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kc3-lang/angle/src/libGLESv2/ProgramBinary.cpp
Nicolas Capens
- src/libGLESv2/ProgramBinary.cpp
-
#include "precompiled.h" // // Copyright (c) 2002-2013 The ANGLE Project Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // // Program.cpp: Implements the gl::Program class. Implements GL program objects // and related functionality. [OpenGL ES 2.0.24] section 2.10.3 page 28. #include "libGLESv2/BinaryStream.h" #include "libGLESv2/ProgramBinary.h" #include "libGLESv2/renderer/ShaderExecutable.h" #include "common/debug.h" #include "common/version.h" #include "common/utilities.h" #include "libGLESv2/main.h" #include "libGLESv2/Shader.h" #include "libGLESv2/Program.h" #include "libGLESv2/renderer/Renderer.h" #include "libGLESv2/renderer/VertexDataManager.h" #include "libGLESv2/Context.h" #include "libGLESv2/Buffer.h" #undef near #undef far namespace gl { std::string str(int i) { char buffer[20]; snprintf(buffer, sizeof(buffer), "%d", i); return buffer; } std::string arrayString(int i) { return "[" + str(i) + "]"; } std::string arrayString(unsigned int i) { return (i == GL_INVALID_INDEX ? "" : "[" + str(i) + "]"); } namespace gl_d3d { std::string TypeString(GLenum type) { switch (type) { case GL_FLOAT: return "float"; case GL_FLOAT_VEC2: return "float2"; case GL_FLOAT_VEC3: return "float3"; case GL_FLOAT_VEC4: return "float4"; case GL_INT: return "int"; case GL_INT_VEC2: return "int2"; case GL_INT_VEC3: return "int3"; case GL_INT_VEC4: return "int4"; case GL_UNSIGNED_INT: return "uint"; case GL_UNSIGNED_INT_VEC2: return "uint2"; case GL_UNSIGNED_INT_VEC3: return "uint3"; case GL_UNSIGNED_INT_VEC4: return "uint4"; case GL_FLOAT_MAT2: return "float2x2"; case GL_FLOAT_MAT3: return "float3x3"; case GL_FLOAT_MAT4: return "float4x4"; case GL_FLOAT_MAT2x3: return "float2x3"; case GL_FLOAT_MAT3x2: return "float3x2"; case GL_FLOAT_MAT2x4: return "float2x4"; case GL_FLOAT_MAT4x2: return "float4x2"; case GL_FLOAT_MAT3x4: return "float3x4"; case GL_FLOAT_MAT4x3: return "float4x3"; default: UNREACHABLE(); return "invalid-gl-type"; } } } namespace { unsigned int parseAndStripArrayIndex(std::string* name) { unsigned int subscript = GL_INVALID_INDEX; // Strip any trailing array operator and retrieve the subscript size_t open = name->find_last_of('['); size_t close = name->find_last_of(']'); if (open != std::string::npos && close == name->length() - 1) { subscript = atoi(name->substr(open + 1).c_str()); name->erase(open); } return subscript; } } VariableLocation::VariableLocation(const std::string &name, unsigned int element, unsigned int index) : name(name), element(element), index(index) { } unsigned int ProgramBinary::mCurrentSerial = 1; ProgramBinary::ProgramBinary(rx::Renderer *renderer) : mRenderer(renderer), RefCountObject(0), mSerial(issueSerial()) { mPixelExecutable = NULL; mVertexExecutable = NULL; mGeometryExecutable = NULL; mValidated = false; for (int index = 0; index < MAX_VERTEX_ATTRIBS; index++) { mSemanticIndex[index] = -1; } for (int index = 0; index < MAX_TEXTURE_IMAGE_UNITS; index++) { mSamplersPS[index].active = false; } for (int index = 0; index < IMPLEMENTATION_MAX_VERTEX_TEXTURE_IMAGE_UNITS; index++) { mSamplersVS[index].active = false; } mUsedVertexSamplerRange = 0; mUsedPixelSamplerRange = 0; mUsesPointSize = false; mShaderVersion = 100; } ProgramBinary::~ProgramBinary() { delete mPixelExecutable; mPixelExecutable = NULL; delete mVertexExecutable; mVertexExecutable = NULL; delete mGeometryExecutable; mGeometryExecutable = NULL; while (!mUniforms.empty()) { delete mUniforms.back(); mUniforms.pop_back(); } while (!mUniformBlocks.empty()) { delete mUniformBlocks.back(); mUniformBlocks.pop_back(); } } unsigned int ProgramBinary::getSerial() const { return mSerial; } int ProgramBinary::getShaderVersion() const { return mShaderVersion; } unsigned int ProgramBinary::issueSerial() { return mCurrentSerial++; } rx::ShaderExecutable *ProgramBinary::getPixelExecutable() { return mPixelExecutable; } rx::ShaderExecutable *ProgramBinary::getVertexExecutable() { return mVertexExecutable; } rx::ShaderExecutable *ProgramBinary::getGeometryExecutable() { return mGeometryExecutable; } GLuint ProgramBinary::getAttributeLocation(const char *name) { if (name) { for (int index = 0; index < MAX_VERTEX_ATTRIBS; index++) { if (mLinkedAttribute[index].name == std::string(name)) { return index; } } } return -1; } int ProgramBinary::getSemanticIndex(int attributeIndex) { ASSERT(attributeIndex >= 0 && attributeIndex < MAX_VERTEX_ATTRIBS); return mSemanticIndex[attributeIndex]; } // Returns one more than the highest sampler index used. GLint ProgramBinary::getUsedSamplerRange(SamplerType type) { switch (type) { case SAMPLER_PIXEL: return mUsedPixelSamplerRange; case SAMPLER_VERTEX: return mUsedVertexSamplerRange; default: UNREACHABLE(); return 0; } } bool ProgramBinary::usesPointSize() const { return mUsesPointSize; } bool ProgramBinary::usesPointSpriteEmulation() const { return mUsesPointSize && mRenderer->getMajorShaderModel() >= 4; } bool ProgramBinary::usesGeometryShader() const { return usesPointSpriteEmulation(); } // Returns the index of the texture image unit (0-19) corresponding to a Direct3D 9 sampler // index (0-15 for the pixel shader and 0-3 for the vertex shader). GLint ProgramBinary::getSamplerMapping(SamplerType type, unsigned int samplerIndex) { GLint logicalTextureUnit = -1; switch (type) { case SAMPLER_PIXEL: ASSERT(samplerIndex < sizeof(mSamplersPS)/sizeof(mSamplersPS[0])); if (mSamplersPS[samplerIndex].active) { logicalTextureUnit = mSamplersPS[samplerIndex].logicalTextureUnit; } break; case SAMPLER_VERTEX: ASSERT(samplerIndex < sizeof(mSamplersVS)/sizeof(mSamplersVS[0])); if (mSamplersVS[samplerIndex].active) { logicalTextureUnit = mSamplersVS[samplerIndex].logicalTextureUnit; } break; default: UNREACHABLE(); } if (logicalTextureUnit >= 0 && logicalTextureUnit < (GLint)mRenderer->getMaxCombinedTextureImageUnits()) { return logicalTextureUnit; } return -1; } // Returns the texture type for a given Direct3D 9 sampler type and // index (0-15 for the pixel shader and 0-3 for the vertex shader). TextureType ProgramBinary::getSamplerTextureType(SamplerType type, unsigned int samplerIndex) { switch (type) { case SAMPLER_PIXEL: ASSERT(samplerIndex < sizeof(mSamplersPS)/sizeof(mSamplersPS[0])); ASSERT(mSamplersPS[samplerIndex].active); return mSamplersPS[samplerIndex].textureType; case SAMPLER_VERTEX: ASSERT(samplerIndex < sizeof(mSamplersVS)/sizeof(mSamplersVS[0])); ASSERT(mSamplersVS[samplerIndex].active); return mSamplersVS[samplerIndex].textureType; default: UNREACHABLE(); } return TEXTURE_2D; } GLint ProgramBinary::getUniformLocation(std::string name) { unsigned int subscript = parseAndStripArrayIndex(&name); unsigned int numUniforms = mUniformIndex.size(); for (unsigned int location = 0; location < numUniforms; location++) { if (mUniformIndex[location].name == name) { const int index = mUniformIndex[location].index; const bool isArray = mUniforms[index]->isArray(); if ((isArray && mUniformIndex[location].element == subscript) || (subscript == GL_INVALID_INDEX)) { return location; } } } return -1; } GLuint ProgramBinary::getUniformIndex(std::string name) { unsigned int subscript = parseAndStripArrayIndex(&name); // The app is not allowed to specify array indices other than 0 for arrays of basic types if (subscript != 0 && subscript != GL_INVALID_INDEX) { return GL_INVALID_INDEX; } unsigned int numUniforms = mUniforms.size(); for (unsigned int index = 0; index < numUniforms; index++) { if (mUniforms[index]->name == name) { if (mUniforms[index]->isArray() || subscript == GL_INVALID_INDEX) { return index; } } } return GL_INVALID_INDEX; } GLuint ProgramBinary::getUniformBlockIndex(std::string name) { unsigned int subscript = parseAndStripArrayIndex(&name); unsigned int numUniformBlocks = mUniformBlocks.size(); for (unsigned int blockIndex = 0; blockIndex < numUniformBlocks; blockIndex++) { const UniformBlock &uniformBlock = *mUniformBlocks[blockIndex]; if (uniformBlock.name == name) { const bool arrayElementZero = (subscript == GL_INVALID_INDEX && uniformBlock.elementIndex == 0); if (subscript == uniformBlock.elementIndex || arrayElementZero) { return blockIndex; } } } return GL_INVALID_INDEX; } UniformBlock *ProgramBinary::getUniformBlockByIndex(GLuint blockIndex) { ASSERT(blockIndex < mUniformBlocks.size()); return mUniformBlocks[blockIndex]; } GLint ProgramBinary::getFragDataLocation(const char *name) const { std::string baseName(name); unsigned int arrayIndex; arrayIndex = parseAndStripArrayIndex(&baseName); for (auto locationIt = mOutputVariables.begin(); locationIt != mOutputVariables.end(); locationIt++) { const VariableLocation &outputVariable = locationIt->second; if (outputVariable.name == baseName && (arrayIndex == GL_INVALID_INDEX || arrayIndex == outputVariable.element)) { return static_cast<GLint>(locationIt->first); } } return -1; } template <typename T> bool ProgramBinary::setUniform(GLint location, GLsizei count, const T* v, GLenum targetUniformType) { if (location < 0 || location >= (int)mUniformIndex.size()) { return false; } const int components = UniformComponentCount(targetUniformType); const GLenum targetBoolType = UniformBoolVectorType(targetUniformType); Uniform *targetUniform = mUniforms[mUniformIndex[location].index]; targetUniform->dirty = true; int elementCount = targetUniform->elementCount(); if (elementCount == 1 && count > 1) return false; // attempting to write an array to a non-array uniform is an INVALID_OPERATION count = std::min(elementCount - (int)mUniformIndex[location].element, count); if (targetUniform->type == targetUniformType) { T *target = (T*)targetUniform->data + mUniformIndex[location].element * 4; for (int i = 0; i < count; i++) { for (int c = 0; c < components; c++) { target[c] = v[c]; } for (int c = components; c < 4; c++) { target[c] = 0; } target += 4; v += components; } } else if (targetUniform->type == targetBoolType) { GLint *boolParams = (GLint*)targetUniform->data + mUniformIndex[location].element * 4; for (int i = 0; i < count; i++) { for (int c = 0; c < components; c++) { boolParams[c] = (v[c] == static_cast<T>(0)) ? GL_FALSE : GL_TRUE; } for (int c = components; c < 4; c++) { boolParams[c] = GL_FALSE; } boolParams += 4; v += components; } } else { return false; } return true; } bool ProgramBinary::setUniform1fv(GLint location, GLsizei count, const GLfloat* v) { return setUniform(location, count, v, GL_FLOAT); } bool ProgramBinary::setUniform2fv(GLint location, GLsizei count, const GLfloat *v) { return setUniform(location, count, v, GL_FLOAT_VEC2); } bool ProgramBinary::setUniform3fv(GLint location, GLsizei count, const GLfloat *v) { return setUniform(location, count, v, GL_FLOAT_VEC3); } bool ProgramBinary::setUniform4fv(GLint location, GLsizei count, const GLfloat *v) { return setUniform(location, count, v, GL_FLOAT_VEC4); } template<typename T> void transposeMatrix(T *target, const GLfloat *value, int targetWidth, int targetHeight, int srcWidth, int srcHeight) { int copyWidth = std::min(targetHeight, srcWidth); int copyHeight = std::min(targetWidth, srcHeight); for (int x = 0; x < copyWidth; x++) { for (int y = 0; y < copyHeight; y++) { target[x * targetWidth + y] = static_cast<T>(value[y * srcWidth + x]); } } // clear unfilled right side for (int y = 0; y < copyWidth; y++) { for (int x = copyHeight; x < targetWidth; x++) { target[y * targetWidth + x] = static_cast<T>(0); } } // clear unfilled bottom. for (int y = copyWidth; y < targetHeight; y++) { for (int x = 0; x < targetWidth; x++) { target[y * targetWidth + x] = static_cast<T>(0); } } } template<typename T> void expandMatrix(T *target, const GLfloat *value, int targetWidth, int targetHeight, int srcWidth, int srcHeight) { int copyWidth = std::min(targetWidth, srcWidth); int copyHeight = std::min(targetHeight, srcHeight); for (int y = 0; y < copyHeight; y++) { for (int x = 0; x < copyWidth; x++) { target[y * targetWidth + x] = static_cast<T>(value[y * srcWidth + x]); } } // clear unfilled right side for (int y = 0; y < copyHeight; y++) { for (int x = copyWidth; x < targetWidth; x++) { target[y * targetWidth + x] = static_cast<T>(0); } } // clear unfilled bottom. for (int y = copyHeight; y < targetHeight; y++) { for (int x = 0; x < targetWidth; x++) { target[y * targetWidth + x] = static_cast<T>(0); } } } template <int cols, int rows> bool ProgramBinary::setUniformMatrixfv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value, GLenum targetUniformType) { if (location < 0 || location >= (int)mUniformIndex.size()) { return false; } Uniform *targetUniform = mUniforms[mUniformIndex[location].index]; targetUniform->dirty = true; if (targetUniform->type != targetUniformType) { return false; } int elementCount = targetUniform->elementCount(); if (elementCount == 1 && count > 1) return false; // attempting to write an array to a non-array uniform is an INVALID_OPERATION count = std::min(elementCount - (int)mUniformIndex[location].element, count); const unsigned int targetMatrixStride = (4 * rows); GLfloat *target = (GLfloat*)(targetUniform->data + mUniformIndex[location].element * sizeof(GLfloat) * targetMatrixStride); for (int i = 0; i < count; i++) { // Internally store matrices as transposed versions to accomodate HLSL matrix indexing if (transpose == GL_FALSE) { transposeMatrix<GLfloat>(target, value, 4, rows, rows, cols); } else { expandMatrix<GLfloat>(target, value, 4, rows, cols, rows); } target += targetMatrixStride; value += cols * rows; } return true; } bool ProgramBinary::setUniformMatrix2fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<2, 2>(location, count, transpose, value, GL_FLOAT_MAT2); } bool ProgramBinary::setUniformMatrix3fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<3, 3>(location, count, transpose, value, GL_FLOAT_MAT3); } bool ProgramBinary::setUniformMatrix4fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<4, 4>(location, count, transpose, value, GL_FLOAT_MAT4); } bool ProgramBinary::setUniformMatrix2x3fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<2, 3>(location, count, transpose, value, GL_FLOAT_MAT2x3); } bool ProgramBinary::setUniformMatrix3x2fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<3, 2>(location, count, transpose, value, GL_FLOAT_MAT3x2); } bool ProgramBinary::setUniformMatrix2x4fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<2, 4>(location, count, transpose, value, GL_FLOAT_MAT2x4); } bool ProgramBinary::setUniformMatrix4x2fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<4, 2>(location, count, transpose, value, GL_FLOAT_MAT4x2); } bool ProgramBinary::setUniformMatrix3x4fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<3, 4>(location, count, transpose, value, GL_FLOAT_MAT3x4); } bool ProgramBinary::setUniformMatrix4x3fv(GLint location, GLsizei count, GLboolean transpose, const GLfloat *value) { return setUniformMatrixfv<4, 3>(location, count, transpose, value, GL_FLOAT_MAT4x3); } bool ProgramBinary::setUniform1iv(GLint location, GLsizei count, const GLint *v) { if (location < 0 || location >= (int)mUniformIndex.size()) { return false; } Uniform *targetUniform = mUniforms[mUniformIndex[location].index]; targetUniform->dirty = true; int elementCount = targetUniform->elementCount(); if (elementCount == 1 && count > 1) return false; // attempting to write an array to a non-array uniform is an INVALID_OPERATION count = std::min(elementCount - (int)mUniformIndex[location].element, count); if (targetUniform->type == GL_INT || IsSampler(targetUniform->type)) { GLint *target = (GLint*)targetUniform->data + mUniformIndex[location].element * 4; for (int i = 0; i < count; i++) { target[0] = v[0]; target[1] = 0; target[2] = 0; target[3] = 0; target += 4; v += 1; } } else if (targetUniform->type == GL_BOOL) { GLint *boolParams = (GLint*)targetUniform->data + mUniformIndex[location].element * 4; for (int i = 0; i < count; i++) { boolParams[0] = (v[0] == 0) ? GL_FALSE : GL_TRUE; boolParams[1] = GL_FALSE; boolParams[2] = GL_FALSE; boolParams[3] = GL_FALSE; boolParams += 4; v += 1; } } else { return false; } return true; } bool ProgramBinary::setUniform2iv(GLint location, GLsizei count, const GLint *v) { return setUniform(location, count, v, GL_INT_VEC2); } bool ProgramBinary::setUniform3iv(GLint location, GLsizei count, const GLint *v) { return setUniform(location, count, v, GL_INT_VEC3); } bool ProgramBinary::setUniform4iv(GLint location, GLsizei count, const GLint *v) { return setUniform(location, count, v, GL_INT_VEC4); } bool ProgramBinary::setUniform1uiv(GLint location, GLsizei count, const GLuint *v) { return setUniform(location, count, v, GL_UNSIGNED_INT); } bool ProgramBinary::setUniform2uiv(GLint location, GLsizei count, const GLuint *v) { return setUniform(location, count, v, GL_UNSIGNED_INT_VEC2); } bool ProgramBinary::setUniform3uiv(GLint location, GLsizei count, const GLuint *v) { return setUniform(location, count, v, GL_UNSIGNED_INT_VEC3); } bool ProgramBinary::setUniform4uiv(GLint location, GLsizei count, const GLuint *v) { return setUniform(location, count, v, GL_UNSIGNED_INT_VEC4); } template <typename T> bool ProgramBinary::getUniformv(GLint location, GLsizei *bufSize, T *params, GLenum uniformType) { if (location < 0 || location >= (int)mUniformIndex.size()) { return false; } Uniform *targetUniform = mUniforms[mUniformIndex[location].index]; // sized queries -- ensure the provided buffer is large enough if (bufSize) { int requiredBytes = UniformExternalSize(targetUniform->type); if (*bufSize < requiredBytes) { return false; } } if (IsMatrixType(targetUniform->type)) { const int rows = VariableRowCount(targetUniform->type); const int cols = VariableColumnCount(targetUniform->type); transposeMatrix(params, (GLfloat*)targetUniform->data + mUniformIndex[location].element * 4 * rows, cols, rows, 4, rows); } else if (uniformType == UniformComponentType(targetUniform->type)) { unsigned int size = UniformComponentCount(targetUniform->type); memcpy(params, targetUniform->data + mUniformIndex[location].element * 4 * sizeof(T), size * sizeof(T)); } else { unsigned int size = UniformComponentCount(targetUniform->type); switch (UniformComponentType(targetUniform->type)) { case GL_BOOL: { GLint *boolParams = (GLint*)targetUniform->data + mUniformIndex[location].element * 4; for (unsigned int i = 0; i < size; i++) { params[i] = (boolParams[i] == GL_FALSE) ? static_cast<T>(0) : static_cast<T>(1); } } break; case GL_FLOAT: { GLfloat *floatParams = (GLfloat*)targetUniform->data + mUniformIndex[location].element * 4; for (unsigned int i = 0; i < size; i++) { params[i] = static_cast<T>(floatParams[i]); } } break; case GL_INT: { GLint *intParams = (GLint*)targetUniform->data + mUniformIndex[location].element * 4; for (unsigned int i = 0; i < size; i++) { params[i] = static_cast<T>(intParams[i]); } } break; case GL_UNSIGNED_INT: { GLuint *uintParams = (GLuint*)targetUniform->data + mUniformIndex[location].element * 4; for (unsigned int i = 0; i < size; i++) { params[i] = static_cast<T>(uintParams[i]); } } break; default: UNREACHABLE(); } } return true; } bool ProgramBinary::getUniformfv(GLint location, GLsizei *bufSize, GLfloat *params) { return getUniformv(location, bufSize, params, GL_FLOAT); } bool ProgramBinary::getUniformiv(GLint location, GLsizei *bufSize, GLint *params) { return getUniformv(location, bufSize, params, GL_INT); } bool ProgramBinary::getUniformuiv(GLint location, GLsizei *bufSize, GLuint *params) { return getUniformv(location, bufSize, params, GL_UNSIGNED_INT); } void ProgramBinary::dirtyAllUniforms() { unsigned int numUniforms = mUniforms.size(); for (unsigned int index = 0; index < numUniforms; index++) { mUniforms[index]->dirty = true; } } // Applies all the uniforms set for this program object to the renderer void ProgramBinary::applyUniforms() { // Retrieve sampler uniform values for (std::vector<Uniform*>::iterator ub = mUniforms.begin(), ue = mUniforms.end(); ub != ue; ++ub) { Uniform *targetUniform = *ub; if (targetUniform->dirty) { if (IsSampler(targetUniform->type)) { int count = targetUniform->elementCount(); GLint (*v)[4] = (GLint(*)[4])targetUniform->data; if (targetUniform->isReferencedByFragmentShader()) { unsigned int firstIndex = targetUniform->psRegisterIndex; for (int i = 0; i < count; i++) { unsigned int samplerIndex = firstIndex + i; if (samplerIndex < MAX_TEXTURE_IMAGE_UNITS) { ASSERT(mSamplersPS[samplerIndex].active); mSamplersPS[samplerIndex].logicalTextureUnit = v[i][0]; } } } if (targetUniform->isReferencedByVertexShader()) { unsigned int firstIndex = targetUniform->vsRegisterIndex; for (int i = 0; i < count; i++) { unsigned int samplerIndex = firstIndex + i; if (samplerIndex < IMPLEMENTATION_MAX_VERTEX_TEXTURE_IMAGE_UNITS) { ASSERT(mSamplersVS[samplerIndex].active); mSamplersVS[samplerIndex].logicalTextureUnit = v[i][0]; } } } } } } mRenderer->applyUniforms(this, &mUniforms); } bool ProgramBinary::applyUniformBuffers(const std::vector<gl::Buffer*> boundBuffers) { const gl::Buffer *vertexUniformBuffers[gl::IMPLEMENTATION_MAX_VERTEX_SHADER_UNIFORM_BUFFERS] = {NULL}; const gl::Buffer *fragmentUniformBuffers[gl::IMPLEMENTATION_MAX_FRAGMENT_SHADER_UNIFORM_BUFFERS] = {NULL}; const unsigned int reservedBuffersInVS = mRenderer->getReservedVertexUniformBuffers(); const unsigned int reservedBuffersInFS = mRenderer->getReservedFragmentUniformBuffers(); ASSERT(boundBuffers.size() == mUniformBlocks.size()); for (unsigned int uniformBlockIndex = 0; uniformBlockIndex < mUniformBlocks.size(); uniformBlockIndex++) { gl::UniformBlock *uniformBlock = getUniformBlockByIndex(uniformBlockIndex); gl::Buffer *uniformBuffer = boundBuffers[uniformBlockIndex]; ASSERT(uniformBlock && uniformBuffer); if (uniformBuffer->size() < uniformBlock->dataSize) { // undefined behaviour return false; } ASSERT(uniformBlock->isReferencedByVertexShader() || uniformBlock->isReferencedByFragmentShader()); if (uniformBlock->isReferencedByVertexShader()) { unsigned int registerIndex = uniformBlock->vsRegisterIndex - reservedBuffersInVS; ASSERT(vertexUniformBuffers[registerIndex] == NULL); ASSERT(registerIndex < mRenderer->getMaxVertexShaderUniformBuffers()); vertexUniformBuffers[registerIndex] = uniformBuffer; } if (uniformBlock->isReferencedByFragmentShader()) { unsigned int registerIndex = uniformBlock->psRegisterIndex - reservedBuffersInFS; ASSERT(fragmentUniformBuffers[registerIndex] == NULL); ASSERT(registerIndex < mRenderer->getMaxFragmentShaderUniformBuffers()); fragmentUniformBuffers[registerIndex] = uniformBuffer; } } return mRenderer->setUniformBuffers(vertexUniformBuffers, fragmentUniformBuffers); } // Packs varyings into generic varying registers, using the algorithm from [OpenGL ES Shading Language 1.00 rev. 17] appendix A section 7 page 111 // Returns the number of used varying registers, or -1 if unsuccesful int ProgramBinary::packVaryings(InfoLog &infoLog, const Varying *packing[][4], FragmentShader *fragmentShader) { const int maxVaryingVectors = mRenderer->getMaxVaryingVectors(); fragmentShader->resetVaryingsRegisterAssignment(); for (VaryingList::iterator varying = fragmentShader->mVaryings.begin(); varying != fragmentShader->mVaryings.end(); varying++) { GLenum transposedType = TransposeMatrixType(varying->type); int n = VariableRowCount(transposedType) * varying->size; int m = VariableColumnCount(transposedType); bool success = false; if (m == 2 || m == 3 || m == 4) { for (int r = 0; r <= maxVaryingVectors - n && !success; r++) { bool available = true; for (int y = 0; y < n && available; y++) { for (int x = 0; x < m && available; x++) { if (packing[r + y][x]) { available = false; } } } if (available) { varying->reg = r; varying->col = 0; for (int y = 0; y < n; y++) { for (int x = 0; x < m; x++) { packing[r + y][x] = &*varying; } } success = true; } } if (!success && m == 2) { for (int r = maxVaryingVectors - n; r >= 0 && !success; r--) { bool available = true; for (int y = 0; y < n && available; y++) { for (int x = 2; x < 4 && available; x++) { if (packing[r + y][x]) { available = false; } } } if (available) { varying->reg = r; varying->col = 2; for (int y = 0; y < n; y++) { for (int x = 2; x < 4; x++) { packing[r + y][x] = &*varying; } } success = true; } } } } else if (m == 1) { int space[4] = {0}; for (int y = 0; y < maxVaryingVectors; y++) { for (int x = 0; x < 4; x++) { space[x] += packing[y][x] ? 0 : 1; } } int column = 0; for (int x = 0; x < 4; x++) { if (space[x] >= n && space[x] < space[column]) { column = x; } } if (space[column] >= n) { for (int r = 0; r < maxVaryingVectors; r++) { if (!packing[r][column]) { varying->reg = r; for (int y = r; y < r + n; y++) { packing[y][column] = &*varying; } break; } } varying->col = column; success = true; } } else UNREACHABLE(); if (!success) { infoLog.append("Could not pack varying %s", varying->name.c_str()); return -1; } } // Return the number of used registers int registers = 0; for (int r = 0; r < maxVaryingVectors; r++) { if (packing[r][0] || packing[r][1] || packing[r][2] || packing[r][3]) { registers++; } } return registers; } void ProgramBinary::defineOutputVariables(FragmentShader *fragmentShader) { const sh::ActiveShaderVariables &outputVars = fragmentShader->getOutputVariables(); for (unsigned int outputVariableIndex = 0; outputVariableIndex < outputVars.size(); outputVariableIndex++) { const sh::ShaderVariable &outputVariable = outputVars[outputVariableIndex]; const int baseLocation = outputVariable.location == -1 ? 0 : outputVariable.location; if (outputVariable.arraySize > 0) { for (unsigned int elementIndex = 0; elementIndex < outputVariable.arraySize; elementIndex++) { const int location = baseLocation + elementIndex; ASSERT(mOutputVariables.count(location) == 0); mOutputVariables[location] = VariableLocation(outputVariable.name, elementIndex, outputVariableIndex); } } else { ASSERT(mOutputVariables.count(baseLocation) == 0); mOutputVariables[baseLocation] = VariableLocation(outputVariable.name, GL_INVALID_INDEX, outputVariableIndex); } } } bool ProgramBinary::linkVaryings(InfoLog &infoLog, int registers, const Varying *packing[][4], std::string& pixelHLSL, std::string& vertexHLSL, FragmentShader *fragmentShader, VertexShader *vertexShader) { if (pixelHLSL.empty() || vertexHLSL.empty()) { return false; } bool usesMRT = fragmentShader->mUsesMultipleRenderTargets; bool usesFragColor = fragmentShader->mUsesFragColor; bool usesFragData = fragmentShader->mUsesFragData; if (usesFragColor && usesFragData) { infoLog.append("Cannot use both gl_FragColor and gl_FragData in the same fragment shader."); return false; } // Write the HLSL input/output declarations const int shaderModel = mRenderer->getMajorShaderModel(); const int maxVaryingVectors = mRenderer->getMaxVaryingVectors(); const int registersNeeded = registers + (fragmentShader->mUsesFragCoord ? 1 : 0) + (fragmentShader->mUsesPointCoord ? 1 : 0); // Two cases when writing to gl_FragColor and using ESSL 1.0: // - with a 3.0 context, the output color is copied to channel 0 // - with a 2.0 context, the output color is broadcast to all channels const bool broadcast = (fragmentShader->mUsesFragColor && mRenderer->getCurrentClientVersion() < 3); const unsigned int numRenderTargets = (broadcast || usesMRT ? mRenderer->getMaxRenderTargets() : 1); if (registersNeeded > maxVaryingVectors) { infoLog.append("No varying registers left to support gl_FragCoord/gl_PointCoord"); return false; } vertexShader->resetVaryingsRegisterAssignment(); for (VaryingList::iterator input = fragmentShader->mVaryings.begin(); input != fragmentShader->mVaryings.end(); input++) { bool matched = false; for (VaryingList::iterator output = vertexShader->mVaryings.begin(); output != vertexShader->mVaryings.end(); output++) { if (output->name == input->name) { if (output->type != input->type || output->size != input->size || output->interpolation != input->interpolation) { infoLog.append("Type of vertex varying %s does not match that of the fragment varying", output->name.c_str()); return false; } output->reg = input->reg; output->col = input->col; matched = true; break; } } if (!matched) { infoLog.append("Fragment varying %s does not match any vertex varying", input->name.c_str()); return false; } } mUsesPointSize = vertexShader->mUsesPointSize; std::string varyingSemantic = (mUsesPointSize && shaderModel == 3) ? "COLOR" : "TEXCOORD"; std::string targetSemantic = (shaderModel >= 4) ? "SV_Target" : "COLOR"; std::string positionSemantic = (shaderModel >= 4) ? "SV_Position" : "POSITION"; std::string depthSemantic = (shaderModel >= 4) ? "SV_Depth" : "DEPTH"; std::string varyingHLSL = generateVaryingHLSL(fragmentShader, varyingSemantic); // special varyings that use reserved registers int reservedRegisterIndex = registers; std::string fragCoordSemantic; std::string pointCoordSemantic; if (fragmentShader->mUsesFragCoord) { fragCoordSemantic = varyingSemantic + str(reservedRegisterIndex++); } if (fragmentShader->mUsesPointCoord) { // Shader model 3 uses a special TEXCOORD semantic for point sprite texcoords. // In DX11 we compute this in the GS. if (shaderModel == 3) { pointCoordSemantic = "TEXCOORD0"; } else if (shaderModel >= 4) { pointCoordSemantic = varyingSemantic + str(reservedRegisterIndex++); } } vertexHLSL += "struct VS_INPUT\n" "{\n"; int semanticIndex = 0; const sh::ActiveShaderVariables &activeAttributes = vertexShader->mActiveAttributes; for (unsigned int attributeIndex = 0; attributeIndex < activeAttributes.size(); attributeIndex++) { const sh::ShaderVariable &attribute = activeAttributes[attributeIndex]; vertexHLSL += " " + gl_d3d::TypeString(TransposeMatrixType(attribute.type)) + " "; vertexHLSL += decorateAttribute(attribute.name) + " : TEXCOORD" + str(semanticIndex) + ";\n"; semanticIndex += AttributeRegisterCount(attribute.type); } vertexHLSL += "};\n" "\n" "struct VS_OUTPUT\n" "{\n"; if (shaderModel < 4) { vertexHLSL += " float4 gl_Position : " + positionSemantic + ";\n"; } vertexHLSL += varyingHLSL; if (fragmentShader->mUsesFragCoord) { vertexHLSL += " float4 gl_FragCoord : " + fragCoordSemantic + ";\n"; } if (vertexShader->mUsesPointSize && shaderModel >= 3) { vertexHLSL += " float gl_PointSize : PSIZE;\n"; } if (shaderModel >= 4) { vertexHLSL += " float4 gl_Position : " + positionSemantic + ";\n"; } vertexHLSL += "};\n" "\n" "VS_OUTPUT main(VS_INPUT input)\n" "{\n"; for (unsigned int attributeIndex = 0; attributeIndex < activeAttributes.size(); attributeIndex++) { const sh::ShaderVariable &attribute = activeAttributes[attributeIndex]; vertexHLSL += " " + decorateAttribute(attribute.name) + " = "; if (IsMatrixType(attribute.type)) // Matrix { vertexHLSL += "transpose"; } vertexHLSL += "(input." + decorateAttribute(attribute.name) + ");\n"; } if (shaderModel >= 4) { vertexHLSL += "\n" " gl_main();\n" "\n" " VS_OUTPUT output;\n" " output.gl_Position.x = gl_Position.x;\n" " output.gl_Position.y = -gl_Position.y;\n" " output.gl_Position.z = (gl_Position.z + gl_Position.w) * 0.5;\n" " output.gl_Position.w = gl_Position.w;\n"; } else { vertexHLSL += "\n" " gl_main();\n" "\n" " VS_OUTPUT output;\n" " output.gl_Position.x = gl_Position.x * dx_ViewAdjust.z + dx_ViewAdjust.x * gl_Position.w;\n" " output.gl_Position.y = -(gl_Position.y * dx_ViewAdjust.w + dx_ViewAdjust.y * gl_Position.w);\n" " output.gl_Position.z = (gl_Position.z + gl_Position.w) * 0.5;\n" " output.gl_Position.w = gl_Position.w;\n"; } if (vertexShader->mUsesPointSize && shaderModel >= 3) { vertexHLSL += " output.gl_PointSize = gl_PointSize;\n"; } if (fragmentShader->mUsesFragCoord) { vertexHLSL += " output.gl_FragCoord = gl_Position;\n"; } for (VaryingList::iterator varying = vertexShader->mVaryings.begin(); varying != vertexShader->mVaryings.end(); varying++) { if (varying->reg >= 0) { for (int i = 0; i < varying->size; i++) { int rows = VariableRowCount(TransposeMatrixType(varying->type)); for (int j = 0; j < rows; j++) { int r = varying->reg + i * rows + j; vertexHLSL += " output.v" + str(r); bool sharedRegister = false; // Register used by multiple varyings for (int x = 0; x < 4; x++) { if (packing[r][x] && packing[r][x] != packing[r][0]) { sharedRegister = true; break; } } if(sharedRegister) { vertexHLSL += "."; for (int x = 0; x < 4; x++) { if (packing[r][x] == &*varying) { switch(x) { case 0: vertexHLSL += "x"; break; case 1: vertexHLSL += "y"; break; case 2: vertexHLSL += "z"; break; case 3: vertexHLSL += "w"; break; } } } } vertexHLSL += " = " + varying->name; if (varying->array) { vertexHLSL += arrayString(i); } if (rows > 1) { vertexHLSL += arrayString(j); } vertexHLSL += ";\n"; } } } } vertexHLSL += "\n" " return output;\n" "}\n"; pixelHLSL += "struct PS_INPUT\n" "{\n"; pixelHLSL += varyingHLSL; if (fragmentShader->mUsesFragCoord) { pixelHLSL += " float4 gl_FragCoord : " + fragCoordSemantic + ";\n"; } if (fragmentShader->mUsesPointCoord && shaderModel >= 3) { pixelHLSL += " float2 gl_PointCoord : " + pointCoordSemantic + ";\n"; } // Must consume the PSIZE element if the geometry shader is not active // We won't know if we use a GS until we draw if (vertexShader->mUsesPointSize && shaderModel >= 4) { pixelHLSL += " float gl_PointSize : PSIZE;\n"; } if (fragmentShader->mUsesFragCoord) { if (shaderModel >= 4) { pixelHLSL += " float4 dx_VPos : SV_Position;\n"; } else if (shaderModel >= 3) { pixelHLSL += " float2 dx_VPos : VPOS;\n"; } } pixelHLSL += "};\n" "\n" "struct PS_OUTPUT\n" "{\n"; if (mShaderVersion < 300) { for (unsigned int renderTargetIndex = 0; renderTargetIndex < numRenderTargets; renderTargetIndex++) { pixelHLSL += " float4 gl_Color" + str(renderTargetIndex) + " : " + targetSemantic + str(renderTargetIndex) + ";\n"; } if (fragmentShader->mUsesFragDepth) { pixelHLSL += " float gl_Depth : " + depthSemantic + ";\n"; } } else { defineOutputVariables(fragmentShader); const sh::ActiveShaderVariables &outputVars = fragmentShader->getOutputVariables(); for (auto locationIt = mOutputVariables.begin(); locationIt != mOutputVariables.end(); locationIt++) { const VariableLocation &outputLocation = locationIt->second; const sh::ShaderVariable &outputVariable = outputVars[outputLocation.index]; const std::string &elementString = (outputLocation.element == GL_INVALID_INDEX ? "" : str(outputLocation.element)); pixelHLSL += " " + gl_d3d::TypeString(outputVariable.type) + " out_" + outputLocation.name + elementString + " : " + targetSemantic + str(locationIt->first) + ";\n"; } } pixelHLSL += "};\n" "\n"; if (fragmentShader->mUsesFrontFacing) { if (shaderModel >= 4) { pixelHLSL += "PS_OUTPUT main(PS_INPUT input, bool isFrontFace : SV_IsFrontFace)\n" "{\n"; } else { pixelHLSL += "PS_OUTPUT main(PS_INPUT input, float vFace : VFACE)\n" "{\n"; } } else { pixelHLSL += "PS_OUTPUT main(PS_INPUT input)\n" "{\n"; } if (fragmentShader->mUsesFragCoord) { pixelHLSL += " float rhw = 1.0 / input.gl_FragCoord.w;\n"; if (shaderModel >= 4) { pixelHLSL += " gl_FragCoord.x = input.dx_VPos.x;\n" " gl_FragCoord.y = input.dx_VPos.y;\n"; } else if (shaderModel >= 3) { pixelHLSL += " gl_FragCoord.x = input.dx_VPos.x + 0.5;\n" " gl_FragCoord.y = input.dx_VPos.y + 0.5;\n"; } else { // dx_ViewCoords contains the viewport width/2, height/2, center.x and center.y. See Renderer::setViewport() pixelHLSL += " gl_FragCoord.x = (input.gl_FragCoord.x * rhw) * dx_ViewCoords.x + dx_ViewCoords.z;\n" " gl_FragCoord.y = (input.gl_FragCoord.y * rhw) * dx_ViewCoords.y + dx_ViewCoords.w;\n"; } pixelHLSL += " gl_FragCoord.z = (input.gl_FragCoord.z * rhw) * dx_DepthFront.x + dx_DepthFront.y;\n" " gl_FragCoord.w = rhw;\n"; } if (fragmentShader->mUsesPointCoord && shaderModel >= 3) { pixelHLSL += " gl_PointCoord.x = input.gl_PointCoord.x;\n"; pixelHLSL += " gl_PointCoord.y = 1.0 - input.gl_PointCoord.y;\n"; } if (fragmentShader->mUsesFrontFacing) { if (shaderModel <= 3) { pixelHLSL += " gl_FrontFacing = (vFace * dx_DepthFront.z >= 0.0);\n"; } else { pixelHLSL += " gl_FrontFacing = isFrontFace;\n"; } } for (VaryingList::iterator varying = fragmentShader->mVaryings.begin(); varying != fragmentShader->mVaryings.end(); varying++) { if (varying->reg >= 0) { for (int i = 0; i < varying->size; i++) { GLenum transposedType = TransposeMatrixType(varying->type); int rows = VariableRowCount(transposedType); for (int j = 0; j < rows; j++) { std::string n = str(varying->reg + i * rows + j); pixelHLSL += " " + varying->name; if (varying->array) { pixelHLSL += arrayString(i); } if (rows > 1) { pixelHLSL += arrayString(j); } switch (VariableColumnCount(transposedType)) { case 1: pixelHLSL += " = input.v" + n + ".x;\n"; break; case 2: pixelHLSL += " = input.v" + n + ".xy;\n"; break; case 3: pixelHLSL += " = input.v" + n + ".xyz;\n"; break; case 4: pixelHLSL += " = input.v" + n + ";\n"; break; default: UNREACHABLE(); } } } } else UNREACHABLE(); } pixelHLSL += "\n" " gl_main();\n" "\n" " PS_OUTPUT output;\n"; if (mShaderVersion < 300) { for (unsigned int renderTargetIndex = 0; renderTargetIndex < numRenderTargets; renderTargetIndex++) { unsigned int sourceColorIndex = broadcast ? 0 : renderTargetIndex; pixelHLSL += " output.gl_Color" + str(renderTargetIndex) + " = gl_Color[" + str(sourceColorIndex) + "];\n"; } if (fragmentShader->mUsesFragDepth) { pixelHLSL += " output.gl_Depth = gl_Depth;\n"; } } else { for (auto locationIt = mOutputVariables.begin(); locationIt != mOutputVariables.end(); locationIt++) { const VariableLocation &outputLocation = locationIt->second; const std::string &variableName = "out_" + outputLocation.name; const std::string &outVariableName = variableName + (outputLocation.element == GL_INVALID_INDEX ? "" : str(outputLocation.element)); const std::string &staticVariableName = variableName + arrayString(outputLocation.element); pixelHLSL += " output." + outVariableName + " = " + staticVariableName + ";\n"; } } pixelHLSL += "\n" " return output;\n" "}\n"; return true; } std::string ProgramBinary::generateVaryingHLSL(FragmentShader *fragmentShader, const std::string &varyingSemantic) const { std::string varyingHLSL; for (VaryingList::iterator varying = fragmentShader->mVaryings.begin(); varying != fragmentShader->mVaryings.end(); varying++) { if (varying->reg >= 0) { for (int i = 0; i < varying->size; i++) { GLenum transposedType = TransposeMatrixType(varying->type); int rows = VariableRowCount(transposedType); for (int j = 0; j < rows; j++) { switch (varying->interpolation) { case Smooth: varyingHLSL += " "; break; case Flat: varyingHLSL += " nointerpolation "; break; case Centroid: varyingHLSL += " centroid "; break; default: UNREACHABLE(); } std::string n = str(varying->reg + i * rows + j); std::string typeString = gl_d3d::TypeString(UniformComponentType(transposedType)) + str(VariableColumnCount(transposedType)); varyingHLSL += typeString + " v" + n + " : " + varyingSemantic + n + ";\n"; } } } else UNREACHABLE(); } return varyingHLSL; } bool ProgramBinary::load(InfoLog &infoLog, const void *binary, GLsizei length) { BinaryInputStream stream(binary, length); int format = 0; stream.read(&format); if (format != GL_PROGRAM_BINARY_ANGLE) { infoLog.append("Invalid program binary format."); return false; } int version = 0; stream.read(&version); if (version != VERSION_DWORD) { infoLog.append("Invalid program binary version."); return false; } int compileFlags = 0; stream.read(&compileFlags); if (compileFlags != ANGLE_COMPILE_OPTIMIZATION_LEVEL) { infoLog.append("Mismatched compilation flags."); return false; } for (int i = 0; i < MAX_VERTEX_ATTRIBS; ++i) { stream.read(&mLinkedAttribute[i].type); std::string name; stream.read(&name); mLinkedAttribute[i].name = name; stream.read(&mSemanticIndex[i]); } for (unsigned int i = 0; i < MAX_TEXTURE_IMAGE_UNITS; ++i) { stream.read(&mSamplersPS[i].active); stream.read(&mSamplersPS[i].logicalTextureUnit); int textureType; stream.read(&textureType); mSamplersPS[i].textureType = (TextureType) textureType; } for (unsigned int i = 0; i < IMPLEMENTATION_MAX_VERTEX_TEXTURE_IMAGE_UNITS; ++i) { stream.read(&mSamplersVS[i].active); stream.read(&mSamplersVS[i].logicalTextureUnit); int textureType; stream.read(&textureType); mSamplersVS[i].textureType = (TextureType) textureType; } stream.read(&mUsedVertexSamplerRange); stream.read(&mUsedPixelSamplerRange); stream.read(&mUsesPointSize); stream.read(&mShaderVersion); size_t size; stream.read(&size); if (stream.error()) { infoLog.append("Invalid program binary."); return false; } mUniforms.resize(size); for (unsigned int i = 0; i < size; ++i) { GLenum type; GLenum precision; std::string name; unsigned int arraySize; int blockIndex; stream.read(&type); stream.read(&precision); stream.read(&name); stream.read(&arraySize); stream.read(&blockIndex); int offset; int arrayStride; int matrixStride; bool isRowMajorMatrix; stream.read(&offset); stream.read(&arrayStride); stream.read(&matrixStride); stream.read(&isRowMajorMatrix); const sh::BlockMemberInfo blockInfo(offset, arrayStride, matrixStride, isRowMajorMatrix); mUniforms[i] = new Uniform(type, precision, name, arraySize, blockIndex, blockInfo); stream.read(&mUniforms[i]->psRegisterIndex); stream.read(&mUniforms[i]->vsRegisterIndex); stream.read(&mUniforms[i]->registerCount); } stream.read(&size); if (stream.error()) { infoLog.append("Invalid program binary."); return false; } mUniformBlocks.resize(size); for (unsigned int uniformBlockIndex = 0; uniformBlockIndex < size; ++uniformBlockIndex) { std::string name; unsigned int elementIndex; unsigned int dataSize; stream.read(&name); stream.read(&elementIndex); stream.read(&dataSize); mUniformBlocks[uniformBlockIndex] = new UniformBlock(name, elementIndex, dataSize); UniformBlock& uniformBlock = *mUniformBlocks[uniformBlockIndex]; stream.read(&uniformBlock.psRegisterIndex); stream.read(&uniformBlock.vsRegisterIndex); size_t numMembers; stream.read(&numMembers); uniformBlock.memberUniformIndexes.resize(numMembers); for (unsigned int blockMemberIndex = 0; blockMemberIndex < numMembers; blockMemberIndex++) { stream.read(&uniformBlock.memberUniformIndexes[blockMemberIndex]); } } stream.read(&size); if (stream.error()) { infoLog.append("Invalid program binary."); return false; } mUniformIndex.resize(size); for (unsigned int i = 0; i < size; ++i) { stream.read(&mUniformIndex[i].name); stream.read(&mUniformIndex[i].element); stream.read(&mUniformIndex[i].index); } unsigned int pixelShaderSize; stream.read(&pixelShaderSize); unsigned int vertexShaderSize; stream.read(&vertexShaderSize); unsigned int geometryShaderSize; stream.read(&geometryShaderSize); const char *ptr = (const char*) binary + stream.offset(); const GUID *binaryIdentifier = (const GUID *) ptr; ptr += sizeof(GUID); GUID identifier = mRenderer->getAdapterIdentifier(); if (memcmp(&identifier, binaryIdentifier, sizeof(GUID)) != 0) { infoLog.append("Invalid program binary."); return false; } const char *pixelShaderFunction = ptr; ptr += pixelShaderSize; const char *vertexShaderFunction = ptr; ptr += vertexShaderSize; const char *geometryShaderFunction = geometryShaderSize > 0 ? ptr : NULL; ptr += geometryShaderSize; mPixelExecutable = mRenderer->loadExecutable(reinterpret_cast<const DWORD*>(pixelShaderFunction), pixelShaderSize, rx::SHADER_PIXEL); if (!mPixelExecutable) { infoLog.append("Could not create pixel shader."); return false; } mVertexExecutable = mRenderer->loadExecutable(reinterpret_cast<const DWORD*>(vertexShaderFunction), vertexShaderSize, rx::SHADER_VERTEX); if (!mVertexExecutable) { infoLog.append("Could not create vertex shader."); delete mPixelExecutable; mPixelExecutable = NULL; return false; } if (geometryShaderFunction != NULL && geometryShaderSize > 0) { mGeometryExecutable = mRenderer->loadExecutable(reinterpret_cast<const DWORD*>(geometryShaderFunction), geometryShaderSize, rx::SHADER_GEOMETRY); if (!mGeometryExecutable) { infoLog.append("Could not create geometry shader."); delete mPixelExecutable; mPixelExecutable = NULL; delete mVertexExecutable; mVertexExecutable = NULL; return false; } } else { mGeometryExecutable = NULL; } return true; } bool ProgramBinary::save(void* binary, GLsizei bufSize, GLsizei *length) { BinaryOutputStream stream; stream.write(GL_PROGRAM_BINARY_ANGLE); stream.write(VERSION_DWORD); stream.write(ANGLE_COMPILE_OPTIMIZATION_LEVEL); for (unsigned int i = 0; i < MAX_VERTEX_ATTRIBS; ++i) { stream.write(mLinkedAttribute[i].type); stream.write(mLinkedAttribute[i].name); stream.write(mSemanticIndex[i]); } for (unsigned int i = 0; i < MAX_TEXTURE_IMAGE_UNITS; ++i) { stream.write(mSamplersPS[i].active); stream.write(mSamplersPS[i].logicalTextureUnit); stream.write((int) mSamplersPS[i].textureType); } for (unsigned int i = 0; i < IMPLEMENTATION_MAX_VERTEX_TEXTURE_IMAGE_UNITS; ++i) { stream.write(mSamplersVS[i].active); stream.write(mSamplersVS[i].logicalTextureUnit); stream.write((int) mSamplersVS[i].textureType); } stream.write(mUsedVertexSamplerRange); stream.write(mUsedPixelSamplerRange); stream.write(mUsesPointSize); stream.write(mShaderVersion); stream.write(mUniforms.size()); for (unsigned int uniformIndex = 0; uniformIndex < mUniforms.size(); ++uniformIndex) { const Uniform &uniform = *mUniforms[uniformIndex]; stream.write(uniform.type); stream.write(uniform.precision); stream.write(uniform.name); stream.write(uniform.arraySize); stream.write(uniform.blockIndex); stream.write(uniform.blockInfo.offset); stream.write(uniform.blockInfo.arrayStride); stream.write(uniform.blockInfo.matrixStride); stream.write(uniform.blockInfo.isRowMajorMatrix); stream.write(uniform.psRegisterIndex); stream.write(uniform.vsRegisterIndex); stream.write(uniform.registerCount); } stream.write(mUniformBlocks.size()); for (unsigned int uniformBlockIndex = 0; uniformBlockIndex < mUniformBlocks.size(); ++uniformBlockIndex) { const UniformBlock& uniformBlock = *mUniformBlocks[uniformBlockIndex]; stream.write(uniformBlock.name); stream.write(uniformBlock.elementIndex); stream.write(uniformBlock.dataSize); stream.write(uniformBlock.memberUniformIndexes.size()); for (unsigned int blockMemberIndex = 0; blockMemberIndex < uniformBlock.memberUniformIndexes.size(); blockMemberIndex++) { stream.write(uniformBlock.memberUniformIndexes[blockMemberIndex]); } stream.write(uniformBlock.psRegisterIndex); stream.write(uniformBlock.vsRegisterIndex); } stream.write(mUniformIndex.size()); for (unsigned int i = 0; i < mUniformIndex.size(); ++i) { stream.write(mUniformIndex[i].name); stream.write(mUniformIndex[i].element); stream.write(mUniformIndex[i].index); } UINT pixelShaderSize = mPixelExecutable->getLength(); stream.write(pixelShaderSize); UINT vertexShaderSize = mVertexExecutable->getLength(); stream.write(vertexShaderSize); UINT geometryShaderSize = (mGeometryExecutable != NULL) ? mGeometryExecutable->getLength() : 0; stream.write(geometryShaderSize); GUID identifier = mRenderer->getAdapterIdentifier(); GLsizei streamLength = stream.length(); const void *streamData = stream.data(); GLsizei totalLength = streamLength + sizeof(GUID) + pixelShaderSize + vertexShaderSize + geometryShaderSize; if (totalLength > bufSize) { if (length) { *length = 0; } return false; } if (binary) { char *ptr = (char*) binary; memcpy(ptr, streamData, streamLength); ptr += streamLength; memcpy(ptr, &identifier, sizeof(GUID)); ptr += sizeof(GUID); memcpy(ptr, mPixelExecutable->getFunction(), pixelShaderSize); ptr += pixelShaderSize; memcpy(ptr, mVertexExecutable->getFunction(), vertexShaderSize); ptr += vertexShaderSize; if (mGeometryExecutable != NULL && geometryShaderSize > 0) { memcpy(ptr, mGeometryExecutable->getFunction(), geometryShaderSize); ptr += geometryShaderSize; } ASSERT(ptr - totalLength == binary); } if (length) { *length = totalLength; } return true; } GLint ProgramBinary::getLength() { GLint length; if (save(NULL, INT_MAX, &length)) { return length; } else { return 0; } } bool ProgramBinary::link(InfoLog &infoLog, const AttributeBindings &attributeBindings, FragmentShader *fragmentShader, VertexShader *vertexShader) { if (!fragmentShader || !fragmentShader->isCompiled()) { return false; } if (!vertexShader || !vertexShader->isCompiled()) { return false; } mShaderVersion = vertexShader->getShaderVersion(); std::string pixelHLSL = fragmentShader->getHLSL(); std::string vertexHLSL = vertexShader->getHLSL(); // Map the varyings to the register file const Varying *packing[IMPLEMENTATION_MAX_VARYING_VECTORS][4] = {NULL}; int registers = packVaryings(infoLog, packing, fragmentShader); if (registers < 0) { return false; } if (!linkVaryings(infoLog, registers, packing, pixelHLSL, vertexHLSL, fragmentShader, vertexShader)) { return false; } bool success = true; if (!linkAttributes(infoLog, attributeBindings, fragmentShader, vertexShader)) { success = false; } if (!linkUniforms(infoLog, vertexShader->getUniforms(), fragmentShader->getUniforms())) { success = false; } // special case for gl_DepthRange, the only built-in uniform (also a struct) if (vertexShader->mUsesDepthRange || fragmentShader->mUsesDepthRange) { mUniforms.push_back(new Uniform(GL_FLOAT, GL_HIGH_FLOAT, "gl_DepthRange.near", 0, -1, sh::BlockMemberInfo::defaultBlockInfo)); mUniforms.push_back(new Uniform(GL_FLOAT, GL_HIGH_FLOAT, "gl_DepthRange.far", 0, -1, sh::BlockMemberInfo::defaultBlockInfo)); mUniforms.push_back(new Uniform(GL_FLOAT, GL_HIGH_FLOAT, "gl_DepthRange.diff", 0, -1, sh::BlockMemberInfo::defaultBlockInfo)); } if (!linkUniformBlocks(infoLog, vertexShader->getInterfaceBlocks(), fragmentShader->getInterfaceBlocks())) { success = false; } if (success) { mVertexExecutable = mRenderer->compileToExecutable(infoLog, vertexHLSL.c_str(), rx::SHADER_VERTEX); mPixelExecutable = mRenderer->compileToExecutable(infoLog, pixelHLSL.c_str(), rx::SHADER_PIXEL); if (usesGeometryShader()) { std::string geometryHLSL = generateGeometryShaderHLSL(registers, packing, fragmentShader, vertexShader); mGeometryExecutable = mRenderer->compileToExecutable(infoLog, geometryHLSL.c_str(), rx::SHADER_GEOMETRY); } if (!mVertexExecutable || !mPixelExecutable || (usesGeometryShader() && !mGeometryExecutable)) { infoLog.append("Failed to create D3D shaders."); success = false; delete mVertexExecutable; mVertexExecutable = NULL; delete mPixelExecutable; mPixelExecutable = NULL; delete mGeometryExecutable; mGeometryExecutable = NULL; } } return success; } // Determines the mapping between GL attributes and Direct3D 9 vertex stream usage indices bool ProgramBinary::linkAttributes(InfoLog &infoLog, const AttributeBindings &attributeBindings, FragmentShader *fragmentShader, VertexShader *vertexShader) { unsigned int usedLocations = 0; const sh::ActiveShaderVariables &activeAttributes = vertexShader->mActiveAttributes; // Link attributes that have a binding location for (unsigned int attributeIndex = 0; attributeIndex < activeAttributes.size(); attributeIndex++) { const sh::ShaderVariable &attribute = activeAttributes[attributeIndex]; const int location = attribute.location == -1 ? attributeBindings.getAttributeBinding(attribute.name) : attribute.location; if (location != -1) // Set by glBindAttribLocation or by location layout qualifier { const int rows = AttributeRegisterCount(attribute.type); if (rows + location > MAX_VERTEX_ATTRIBS) { infoLog.append("Active attribute (%s) at location %d is too big to fit", attribute.name.c_str(), location); return false; } for (int row = 0; row < rows; row++) { const int rowLocation = location + row; sh::ShaderVariable &linkedAttribute = mLinkedAttribute[rowLocation]; // In GLSL 3.00, attribute aliasing produces a link error // In GLSL 1.00, attribute aliasing is allowed if (mShaderVersion >= 300) { if (!linkedAttribute.name.empty()) { infoLog.append("Attribute '%s' aliases attribute '%s' at location %d", attribute.name.c_str(), linkedAttribute.name.c_str(), rowLocation); return false; } } linkedAttribute = attribute; usedLocations |= 1 << rowLocation; } } } // Link attributes that don't have a binding location for (unsigned int attributeIndex = 0; attributeIndex < activeAttributes.size(); attributeIndex++) { const sh::ShaderVariable &attribute = activeAttributes[attributeIndex]; const int location = attribute.location == -1 ? attributeBindings.getAttributeBinding(attribute.name) : attribute.location; if (location == -1) // Not set by glBindAttribLocation or by location layout qualifier { int rows = AttributeRegisterCount(attribute.type); int availableIndex = AllocateFirstFreeBits(&usedLocations, rows, MAX_VERTEX_ATTRIBS); if (availableIndex == -1 || availableIndex + rows > MAX_VERTEX_ATTRIBS) { infoLog.append("Too many active attributes (%s)", attribute.name.c_str()); return false; // Fail to link } mLinkedAttribute[availableIndex] = attribute; } } for (int attributeIndex = 0; attributeIndex < MAX_VERTEX_ATTRIBS; ) { int index = vertexShader->getSemanticIndex(mLinkedAttribute[attributeIndex].name); int rows = AttributeRegisterCount(mLinkedAttribute[attributeIndex].type); for (int r = 0; r < rows; r++) { mSemanticIndex[attributeIndex++] = index++; } } return true; } bool ProgramBinary::areMatchingUniforms(InfoLog &infoLog, const std::string &uniformName, const sh::Uniform &vertexUniform, const sh::Uniform &fragmentUniform) { if (vertexUniform.type != fragmentUniform.type) { infoLog.append("Types for %s differ between vertex and fragment shaders", uniformName.c_str()); return false; } else if (vertexUniform.arraySize != fragmentUniform.arraySize) { infoLog.append("Array sizes for %s differ between vertex and fragment shaders", uniformName.c_str()); return false; } else if (vertexUniform.precision != fragmentUniform.precision) { infoLog.append("Precisions for %s differ between vertex and fragment shaders", uniformName.c_str()); return false; } else if (vertexUniform.fields.size() != fragmentUniform.fields.size()) { infoLog.append("Structure lengths for %s differ between vertex and fragment shaders", uniformName.c_str()); } else if (vertexUniform.isRowMajorMatrix != fragmentUniform.isRowMajorMatrix) { infoLog.append("Matrix packings for %s differ between vertex and fragment shaders", uniformName.c_str()); return false; } const unsigned int numMembers = vertexUniform.fields.size(); for (unsigned int memberIndex = 0; memberIndex < numMembers; memberIndex++) { const sh::Uniform &vertexMember = vertexUniform.fields[memberIndex]; const sh::Uniform &fragmentMember = fragmentUniform.fields[memberIndex]; if (vertexMember.name != fragmentMember.name) { infoLog.append("Name mismatch for field %d of %s: (in vertex: '%s', in fragment: '%s')", memberIndex, uniformName.c_str(), vertexMember.name.c_str(), fragmentMember.name.c_str()); return false; } const std::string memberName = uniformName + "." + vertexUniform.name; if (!areMatchingUniforms(infoLog, memberName, vertexMember, fragmentMember)) { return false; } } return true; } bool ProgramBinary::linkUniforms(InfoLog &infoLog, const sh::ActiveUniforms &vertexUniforms, const sh::ActiveUniforms &fragmentUniforms) { // Check that uniforms defined in the vertex and fragment shaders are identical typedef std::map<std::string, const sh::Uniform*> UniformMap; UniformMap linkedUniforms; for (unsigned int vertexUniformIndex = 0; vertexUniformIndex < vertexUniforms.size(); vertexUniformIndex++) { const sh::Uniform &vertexUniform = vertexUniforms[vertexUniformIndex]; linkedUniforms[vertexUniform.name] = &vertexUniform; } for (unsigned int fragmentUniformIndex = 0; fragmentUniformIndex < fragmentUniforms.size(); fragmentUniformIndex++) { const sh::Uniform &fragmentUniform = fragmentUniforms[fragmentUniformIndex]; UniformMap::const_iterator entry = linkedUniforms.find(fragmentUniform.name); if (entry != linkedUniforms.end()) { const sh::Uniform &vertexUniform = *entry->second; const std::string &uniformName = "uniform " + vertexUniform.name; if (!areMatchingUniforms(infoLog, uniformName, vertexUniform, fragmentUniform)) { return false; } } } for (unsigned int uniformIndex = 0; uniformIndex < vertexUniforms.size(); uniformIndex++) { if (!defineUniform(GL_VERTEX_SHADER, vertexUniforms[uniformIndex], infoLog)) { return false; } } for (unsigned int uniformIndex = 0; uniformIndex < fragmentUniforms.size(); uniformIndex++) { if (!defineUniform(GL_FRAGMENT_SHADER, fragmentUniforms[uniformIndex], infoLog)) { return false; } } return true; } int totalRegisterCount(const sh::Uniform &uniform) { int registerCount = 0; if (!uniform.fields.empty()) { for (unsigned int fieldIndex = 0; fieldIndex < uniform.fields.size(); fieldIndex++) { registerCount += totalRegisterCount(uniform.fields[fieldIndex]); } } else { registerCount = 1; } return (uniform.arraySize > 0) ? uniform.arraySize * registerCount : registerCount; } TextureType ProgramBinary::getTextureType(GLenum samplerType, InfoLog &infoLog) { switch(samplerType) { case GL_SAMPLER_2D: case GL_INT_SAMPLER_2D: case GL_UNSIGNED_INT_SAMPLER_2D: case GL_SAMPLER_2D_SHADOW: return TEXTURE_2D; case GL_SAMPLER_3D: case GL_INT_SAMPLER_3D: case GL_UNSIGNED_INT_SAMPLER_3D: return TEXTURE_3D; case GL_SAMPLER_CUBE: case GL_SAMPLER_CUBE_SHADOW: return TEXTURE_CUBE; case GL_INT_SAMPLER_CUBE: case GL_UNSIGNED_INT_SAMPLER_CUBE: //UNIMPLEMENTED(); infoLog.append("Integer cube texture sampling is currently not supported by ANGLE and returns a black color."); return TEXTURE_CUBE; case GL_SAMPLER_2D_ARRAY: case GL_INT_SAMPLER_2D_ARRAY: case GL_UNSIGNED_INT_SAMPLER_2D_ARRAY: case GL_SAMPLER_2D_ARRAY_SHADOW: return TEXTURE_2D_ARRAY; default: UNREACHABLE(); } return TEXTURE_2D; } bool ProgramBinary::defineUniform(GLenum shader, const sh::Uniform &constant, InfoLog &infoLog) { if (!constant.fields.empty()) { if (constant.arraySize > 0) { unsigned int elementRegisterIndex = constant.registerIndex; for (unsigned int elementIndex = 0; elementIndex < constant.arraySize; elementIndex++) { for (size_t fieldIndex = 0; fieldIndex < constant.fields.size(); fieldIndex++) { const sh::Uniform &field = constant.fields[fieldIndex]; const std::string &uniformName = constant.name + arrayString(elementIndex) + "." + field.name; const sh::Uniform fieldUniform(field.type, field.precision, uniformName.c_str(), field.arraySize, elementRegisterIndex, field.isRowMajorMatrix); if (!defineUniform(shader, fieldUniform, infoLog)) { return false; } elementRegisterIndex += totalRegisterCount(field); } } } else { unsigned int fieldRegisterIndex = constant.registerIndex; for (size_t fieldIndex = 0; fieldIndex < constant.fields.size(); fieldIndex++) { const sh::Uniform &field = constant.fields[fieldIndex]; const std::string &uniformName = constant.name + "." + field.name; sh::Uniform fieldUniform(field.type, field.precision, uniformName.c_str(), field.arraySize, fieldRegisterIndex, field.isRowMajorMatrix); fieldUniform.fields = field.fields; if (!defineUniform(shader, fieldUniform, infoLog)) { return false; } fieldRegisterIndex += totalRegisterCount(field); } } return true; } if (IsSampler(constant.type)) { unsigned int samplerIndex = constant.registerIndex; do { if (shader == GL_VERTEX_SHADER) { if (samplerIndex < mRenderer->getMaxVertexTextureImageUnits()) { mSamplersVS[samplerIndex].active = true; mSamplersVS[samplerIndex].textureType = getTextureType(constant.type, infoLog); mSamplersVS[samplerIndex].logicalTextureUnit = 0; mUsedVertexSamplerRange = std::max(samplerIndex + 1, mUsedVertexSamplerRange); } else { infoLog.append("Vertex shader sampler count exceeds the maximum vertex texture units (%d).", mRenderer->getMaxVertexTextureImageUnits()); return false; } } else if (shader == GL_FRAGMENT_SHADER) { if (samplerIndex < MAX_TEXTURE_IMAGE_UNITS) { mSamplersPS[samplerIndex].active = true; mSamplersPS[samplerIndex].textureType = getTextureType(constant.type, infoLog); mSamplersPS[samplerIndex].logicalTextureUnit = 0; mUsedPixelSamplerRange = std::max(samplerIndex + 1, mUsedPixelSamplerRange); } else { infoLog.append("Pixel shader sampler count exceeds MAX_TEXTURE_IMAGE_UNITS (%d).", MAX_TEXTURE_IMAGE_UNITS); return false; } } else UNREACHABLE(); samplerIndex++; } while (samplerIndex < constant.registerIndex + constant.arraySize); } Uniform *uniform = NULL; GLint location = getUniformLocation(constant.name); if (location >= 0) // Previously defined, type and precision must match { uniform = mUniforms[mUniformIndex[location].index]; } else { uniform = new Uniform(constant.type, constant.precision, constant.name, constant.arraySize, -1, sh::BlockMemberInfo::defaultBlockInfo); } if (!uniform) { return false; } if (shader == GL_FRAGMENT_SHADER) { uniform->psRegisterIndex = constant.registerIndex; } else if (shader == GL_VERTEX_SHADER) { uniform->vsRegisterIndex = constant.registerIndex; } else UNREACHABLE(); if (location >= 0) { return uniform->type == constant.type; } mUniforms.push_back(uniform); unsigned int uniformIndex = mUniforms.size() - 1; for (unsigned int arrayElementIndex = 0; arrayElementIndex < uniform->elementCount(); arrayElementIndex++) { mUniformIndex.push_back(VariableLocation(uniform->name, arrayElementIndex, uniformIndex)); } if (shader == GL_VERTEX_SHADER) { if (constant.registerIndex + uniform->registerCount > mRenderer->getReservedVertexUniformVectors() + mRenderer->getMaxVertexUniformVectors()) { infoLog.append("Vertex shader active uniforms exceed GL_MAX_VERTEX_UNIFORM_VECTORS (%u)", mRenderer->getMaxVertexUniformVectors()); return false; } } else if (shader == GL_FRAGMENT_SHADER) { if (constant.registerIndex + uniform->registerCount > mRenderer->getReservedFragmentUniformVectors() + mRenderer->getMaxFragmentUniformVectors()) { infoLog.append("Fragment shader active uniforms exceed GL_MAX_FRAGMENT_UNIFORM_VECTORS (%u)", mRenderer->getMaxFragmentUniformVectors()); return false; } } else UNREACHABLE(); return true; } bool ProgramBinary::areMatchingInterfaceBlocks(InfoLog &infoLog, const sh::InterfaceBlock &vertexInterfaceBlock, const sh::InterfaceBlock &fragmentInterfaceBlock) { const char* blockName = vertexInterfaceBlock.name.c_str(); // validate blocks for the same member types if (vertexInterfaceBlock.activeUniforms.size() != fragmentInterfaceBlock.activeUniforms.size()) { infoLog.append("Types for interface block '%s' differ between vertex and fragment shaders", blockName); return false; } if (vertexInterfaceBlock.arraySize != fragmentInterfaceBlock.arraySize) { infoLog.append("Array sizes differ for interface block '%s' between vertex and fragment shaders", blockName); return false; } const unsigned int numBlockMembers = vertexInterfaceBlock.activeUniforms.size(); for (unsigned int blockMemberIndex = 0; blockMemberIndex < numBlockMembers; blockMemberIndex++) { const sh::Uniform &vertexMember = vertexInterfaceBlock.activeUniforms[blockMemberIndex]; const sh::Uniform &fragmentMember = fragmentInterfaceBlock.activeUniforms[blockMemberIndex]; if (vertexMember.name != fragmentMember.name) { infoLog.append("Name mismatch for field %d of interface block %s: (in vertex: '%s', in fragment: '%s')", blockMemberIndex, blockName, vertexMember.name.c_str(), fragmentMember.name.c_str()); return false; } std::string uniformName = "interface block " + vertexInterfaceBlock.name + " member " + vertexMember.name; if (!areMatchingUniforms(infoLog, uniformName, vertexMember, fragmentMember)) { return false; } } return true; } bool ProgramBinary::linkUniformBlocks(InfoLog &infoLog, const sh::ActiveInterfaceBlocks &vertexInterfaceBlocks, const sh::ActiveInterfaceBlocks &fragmentInterfaceBlocks) { // Check that interface blocks defined in the vertex and fragment shaders are identical typedef std::map<std::string, const sh::InterfaceBlock*> UniformBlockMap; UniformBlockMap linkedUniformBlocks; for (unsigned int blockIndex = 0; blockIndex < vertexInterfaceBlocks.size(); blockIndex++) { const sh::InterfaceBlock &vertexInterfaceBlock = vertexInterfaceBlocks[blockIndex]; linkedUniformBlocks[vertexInterfaceBlock.name] = &vertexInterfaceBlock; } for (unsigned int blockIndex = 0; blockIndex < fragmentInterfaceBlocks.size(); blockIndex++) { const sh::InterfaceBlock &fragmentInterfaceBlock = fragmentInterfaceBlocks[blockIndex]; UniformBlockMap::const_iterator entry = linkedUniformBlocks.find(fragmentInterfaceBlock.name); if (entry != linkedUniformBlocks.end()) { const sh::InterfaceBlock &vertexInterfaceBlock = *entry->second; if (!areMatchingInterfaceBlocks(infoLog, vertexInterfaceBlock, fragmentInterfaceBlock)) { return false; } } } for (unsigned int blockIndex = 0; blockIndex < vertexInterfaceBlocks.size(); blockIndex++) { if (!defineUniformBlock(infoLog, GL_VERTEX_SHADER, vertexInterfaceBlocks[blockIndex])) { return false; } } for (unsigned int blockIndex = 0; blockIndex < fragmentInterfaceBlocks.size(); blockIndex++) { if (!defineUniformBlock(infoLog, GL_FRAGMENT_SHADER, fragmentInterfaceBlocks[blockIndex])) { return false; } } return true; } void ProgramBinary::defineUniformBlockMembers(const sh::ActiveUniforms &uniforms, const std::string &prefix, int blockIndex, BlockInfoItr *blockInfoItr, std::vector<unsigned int> *blockUniformIndexes) { for (unsigned int uniformIndex = 0; uniformIndex < uniforms.size(); uniformIndex++) { const sh::Uniform &uniform = uniforms[uniformIndex]; const std::string &uniformName = (prefix.empty() ? uniform.name : prefix + "." + uniform.name); if (!uniform.fields.empty()) { if (uniform.arraySize > 0) { for (unsigned int arrayElement = 0; arrayElement < uniform.arraySize; arrayElement++) { const std::string uniformElementName = uniformName + arrayString(arrayElement); defineUniformBlockMembers(uniform.fields, uniformElementName, blockIndex, blockInfoItr, blockUniformIndexes); } } else { defineUniformBlockMembers(uniform.fields, uniformName, blockIndex, blockInfoItr, blockUniformIndexes); } } else { Uniform *newUniform = new Uniform(uniform.type, uniform.precision, uniformName, uniform.arraySize, blockIndex, **blockInfoItr); // add to uniform list, but not index, since uniform block uniforms have no location blockUniformIndexes->push_back(mUniforms.size()); mUniforms.push_back(newUniform); (*blockInfoItr)++; } } } bool ProgramBinary::defineUniformBlock(InfoLog &infoLog, GLenum shader, const sh::InterfaceBlock &interfaceBlock) { // create uniform block entries if they do not exist if (getUniformBlockIndex(interfaceBlock.name) == GL_INVALID_INDEX) { std::vector<unsigned int> blockUniformIndexes; const unsigned int blockIndex = mUniformBlocks.size(); // define member uniforms BlockInfoItr blockInfoItr = interfaceBlock.blockInfo.cbegin(); defineUniformBlockMembers(interfaceBlock.activeUniforms, "", blockIndex, &blockInfoItr, &blockUniformIndexes); // create all the uniform blocks if (interfaceBlock.arraySize > 0) { for (unsigned int uniformBlockElement = 0; uniformBlockElement < interfaceBlock.arraySize; uniformBlockElement++) { gl::UniformBlock *newUniformBlock = new UniformBlock(interfaceBlock.name, uniformBlockElement, interfaceBlock.dataSize); newUniformBlock->memberUniformIndexes = blockUniformIndexes; mUniformBlocks.push_back(newUniformBlock); } } else { gl::UniformBlock *newUniformBlock = new UniformBlock(interfaceBlock.name, GL_INVALID_INDEX, interfaceBlock.dataSize); newUniformBlock->memberUniformIndexes = blockUniformIndexes; mUniformBlocks.push_back(newUniformBlock); } } // Assign registers to the uniform blocks const GLuint blockIndex = getUniformBlockIndex(interfaceBlock.name); const unsigned int elementCount = std::max(1u, interfaceBlock.arraySize); ASSERT(blockIndex != GL_INVALID_INDEX); ASSERT(blockIndex + elementCount <= mUniformBlocks.size()); for (unsigned int uniformBlockElement = 0; uniformBlockElement < elementCount; uniformBlockElement++) { gl::UniformBlock *uniformBlock = mUniformBlocks[blockIndex + uniformBlockElement]; ASSERT(uniformBlock->name == interfaceBlock.name); if (!assignUniformBlockRegister(infoLog, uniformBlock, shader, interfaceBlock.registerIndex + uniformBlockElement)) { return false; } } return true; } bool ProgramBinary::assignUniformBlockRegister(InfoLog &infoLog, UniformBlock *uniformBlock, GLenum shader, unsigned int registerIndex) { if (shader == GL_VERTEX_SHADER) { uniformBlock->vsRegisterIndex = registerIndex; unsigned int maximumBlocks = mRenderer->getMaxVertexShaderUniformBuffers(); if (registerIndex - mRenderer->getReservedVertexUniformBuffers() >= maximumBlocks) { infoLog.append("Vertex shader uniform block count exceed GL_MAX_VERTEX_UNIFORM_BLOCKS (%u)", maximumBlocks); return false; } } else if (shader == GL_FRAGMENT_SHADER) { uniformBlock->psRegisterIndex = registerIndex; unsigned int maximumBlocks = mRenderer->getMaxFragmentShaderUniformBuffers(); if (registerIndex - mRenderer->getReservedFragmentUniformBuffers() >= maximumBlocks) { infoLog.append("Fragment shader uniform block count exceed GL_MAX_FRAGMENT_UNIFORM_BLOCKS (%u)", maximumBlocks); return false; } } else UNREACHABLE(); return true; } std::string ProgramBinary::generateGeometryShaderHLSL(int registers, const Varying *packing[][4], FragmentShader *fragmentShader, VertexShader *vertexShader) const { // for now we only handle point sprite emulation ASSERT(usesPointSpriteEmulation()); return generatePointSpriteHLSL(registers, packing, fragmentShader, vertexShader); } std::string ProgramBinary::generatePointSpriteHLSL(int registers, const Varying *packing[][4], FragmentShader *fragmentShader, VertexShader *vertexShader) const { ASSERT(registers >= 0); ASSERT(vertexShader->mUsesPointSize); ASSERT(mRenderer->getMajorShaderModel() >= 4); std::string geomHLSL; std::string varyingSemantic = "TEXCOORD"; std::string fragCoordSemantic; std::string pointCoordSemantic; int reservedRegisterIndex = registers; if (fragmentShader->mUsesFragCoord) { fragCoordSemantic = varyingSemantic + str(reservedRegisterIndex++); } if (fragmentShader->mUsesPointCoord) { pointCoordSemantic = varyingSemantic + str(reservedRegisterIndex++); } geomHLSL += "uniform float4 dx_ViewCoords : register(c1);\n" "\n" "struct GS_INPUT\n" "{\n"; std::string varyingHLSL = generateVaryingHLSL(fragmentShader, varyingSemantic); geomHLSL += varyingHLSL; if (fragmentShader->mUsesFragCoord) { geomHLSL += " float4 gl_FragCoord : " + fragCoordSemantic + ";\n"; } geomHLSL += " float gl_PointSize : PSIZE;\n" " float4 gl_Position : SV_Position;\n" "};\n" "\n" "struct GS_OUTPUT\n" "{\n"; geomHLSL += varyingHLSL; if (fragmentShader->mUsesFragCoord) { geomHLSL += " float4 gl_FragCoord : " + fragCoordSemantic + ";\n"; } if (fragmentShader->mUsesPointCoord) { geomHLSL += " float2 gl_PointCoord : " + pointCoordSemantic + ";\n"; } geomHLSL += " float gl_PointSize : PSIZE;\n" " float4 gl_Position : SV_Position;\n" "};\n" "\n" "static float2 pointSpriteCorners[] = \n" "{\n" " float2( 0.5f, -0.5f),\n" " float2( 0.5f, 0.5f),\n" " float2(-0.5f, -0.5f),\n" " float2(-0.5f, 0.5f)\n" "};\n" "\n" "static float2 pointSpriteTexcoords[] = \n" "{\n" " float2(1.0f, 1.0f),\n" " float2(1.0f, 0.0f),\n" " float2(0.0f, 1.0f),\n" " float2(0.0f, 0.0f)\n" "};\n" "\n" "static float minPointSize = " + str(ALIASED_POINT_SIZE_RANGE_MIN) + ".0f;\n" "static float maxPointSize = " + str(mRenderer->getMaxPointSize()) + ".0f;\n" "\n" "[maxvertexcount(4)]\n" "void main(point GS_INPUT input[1], inout TriangleStream<GS_OUTPUT> outStream)\n" "{\n" " GS_OUTPUT output = (GS_OUTPUT)0;\n" " output.gl_PointSize = input[0].gl_PointSize;\n"; for (int r = 0; r < registers; r++) { geomHLSL += " output.v" + str(r) + " = input[0].v" + str(r) + ";\n"; } if (fragmentShader->mUsesFragCoord) { geomHLSL += " output.gl_FragCoord = input[0].gl_FragCoord;\n"; } geomHLSL += " \n" " float gl_PointSize = clamp(input[0].gl_PointSize, minPointSize, maxPointSize);\n" " float4 gl_Position = input[0].gl_Position;\n" " float2 viewportScale = float2(1.0f / dx_ViewCoords.x, 1.0f / dx_ViewCoords.y) * gl_Position.w;\n"; for (int corner = 0; corner < 4; corner++) { geomHLSL += " \n" " output.gl_Position = gl_Position + float4(pointSpriteCorners[" + str(corner) + "] * viewportScale * gl_PointSize, 0.0f, 0.0f);\n"; if (fragmentShader->mUsesPointCoord) { geomHLSL += " output.gl_PointCoord = pointSpriteTexcoords[" + str(corner) + "];\n"; } geomHLSL += " outStream.Append(output);\n"; } geomHLSL += " \n" " outStream.RestartStrip();\n" "}\n"; return geomHLSL; } // This method needs to match OutputHLSL::decorate std::string ProgramBinary::decorateAttribute(const std::string &name) { if (name.compare(0, 3, "gl_") != 0 && name.compare(0, 3, "dx_") != 0) { return "_" + name; } return name; } bool ProgramBinary::isValidated() const { return mValidated; } void ProgramBinary::getActiveAttribute(GLuint index, GLsizei bufsize, GLsizei *length, GLint *size, GLenum *type, GLchar *name) const { // Skip over inactive attributes unsigned int activeAttribute = 0; unsigned int attribute; for (attribute = 0; attribute < MAX_VERTEX_ATTRIBS; attribute++) { if (mLinkedAttribute[attribute].name.empty()) { continue; } if (activeAttribute == index) { break; } activeAttribute++; } if (bufsize > 0) { const char *string = mLinkedAttribute[attribute].name.c_str(); strncpy(name, string, bufsize); name[bufsize - 1] = '\0'; if (length) { *length = strlen(name); } } *size = 1; // Always a single 'type' instance *type = mLinkedAttribute[attribute].type; } GLint ProgramBinary::getActiveAttributeCount() const { int count = 0; for (int attributeIndex = 0; attributeIndex < MAX_VERTEX_ATTRIBS; attributeIndex++) { if (!mLinkedAttribute[attributeIndex].name.empty()) { count++; } } return count; } GLint ProgramBinary::getActiveAttributeMaxLength() const { int maxLength = 0; for (int attributeIndex = 0; attributeIndex < MAX_VERTEX_ATTRIBS; attributeIndex++) { if (!mLinkedAttribute[attributeIndex].name.empty()) { maxLength = std::max((int)(mLinkedAttribute[attributeIndex].name.length() + 1), maxLength); } } return maxLength; } void ProgramBinary::getActiveUniform(GLuint index, GLsizei bufsize, GLsizei *length, GLint *size, GLenum *type, GLchar *name) const { ASSERT(index < mUniforms.size()); // index must be smaller than getActiveUniformCount() if (bufsize > 0) { std::string string = mUniforms[index]->name; if (mUniforms[index]->isArray()) { string += "[0]"; } strncpy(name, string.c_str(), bufsize); name[bufsize - 1] = '\0'; if (length) { *length = strlen(name); } } *size = mUniforms[index]->elementCount(); *type = mUniforms[index]->type; } GLint ProgramBinary::getActiveUniformCount() const { return mUniforms.size(); } GLint ProgramBinary::getActiveUniformMaxLength() const { int maxLength = 0; unsigned int numUniforms = mUniforms.size(); for (unsigned int uniformIndex = 0; uniformIndex < numUniforms; uniformIndex++) { if (!mUniforms[uniformIndex]->name.empty()) { int length = (int)(mUniforms[uniformIndex]->name.length() + 1); if (mUniforms[uniformIndex]->isArray()) { length += 3; // Counting in "[0]". } maxLength = std::max(length, maxLength); } } return maxLength; } GLint ProgramBinary::getActiveUniformi(GLuint index, GLenum pname) const { const gl::Uniform& uniform = *mUniforms[index]; switch (pname) { case GL_UNIFORM_TYPE: return static_cast<GLint>(uniform.type); case GL_UNIFORM_SIZE: return static_cast<GLint>(uniform.elementCount()); case GL_UNIFORM_NAME_LENGTH: return static_cast<GLint>(uniform.name.size() + 1 + (uniform.isArray() ? 3 : 0)); case GL_UNIFORM_BLOCK_INDEX: return uniform.blockIndex; case GL_UNIFORM_OFFSET: return uniform.blockInfo.offset; case GL_UNIFORM_ARRAY_STRIDE: return uniform.blockInfo.arrayStride; case GL_UNIFORM_MATRIX_STRIDE: return uniform.blockInfo.matrixStride; case GL_UNIFORM_IS_ROW_MAJOR: return static_cast<GLint>(uniform.blockInfo.isRowMajorMatrix); default: UNREACHABLE(); break; } return 0; } void ProgramBinary::getActiveUniformBlockName(GLuint uniformBlockIndex, GLsizei bufSize, GLsizei *length, GLchar *uniformBlockName) const { ASSERT(uniformBlockIndex < mUniformBlocks.size()); // index must be smaller than getActiveUniformBlockCount() const UniformBlock &uniformBlock = *mUniformBlocks[uniformBlockIndex]; if (bufSize > 0) { std::string string = uniformBlock.name; if (uniformBlock.isArrayElement()) { string += arrayString(uniformBlock.elementIndex); } strncpy(uniformBlockName, string.c_str(), bufSize); uniformBlockName[bufSize - 1] = '\0'; if (length) { *length = strlen(uniformBlockName); } } } void ProgramBinary::getActiveUniformBlockiv(GLuint uniformBlockIndex, GLenum pname, GLint *params) const { ASSERT(uniformBlockIndex < mUniformBlocks.size()); // index must be smaller than getActiveUniformBlockCount() const UniformBlock &uniformBlock = *mUniformBlocks[uniformBlockIndex]; switch (pname) { case GL_UNIFORM_BLOCK_DATA_SIZE: *params = static_cast<GLint>(uniformBlock.dataSize); break; case GL_UNIFORM_BLOCK_NAME_LENGTH: *params = static_cast<GLint>(uniformBlock.name.size() + 1 + (uniformBlock.isArrayElement() ? 3 : 0)); break; case GL_UNIFORM_BLOCK_ACTIVE_UNIFORMS: *params = static_cast<GLint>(uniformBlock.memberUniformIndexes.size()); break; case GL_UNIFORM_BLOCK_ACTIVE_UNIFORM_INDICES: { for (unsigned int blockMemberIndex = 0; blockMemberIndex < uniformBlock.memberUniformIndexes.size(); blockMemberIndex++) { params[blockMemberIndex] = static_cast<GLint>(uniformBlock.memberUniformIndexes[blockMemberIndex]); } } break; case GL_UNIFORM_BLOCK_REFERENCED_BY_VERTEX_SHADER: *params = static_cast<GLint>(uniformBlock.isReferencedByVertexShader()); break; case GL_UNIFORM_BLOCK_REFERENCED_BY_FRAGMENT_SHADER: *params = static_cast<GLint>(uniformBlock.isReferencedByFragmentShader()); break; default: UNREACHABLE(); } } GLuint ProgramBinary::getActiveUniformBlockCount() const { return mUniformBlocks.size(); } GLuint ProgramBinary::getActiveUniformBlockMaxLength() const { unsigned int maxLength = 0; unsigned int numUniformBlocks = mUniformBlocks.size(); for (unsigned int uniformBlockIndex = 0; uniformBlockIndex < numUniformBlocks; uniformBlockIndex++) { const UniformBlock &uniformBlock = *mUniformBlocks[uniformBlockIndex]; if (!uniformBlock.name.empty()) { const unsigned int length = uniformBlock.name.length() + 1; // Counting in "[0]". const unsigned int arrayLength = (uniformBlock.isArrayElement() ? 3 : 0); maxLength = std::max(length + arrayLength, maxLength); } } return maxLength; } void ProgramBinary::validate(InfoLog &infoLog) { applyUniforms(); if (!validateSamplers(&infoLog)) { mValidated = false; } else { mValidated = true; } } bool ProgramBinary::validateSamplers(InfoLog *infoLog) { // if any two active samplers in a program are of different types, but refer to the same // texture image unit, and this is the current program, then ValidateProgram will fail, and // DrawArrays and DrawElements will issue the INVALID_OPERATION error. const unsigned int maxCombinedTextureImageUnits = mRenderer->getMaxCombinedTextureImageUnits(); TextureType textureUnitType[IMPLEMENTATION_MAX_COMBINED_TEXTURE_IMAGE_UNITS]; for (unsigned int i = 0; i < IMPLEMENTATION_MAX_COMBINED_TEXTURE_IMAGE_UNITS; ++i) { textureUnitType[i] = TEXTURE_UNKNOWN; } for (unsigned int i = 0; i < mUsedPixelSamplerRange; ++i) { if (mSamplersPS[i].active) { unsigned int unit = mSamplersPS[i].logicalTextureUnit; if (unit >= maxCombinedTextureImageUnits) { if (infoLog) { infoLog->append("Sampler uniform (%d) exceeds IMPLEMENTATION_MAX_COMBINED_TEXTURE_IMAGE_UNITS (%d)", unit, maxCombinedTextureImageUnits); } return false; } if (textureUnitType[unit] != TEXTURE_UNKNOWN) { if (mSamplersPS[i].textureType != textureUnitType[unit]) { if (infoLog) { infoLog->append("Samplers of conflicting types refer to the same texture image unit (%d).", unit); } return false; } } else { textureUnitType[unit] = mSamplersPS[i].textureType; } } } for (unsigned int i = 0; i < mUsedVertexSamplerRange; ++i) { if (mSamplersVS[i].active) { unsigned int unit = mSamplersVS[i].logicalTextureUnit; if (unit >= maxCombinedTextureImageUnits) { if (infoLog) { infoLog->append("Sampler uniform (%d) exceeds IMPLEMENTATION_MAX_COMBINED_TEXTURE_IMAGE_UNITS (%d)", unit, maxCombinedTextureImageUnits); } return false; } if (textureUnitType[unit] != TEXTURE_UNKNOWN) { if (mSamplersVS[i].textureType != textureUnitType[unit]) { if (infoLog) { infoLog->append("Samplers of conflicting types refer to the same texture image unit (%d).", unit); } return false; } } else { textureUnitType[unit] = mSamplersVS[i].textureType; } } } return true; } ProgramBinary::Sampler::Sampler() : active(false), logicalTextureUnit(0), textureType(TEXTURE_2D) { } struct AttributeSorter { AttributeSorter(const int (&semanticIndices)[MAX_VERTEX_ATTRIBS]) : originalIndices(semanticIndices) { for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++) { indices[i] = i; } std::sort(&indices[0], &indices[MAX_VERTEX_ATTRIBS], *this); } bool operator()(int a, int b) { return originalIndices[a] == -1 ? false : originalIndices[a] < originalIndices[b]; } int indices[MAX_VERTEX_ATTRIBS]; const int (&originalIndices)[MAX_VERTEX_ATTRIBS]; }; void ProgramBinary::sortAttributesByLayout(rx::TranslatedAttribute attributes[MAX_VERTEX_ATTRIBS], int sortedSemanticIndices[MAX_VERTEX_ATTRIBS]) const { AttributeSorter sorter(mSemanticIndex); int oldIndices[MAX_VERTEX_ATTRIBS]; rx::TranslatedAttribute oldTranslatedAttributes[MAX_VERTEX_ATTRIBS]; for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++) { oldIndices[i] = mSemanticIndex[i]; oldTranslatedAttributes[i] = attributes[i]; } for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++) { int oldIndex = sorter.indices[i]; sortedSemanticIndices[i] = oldIndices[oldIndex]; attributes[i] = oldTranslatedAttributes[oldIndex]; } } }