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/*
* QEMU Enhanced Disk Format L2 Cache
*
* Copyright IBM, Corp. 2010
*
* Authors:
* Anthony Liguori <aliguori@us.ibm.com>
*
* This work is licensed under the terms of the GNU LGPL, version 2 or later.
* See the COPYING.LIB file in the top-level directory.
*
*/
/*
* L2 table cache usage is as follows:
*
* An open image has one L2 table cache that is used to avoid accessing the
* image file for recently referenced L2 tables.
*
* Cluster offset lookup translates the logical offset within the block device
* to a cluster offset within the image file. This is done by indexing into
* the L1 and L2 tables which store cluster offsets. It is here where the L2
* table cache serves up recently referenced L2 tables.
*
* If there is a cache miss, that L2 table is read from the image file and
* committed to the cache. Subsequent accesses to that L2 table will be served
* from the cache until the table is evicted from the cache.
*
* L2 tables are also committed to the cache when new L2 tables are allocated
* in the image file. Since the L2 table cache is write-through, the new L2
* table is first written out to the image file and then committed to the
* cache.
*
* Multiple I/O requests may be using an L2 table cache entry at any given
* time. That means an entry may be in use across several requests and
* reference counting is needed to free the entry at the correct time. In
* particular, an entry evicted from the cache will only be freed once all
* references are dropped.
*
* An in-flight I/O request will hold a reference to a L2 table cache entry for
* the period during which it needs to access the L2 table. This includes
* cluster offset lookup, L2 table allocation, and L2 table update when a new
* data cluster has been allocated.
*
* An interesting case occurs when two requests need to access an L2 table that
* is not in the cache. Since the operation to read the table from the image
* file takes some time to complete, both requests may see a cache miss and
* start reading the L2 table from the image file. The first to finish will
* commit its L2 table into the cache. When the second tries to commit its
* table will be deleted in favor of the existing cache entry.
*/
#include "trace.h"
#include "qed.h"
/* Each L2 holds 2GB so this let's us fully cache a 100GB disk */
#define MAX_L2_CACHE_SIZE 50
/**
* Initialize the L2 cache
*/
void qed_init_l2_cache(L2TableCache *l2_cache)
{
QTAILQ_INIT(&l2_cache->entries);
l2_cache->n_entries = 0;
}
/**
* Free the L2 cache
*/
void qed_free_l2_cache(L2TableCache *l2_cache)
{
CachedL2Table *entry, *next_entry;
QTAILQ_FOREACH_SAFE(entry, &l2_cache->entries, node, next_entry) {
qemu_vfree(entry->table);
g_free(entry);
}
}
/**
* Allocate an uninitialized entry from the cache
*
* The returned entry has a reference count of 1 and is owned by the caller.
* The caller must allocate the actual table field for this entry and it must
* be freeable using qemu_vfree().
*/
CachedL2Table *qed_alloc_l2_cache_entry(L2TableCache *l2_cache)
{
CachedL2Table *entry;
entry = g_malloc0(sizeof(*entry));
entry->ref++;
trace_qed_alloc_l2_cache_entry(l2_cache, entry);
return entry;
}
/**
* Decrease an entry's reference count and free if necessary when the reference
* count drops to zero.
*/
void qed_unref_l2_cache_entry(CachedL2Table *entry)
{
if (!entry) {
return;
}
entry->ref--;
trace_qed_unref_l2_cache_entry(entry, entry->ref);
if (entry->ref == 0) {
qemu_vfree(entry->table);
g_free(entry);
}
}
/**
* Find an entry in the L2 cache. This may return NULL and it's up to the
* caller to satisfy the cache miss.
*
* For a cached entry, this function increases the reference count and returns
* the entry.
*/
CachedL2Table *qed_find_l2_cache_entry(L2TableCache *l2_cache, uint64_t offset)
{
CachedL2Table *entry;
QTAILQ_FOREACH(entry, &l2_cache->entries, node) {
if (entry->offset == offset) {
trace_qed_find_l2_cache_entry(l2_cache, entry, offset, entry->ref);
entry->ref++;
return entry;
}
}
return NULL;
}
/**
* Commit an L2 cache entry into the cache. This is meant to be used as part of
* the process to satisfy a cache miss. A caller would allocate an entry which
* is not actually in the L2 cache and then once the entry was valid and
* present on disk, the entry can be committed into the cache.
*
* Since the cache is write-through, it's important that this function is not
* called until the entry is present on disk and the L1 has been updated to
* point to the entry.
*
* N.B. This function steals a reference to the l2_table from the caller so the
* caller must obtain a new reference by issuing a call to
* qed_find_l2_cache_entry().
*/
void qed_commit_l2_cache_entry(L2TableCache *l2_cache, CachedL2Table *l2_table)
{
CachedL2Table *entry;
entry = qed_find_l2_cache_entry(l2_cache, l2_table->offset);
if (entry) {
qed_unref_l2_cache_entry(entry);
qed_unref_l2_cache_entry(l2_table);
return;
}
/* Evict an unused cache entry so we have space. If all entries are in use
* we can grow the cache temporarily and we try to shrink back down later.
*/
if (l2_cache->n_entries >= MAX_L2_CACHE_SIZE) {
CachedL2Table *next;
QTAILQ_FOREACH_SAFE(entry, &l2_cache->entries, node, next) {
if (entry->ref > 1) {
continue;
}
QTAILQ_REMOVE(&l2_cache->entries, entry, node);
l2_cache->n_entries--;
qed_unref_l2_cache_entry(entry);
/* Stop evicting when we've shrunk back to max size */
if (l2_cache->n_entries < MAX_L2_CACHE_SIZE) {
break;
}
}
}
l2_cache->n_entries++;
QTAILQ_INSERT_TAIL(&l2_cache->entries, l2_table, node);
}