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// 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/metal/RenderPipelineMTL.h"
#include "dawn_native/CreatePipelineAsyncTask.h"
#include "dawn_native/VertexFormat.h"
#include "dawn_native/metal/DeviceMTL.h"
#include "dawn_native/metal/PipelineLayoutMTL.h"
#include "dawn_native/metal/ShaderModuleMTL.h"
#include "dawn_native/metal/TextureMTL.h"
#include "dawn_native/metal/UtilsMetal.h"
namespace dawn_native { namespace metal {
namespace {
MTLVertexFormat VertexFormatType(wgpu::VertexFormat format) {
switch (format) {
case wgpu::VertexFormat::Uint8x2:
return MTLVertexFormatUChar2;
case wgpu::VertexFormat::Uint8x4:
return MTLVertexFormatUChar4;
case wgpu::VertexFormat::Sint8x2:
return MTLVertexFormatChar2;
case wgpu::VertexFormat::Sint8x4:
return MTLVertexFormatChar4;
case wgpu::VertexFormat::Unorm8x2:
return MTLVertexFormatUChar2Normalized;
case wgpu::VertexFormat::Unorm8x4:
return MTLVertexFormatUChar4Normalized;
case wgpu::VertexFormat::Snorm8x2:
return MTLVertexFormatChar2Normalized;
case wgpu::VertexFormat::Snorm8x4:
return MTLVertexFormatChar4Normalized;
case wgpu::VertexFormat::Uint16x2:
return MTLVertexFormatUShort2;
case wgpu::VertexFormat::Uint16x4:
return MTLVertexFormatUShort4;
case wgpu::VertexFormat::Sint16x2:
return MTLVertexFormatShort2;
case wgpu::VertexFormat::Sint16x4:
return MTLVertexFormatShort4;
case wgpu::VertexFormat::Unorm16x2:
return MTLVertexFormatUShort2Normalized;
case wgpu::VertexFormat::Unorm16x4:
return MTLVertexFormatUShort4Normalized;
case wgpu::VertexFormat::Snorm16x2:
return MTLVertexFormatShort2Normalized;
case wgpu::VertexFormat::Snorm16x4:
return MTLVertexFormatShort4Normalized;
case wgpu::VertexFormat::Float16x2:
return MTLVertexFormatHalf2;
case wgpu::VertexFormat::Float16x4:
return MTLVertexFormatHalf4;
case wgpu::VertexFormat::Float32:
return MTLVertexFormatFloat;
case wgpu::VertexFormat::Float32x2:
return MTLVertexFormatFloat2;
case wgpu::VertexFormat::Float32x3:
return MTLVertexFormatFloat3;
case wgpu::VertexFormat::Float32x4:
return MTLVertexFormatFloat4;
case wgpu::VertexFormat::Uint32:
return MTLVertexFormatUInt;
case wgpu::VertexFormat::Uint32x2:
return MTLVertexFormatUInt2;
case wgpu::VertexFormat::Uint32x3:
return MTLVertexFormatUInt3;
case wgpu::VertexFormat::Uint32x4:
return MTLVertexFormatUInt4;
case wgpu::VertexFormat::Sint32:
return MTLVertexFormatInt;
case wgpu::VertexFormat::Sint32x2:
return MTLVertexFormatInt2;
case wgpu::VertexFormat::Sint32x3:
return MTLVertexFormatInt3;
case wgpu::VertexFormat::Sint32x4:
return MTLVertexFormatInt4;
default:
UNREACHABLE();
}
}
MTLVertexStepFunction VertexStepModeFunction(wgpu::VertexStepMode mode) {
switch (mode) {
case wgpu::VertexStepMode::Vertex:
return MTLVertexStepFunctionPerVertex;
case wgpu::VertexStepMode::Instance:
return MTLVertexStepFunctionPerInstance;
}
}
MTLPrimitiveType MTLPrimitiveTopology(wgpu::PrimitiveTopology primitiveTopology) {
switch (primitiveTopology) {
case wgpu::PrimitiveTopology::PointList:
return MTLPrimitiveTypePoint;
case wgpu::PrimitiveTopology::LineList:
return MTLPrimitiveTypeLine;
case wgpu::PrimitiveTopology::LineStrip:
return MTLPrimitiveTypeLineStrip;
case wgpu::PrimitiveTopology::TriangleList:
return MTLPrimitiveTypeTriangle;
case wgpu::PrimitiveTopology::TriangleStrip:
return MTLPrimitiveTypeTriangleStrip;
}
}
MTLPrimitiveTopologyClass MTLInputPrimitiveTopology(
wgpu::PrimitiveTopology primitiveTopology) {
switch (primitiveTopology) {
case wgpu::PrimitiveTopology::PointList:
return MTLPrimitiveTopologyClassPoint;
case wgpu::PrimitiveTopology::LineList:
case wgpu::PrimitiveTopology::LineStrip:
return MTLPrimitiveTopologyClassLine;
case wgpu::PrimitiveTopology::TriangleList:
case wgpu::PrimitiveTopology::TriangleStrip:
return MTLPrimitiveTopologyClassTriangle;
}
}
MTLBlendFactor MetalBlendFactor(wgpu::BlendFactor factor, bool alpha) {
switch (factor) {
case wgpu::BlendFactor::Zero:
return MTLBlendFactorZero;
case wgpu::BlendFactor::One:
return MTLBlendFactorOne;
case wgpu::BlendFactor::Src:
return MTLBlendFactorSourceColor;
case wgpu::BlendFactor::OneMinusSrc:
return MTLBlendFactorOneMinusSourceColor;
case wgpu::BlendFactor::SrcAlpha:
return MTLBlendFactorSourceAlpha;
case wgpu::BlendFactor::OneMinusSrcAlpha:
return MTLBlendFactorOneMinusSourceAlpha;
case wgpu::BlendFactor::Dst:
return MTLBlendFactorDestinationColor;
case wgpu::BlendFactor::OneMinusDst:
return MTLBlendFactorOneMinusDestinationColor;
case wgpu::BlendFactor::DstAlpha:
return MTLBlendFactorDestinationAlpha;
case wgpu::BlendFactor::OneMinusDstAlpha:
return MTLBlendFactorOneMinusDestinationAlpha;
case wgpu::BlendFactor::SrcAlphaSaturated:
return MTLBlendFactorSourceAlphaSaturated;
case wgpu::BlendFactor::Constant:
return alpha ? MTLBlendFactorBlendAlpha : MTLBlendFactorBlendColor;
case wgpu::BlendFactor::OneMinusConstant:
return alpha ? MTLBlendFactorOneMinusBlendAlpha
: MTLBlendFactorOneMinusBlendColor;
}
}
MTLBlendOperation MetalBlendOperation(wgpu::BlendOperation operation) {
switch (operation) {
case wgpu::BlendOperation::Add:
return MTLBlendOperationAdd;
case wgpu::BlendOperation::Subtract:
return MTLBlendOperationSubtract;
case wgpu::BlendOperation::ReverseSubtract:
return MTLBlendOperationReverseSubtract;
case wgpu::BlendOperation::Min:
return MTLBlendOperationMin;
case wgpu::BlendOperation::Max:
return MTLBlendOperationMax;
}
}
MTLColorWriteMask MetalColorWriteMask(wgpu::ColorWriteMask writeMask,
bool isDeclaredInFragmentShader) {
if (!isDeclaredInFragmentShader) {
return MTLColorWriteMaskNone;
}
MTLColorWriteMask mask = MTLColorWriteMaskNone;
if (writeMask & wgpu::ColorWriteMask::Red) {
mask |= MTLColorWriteMaskRed;
}
if (writeMask & wgpu::ColorWriteMask::Green) {
mask |= MTLColorWriteMaskGreen;
}
if (writeMask & wgpu::ColorWriteMask::Blue) {
mask |= MTLColorWriteMaskBlue;
}
if (writeMask & wgpu::ColorWriteMask::Alpha) {
mask |= MTLColorWriteMaskAlpha;
}
return mask;
}
void ComputeBlendDesc(MTLRenderPipelineColorAttachmentDescriptor* attachment,
const ColorTargetState* state,
bool isDeclaredInFragmentShader) {
attachment.blendingEnabled = state->blend != nullptr;
if (attachment.blendingEnabled) {
attachment.sourceRGBBlendFactor =
MetalBlendFactor(state->blend->color.srcFactor, false);
attachment.destinationRGBBlendFactor =
MetalBlendFactor(state->blend->color.dstFactor, false);
attachment.rgbBlendOperation = MetalBlendOperation(state->blend->color.operation);
attachment.sourceAlphaBlendFactor =
MetalBlendFactor(state->blend->alpha.srcFactor, true);
attachment.destinationAlphaBlendFactor =
MetalBlendFactor(state->blend->alpha.dstFactor, true);
attachment.alphaBlendOperation = MetalBlendOperation(state->blend->alpha.operation);
}
attachment.writeMask =
MetalColorWriteMask(state->writeMask, isDeclaredInFragmentShader);
}
MTLStencilOperation MetalStencilOperation(wgpu::StencilOperation stencilOperation) {
switch (stencilOperation) {
case wgpu::StencilOperation::Keep:
return MTLStencilOperationKeep;
case wgpu::StencilOperation::Zero:
return MTLStencilOperationZero;
case wgpu::StencilOperation::Replace:
return MTLStencilOperationReplace;
case wgpu::StencilOperation::Invert:
return MTLStencilOperationInvert;
case wgpu::StencilOperation::IncrementClamp:
return MTLStencilOperationIncrementClamp;
case wgpu::StencilOperation::DecrementClamp:
return MTLStencilOperationDecrementClamp;
case wgpu::StencilOperation::IncrementWrap:
return MTLStencilOperationIncrementWrap;
case wgpu::StencilOperation::DecrementWrap:
return MTLStencilOperationDecrementWrap;
}
}
NSRef<MTLDepthStencilDescriptor> MakeDepthStencilDesc(const DepthStencilState* descriptor) {
NSRef<MTLDepthStencilDescriptor> mtlDepthStencilDescRef =
AcquireNSRef([MTLDepthStencilDescriptor new]);
MTLDepthStencilDescriptor* mtlDepthStencilDescriptor = mtlDepthStencilDescRef.Get();
mtlDepthStencilDescriptor.depthCompareFunction =
ToMetalCompareFunction(descriptor->depthCompare);
mtlDepthStencilDescriptor.depthWriteEnabled = descriptor->depthWriteEnabled;
if (StencilTestEnabled(descriptor)) {
NSRef<MTLStencilDescriptor> backFaceStencilRef =
AcquireNSRef([MTLStencilDescriptor new]);
MTLStencilDescriptor* backFaceStencil = backFaceStencilRef.Get();
NSRef<MTLStencilDescriptor> frontFaceStencilRef =
AcquireNSRef([MTLStencilDescriptor new]);
MTLStencilDescriptor* frontFaceStencil = frontFaceStencilRef.Get();
backFaceStencil.stencilCompareFunction =
ToMetalCompareFunction(descriptor->stencilBack.compare);
backFaceStencil.stencilFailureOperation =
MetalStencilOperation(descriptor->stencilBack.failOp);
backFaceStencil.depthFailureOperation =
MetalStencilOperation(descriptor->stencilBack.depthFailOp);
backFaceStencil.depthStencilPassOperation =
MetalStencilOperation(descriptor->stencilBack.passOp);
backFaceStencil.readMask = descriptor->stencilReadMask;
backFaceStencil.writeMask = descriptor->stencilWriteMask;
frontFaceStencil.stencilCompareFunction =
ToMetalCompareFunction(descriptor->stencilFront.compare);
frontFaceStencil.stencilFailureOperation =
MetalStencilOperation(descriptor->stencilFront.failOp);
frontFaceStencil.depthFailureOperation =
MetalStencilOperation(descriptor->stencilFront.depthFailOp);
frontFaceStencil.depthStencilPassOperation =
MetalStencilOperation(descriptor->stencilFront.passOp);
frontFaceStencil.readMask = descriptor->stencilReadMask;
frontFaceStencil.writeMask = descriptor->stencilWriteMask;
mtlDepthStencilDescriptor.backFaceStencil = backFaceStencil;
mtlDepthStencilDescriptor.frontFaceStencil = frontFaceStencil;
}
return mtlDepthStencilDescRef;
}
MTLWinding MTLFrontFace(wgpu::FrontFace face) {
switch (face) {
case wgpu::FrontFace::CW:
return MTLWindingClockwise;
case wgpu::FrontFace::CCW:
return MTLWindingCounterClockwise;
}
}
MTLCullMode ToMTLCullMode(wgpu::CullMode mode) {
switch (mode) {
case wgpu::CullMode::None:
return MTLCullModeNone;
case wgpu::CullMode::Front:
return MTLCullModeFront;
case wgpu::CullMode::Back:
return MTLCullModeBack;
}
}
} // anonymous namespace
// static
ResultOrError<Ref<RenderPipeline>> RenderPipeline::Create(
Device* device,
const RenderPipelineDescriptor* descriptor) {
Ref<RenderPipeline> pipeline = AcquireRef(new RenderPipeline(device, descriptor));
DAWN_TRY(pipeline->Initialize());
return pipeline;
}
MaybeError RenderPipeline::Initialize() {
mMtlPrimitiveTopology = MTLPrimitiveTopology(GetPrimitiveTopology());
mMtlFrontFace = MTLFrontFace(GetFrontFace());
mMtlCullMode = ToMTLCullMode(GetCullMode());
auto mtlDevice = ToBackend(GetDevice())->GetMTLDevice();
NSRef<MTLRenderPipelineDescriptor> descriptorMTLRef =
AcquireNSRef([MTLRenderPipelineDescriptor new]);
MTLRenderPipelineDescriptor* descriptorMTL = descriptorMTLRef.Get();
// TODO: MakeVertexDesc should be const in the future, so we don't need to call it here when
// vertex pulling is enabled
NSRef<MTLVertexDescriptor> vertexDesc = MakeVertexDesc();
// Calling MakeVertexDesc first is important since it sets indices for packed bindings
if (GetDevice()->IsToggleEnabled(Toggle::MetalEnableVertexPulling)) {
vertexDesc = AcquireNSRef([MTLVertexDescriptor new]);
}
descriptorMTL.vertexDescriptor = vertexDesc.Get();
const PerStage<ProgrammableStage>& allStages = GetAllStages();
const ProgrammableStage& vertexStage = allStages[wgpu::ShaderStage::Vertex];
ShaderModule* vertexModule = ToBackend(vertexStage.module).Get();
const char* vertexEntryPoint = vertexStage.entryPoint.c_str();
ShaderModule::MetalFunctionData vertexData;
DAWN_TRY(vertexModule->CreateFunction(vertexEntryPoint, SingleShaderStage::Vertex,
ToBackend(GetLayout()), &vertexData, 0xFFFFFFFF,
this));
descriptorMTL.vertexFunction = vertexData.function.Get();
if (vertexData.needsStorageBufferLength) {
mStagesRequiringStorageBufferLength |= wgpu::ShaderStage::Vertex;
}
if (GetStageMask() & wgpu::ShaderStage::Fragment) {
const ProgrammableStage& fragmentStage = allStages[wgpu::ShaderStage::Fragment];
ShaderModule* fragmentModule = ToBackend(fragmentStage.module).Get();
const char* fragmentEntryPoint = fragmentStage.entryPoint.c_str();
ShaderModule::MetalFunctionData fragmentData;
DAWN_TRY(fragmentModule->CreateFunction(fragmentEntryPoint, SingleShaderStage::Fragment,
ToBackend(GetLayout()), &fragmentData,
GetSampleMask()));
descriptorMTL.fragmentFunction = fragmentData.function.Get();
if (fragmentData.needsStorageBufferLength) {
mStagesRequiringStorageBufferLength |= wgpu::ShaderStage::Fragment;
}
const auto& fragmentOutputsWritten = fragmentStage.metadata->fragmentOutputsWritten;
for (ColorAttachmentIndex i : IterateBitSet(GetColorAttachmentsMask())) {
descriptorMTL.colorAttachments[static_cast<uint8_t>(i)].pixelFormat =
MetalPixelFormat(GetColorAttachmentFormat(i));
const ColorTargetState* descriptor = GetColorTargetState(i);
ComputeBlendDesc(descriptorMTL.colorAttachments[static_cast<uint8_t>(i)],
descriptor, fragmentOutputsWritten[i]);
}
}
if (HasDepthStencilAttachment()) {
wgpu::TextureFormat depthStencilFormat = GetDepthStencilFormat();
const Format& internalFormat = GetDevice()->GetValidInternalFormat(depthStencilFormat);
MTLPixelFormat metalFormat = MetalPixelFormat(depthStencilFormat);
if (internalFormat.HasDepth()) {
descriptorMTL.depthAttachmentPixelFormat = metalFormat;
}
if (internalFormat.HasStencil()) {
descriptorMTL.stencilAttachmentPixelFormat = metalFormat;
}
}
descriptorMTL.inputPrimitiveTopology = MTLInputPrimitiveTopology(GetPrimitiveTopology());
descriptorMTL.sampleCount = GetSampleCount();
descriptorMTL.alphaToCoverageEnabled = IsAlphaToCoverageEnabled();
NSError* error = nullptr;
mMtlRenderPipelineState =
AcquireNSPRef([mtlDevice newRenderPipelineStateWithDescriptor:descriptorMTL
error:&error]);
if (error != nullptr) {
return DAWN_INTERNAL_ERROR(std::string("Error creating pipeline state") +
[error.localizedDescription UTF8String]);
}
ASSERT(mMtlRenderPipelineState != nil);
// Create depth stencil state and cache it, fetch the cached depth stencil state when we
// call setDepthStencilState() for a given render pipeline in CommandEncoder, in order
// to improve performance.
NSRef<MTLDepthStencilDescriptor> depthStencilDesc =
MakeDepthStencilDesc(GetDepthStencilState());
mMtlDepthStencilState =
AcquireNSPRef([mtlDevice newDepthStencilStateWithDescriptor:depthStencilDesc.Get()]);
return {};
}
MTLPrimitiveType RenderPipeline::GetMTLPrimitiveTopology() const {
return mMtlPrimitiveTopology;
}
MTLWinding RenderPipeline::GetMTLFrontFace() const {
return mMtlFrontFace;
}
MTLCullMode RenderPipeline::GetMTLCullMode() const {
return mMtlCullMode;
}
void RenderPipeline::Encode(id<MTLRenderCommandEncoder> encoder) {
[encoder setRenderPipelineState:mMtlRenderPipelineState.Get()];
}
id<MTLDepthStencilState> RenderPipeline::GetMTLDepthStencilState() {
return mMtlDepthStencilState.Get();
}
uint32_t RenderPipeline::GetMtlVertexBufferIndex(VertexBufferSlot slot) const {
ASSERT(slot < kMaxVertexBuffersTyped);
return mMtlVertexBufferIndices[slot];
}
wgpu::ShaderStage RenderPipeline::GetStagesRequiringStorageBufferLength() const {
return mStagesRequiringStorageBufferLength;
}
MTLVertexDescriptor* RenderPipeline::MakeVertexDesc() {
MTLVertexDescriptor* mtlVertexDescriptor = [MTLVertexDescriptor new];
// Vertex buffers are packed after all the buffers for the bind groups.
uint32_t mtlVertexBufferIndex =
ToBackend(GetLayout())->GetBufferBindingCount(SingleShaderStage::Vertex);
for (VertexBufferSlot slot : IterateBitSet(GetVertexBufferSlotsUsed())) {
const VertexBufferInfo& info = GetVertexBuffer(slot);
MTLVertexBufferLayoutDescriptor* layoutDesc = [MTLVertexBufferLayoutDescriptor new];
if (info.arrayStride == 0) {
// For MTLVertexStepFunctionConstant, the stepRate must be 0,
// but the arrayStride must NOT be 0, so we made up it with
// max(attrib.offset + sizeof(attrib) for each attrib)
size_t maxArrayStride = 0;
for (VertexAttributeLocation loc : IterateBitSet(GetAttributeLocationsUsed())) {
const VertexAttributeInfo& attrib = GetAttribute(loc);
// Only use the attributes that use the current input
if (attrib.vertexBufferSlot != slot) {
continue;
}
maxArrayStride =
std::max(maxArrayStride, GetVertexFormatInfo(attrib.format).byteSize +
size_t(attrib.offset));
}
layoutDesc.stepFunction = MTLVertexStepFunctionConstant;
layoutDesc.stepRate = 0;
// Metal requires the stride must be a multiple of 4 bytes, align it with next
// multiple of 4 if it's not.
layoutDesc.stride = Align(maxArrayStride, 4);
} else {
layoutDesc.stepFunction = VertexStepModeFunction(info.stepMode);
layoutDesc.stepRate = 1;
layoutDesc.stride = info.arrayStride;
}
mtlVertexDescriptor.layouts[mtlVertexBufferIndex] = layoutDesc;
[layoutDesc release];
mMtlVertexBufferIndices[slot] = mtlVertexBufferIndex;
mtlVertexBufferIndex++;
}
for (VertexAttributeLocation loc : IterateBitSet(GetAttributeLocationsUsed())) {
const VertexAttributeInfo& info = GetAttribute(loc);
auto attribDesc = [MTLVertexAttributeDescriptor new];
attribDesc.format = VertexFormatType(info.format);
attribDesc.offset = info.offset;
attribDesc.bufferIndex = mMtlVertexBufferIndices[info.vertexBufferSlot];
mtlVertexDescriptor.attributes[static_cast<uint8_t>(loc)] = attribDesc;
[attribDesc release];
}
return mtlVertexDescriptor;
}
void RenderPipeline::CreateAsync(Device* device,
const RenderPipelineDescriptor* descriptor,
size_t blueprintHash,
WGPUCreateRenderPipelineAsyncCallback callback,
void* userdata) {
Ref<RenderPipeline> pipeline = AcquireRef(new RenderPipeline(device, descriptor));
std::unique_ptr<CreateRenderPipelineAsyncTask> asyncTask =
std::make_unique<CreateRenderPipelineAsyncTask>(pipeline, blueprintHash, callback,
userdata);
CreateRenderPipelineAsyncTask::RunAsync(std::move(asyncTask));
}
}} // namespace dawn_native::metal