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/*
Copyright 2010 Google Inc.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
#include "GrGpu.h"
#include "GrMemory.h"
#include "GrTextStrike.h"
#include "GrTextureCache.h"
#include "GrClipIterator.h"
#include "GrIndexBuffer.h"
#include "GrVertexBuffer.h"
#include "GrBufferAllocPool.h"
#include "GrPathRenderer.h"
// probably makes no sense for this to be less than a page
static const size_t VERTEX_POOL_VB_SIZE = 1 << 12;
static const int VERTEX_POOL_VB_COUNT = 1;
////////////////////////////////////////////////////////////////////////////////
extern void gr_run_unittests();
GrGpu::GrGpu()
: f8bitPaletteSupport(false)
, fCurrPoolVertexBuffer(NULL)
, fCurrPoolStartVertex(0)
, fCurrPoolIndexBuffer(NULL)
, fCurrPoolStartIndex(0)
, fContext(NULL)
, fVertexPool(NULL)
, fIndexPool(NULL)
, fQuadIndexBuffer(NULL)
, fUnitSquareVertexBuffer(NULL)
, fDefaultPathRenderer(NULL)
, fClientPathRenderer(NULL)
, fContextIsDirty(true)
, fVertexPoolInUse(false)
, fIndexPoolInUse(false)
, fResourceHead(NULL) {
#if GR_DEBUG
//gr_run_unittests();
#endif
resetStats();
}
GrGpu::~GrGpu() {
releaseResources();
}
void GrGpu::abandonResources() {
while (NULL != fResourceHead) {
fResourceHead->abandon();
}
GrAssert(NULL == fQuadIndexBuffer || !fQuadIndexBuffer->isValid());
GrAssert(NULL == fUnitSquareVertexBuffer ||
!fUnitSquareVertexBuffer->isValid());
GrSafeSetNull(fQuadIndexBuffer);
GrSafeSetNull(fUnitSquareVertexBuffer);
delete fVertexPool;
fVertexPool = NULL;
delete fIndexPool;
fIndexPool = NULL;
}
void GrGpu::releaseResources() {
while (NULL != fResourceHead) {
fResourceHead->release();
}
GrAssert(NULL == fQuadIndexBuffer || !fQuadIndexBuffer->isValid());
GrAssert(NULL == fUnitSquareVertexBuffer ||
!fUnitSquareVertexBuffer->isValid());
GrSafeSetNull(fQuadIndexBuffer);
GrSafeSetNull(fUnitSquareVertexBuffer);
delete fVertexPool;
fVertexPool = NULL;
delete fIndexPool;
fIndexPool = NULL;
}
void GrGpu::insertResource(GrResource* resource) {
GrAssert(NULL != resource);
GrAssert(this == resource->getGpu());
GrAssert(NULL == resource->fNext);
GrAssert(NULL == resource->fPrevious);
resource->fNext = fResourceHead;
if (NULL != fResourceHead) {
GrAssert(NULL == fResourceHead->fPrevious);
fResourceHead->fPrevious = resource;
}
fResourceHead = resource;
}
void GrGpu::removeResource(GrResource* resource) {
GrAssert(NULL != resource);
GrAssert(NULL != fResourceHead);
if (fResourceHead == resource) {
GrAssert(NULL == resource->fPrevious);
fResourceHead = resource->fNext;
} else {
GrAssert(NULL != fResourceHead);
resource->fPrevious->fNext = resource->fNext;
}
if (NULL != resource->fNext) {
resource->fNext->fPrevious = resource->fPrevious;
}
resource->fNext = NULL;
resource->fPrevious = NULL;
}
void GrGpu::unimpl(const char msg[]) {
#if GR_DEBUG
GrPrintf("--- GrGpu unimplemented(\"%s\")\n", msg);
#endif
}
////////////////////////////////////////////////////////////////////////////////
GrTexture* GrGpu::createTexture(const GrTextureDesc& desc,
const void* srcData, size_t rowBytes) {
this->handleDirtyContext();
return this->onCreateTexture(desc, srcData, rowBytes);
}
GrRenderTarget* GrGpu::createRenderTargetFrom3DApiState() {
this->handleDirtyContext();
return this->onCreateRenderTargetFrom3DApiState();
}
GrResource* GrGpu::createPlatformSurface(const GrPlatformSurfaceDesc& desc) {
this->handleDirtyContext();
return this->onCreatePlatformSurface(desc);
}
GrVertexBuffer* GrGpu::createVertexBuffer(uint32_t size, bool dynamic) {
this->handleDirtyContext();
return this->onCreateVertexBuffer(size, dynamic);
}
GrIndexBuffer* GrGpu::createIndexBuffer(uint32_t size, bool dynamic) {
this->handleDirtyContext();
return this->onCreateIndexBuffer(size, dynamic);
}
void GrGpu::clear(const GrIRect* rect, GrColor color) {
this->handleDirtyContext();
this->onClear(rect, color);
}
void GrGpu::forceRenderTargetFlush() {
this->handleDirtyContext();
this->onForceRenderTargetFlush();
}
bool GrGpu::readPixels(GrRenderTarget* target,
int left, int top, int width, int height,
GrPixelConfig config, void* buffer) {
this->handleDirtyContext();
return this->onReadPixels(target, left, top, width, height, config, buffer);
}
////////////////////////////////////////////////////////////////////////////////
static const int MAX_QUADS = 1 << 12; // max possible: (1 << 14) - 1;
GR_STATIC_ASSERT(4 * MAX_QUADS <= 65535);
static inline void fill_indices(uint16_t* indices, int quadCount) {
for (int i = 0; i < quadCount; ++i) {
indices[6 * i + 0] = 4 * i + 0;
indices[6 * i + 1] = 4 * i + 1;
indices[6 * i + 2] = 4 * i + 2;
indices[6 * i + 3] = 4 * i + 0;
indices[6 * i + 4] = 4 * i + 2;
indices[6 * i + 5] = 4 * i + 3;
}
}
const GrIndexBuffer* GrGpu::getQuadIndexBuffer() const {
if (NULL == fQuadIndexBuffer) {
static const int SIZE = sizeof(uint16_t) * 6 * MAX_QUADS;
GrGpu* me = const_cast<GrGpu*>(this);
fQuadIndexBuffer = me->createIndexBuffer(SIZE, false);
if (NULL != fQuadIndexBuffer) {
uint16_t* indices = (uint16_t*)fQuadIndexBuffer->lock();
if (NULL != indices) {
fill_indices(indices, MAX_QUADS);
fQuadIndexBuffer->unlock();
} else {
indices = (uint16_t*)GrMalloc(SIZE);
fill_indices(indices, MAX_QUADS);
if (!fQuadIndexBuffer->updateData(indices, SIZE)) {
fQuadIndexBuffer->unref();
fQuadIndexBuffer = NULL;
GrCrash("Can't get indices into buffer!");
}
GrFree(indices);
}
}
}
return fQuadIndexBuffer;
}
const GrVertexBuffer* GrGpu::getUnitSquareVertexBuffer() const {
if (NULL == fUnitSquareVertexBuffer) {
static const GrPoint DATA[] = {
{ 0, 0 },
{ GR_Scalar1, 0 },
{ GR_Scalar1, GR_Scalar1 },
{ 0, GR_Scalar1 }
#if 0
GrPoint(0, 0),
GrPoint(GR_Scalar1,0),
GrPoint(GR_Scalar1,GR_Scalar1),
GrPoint(0, GR_Scalar1)
#endif
};
static const size_t SIZE = sizeof(DATA);
GrGpu* me = const_cast<GrGpu*>(this);
fUnitSquareVertexBuffer = me->createVertexBuffer(SIZE, false);
if (NULL != fUnitSquareVertexBuffer) {
if (!fUnitSquareVertexBuffer->updateData(DATA, SIZE)) {
fUnitSquareVertexBuffer->unref();
fUnitSquareVertexBuffer = NULL;
GrCrash("Can't get vertices into buffer!");
}
}
}
return fUnitSquareVertexBuffer;
}
////////////////////////////////////////////////////////////////////////////////
void GrGpu::clipWillBeSet(const GrClip& newClip) {
if (newClip != fClip) {
fClipState.fClipIsDirty = true;
}
}
////////////////////////////////////////////////////////////////////////////////
// stencil settings to use when clip is in stencil
const GrStencilSettings GrGpu::gClipStencilSettings = {
kKeep_StencilOp, kKeep_StencilOp,
kKeep_StencilOp, kKeep_StencilOp,
kAlwaysIfInClip_StencilFunc, kAlwaysIfInClip_StencilFunc,
0, 0,
0, 0,
0, 0
};
// mapping of clip-respecting stencil funcs to normal stencil funcs
// mapping depends on whether stencil-clipping is in effect.
static const GrStencilFunc gGrClipToNormalStencilFunc[2][kClipStencilFuncCount] = {
{// Stencil-Clipping is DISABLED, effectively always inside the clip
// In the Clip Funcs
kAlways_StencilFunc, // kAlwaysIfInClip_StencilFunc
kEqual_StencilFunc, // kEqualIfInClip_StencilFunc
kLess_StencilFunc, // kLessIfInClip_StencilFunc
kLEqual_StencilFunc, // kLEqualIfInClip_StencilFunc
// Special in the clip func that forces user's ref to be 0.
kNotEqual_StencilFunc, // kNonZeroIfInClip_StencilFunc
// make ref 0 and do normal nequal.
},
{// Stencil-Clipping is ENABLED
// In the Clip Funcs
kEqual_StencilFunc, // kAlwaysIfInClip_StencilFunc
// eq stencil clip bit, mask
// out user bits.
kEqual_StencilFunc, // kEqualIfInClip_StencilFunc
// add stencil bit to mask and ref
kLess_StencilFunc, // kLessIfInClip_StencilFunc
kLEqual_StencilFunc, // kLEqualIfInClip_StencilFunc
// for both of these we can add
// the clip bit to the mask and
// ref and compare as normal
// Special in the clip func that forces user's ref to be 0.
kLess_StencilFunc, // kNonZeroIfInClip_StencilFunc
// make ref have only the clip bit set
// and make comparison be less
// 10..0 < 1..user_bits..
}
};
GrStencilFunc GrGpu::ConvertStencilFunc(bool stencilInClip, GrStencilFunc func) {
GrAssert(func >= 0);
if (func >= kBasicStencilFuncCount) {
GrAssert(func < kStencilFuncCount);
func = gGrClipToNormalStencilFunc[stencilInClip ? 1 : 0][func - kBasicStencilFuncCount];
GrAssert(func >= 0 && func < kBasicStencilFuncCount);
}
return func;
}
void GrGpu::ConvertStencilFuncAndMask(GrStencilFunc func,
bool clipInStencil,
unsigned int clipBit,
unsigned int userBits,
unsigned int* ref,
unsigned int* mask) {
if (func < kBasicStencilFuncCount) {
*mask &= userBits;
*ref &= userBits;
} else {
if (clipInStencil) {
switch (func) {
case kAlwaysIfInClip_StencilFunc:
*mask = clipBit;
*ref = clipBit;
break;
case kEqualIfInClip_StencilFunc:
case kLessIfInClip_StencilFunc:
case kLEqualIfInClip_StencilFunc:
*mask = (*mask & userBits) | clipBit;
*ref = (*ref & userBits) | clipBit;
break;
case kNonZeroIfInClip_StencilFunc:
*mask = (*mask & userBits) | clipBit;
*ref = clipBit;
break;
default:
GrCrash("Unknown stencil func");
}
} else {
*mask &= userBits;
*ref &= userBits;
}
}
}
////////////////////////////////////////////////////////////////////////////////
#define VISUALIZE_COMPLEX_CLIP 0
#if VISUALIZE_COMPLEX_CLIP
#include "GrRandom.h"
GrRandom gRandom;
#define SET_RANDOM_COLOR this->setColor(0xff000000 | gRandom.nextU());
#else
#define SET_RANDOM_COLOR
#endif
bool GrGpu::setupClipAndFlushState(GrPrimitiveType type) {
const GrIRect* r = NULL;
GrIRect clipRect;
// we check this early because we need a valid
// render target to setup stencil clipping
// before even going into flushGraphicsState
if (NULL == fCurrDrawState.fRenderTarget) {
GrAssert(!"No render target bound.");
return false;
}
if (fCurrDrawState.fFlagBits & kClip_StateBit) {
GrRenderTarget& rt = *fCurrDrawState.fRenderTarget;
GrRect bounds;
GrRect rtRect;
rtRect.setLTRB(0, 0,
GrIntToScalar(rt.width()), GrIntToScalar(rt.height()));
if (fClip.hasConservativeBounds()) {
bounds = fClip.getConservativeBounds();
if (!bounds.intersect(rtRect)) {
bounds.setEmpty();
}
} else {
bounds = rtRect;
}
bounds.roundOut(&clipRect);
if (clipRect.isEmpty()) {
clipRect.setLTRB(0,0,0,0);
}
r = &clipRect;
fClipState.fClipInStencil = !fClip.isRect() &&
!fClip.isEmpty() &&
!bounds.isEmpty();
if (fClipState.fClipInStencil &&
(fClipState.fClipIsDirty ||
fClip != rt.fLastStencilClip)) {
rt.fLastStencilClip = fClip;
// we set the current clip to the bounds so that our recursive
// draws are scissored to them. We use the copy of the complex clip
// in the rt to render
const GrClip& clip = rt.fLastStencilClip;
fClip.setFromRect(bounds);
AutoStateRestore asr(this);
AutoInternalDrawGeomRestore aidgr(this);
this->setViewMatrix(GrMatrix::I());
this->clearStencilClip(clipRect);
this->flushScissor(NULL);
#if !VISUALIZE_COMPLEX_CLIP
this->enableState(kNoColorWrites_StateBit);
#else
this->disableState(kNoColorWrites_StateBit);
#endif
int count = clip.getElementCount();
int clipBit = rt.stencilBits();
clipBit = (1 << (clipBit-1));
// often we'll see the first two elements of the clip are
// the full rt size and another element intersected with it.
// We can skip the first full-size rect and save a big rect draw.
int firstElement = 0;
if (clip.getElementCount() > 1 &&
kRect_ClipType == clip.getElementType(0) &&
kIntersect_SetOp == clip.getOp(1)&&
clip.getRect(0).contains(bounds)) {
firstElement = 1;
}
// walk through each clip element and perform its set op
// with the existing clip.
for (int c = firstElement; c < count; ++c) {
GrPathFill fill;
// enabled at bottom of loop
this->disableState(kModifyStencilClip_StateBit);
bool canRenderDirectToStencil; // can the clip element be drawn
// directly to the stencil buffer
// with a non-inverted fill rule
// without extra passes to
// resolve in/out status.
GrPathRenderer* pr = NULL;
const GrPath* clipPath = NULL;
if (kRect_ClipType == clip.getElementType(c)) {
canRenderDirectToStencil = true;
fill = kEvenOdd_PathFill;
} else {
fill = clip.getPathFill(c);
clipPath = &clip.getPath(c);
pr = this->getClipPathRenderer(*clipPath, NonInvertedFill(fill));
canRenderDirectToStencil =
!pr->requiresStencilPass(this, *clipPath,
NonInvertedFill(fill));
}
GrSetOp op = firstElement == c ? kReplace_SetOp : clip.getOp(c);
int passes;
GrStencilSettings stencilSettings[GrStencilSettings::kMaxStencilClipPasses];
bool canDrawDirectToClip; // Given the renderer, the element,
// fill rule, and set operation can
// we render the element directly to
// stencil bit used for clipping.
canDrawDirectToClip =
GrStencilSettings::GetClipPasses(op,
canRenderDirectToStencil,
clipBit,
IsFillInverted(fill),
&passes, stencilSettings);
// draw the element to the client stencil bits if necessary
if (!canDrawDirectToClip) {
static const GrStencilSettings gDrawToStencil = {
kIncClamp_StencilOp, kIncClamp_StencilOp,
kIncClamp_StencilOp, kIncClamp_StencilOp,
kAlways_StencilFunc, kAlways_StencilFunc,
0xffffffff, 0xffffffff,
0x00000000, 0x00000000,
0xffffffff, 0xffffffff,
};
SET_RANDOM_COLOR
if (kRect_ClipType == clip.getElementType(c)) {
this->setStencil(gDrawToStencil);
this->drawSimpleRect(clip.getRect(c), NULL, 0);
} else {
if (canRenderDirectToStencil) {
this->setStencil(gDrawToStencil);
pr->drawPath(this, 0, *clipPath, NonInvertedFill(fill),
NULL);
} else {
pr->drawPathToStencil(this, *clipPath,
NonInvertedFill(fill),
NULL);
}
}
}
// now we modify the clip bit by rendering either the clip
// element directly or a bounding rect of the entire clip.
this->enableState(kModifyStencilClip_StateBit);
for (int p = 0; p < passes; ++p) {
this->setStencil(stencilSettings[p]);
if (canDrawDirectToClip) {
if (kRect_ClipType == clip.getElementType(c)) {
SET_RANDOM_COLOR
this->drawSimpleRect(clip.getRect(c), NULL, 0);
} else {
SET_RANDOM_COLOR
GrAssert(!IsFillInverted(fill));
pr->drawPath(this, 0, *clipPath, fill, NULL);
}
} else {
SET_RANDOM_COLOR
this->drawSimpleRect(bounds, NULL, 0);
}
}
}
fClip = clip;
// recusive draws would have disabled this.
fClipState.fClipInStencil = true;
}
fClipState.fClipIsDirty = false;
}
// Must flush the scissor after graphics state
if (!this->flushGraphicsState(type)) {
return false;
}
this->flushScissor(r);
return true;
}
GrPathRenderer* GrGpu::getClipPathRenderer(const GrPath& path,
GrPathFill fill) {
if (NULL != fClientPathRenderer &&
fClientPathRenderer->canDrawPath(this, path, fill)) {
return fClientPathRenderer;
} else {
if (NULL == fDefaultPathRenderer) {
fDefaultPathRenderer =
new GrDefaultPathRenderer(this->supportsTwoSidedStencil(),
this->supportsStencilWrapOps());
}
GrAssert(fDefaultPathRenderer->canDrawPath(this, path, fill));
return fDefaultPathRenderer;
}
}
////////////////////////////////////////////////////////////////////////////////
void GrGpu::drawIndexed(GrPrimitiveType type,
int startVertex,
int startIndex,
int vertexCount,
int indexCount) {
GrAssert(kReserved_GeometrySrcType != fGeometrySrc.fVertexSrc ||
fReservedGeometry.fLocked);
GrAssert(kReserved_GeometrySrcType != fGeometrySrc.fIndexSrc ||
fReservedGeometry.fLocked);
this->handleDirtyContext();
if (!this->setupClipAndFlushState(type)) {
return;
}
#if GR_COLLECT_STATS
fStats.fVertexCnt += vertexCount;
fStats.fIndexCnt += indexCount;
fStats.fDrawCnt += 1;
#endif
int sVertex = startVertex;
int sIndex = startIndex;
setupGeometry(&sVertex, &sIndex, vertexCount, indexCount);
this->onDrawIndexed(type, sVertex, sIndex,
vertexCount, indexCount);
}
void GrGpu::drawNonIndexed(GrPrimitiveType type,
int startVertex,
int vertexCount) {
GrAssert(kReserved_GeometrySrcType != fGeometrySrc.fVertexSrc ||
fReservedGeometry.fLocked);
this->handleDirtyContext();
if (!this->setupClipAndFlushState(type)) {
return;
}
#if GR_COLLECT_STATS
fStats.fVertexCnt += vertexCount;
fStats.fDrawCnt += 1;
#endif
int sVertex = startVertex;
setupGeometry(&sVertex, NULL, vertexCount, 0);
this->onDrawNonIndexed(type, sVertex, vertexCount);
}
void GrGpu::finalizeReservedVertices() {
GrAssert(NULL != fVertexPool);
fVertexPool->unlock();
}
void GrGpu::finalizeReservedIndices() {
GrAssert(NULL != fIndexPool);
fIndexPool->unlock();
}
void GrGpu::prepareVertexPool() {
if (NULL == fVertexPool) {
fVertexPool = new GrVertexBufferAllocPool(this, true,
VERTEX_POOL_VB_SIZE,
VERTEX_POOL_VB_COUNT);
fVertexPool->releaseGpuRef();
} else if (!fVertexPoolInUse) {
// the client doesn't have valid data in the pool
fVertexPool->reset();
}
}
void GrGpu::prepareIndexPool() {
if (NULL == fIndexPool) {
fIndexPool = new GrIndexBufferAllocPool(this, true, 0, 1);
fIndexPool->releaseGpuRef();
} else if (!fIndexPoolInUse) {
// the client doesn't have valid data in the pool
fIndexPool->reset();
}
}
bool GrGpu::onAcquireGeometry(GrVertexLayout vertexLayout,
void** vertices,
void** indices) {
GrAssert(!fReservedGeometry.fLocked);
size_t reservedVertexSpace = 0;
if (fReservedGeometry.fVertexCount) {
GrAssert(NULL != vertices);
this->prepareVertexPool();
*vertices = fVertexPool->makeSpace(vertexLayout,
fReservedGeometry.fVertexCount,
&fCurrPoolVertexBuffer,
&fCurrPoolStartVertex);
if (NULL == *vertices) {
return false;
}
reservedVertexSpace = VertexSize(vertexLayout) *
fReservedGeometry.fVertexCount;
}
if (fReservedGeometry.fIndexCount) {
GrAssert(NULL != indices);
this->prepareIndexPool();
*indices = fIndexPool->makeSpace(fReservedGeometry.fIndexCount,
&fCurrPoolIndexBuffer,
&fCurrPoolStartIndex);
if (NULL == *indices) {
fVertexPool->putBack(reservedVertexSpace);
fCurrPoolVertexBuffer = NULL;
return false;
}
}
return true;
}
void GrGpu::onReleaseGeometry() {}
void GrGpu::onSetVertexSourceToArray(const void* vertexArray, int vertexCount) {
GrAssert(!fReservedGeometry.fLocked || !fReservedGeometry.fVertexCount);
this->prepareVertexPool();
#if GR_DEBUG
bool success =
#endif
fVertexPool->appendVertices(fGeometrySrc.fVertexLayout,
vertexCount,
vertexArray,
&fCurrPoolVertexBuffer,
&fCurrPoolStartVertex);
GR_DEBUGASSERT(success);
}
void GrGpu::onSetIndexSourceToArray(const void* indexArray, int indexCount) {
GrAssert(!fReservedGeometry.fLocked || !fReservedGeometry.fIndexCount);
this->prepareIndexPool();
#if GR_DEBUG
bool success =
#endif
fIndexPool->appendIndices(indexCount,
indexArray,
&fCurrPoolIndexBuffer,
&fCurrPoolStartIndex);
GR_DEBUGASSERT(success);
}
////////////////////////////////////////////////////////////////////////////////
const GrGpuStats& GrGpu::getStats() const {
return fStats;
}
void GrGpu::resetStats() {
memset(&fStats, 0, sizeof(fStats));
}
void GrGpu::printStats() const {
if (GR_COLLECT_STATS) {
GrPrintf(
"-v-------------------------GPU STATS----------------------------v-\n"
"Stats collection is: %s\n"
"Draws: %04d, Verts: %04d, Indices: %04d\n"
"ProgChanges: %04d, TexChanges: %04d, RTChanges: %04d\n"
"TexCreates: %04d, RTCreates:%04d\n"
"-^--------------------------------------------------------------^-\n",
(GR_COLLECT_STATS ? "ON" : "OFF"),
fStats.fDrawCnt, fStats.fVertexCnt, fStats.fIndexCnt,
fStats.fProgChngCnt, fStats.fTextureChngCnt, fStats.fRenderTargetChngCnt,
fStats.fTextureCreateCnt, fStats.fRenderTargetCreateCnt);
}
}
////////////////////////////////////////////////////////////////////////////////
const GrSamplerState GrSamplerState::gClampNoFilter(
GrSamplerState::kClamp_WrapMode,
GrSamplerState::kClamp_WrapMode,
GrSamplerState::kNormal_SampleMode,
GrMatrix::I(),
GrSamplerState::kNearest_Filter);