src/dawn_native/opengl/RenderPipelineGL.cpp - dawn - Git at Google

 // Copyright 2017 The Dawn Authors
 //
 // 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 "dawn_native/opengl/RenderPipelineGL.h"

 #include "dawn_native/opengl/DeviceGL.h"
 #include "dawn_native/opengl/Forward.h"
 #include "dawn_native/opengl/PersistentPipelineStateGL.h"
 #include "dawn_native/opengl/UtilsGL.h"

 namespace dawn_native { namespace opengl {

     namespace {

         GLenum GLPrimitiveTopology(wgpu::PrimitiveTopology primitiveTopology) {
             switch (primitiveTopology) {
                 case wgpu::PrimitiveTopology::PointList:
                     return GL_POINTS;
                 case wgpu::PrimitiveTopology::LineList:
                     return GL_LINES;
                 case wgpu::PrimitiveTopology::LineStrip:
                     return GL_LINE_STRIP;
                 case wgpu::PrimitiveTopology::TriangleList:
                     return GL_TRIANGLES;
                 case wgpu::PrimitiveTopology::TriangleStrip:
                     return GL_TRIANGLE_STRIP;
             }
         }

         void ApplyFrontFaceAndCulling(const OpenGLFunctions& gl,
                                       wgpu::FrontFace face,
                                       wgpu::CullMode mode) {
             // Note that we invert winding direction in OpenGL. Because Y axis is up in OpenGL,
             // which is different from WebGPU and other backends (Y axis is down).
             GLenum direction = (face == wgpu::FrontFace::CCW) ? GL_CW : GL_CCW;
             gl.FrontFace(direction);

             if (mode == wgpu::CullMode::None) {
                 gl.Disable(GL_CULL_FACE);
             } else {
                 gl.Enable(GL_CULL_FACE);

                 GLenum cullMode = (mode == wgpu::CullMode::Front) ? GL_FRONT : GL_BACK;
                 gl.CullFace(cullMode);
             }
         }

         GLenum GLBlendFactor(wgpu::BlendFactor factor, bool alpha) {
             switch (factor) {
                 case wgpu::BlendFactor::Zero:
                     return GL_ZERO;
                 case wgpu::BlendFactor::One:
                     return GL_ONE;
                 case wgpu::BlendFactor::Src:
                     return GL_SRC_COLOR;
                 case wgpu::BlendFactor::OneMinusSrc:
                     return GL_ONE_MINUS_SRC_COLOR;
                 case wgpu::BlendFactor::SrcAlpha:
                     return GL_SRC_ALPHA;
                 case wgpu::BlendFactor::OneMinusSrcAlpha:
                     return GL_ONE_MINUS_SRC_ALPHA;
                 case wgpu::BlendFactor::Dst:
                     return GL_DST_COLOR;
                 case wgpu::BlendFactor::OneMinusDst:
                     return GL_ONE_MINUS_DST_COLOR;
                 case wgpu::BlendFactor::DstAlpha:
                     return GL_DST_ALPHA;
                 case wgpu::BlendFactor::OneMinusDstAlpha:
                     return GL_ONE_MINUS_DST_ALPHA;
                 case wgpu::BlendFactor::SrcAlphaSaturated:
                     return GL_SRC_ALPHA_SATURATE;
                 case wgpu::BlendFactor::Constant:
                     return alpha ? GL_CONSTANT_ALPHA : GL_CONSTANT_COLOR;
                 case wgpu::BlendFactor::OneMinusConstant:
                     return alpha ? GL_ONE_MINUS_CONSTANT_ALPHA : GL_ONE_MINUS_CONSTANT_COLOR;

                 // Deprecated blend factors should be normalized prior to this call.
                 case wgpu::BlendFactor::SrcColor:
                 case wgpu::BlendFactor::OneMinusSrcColor:
                 case wgpu::BlendFactor::DstColor:
                 case wgpu::BlendFactor::OneMinusDstColor:
                 case wgpu::BlendFactor::BlendColor:
                 case wgpu::BlendFactor::OneMinusBlendColor:
                     UNREACHABLE();
             }
         }

         GLenum GLBlendMode(wgpu::BlendOperation operation) {
             switch (operation) {
                 case wgpu::BlendOperation::Add:
                     return GL_FUNC_ADD;
                 case wgpu::BlendOperation::Subtract:
                     return GL_FUNC_SUBTRACT;
                 case wgpu::BlendOperation::ReverseSubtract:
                     return GL_FUNC_REVERSE_SUBTRACT;
                 case wgpu::BlendOperation::Min:
                     return GL_MIN;
                 case wgpu::BlendOperation::Max:
                     return GL_MAX;
             }
         }

         void ApplyColorState(const OpenGLFunctions& gl,
                              ColorAttachmentIndex attachment,
                              const ColorTargetState* state) {
             GLuint colorBuffer = static_cast<GLuint>(static_cast<uint8_t>(attachment));
             if (state->blend != nullptr) {
                 gl.Enablei(GL_BLEND, colorBuffer);
                 gl.BlendEquationSeparatei(colorBuffer, GLBlendMode(state->blend->color.operation),
                                           GLBlendMode(state->blend->alpha.operation));
                 gl.BlendFuncSeparatei(colorBuffer,
                                       GLBlendFactor(state->blend->color.srcFactor, false),
                                       GLBlendFactor(state->blend->color.dstFactor, false),
                                       GLBlendFactor(state->blend->alpha.srcFactor, true),
                                       GLBlendFactor(state->blend->alpha.dstFactor, true));
             } else {
                 gl.Disablei(GL_BLEND, colorBuffer);
             }
             gl.ColorMaski(colorBuffer, state->writeMask & wgpu::ColorWriteMask::Red,
                           state->writeMask & wgpu::ColorWriteMask::Green,
                           state->writeMask & wgpu::ColorWriteMask::Blue,
                           state->writeMask & wgpu::ColorWriteMask::Alpha);
         }

         void ApplyColorState(const OpenGLFunctions& gl, const ColorTargetState* state) {
             if (state->blend != nullptr) {
                 gl.Enable(GL_BLEND);
                 gl.BlendEquationSeparate(GLBlendMode(state->blend->color.operation),
                                          GLBlendMode(state->blend->alpha.operation));
                 gl.BlendFuncSeparate(GLBlendFactor(state->blend->color.srcFactor, false),
                                      GLBlendFactor(state->blend->color.dstFactor, false),
                                      GLBlendFactor(state->blend->alpha.srcFactor, true),
                                      GLBlendFactor(state->blend->alpha.dstFactor, true));
             } else {
                 gl.Disable(GL_BLEND);
             }
             gl.ColorMask(state->writeMask & wgpu::ColorWriteMask::Red,
                          state->writeMask & wgpu::ColorWriteMask::Green,
                          state->writeMask & wgpu::ColorWriteMask::Blue,
                          state->writeMask & wgpu::ColorWriteMask::Alpha);
         }

         bool Equal(const BlendDescriptor& lhs, const BlendDescriptor& rhs) {
             return lhs.operation == rhs.operation && lhs.srcFactor == rhs.srcFactor &&
                    lhs.dstFactor == rhs.dstFactor;
         }

         GLuint OpenGLStencilOperation(wgpu::StencilOperation stencilOperation) {
             switch (stencilOperation) {
                 case wgpu::StencilOperation::Keep:
                     return GL_KEEP;
                 case wgpu::StencilOperation::Zero:
                     return GL_ZERO;
                 case wgpu::StencilOperation::Replace:
                     return GL_REPLACE;
                 case wgpu::StencilOperation::Invert:
                     return GL_INVERT;
                 case wgpu::StencilOperation::IncrementClamp:
                     return GL_INCR;
                 case wgpu::StencilOperation::DecrementClamp:
                     return GL_DECR;
                 case wgpu::StencilOperation::IncrementWrap:
                     return GL_INCR_WRAP;
                 case wgpu::StencilOperation::DecrementWrap:
                     return GL_DECR_WRAP;
             }
         }

         void ApplyDepthStencilState(const OpenGLFunctions& gl,
                                     const DepthStencilState* descriptor,
                                     PersistentPipelineState* persistentPipelineState) {
             // Depth writes only occur if depth is enabled
             if (descriptor->depthCompare == wgpu::CompareFunction::Always &&
                 !descriptor->depthWriteEnabled) {
                 gl.Disable(GL_DEPTH_TEST);
             } else {
                 gl.Enable(GL_DEPTH_TEST);
             }

             if (descriptor->depthWriteEnabled) {
                 gl.DepthMask(GL_TRUE);
             } else {
                 gl.DepthMask(GL_FALSE);
             }

             gl.DepthFunc(ToOpenGLCompareFunction(descriptor->depthCompare));

             if (StencilTestEnabled(descriptor)) {
                 gl.Enable(GL_STENCIL_TEST);
             } else {
                 gl.Disable(GL_STENCIL_TEST);
             }

             GLenum backCompareFunction = ToOpenGLCompareFunction(descriptor->stencilBack.compare);
             GLenum frontCompareFunction = ToOpenGLCompareFunction(descriptor->stencilFront.compare);
             persistentPipelineState->SetStencilFuncsAndMask(
                 gl, backCompareFunction, frontCompareFunction, descriptor->stencilReadMask);

             gl.StencilOpSeparate(GL_BACK, OpenGLStencilOperation(descriptor->stencilBack.failOp),
                                  OpenGLStencilOperation(descriptor->stencilBack.depthFailOp),
                                  OpenGLStencilOperation(descriptor->stencilBack.passOp));
             gl.StencilOpSeparate(GL_FRONT, OpenGLStencilOperation(descriptor->stencilFront.failOp),
                                  OpenGLStencilOperation(descriptor->stencilFront.depthFailOp),
                                  OpenGLStencilOperation(descriptor->stencilFront.passOp));

             gl.StencilMask(descriptor->stencilWriteMask);
         }

     }  // anonymous namespace

     RenderPipeline::RenderPipeline(Device* device, const RenderPipelineDescriptor* descriptor)
         : RenderPipelineBase(device, descriptor),
           mVertexArrayObject(0),
           mGlPrimitiveTopology(GLPrimitiveTopology(GetPrimitiveTopology())) {
         PerStage<const ShaderModule*> modules(nullptr);
         modules[SingleShaderStage::Vertex] = ToBackend(descriptor->vertex.module);
         modules[SingleShaderStage::Fragment] = ToBackend(descriptor->fragment->module);

         PipelineGL::Initialize(device->gl, ToBackend(GetLayout()), GetAllStages());
         CreateVAOForVertexState();
     }

     RenderPipeline::~RenderPipeline() {
         const OpenGLFunctions& gl = ToBackend(GetDevice())->gl;
         gl.DeleteVertexArrays(1, &mVertexArrayObject);
         gl.BindVertexArray(0);
     }

     GLenum RenderPipeline::GetGLPrimitiveTopology() const {
         return mGlPrimitiveTopology;
     }

     ityp::bitset<VertexAttributeLocation, kMaxVertexAttributes>
     RenderPipeline::GetAttributesUsingVertexBuffer(VertexBufferSlot slot) const {
         ASSERT(!IsError());
         return mAttributesUsingVertexBuffer[slot];
     }

     void RenderPipeline::CreateVAOForVertexState() {
         const OpenGLFunctions& gl = ToBackend(GetDevice())->gl;

         gl.GenVertexArrays(1, &mVertexArrayObject);
         gl.BindVertexArray(mVertexArrayObject);

         for (VertexAttributeLocation location : IterateBitSet(GetAttributeLocationsUsed())) {
             const auto& attribute = GetAttribute(location);
             GLuint glAttrib = static_cast<GLuint>(static_cast<uint8_t>(location));
             gl.EnableVertexAttribArray(glAttrib);

             mAttributesUsingVertexBuffer[attribute.vertexBufferSlot][location] = true;
             const VertexBufferInfo& vertexBuffer = GetVertexBuffer(attribute.vertexBufferSlot);

             if (vertexBuffer.arrayStride == 0) {
                 // Emulate a stride of zero (constant vertex attribute) by
                 // setting the attribute instance divisor to a huge number.
                 gl.VertexAttribDivisor(glAttrib, 0xffffffff);
             } else {
                 switch (vertexBuffer.stepMode) {
                     case wgpu::InputStepMode::Vertex:
                         break;
                     case wgpu::InputStepMode::Instance:
                         gl.VertexAttribDivisor(glAttrib, 1);
                         break;
                 }
             }
         }
     }

     void RenderPipeline::ApplyNow(PersistentPipelineState& persistentPipelineState) {
         const OpenGLFunctions& gl = ToBackend(GetDevice())->gl;
         PipelineGL::ApplyNow(gl);

         ASSERT(mVertexArrayObject);
         gl.BindVertexArray(mVertexArrayObject);

         ApplyFrontFaceAndCulling(gl, GetFrontFace(), GetCullMode());

         ApplyDepthStencilState(gl, GetDepthStencilState(), &persistentPipelineState);

         gl.SampleMaski(0, GetSampleMask());
         if (IsAlphaToCoverageEnabled()) {
             gl.Enable(GL_SAMPLE_ALPHA_TO_COVERAGE);
         } else {
             gl.Disable(GL_SAMPLE_ALPHA_TO_COVERAGE);
         }

         if (IsDepthBiasEnabled()) {
             gl.Enable(GL_POLYGON_OFFSET_FILL);
             float depthBias = GetDepthBias();
             float slopeScale = GetDepthBiasSlopeScale();
             if (gl.PolygonOffsetClamp != nullptr) {
                 gl.PolygonOffsetClamp(slopeScale, depthBias, GetDepthBiasClamp());
             } else {
                 gl.PolygonOffset(slopeScale, depthBias);
             }
         } else {
             gl.Disable(GL_POLYGON_OFFSET_FILL);
         }

         if (!GetDevice()->IsToggleEnabled(Toggle::DisableIndexedDrawBuffers)) {
             for (ColorAttachmentIndex attachmentSlot : IterateBitSet(GetColorAttachmentsMask())) {
                 ApplyColorState(gl, attachmentSlot, GetColorTargetState(attachmentSlot));
             }
         } else {
             const ColorTargetState* prevDescriptor = nullptr;
             for (ColorAttachmentIndex attachmentSlot : IterateBitSet(GetColorAttachmentsMask())) {
                 const ColorTargetState* descriptor = GetColorTargetState(attachmentSlot);
                 if (!prevDescriptor) {
                     ApplyColorState(gl, descriptor);
                     prevDescriptor = descriptor;
                 } else if ((descriptor->blend == nullptr) != (prevDescriptor->blend == nullptr)) {
                     // TODO(crbug.com/dawn/582): GLES < 3.2 does not support different blend states
                     // per color target. Add validation to prevent this as it is not.
                     ASSERT(false);
                 } else if (descriptor->blend != nullptr) {
                     if (!Equal(descriptor->blend->alpha, prevDescriptor->blend->alpha) ||
                         !Equal(descriptor->blend->color, prevDescriptor->blend->color) ||
                         descriptor->writeMask != prevDescriptor->writeMask) {
                         // TODO(crbug.com/dawn/582)
                         ASSERT(false);
                     }
                 }
             }
         }
     }

 }}  // namespace dawn_native::opengl
	// Copyright 2017 The Dawn Authors
	//
	// 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 "dawn_native/opengl/RenderPipelineGL.h"

	#include "dawn_native/opengl/DeviceGL.h"
	#include "dawn_native/opengl/Forward.h"
	#include "dawn_native/opengl/PersistentPipelineStateGL.h"
	#include "dawn_native/opengl/UtilsGL.h"

	namespace dawn_native { namespace opengl {

	namespace {

	GLenum GLPrimitiveTopology(wgpu::PrimitiveTopology primitiveTopology) {
	switch (primitiveTopology) {
	case wgpu::PrimitiveTopology::PointList:
	return GL_POINTS;
	case wgpu::PrimitiveTopology::LineList:
	return GL_LINES;
	case wgpu::PrimitiveTopology::LineStrip:
	return GL_LINE_STRIP;
	case wgpu::PrimitiveTopology::TriangleList:
	return GL_TRIANGLES;
	case wgpu::PrimitiveTopology::TriangleStrip:
	return GL_TRIANGLE_STRIP;
	}
	}

	void ApplyFrontFaceAndCulling(const OpenGLFunctions& gl,
	wgpu::FrontFace face,
	wgpu::CullMode mode) {
	// Note that we invert winding direction in OpenGL. Because Y axis is up in OpenGL,
	// which is different from WebGPU and other backends (Y axis is down).
	GLenum direction = (face == wgpu::FrontFace::CCW) ? GL_CW : GL_CCW;
	gl.FrontFace(direction);

	if (mode == wgpu::CullMode::None) {
	gl.Disable(GL_CULL_FACE);
	} else {
	gl.Enable(GL_CULL_FACE);

	GLenum cullMode = (mode == wgpu::CullMode::Front) ? GL_FRONT : GL_BACK;
	gl.CullFace(cullMode);
	}
	}

	GLenum GLBlendFactor(wgpu::BlendFactor factor, bool alpha) {
	switch (factor) {
	case wgpu::BlendFactor::Zero:
	return GL_ZERO;
	case wgpu::BlendFactor::One:
	return GL_ONE;
	case wgpu::BlendFactor::Src:
	return GL_SRC_COLOR;
	case wgpu::BlendFactor::OneMinusSrc:
	return GL_ONE_MINUS_SRC_COLOR;
	case wgpu::BlendFactor::SrcAlpha:
	return GL_SRC_ALPHA;
	case wgpu::BlendFactor::OneMinusSrcAlpha:
	return GL_ONE_MINUS_SRC_ALPHA;
	case wgpu::BlendFactor::Dst:
	return GL_DST_COLOR;
	case wgpu::BlendFactor::OneMinusDst:
	return GL_ONE_MINUS_DST_COLOR;
	case wgpu::BlendFactor::DstAlpha:
	return GL_DST_ALPHA;
	case wgpu::BlendFactor::OneMinusDstAlpha:
	return GL_ONE_MINUS_DST_ALPHA;
	case wgpu::BlendFactor::SrcAlphaSaturated:
	return GL_SRC_ALPHA_SATURATE;
	case wgpu::BlendFactor::Constant:
	return alpha ? GL_CONSTANT_ALPHA : GL_CONSTANT_COLOR;
	case wgpu::BlendFactor::OneMinusConstant:
	return alpha ? GL_ONE_MINUS_CONSTANT_ALPHA : GL_ONE_MINUS_CONSTANT_COLOR;

	// Deprecated blend factors should be normalized prior to this call.
	case wgpu::BlendFactor::SrcColor:
	case wgpu::BlendFactor::OneMinusSrcColor:
	case wgpu::BlendFactor::DstColor:
	case wgpu::BlendFactor::OneMinusDstColor:
	case wgpu::BlendFactor::BlendColor:
	case wgpu::BlendFactor::OneMinusBlendColor:
	UNREACHABLE();
	}
	}

	GLenum GLBlendMode(wgpu::BlendOperation operation) {
	switch (operation) {
	case wgpu::BlendOperation::Add:
	return GL_FUNC_ADD;
	case wgpu::BlendOperation::Subtract:
	return GL_FUNC_SUBTRACT;
	case wgpu::BlendOperation::ReverseSubtract:
	return GL_FUNC_REVERSE_SUBTRACT;
	case wgpu::BlendOperation::Min:
	return GL_MIN;
	case wgpu::BlendOperation::Max:
	return GL_MAX;
	}
	}

	void ApplyColorState(const OpenGLFunctions& gl,
	ColorAttachmentIndex attachment,
	const ColorTargetState* state) {
	GLuint colorBuffer = static_cast<GLuint>(static_cast<uint8_t>(attachment));
	if (state->blend != nullptr) {
	gl.Enablei(GL_BLEND, colorBuffer);
	gl.BlendEquationSeparatei(colorBuffer, GLBlendMode(state->blend->color.operation),
	GLBlendMode(state->blend->alpha.operation));
	gl.BlendFuncSeparatei(colorBuffer,
	GLBlendFactor(state->blend->color.srcFactor, false),
	GLBlendFactor(state->blend->color.dstFactor, false),
	GLBlendFactor(state->blend->alpha.srcFactor, true),
	GLBlendFactor(state->blend->alpha.dstFactor, true));
	} else {
	gl.Disablei(GL_BLEND, colorBuffer);
	}
	gl.ColorMaski(colorBuffer, state->writeMask & wgpu::ColorWriteMask::Red,
	state->writeMask & wgpu::ColorWriteMask::Green,
	state->writeMask & wgpu::ColorWriteMask::Blue,
	state->writeMask & wgpu::ColorWriteMask::Alpha);
	}

	void ApplyColorState(const OpenGLFunctions& gl, const ColorTargetState* state) {
	if (state->blend != nullptr) {
	gl.Enable(GL_BLEND);
	gl.BlendEquationSeparate(GLBlendMode(state->blend->color.operation),
	GLBlendMode(state->blend->alpha.operation));
	gl.BlendFuncSeparate(GLBlendFactor(state->blend->color.srcFactor, false),
	GLBlendFactor(state->blend->color.dstFactor, false),
	GLBlendFactor(state->blend->alpha.srcFactor, true),
	GLBlendFactor(state->blend->alpha.dstFactor, true));
	} else {
	gl.Disable(GL_BLEND);
	}
	gl.ColorMask(state->writeMask & wgpu::ColorWriteMask::Red,
	state->writeMask & wgpu::ColorWriteMask::Green,
	state->writeMask & wgpu::ColorWriteMask::Blue,
	state->writeMask & wgpu::ColorWriteMask::Alpha);
	}

	bool Equal(const BlendDescriptor& lhs, const BlendDescriptor& rhs) {
	return lhs.operation == rhs.operation && lhs.srcFactor == rhs.srcFactor &&
	lhs.dstFactor == rhs.dstFactor;
	}

	GLuint OpenGLStencilOperation(wgpu::StencilOperation stencilOperation) {
	switch (stencilOperation) {
	case wgpu::StencilOperation::Keep:
	return GL_KEEP;
	case wgpu::StencilOperation::Zero:
	return GL_ZERO;
	case wgpu::StencilOperation::Replace:
	return GL_REPLACE;
	case wgpu::StencilOperation::Invert:
	return GL_INVERT;
	case wgpu::StencilOperation::IncrementClamp:
	return GL_INCR;
	case wgpu::StencilOperation::DecrementClamp:
	return GL_DECR;
	case wgpu::StencilOperation::IncrementWrap:
	return GL_INCR_WRAP;
	case wgpu::StencilOperation::DecrementWrap:
	return GL_DECR_WRAP;
	}
	}

	void ApplyDepthStencilState(const OpenGLFunctions& gl,
	const DepthStencilState* descriptor,
	PersistentPipelineState* persistentPipelineState) {
	// Depth writes only occur if depth is enabled
	if (descriptor->depthCompare == wgpu::CompareFunction::Always &&
	!descriptor->depthWriteEnabled) {
	gl.Disable(GL_DEPTH_TEST);
	} else {
	gl.Enable(GL_DEPTH_TEST);
	}

	if (descriptor->depthWriteEnabled) {
	gl.DepthMask(GL_TRUE);
	} else {
	gl.DepthMask(GL_FALSE);
	}

	gl.DepthFunc(ToOpenGLCompareFunction(descriptor->depthCompare));

	if (StencilTestEnabled(descriptor)) {
	gl.Enable(GL_STENCIL_TEST);
	} else {
	gl.Disable(GL_STENCIL_TEST);
	}

	GLenum backCompareFunction = ToOpenGLCompareFunction(descriptor->stencilBack.compare);
	GLenum frontCompareFunction = ToOpenGLCompareFunction(descriptor->stencilFront.compare);
	persistentPipelineState->SetStencilFuncsAndMask(
	gl, backCompareFunction, frontCompareFunction, descriptor->stencilReadMask);

	gl.StencilOpSeparate(GL_BACK, OpenGLStencilOperation(descriptor->stencilBack.failOp),
	OpenGLStencilOperation(descriptor->stencilBack.depthFailOp),
	OpenGLStencilOperation(descriptor->stencilBack.passOp));
	gl.StencilOpSeparate(GL_FRONT, OpenGLStencilOperation(descriptor->stencilFront.failOp),
	OpenGLStencilOperation(descriptor->stencilFront.depthFailOp),
	OpenGLStencilOperation(descriptor->stencilFront.passOp));

	gl.StencilMask(descriptor->stencilWriteMask);
	}

	} // anonymous namespace

	RenderPipeline::RenderPipeline(Device* device, const RenderPipelineDescriptor* descriptor)
	: RenderPipelineBase(device, descriptor),
	mVertexArrayObject(0),
	mGlPrimitiveTopology(GLPrimitiveTopology(GetPrimitiveTopology())) {
	PerStage<const ShaderModule*> modules(nullptr);
	modules[SingleShaderStage::Vertex] = ToBackend(descriptor->vertex.module);
	modules[SingleShaderStage::Fragment] = ToBackend(descriptor->fragment->module);

	PipelineGL::Initialize(device->gl, ToBackend(GetLayout()), GetAllStages());
	CreateVAOForVertexState();
	}

	RenderPipeline::~RenderPipeline() {
	const OpenGLFunctions& gl = ToBackend(GetDevice())->gl;
	gl.DeleteVertexArrays(1, &mVertexArrayObject);
	gl.BindVertexArray(0);
	}

	GLenum RenderPipeline::GetGLPrimitiveTopology() const {
	return mGlPrimitiveTopology;
	}

	ityp::bitset<VertexAttributeLocation, kMaxVertexAttributes>
	RenderPipeline::GetAttributesUsingVertexBuffer(VertexBufferSlot slot) const {
	ASSERT(!IsError());
	return mAttributesUsingVertexBuffer[slot];
	}

	void RenderPipeline::CreateVAOForVertexState() {
	const OpenGLFunctions& gl = ToBackend(GetDevice())->gl;

	gl.GenVertexArrays(1, &mVertexArrayObject);
	gl.BindVertexArray(mVertexArrayObject);

	for (VertexAttributeLocation location : IterateBitSet(GetAttributeLocationsUsed())) {
	const auto& attribute = GetAttribute(location);
	GLuint glAttrib = static_cast<GLuint>(static_cast<uint8_t>(location));
	gl.EnableVertexAttribArray(glAttrib);

	mAttributesUsingVertexBuffer[attribute.vertexBufferSlot][location] = true;
	const VertexBufferInfo& vertexBuffer = GetVertexBuffer(attribute.vertexBufferSlot);

	if (vertexBuffer.arrayStride == 0) {
	// Emulate a stride of zero (constant vertex attribute) by
	// setting the attribute instance divisor to a huge number.
	gl.VertexAttribDivisor(glAttrib, 0xffffffff);
	} else {
	switch (vertexBuffer.stepMode) {
	case wgpu::InputStepMode::Vertex:
	break;
	case wgpu::InputStepMode::Instance:
	gl.VertexAttribDivisor(glAttrib, 1);
	break;
	}
	}
	}
	}

	void RenderPipeline::ApplyNow(PersistentPipelineState& persistentPipelineState) {
	const OpenGLFunctions& gl = ToBackend(GetDevice())->gl;
	PipelineGL::ApplyNow(gl);

	ASSERT(mVertexArrayObject);
	gl.BindVertexArray(mVertexArrayObject);

	ApplyFrontFaceAndCulling(gl, GetFrontFace(), GetCullMode());

	ApplyDepthStencilState(gl, GetDepthStencilState(), &persistentPipelineState);

	gl.SampleMaski(0, GetSampleMask());
	if (IsAlphaToCoverageEnabled()) {
	gl.Enable(GL_SAMPLE_ALPHA_TO_COVERAGE);
	} else {
	gl.Disable(GL_SAMPLE_ALPHA_TO_COVERAGE);
	}

	if (IsDepthBiasEnabled()) {
	gl.Enable(GL_POLYGON_OFFSET_FILL);
	float depthBias = GetDepthBias();
	float slopeScale = GetDepthBiasSlopeScale();
	if (gl.PolygonOffsetClamp != nullptr) {
	gl.PolygonOffsetClamp(slopeScale, depthBias, GetDepthBiasClamp());
	} else {
	gl.PolygonOffset(slopeScale, depthBias);
	}
	} else {
	gl.Disable(GL_POLYGON_OFFSET_FILL);
	}

	if (!GetDevice()->IsToggleEnabled(Toggle::DisableIndexedDrawBuffers)) {
	for (ColorAttachmentIndex attachmentSlot : IterateBitSet(GetColorAttachmentsMask())) {
	ApplyColorState(gl, attachmentSlot, GetColorTargetState(attachmentSlot));
	}
	} else {
	const ColorTargetState* prevDescriptor = nullptr;
	for (ColorAttachmentIndex attachmentSlot : IterateBitSet(GetColorAttachmentsMask())) {
	const ColorTargetState* descriptor = GetColorTargetState(attachmentSlot);
	if (!prevDescriptor) {
	ApplyColorState(gl, descriptor);
	prevDescriptor = descriptor;
	} else if ((descriptor->blend == nullptr) != (prevDescriptor->blend == nullptr)) {
	// TODO(crbug.com/dawn/582): GLES < 3.2 does not support different blend states
	// per color target. Add validation to prevent this as it is not.
	ASSERT(false);
	} else if (descriptor->blend != nullptr) {
	if (!Equal(descriptor->blend->alpha, prevDescriptor->blend->alpha) \|\|
	!Equal(descriptor->blend->color, prevDescriptor->blend->color) \|\|
	descriptor->writeMask != prevDescriptor->writeMask) {
	// TODO(crbug.com/dawn/582)
	ASSERT(false);
	}
	}
	}
	}
	}

	}} // namespace dawn_native::opengl