blob: 1f9538d32a7245b117a51e00f8238ad0c7f5aef5 [file] [log] [blame]
/*
* Copyright 2020 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "src/gpu/ganesh/GrThreadSafeCache.h"
#include "include/gpu/GrDirectContext.h"
#include "src/gpu/GpuTypesPriv.h"
#include "src/gpu/ganesh/GrCaps.h"
#include "src/gpu/ganesh/GrDirectContextPriv.h"
#include "src/gpu/ganesh/GrGpuBuffer.h"
#include "src/gpu/ganesh/GrProxyProvider.h"
#include "src/gpu/ganesh/GrRenderTargetProxy.h"
#include "src/gpu/ganesh/GrResourceCache.h"
#include "src/gpu/ganesh/GrTexture.h"
GrThreadSafeCache::VertexData::~VertexData () {
this->reset();
}
GrThreadSafeCache::GrThreadSafeCache()
: fFreeEntryList(nullptr) {
}
GrThreadSafeCache::~GrThreadSafeCache() {
this->dropAllRefs();
}
#if defined(GR_TEST_UTILS)
int GrThreadSafeCache::numEntries() const {
SkAutoSpinlock lock{fSpinLock};
return fUniquelyKeyedEntryMap.count();
}
size_t GrThreadSafeCache::approxBytesUsedForHash() const {
SkAutoSpinlock lock{fSpinLock};
return fUniquelyKeyedEntryMap.approxBytesUsed();
}
#endif
void GrThreadSafeCache::dropAllRefs() {
SkAutoSpinlock lock{fSpinLock};
fUniquelyKeyedEntryMap.reset();
while (auto tmp = fUniquelyKeyedEntryList.head()) {
fUniquelyKeyedEntryList.remove(tmp);
this->recycleEntry(tmp);
}
// TODO: should we empty out the fFreeEntryList and reset fEntryAllocator?
}
// TODO: If iterating becomes too expensive switch to using something like GrIORef for the
// GrSurfaceProxy
void GrThreadSafeCache::dropUniqueRefs(GrResourceCache* resourceCache) {
SkAutoSpinlock lock{fSpinLock};
// Iterate from LRU to MRU
Entry* cur = fUniquelyKeyedEntryList.tail();
Entry* prev = cur ? cur->fPrev : nullptr;
while (cur) {
if (resourceCache && !resourceCache->overBudget()) {
return;
}
if (cur->uniquelyHeld()) {
fUniquelyKeyedEntryMap.remove(cur->key());
fUniquelyKeyedEntryList.remove(cur);
this->recycleEntry(cur);
}
cur = prev;
prev = cur ? cur->fPrev : nullptr;
}
}
void GrThreadSafeCache::dropUniqueRefsOlderThan(skgpu::StdSteadyClock::time_point purgeTime) {
SkAutoSpinlock lock{fSpinLock};
// Iterate from LRU to MRU
Entry* cur = fUniquelyKeyedEntryList.tail();
Entry* prev = cur ? cur->fPrev : nullptr;
while (cur) {
if (cur->fLastAccess >= purgeTime) {
// This entry and all the remaining ones in the list will be newer than 'purgeTime'
return;
}
if (cur->uniquelyHeld()) {
fUniquelyKeyedEntryMap.remove(cur->key());
fUniquelyKeyedEntryList.remove(cur);
this->recycleEntry(cur);
}
cur = prev;
prev = cur ? cur->fPrev : nullptr;
}
}
void GrThreadSafeCache::makeExistingEntryMRU(Entry* entry) {
SkASSERT(fUniquelyKeyedEntryList.isInList(entry));
entry->fLastAccess = skgpu::StdSteadyClock::now();
fUniquelyKeyedEntryList.remove(entry);
fUniquelyKeyedEntryList.addToHead(entry);
}
std::tuple<GrSurfaceProxyView, sk_sp<SkData>> GrThreadSafeCache::internalFind(
const skgpu::UniqueKey& key) {
Entry* tmp = fUniquelyKeyedEntryMap.find(key);
if (tmp) {
this->makeExistingEntryMRU(tmp);
return { tmp->view(), tmp->refCustomData() };
}
return {};
}
#ifdef SK_DEBUG
bool GrThreadSafeCache::has(const skgpu::UniqueKey& key) {
SkAutoSpinlock lock{fSpinLock};
Entry* tmp = fUniquelyKeyedEntryMap.find(key);
return SkToBool(tmp);
}
#endif
GrSurfaceProxyView GrThreadSafeCache::find(const skgpu::UniqueKey& key) {
SkAutoSpinlock lock{fSpinLock};
GrSurfaceProxyView view;
std::tie(view, std::ignore) = this->internalFind(key);
return view;
}
std::tuple<GrSurfaceProxyView, sk_sp<SkData>> GrThreadSafeCache::findWithData(
const skgpu::UniqueKey& key) {
SkAutoSpinlock lock{fSpinLock};
return this->internalFind(key);
}
GrThreadSafeCache::Entry* GrThreadSafeCache::getEntry(const skgpu::UniqueKey& key,
const GrSurfaceProxyView& view) {
Entry* entry;
if (fFreeEntryList) {
entry = fFreeEntryList;
fFreeEntryList = entry->fNext;
entry->fNext = nullptr;
entry->set(key, view);
} else {
entry = fEntryAllocator.make<Entry>(key, view);
}
return this->makeNewEntryMRU(entry);
}
GrThreadSafeCache::Entry* GrThreadSafeCache::makeNewEntryMRU(Entry* entry) {
entry->fLastAccess = skgpu::StdSteadyClock::now();
fUniquelyKeyedEntryList.addToHead(entry);
fUniquelyKeyedEntryMap.add(entry);
return entry;
}
GrThreadSafeCache::Entry* GrThreadSafeCache::getEntry(const skgpu::UniqueKey& key,
sk_sp<VertexData> vertData) {
Entry* entry;
if (fFreeEntryList) {
entry = fFreeEntryList;
fFreeEntryList = entry->fNext;
entry->fNext = nullptr;
entry->set(key, std::move(vertData));
} else {
entry = fEntryAllocator.make<Entry>(key, std::move(vertData));
}
return this->makeNewEntryMRU(entry);
}
void GrThreadSafeCache::recycleEntry(Entry* dead) {
SkASSERT(!dead->fPrev && !dead->fNext && !dead->fList);
dead->makeEmpty();
dead->fNext = fFreeEntryList;
fFreeEntryList = dead;
}
std::tuple<GrSurfaceProxyView, sk_sp<SkData>> GrThreadSafeCache::internalAdd(
const skgpu::UniqueKey& key,
const GrSurfaceProxyView& view) {
Entry* tmp = fUniquelyKeyedEntryMap.find(key);
if (!tmp) {
tmp = this->getEntry(key, view);
SkASSERT(fUniquelyKeyedEntryMap.find(key));
}
return { tmp->view(), tmp->refCustomData() };
}
GrSurfaceProxyView GrThreadSafeCache::add(const skgpu::UniqueKey& key,
const GrSurfaceProxyView& view) {
SkAutoSpinlock lock{fSpinLock};
GrSurfaceProxyView newView;
std::tie(newView, std::ignore) = this->internalAdd(key, view);
return newView;
}
std::tuple<GrSurfaceProxyView, sk_sp<SkData>> GrThreadSafeCache::addWithData(
const skgpu::UniqueKey& key,
const GrSurfaceProxyView& view) {
SkAutoSpinlock lock{fSpinLock};
return this->internalAdd(key, view);
}
GrSurfaceProxyView GrThreadSafeCache::findOrAdd(const skgpu::UniqueKey& key,
const GrSurfaceProxyView& v) {
SkAutoSpinlock lock{fSpinLock};
GrSurfaceProxyView view;
std::tie(view, std::ignore) = this->internalFind(key);
if (view) {
return view;
}
std::tie(view, std::ignore) = this->internalAdd(key, v);
return view;
}
std::tuple<GrSurfaceProxyView, sk_sp<SkData>> GrThreadSafeCache::findOrAddWithData(
const skgpu::UniqueKey& key,
const GrSurfaceProxyView& v) {
SkAutoSpinlock lock{fSpinLock};
auto [view, data] = this->internalFind(key);
if (view) {
return { std::move(view), std::move(data) };
}
return this->internalAdd(key, v);
}
sk_sp<GrThreadSafeCache::VertexData> GrThreadSafeCache::MakeVertexData(const void* vertices,
int vertexCount,
size_t vertexSize) {
return sk_sp<VertexData>(new VertexData(vertices, vertexCount, vertexSize));
}
sk_sp<GrThreadSafeCache::VertexData> GrThreadSafeCache::MakeVertexData(sk_sp<GrGpuBuffer> buffer,
int vertexCount,
size_t vertexSize) {
return sk_sp<VertexData>(new VertexData(std::move(buffer), vertexCount, vertexSize));
}
std::tuple<sk_sp<GrThreadSafeCache::VertexData>, sk_sp<SkData>>
GrThreadSafeCache::internalFindVerts(const skgpu::UniqueKey& key) {
Entry* tmp = fUniquelyKeyedEntryMap.find(key);
if (tmp) {
this->makeExistingEntryMRU(tmp);
return { tmp->vertexData(), tmp->refCustomData() };
}
return {};
}
std::tuple<sk_sp<GrThreadSafeCache::VertexData>, sk_sp<SkData>>
GrThreadSafeCache::findVertsWithData(const skgpu::UniqueKey& key) {
SkAutoSpinlock lock{fSpinLock};
return this->internalFindVerts(key);
}
std::tuple<sk_sp<GrThreadSafeCache::VertexData>, sk_sp<SkData>> GrThreadSafeCache::internalAddVerts(
const skgpu::UniqueKey& key,
sk_sp<VertexData> vertData,
IsNewerBetter isNewerBetter) {
Entry* tmp = fUniquelyKeyedEntryMap.find(key);
if (!tmp) {
tmp = this->getEntry(key, std::move(vertData));
SkASSERT(fUniquelyKeyedEntryMap.find(key));
} else if (isNewerBetter(tmp->getCustomData(), key.getCustomData())) {
// This orphans any existing uses of the prior vertex data but ensures the best
// version is in the cache.
tmp->set(key, std::move(vertData));
}
return { tmp->vertexData(), tmp->refCustomData() };
}
std::tuple<sk_sp<GrThreadSafeCache::VertexData>, sk_sp<SkData>> GrThreadSafeCache::addVertsWithData(
const skgpu::UniqueKey& key,
sk_sp<VertexData> vertData,
IsNewerBetter isNewerBetter) {
SkAutoSpinlock lock{fSpinLock};
return this->internalAddVerts(key, std::move(vertData), isNewerBetter);
}
void GrThreadSafeCache::remove(const skgpu::UniqueKey& key) {
SkAutoSpinlock lock{fSpinLock};
Entry* tmp = fUniquelyKeyedEntryMap.find(key);
if (tmp) {
fUniquelyKeyedEntryMap.remove(key);
fUniquelyKeyedEntryList.remove(tmp);
this->recycleEntry(tmp);
}
}
std::tuple<GrSurfaceProxyView, sk_sp<GrThreadSafeCache::Trampoline>>
GrThreadSafeCache::CreateLazyView(GrDirectContext* dContext,
GrColorType origCT,
SkISize dimensions,
GrSurfaceOrigin origin,
SkBackingFit fit) {
GrProxyProvider* proxyProvider = dContext->priv().proxyProvider();
const GrCaps* caps = dContext->priv().caps();
constexpr int kSampleCnt = 1;
auto [newCT, format] = caps->getFallbackColorTypeAndFormat(origCT, kSampleCnt);
if (newCT == GrColorType::kUnknown) {
return {GrSurfaceProxyView(nullptr), nullptr};
}
sk_sp<Trampoline> trampoline(new Trampoline);
GrProxyProvider::TextureInfo texInfo{skgpu::Mipmapped::kNo, GrTextureType::k2D};
sk_sp<GrRenderTargetProxy> proxy = proxyProvider->createLazyRenderTargetProxy(
[trampoline](
GrResourceProvider* resourceProvider,
const GrSurfaceProxy::LazySurfaceDesc&) -> GrSurfaceProxy::LazyCallbackResult {
if (!resourceProvider || !trampoline->fProxy ||
!trampoline->fProxy->isInstantiated()) {
return GrSurfaceProxy::LazyCallbackResult(nullptr, true);
}
SkASSERT(!trampoline->fProxy->peekTexture()->getUniqueKey().isValid());
return GrSurfaceProxy::LazyCallbackResult(
sk_ref_sp(trampoline->fProxy->peekTexture()));
},
format,
dimensions,
kSampleCnt,
GrInternalSurfaceFlags::kNone,
&texInfo,
GrMipmapStatus::kNotAllocated,
fit,
skgpu::Budgeted::kYes,
GrProtected::kNo,
/* wrapsVkSecondaryCB */ false,
GrSurfaceProxy::UseAllocator::kYes);
// TODO: It seems like this 'newCT' usage should be 'origCT' but this is
// what skgpu::ganesh::SurfaceDrawContext::MakeWithFallback does
skgpu::Swizzle swizzle = dContext->priv().caps()->getReadSwizzle(format, newCT);
return {{std::move(proxy), origin, swizzle}, std::move(trampoline)};
}