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// SPDX-License-Identifier: GPL-2.0-or-later
#include <linux/bio.h>
#include "cache.h"
#include "backing_dev.h"
#include "cache_dev.h"
#include "dm_pcache.h"
static void writeback_ctx_end(struct pcache_cache *cache, int ret)
{
if (ret && !cache->writeback_ctx.ret) {
pcache_dev_err(CACHE_TO_PCACHE(cache), "writeback error: %d", ret);
cache->writeback_ctx.ret = ret;
}
if (!atomic_dec_and_test(&cache->writeback_ctx.pending))
return;
if (!cache->writeback_ctx.ret) {
backing_dev_flush(cache->backing_dev);
mutex_lock(&cache->dirty_tail_lock);
cache_pos_advance(&cache->dirty_tail, cache->writeback_ctx.advance);
cache_encode_dirty_tail(cache);
mutex_unlock(&cache->dirty_tail_lock);
}
queue_delayed_work(cache_get_wq(cache), &cache->writeback_work, 0);
}
static void writeback_end_req(struct pcache_backing_dev_req *backing_req, int ret)
{
struct pcache_cache *cache = backing_req->priv_data;
mutex_lock(&cache->writeback_lock);
writeback_ctx_end(cache, ret);
mutex_unlock(&cache->writeback_lock);
}
static inline bool is_cache_clean(struct pcache_cache *cache, struct pcache_cache_pos *dirty_tail)
{
struct dm_pcache *pcache = CACHE_TO_PCACHE(cache);
struct pcache_cache_kset_onmedia *kset_onmedia;
u32 to_copy;
void *addr;
int ret;
addr = cache_pos_addr(dirty_tail);
kset_onmedia = (struct pcache_cache_kset_onmedia *)cache->wb_kset_onmedia_buf;
to_copy = min(PCACHE_KSET_ONMEDIA_SIZE_MAX, PCACHE_SEG_SIZE - dirty_tail->seg_off);
ret = copy_mc_to_kernel(kset_onmedia, addr, to_copy);
if (ret) {
pcache_dev_err(pcache, "error to read kset: %d", ret);
return true;
}
/* Check if the magic number matches the expected value */
if (kset_onmedia->magic != PCACHE_KSET_MAGIC) {
pcache_dev_debug(pcache, "dirty_tail: %u:%u magic: %llx, not expected: %llx\n",
dirty_tail->cache_seg->cache_seg_id, dirty_tail->seg_off,
kset_onmedia->magic, PCACHE_KSET_MAGIC);
return true;
}
/* Verify the CRC checksum for data integrity */
if (kset_onmedia->crc != cache_kset_crc(kset_onmedia)) {
pcache_dev_debug(pcache, "dirty_tail: %u:%u crc: %x, not expected: %x\n",
dirty_tail->cache_seg->cache_seg_id, dirty_tail->seg_off,
cache_kset_crc(kset_onmedia), kset_onmedia->crc);
return true;
}
return false;
}
void cache_writeback_exit(struct pcache_cache *cache)
{
cancel_delayed_work_sync(&cache->writeback_work);
backing_dev_flush(cache->backing_dev);
cache_tree_exit(&cache->writeback_key_tree);
}
int cache_writeback_init(struct pcache_cache *cache)
{
int ret;
ret = cache_tree_init(cache, &cache->writeback_key_tree, 1);
if (ret)
goto err;
atomic_set(&cache->writeback_ctx.pending, 0);
/* Queue delayed work to start writeback handling */
queue_delayed_work(cache_get_wq(cache), &cache->writeback_work, 0);
return 0;
err:
return ret;
}
static void cache_key_writeback(struct pcache_cache *cache, struct pcache_cache_key *key)
{
struct pcache_backing_dev_req *writeback_req;
struct pcache_backing_dev_req_opts writeback_req_opts = { 0 };
struct pcache_cache_pos *pos;
void *addr;
u32 seg_remain, req_len, done = 0;
if (cache_key_clean(key))
return;
pos = &key->cache_pos;
seg_remain = cache_seg_remain(pos);
BUG_ON(seg_remain < key->len);
next_req:
addr = cache_pos_addr(pos) + done;
req_len = backing_dev_req_coalesced_max_len(addr, key->len - done);
writeback_req_opts.type = BACKING_DEV_REQ_TYPE_KMEM;
writeback_req_opts.gfp_mask = GFP_NOIO;
writeback_req_opts.end_fn = writeback_end_req;
writeback_req_opts.priv_data = cache;
writeback_req_opts.kmem.data = addr;
writeback_req_opts.kmem.opf = REQ_OP_WRITE;
writeback_req_opts.kmem.len = req_len;
writeback_req_opts.kmem.backing_off = key->off + done;
writeback_req = backing_dev_req_create(cache->backing_dev, &writeback_req_opts);
atomic_inc(&cache->writeback_ctx.pending);
backing_dev_req_submit(writeback_req, true);
done += req_len;
if (done < key->len)
goto next_req;
}
static void cache_wb_tree_writeback(struct pcache_cache *cache, u32 advance)
{
struct pcache_cache_tree *cache_tree = &cache->writeback_key_tree;
struct pcache_cache_subtree *cache_subtree;
struct rb_node *node;
struct pcache_cache_key *key;
u32 i;
cache->writeback_ctx.ret = 0;
cache->writeback_ctx.advance = advance;
atomic_set(&cache->writeback_ctx.pending, 1);
for (i = 0; i < cache_tree->n_subtrees; i++) {
cache_subtree = &cache_tree->subtrees[i];
node = rb_first(&cache_subtree->root);
while (node) {
key = CACHE_KEY(node);
node = rb_next(node);
cache_key_writeback(cache, key);
cache_key_delete(key);
}
}
writeback_ctx_end(cache, 0);
}
static int cache_kset_insert_tree(struct pcache_cache *cache, struct pcache_cache_kset_onmedia *kset_onmedia)
{
struct pcache_cache_key_onmedia *key_onmedia;
struct pcache_cache_subtree *cache_subtree;
struct pcache_cache_key *key;
int ret;
u32 i;
/* Iterate through all keys in the kset and write each back to storage */
for (i = 0; i < kset_onmedia->key_num; i++) {
key_onmedia = &kset_onmedia->data[i];
key = cache_key_alloc(&cache->writeback_key_tree, GFP_NOIO);
ret = cache_key_decode(cache, key_onmedia, key);
if (ret) {
cache_key_put(key);
goto clear_tree;
}
cache_subtree = get_subtree(&cache->writeback_key_tree, key->off);
spin_lock(&cache_subtree->tree_lock);
cache_key_insert(&cache->writeback_key_tree, key, true);
spin_unlock(&cache_subtree->tree_lock);
}
return 0;
clear_tree:
cache_tree_clear(&cache->writeback_key_tree);
return ret;
}
static void last_kset_writeback(struct pcache_cache *cache,
struct pcache_cache_kset_onmedia *last_kset_onmedia)
{
struct dm_pcache *pcache = CACHE_TO_PCACHE(cache);
struct pcache_cache_segment *next_seg;
pcache_dev_debug(pcache, "last kset, next: %u\n", last_kset_onmedia->next_cache_seg_id);
next_seg = &cache->segments[last_kset_onmedia->next_cache_seg_id];
mutex_lock(&cache->dirty_tail_lock);
cache->dirty_tail.cache_seg = next_seg;
cache->dirty_tail.seg_off = 0;
cache_encode_dirty_tail(cache);
mutex_unlock(&cache->dirty_tail_lock);
}
void cache_writeback_fn(struct work_struct *work)
{
struct pcache_cache *cache = container_of(work, struct pcache_cache, writeback_work.work);
struct dm_pcache *pcache = CACHE_TO_PCACHE(cache);
struct pcache_cache_pos dirty_tail;
struct pcache_cache_kset_onmedia *kset_onmedia;
u32 delay;
int ret;
mutex_lock(&cache->writeback_lock);
if (atomic_read(&cache->writeback_ctx.pending))
goto unlock;
if (pcache_is_stopping(pcache))
goto unlock;
kset_onmedia = (struct pcache_cache_kset_onmedia *)cache->wb_kset_onmedia_buf;
mutex_lock(&cache->dirty_tail_lock);
cache_pos_copy(&dirty_tail, &cache->dirty_tail);
mutex_unlock(&cache->dirty_tail_lock);
if (is_cache_clean(cache, &dirty_tail)) {
delay = PCACHE_CACHE_WRITEBACK_INTERVAL;
goto queue_work;
}
if (kset_onmedia->flags & PCACHE_KSET_FLAGS_LAST) {
last_kset_writeback(cache, kset_onmedia);
delay = 0;
goto queue_work;
}
ret = cache_kset_insert_tree(cache, kset_onmedia);
if (ret) {
delay = PCACHE_CACHE_WRITEBACK_INTERVAL;
goto queue_work;
}
cache_wb_tree_writeback(cache, get_kset_onmedia_size(kset_onmedia));
delay = 0;
queue_work:
queue_delayed_work(cache_get_wq(cache), &cache->writeback_work, delay);
unlock:
mutex_unlock(&cache->writeback_lock);
}
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