed_root->node_list.next;
} else if (list_is_last(&node->n_list, &delayed_root->node_list))
goto out;
else
p = node->n_list.next;
next = list_entry(p, struct btrfs_delayed_node, n_list);
refcount_inc(&next->refs);
out:
spin_unlock(&delayed_root->lock);
return next;
}
static void __btrfs_release_delayed_node(
struct btrfs_delayed_node *delayed_node,
int mod)
{
struct btrfs_delayed_root *delayed_root;
if (!delayed_node)
return;
delayed_root = delayed_node->root->fs_info->delayed_root;
mutex_lock(&delayed_node->mutex);
if (delayed_node->count)
btrfs_queue_delayed_node(delayed_root, delayed_node, mod);
else
btrfs_dequeue_delayed_node(delayed_root, delayed_node);
mutex_unlock(&delayed_node->mutex);
if (refcount_dec_and_test(&delayed_node->refs)) {
struct btrfs_root *root = delayed_node->root;
spin_lock(&root->inode_lock);
/*
* Once our refcount goes to zero, nobody is allowed to bump it
* back up. We can delete it now.
*/
ASSERT(refcount_read(&delayed_node->refs) == 0);
xa_erase(&root->delayed_nodes, delayed_node->inode_id);
spin_unlock(&root->inode_lock);
kmem_cache_free(delayed_node_cache, delayed_node);
}
}
static inline void btrfs_release_delayed_node(struct btrfs_delayed_node *node)
{
__btrfs_release_delayed_node(node, 0);
}
static struct btrfs_delayed_node *btrfs_first_prepared_delayed_node(
struct btrfs_delayed_root *delayed_root)
{
struct list_head *p;
struct btrfs_delayed_node *node = NULL;
spin_lock(&delayed_root->lock);
if (list_empty(&delayed_root->prepare_list))
goto out;
p = delayed_root->prepare_list.next;
list_del_init(p);
node = list_entry(p, struct btrfs_delayed_node, p_list);
refcount_inc(&node->refs);
out:
spin_unlock(&delayed_root->lock);
return node;
}
static inline void btrfs_release_prepared_delayed_node(
struct btrfs_delayed_node *node)
{
__btrfs_release_delayed_node(node, 1);
}
static struct btrfs_delayed_item *btrfs_alloc_delayed_item(u16 data_len,
struct btrfs_delayed_node *node,
enum btrfs_delayed_item_type type)
{
struct btrfs_delayed_item *item;
item = kmalloc(struct_size(item, data, data_len), GFP_NOFS);
if (item) {
item->data_len = data_len;
item->type = type;
item->bytes_reserved = 0;
item->delayed_node = node;
RB_CLEAR_NODE(&item->rb_node);
INIT_LIST_HEAD(&item->log_list);
item->logged = false;
refcount_set(&item->refs, 1);
}
return item;
}
/*
* Look up the delayed item by key.
*
* @delayed_node: pointer to the delayed node
* @index: the dir index value to lookup (offset of a dir index key)
*
* Note: if we don't find the right item, we will return the prev item and
* the next item.
*/
static struct btrfs_delayed_item *__btrfs_lookup_delayed_item(
struct rb_root *root,
u64 index)
{
struct rb_node *node = root->rb_node;
struct btrfs_delayed_item *delayed_item = NULL;
while (node) {
delayed_item = rb_entry(node, struct btrfs_delayed_item,
rb_node);
if (delayed_item->index < index)
node = node->rb_right;
else if (delayed_item->index > index)
node = node->rb_left;
else
return delayed_item;
}
return NULL;
}
static int __btrfs_add_delayed_item(struct btrfs_delayed_node *delayed_node,
struct btrfs_delayed_item *ins)
{
struct rb_node **p, *node;
struct rb_node *parent_node = NULL;
struct rb_root_cached *root;
struct btrfs_delayed_item *item;
bool leftmost = true;
if (ins->type == BTRFS_DELAYED_INSERTION_ITEM)
root = &delayed_node->ins_root;
else
root = &delayed_node->del_root;
p = &root->rb_root.rb_node;
node = &ins->rb_node;
while (*p) {
parent_node = *p;
item = rb_entry(parent_node, struct btrfs_delayed_item,
rb_node);
if (item->index < ins->index) {
p = &(*p)->rb_right;
leftmost = false;
} else if (item->index > ins->index) {
p = &(*p)->rb_left;
} else {
return -EEXIST;
}
}
rb_link_node(node, parent_node, p);
rb_insert_color_cached(node, root, leftmost);
if (ins->type == BTRFS_DELAYED_INSERTION_ITEM &&
ins->index >= delayed_node->index_cnt)
delayed_node->index_cnt = ins->index + 1;
delayed_node->count++;
atomic_inc(&delayed_node->root->fs_info->delayed_root->items);
return 0;
}
static void finish_one_item(struct btrfs_delayed_root *delayed_root)
{
int seq = atomic_inc_return(&delayed_root->items_seq);
/* atomic_dec_return implies a barrier */
if ((atomic_dec_return(&delayed_root->items) <
BTRFS_DELAYED_BACKGROUND || seq % BTRFS_DELAYED_BATCH == 0))
cond_wake_up_nomb(&delayed_root->wait);
}
static void __btrfs_remove_delayed_item(struct btrfs_delayed_item *delayed_item)
{
struct btrfs_delayed_node *delayed_node = delayed_item->delayed_node;
struct rb_root_cached *root;
struct btrfs_delayed_root *delayed_root;
/* Not inserted, ignore it. */
if (RB_EMPTY_NODE(&delayed_item->rb_node))
return;
/* If it's in a rbtree, then we need to have delayed node locked. */
lockdep_assert_held(&delayed_node->mutex);
delayed_root = delayed_node->root->fs_info->delayed_root;
if (delayed_item->type == BTRFS_DELAYED_INSERTION_ITEM)
root = &delayed_node->ins_root;
else
root = &delayed_node->del_root;
rb_erase_cached(&delayed_item->rb_node, root);
RB_CLEAR_NODE(&delayed_item->rb_node);
delayed_node->count--;
finish_one_item(delayed_root);
}
static void btrfs_release_delayed_item(struct btrfs_delayed_item *item)
{
if (item) {
__btrfs_remove_delayed_item(item);
if (refcount_dec_and_test(&item->refs))
kfree(item);
}
}
static struct btrfs_delayed_item *__btrfs_first_delayed_insertion_item(
struct btrfs_delayed_node *delayed_node)
{
struct rb_node *p;
struct btrfs_delayed_item *item = NULL;
p = rb_first_cached(&delayed_node->ins_root);
if (p)
item = rb_entry(p, struct btrfs_delayed_item, rb_node);
return item;
}
static struct btrfs_delayed_item *__btrfs_first_delayed_deletion_item(
struct btrfs_delayed_node *delayed_node)
{
struct rb_node *p;
struct btrfs_delayed_item *item = NULL;
p = rb_first_cached(&delayed_node->del_root);
if (p)
item = rb_entry(p, struct btrfs_delayed_item, rb_node);
return item;
}
static struct btrfs_delayed_item *__btrfs_next_delayed_item(
struct btrfs_delayed_item *item)
{
struct rb_node *p;
struct btrfs_delayed_item *next = NULL;
p = rb_next(&item->rb_node);
if (p)
next = rb_entry(p, struct btrfs_delayed_item, rb_node);
return next;
}
static int btrfs_delayed_item_reserve_metadata(struct btrfs_trans_handle *trans,
struct btrfs_delayed_item *item)
{
struct btrfs_block_rsv *src_rsv;
struct btrfs_block_rsv *dst_rsv;
struct btrfs_fs_info *fs_info = trans->fs_info;
u64 num_bytes;
int ret;
if (!trans->bytes_reserved)
return 0;
src_rsv = trans->block_rsv;
dst_rsv = &fs_info->delayed_block_rsv;
num_bytes = btrfs_calc_insert_metadata_size(fs_info, 1);
/*
* Here we migrate space rsv from transaction rsv, since have already
* reserved space when starting a transaction. So no need to reserve
* qgroup space here.
*/
ret = btrfs_block_rsv_migrate(src_rsv, dst_rsv, num_bytes, true);
if (!ret) {
trace_btrfs_space_reservation(fs_info, "delayed_item",
item->delayed_node->inode_id,
num_bytes, 1);
/*
* For insertions we track reserved metadata space by accounting
* for the number of leaves that will be used, based on the delayed
* node's curr_index_batch_size and index_item_leaves fields.
*/
if (item->type == BTRFS_DELAYED_DELETION_ITEM)
item->bytes_reserved = num_bytes;
}
return ret;
}
static void btrfs_delayed_item_release_metadata(struct btrfs_root *root,
struct btrfs_delayed_item *item)
{
struct btrfs_block_rsv *rsv;
struct btrfs_fs_info *fs_info = root->fs_info;
if (!item->bytes_reserved)
return;
rsv = &fs_info->delayed_block_rsv;
/*
* Check btrfs_delayed_item_reserve_metadata() to see why we don't need
* to release/reserve qgroup space.
*/
trace_btrfs_space_reservation(fs_info, "delayed_item",
item->delayed_node->inode_id,
item->bytes_reserved, 0);
btrfs_block_rsv_release(fs_info, rsv, item->bytes_reserved, NULL);
}
static void btrfs_delayed_item_release_leaves(struct btrfs_delayed_node *node,
unsigned int num_leaves)
{
struct btrfs_fs_info *fs_info = node->root->fs_info;
const u64 bytes = btrfs_calc_insert_metadata_size(fs_info, num_leaves);
/* There are no space reservations during log replay, bail out. */
if (test_bit(BTRFS_FS_LOG_RECOVERING, &fs_info->flags))
return;
trace_btrfs_space_reservation(fs_info, "delayed_item", node->inode_id,
bytes, 0);
btrfs_block_rsv_release(fs_info, &fs_info->delayed_block_rsv, bytes, NULL);
}
static int btrfs_delayed_inode_reserve_metadata(
struct btrfs_trans_handle *trans,
struct btrfs_root *root,
struct btrfs_delayed_node *node)
{
struct btrfs_fs_info *fs_info = root->fs_info;
struct btrfs_block_rsv *src_rsv;
struct btrfs_block_rsv *dst_rsv;
u64 num_bytes;
int ret;
src_rsv = trans->block_rsv;
dst_rsv = &fs_info->delayed_block_rsv;
num_bytes = btrfs_calc_metadata_size(fs_info, 1);
/*
* btrfs_dirty_inode will update the inode under btrfs_join_transaction
* which doesn't reserve space for speed. This is a problem since we
* still need to reserve space for this update, so try to reserve the
* space.
*
* Now if src_rsv == delalloc_block_rsv we'll let it just steal since
* we always reserve enough to update the inode item.
*/
if (!src_rsv || (!trans->bytes_reserved &&
src_rsv->type != BTRFS_BLOCK_RSV_DELALLOC)) {
ret = btrfs_qgroup_reserve_meta(root, num_bytes,
BTRFS_QGROUP_RSV_META_PREALLOC, true);
if (ret < 0)
return ret;
ret = btrfs_block_rsv_add(fs_info, dst_rsv, num_bytes,
BTRFS_RESERVE_NO_FLUSH);
/* NO_FLUSH could only fail with -ENOSPC */
ASSERT(ret == 0 || ret == -ENOSPC);
if (ret)
btrfs_qgroup_free_meta_prealloc(root, num_bytes);
} else {
ret = btrfs_block_rsv_migrate(src_rsv, dst_rsv, num_bytes, true);
}
if (!ret) {
trace_btrfs_space_reservation(fs_info, "delayed_inode",
node->inode_id, num_bytes, 1);
node->bytes_reserved = num_bytes;
}
return ret;
}
static void btrfs_delayed_inode_release_metadata(struct btrfs_fs_info *fs_info,
struct btrfs_delayed_node *node,
bool qgroup_free)
{
struct btrfs_block_rsv *rsv;
if (!node->bytes_reserved)
return;
rsv = &fs_info->delayed_block_rsv;
trace_btrfs_space_reservation(fs_info, "delayed_inode",
node->inode_id, node->bytes_reserved, 0);
btrfs_block_rsv_release(fs_info, rsv, node->bytes_reserved, NULL);
if (qgroup_free)
btrfs_qgroup_free_meta_prealloc(node->root,
node->bytes_reserved);
else
btrfs_qgroup_convert_reserved_meta(node->root,
node->bytes_reserved);
node->bytes_reserved = 0;
}
/*
* Insert a single delayed item or a batch of delayed items, as many as possible
* that fit in a leaf. The delayed items (dir index keys) are sorted by their key
* in the rbtree, and if there's a gap between two consecutive dir index items,
* then it means at some point we had delayed dir indexes to add but they got
* removed (by btrfs_delete_delayed_dir_index()) before we attempted to flush them
* into the subvolume tree. Dir index keys also have their offsets coming from a
* monotonically increasing counter, so we can't get new keys with an offset that
* fits within a gap between delayed dir index items.
*/
static int btrfs_insert_delayed_item(struct btrfs_trans_handle *trans,
struct btrfs_root *root,
struct btrfs_path *path,
struct btrfs_delayed_item *first_item)
{
struct btrfs_fs_info *fs_info = root->fs_info;
struct btrfs_delayed_node *node = first_item->delayed_node;
LIST_HEAD(item_list);
struct btrfs_delayed_item *curr;
struct btrfs_delayed_item *next;
const int max_size = BTRFS_LEAF_DATA_SIZE(fs_info);
struct btrfs_item_batch batch;
struct btrfs_key first_key;
const u32 first_data_size = first_item->data_len;
int total_size;
char *ins_data = NULL;
int ret;
bool continuous_keys_only = false;
lockdep_assert_held(&node->mutex);
/*
* During normal operation the delayed index offset is continuously
* increasing, so we can batch insert all items as there will not be any
* overlapping keys in the tree.
*
* The exception to this is log replay, where we may have interleaved
* offsets in the tree, so our batch needs to be continuous keys only in
* order to ensure we do not end up with out of order items in our leaf.
*/
if (test_bit(BTRFS_FS_LOG_RECOVERING, &fs_info->flags))
continuous_keys_only = true;
/*
* For delayed items to insert, we track reserved metadata bytes based
* on the number of leaves that we will use.
* See btrfs_insert_delayed_dir_index() and
* btrfs_delayed_item_reserve_metadata()).
*/
ASSERT(first_item->bytes_reserved == 0);
list_add_tail(&first_item->tree_list, &item_list);
batch.total_data_size = first_data_size;
batch.nr = 1;
total_size = first_data_size + sizeof(struct btrfs_item);
curr = first_item;
while (true) {
int next_size;
next = __btrfs_next_delayed_item(curr);
if (!next)
break;
/*
* We cannot allow gaps in the key space if we're doing log
* replay.
*/
if (continuous_keys_only && (next->index != curr->index + 1))
break;
ASSERT(next->bytes_reserved == 0);
next_size = next->data_len + sizeof(struct btrfs_item);
if (total_size + next_size > max_size)
break;
list_add_tail(&next->tree_list, &item_list);
batch.nr++;
total_size += next_size;
batch.total_data_size += next->data_len;
curr = next;
}
if (batch.nr == 1) {
first_key.objectid = node->inode_id;
first_key.type = BTRFS_DIR_INDEX_KEY;
first_key.offset = first_item->index;
batch.keys = &first_key;
batch.data_sizes = &first_data_size;
} else {
struct btrfs_key *ins_keys;
u32 *ins_sizes;
int i = 0;
ins_data = kmalloc(batch.nr * sizeof(u32) +
batch.nr * sizeof(struct btrfs_key), GFP_NOFS);
if (!ins_data) {
ret = -ENOMEM;
goto out;
}
ins_sizes = (u32 *)ins_data;
ins_keys = (struct btrfs_key *)(ins_data + batch.nr * sizeof(u32));
batch.keys = ins_keys;
batch.data_sizes = ins_sizes;
list_for_each_entry(curr, &item_list, tree_list) {
ins_keys[i].objectid = node->inode_id;
ins_keys[i].type = BTRFS_DIR_INDEX_KEY;
ins_keys[i].offset = curr->index;
ins_sizes[i] = curr->data_len;
i++;
}
}
ret = btrfs_insert_empty_items(trans, root, path, &batch);
if (ret)
goto out;
list_for_each_entry(curr, &item_list, tree_list) {
char *data_ptr;
data_ptr = btrfs_item_ptr(path->nodes[0], path->slots[0], char);
write_extent_buffer(path->nodes[0], &curr->data,
(unsigned long)data_ptr, curr->data_len);
path->slots[0]++;
}
/*
* Now release our path before releasing the delayed items and their
* metadata reservations, so that we don't block other tasks for more
* time than needed.
*/
btrfs_release_path(path);
ASSERT(node->index_item_leaves > 0);
/*
* For normal operations we will batch an entire leaf's worth of delayed
* items, so if there are more items to process we can decrement
* index_item_leaves by 1 as we inserted 1 leaf's worth of items.
*
* However for log replay we may not have inserted an entire leaf's
* worth of items, we may have not had continuous items, so decrementing
* here would mess up the index_item_leaves accounting. For this case
* only clean up the accounting when there are no items left.
*/
if (next && !continuous_keys_only) {
/*
* We inserted one batch of items into a leaf a there are more
* items to flush in a future batch, now release one unit of
* metadata space from the delayed block reserve, corresponding
* the leaf we just flushed to.
*/
btrfs_delayed_item_release_leaves(node, 1);
node->index_item_leaves--;
} else if (!next) {
/*
* There are no more items to insert. We can have a number of
* reserved leaves > 1 here - this happens when many dir index
* items are added and then removed before they are flushed (file
* names with a very short life, never span a transaction). So
* release all remaining leaves.
*/
btrfs_delayed_item_release_leaves(node, node->index_item_leaves);
node->index_item_leaves = 0;
}
list_for_each_entry_safe(curr, next, &item_list, tree_list) {
list_del(&curr->tree_list);
btrfs_release_delayed_item(curr);
}
out:
kfree(ins_data);
return ret;
}
static int btrfs_insert_delayed_items(struct btrfs_trans_handle *trans,
struct btrfs_path *path,
struct btrfs_root *root,
struct btrfs_delayed_node *node)
{
int ret = 0;
while (ret == 0) {
struct btrfs_delayed_item *curr;
mutex_lock(&node->mutex);
curr = __btrfs_first_delayed_insertion_item(node);
if (!curr) {
mutex_unlock(&node->mutex);
break;
}
ret = btrfs_insert_delayed_item(trans, root, path, curr);
mutex_unlock(&node->mutex);
}
return ret;
}
static int btrfs_batch_delete_items(struct btrfs_trans_handle *trans,
struct btrfs_root *root,
struct btrfs_path *path,
struct btrfs_delayed_item *item)
{
const u64 ino = item->delayed_node->inode_id;
struct btrfs_fs_info *fs_info = root->fs_info;
struct btrfs_delayed_item *curr, *next;
struct extent_buffer *leaf = path->nodes[0];
LIST_HEAD(batch_list);
int nitems, slot, last_slot;
int ret;
u64 total_reserved_size = item->bytes_reserved;
ASSERT(leaf != NULL);
slot = path->slots[0];
last_slot = btrfs_header_nritems(leaf) - 1;
/*
* Our caller always gives us a path pointing to an existing item, so
* this can not happen.
*/
ASSERT(slot <= last_slot);
if (WARN_ON(slot > last_slot))
return -ENOENT;
nitems = 1;
curr = item;
list_add_tail(&curr->tree_list, &batch_list);
/*
* Keep checking if the next delayed item matches the next item in the
* leaf - if so, we can add it to the batch of items to delete from the
* leaf.
*/
while (slot < last_slot) {
struct btrfs_key key;
next = __btrfs_next_delayed_item(curr);
if (!next)
break;
slot++;
btrfs_item_key_to_cpu(leaf, &key, slot);
if (key.objectid != ino ||
key.type != BTRFS_DIR_INDEX_KEY ||
key.offset != next->index)
break;
nitems++;
curr = next;
list_add_tail(&curr->tree_list, &batch_list);
total_reserved_size += curr->bytes_reserved;
}
ret = btrfs_del_items(trans, root, path, path->slots[0], nitems);
if (ret)
return ret;
/* In case of BTRFS_FS_LOG_RECOVERING items won't have reserved space */
if (total_reserved_size > 0) {
/*
* Check btrfs_delayed_item_reserve_metadata() to see why we
* don't need to release/reserve qgroup space.
*/
trace_btrfs_space_reservation(fs_info, "delayed_item", ino,
total_reserved_size, 0);
btrfs_block_rsv_release(fs_info, &fs_info->delayed_block_rsv,
total_reserved_size, NULL);
}
list_for_each_entry_safe(curr, next, &batch_list, tree_list) {
list_del(&curr->tree_list);
btrfs_release_delayed_item(curr);
}
return 0;
}
static int btrfs_delete_delayed_items(struct btrfs_trans_handle *trans,
struct btrfs_path *path,
struct btrfs_root *root,
struct btrfs_delayed_node *node)
{
struct btrfs_key key;
int ret = 0;
key.objectid = node->inode_id;
key.type = BTRFS_DIR_INDEX_KEY;
while (ret == 0) {
struct btrfs_delayed_item *item;
mutex_lock(&node->mutex);
item = __btrfs_first_delayed_deletion_item(node);
if (!item) {
mutex_unlock(&node->mutex);
break;
}
key.offset = item->index;
ret = btrfs_search_slot(trans, root, &key, path, -1, 1);
if (ret > 0) {
/*
* There's no matching item in the leaf. This means we
* have already deleted this item in a past run of the
* delayed items. We ignore errors when running delayed
* items from an async context, through a work queue job
* running btrfs_async_run_delayed_root(), and don't
* release delayed items that failed to complete. This
* is because we will retry later, and at transaction
* commit time we always run delayed items and will
* then deal with errors if they fail to run again.
*
* So just release delayed items for which we can't find
* an item in the tree, and move to the next item.
*/
btrfs_release_path(path);
btrfs_release_delayed_item(item);
ret = 0;
} else if (ret == 0) {
ret = btrfs_batch_delete_items(trans, root, path, item);
btrfs_release_path(path);
}
/*
* We unlock and relock on each iteration, this is to prevent
* blocking other tasks for too long while we are being run from
* the async context (work queue job). Those tasks are typically
* running system calls like creat/mkdir/rename/unlink/etc which
* need to add delayed items to this delayed node.
*/
mutex_unlock(&node->mutex);
}
return ret;
}
static void btrfs_release_delayed_inode(struct btrfs_delayed_node *delayed_node)
{
struct btrfs_delayed_root *delayed_root;
if (delayed_node &&
test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags)) {
ASSERT(delayed_node->root);
clear_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags);
delayed_node->count--;
delayed_root = delayed_node->root->fs_info->delayed_root;
finish_one_item(delayed_root);
}
}
static void btrfs_release_delayed_iref(struct btrfs_delayed_node *delayed_node)
{
if (test_and_clear_bit(BTRFS_DELAYED_NODE_DEL_IREF, &delayed_node->flags)) {
struct btrfs_delayed_root *delayed_root;
ASSERT(delayed_node->root);
delayed_node->count--;
delayed_root = delayed_node->root->fs_info->delayed_root;
finish_one_item(delayed_root);
}
}
static int __btrfs_update_delayed_inode(struct btrfs_trans_handle *trans,
struct btrfs_root *root,
struct btrfs_path *path,
struct btrfs_delayed_node *node)
{
struct btrfs_fs_info *fs_info = root->fs_info;
struct btrfs_key key;
struct btrfs_inode_item *inode_item;
struct extent_buffer *leaf;
int mod;
int ret;
key.objectid = node->inode_id;
key.type = BTRFS_INODE_ITEM_KEY;
key.offset = 0;
if (test_bit(BTRFS_DELAYED_NODE_DEL_IREF, &node->flags))
mod = -1;
else
mod = 1;
ret = btrfs_lookup_inode(trans, root, path, &key, mod);
if (ret > 0)
ret = -ENOENT;
if (ret < 0)
goto out;
leaf = path->nodes[0];
inode_item = btrfs_item_ptr(leaf, path->slots[0],
struct btrfs_inode_item);
write_extent_buffer(leaf, &node->inode_item, (unsigned long)inode_item,
sizeof(struct btrfs_inode_item));
btrfs_mark_buffer_dirty(trans, leaf);
if (!test_bit(BTRFS_DELAYED_NODE_DEL_IREF, &node->flags))
goto out;
/*
* Now we're going to delete the INODE_REF/EXTREF, which should be the
* only one ref left. Check if the next item is an INODE_REF/EXTREF.
*
* But if we're the last item already, release and search for the last
* INODE_REF/EXTREF.
*/
if (path->slots[0] + 1 >= btrfs_header_nritems(leaf)) {
key.objectid = node->inode_id;
key.type = BTRFS_INODE_EXTREF_KEY;
key.offset = (u64)-1;
btrfs_release_path(path);
ret = btrfs_search_slot(trans, root, &key, path, -1, 1);
if (ret < 0)
goto err_out;
ASSERT(ret > 0);
ASSERT(path->slots[0] > 0);
ret = 0;
path->slots[0]--;
leaf = path->nodes[0];
} else {
path->slots[0]++;
}
btrfs_item_key_to_cpu(leaf, &key, path->slots[0]);
if (key.objectid != node->inode_id)
goto out;
if (key.type != BTRFS_INODE_REF_KEY &&
key.type != BTRFS_INODE_EXTREF_KEY)
goto out;
/*
* Delayed iref deletion is for the inode who has only one link,
* so there is only one iref. The case that several irefs are
* in the same item doesn't exist.
*/
ret = btrfs_del_item(trans, root, path);
out:
btrfs_release_delayed_iref(node);
btrfs_release_path(path);
err_out:
btrfs_delayed_inode_release_metadata(fs_info, node, (ret < 0));
btrfs_release_delayed_inode(node);
/*
* If we fail to update the delayed inode we need to abort the
* transaction, because we could leave the inode with the improper
* counts behind.
*/
if (ret && ret != -ENOENT)
btrfs_abort_transaction(trans, ret);
return ret;
}
static inline int btrfs_update_delayed_inode(struct btrfs_trans_handle *trans,
struct btrfs_root *root,
struct btrfs_path *path,
struct btrfs_delayed_node *node)
{
int ret;
mutex_lock(&node->mutex);
if (!test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &node->flags)) {
mutex_unlock(&node->mutex);
return 0;
}
ret = __btrfs_update_delayed_inode(trans, root, path, node);
mutex_unlock(&node->mutex);
return ret;
}
static inline int
__btrfs_commit_inode_delayed_items(struct btrfs_trans_handle *trans,
struct btrfs_path *path,
struct btrfs_delayed_node *node)
{
int ret;
ret = btrfs_insert_delayed_items(trans, path, node->root, node);
if (ret)
return ret;
ret = btrfs_delete_delayed_items(trans, path, node->root, node);
if (ret)
return ret;
ret = btrfs_record_root_in_trans(trans, node->root);
if (ret)
return ret;
ret = btrfs_update_delayed_inode(trans, node->root, path, node);
return ret;
}
/*
* Called when committing the transaction.
* Returns 0 on success.
* Returns < 0 on error and returns with an aborted transaction with any
* outstanding delayed items cleaned up.
*/
static int __btrfs_run_delayed_items(struct btrfs_trans_handle *trans, int nr)
{
struct btrfs_fs_info *fs_info = trans->fs_info;
struct btrfs_delayed_root *delayed_root;
struct btrfs_delayed_node *curr_node, *prev_node;
struct btrfs_path *path;
struct btrfs_block_rsv *block_rsv;
int ret = 0;
bool count = (nr > 0);
if (TRANS_ABORTED(trans))
return -EIO;
path = btrfs_alloc_path();
if (!path)
return -ENOMEM;
block_rsv = trans->block_rsv;
trans->block_rsv = &fs_info->delayed_block_rsv;
delayed_root = fs_info->delayed_root;
curr_node = btrfs_first_delayed_node(delayed_root);
while (curr_node && (!count || nr--)) {
ret = __btrfs_commit_inode_delayed_items(trans, path,
curr_node);
if (ret) {
btrfs_abort_transaction(trans, ret);
break;
}
prev_node = curr_node;
curr_node = btrfs_next_delayed_node(curr_node);
/*
* See the comment below about releasing path before releasing
* node. If the commit of delayed items was successful the path
* should always be released, but in case of an error, it may
* point to locked extent buffers (a leaf at the very least).
*/
ASSERT(path->nodes[0] == NULL);
btrfs_release_delayed_node(prev_node);
}
/*
* Release the path to avoid a potential deadlock and lockdep splat when
* releasing the delayed node, as that requires taking the delayed node's
* mutex. If another task starts running delayed items before we take
* the mutex, it will first lock the mutex and then it may try to lock
* the same btree path (leaf).
*/
btrfs_free_path(path);
if (curr_node)
btrfs_release_delayed_node(curr_node);
trans->block_rsv = block_rsv;
return ret;
}
int btrfs_run_delayed_items(struct btrfs_trans_handle *trans)
{
return __btrfs_run_delayed_items(trans, -1);
}
int btrfs_run_delayed_items_nr(struct btrfs_trans_handle *trans, int nr)
{
return __btrfs_run_delayed_items(trans, nr);
}
int btrfs_commit_inode_delayed_items(struct btrfs_trans_handle *trans,
struct btrfs_inode *inode)
{
struct btrfs_delayed_node *delayed_node = btrfs_get_delayed_node(inode);
struct btrfs_path *path;
struct btrfs_block_rsv *block_rsv;
int ret;
if (!delayed_node)
return 0;
mutex_lock(&delayed_node->mutex);
if (!delayed_node->count) {
mutex_unlock(&delayed_node->mutex);
btrfs_release_delayed_node(delayed_node);
return 0;
}
mutex_unlock(&delayed_node->mutex);
path = btrfs_alloc_path();
if (!path) {
btrfs_release_delayed_node(delayed_node);
return -ENOMEM;
}
block_rsv = trans->block_rsv;
trans->block_rsv = &delayed_node->root->fs_info->delayed_block_rsv;
ret = __btrfs_commit_inode_delayed_items(trans, path, delayed_node);
btrfs_release_delayed_node(delayed_node);
btrfs_free_path(path);
trans->block_rsv = block_rsv;
return ret;
}
int btrfs_commit_inode_delayed_inode(struct btrfs_inode *inode)
{
struct btrfs_fs_info *fs_info = inode->root->fs_info;
struct btrfs_trans_handle *trans;
struct btrfs_delayed_node *delayed_node = btrfs_get_delayed_node(inode);
struct btrfs_path *path;
struct btrfs_block_rsv *block_rsv;
int ret;
if (!delayed_node)
return 0;
mutex_lock(&delayed_node->mutex);
if (!test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags)) {
mutex_unlock(&delayed_node->mutex);
btrfs_release_delayed_node(delayed_node);
return 0;
}
mutex_unlock(&delayed_node->mutex);
trans = btrfs_join_transaction(delayed_node->root);
if (IS_ERR(trans)) {
ret = PTR_ERR(trans);
goto out;
}
path = btrfs_alloc_path();
if (!path) {
ret = -ENOMEM;
goto trans_out;
}
block_rsv = trans->block_rsv;
trans->block_rsv = &fs_info->delayed_block_rsv;
mutex_lock(&delayed_node->mutex);
if (test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags))
ret = __btrfs_update_delayed_inode(trans, delayed_node->root,
path, delayed_node);
else
ret = 0;
mutex_unlock(&delayed_node->mutex);
btrfs_free_path(path);
trans->block_rsv = block_rsv;
trans_out:
btrfs_end_transaction(trans);
btrfs_btree_balance_dirty(fs_info);
out:
btrfs_release_delayed_node(delayed_node);
return ret;
}
void btrfs_remove_delayed_node(struct btrfs_inode *inode)
{
struct btrfs_delayed_node *delayed_node;
delayed_node = READ_ONCE(inode->delayed_node);
if (!delayed_node)
return;
inode->delayed_node = NULL;
btrfs_release_delayed_node(delayed_node);
}
struct btrfs_async_delayed_work {
struct btrfs_delayed_root *delayed_root;
int nr;
struct btrfs_work work;
};
static void btrfs_async_run_delayed_root(struct btrfs_work *work)
{
struct btrfs_async_delayed_work *async_work;
struct btrfs_delayed_root *delayed_root;
struct btrfs_trans_handle *trans;
struct btrfs_path *path;
struct btrfs_delayed_node *delayed_node = NULL;
struct btrfs_root *root;
struct btrfs_block_rsv *block_rsv;
int total_done = 0;
async_work = container_of(work, struct btrfs_async_delayed_work, work);
delayed_root = async_work->delayed_root;
path = btrfs_alloc_path();
if (!path)
goto out;
do {
if (atomic_read(&delayed_root->items) <
BTRFS_DELAYED_BACKGROUND / 2)
break;
delayed_node = btrfs_first_prepared_delayed_node(delayed_root);
if (!delayed_node)
break;
root = delayed_node->root;
trans = btrfs_join_transaction(root);
if (IS_ERR(trans)) {
btrfs_release_path(path);
btrfs_release_prepared_delayed_node(delayed_node);
total_done++;
continue;
}
block_rsv = trans->block_rsv;
trans->block_rsv = &root->fs_info->delayed_block_rsv;
__btrfs_commit_inode_delayed_items(trans, path, delayed_node);
trans->block_rsv = block_rsv;
btrfs_end_transaction(trans);
btrfs_btree_balance_dirty_nodelay(root->fs_info);
btrfs_release_path(path);
btrfs_release_prepared_delayed_node(delayed_node);
total_done++;
} while ((async_work->nr == 0 && total_done < BTRFS_DELAYED_WRITEBACK)
|| total_done < async_work->nr);
btrfs_free_path(path);
out:
wake_up(&delayed_root->wait);
kfree(async_work);
}
static int btrfs_wq_run_delayed_node(struct btrfs_delayed_root *delayed_root,
struct btrfs_fs_info *fs_info, int nr)
{
struct btrfs_async_delayed_work *async_work;
async_work = kmalloc(sizeof(*async_work), GFP_NOFS);
if (!async_work)
return -ENOMEM;
async_work->delayed_root = delayed_root;
btrfs_init_work(&async_work->work, btrfs_async_run_delayed_root, NULL);
async_work->nr = nr;
btrfs_queue_work(fs_info->delayed_workers, &async_work->work);
return 0;
}
void btrfs_assert_delayed_root_empty(struct btrfs_fs_info *fs_info)
{
WARN_ON(btrfs_first_delayed_node(fs_info->delayed_root));
}
static int could_end_wait(struct btrfs_delayed_root *delayed_root, int seq)
{
int val = atomic_read(&delayed_root->items_seq);
if (val < seq || val >= seq + BTRFS_DELAYED_BATCH)
return 1;
if (atomic_read(&delayed_root->items) < BTRFS_DELAYED_BACKGROUND)
return 1;
return 0;
}
void btrfs_balance_delayed_items(struct btrfs_fs_info *fs_info)
{
struct btrfs_delayed_root *delayed_root = fs_info->delayed_root;
if ((atomic_read(&delayed_root->items) < BTRFS_DELAYED_BACKGROUND) ||
btrfs_workqueue_normal_congested(fs_info->delayed_workers))
return;
if (atomic_read(&delayed_root->items) >= BTRFS_DELAYED_WRITEBACK) {
int seq;
int ret;
seq = atomic_read(&delayed_root->items_seq);
ret = btrfs_wq_run_delayed_node(delayed_root, fs_info, 0);
if (ret)
return;
wait_event_interruptible(delayed_root->wait,
could_end_wait(delayed_root, seq));
return;
}
btrfs_wq_run_delayed_node(delayed_root, fs_info, BTRFS_DELAYED_BATCH);
}
static void btrfs_release_dir_index_item_space(struct btrfs_trans_handle *trans)
{
struct btrfs_fs_info *fs_info = trans->fs_info;
const u64 bytes = btrfs_calc_insert_metadata_size(fs_info, 1);
if (test_bit(BTRFS_FS_LOG_RECOVERING, &fs_info->flags))
return;
/*
* Adding the new dir index item does not require touching another
* leaf, so we can release 1 unit of metadata that was previously
* reserved when starting the transaction. This applies only to
* the case where we had a transaction start and excludes the
* transaction join case (when replaying log trees).
*/
trace_btrfs_space_reservation(fs_info, "transaction",
trans->transid, bytes, 0);
btrfs_block_rsv_release(fs_info, trans->block_rsv, bytes, NULL);
ASSERT(trans->bytes_reserved >= bytes);
trans->bytes_reserved -= bytes;
}
/* Will return 0, -ENOMEM or -EEXIST (index number collision, unexpected). */
int btrfs_insert_delayed_dir_index(struct btrfs_trans_handle *trans,
const char *name, int name_len,
struct btrfs_inode *dir,
struct btrfs_disk_key *disk_key, u8 flags,
u64 index)
{
struct btrfs_fs_info *fs_info = trans->fs_info;
const unsigned int leaf_data_size = BTRFS_LEAF_DATA_SIZE(fs_info);
struct btrfs_delayed_node *delayed_node;
struct btrfs_delayed_item *delayed_item;
struct btrfs_dir_item *dir_item;
bool reserve_leaf_space;
u32 data_len;
int ret;
delayed_node = btrfs_get_or_create_delayed_node(dir);
if (IS_ERR(delayed_node))
return PTR_ERR(delayed_node);
delayed_item = btrfs_alloc_delayed_item(sizeof(*dir_item) + name_len,
delayed_node,
BTRFS_DELAYED_INSERTION_ITEM);
if (!delayed_item) {
ret = -ENOMEM;
goto release_node;
}
delayed_item->index = index;
dir_item = (struct btrfs_dir_item *)delayed_item->data;
dir_item->location = *disk_key;
btrfs_set_stack_dir_transid(dir_item, trans->transid);
btrfs_set_stack_dir_data_len(dir_item, 0);
btrfs_set_stack_dir_name_len(dir_item, name_len);
btrfs_set_stack_dir_flags(dir_item, flags);
memcpy((char *)(dir_item + 1), name, name_len);
data_len = delayed_item->data_len + sizeof(struct btrfs_item);
mutex_lock(&delayed_node->mutex);
/*
* First attempt to insert the delayed item. This is to make the error
* handling path simpler in case we fail (-EEXIST). There's no risk of
* any other task coming in and running the delayed item before we do
* the metadata space reservation below, because we are holding the
* delayed node's mutex and that mutex must also be locked before the
* node's delayed items can be run.
*/
ret = __btrfs_add_delayed_item(delayed_node, delayed_item);
if (unlikely(ret)) {
btrfs_err(trans->fs_info,
"error adding delayed dir index item, name: %.*s, index: %llu, root: %llu, dir: %llu, dir->index_cnt: %llu, delayed_node->index_cnt: %llu, error: %d",
name_len, name, index, btrfs_root_id(delayed_node->root),
delayed_node->inode_id, dir->index_cnt,
delayed_node->index_cnt, ret);
btrfs_release_delayed_item(delayed_item);
btrfs_release_dir_index_item_space(trans);
mutex_unlock(&delayed_node->mutex);
goto release_node;
}
if (delayed_node->index_item_leaves == 0 ||
delayed_node->curr_index_batch_size + data_len > leaf_data_size) {
delayed_node->curr_index_batch_size = data_len;
reserve_leaf_space = true;
} else {
delayed_node->curr_index_batch_size += data_len;
reserve_leaf_space = false;
}
if (reserve_leaf_space) {
ret = btrfs_delayed_item_reserve_metadata(trans, delayed_item);
/*
* Space was reserved for a dir index item insertion when we
* started the transaction, so getting a failure here should be
* impossible.
*/
if (WARN_ON(ret)) {
btrfs_release_delayed_item(delayed_item);
mutex_unlock(&delayed_node->mutex);
goto release_node;
}
delayed_node->index_item_leaves++;
} else {
btrfs_release_dir_index_item_space(trans);
}
mutex_unlock(&delayed_node->mutex);
release_node:
btrfs_release_delayed_node(delayed_node);
return ret;
}
static int btrfs_delete_delayed_insertion_item(struct btrfs_fs_info *fs_info,
struct btrfs_delayed_node *node,
u64 index)
{
struct btrfs_delayed_item *item;
mutex_lock(&node->mutex);
item = __btrfs_lookup_delayed_item(&node->ins_root.rb_root, index);
if (!item) {
mutex_unlock(&node->mutex);
return 1;
}
/*
* For delayed items to insert, we track reserved metadata bytes based
* on the number of leaves that we will use.
* See btrfs_insert_delayed_dir_index() and
* btrfs_delayed_item_reserve_metadata()).
*/
ASSERT(item->bytes_reserved == 0);
ASSERT(node->index_item_leaves > 0);
/*
* If there's only one leaf reserved, we can decrement this item from the
* current batch, otherwise we can not because we don't know which leaf
* it belongs to. With the current limit on delayed items, we rarely
* accumulate enough dir index items to fill more than one leaf (even
* when using a leaf size of 4K).
*/
if (node->index_item_leaves == 1) {
const u32 data_len = item->data_len + sizeof(struct btrfs_item);
ASSERT(node->curr_index_batch_size >= data_len);
node->curr_index_batch_size -= data_len;
}
btrfs_release_delayed_item(item);
/* If we now have no more dir index items, we can release all leaves. */
if (RB_EMPTY_ROOT(&node->ins_root.rb_root)) {
btrfs_delayed_item_release_leaves(node, node->index_item_leaves);
node->index_item_leaves = 0;
}
mutex_unlock(&node->mutex);
return 0;
}
int btrfs_delete_delayed_dir_index(struct btrfs_trans_handle *trans,
struct btrfs_inode *dir, u64 index)
{
struct btrfs_delayed_node *node;
struct btrfs_delayed_item *item;
int ret;
node = btrfs_get_or_create_delayed_node(dir);
if (IS_ERR(node))
return PTR_ERR(node);
ret = btrfs_delete_delayed_insertion_item(trans->fs_info, node, index);
if (!ret)
goto end;
item = btrfs_alloc_delayed_item(0, node, BTRFS_DELAYED_DELETION_ITEM);
if (!item) {
ret = -ENOMEM;
goto end;
}
item->index = index;
ret = btrfs_delayed_item_reserve_metadata(trans, item);
/*
* we have reserved enough space when we start a new transaction,
* so reserving metadata failure is impossible.
*/
if (ret < 0) {
btrfs_err(trans->fs_info,
"metadata reservation failed for delayed dir item deltiona, should have been reserved");
btrfs_release_delayed_item(item);
goto end;
}
mutex_lock(&node->mutex);
ret = __btrfs_add_delayed_item(node, item);
if (unlikely(ret)) {
btrfs_err(trans->fs_info,
"err add delayed dir index item(index: %llu) into the deletion tree of the delayed node(root id: %llu, inode id: %llu, errno: %d)",
index, node->root->root_key.objectid,
node->inode_id, ret);
btrfs_delayed_item_release_metadata(dir->root, item);
btrfs_release_delayed_item(item);
}
mutex_unlock(&node->mutex);
end:
btrfs_release_delayed_node(node);
return ret;
}
int btrfs_inode_delayed_dir_index_count(struct btrfs_inode *inode)
{
struct btrfs_delayed_node *delayed_node = btrfs_get_delayed_node(inode);
if (!delayed_node)
return -ENOENT;
/*
* Since we have held i_mutex of this directory, it is impossible that
* a new directory index is added into the delayed node and index_cnt
* is updated now. So we needn't lock the delayed node.
*/
if (!delayed_node->index_cnt) {
btrfs_release_delayed_node(delayed_node);
return -EINVAL;
}
inode->index_cnt = delayed_node->index_cnt;
btrfs_release_delayed_node(delayed_node);
return 0;
}
bool btrfs_readdir_get_delayed_items(struct inode *inode,
u64 last_index,
struct list_head *ins_list,
struct list_head *del_list)
{
struct btrfs_delayed_node *delayed_node;
struct btrfs_delayed_item *item;
delayed_node = btrfs_get_delayed_node(BTRFS_I(inode));
if (!delayed_node)
return false;
/*
* We can only do one readdir with delayed items at a time because of
* item->readdir_list.
*/
btrfs_inode_unlock(BTRFS_I(inode), BTRFS_ILOCK_SHARED);
btrfs_inode_lock(BTRFS_I(inode), 0);
mutex_lock(&delayed_node->mutex);
item = __btrfs_first_delayed_insertion_item(delayed_node);
while (item && item->index <= last_index) {
refcount_inc(&item->refs);
list_add_tail(&item->readdir_list, ins_list);
item = __btrfs_next_delayed_item(item);
}
item = __btrfs_first_delayed_deletion_item(delayed_node);
while (item && item->index <= last_index) {
refcount_inc(&item->refs);
list_add_tail(&item->readdir_list, del_list);
item = __btrfs_next_delayed_item(item);
}
mutex_unlock(&delayed_node->mutex);
/*
* This delayed node is still cached in the btrfs inode, so refs
* must be > 1 now, and we needn't check it is going to be freed
* or not.
*
* Besides that, this function is used to read dir, we do not
* insert/delete delayed items in this period. So we also needn't
* requeue or dequeue this delayed node.
*/
refcount_dec(&delayed_node->refs);
return true;
}
void btrfs_readdir_put_delayed_items(struct inode *inode,
struct list_head *ins_list,
struct list_head *del_list)
{
struct btrfs_delayed_item *curr, *next;
list_for_each_entry_safe(curr, next, ins_list, readdir_list) {
list_del(&curr->readdir_list);
if (refcount_dec_and_test(&curr->refs))
kfree(curr);
}
list_for_each_entry_safe(curr, next, del_list, readdir_list) {
list_del(&curr->readdir_list);
if (refcount_dec_and_test(&curr->refs))
kfree(curr);
}
/*
* The VFS is going to do up_read(), so we need to downgrade back to a
* read lock.
*/
downgrade_write(&inode->i_rwsem);
}
int btrfs_should_delete_dir_index(struct list_head *del_list,
u64 index)
{
struct btrfs_delayed_item *curr;
int ret = 0;
list_for_each_entry(curr, del_list, readdir_list) {
if (curr->index > index)
break;
if (curr->index == index) {
ret = 1;
break;
}
}
return ret;
}
/*
* Read dir info stored in the delayed tree.
*/
int btrfs_readdir_delayed_dir_index(struct dir_context *ctx,
struct list_head *ins_list)
{
struct btrfs_dir_item *di;
struct btrfs_delayed_item *curr, *next;
struct btrfs_key location;
char *name;
int name_len;
int over = 0;
unsigned char d_type;
/*
* Changing the data of the delayed item is impossible. So
* we needn't lock them. And we have held i_mutex of the
* directory, nobody can delete any directory indexes now.
*/
list_for_each_entry_safe(curr, next, ins_list, readdir_list) {
list_del(&curr->readdir_list);
if (curr->index < ctx->pos) {
if (refcount_dec_and_test(&curr->refs))
kfree(curr);
continue;
}
ctx->pos = curr->index;
di = (struct btrfs_dir_item *)curr->data;
name = (char *)(di + 1);
name_len = btrfs_stack_dir_name_len(di);
d_type = fs_ftype_to_dtype(btrfs_dir_flags_to_ftype(di->type));
btrfs_disk_key_to_cpu(&location, &di->location);
over = !dir_emit(ctx, name, name_len,
location.objectid, d_type);
if (refcount_dec_and_test(&curr->refs))
kfree(curr);
if (over)
return 1;
ctx->pos++;
}
return 0;
}
static void fill_stack_inode_item(struct btrfs_trans_handle *trans,
struct btrfs_inode_item *inode_item,
struct inode *inode)
{
u64 flags;
btrfs_set_stack_inode_uid(inode_item, i_uid_read(inode));
btrfs_set_stack_inode_gid(inode_item, i_gid_read(inode));
btrfs_set_stack_inode_size(inode_item, BTRFS_I(inode)->disk_i_size);
btrfs_set_stack_inode_mode(inode_item, inode->i_mode);
btrfs_set_stack_inode_nlink(inode_item, inode->i_nlink);
btrfs_set_stack_inode_nbytes(inode_item, inode_get_bytes(inode));
btrfs_set_stack_inode_generation(inode_item,
BTRFS_I(inode)->generation);
btrfs_set_stack_inode_sequence(inode_item,
inode_peek_iversion(inode));
btrfs_set_stack_inode_transid(inode_item, trans->transid);
btrfs_set_stack_inode_rdev(inode_item, inode->i_rdev);
flags = btrfs_inode_combine_flags(BTRFS_I(inode)->flags,
BTRFS_I(inode)->ro_flags);
btrfs_set_stack_inode_flags(inode_item, flags);
btrfs_set_stack_inode_block_group(inode_item, 0);
btrfs_set_stack_timespec_sec(&inode_item->atime,
inode_get_atime_sec(inode));
btrfs_set_stack_timespec_nsec(&inode_item->atime,
inode_get_atime_nsec(inode));
btrfs_set_stack_timespec_sec(&inode_item->mtime,
inode_get_mtime_sec(inode));
btrfs_set_stack_timespec_nsec(&inode_item->mtime,
inode_get_mtime_nsec(inode));
btrfs_set_stack_timespec_sec(&inode_item->ctime,
inode_get_ctime_sec(inode));
btrfs_set_stack_timespec_nsec(&inode_item->ctime,
inode_get_ctime_nsec(inode));
btrfs_set_stack_timespec_sec(&inode_item->otime, BTRFS_I(inode)->i_otime_sec);
btrfs_set_stack_timespec_nsec(&inode_item->otime, BTRFS_I(inode)->i_otime_nsec);
}
int btrfs_fill_inode(struct inode *inode, u32 *rdev)
{
struct btrfs_fs_info *fs_info = BTRFS_I(inode)->root->fs_info;
struct btrfs_delayed_node *delayed_node;
struct btrfs_inode_item *inode_item;
delayed_node = btrfs_get_delayed_node(BTRFS_I(inode));
if (!delayed_node)
return -ENOENT;
mutex_lock(&delayed_node->mutex);
if (!test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags)) {
mutex_unlock(&delayed_node->mutex);
btrfs_release_delayed_node(delayed_node);
return -ENOENT;
}
inode_item = &delayed_node->inode_item;
i_uid_write(inode, btrfs_stack_inode_uid(inode_item));
i_gid_write(inode, btrfs_stack_inode_gid(inode_item));
btrfs_i_size_write(BTRFS_I(inode), btrfs_stack_inode_size(inode_item));
btrfs_inode_set_file_extent_range(BTRFS_I(inode), 0,
round_up(i_size_read(inode), fs_info->sectorsize));
inode->i_mode = btrfs_stack_inode_mode(inode_item);
set_nlink(inode, btrfs_stack_inode_nlink(inode_item));
inode_set_bytes(inode, btrfs_stack_inode_nbytes(inode_item));
BTRFS_I(inode)->generation = btrfs_stack_inode_generation(inode_item);
BTRFS_I(inode)->last_trans = btrfs_stack_inode_transid(inode_item);
inode_set_iversion_queried(inode,
btrfs_stack_inode_sequence(inode_item));
inode->i_rdev = 0;
*rdev = btrfs_stack_inode_rdev(inode_item);
btrfs_inode_split_flags(btrfs_stack_inode_flags(inode_item),
&BTRFS_I(inode)->flags, &BTRFS_I(inode)->ro_flags);
inode_set_atime(inode, btrfs_stack_timespec_sec(&inode_item->atime),
btrfs_stack_timespec_nsec(&inode_item->atime));
inode_set_mtime(inode, btrfs_stack_timespec_sec(&inode_item->mtime),
btrfs_stack_timespec_nsec(&inode_item->mtime));
inode_set_ctime(inode, btrfs_stack_timespec_sec(&inode_item->ctime),
btrfs_stack_timespec_nsec(&inode_item->ctime));
BTRFS_I(inode)->i_otime_sec = btrfs_stack_timespec_sec(&inode_item->otime);
BTRFS_I(inode)->i_otime_nsec = btrfs_stack_timespec_nsec(&inode_item->otime);
inode->i_generation = BTRFS_I(inode)->generation;
BTRFS_I(inode)->index_cnt = (u64)-1;
mutex_unlock(&delayed_node->mutex);
btrfs_release_delayed_node(delayed_node);
return 0;
}
int btrfs_delayed_update_inode(struct btrfs_trans_handle *trans,
struct btrfs_inode *inode)
{
struct btrfs_root *root = inode->root;
struct btrfs_delayed_node *delayed_node;
int ret = 0;
delayed_node = btrfs_get_or_create_delayed_node(inode);
if (IS_ERR(delayed_node))
return PTR_ERR(delayed_node);
mutex_lock(&delayed_node->mutex);
if (test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags)) {
fill_stack_inode_item(trans, &delayed_node->inode_item,
&inode->vfs_inode);
goto release_node;
}
ret = btrfs_delayed_inode_reserve_metadata(trans, root, delayed_node);
if (ret)
goto release_node;
fill_stack_inode_item(trans, &delayed_node->inode_item, &inode->vfs_inode);
set_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags);
delayed_node->count++;
atomic_inc(&root->fs_info->delayed_root->items);
release_node:
mutex_unlock(&delayed_node->mutex);
btrfs_release_delayed_node(delayed_node);
return ret;
}
int btrfs_delayed_delete_inode_ref(struct btrfs_inode *inode)
{
struct btrfs_fs_info *fs_info = inode->root->fs_info;
struct btrfs_delayed_node *delayed_node;
/*
* we don't do delayed inode updates during log recovery because it
* leads to enospc problems. This means we also can't do
* delayed inode refs
*/
if (test_bit(BTRFS_FS_LOG_RECOVERING, &fs_info->flags))
return -EAGAIN;
delayed_node = btrfs_get_or_create_delayed_node(inode);
if (IS_ERR(delayed_node))
return PTR_ERR(delayed_node);
/*
* We don't reserve space for inode ref deletion is because:
* - We ONLY do async inode ref deletion for the inode who has only
* one link(i_nlink == 1), it means there is only one inode ref.
* And in most case, the inode ref and the inode item are in the
* same leaf, and we will deal with them at the same time.
* Since we are sure we will reserve the space for the inode item,
* it is unnecessary to reserve space for inode ref deletion.
* - If the inode ref and the inode item are not in the same leaf,
* We also needn't worry about enospc problem, because we reserve
* much more space for the inode update than it needs.
* - At the worst, we can steal some space from the global reservation.
* It is very rare.
*/
mutex_lock(&delayed_node->mutex);
if (test_bit(BTRFS_DELAYED_NODE_DEL_IREF, &delayed_node->flags))
goto release_node;
set_bit(BTRFS_DELAYED_NODE_DEL_IREF, &delayed_node->flags);
delayed_node->count++;
atomic_inc(&fs_info->delayed_root->items);
release_node:
mutex_unlock(&delayed_node->mutex);
btrfs_release_delayed_node(delayed_node);
return 0;
}
static void __btrfs_kill_delayed_node(struct btrfs_delayed_node *delayed_node)
{
struct btrfs_root *root = delayed_node->root;
struct btrfs_fs_info *fs_info = root->fs_info;
struct btrfs_delayed_item *curr_item, *prev_item;
mutex_lock(&delayed_node->mutex);
curr_item = __btrfs_first_delayed_insertion_item(delayed_node);
while (curr_item) {
prev_item = curr_item;
curr_item = __btrfs_next_delayed_item(prev_item);
btrfs_release_delayed_item(prev_item);
}
if (delayed_node->index_item_leaves > 0) {
btrfs_delayed_item_release_leaves(delayed_node,
delayed_node->index_item_leaves);
delayed_node->index_item_leaves = 0;
}
curr_item = __btrfs_first_delayed_deletion_item(delayed_node);
while (curr_item) {
btrfs_delayed_item_release_metadata(root, curr_item);
prev_item = curr_item;
curr_item = __btrfs_next_delayed_item(prev_item);
btrfs_release_delayed_item(prev_item);
}
btrfs_release_delayed_iref(delayed_node);
if (test_bit(BTRFS_DELAYED_NODE_INODE_DIRTY, &delayed_node->flags)) {
btrfs_delayed_inode_release_metadata(fs_info, delayed_node, false);
btrfs_release_delayed_inode(delayed_node);
}
mutex_unlock(&delayed_node->mutex);
}
void btrfs_kill_delayed_inode_items(struct btrfs_inode *inode)
{
struct btrfs_delayed_node *delayed_node;
delayed_node = btrfs_get_delayed_node(inode);
if (!delayed_node)
return;
__btrfs_kill_delayed_node(delayed_node);
btrfs_release_delayed_node(delayed_node);
}
void btrfs_kill_all_delayed_nodes(struct btrfs_root *root)
{
unsigned long index = 0;
struct btrfs_delayed_node *delayed_nodes[8];
while (1) {
struct btrfs_delayed_node *node;
int count;
spin_lock(&root->inode_lock);
if (xa_empty(&root->delayed_nodes)) {
spin_unlock(&root->inode_lock);
return;
}
count = 0;
xa_for_each_start(&root->delayed_nodes, index, node, index) {
/*
* Don't increase refs in case the node is dead and
* about to be removed from the tree in the loop below
*/
if (refcount_inc_not_zero(&node->refs)) {
delayed_nodes[count] = node;
count++;
}
if (count >= ARRAY_SIZE(delayed_nodes))
break;
}
spin_unlock(&root->inode_lock);
index++;
for (int i = 0; i < count; i++) {
__btrfs_kill_delayed_node(delayed_nodes[i]);
btrfs_release_delayed_node(delayed_nodes[i]);
}
}
}
void btrfs_destroy_delayed_inodes(struct btrfs_fs_info *fs_info)
{
struct btrfs_delayed_node *curr_node, *prev_node;
curr_node = btrfs_first_delayed_node(fs_info->delayed_root);
while (curr_node) {
__btrfs_kill_delayed_node(curr_node);
prev_node = curr_node;
curr_node = btrfs_next_delayed_node(curr_node);
btrfs_release_delayed_node(prev_node);
}
}
void btrfs_log_get_delayed_items(struct btrfs_inode *inode,
struct list_head *ins_list,
struct list_head *del_list)
{
struct btrfs_delayed_node *node;
struct btrfs_delayed_item *item;
node = btrfs_get_delayed_node(inode);
if (!node)
return;
mutex_lock(&node->mutex);
item = __btrfs_first_delayed_insertion_item(node);
while (item) {
/*
* It's possible that the item is already in a log list. This
* can happen in case two tasks are trying to log the same
* directory. For example if we have tasks A and task B:
*
* Task A collected the delayed items into a log list while
* under the inode's log_mutex (at btrfs_log_inode()), but it
* only releases the items after logging the inodes they point
* to (if they are new inodes), which happens after unlocking
* the log mutex;
*
* Task B enters btrfs_log_inode() and acquires the log_mutex
* of the same directory inode, before task B releases the
* delayed items. This can happen for example when logging some
* inode we need to trigger logging of its parent directory, so
* logging two files that have the same parent directory can
* lead to this.
*
* If this happens, just ignore delayed items already in a log
* list. All the tasks logging the directory are under a log
* transaction and whichever finishes first can not sync the log
* before the other completes and leaves the log transaction.
*/
if (!item->logged && list_empty(&item->log_list)) {
refcount_inc(&item->refs);
list_add_tail(&item->log_list, ins_list);
}
item = __btrfs_next_delayed_item(item);
}
item = __btrfs_first_delayed_deletion_item(node);
while (item) {
/* It may be non-empty, for the same reason mentioned above. */
if (!item->logged && list_empty(&item->log_list)) {
refcount_inc(&item->refs);
list_add_tail(&item->log_list, del_list);
}
item = __btrfs_next_delayed_item(item);
}
mutex_unlock(&node->mutex);
/*
* We are called during inode logging, which means the inode is in use
* and can not be evicted before we finish logging the inode. So we never
* have the last reference on the delayed inode.
* Also, we don't use btrfs_release_delayed_node() because that would
* requeue the delayed inode (change its order in the list of prepared
* nodes) and we don't want to do such change because we don't create or
* delete delayed items.
*/
ASSERT(refcount_read(&node->refs) > 1);
refcount_dec(&node->refs);
}
void btrfs_log_put_delayed_items(struct btrfs_inode *inode,
struct list_head *ins_list,
struct list_head *del_list)
{
struct btrfs_delayed_node *node;
struct btrfs_delayed_item *item;
struct btrfs_delayed_item *next;
node = btrfs_get_delayed_node(inode);
if (!node)
return;
mutex_lock(&node->mutex);
list_for_each_entry_safe(item, next, ins_list, log_list) {
item->logged = true;
list_del_init(&item->log_list);
if (refcount_dec_and_test(&item->refs))
kfree(item);
}
list_for_each_entry_safe(item, next, del_list, log_list) {
item->logged = true;
list_del_init(&item->log_list);
if (refcount_dec_and_test(&item->refs))
kfree(item);
}
mutex_unlock(&node->mutex);
/*
* We are called during inode logging, which means the inode is in use
* and can not be evicted before we finish logging the inode. So we never
* have the last reference on the delayed inode.
* Also, we don't use btrfs_release_delayed_node() because that would
* requeue the delayed inode (change its order in the list of prepared
* nodes) and we don't want to do such change because we don't create or
* delete delayed items.
*/
ASSERT(refcount_read(&node->refs) > 1);
refcount_dec(&node->refs);
}