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/*
* Copyright 2010 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "GrBufferAllocPool.h"
#include "GrTypes.h"
#include "GrVertexBuffer.h"
#include "GrIndexBuffer.h"
#include "GrGpu.h"
#if GR_DEBUG
#define VALIDATE validate
#else
static void VALIDATE(bool x = false) {}
#endif
// page size
#define GrBufferAllocPool_MIN_BLOCK_SIZE ((size_t)1 << 12)
GrBufferAllocPool::GrBufferAllocPool(GrGpu* gpu,
BufferType bufferType,
bool frequentResetHint,
size_t blockSize,
int preallocBufferCnt) :
fBlocks(GrMax(8, 2*preallocBufferCnt)) {
GrAssert(NULL != gpu);
fGpu = gpu;
fGpu->ref();
fGpuIsReffed = true;
fBufferType = bufferType;
fFrequentResetHint = frequentResetHint;
fBufferPtr = NULL;
fMinBlockSize = GrMax(GrBufferAllocPool_MIN_BLOCK_SIZE, blockSize);
fBytesInUse = 0;
fPreallocBuffersInUse = 0;
fPreallocBufferStartIdx = 0;
for (int i = 0; i < preallocBufferCnt; ++i) {
GrGeometryBuffer* buffer = this->createBuffer(fMinBlockSize);
if (NULL != buffer) {
*fPreallocBuffers.append() = buffer;
}
}
}
GrBufferAllocPool::~GrBufferAllocPool() {
VALIDATE();
if (fBlocks.count()) {
GrGeometryBuffer* buffer = fBlocks.back().fBuffer;
if (buffer->isLocked()) {
buffer->unlock();
}
}
while (!fBlocks.empty()) {
destroyBlock();
}
fPreallocBuffers.unrefAll();
releaseGpuRef();
}
void GrBufferAllocPool::releaseGpuRef() {
if (fGpuIsReffed) {
fGpu->unref();
fGpuIsReffed = false;
}
}
void GrBufferAllocPool::reset() {
VALIDATE();
fBytesInUse = 0;
if (fBlocks.count()) {
GrGeometryBuffer* buffer = fBlocks.back().fBuffer;
if (buffer->isLocked()) {
buffer->unlock();
}
}
// fPreallocBuffersInUse will be decremented down to zero in the while loop
int preallocBuffersInUse = fPreallocBuffersInUse;
while (!fBlocks.empty()) {
this->destroyBlock();
}
if (fPreallocBuffers.count()) {
// must set this after above loop.
fPreallocBufferStartIdx = (fPreallocBufferStartIdx +
preallocBuffersInUse) %
fPreallocBuffers.count();
}
// we may have created a large cpu mirror of a large VB. Reset the size
// to match our pre-allocated VBs.
fCpuData.reset(fMinBlockSize);
GrAssert(0 == fPreallocBuffersInUse);
VALIDATE();
}
void GrBufferAllocPool::unlock() {
VALIDATE();
if (NULL != fBufferPtr) {
BufferBlock& block = fBlocks.back();
if (block.fBuffer->isLocked()) {
block.fBuffer->unlock();
} else {
size_t flushSize = block.fBuffer->sizeInBytes() - block.fBytesFree;
flushCpuData(fBlocks.back().fBuffer, flushSize);
}
fBufferPtr = NULL;
}
VALIDATE();
}
#if GR_DEBUG
void GrBufferAllocPool::validate(bool unusedBlockAllowed) const {
if (NULL != fBufferPtr) {
GrAssert(!fBlocks.empty());
if (fBlocks.back().fBuffer->isLocked()) {
GrGeometryBuffer* buf = fBlocks.back().fBuffer;
GrAssert(buf->lockPtr() == fBufferPtr);
} else {
GrAssert(fCpuData.get() == fBufferPtr);
}
} else {
GrAssert(fBlocks.empty() || !fBlocks.back().fBuffer->isLocked());
}
size_t bytesInUse = 0;
for (int i = 0; i < fBlocks.count() - 1; ++i) {
GrAssert(!fBlocks[i].fBuffer->isLocked());
}
for (int i = 0; i < fBlocks.count(); ++i) {
size_t bytes = fBlocks[i].fBuffer->sizeInBytes() - fBlocks[i].fBytesFree;
bytesInUse += bytes;
GrAssert(bytes || unusedBlockAllowed);
}
GrAssert(bytesInUse == fBytesInUse);
if (unusedBlockAllowed) {
GrAssert((fBytesInUse && !fBlocks.empty()) ||
(!fBytesInUse && (fBlocks.count() < 2)));
} else {
GrAssert((0 == fBytesInUse) == fBlocks.empty());
}
}
#endif
void* GrBufferAllocPool::makeSpace(size_t size,
size_t alignment,
const GrGeometryBuffer** buffer,
size_t* offset) {
VALIDATE();
GrAssert(NULL != buffer);
GrAssert(NULL != offset);
if (NULL != fBufferPtr) {
BufferBlock& back = fBlocks.back();
size_t usedBytes = back.fBuffer->sizeInBytes() - back.fBytesFree;
size_t pad = GrSizeAlignUpPad(usedBytes,
alignment);
if ((size + pad) <= back.fBytesFree) {
usedBytes += pad;
*offset = usedBytes;
*buffer = back.fBuffer;
back.fBytesFree -= size + pad;
fBytesInUse += size + pad;
VALIDATE();
return (void*)(reinterpret_cast<intptr_t>(fBufferPtr) + usedBytes);
}
}
// We could honor the space request using by a partial update of the current
// VB (if there is room). But we don't currently use draw calls to GL that
// allow the driver to know that previously issued draws won't read from
// the part of the buffer we update. Also, the GL buffer implementation
// may be cheating on the actual buffer size by shrinking the buffer on
// updateData() if the amount of data passed is less than the full buffer
// size.
if (!createBlock(size)) {
return NULL;
}
GrAssert(NULL != fBufferPtr);
*offset = 0;
BufferBlock& back = fBlocks.back();
*buffer = back.fBuffer;
back.fBytesFree -= size;
fBytesInUse += size;
VALIDATE();
return fBufferPtr;
}
int GrBufferAllocPool::currentBufferItems(size_t itemSize) const {
VALIDATE();
if (NULL != fBufferPtr) {
const BufferBlock& back = fBlocks.back();
size_t usedBytes = back.fBuffer->sizeInBytes() - back.fBytesFree;
size_t pad = GrSizeAlignUpPad(usedBytes, itemSize);
return (back.fBytesFree - pad) / itemSize;
} else if (fPreallocBuffersInUse < fPreallocBuffers.count()) {
return fMinBlockSize / itemSize;
}
return 0;
}
int GrBufferAllocPool::preallocatedBuffersRemaining() const {
return fPreallocBuffers.count() - fPreallocBuffersInUse;
}
int GrBufferAllocPool::preallocatedBufferCount() const {
return fPreallocBuffers.count();
}
void GrBufferAllocPool::putBack(size_t bytes) {
VALIDATE();
// if the putBack unwinds all the preallocated buffers then we will
// advance the starting index. As blocks are destroyed fPreallocBuffersInUse
// will be decremented. I will reach zero if all blocks using preallocated
// buffers are released.
int preallocBuffersInUse = fPreallocBuffersInUse;
while (bytes) {
// caller shouldnt try to put back more than they've taken
GrAssert(!fBlocks.empty());
BufferBlock& block = fBlocks.back();
size_t bytesUsed = block.fBuffer->sizeInBytes() - block.fBytesFree;
if (bytes >= bytesUsed) {
bytes -= bytesUsed;
fBytesInUse -= bytesUsed;
// if we locked a vb to satisfy the make space and we're releasing
// beyond it, then unlock it.
if (block.fBuffer->isLocked()) {
block.fBuffer->unlock();
}
this->destroyBlock();
} else {
block.fBytesFree += bytes;
fBytesInUse -= bytes;
bytes = 0;
break;
}
}
if (!fPreallocBuffersInUse && fPreallocBuffers.count()) {
fPreallocBufferStartIdx = (fPreallocBufferStartIdx +
preallocBuffersInUse) %
fPreallocBuffers.count();
}
VALIDATE();
}
bool GrBufferAllocPool::createBlock(size_t requestSize) {
size_t size = GrMax(requestSize, fMinBlockSize);
GrAssert(size >= GrBufferAllocPool_MIN_BLOCK_SIZE);
VALIDATE();
BufferBlock& block = fBlocks.push_back();
if (size == fMinBlockSize &&
fPreallocBuffersInUse < fPreallocBuffers.count()) {
uint32_t nextBuffer = (fPreallocBuffersInUse +
fPreallocBufferStartIdx) %
fPreallocBuffers.count();
block.fBuffer = fPreallocBuffers[nextBuffer];
block.fBuffer->ref();
++fPreallocBuffersInUse;
} else {
block.fBuffer = this->createBuffer(size);
if (NULL == block.fBuffer) {
fBlocks.pop_back();
return false;
}
}
block.fBytesFree = size;
if (NULL != fBufferPtr) {
GrAssert(fBlocks.count() > 1);
BufferBlock& prev = fBlocks.fromBack(1);
if (prev.fBuffer->isLocked()) {
prev.fBuffer->unlock();
} else {
flushCpuData(prev.fBuffer,
prev.fBuffer->sizeInBytes() - prev.fBytesFree);
}
fBufferPtr = NULL;
}
GrAssert(NULL == fBufferPtr);
if (fGpu->getCaps().fBufferLockSupport &&
size > GR_GEOM_BUFFER_LOCK_THRESHOLD &&
(!fFrequentResetHint || requestSize > GR_GEOM_BUFFER_LOCK_THRESHOLD)) {
fBufferPtr = block.fBuffer->lock();
}
if (NULL == fBufferPtr) {
fBufferPtr = fCpuData.reset(size);
}
VALIDATE(true);
return true;
}
void GrBufferAllocPool::destroyBlock() {
GrAssert(!fBlocks.empty());
BufferBlock& block = fBlocks.back();
if (fPreallocBuffersInUse > 0) {
uint32_t prevPreallocBuffer = (fPreallocBuffersInUse +
fPreallocBufferStartIdx +
(fPreallocBuffers.count() - 1)) %
fPreallocBuffers.count();
if (block.fBuffer == fPreallocBuffers[prevPreallocBuffer]) {
--fPreallocBuffersInUse;
}
}
GrAssert(!block.fBuffer->isLocked());
block.fBuffer->unref();
fBlocks.pop_back();
fBufferPtr = NULL;
}
void GrBufferAllocPool::flushCpuData(GrGeometryBuffer* buffer,
size_t flushSize) {
GrAssert(NULL != buffer);
GrAssert(!buffer->isLocked());
GrAssert(fCpuData.get() == fBufferPtr);
GrAssert(flushSize <= buffer->sizeInBytes());
VALIDATE(true);
if (fGpu->getCaps().fBufferLockSupport &&
flushSize > GR_GEOM_BUFFER_LOCK_THRESHOLD) {
void* data = buffer->lock();
if (NULL != data) {
memcpy(data, fBufferPtr, flushSize);
buffer->unlock();
return;
}
}
buffer->updateData(fBufferPtr, flushSize);
VALIDATE(true);
}
GrGeometryBuffer* GrBufferAllocPool::createBuffer(size_t size) {
if (kIndex_BufferType == fBufferType) {
return fGpu->createIndexBuffer(size, true);
} else {
GrAssert(kVertex_BufferType == fBufferType);
return fGpu->createVertexBuffer(size, true);
}
}
////////////////////////////////////////////////////////////////////////////////
GrVertexBufferAllocPool::GrVertexBufferAllocPool(GrGpu* gpu,
bool frequentResetHint,
size_t bufferSize,
int preallocBufferCnt)
: GrBufferAllocPool(gpu,
kVertex_BufferType,
frequentResetHint,
bufferSize,
preallocBufferCnt) {
}
void* GrVertexBufferAllocPool::makeSpace(GrVertexLayout layout,
int vertexCount,
const GrVertexBuffer** buffer,
int* startVertex) {
GrAssert(vertexCount >= 0);
GrAssert(NULL != buffer);
GrAssert(NULL != startVertex);
size_t vSize = GrDrawTarget::VertexSize(layout);
size_t offset = 0; // assign to suppress warning
const GrGeometryBuffer* geomBuffer = NULL; // assign to suppress warning
void* ptr = INHERITED::makeSpace(vSize * vertexCount,
vSize,
&geomBuffer,
&offset);
*buffer = (const GrVertexBuffer*) geomBuffer;
GrAssert(0 == offset % vSize);
*startVertex = offset / vSize;
return ptr;
}
bool GrVertexBufferAllocPool::appendVertices(GrVertexLayout layout,
int vertexCount,
const void* vertices,
const GrVertexBuffer** buffer,
int* startVertex) {
void* space = makeSpace(layout, vertexCount, buffer, startVertex);
if (NULL != space) {
memcpy(space,
vertices,
GrDrawTarget::VertexSize(layout) * vertexCount);
return true;
} else {
return false;
}
}
int GrVertexBufferAllocPool::preallocatedBufferVertices(GrVertexLayout layout) const {
return INHERITED::preallocatedBufferSize() /
GrDrawTarget::VertexSize(layout);
}
int GrVertexBufferAllocPool::currentBufferVertices(GrVertexLayout layout) const {
return currentBufferItems(GrDrawTarget::VertexSize(layout));
}
////////////////////////////////////////////////////////////////////////////////
GrIndexBufferAllocPool::GrIndexBufferAllocPool(GrGpu* gpu,
bool frequentResetHint,
size_t bufferSize,
int preallocBufferCnt)
: GrBufferAllocPool(gpu,
kIndex_BufferType,
frequentResetHint,
bufferSize,
preallocBufferCnt) {
}
void* GrIndexBufferAllocPool::makeSpace(int indexCount,
const GrIndexBuffer** buffer,
int* startIndex) {
GrAssert(indexCount >= 0);
GrAssert(NULL != buffer);
GrAssert(NULL != startIndex);
size_t offset = 0; // assign to suppress warning
const GrGeometryBuffer* geomBuffer = NULL; // assign to suppress warning
void* ptr = INHERITED::makeSpace(indexCount * sizeof(uint16_t),
sizeof(uint16_t),
&geomBuffer,
&offset);
*buffer = (const GrIndexBuffer*) geomBuffer;
GrAssert(0 == offset % sizeof(uint16_t));
*startIndex = offset / sizeof(uint16_t);
return ptr;
}
bool GrIndexBufferAllocPool::appendIndices(int indexCount,
const void* indices,
const GrIndexBuffer** buffer,
int* startIndex) {
void* space = makeSpace(indexCount, buffer, startIndex);
if (NULL != space) {
memcpy(space, indices, sizeof(uint16_t) * indexCount);
return true;
} else {
return false;
}
}
int GrIndexBufferAllocPool::preallocatedBufferIndices() const {
return INHERITED::preallocatedBufferSize() / sizeof(uint16_t);
}
int GrIndexBufferAllocPool::currentBufferIndices() const {
return currentBufferItems(sizeof(uint16_t));
}