kc3-lang/angle/src/compiler/translator/tree_util/DriverUniform.cpp

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• Hash : 47c66901
  Author :
  Date : 2024-10-21T12:47:22
  

  Vulkan: Set gl_Layer to 0 if the framebuffer is not layered
  
  Bug: angleproject:372390039
  Change-Id: I29067c9488e06f6dd2e90f207fecb843267fb77c
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/5949263
  Reviewed-by: Charlie Lao <cclao@google.com>
  Reviewed-by: Yuxin Hu <yuxinhu@google.com>
  Commit-Queue: Shahbaz Youssefi <syoussefi@chromium.org>
  

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• src/compiler/translator/tree_util/DriverUniform.cpp

• //
  // Copyright 2020 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.
  //
  // DriverUniform.cpp: Add code to support driver uniforms
  //
  
  #include "compiler/translator/tree_util/DriverUniform.h"
  
  #include "compiler/translator/Compiler.h"
  #include "compiler/translator/IntermNode.h"
  #include "compiler/translator/StaticType.h"
  #include "compiler/translator/SymbolTable.h"
  #include "compiler/translator/tree_util/FindMain.h"
  #include "compiler/translator/tree_util/IntermNode_util.h"
  #include "compiler/translator/tree_util/IntermTraverse.h"
  #include "compiler/translator/util.h"
  
  namespace sh
  {
  
  namespace
  {
  constexpr ImmutableString kEmulatedDepthRangeParams = ImmutableString("ANGLEDepthRangeParams");
  constexpr ImmutableString kDriverUniformsBlockName  = ImmutableString("ANGLEUniformBlock");
  constexpr ImmutableString kDriverUniformsVarName    = ImmutableString("ANGLEUniforms");
  
  constexpr const char kAcbBufferOffsets[] = "acbBufferOffsets";
  constexpr const char kDepthRange[]       = "depthRange";
  constexpr const char kRenderArea[]       = "renderArea";
  constexpr const char kFlipXY[]           = "flipXY";
  constexpr const char kDither[]           = "dither";
  constexpr const char kMisc[]             = "misc";
  
  // Extended uniforms
  constexpr const char kXfbBufferOffsets[]       = "xfbBufferOffsets";
  constexpr const char kXfbVerticesPerInstance[] = "xfbVerticesPerInstance";
  constexpr const char kUnused[]                 = "unused";
  constexpr const char kUnused2[]                = "unused2";
  }  // anonymous namespace
  
  // Class DriverUniform
  bool DriverUniform::addComputeDriverUniformsToShader(TIntermBlock *root, TSymbolTable *symbolTable)
  {
      constexpr size_t kNumComputeDriverUniforms                                               = 1;
      constexpr std::array<const char *, kNumComputeDriverUniforms> kComputeDriverUniformNames = {
          {kAcbBufferOffsets}};
  
      ASSERT(!mDriverUniforms);
      // This field list mirrors the structure of ComputeDriverUniforms in ContextVk.cpp.
      TFieldList *driverFieldList = new TFieldList;
  
      const std::array<TType *, kNumComputeDriverUniforms> kDriverUniformTypes = {{
          new TType(EbtUInt, EbpHigh, EvqGlobal, 4),
      }};
  
      for (size_t uniformIndex = 0; uniformIndex < kNumComputeDriverUniforms; ++uniformIndex)
      {
          TField *driverUniformField =
              new TField(kDriverUniformTypes[uniformIndex],
                         ImmutableString(kComputeDriverUniformNames[uniformIndex]), TSourceLoc(),
                         SymbolType::AngleInternal);
          driverFieldList->push_back(driverUniformField);
      }
  
      // Define a driver uniform block "ANGLEUniformBlock" with instance name "ANGLEUniforms".
      TLayoutQualifier layoutQualifier = TLayoutQualifier::Create();
      layoutQualifier.blockStorage     = EbsStd140;
      layoutQualifier.pushConstant     = true;
  
      mDriverUniforms = DeclareInterfaceBlock(root, symbolTable, driverFieldList, EvqUniform,
                                              layoutQualifier, TMemoryQualifier::Create(), 0,
                                              kDriverUniformsBlockName, kDriverUniformsVarName);
      return mDriverUniforms != nullptr;
  }
  
  TFieldList *DriverUniform::createUniformFields(TSymbolTable *symbolTable)
  {
      constexpr size_t kNumGraphicsDriverUniforms                                                = 6;
      constexpr std::array<const char *, kNumGraphicsDriverUniforms> kGraphicsDriverUniformNames = {{
          kAcbBufferOffsets,
          kDepthRange,
          kRenderArea,
          kFlipXY,
          kDither,
          kMisc,
      }};
  
      // This field list mirrors the structure of GraphicsDriverUniforms in ContextVk.cpp.
      TFieldList *driverFieldList = new TFieldList;
  
      const std::array<TType *, kNumGraphicsDriverUniforms> kDriverUniformTypes = {{
          // acbBufferOffsets: Packed ubyte8
          new TType(EbtUInt, EbpHigh, EvqGlobal, 2),
          // depthRange: Near and far depth
          new TType(EbtFloat, EbpHigh, EvqGlobal, 2),
          // renderArea: Packed ushort2
          new TType(EbtUInt, EbpHigh, EvqGlobal),
          // flipXY: Packed snorm4
          new TType(EbtUInt, EbpHigh, EvqGlobal),
          // dither: ushort
          new TType(EbtUInt, EbpHigh, EvqGlobal),
          // misc: Various bits of state
          new TType(EbtUInt, EbpHigh, EvqGlobal),
      }};
  
      for (size_t uniformIndex = 0; uniformIndex < kNumGraphicsDriverUniforms; ++uniformIndex)
      {
          TField *driverUniformField =
              new TField(kDriverUniformTypes[uniformIndex],
                         ImmutableString(kGraphicsDriverUniformNames[uniformIndex]), TSourceLoc(),
                         SymbolType::AngleInternal);
          driverFieldList->push_back(driverUniformField);
      }
  
      return driverFieldList;
  }
  
  const TType *DriverUniform::createEmulatedDepthRangeType(TSymbolTable *symbolTable)
  {
      // If already defined, return it immediately.
      if (mEmulatedDepthRangeType != nullptr)
      {
          return mEmulatedDepthRangeType;
      }
  
      // Create the depth range type.
      TFieldList *depthRangeParamsFields = new TFieldList();
      TType *floatType                   = new TType(EbtFloat, EbpHigh, EvqGlobal, 1, 1);
      depthRangeParamsFields->push_back(
          new TField(floatType, ImmutableString("near"), TSourceLoc(), SymbolType::AngleInternal));
      depthRangeParamsFields->push_back(
          new TField(floatType, ImmutableString("far"), TSourceLoc(), SymbolType::AngleInternal));
      depthRangeParamsFields->push_back(
          new TField(floatType, ImmutableString("diff"), TSourceLoc(), SymbolType::AngleInternal));
  
      TStructure *emulatedDepthRangeParams = new TStructure(
          symbolTable, kEmulatedDepthRangeParams, depthRangeParamsFields, SymbolType::AngleInternal);
  
      mEmulatedDepthRangeType = new TType(emulatedDepthRangeParams, false);
  
      return mEmulatedDepthRangeType;
  }
  
  // The Add*DriverUniformsToShader operation adds an internal uniform block to a shader. The driver
  // block is used to implement Vulkan-specific features and workarounds. Returns the driver uniforms
  // variable.
  //
  // There are Graphics and Compute variations as they require different uniforms.
  bool DriverUniform::addGraphicsDriverUniformsToShader(TIntermBlock *root, TSymbolTable *symbolTable)
  {
      ASSERT(!mDriverUniforms);
  
      // Declare the depth range struct type.
      const TType *emulatedDepthRangeType     = createEmulatedDepthRangeType(symbolTable);
      const TType *emulatedDepthRangeDeclType = new TType(emulatedDepthRangeType->getStruct(), true);
  
      const TVariable *depthRangeVar =
          new TVariable(symbolTable->nextUniqueId(), kEmptyImmutableString, SymbolType::Empty,
                        TExtension::UNDEFINED, emulatedDepthRangeDeclType);
  
      DeclareGlobalVariable(root, depthRangeVar);
  
      TFieldList *driverFieldList = createUniformFields(symbolTable);
      if (mMode == DriverUniformMode::InterfaceBlock)
      {
          // Define a driver uniform block "ANGLEUniformBlock" with instance name "ANGLEUniforms".
          TLayoutQualifier layoutQualifier = TLayoutQualifier::Create();
          layoutQualifier.blockStorage     = EbsStd140;
          layoutQualifier.pushConstant     = true;
  
          mDriverUniforms = DeclareInterfaceBlock(root, symbolTable, driverFieldList, EvqUniform,
                                                  layoutQualifier, TMemoryQualifier::Create(), 0,
                                                  kDriverUniformsBlockName, kDriverUniformsVarName);
      }
      else
      {
          // Declare a structure "ANGLEUniformBlock" with instance name "ANGLE_angleUniforms".
          // This code path is taken only by the direct-to-Metal backend, and the assumptions
          // about the naming conventions of ANGLE-internal variables run too deeply to rename
          // this one.
          auto varName = ImmutableString("ANGLE_angleUniforms");
          auto result =
              DeclareStructure(root, symbolTable, driverFieldList, EvqUniform,
                               TMemoryQualifier::Create(), 0, kDriverUniformsBlockName, &varName);
          mDriverUniforms = result.second;
      }
  
      return mDriverUniforms != nullptr;
  }
  
  TIntermTyped *DriverUniform::createDriverUniformRef(const char *fieldName) const
  {
      size_t fieldIndex = 0;
      if (mMode == DriverUniformMode::InterfaceBlock)
      {
          fieldIndex =
              FindFieldIndex(mDriverUniforms->getType().getInterfaceBlock()->fields(), fieldName);
      }
      else
      {
          fieldIndex = FindFieldIndex(mDriverUniforms->getType().getStruct()->fields(), fieldName);
      }
  
      TIntermSymbol *angleUniformsRef = new TIntermSymbol(mDriverUniforms);
      TConstantUnion *uniformIndex    = new TConstantUnion;
      uniformIndex->setIConst(static_cast<int>(fieldIndex));
      TIntermConstantUnion *indexRef =
          new TIntermConstantUnion(uniformIndex, *StaticType::GetBasic<EbtInt, EbpLow>());
      if (mMode == DriverUniformMode::InterfaceBlock)
      {
          return new TIntermBinary(EOpIndexDirectInterfaceBlock, angleUniformsRef, indexRef);
      }
      return new TIntermBinary(EOpIndexDirectStruct, angleUniformsRef, indexRef);
  }
  
  TIntermTyped *DriverUniform::getAcbBufferOffsets() const
  {
      return createDriverUniformRef(kAcbBufferOffsets);
  }
  
  TIntermTyped *DriverUniform::getDepthRange() const
  {
      ASSERT(mEmulatedDepthRangeType != nullptr);
  
      TIntermTyped *depthRangeRef = createDriverUniformRef(kDepthRange);
      TIntermTyped *nearRef       = new TIntermSwizzle(depthRangeRef, {0});
      TIntermTyped *farRef        = new TIntermSwizzle(depthRangeRef->deepCopy(), {1});
      TIntermTyped *diff          = new TIntermBinary(EOpSub, farRef, nearRef);
  
      TIntermSequence args = {
          nearRef->deepCopy(),
          farRef->deepCopy(),
          diff,
      };
  
      return TIntermAggregate::CreateConstructor(*mEmulatedDepthRangeType, &args);
  }
  
  TIntermTyped *DriverUniform::getViewportZScale() const
  {
      ASSERT(mEmulatedDepthRangeType != nullptr);
  
      TIntermTyped *depthRangeRef = createDriverUniformRef(kDepthRange);
      TIntermTyped *nearRef       = new TIntermSwizzle(depthRangeRef, {0});
      TIntermTyped *farRef        = new TIntermSwizzle(depthRangeRef->deepCopy(), {1});
  
      TIntermTyped *isNegative = new TIntermBinary(EOpLessThan, farRef, nearRef);
  
      return new TIntermTernary(isNegative, CreateFloatNode(-1, EbpMedium),
                                CreateFloatNode(1, EbpMedium));
  }
  
  TIntermTyped *DriverUniform::getHalfRenderArea() const
  {
      TIntermTyped *renderAreaRef = createDriverUniformRef(kRenderArea);
      TIntermTyped *width = new TIntermBinary(EOpBitwiseAnd, renderAreaRef, CreateUIntNode(0xFFFF));
      TIntermTyped *height =
          new TIntermBinary(EOpBitShiftRight, renderAreaRef->deepCopy(), CreateUIntNode(16));
  
      TIntermSequence widthArgs = {
          width,
      };
      TIntermTyped *widthAsFloat =
          TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtFloat, EbpHigh>(), &widthArgs);
  
      TIntermSequence heightArgs = {
          height,
      };
      TIntermTyped *heightAsFloat = TIntermAggregate::CreateConstructor(
          *StaticType::GetBasic<EbtFloat, EbpHigh>(), &heightArgs);
  
      TIntermSequence args = {
          widthAsFloat,
          heightAsFloat,
      };
  
      TIntermTyped *renderArea =
          TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtFloat, EbpHigh, 2>(), &args);
      return new TIntermBinary(EOpVectorTimesScalar, renderArea, CreateFloatNode(0.5, EbpMedium));
  }
  
  TIntermTyped *DriverUniform::getFlipXY(TSymbolTable *symbolTable, DriverUniformFlip stage) const
  {
      TIntermTyped *flipXY = createDriverUniformRef(kFlipXY);
      TIntermTyped *values =
          CreateBuiltInUnaryFunctionCallNode("unpackSnorm4x8", flipXY, *symbolTable, 310);
  
      if (stage == DriverUniformFlip::Fragment)
      {
          return new TIntermSwizzle(values, {0, 1});
      }
  
      return new TIntermSwizzle(values, {2, 3});
  }
  
  TIntermTyped *DriverUniform::getNegFlipXY(TSymbolTable *symbolTable, DriverUniformFlip stage) const
  {
      TIntermTyped *flipXY = getFlipXY(symbolTable, stage);
  
      constexpr std::array<float, 2> kMultiplier = {1, -1};
      return new TIntermBinary(EOpMul, flipXY, CreateVecNode(kMultiplier.data(), 2, EbpLow));
  }
  
  TIntermTyped *DriverUniform::getDither() const
  {
      return createDriverUniformRef(kDither);
  }
  
  TIntermTyped *DriverUniform::getSwapXY() const
  {
      TIntermTyped *miscRef = createDriverUniformRef(kMisc);
      TIntermTyped *swapXY  = new TIntermBinary(EOpBitwiseAnd, miscRef,
                                                CreateUIntNode(vk::kDriverUniformsMiscSwapXYMask));
  
      TIntermSequence args = {
          swapXY,
      };
      return TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtBool, EbpUndefined>(),
                                                 &args);
  }
  
  TIntermTyped *DriverUniform::getAdvancedBlendEquation() const
  {
      TIntermTyped *miscRef = createDriverUniformRef(kMisc);
      TIntermTyped *equation =
          new TIntermBinary(EOpBitShiftRight, miscRef,
                            CreateUIntNode(vk::kDriverUniformsMiscAdvancedBlendEquationOffset));
      equation = new TIntermBinary(EOpBitwiseAnd, equation,
                                   CreateUIntNode(vk::kDriverUniformsMiscAdvancedBlendEquationMask));
  
      return equation;
  }
  
  TIntermTyped *DriverUniform::getNumSamples() const
  {
      TIntermTyped *miscRef     = createDriverUniformRef(kMisc);
      TIntermTyped *sampleCount = new TIntermBinary(
          EOpBitShiftRight, miscRef, CreateUIntNode(vk::kDriverUniformsMiscSampleCountOffset));
      sampleCount = new TIntermBinary(EOpBitwiseAnd, sampleCount,
                                      CreateUIntNode(vk::kDriverUniformsMiscSampleCountMask));
  
      return sampleCount;
  }
  
  TIntermTyped *DriverUniform::getClipDistancesEnabled() const
  {
      TIntermTyped *miscRef     = createDriverUniformRef(kMisc);
      TIntermTyped *enabledMask = new TIntermBinary(
          EOpBitShiftRight, miscRef, CreateUIntNode(vk::kDriverUniformsMiscEnabledClipPlanesOffset));
      enabledMask = new TIntermBinary(EOpBitwiseAnd, enabledMask,
                                      CreateUIntNode(vk::kDriverUniformsMiscEnabledClipPlanesMask));
  
      return enabledMask;
  }
  
  TIntermTyped *DriverUniform::getTransformDepth() const
  {
      TIntermTyped *miscRef        = createDriverUniformRef(kMisc);
      TIntermTyped *transformDepth = new TIntermBinary(
          EOpBitShiftRight, miscRef, CreateUIntNode(vk::kDriverUniformsMiscTransformDepthOffset));
      transformDepth = new TIntermBinary(EOpBitwiseAnd, transformDepth,
                                         CreateUIntNode(vk::kDriverUniformsMiscTransformDepthMask));
  
      TIntermSequence args = {
          transformDepth,
      };
      return TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtBool, EbpUndefined>(),
                                                 &args);
  }
  
  TIntermTyped *DriverUniform::getAlphaToCoverage() const
  {
      TIntermTyped *miscRef         = createDriverUniformRef(kMisc);
      TIntermTyped *alphaToCoverage = new TIntermBinary(
          EOpBitShiftRight, miscRef, CreateUIntNode(vk::kDriverUniformsMiscAlphaToCoverageOffset));
      alphaToCoverage = new TIntermBinary(EOpBitwiseAnd, alphaToCoverage,
                                          CreateUIntNode(vk::kDriverUniformsMiscAlphaToCoverageMask));
  
      TIntermSequence args = {
          alphaToCoverage,
      };
      return TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtBool, EbpUndefined>(),
                                                 &args);
  }
  
  TIntermTyped *DriverUniform::getLayeredFramebuffer() const
  {
      TIntermTyped *miscRef            = createDriverUniformRef(kMisc);
      TIntermTyped *layeredFramebuffer = new TIntermBinary(
          EOpBitShiftRight, miscRef, CreateUIntNode(vk::kDriverUniformsMiscLayeredFramebufferOffset));
      layeredFramebuffer =
          new TIntermBinary(EOpBitwiseAnd, layeredFramebuffer,
                            CreateUIntNode(vk::kDriverUniformsMiscLayeredFramebufferMask));
  
      TIntermSequence args = {
          layeredFramebuffer,
      };
      return TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtBool, EbpUndefined>(),
                                                 &args);
  }
  
  //
  // Class DriverUniformExtended
  //
  TFieldList *DriverUniformExtended::createUniformFields(TSymbolTable *symbolTable)
  {
      TFieldList *driverFieldList = DriverUniform::createUniformFields(symbolTable);
  
      constexpr size_t kNumGraphicsDriverUniformsExt = 4;
      constexpr std::array<const char *, kNumGraphicsDriverUniformsExt>
          kGraphicsDriverUniformNamesExt = {
              {kXfbBufferOffsets, kXfbVerticesPerInstance, kUnused, kUnused2}};
  
      const std::array<TType *, kNumGraphicsDriverUniformsExt> kDriverUniformTypesExt = {{
          // xfbBufferOffsets: uvec4
          new TType(EbtInt, EbpHigh, EvqGlobal, 4),
          // xfbVerticesPerInstance: uint
          new TType(EbtInt, EbpHigh, EvqGlobal),
          // unused: uvec3
          new TType(EbtUInt, EbpHigh, EvqGlobal),
          new TType(EbtUInt, EbpHigh, EvqGlobal, 2),
      }};
  
      for (size_t uniformIndex = 0; uniformIndex < kNumGraphicsDriverUniformsExt; ++uniformIndex)
      {
          TField *driverUniformField =
              new TField(kDriverUniformTypesExt[uniformIndex],
                         ImmutableString(kGraphicsDriverUniformNamesExt[uniformIndex]), TSourceLoc(),
                         SymbolType::AngleInternal);
          driverFieldList->push_back(driverUniformField);
      }
  
      return driverFieldList;
  }
  
  TIntermTyped *DriverUniformExtended::getXfbBufferOffsets() const
  {
      return createDriverUniformRef(kXfbBufferOffsets);
  }
  
  TIntermTyped *DriverUniformExtended::getXfbVerticesPerInstance() const
  {
      return createDriverUniformRef(kXfbVerticesPerInstance);
  }
  
  TIntermTyped *MakeSwapXMultiplier(TIntermTyped *swapped)
  {
      // float(!swapped)
      TIntermSequence args = {
          new TIntermUnary(EOpLogicalNot, swapped, nullptr),
      };
      return TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtFloat, EbpLow>(), &args);
  }
  
  TIntermTyped *MakeSwapYMultiplier(TIntermTyped *swapped)
  {
      // float(swapped)
      TIntermSequence args = {
          swapped,
      };
      return TIntermAggregate::CreateConstructor(*StaticType::GetBasic<EbtFloat, EbpLow>(), &args);
  }
  }  // namespace sh
  

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