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/*
* Copyright 2018 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "GrMtlPipelineStateBuilder.h"
#include "GrContext.h"
#include "GrContextPriv.h"
#include "GrMtlGpu.h"
#include "GrMtlPipelineState.h"
#include "GrMtlUtil.h"
#import <simd/simd.h>
GrMtlPipelineState* GrMtlPipelineStateBuilder::CreatePipelineState(
GrRenderTarget* renderTarget, GrSurfaceOrigin origin,
const GrPrimitiveProcessor& primProc,
const GrTextureProxy* const primProcProxies[],
const GrPipeline& pipeline,
GrProgramDesc* desc,
GrMtlGpu* gpu) {
GrMtlPipelineStateBuilder builder(renderTarget, origin, primProc, primProcProxies, pipeline,
desc, gpu);
if (!builder.emitAndInstallProcs()) {
return nullptr;
}
return builder.finalize(primProc, pipeline, desc);
}
GrMtlPipelineStateBuilder::GrMtlPipelineStateBuilder(GrRenderTarget* renderTarget, GrSurfaceOrigin origin,
const GrPrimitiveProcessor& primProc,
const GrTextureProxy* const primProcProxies[],
const GrPipeline& pipeline,
GrProgramDesc* desc,
GrMtlGpu* gpu)
: INHERITED(renderTarget, origin, primProc, primProcProxies, pipeline, desc)
, fGpu(gpu)
, fUniformHandler(this)
, fVaryingHandler(this) {
}
const GrCaps* GrMtlPipelineStateBuilder::caps() const {
return fGpu->caps();
}
void GrMtlPipelineStateBuilder::finalizeFragmentOutputColor(GrShaderVar& outputColor) {
outputColor.addLayoutQualifier("location = 0, index = 0");
}
void GrMtlPipelineStateBuilder::finalizeFragmentSecondaryColor(GrShaderVar& outputColor) {
outputColor.addLayoutQualifier("location = 0, index = 1");
}
id<MTLLibrary> GrMtlPipelineStateBuilder::createMtlShaderLibrary(
const GrGLSLShaderBuilder& builder,
SkSL::Program::Kind kind,
const SkSL::Program::Settings& settings,
GrProgramDesc* desc) {
SkString shaderString;
for (int i = 0; i < builder.fCompilerStrings.count(); ++i) {
if (builder.fCompilerStrings[i]) {
shaderString.append(builder.fCompilerStrings[i]);
shaderString.append("\n");
}
}
SkSL::Program::Inputs inputs;
id<MTLLibrary> shaderLibrary = GrCompileMtlShaderLibrary(fGpu, shaderString.c_str(),
kind, settings, &inputs);
if (shaderLibrary == nil) {
return nil;
}
if (inputs.fRTHeight) {
this->addRTHeightUniform(SKSL_RTHEIGHT_NAME);
}
if (inputs.fFlipY) {
desc->setSurfaceOriginKey(GrGLSLFragmentShaderBuilder::KeyForSurfaceOrigin(this->origin()));
}
return shaderLibrary;
}
static inline MTLVertexFormat attribute_type_to_mtlformat(GrVertexAttribType type) {
// All half types will actually be float types. We are currently not using half types with
// metal to avoid an issue with narrow type coercions (float->half) http://skbug.com/8221
switch (type) {
case kFloat_GrVertexAttribType:
return MTLVertexFormatFloat;
case kFloat2_GrVertexAttribType:
return MTLVertexFormatFloat2;
case kFloat3_GrVertexAttribType:
return MTLVertexFormatFloat3;
case kFloat4_GrVertexAttribType:
return MTLVertexFormatFloat4;
case kHalf_GrVertexAttribType:
return MTLVertexFormatHalf;
case kHalf2_GrVertexAttribType:
return MTLVertexFormatHalf2;
case kHalf3_GrVertexAttribType:
return MTLVertexFormatHalf3;
case kHalf4_GrVertexAttribType:
return MTLVertexFormatHalf4;
case kInt2_GrVertexAttribType:
return MTLVertexFormatInt2;
case kInt3_GrVertexAttribType:
return MTLVertexFormatInt3;
case kInt4_GrVertexAttribType:
return MTLVertexFormatInt4;
case kByte_GrVertexAttribType:
return MTLVertexFormatChar;
case kByte2_GrVertexAttribType:
return MTLVertexFormatChar2;
case kByte3_GrVertexAttribType:
return MTLVertexFormatChar3;
case kByte4_GrVertexAttribType:
return MTLVertexFormatChar4;
case kUByte_GrVertexAttribType:
return MTLVertexFormatUChar;
case kUByte2_GrVertexAttribType:
return MTLVertexFormatUChar2;
case kUByte3_GrVertexAttribType:
return MTLVertexFormatUChar3;
case kUByte4_GrVertexAttribType:
return MTLVertexFormatUChar4;
case kUByte_norm_GrVertexAttribType:
return MTLVertexFormatUCharNormalized;
case kUByte4_norm_GrVertexAttribType:
return MTLVertexFormatUChar4Normalized;
case kShort2_GrVertexAttribType:
return MTLVertexFormatShort2;
case kShort4_GrVertexAttribType:
return MTLVertexFormatShort4;
case kUShort2_GrVertexAttribType:
return MTLVertexFormatUShort2;
case kUShort2_norm_GrVertexAttribType:
return MTLVertexFormatUShort2Normalized;
case kInt_GrVertexAttribType:
return MTLVertexFormatInt;
case kUint_GrVertexAttribType:
return MTLVertexFormatUInt;
}
SK_ABORT("Unknown vertex attribute type");
return MTLVertexFormatInvalid;
}
static MTLVertexDescriptor* create_vertex_descriptor(const GrPrimitiveProcessor& primProc) {
uint32_t vertexBinding = 0, instanceBinding = 0;
int nextBinding = GrMtlUniformHandler::kLastUniformBinding + 1;
if (primProc.hasVertexAttributes()) {
vertexBinding = nextBinding++;
}
if (primProc.hasInstanceAttributes()) {
instanceBinding = nextBinding;
}
auto vertexDescriptor = [[MTLVertexDescriptor alloc] init];
int attributeIndex = 0;
int vertexAttributeCount = primProc.numVertexAttributes();
size_t vertexAttributeOffset = 0;
for (const auto& attribute : primProc.vertexAttributes()) {
MTLVertexAttributeDescriptor* mtlAttribute = vertexDescriptor.attributes[attributeIndex];
mtlAttribute.format = attribute_type_to_mtlformat(attribute.cpuType());
mtlAttribute.offset = vertexAttributeOffset;
mtlAttribute.bufferIndex = vertexBinding;
vertexAttributeOffset += attribute.sizeAlign4();
attributeIndex++;
}
SkASSERT(vertexAttributeOffset == primProc.vertexStride());
if (vertexAttributeCount) {
MTLVertexBufferLayoutDescriptor* vertexBufferLayout =
vertexDescriptor.layouts[vertexBinding];
vertexBufferLayout.stepFunction = MTLVertexStepFunctionPerVertex;
vertexBufferLayout.stepRate = 1;
vertexBufferLayout.stride = vertexAttributeOffset;
}
int instanceAttributeCount = primProc.numInstanceAttributes();
size_t instanceAttributeOffset = 0;
for (const auto& attribute : primProc.instanceAttributes()) {
MTLVertexAttributeDescriptor* mtlAttribute = vertexDescriptor.attributes[attributeIndex];
mtlAttribute.format = attribute_type_to_mtlformat(attribute.cpuType());
mtlAttribute.offset = instanceAttributeOffset;
mtlAttribute.bufferIndex = instanceBinding;
instanceAttributeOffset += attribute.sizeAlign4();
attributeIndex++;
}
SkASSERT(instanceAttributeOffset == primProc.instanceStride());
if (instanceAttributeCount) {
MTLVertexBufferLayoutDescriptor* instanceBufferLayout =
vertexDescriptor.layouts[instanceBinding];
instanceBufferLayout.stepFunction = MTLVertexStepFunctionPerInstance;
instanceBufferLayout.stepRate = 1;
instanceBufferLayout.stride = instanceAttributeOffset;
}
return vertexDescriptor;
}
static MTLBlendFactor blend_coeff_to_mtl_blend(GrBlendCoeff coeff) {
static const MTLBlendFactor gTable[] = {
MTLBlendFactorZero, // kZero_GrBlendCoeff
MTLBlendFactorOne, // kOne_GrBlendCoeff
MTLBlendFactorSourceColor, // kSC_GrBlendCoeff
MTLBlendFactorOneMinusSourceColor, // kISC_GrBlendCoeff
MTLBlendFactorDestinationColor, // kDC_GrBlendCoeff
MTLBlendFactorOneMinusDestinationColor, // kIDC_GrBlendCoeff
MTLBlendFactorSourceAlpha, // kSA_GrBlendCoeff
MTLBlendFactorOneMinusSourceAlpha, // kISA_GrBlendCoeff
MTLBlendFactorDestinationAlpha, // kDA_GrBlendCoeff
MTLBlendFactorOneMinusDestinationAlpha, // kIDA_GrBlendCoeff
MTLBlendFactorBlendColor, // kConstC_GrBlendCoeff
MTLBlendFactorOneMinusBlendColor, // kIConstC_GrBlendCoeff
MTLBlendFactorBlendAlpha, // kConstA_GrBlendCoeff
MTLBlendFactorOneMinusBlendAlpha, // kIConstA_GrBlendCoeff
MTLBlendFactorSource1Color, // kS2C_GrBlendCoeff
MTLBlendFactorOneMinusSource1Color, // kIS2C_GrBlendCoeff
MTLBlendFactorSource1Alpha, // kS2A_GrBlendCoeff
MTLBlendFactorOneMinusSource1Alpha, // kIS2A_GrBlendCoeff
MTLBlendFactorZero, // kIllegal_GrBlendCoeff
};
GR_STATIC_ASSERT(SK_ARRAY_COUNT(gTable) == kGrBlendCoeffCnt);
GR_STATIC_ASSERT(0 == kZero_GrBlendCoeff);
GR_STATIC_ASSERT(1 == kOne_GrBlendCoeff);
GR_STATIC_ASSERT(2 == kSC_GrBlendCoeff);
GR_STATIC_ASSERT(3 == kISC_GrBlendCoeff);
GR_STATIC_ASSERT(4 == kDC_GrBlendCoeff);
GR_STATIC_ASSERT(5 == kIDC_GrBlendCoeff);
GR_STATIC_ASSERT(6 == kSA_GrBlendCoeff);
GR_STATIC_ASSERT(7 == kISA_GrBlendCoeff);
GR_STATIC_ASSERT(8 == kDA_GrBlendCoeff);
GR_STATIC_ASSERT(9 == kIDA_GrBlendCoeff);
GR_STATIC_ASSERT(10 == kConstC_GrBlendCoeff);
GR_STATIC_ASSERT(11 == kIConstC_GrBlendCoeff);
GR_STATIC_ASSERT(12 == kConstA_GrBlendCoeff);
GR_STATIC_ASSERT(13 == kIConstA_GrBlendCoeff);
GR_STATIC_ASSERT(14 == kS2C_GrBlendCoeff);
GR_STATIC_ASSERT(15 == kIS2C_GrBlendCoeff);
GR_STATIC_ASSERT(16 == kS2A_GrBlendCoeff);
GR_STATIC_ASSERT(17 == kIS2A_GrBlendCoeff);
SkASSERT((unsigned)coeff < kGrBlendCoeffCnt);
return gTable[coeff];
}
static MTLBlendOperation blend_equation_to_mtl_blend_op(GrBlendEquation equation) {
static const MTLBlendOperation gTable[] = {
MTLBlendOperationAdd, // kAdd_GrBlendEquation
MTLBlendOperationSubtract, // kSubtract_GrBlendEquation
MTLBlendOperationReverseSubtract, // kReverseSubtract_GrBlendEquation
};
GR_STATIC_ASSERT(SK_ARRAY_COUNT(gTable) == kFirstAdvancedGrBlendEquation);
GR_STATIC_ASSERT(0 == kAdd_GrBlendEquation);
GR_STATIC_ASSERT(1 == kSubtract_GrBlendEquation);
GR_STATIC_ASSERT(2 == kReverseSubtract_GrBlendEquation);
SkASSERT((unsigned)equation < kGrBlendEquationCnt);
return gTable[equation];
}
static MTLRenderPipelineColorAttachmentDescriptor* create_color_attachment(
GrPixelConfig config, const GrPipeline& pipeline) {
auto mtlColorAttachment = [[MTLRenderPipelineColorAttachmentDescriptor alloc] init];
// pixel format
MTLPixelFormat format;
SkAssertResult(GrPixelConfigToMTLFormat(config, &format));
mtlColorAttachment.pixelFormat = format;
// blending
GrXferProcessor::BlendInfo blendInfo;
pipeline.getXferProcessor().getBlendInfo(&blendInfo);
GrBlendEquation equation = blendInfo.fEquation;
GrBlendCoeff srcCoeff = blendInfo.fSrcBlend;
GrBlendCoeff dstCoeff = blendInfo.fDstBlend;
bool blendOff = (kAdd_GrBlendEquation == equation || kSubtract_GrBlendEquation == equation) &&
kOne_GrBlendCoeff == srcCoeff && kZero_GrBlendCoeff == dstCoeff;
mtlColorAttachment.blendingEnabled = !blendOff;
if (!blendOff) {
mtlColorAttachment.sourceRGBBlendFactor = blend_coeff_to_mtl_blend(srcCoeff);
mtlColorAttachment.destinationRGBBlendFactor = blend_coeff_to_mtl_blend(dstCoeff);
mtlColorAttachment.rgbBlendOperation = blend_equation_to_mtl_blend_op(equation);
mtlColorAttachment.sourceAlphaBlendFactor = blend_coeff_to_mtl_blend(srcCoeff);
mtlColorAttachment.destinationAlphaBlendFactor = blend_coeff_to_mtl_blend(dstCoeff);
mtlColorAttachment.alphaBlendOperation = blend_equation_to_mtl_blend_op(equation);
}
if (!blendInfo.fWriteColor) {
mtlColorAttachment.writeMask = MTLColorWriteMaskNone;
} else {
mtlColorAttachment.writeMask = MTLColorWriteMaskAll;
}
return mtlColorAttachment;
}
uint32_t buffer_size(uint32_t offset, uint32_t maxAlignment) {
// Metal expects the buffer to be padded at the end according to the alignment
// of the largest element in the buffer.
uint32_t offsetDiff = offset & maxAlignment;
if (offsetDiff != 0) {
offsetDiff = maxAlignment - offsetDiff + 1;
}
return offset + offsetDiff;
}
GrMtlPipelineState* GrMtlPipelineStateBuilder::finalize(const GrPrimitiveProcessor& primProc,
const GrPipeline& pipeline,
GrProgramDesc* desc) {
auto pipelineDescriptor = [[MTLRenderPipelineDescriptor alloc] init];
fVS.extensions().appendf("#extension GL_ARB_separate_shader_objects : enable\n");
fFS.extensions().appendf("#extension GL_ARB_separate_shader_objects : enable\n");
fVS.extensions().appendf("#extension GL_ARB_shading_language_420pack : enable\n");
fFS.extensions().appendf("#extension GL_ARB_shading_language_420pack : enable\n");
this->finalizeShaders();
SkSL::Program::Settings settings;
settings.fCaps = this->caps()->shaderCaps();
settings.fFlipY = this->origin() != kTopLeft_GrSurfaceOrigin;
settings.fSharpenTextures = fGpu->getContext()->priv().options().fSharpenMipmappedTextures;
SkASSERT(!this->fragColorIsInOut());
id<MTLLibrary> vertexLibrary = nil;
id<MTLLibrary> fragmentLibrary = nil;
vertexLibrary = this->createMtlShaderLibrary(fVS,
SkSL::Program::kVertex_Kind,
settings,
desc);
fragmentLibrary = this->createMtlShaderLibrary(fFS,
SkSL::Program::kFragment_Kind,
settings,
desc);
SkASSERT(!this->primitiveProcessor().willUseGeoShader());
SkASSERT(vertexLibrary);
SkASSERT(fragmentLibrary);
id<MTLFunction> vertexFunction = [vertexLibrary newFunctionWithName: @"vertexMain"];
id<MTLFunction> fragmentFunction = [fragmentLibrary newFunctionWithName: @"fragmentMain"];
pipelineDescriptor.vertexFunction = vertexFunction;
pipelineDescriptor.fragmentFunction = fragmentFunction;
pipelineDescriptor.vertexDescriptor = create_vertex_descriptor(primProc);
pipelineDescriptor.colorAttachments[0] = create_color_attachment(this->config(), pipeline);
SkASSERT(pipelineDescriptor.vertexFunction);
SkASSERT(pipelineDescriptor.fragmentFunction);
SkASSERT(pipelineDescriptor.vertexDescriptor);
SkASSERT(pipelineDescriptor.colorAttachments[0]);
NSError* error = nil;
id<MTLRenderPipelineState> pipelineState =
[fGpu->device() newRenderPipelineStateWithDescriptor: pipelineDescriptor
error: &error];
if (error) {
SkDebugf("Error creating pipeline: %s\n",
[[error localizedDescription] cStringUsingEncoding: NSASCIIStringEncoding]);
return nullptr;
}
uint32_t geomBufferSize = buffer_size(fUniformHandler.fCurrentGeometryUBOOffset,
fUniformHandler.fCurrentGeometryUBOMaxAlignment);
uint32_t fragBufferSize = buffer_size(fUniformHandler.fCurrentFragmentUBOOffset,
fUniformHandler.fCurrentFragmentUBOMaxAlignment);
return new GrMtlPipelineState(fGpu,
pipelineState,
pipelineDescriptor.colorAttachments[0].pixelFormat,
fUniformHandles,
fUniformHandler.fUniforms,
GrMtlBuffer::Make(fGpu,
geomBufferSize,
GrGpuBufferType::kVertex,
kStatic_GrAccessPattern),
GrMtlBuffer::Make(fGpu,
fragBufferSize,
GrGpuBufferType::kVertex,
kStatic_GrAccessPattern),
(uint32_t)fUniformHandler.numSamplers(),
std::move(fGeometryProcessor),
std::move(fXferProcessor),
std::move(fFragmentProcessors),
fFragmentProcessorCnt);
}