blob: d3a8f03138e1b754abf3385aa69176a58b5f74ab [file] [log] [blame]
/*
* Copyright 2011 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrResourceCache_DEFINED
#define GrResourceCache_DEFINED
#include "GrTypes.h"
#include "GrTHashCache.h"
class GrResource;
// return true if a<b, or false if b<a
//
#define RET_IF_LT_OR_GT(a, b) \
do { \
if ((a) < (b)) { \
return true; \
} \
if ((b) < (a)) { \
return false; \
} \
} while (0)
/**
* Helper class for GrResourceCache, the Key is used to identify src data for
* a resource. It is identified by 2 32bit data fields which can hold any
* data (uninterpreted by the cache) and a width/height.
*/
class GrResourceKey {
public:
enum {
kHashBits = 7,
kHashCount = 1 << kHashBits,
kHashMask = kHashCount - 1
};
GrResourceKey(uint32_t p0, uint32_t p1, uint32_t p2, uint32_t p3) {
fP[0] = p0;
fP[1] = p1;
fP[2] = p2;
fP[3] = p3;
this->computeHashIndex();
}
GrResourceKey(uint32_t v[4]) {
memcpy(fP, v, 4 * sizeof(uint32_t));
this->computeHashIndex();
}
GrResourceKey(const GrResourceKey& src) {
memcpy(fP, src.fP, 4 * sizeof(uint32_t));
#if GR_DEBUG
this->computeHashIndex();
GrAssert(fHashIndex == src.fHashIndex);
#endif
fHashIndex = src.fHashIndex;
}
//!< returns hash value [0..kHashMask] for the key
int hashIndex() const { return fHashIndex; }
friend bool operator==(const GrResourceKey& a, const GrResourceKey& b) {
GR_DEBUGASSERT(-1 != a.fHashIndex && -1 != b.fHashIndex);
return 0 == memcmp(a.fP, b.fP, 4 * sizeof(uint32_t));
}
friend bool operator!=(const GrResourceKey& a, const GrResourceKey& b) {
GR_DEBUGASSERT(-1 != a.fHashIndex && -1 != b.fHashIndex);
return !(a == b);
}
friend bool operator<(const GrResourceKey& a, const GrResourceKey& b) {
RET_IF_LT_OR_GT(a.fP[0], b.fP[0]);
RET_IF_LT_OR_GT(a.fP[1], b.fP[1]);
RET_IF_LT_OR_GT(a.fP[2], b.fP[2]);
return a.fP[3] < b.fP[3];
}
uint32_t getValue32(int i) const {
GrAssert(i >=0 && i < 4);
return fP[i];
}
private:
static uint32_t rol(uint32_t x) {
return (x >> 24) | (x << 8);
}
static uint32_t ror(uint32_t x) {
return (x >> 8) | (x << 24);
}
static uint32_t rohalf(uint32_t x) {
return (x >> 16) | (x << 16);
}
void computeHashIndex() {
uint32_t hash = fP[0] ^ rol(fP[1]) ^ ror(fP[2]) ^ rohalf(fP[3]);
// this way to mix and reduce hash to its index may have to change
// depending on how many bits we allocate to the index
hash ^= hash >> 16;
hash ^= hash >> 8;
fHashIndex = hash & kHashMask;
}
uint32_t fP[4];
// this is computed from the fP... fields
int fHashIndex;
friend class GrContext;
};
///////////////////////////////////////////////////////////////////////////////
class GrResourceEntry {
public:
GrResource* resource() const { return fResource; }
const GrResourceKey& key() const { return fKey; }
#if GR_DEBUG
GrResourceEntry* next() const { return fNext; }
GrResourceEntry* prev() const { return fPrev; }
#endif
#if GR_DEBUG
void validate() const;
#else
void validate() const {}
#endif
private:
GrResourceEntry(const GrResourceKey& key, GrResource* resource);
~GrResourceEntry();
bool isLocked() const { return fLockCount != 0; }
void lock() { ++fLockCount; }
void unlock() {
GrAssert(fLockCount > 0);
--fLockCount;
}
GrResourceKey fKey;
GrResource* fResource;
// track if we're in use, used when we need to purge
// we only purge unlocked entries
int fLockCount;
// we're a dlinklist
GrResourceEntry* fPrev;
GrResourceEntry* fNext;
friend class GrResourceCache;
};
///////////////////////////////////////////////////////////////////////////////
#include "GrTHashCache.h"
/**
* Cache of GrResource objects.
*
* These have a corresponding GrResourceKey, built from 128bits identifying the
* resource.
*
* The cache stores the entries in a double-linked list, which is its LRU.
* When an entry is "locked" (i.e. given to the caller), it is moved to the
* head of the list. If/when we must purge some of the entries, we walk the
* list backwards from the tail, since those are the least recently used.
*
* For fast searches, we maintain a sorted array (based on the GrResourceKey)
* which we can bsearch. When a new entry is added, it is inserted into this
* array.
*
* For even faster searches, a hash is computed from the Key. If there is
* a collision between two keys with the same hash, we fall back on the
* bsearch, and update the hash to reflect the most recent Key requested.
*/
class GrResourceCache {
public:
GrResourceCache(int maxCount, size_t maxBytes);
~GrResourceCache();
/**
* Return the current resource cache limits.
*
* @param maxResource If non-null, returns maximum number of resources
* that can be held in the cache.
* @param maxBytes If non-null, returns maximum number of bytes of
* gpu memory that can be held in the cache.
*/
void getLimits(int* maxResources, size_t* maxBytes) const;
/**
* Specify the resource cache limits. If the current cache exceeds either
* of these, it will be purged (LRU) to keep the cache within these limits.
*
* @param maxResources The maximum number of resources that can be held in
* the cache.
* @param maxBytes The maximum number of bytes of resource memory that
* can be held in the cache.
*/
void setLimits(int maxResource, size_t maxResourceBytes);
/**
* Controls whether locks should be nestable or not.
*/
enum LockType {
kNested_LockType,
kSingle_LockType,
};
/**
* Search for an entry with the same Key. If found, "lock" it and return it.
* If not found, return null.
*/
GrResourceEntry* findAndLock(const GrResourceKey&, LockType style);
/**
* Create a new entry, based on the specified key and resource, and return
* its "locked" entry.
*
* Ownership of the resource is transferred to the Entry, which will unref()
* it when we are purged or deleted.
*/
GrResourceEntry* createAndLock(const GrResourceKey&, GrResource*);
/**
* Detach removes an entry from the cache. This prevents the entry from
* being found by a subsequent findAndLock() until it is reattached. The
* entry still counts against the cache's budget and should be reattached
* when exclusive access is no longer needed.
*/
void detach(GrResourceEntry*);
/**
* Reattaches a resource to the cache and unlocks it. Allows it to be found
* by a subsequent findAndLock or be purged (provided its lock count is
* now 0.)
*/
void reattachAndUnlock(GrResourceEntry*);
/**
* When done with an entry, call unlock(entry) on it, which returns it to
* a purgable state.
*/
void unlock(GrResourceEntry*);
void removeAll();
#if GR_DEBUG
void validate() const;
#else
void validate() const {}
#endif
private:
void internalDetach(GrResourceEntry*, bool);
void attachToHead(GrResourceEntry*, bool);
void purgeAsNeeded();
class Key;
GrTHashTable<GrResourceEntry, Key, 8> fCache;
// manage the dlink list
GrResourceEntry* fHead;
GrResourceEntry* fTail;
// our budget, used in purgeAsNeeded()
int fMaxCount;
size_t fMaxBytes;
// our current stats, related to our budget
int fEntryCount;
int fUnlockedEntryCount;
size_t fEntryBytes;
int fClientDetachedCount;
size_t fClientDetachedBytes;
// prevents recursive purging
bool fPurging;
};
///////////////////////////////////////////////////////////////////////////////
#if GR_DEBUG
class GrAutoResourceCacheValidate {
public:
GrAutoResourceCacheValidate(GrResourceCache* cache) : fCache(cache) {
cache->validate();
}
~GrAutoResourceCacheValidate() {
fCache->validate();
}
private:
GrResourceCache* fCache;
};
#else
class GrAutoResourceCacheValidate {
public:
GrAutoResourceCacheValidate(GrResourceCache*) {}
};
#endif
#endif