blob: c6cc68af8ea9986a8aa00ce31bf824238b2524cb [file] [log] [blame]
// Copyright 2016 The SwiftShader Authors. All Rights Reserved.
//
// 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 "VertexProcessor.hpp"
#include "Pipeline/VertexProgram.hpp"
#include "Pipeline/VertexShader.hpp"
#include "Pipeline/PixelShader.hpp"
#include "Pipeline/Constants.hpp"
#include "System/Math.hpp"
#include "System/Debug.hpp"
#include <string.h>
namespace sw
{
bool precacheVertex = false;
void VertexCache::clear()
{
for(int i = 0; i < 16; i++)
{
tag[i] = 0x80000000;
}
}
unsigned int VertexProcessor::States::computeHash()
{
unsigned int *state = (unsigned int*)this;
unsigned int hash = 0;
for(unsigned int i = 0; i < sizeof(States) / 4; i++)
{
hash ^= state[i];
}
return hash;
}
VertexProcessor::State::State()
{
memset(this, 0, sizeof(State));
}
bool VertexProcessor::State::operator==(const State &state) const
{
if(hash != state.hash)
{
return false;
}
return memcmp(static_cast<const States*>(this), static_cast<const States*>(&state), sizeof(States)) == 0;
}
VertexProcessor::TransformFeedbackInfo::TransformFeedbackInfo()
{
buffer = nullptr;
offset = 0;
reg = 0;
row = 0;
col = 0;
stride = 0;
}
VertexProcessor::UniformBufferInfo::UniformBufferInfo()
{
buffer = nullptr;
offset = 0;
}
VertexProcessor::VertexProcessor(Context *context) : context(context)
{
routineCache = nullptr;
setRoutineCacheSize(1024);
}
VertexProcessor::~VertexProcessor()
{
delete routineCache;
routineCache = nullptr;
}
void VertexProcessor::setInputStream(int index, const Stream &stream)
{
context->input[index] = stream;
}
void VertexProcessor::resetInputStreams()
{
for(int i = 0; i < MAX_VERTEX_INPUTS; i++)
{
context->input[i].defaults();
}
}
void VertexProcessor::setFloatConstant(unsigned int index, const float value[4])
{
if(index < VERTEX_UNIFORM_VECTORS)
{
c[index][0] = value[0];
c[index][1] = value[1];
c[index][2] = value[2];
c[index][3] = value[3];
}
else ASSERT(false);
}
void VertexProcessor::setIntegerConstant(unsigned int index, const int integer[4])
{
if(index < 16)
{
i[index][0] = integer[0];
i[index][1] = integer[1];
i[index][2] = integer[2];
i[index][3] = integer[3];
}
else ASSERT(false);
}
void VertexProcessor::setBooleanConstant(unsigned int index, int boolean)
{
if(index < 16)
{
b[index] = boolean != 0;
}
else ASSERT(false);
}
void VertexProcessor::setUniformBuffer(int index, sw::Resource* buffer, int offset)
{
uniformBufferInfo[index].buffer = buffer;
uniformBufferInfo[index].offset = offset;
}
void VertexProcessor::lockUniformBuffers(byte** u, sw::Resource* uniformBuffers[])
{
for(int i = 0; i < MAX_UNIFORM_BUFFER_BINDINGS; ++i)
{
u[i] = uniformBufferInfo[i].buffer ? static_cast<byte*>(uniformBufferInfo[i].buffer->lock(PUBLIC, PRIVATE)) + uniformBufferInfo[i].offset : nullptr;
uniformBuffers[i] = uniformBufferInfo[i].buffer;
}
}
void VertexProcessor::setTransformFeedbackBuffer(int index, sw::Resource* buffer, int offset, unsigned int reg, unsigned int row, unsigned int col, unsigned int stride)
{
transformFeedbackInfo[index].buffer = buffer;
transformFeedbackInfo[index].offset = offset;
transformFeedbackInfo[index].reg = reg;
transformFeedbackInfo[index].row = row;
transformFeedbackInfo[index].col = col;
transformFeedbackInfo[index].stride = stride;
}
void VertexProcessor::lockTransformFeedbackBuffers(byte** t, unsigned int* v, unsigned int* r, unsigned int* c, unsigned int* s, sw::Resource* transformFeedbackBuffers[])
{
for(int i = 0; i < MAX_TRANSFORM_FEEDBACK_INTERLEAVED_COMPONENTS; ++i)
{
t[i] = transformFeedbackInfo[i].buffer ? static_cast<byte*>(transformFeedbackInfo[i].buffer->lock(PUBLIC, PRIVATE)) + transformFeedbackInfo[i].offset : nullptr;
transformFeedbackBuffers[i] = transformFeedbackInfo[i].buffer;
v[i] = transformFeedbackInfo[i].reg;
r[i] = transformFeedbackInfo[i].row;
c[i] = transformFeedbackInfo[i].col;
s[i] = transformFeedbackInfo[i].stride;
}
}
void VertexProcessor::setInstanceID(int instanceID)
{
context->instanceID = instanceID;
}
void VertexProcessor::setTextureFilter(unsigned int sampler, FilterType textureFilter)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setTextureFilter(textureFilter);
}
else ASSERT(false);
}
void VertexProcessor::setMipmapFilter(unsigned int sampler, MipmapType mipmapFilter)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setMipmapFilter(mipmapFilter);
}
else ASSERT(false);
}
void VertexProcessor::setGatherEnable(unsigned int sampler, bool enable)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setGatherEnable(enable);
}
else ASSERT(false);
}
void VertexProcessor::setAddressingModeU(unsigned int sampler, AddressingMode addressMode)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setAddressingModeU(addressMode);
}
else ASSERT(false);
}
void VertexProcessor::setAddressingModeV(unsigned int sampler, AddressingMode addressMode)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setAddressingModeV(addressMode);
}
else ASSERT(false);
}
void VertexProcessor::setAddressingModeW(unsigned int sampler, AddressingMode addressMode)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setAddressingModeW(addressMode);
}
else ASSERT(false);
}
void VertexProcessor::setReadSRGB(unsigned int sampler, bool sRGB)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setReadSRGB(sRGB);
}
else ASSERT(false);
}
void VertexProcessor::setMipmapLOD(unsigned int sampler, float bias)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setMipmapLOD(bias);
}
else ASSERT(false);
}
void VertexProcessor::setBorderColor(unsigned int sampler, const Color<float> &borderColor)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setBorderColor(borderColor);
}
else ASSERT(false);
}
void VertexProcessor::setMaxAnisotropy(unsigned int sampler, float maxAnisotropy)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setMaxAnisotropy(maxAnisotropy);
}
else ASSERT(false);
}
void VertexProcessor::setHighPrecisionFiltering(unsigned int sampler, bool highPrecisionFiltering)
{
if(sampler < TEXTURE_IMAGE_UNITS)
{
context->sampler[sampler].setHighPrecisionFiltering(highPrecisionFiltering);
}
else ASSERT(false);
}
void VertexProcessor::setSwizzleR(unsigned int sampler, SwizzleType swizzleR)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setSwizzleR(swizzleR);
}
else ASSERT(false);
}
void VertexProcessor::setSwizzleG(unsigned int sampler, SwizzleType swizzleG)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setSwizzleG(swizzleG);
}
else ASSERT(false);
}
void VertexProcessor::setSwizzleB(unsigned int sampler, SwizzleType swizzleB)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setSwizzleB(swizzleB);
}
else ASSERT(false);
}
void VertexProcessor::setSwizzleA(unsigned int sampler, SwizzleType swizzleA)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setSwizzleA(swizzleA);
}
else ASSERT(false);
}
void VertexProcessor::setCompareFunc(unsigned int sampler, CompareFunc compFunc)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setCompareFunc(compFunc);
}
else ASSERT(false);
}
void VertexProcessor::setBaseLevel(unsigned int sampler, int baseLevel)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setBaseLevel(baseLevel);
}
else ASSERT(false);
}
void VertexProcessor::setMaxLevel(unsigned int sampler, int maxLevel)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setMaxLevel(maxLevel);
}
else ASSERT(false);
}
void VertexProcessor::setMinLod(unsigned int sampler, float minLod)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setMinLod(minLod);
}
else ASSERT(false);
}
void VertexProcessor::setMaxLod(unsigned int sampler, float maxLod)
{
if(sampler < VERTEX_TEXTURE_IMAGE_UNITS)
{
context->sampler[TEXTURE_IMAGE_UNITS + sampler].setMaxLod(maxLod);
}
else ASSERT(false);
}
void VertexProcessor::setPointSizeMin(float pointSizeMin)
{
this->pointSizeMin = pointSizeMin;
}
void VertexProcessor::setPointSizeMax(float pointSizeMax)
{
this->pointSizeMax = pointSizeMax;
}
void VertexProcessor::setTransformFeedbackQueryEnabled(bool enable)
{
context->transformFeedbackQueryEnabled = enable;
}
void VertexProcessor::enableTransformFeedback(uint64_t enable)
{
context->transformFeedbackEnabled = enable;
}
void VertexProcessor::setRoutineCacheSize(int cacheSize)
{
delete routineCache;
routineCache = new RoutineCache<State>(clamp(cacheSize, 1, 65536), precacheVertex ? "sw-vertex" : 0);
}
const VertexProcessor::State VertexProcessor::update(DrawType drawType)
{
State state;
state.shaderID = context->vertexShader->getSerialID();
state.fixedFunction = !context->vertexShader && context->pixelShaderModel() < 0x0300;
state.textureSampling = context->vertexShader ? context->vertexShader->containsTextureSampling() : false;
state.positionRegister = context->vertexShader ? context->vertexShader->getPositionRegister() : Pos;
state.pointSizeRegister = context->vertexShader ? context->vertexShader->getPointSizeRegister() : Pts;
state.multiSampling = context->getMultiSampleCount() > 1;
state.transformFeedbackQueryEnabled = context->transformFeedbackQueryEnabled;
state.transformFeedbackEnabled = context->transformFeedbackEnabled;
// Note: Quads aren't handled for verticesPerPrimitive, but verticesPerPrimitive is used for transform feedback,
// which is an OpenGL ES 3.0 feature, and OpenGL ES 3.0 doesn't support quads as a primitive type.
DrawType type = static_cast<DrawType>(static_cast<unsigned int>(drawType) & 0xF);
state.verticesPerPrimitive = 1 + (type >= DRAW_LINELIST) + (type >= DRAW_TRIANGLELIST);
for(int i = 0; i < MAX_VERTEX_INPUTS; i++)
{
state.input[i].type = context->input[i].type;
state.input[i].count = context->input[i].count;
state.input[i].normalized = context->input[i].normalized;
state.input[i].attribType = context->vertexShader ? context->vertexShader->getAttribType(i) : SpirvShader::ATTRIBTYPE_FLOAT;
}
for(unsigned int i = 0; i < VERTEX_TEXTURE_IMAGE_UNITS; i++)
{
if(context->vertexShader->usesSampler(i))
{
state.sampler[i] = context->sampler[TEXTURE_IMAGE_UNITS + i].samplerState();
}
}
if(context->vertexShader) // FIXME: Also when pre-transformed?
{
for(int i = 0; i < MAX_VERTEX_OUTPUTS; i++)
{
state.output[i].xWrite = context->vertexShader->getOutput(i, 0).active();
state.output[i].yWrite = context->vertexShader->getOutput(i, 1).active();
state.output[i].zWrite = context->vertexShader->getOutput(i, 2).active();
state.output[i].wWrite = context->vertexShader->getOutput(i, 3).active();
}
}
state.hash = state.computeHash();
return state;
}
Routine *VertexProcessor::routine(const State &state)
{
Routine *routine = routineCache->query(state);
if(!routine) // Create one
{
VertexRoutine *generator = new VertexProgram(state, context->vertexShader);
generator->generate();
routine = (*generator)("VertexRoutine_%0.8X", state.shaderID);
delete generator;
routineCache->add(state, routine);
}
return routine;
}
}