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/*
* Copyright 2014 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkBitmapCache.h"
#include "SkImage.h"
#include "SkResourceCache.h"
#include "SkMipMap.h"
#include "SkPixelRef.h"
#include "SkRect.h"
/**
* Use this for bitmapcache and mipmapcache entries.
*/
uint64_t SkMakeResourceCacheSharedIDForBitmap(uint32_t bitmapGenID) {
uint64_t sharedID = SkSetFourByteTag('b', 'm', 'a', 'p');
return (sharedID << 32) | bitmapGenID;
}
void SkNotifyBitmapGenIDIsStale(uint32_t bitmapGenID) {
SkResourceCache::PostPurgeSharedID(SkMakeResourceCacheSharedIDForBitmap(bitmapGenID));
}
///////////////////////////////////////////////////////////////////////////////////////////////////
/**
This function finds the bounds of the bitmap *within its pixelRef*.
If the bitmap lacks a pixelRef, it will return an empty rect, since
that doesn't make sense. This may be a useful enough function that
it should be somewhere else (in SkBitmap?).
*/
static SkIRect get_bounds_from_bitmap(const SkBitmap& bm) {
if (!(bm.pixelRef())) {
return SkIRect::MakeEmpty();
}
SkIPoint origin = bm.pixelRefOrigin();
return SkIRect::MakeXYWH(origin.fX, origin.fY, bm.width(), bm.height());
}
/**
* This function finds the bounds of the image. Today this is just the entire bounds,
* but in the future we may support subsets within an image, in which case this should
* return that subset (see get_bounds_from_bitmap).
*/
static SkIRect get_bounds_from_image(const SkImage* image) {
SkASSERT(image->width() > 0 && image->height() > 0);
return SkIRect::MakeWH(image->width(), image->height());
}
SkBitmapCacheDesc SkBitmapCacheDesc::Make(uint32_t imageID, int origWidth, int origHeight) {
SkASSERT(imageID);
SkASSERT(origWidth > 0 && origHeight > 0);
return { imageID, 0, 0, {0, 0, origWidth, origHeight} };
}
SkBitmapCacheDesc SkBitmapCacheDesc::Make(const SkBitmap& bm, int scaledWidth, int scaledHeight) {
SkASSERT(bm.width() > 0 && bm.height() > 0);
SkASSERT(scaledWidth > 0 && scaledHeight > 0);
SkASSERT(scaledWidth != bm.width() || scaledHeight != bm.height());
return { bm.getGenerationID(), scaledWidth, scaledHeight, get_bounds_from_bitmap(bm) };
}
SkBitmapCacheDesc SkBitmapCacheDesc::Make(const SkBitmap& bm) {
SkASSERT(bm.width() > 0 && bm.height() > 0);
SkASSERT(bm.pixelRefOrigin() == SkIPoint::Make(0, 0));
return { bm.getGenerationID(), 0, 0, get_bounds_from_bitmap(bm) };
}
SkBitmapCacheDesc SkBitmapCacheDesc::Make(const SkImage* image, int scaledWidth, int scaledHeight) {
SkASSERT(image->width() > 0 && image->height() > 0);
SkASSERT(scaledWidth > 0 && scaledHeight > 0);
// If the dimensions are the same, should we set them to 0,0?
//SkASSERT(scaledWidth != image->width() || scaledHeight != image->height());
return { image->uniqueID(), scaledWidth, scaledHeight, get_bounds_from_image(image) };
}
SkBitmapCacheDesc SkBitmapCacheDesc::Make(const SkImage* image) {
SkASSERT(image->width() > 0 && image->height() > 0);
return { image->uniqueID(), 0, 0, get_bounds_from_image(image) };
}
namespace {
static unsigned gBitmapKeyNamespaceLabel;
struct BitmapKey : public SkResourceCache::Key {
public:
BitmapKey(const SkBitmapCacheDesc& desc) : fDesc(desc) {
this->init(&gBitmapKeyNamespaceLabel, SkMakeResourceCacheSharedIDForBitmap(fDesc.fImageID),
sizeof(fDesc));
}
void dump() const {
SkDebugf("-- add [%d %d] %d [%d %d %d %d]\n",
fDesc.fScaledWidth, fDesc.fScaledHeight, fDesc.fImageID,
fDesc.fSubset.x(), fDesc.fSubset.y(), fDesc.fSubset.width(), fDesc.fSubset.height());
}
const SkBitmapCacheDesc fDesc;
};
}
//////////////////////
#include "SkDiscardableMemory.h"
#include "SkNextID.h"
void SkBitmapCache_setImmutableWithID(SkPixelRef* pr, uint32_t id) {
pr->setImmutableWithID(id);
}
//#define REC_TRACE SkDebugf
static void REC_TRACE(const char format[], ...) {}
// for diagnostics
static int32_t gRecCounter;
class SkBitmapCache::Rec : public SkResourceCache::Rec {
public:
Rec(const SkBitmapCacheDesc& desc, const SkImageInfo& info, size_t rowBytes,
std::unique_ptr<SkDiscardableMemory> dm, void* block)
: fKey(desc)
, fDM(std::move(dm))
, fMalloc(block)
, fInfo(info)
, fRowBytes(rowBytes)
, fExternalCounter(kBeforeFirstInstall_ExternalCounter)
{
SkASSERT(!(fDM && fMalloc)); // can't have both
// We need an ID to return with the bitmap/pixelref.
// If they are not scaling, we can return the same ID as the key/desc
// If they are scaling, we need a new ID
if (desc.fScaledWidth == 0 && desc.fScaledHeight == 0) {
fPrUniqueID = desc.fImageID;
} else {
fPrUniqueID = SkNextID::ImageID();
}
REC_TRACE(" Rec(%d): [%d %d] %d\n",
sk_atomic_inc(&gRecCounter), fInfo.width(), fInfo.height(), fPrUniqueID);
}
~Rec() override {
SkASSERT(0 == fExternalCounter || kBeforeFirstInstall_ExternalCounter == fExternalCounter);
if (fDM && kBeforeFirstInstall_ExternalCounter == fExternalCounter) {
// we never installed, so we need to unlock before we destroy the DM
SkASSERT(fDM->data());
fDM->unlock();
}
REC_TRACE("~Rec(%d): [%d %d] %d\n",
sk_atomic_dec(&gRecCounter) - 1, fInfo.width(), fInfo.height(), fPrUniqueID);
sk_free(fMalloc); // may be null
}
const Key& getKey() const override { return fKey; }
size_t bytesUsed() const override {
return sizeof(fKey) + fInfo.computeByteSize(fRowBytes);
}
bool canBePurged() override {
SkAutoMutexAcquire ama(fMutex);
return fExternalCounter == 0;
}
void postAddInstall(void* payload) override {
SkAssertResult(this->install(static_cast<SkBitmap*>(payload)));
}
const char* getCategory() const override { return "bitmap"; }
SkDiscardableMemory* diagnostic_only_getDiscardable() const override {
return fDM.get();
}
static void ReleaseProc(void* addr, void* ctx) {
Rec* rec = static_cast<Rec*>(ctx);
SkAutoMutexAcquire ama(rec->fMutex);
REC_TRACE(" Rec: [%d] releaseproc\n", rec->fPrUniqueID);
SkASSERT(rec->fExternalCounter > 0);
rec->fExternalCounter -= 1;
if (rec->fDM) {
SkASSERT(rec->fMalloc == nullptr);
if (rec->fExternalCounter == 0) {
REC_TRACE(" Rec [%d] unlock\n", rec->fPrUniqueID);
rec->fDM->unlock();
}
} else {
SkASSERT(rec->fMalloc != nullptr);
}
}
bool install(SkBitmap* bitmap) {
SkAutoMutexAcquire ama(fMutex);
// are we still valid
if (!fDM && !fMalloc) {
REC_TRACE(" Rec: [%d] invalid\n", fPrUniqueID);
return false;
}
/*
constructor fExternalCount < 0 fDM->data()
after install fExternalCount > 0 fDM->data()
after Release fExternalCount == 0 !fDM->data()
*/
if (fDM) {
if (kBeforeFirstInstall_ExternalCounter == fExternalCounter) {
SkASSERT(fDM->data());
} else if (fExternalCounter > 0) {
SkASSERT(fDM->data());
} else {
SkASSERT(fExternalCounter == 0);
if (!fDM->lock()) {
REC_TRACE(" Rec [%d] re-lock failed\n", fPrUniqueID);
fDM.reset(nullptr);
return false;
}
REC_TRACE(" Rec [%d] re-lock succeeded\n", fPrUniqueID);
}
SkASSERT(fDM->data());
}
bitmap->installPixels(fInfo, fDM ? fDM->data() : fMalloc, fRowBytes, ReleaseProc, this);
SkBitmapCache_setImmutableWithID(bitmap->pixelRef(), fPrUniqueID);
REC_TRACE(" Rec: [%d] install new pr\n", fPrUniqueID);
if (kBeforeFirstInstall_ExternalCounter == fExternalCounter) {
fExternalCounter = 1;
} else {
fExternalCounter += 1;
}
SkASSERT(fExternalCounter > 0);
return true;
}
static bool Finder(const SkResourceCache::Rec& baseRec, void* contextBitmap) {
Rec* rec = (Rec*)&baseRec;
SkBitmap* result = (SkBitmap*)contextBitmap;
REC_TRACE(" Rec: [%d] found\n", rec->fPrUniqueID);
return rec->install(result);
}
private:
BitmapKey fKey;
SkMutex fMutex;
// either fDM or fMalloc can be non-null, but not both
std::unique_ptr<SkDiscardableMemory> fDM;
void* fMalloc;
SkImageInfo fInfo;
size_t fRowBytes;
uint32_t fPrUniqueID;
// This field counts the number of external pixelrefs we have created. They notify us when
// they are destroyed so we can decrement this.
//
// > 0 we have outstanding pixelrefs
// == 0 we have no outstanding pixelrefs, and can be safely purged
// < 0 we have been created, but not yet "installed" the first time.
//
int fExternalCounter;
enum {
kBeforeFirstInstall_ExternalCounter = -1
};
};
void SkBitmapCache::PrivateDeleteRec(Rec* rec) { delete rec; }
SkBitmapCache::RecPtr SkBitmapCache::Alloc(const SkBitmapCacheDesc& desc, const SkImageInfo& info,
SkPixmap* pmap) {
// Ensure that the caller is self-consistent:
// - if they are scaling, the info matches the scaled size
// - if they are not, the info matches the subset (i.e. the subset is the entire image)
if (desc.fScaledWidth == 0 && desc.fScaledHeight == 0) {
SkASSERT(info.width() == desc.fSubset.width());
SkASSERT(info.height() == desc.fSubset.height());
} else {
SkASSERT(info.width() == desc.fScaledWidth);
SkASSERT(info.height() == desc.fScaledHeight);
}
const size_t rb = info.minRowBytes();
size_t size = info.computeByteSize(rb);
if (SkImageInfo::ByteSizeOverflowed(size)) {
return nullptr;
}
std::unique_ptr<SkDiscardableMemory> dm;
void* block = nullptr;
auto factory = SkResourceCache::GetDiscardableFactory();
if (factory) {
dm.reset(factory(size));
} else {
block = sk_malloc_canfail(size);
}
if (!dm && !block) {
return nullptr;
}
*pmap = SkPixmap(info, dm ? dm->data() : block, rb);
return RecPtr(new Rec(desc, info, rb, std::move(dm), block));
}
void SkBitmapCache::Add(RecPtr rec, SkBitmap* bitmap) {
SkResourceCache::Add(rec.release(), bitmap);
}
bool SkBitmapCache::Find(const SkBitmapCacheDesc& desc, SkBitmap* result) {
desc.validate();
return SkResourceCache::Find(BitmapKey(desc), SkBitmapCache::Rec::Finder, result);
}
//////////////////////////////////////////////////////////////////////////////////////////
//////////////////////////////////////////////////////////////////////////////////////////
#define CHECK_LOCAL(localCache, localName, globalName, ...) \
((localCache) ? localCache->localName(__VA_ARGS__) : SkResourceCache::globalName(__VA_ARGS__))
namespace {
static unsigned gMipMapKeyNamespaceLabel;
struct MipMapKey : public SkResourceCache::Key {
public:
MipMapKey(uint32_t imageID, const SkIRect& subset)
: fImageID(imageID)
, fSubset(subset)
{
SkASSERT(fImageID);
SkASSERT(!subset.isEmpty());
this->init(&gMipMapKeyNamespaceLabel, SkMakeResourceCacheSharedIDForBitmap(fImageID),
sizeof(fImageID) + sizeof(fSubset));
}
uint32_t fImageID;
SkIRect fSubset;
};
struct MipMapRec : public SkResourceCache::Rec {
MipMapRec(uint32_t imageID, const SkIRect& subset, const SkMipMap* result)
: fKey(imageID, subset)
, fMipMap(result)
{
fMipMap->attachToCacheAndRef();
}
~MipMapRec() override {
fMipMap->detachFromCacheAndUnref();
}
const Key& getKey() const override { return fKey; }
size_t bytesUsed() const override { return sizeof(fKey) + fMipMap->size(); }
const char* getCategory() const override { return "mipmap"; }
SkDiscardableMemory* diagnostic_only_getDiscardable() const override {
return fMipMap->diagnostic_only_getDiscardable();
}
static bool Finder(const SkResourceCache::Rec& baseRec, void* contextMip) {
const MipMapRec& rec = static_cast<const MipMapRec&>(baseRec);
const SkMipMap* mm = SkRef(rec.fMipMap);
// the call to ref() above triggers a "lock" in the case of discardable memory,
// which means we can now check for null (in case the lock failed).
if (nullptr == mm->data()) {
mm->unref(); // balance our call to ref()
return false;
}
// the call must call unref() when they are done.
*(const SkMipMap**)contextMip = mm;
return true;
}
private:
MipMapKey fKey;
const SkMipMap* fMipMap;
};
}
const SkMipMap* SkMipMapCache::FindAndRef(const SkBitmapCacheDesc& desc,
SkResourceCache* localCache) {
SkASSERT(desc.fScaledWidth == 0);
SkASSERT(desc.fScaledHeight == 0);
MipMapKey key(desc.fImageID, desc.fSubset);
const SkMipMap* result;
if (!CHECK_LOCAL(localCache, find, Find, key, MipMapRec::Finder, &result)) {
result = nullptr;
}
return result;
}
static SkResourceCache::DiscardableFactory get_fact(SkResourceCache* localCache) {
return localCache ? localCache->GetDiscardableFactory()
: SkResourceCache::GetDiscardableFactory();
}
const SkMipMap* SkMipMapCache::AddAndRef(const SkBitmap& src, SkResourceCache* localCache) {
SkMipMap* mipmap = SkMipMap::Build(src, get_fact(localCache));
if (mipmap) {
MipMapRec* rec = new MipMapRec(src.getGenerationID(), get_bounds_from_bitmap(src), mipmap);
CHECK_LOCAL(localCache, add, Add, rec);
src.pixelRef()->notifyAddedToCache();
}
return mipmap;
}
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