kc3-lang/angle/src/compiler/translator/tree_ops/RemoveDynamicIndexing.cpp

• Show log

  Commit

• Hash : b3070102
  Author :
  Date : 2019-10-18T16:01:34
  

  Add SH_REMOVE_DYNAMIC_INDEXING_OF_SWIZZLED_VECTOR
  
  This is a workaround for the webgl2 conformance test case
  WebglConformance_conformance2_glsl3_vector_dynamic_indexing_swizzled_lvalue.
  Dynamic indexing of swizzled lvalue like "v.zyx[i] = 0.0" is problematic on
  various platforms. This removes the indexing by translating it this way:
  
  void dyn_index_write_vec3(inout vec3 base, in int index, in float value){
    switch (index) {
      case (0):
        (base[0] = value);
        return ;
      case (1):
        (base[1] = value);
        return ;
      case (2):
        (base[2] = value);
        return ;
      default:
        break;
    }
    if ((index < 0))
    {
      (base[0] = value);
      return ;
    }
    {
      (base[2] = value);
    }
  }
  
  ...
  dyn_index_write_vec3(v.zyx, i, 0.0);
  ...
  
  Bug: chromium:709351
  Change-Id: I971b38eb404209b56e6764af1063878c078a7e88
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/1869109
  Commit-Queue: Jie A Chen <jie.a.chen@intel.com>
  Reviewed-by: Geoff Lang <geofflang@chromium.org>
  

Download

• src/compiler/translator/tree_ops/RemoveDynamicIndexing.cpp

• //
  // Copyright 2002 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.
  //
  // RemoveDynamicIndexing is an AST traverser to remove dynamic indexing of non-SSBO vectors and
  // matrices, replacing them with calls to functions that choose which component to return or write.
  // We don't need to consider dynamic indexing in SSBO since it can be directly as part of the offset
  // of RWByteAddressBuffer.
  //
  
  #include "compiler/translator/tree_ops/RemoveDynamicIndexing.h"
  
  #include "compiler/translator/Compiler.h"
  #include "compiler/translator/Diagnostics.h"
  #include "compiler/translator/InfoSink.h"
  #include "compiler/translator/StaticType.h"
  #include "compiler/translator/SymbolTable.h"
  #include "compiler/translator/tree_util/IntermNodePatternMatcher.h"
  #include "compiler/translator/tree_util/IntermNode_util.h"
  #include "compiler/translator/tree_util/IntermTraverse.h"
  
  namespace sh
  {
  
  namespace
  {
  
  using DynamicIndexingNodeMatcher = std::function<bool(TIntermBinary *)>;
  
  const TType *kIndexType = StaticType::Get<EbtInt, EbpHigh, EvqIn, 1, 1>();
  
  constexpr const ImmutableString kBaseName("base");
  constexpr const ImmutableString kIndexName("index");
  constexpr const ImmutableString kValueName("value");
  
  std::string GetIndexFunctionName(const TType &type, bool write)
  {
      TInfoSinkBase nameSink;
      nameSink << "dyn_index_";
      if (write)
      {
          nameSink << "write_";
      }
      if (type.isMatrix())
      {
          nameSink << "mat" << type.getCols() << "x" << type.getRows();
      }
      else
      {
          switch (type.getBasicType())
          {
              case EbtInt:
                  nameSink << "ivec";
                  break;
              case EbtBool:
                  nameSink << "bvec";
                  break;
              case EbtUInt:
                  nameSink << "uvec";
                  break;
              case EbtFloat:
                  nameSink << "vec";
                  break;
              default:
                  UNREACHABLE();
          }
          nameSink << type.getNominalSize();
      }
      return nameSink.str();
  }
  
  TIntermConstantUnion *CreateIntConstantNode(int i)
  {
      TConstantUnion *constant = new TConstantUnion();
      constant->setIConst(i);
      return new TIntermConstantUnion(constant, TType(EbtInt, EbpHigh));
  }
  
  TIntermTyped *EnsureSignedInt(TIntermTyped *node)
  {
      if (node->getBasicType() == EbtInt)
          return node;
  
      TIntermSequence *arguments = new TIntermSequence();
      arguments->push_back(node);
      return TIntermAggregate::CreateConstructor(TType(EbtInt), arguments);
  }
  
  TType *GetFieldType(const TType &indexedType)
  {
      if (indexedType.isMatrix())
      {
          TType *fieldType = new TType(indexedType.getBasicType(), indexedType.getPrecision());
          fieldType->setPrimarySize(static_cast<unsigned char>(indexedType.getRows()));
          return fieldType;
      }
      else
      {
          return new TType(indexedType.getBasicType(), indexedType.getPrecision());
      }
  }
  
  const TType *GetBaseType(const TType &type, bool write)
  {
      TType *baseType = new TType(type);
      // Conservatively use highp here, even if the indexed type is not highp. That way the code can't
      // end up using mediump version of an indexing function for a highp value, if both mediump and
      // highp values are being indexed in the shader. For HLSL precision doesn't matter, but in
      // principle this code could be used with multiple backends.
      baseType->setPrecision(EbpHigh);
      baseType->setQualifier(EvqInOut);
      if (!write)
          baseType->setQualifier(EvqIn);
      return baseType;
  }
  
  // Generate a read or write function for one field in a vector/matrix.
  // Out-of-range indices are clamped. This is consistent with how ANGLE handles out-of-range
  // indices in other places.
  // Note that indices can be either int or uint. We create only int versions of the functions,
  // and convert uint indices to int at the call site.
  // read function example:
  // float dyn_index_vec2(in vec2 base, in int index)
  // {
  //    switch(index)
  //    {
  //      case (0):
  //        return base[0];
  //      case (1):
  //        return base[1];
  //      default:
  //        break;
  //    }
  //    if (index < 0)
  //      return base[0];
  //    return base[1];
  // }
  // write function example:
  // void dyn_index_write_vec2(inout vec2 base, in int index, in float value)
  // {
  //    switch(index)
  //    {
  //      case (0):
  //        base[0] = value;
  //        return;
  //      case (1):
  //        base[1] = value;
  //        return;
  //      default:
  //        break;
  //    }
  //    if (index < 0)
  //    {
  //      base[0] = value;
  //      return;
  //    }
  //    base[1] = value;
  // }
  // Note that else is not used in above functions to avoid the RewriteElseBlocks transformation.
  TIntermFunctionDefinition *GetIndexFunctionDefinition(const TType &type,
                                                        bool write,
                                                        const TFunction &func,
                                                        TSymbolTable *symbolTable)
  {
      ASSERT(!type.isArray());
  
      int numCases = 0;
      if (type.isMatrix())
      {
          numCases = type.getCols();
      }
      else
      {
          numCases = type.getNominalSize();
      }
  
      std::string functionName                = GetIndexFunctionName(type, write);
      TIntermFunctionPrototype *prototypeNode = CreateInternalFunctionPrototypeNode(func);
  
      TIntermSymbol *baseParam  = new TIntermSymbol(func.getParam(0));
      TIntermSymbol *indexParam = new TIntermSymbol(func.getParam(1));
      TIntermSymbol *valueParam = nullptr;
      if (write)
      {
          valueParam = new TIntermSymbol(func.getParam(2));
      }
  
      TIntermBlock *statementList = new TIntermBlock();
      for (int i = 0; i < numCases; ++i)
      {
          TIntermCase *caseNode = new TIntermCase(CreateIntConstantNode(i));
          statementList->getSequence()->push_back(caseNode);
  
          TIntermBinary *indexNode =
              new TIntermBinary(EOpIndexDirect, baseParam->deepCopy(), CreateIndexNode(i));
          if (write)
          {
              TIntermBinary *assignNode =
                  new TIntermBinary(EOpAssign, indexNode, valueParam->deepCopy());
              statementList->getSequence()->push_back(assignNode);
              TIntermBranch *returnNode = new TIntermBranch(EOpReturn, nullptr);
              statementList->getSequence()->push_back(returnNode);
          }
          else
          {
              TIntermBranch *returnNode = new TIntermBranch(EOpReturn, indexNode);
              statementList->getSequence()->push_back(returnNode);
          }
      }
  
      // Default case
      TIntermCase *defaultNode = new TIntermCase(nullptr);
      statementList->getSequence()->push_back(defaultNode);
      TIntermBranch *breakNode = new TIntermBranch(EOpBreak, nullptr);
      statementList->getSequence()->push_back(breakNode);
  
      TIntermSwitch *switchNode = new TIntermSwitch(indexParam->deepCopy(), statementList);
  
      TIntermBlock *bodyNode = new TIntermBlock();
      bodyNode->getSequence()->push_back(switchNode);
  
      TIntermBinary *cond =
          new TIntermBinary(EOpLessThan, indexParam->deepCopy(), CreateIntConstantNode(0));
  
      // Two blocks: one accesses (either reads or writes) the first element and returns,
      // the other accesses the last element.
      TIntermBlock *useFirstBlock = new TIntermBlock();
      TIntermBlock *useLastBlock  = new TIntermBlock();
      TIntermBinary *indexFirstNode =
          new TIntermBinary(EOpIndexDirect, baseParam->deepCopy(), CreateIndexNode(0));
      TIntermBinary *indexLastNode =
          new TIntermBinary(EOpIndexDirect, baseParam->deepCopy(), CreateIndexNode(numCases - 1));
      if (write)
      {
          TIntermBinary *assignFirstNode =
              new TIntermBinary(EOpAssign, indexFirstNode, valueParam->deepCopy());
          useFirstBlock->getSequence()->push_back(assignFirstNode);
          TIntermBranch *returnNode = new TIntermBranch(EOpReturn, nullptr);
          useFirstBlock->getSequence()->push_back(returnNode);
  
          TIntermBinary *assignLastNode =
              new TIntermBinary(EOpAssign, indexLastNode, valueParam->deepCopy());
          useLastBlock->getSequence()->push_back(assignLastNode);
      }
      else
      {
          TIntermBranch *returnFirstNode = new TIntermBranch(EOpReturn, indexFirstNode);
          useFirstBlock->getSequence()->push_back(returnFirstNode);
  
          TIntermBranch *returnLastNode = new TIntermBranch(EOpReturn, indexLastNode);
          useLastBlock->getSequence()->push_back(returnLastNode);
      }
      TIntermIfElse *ifNode = new TIntermIfElse(cond, useFirstBlock, nullptr);
      bodyNode->getSequence()->push_back(ifNode);
      bodyNode->getSequence()->push_back(useLastBlock);
  
      TIntermFunctionDefinition *indexingFunction =
          new TIntermFunctionDefinition(prototypeNode, bodyNode);
      return indexingFunction;
  }
  
  class RemoveDynamicIndexingTraverser : public TLValueTrackingTraverser
  {
    public:
      RemoveDynamicIndexingTraverser(DynamicIndexingNodeMatcher &&matcher,
                                     TSymbolTable *symbolTable,
                                     PerformanceDiagnostics *perfDiagnostics);
  
      bool visitBinary(Visit visit, TIntermBinary *node) override;
  
      void insertHelperDefinitions(TIntermNode *root);
  
      void nextIteration();
  
      bool usedTreeInsertion() const { return mUsedTreeInsertion; }
  
    protected:
      // Maps of types that are indexed to the indexing function ids used for them. Note that these
      // can not store multiple variants of the same type with different precisions - only one
      // precision gets stored.
      std::map<TType, TFunction *> mIndexedVecAndMatrixTypes;
      std::map<TType, TFunction *> mWrittenVecAndMatrixTypes;
  
      bool mUsedTreeInsertion;
  
      // When true, the traverser will remove side effects from any indexing expression.
      // This is done so that in code like
      //   V[j++][i]++.
      // where V is an array of vectors, j++ will only be evaluated once.
      bool mRemoveIndexSideEffectsInSubtree;
  
      DynamicIndexingNodeMatcher mMatcher;
      PerformanceDiagnostics *mPerfDiagnostics;
  };
  
  RemoveDynamicIndexingTraverser::RemoveDynamicIndexingTraverser(
      DynamicIndexingNodeMatcher &&matcher,
      TSymbolTable *symbolTable,
      PerformanceDiagnostics *perfDiagnostics)
      : TLValueTrackingTraverser(true, false, false, symbolTable),
        mUsedTreeInsertion(false),
        mRemoveIndexSideEffectsInSubtree(false),
        mMatcher(matcher),
        mPerfDiagnostics(perfDiagnostics)
  {}
  
  void RemoveDynamicIndexingTraverser::insertHelperDefinitions(TIntermNode *root)
  {
      TIntermBlock *rootBlock = root->getAsBlock();
      ASSERT(rootBlock != nullptr);
      TIntermSequence insertions;
      for (auto &type : mIndexedVecAndMatrixTypes)
      {
          insertions.push_back(
              GetIndexFunctionDefinition(type.first, false, *type.second, mSymbolTable));
      }
      for (auto &type : mWrittenVecAndMatrixTypes)
      {
          insertions.push_back(
              GetIndexFunctionDefinition(type.first, true, *type.second, mSymbolTable));
      }
      rootBlock->insertChildNodes(0, insertions);
  }
  
  // Create a call to dyn_index_*() based on an indirect indexing op node
  TIntermAggregate *CreateIndexFunctionCall(TIntermBinary *node,
                                            TIntermTyped *index,
                                            TFunction *indexingFunction)
  {
      ASSERT(node->getOp() == EOpIndexIndirect);
      TIntermSequence *arguments = new TIntermSequence();
      arguments->push_back(node->getLeft());
      arguments->push_back(index);
  
      TIntermAggregate *indexingCall =
          TIntermAggregate::CreateFunctionCall(*indexingFunction, arguments);
      indexingCall->setLine(node->getLine());
      return indexingCall;
  }
  
  TIntermAggregate *CreateIndexedWriteFunctionCall(TIntermBinary *node,
                                                   TVariable *index,
                                                   TVariable *writtenValue,
                                                   TFunction *indexedWriteFunction)
  {
      ASSERT(node->getOp() == EOpIndexIndirect);
      TIntermSequence *arguments = new TIntermSequence();
      // Deep copy the child nodes so that two pointers to the same node don't end up in the tree.
      arguments->push_back(node->getLeft()->deepCopy());
      arguments->push_back(CreateTempSymbolNode(index));
      arguments->push_back(CreateTempSymbolNode(writtenValue));
  
      TIntermAggregate *indexedWriteCall =
          TIntermAggregate::CreateFunctionCall(*indexedWriteFunction, arguments);
      indexedWriteCall->setLine(node->getLine());
      return indexedWriteCall;
  }
  
  bool RemoveDynamicIndexingTraverser::visitBinary(Visit visit, TIntermBinary *node)
  {
      if (mUsedTreeInsertion)
          return false;
  
      if (node->getOp() == EOpIndexIndirect)
      {
          if (mRemoveIndexSideEffectsInSubtree)
          {
              ASSERT(node->getRight()->hasSideEffects());
              // In case we're just removing index side effects, convert
              //   v_expr[index_expr]
              // to this:
              //   int s0 = index_expr; v_expr[s0];
              // Now v_expr[s0] can be safely executed several times without unintended side effects.
              TIntermDeclaration *indexVariableDeclaration = nullptr;
              TVariable *indexVariable = DeclareTempVariable(mSymbolTable, node->getRight(),
                                                             EvqTemporary, &indexVariableDeclaration);
              insertStatementInParentBlock(indexVariableDeclaration);
              mUsedTreeInsertion = true;
  
              // Replace the index with the temp variable
              TIntermSymbol *tempIndex = CreateTempSymbolNode(indexVariable);
              queueReplacementWithParent(node, node->getRight(), tempIndex, OriginalNode::IS_DROPPED);
          }
          else if (mMatcher(node))
          {
              if (mPerfDiagnostics)
              {
                  mPerfDiagnostics->warning(node->getLine(),
                                            "Performance: dynamic indexing of vectors and "
                                            "matrices is emulated and can be slow.",
                                            "[]");
              }
              bool write = isLValueRequiredHere();
  
  #if defined(ANGLE_ENABLE_ASSERTS)
              // Make sure that IntermNodePatternMatcher is consistent with the slightly differently
              // implemented checks in this traverser.
              IntermNodePatternMatcher matcher(
                  IntermNodePatternMatcher::kDynamicIndexingOfVectorOrMatrixInLValue);
              ASSERT(matcher.match(node, getParentNode(), isLValueRequiredHere()) == write);
  #endif
  
              const TType &type = node->getLeft()->getType();
              ImmutableString indexingFunctionName(GetIndexFunctionName(type, false));
              TFunction *indexingFunction = nullptr;
              if (mIndexedVecAndMatrixTypes.find(type) == mIndexedVecAndMatrixTypes.end())
              {
                  indexingFunction =
                      new TFunction(mSymbolTable, indexingFunctionName, SymbolType::AngleInternal,
                                    GetFieldType(type), true);
                  indexingFunction->addParameter(new TVariable(
                      mSymbolTable, kBaseName, GetBaseType(type, false), SymbolType::AngleInternal));
                  indexingFunction->addParameter(
                      new TVariable(mSymbolTable, kIndexName, kIndexType, SymbolType::AngleInternal));
                  mIndexedVecAndMatrixTypes[type] = indexingFunction;
              }
              else
              {
                  indexingFunction = mIndexedVecAndMatrixTypes[type];
              }
  
              if (write)
              {
                  // Convert:
                  //   v_expr[index_expr]++;
                  // to this:
                  //   int s0 = index_expr; float s1 = dyn_index(v_expr, s0); s1++;
                  //   dyn_index_write(v_expr, s0, s1);
                  // This works even if index_expr has some side effects.
                  if (node->getLeft()->hasSideEffects())
                  {
                      // If v_expr has side effects, those need to be removed before proceeding.
                      // Otherwise the side effects of v_expr would be evaluated twice.
                      // The only case where an l-value can have side effects is when it is
                      // indexing. For example, it can be V[j++] where V is an array of vectors.
                      mRemoveIndexSideEffectsInSubtree = true;
                      return true;
                  }
  
                  TIntermBinary *leftBinary = node->getLeft()->getAsBinaryNode();
                  if (leftBinary != nullptr && mMatcher(leftBinary))
                  {
                      // This is a case like:
                      // mat2 m;
                      // m[a][b]++;
                      // Process the child node m[a] first.
                      return true;
                  }
  
                  // TODO(oetuaho@nvidia.com): This is not optimal if the expression using the value
                  // only writes it and doesn't need the previous value. http://anglebug.com/1116
  
                  TFunction *indexedWriteFunction = nullptr;
                  if (mWrittenVecAndMatrixTypes.find(type) == mWrittenVecAndMatrixTypes.end())
                  {
                      ImmutableString functionName(
                          GetIndexFunctionName(node->getLeft()->getType(), true));
                      indexedWriteFunction =
                          new TFunction(mSymbolTable, functionName, SymbolType::AngleInternal,
                                        StaticType::GetBasic<EbtVoid>(), false);
                      indexedWriteFunction->addParameter(new TVariable(mSymbolTable, kBaseName,
                                                                       GetBaseType(type, true),
                                                                       SymbolType::AngleInternal));
                      indexedWriteFunction->addParameter(new TVariable(
                          mSymbolTable, kIndexName, kIndexType, SymbolType::AngleInternal));
                      TType *valueType = GetFieldType(type);
                      valueType->setQualifier(EvqIn);
                      indexedWriteFunction->addParameter(new TVariable(
                          mSymbolTable, kValueName, static_cast<const TType *>(valueType),
                          SymbolType::AngleInternal));
                      mWrittenVecAndMatrixTypes[type] = indexedWriteFunction;
                  }
                  else
                  {
                      indexedWriteFunction = mWrittenVecAndMatrixTypes[type];
                  }
  
                  TIntermSequence insertionsBefore;
                  TIntermSequence insertionsAfter;
  
                  // Store the index in a temporary signed int variable.
                  // s0 = index_expr;
                  TIntermTyped *indexInitializer               = EnsureSignedInt(node->getRight());
                  TIntermDeclaration *indexVariableDeclaration = nullptr;
                  TVariable *indexVariable                     = DeclareTempVariable(
                      mSymbolTable, indexInitializer, EvqTemporary, &indexVariableDeclaration);
                  insertionsBefore.push_back(indexVariableDeclaration);
  
                  // s1 = dyn_index(v_expr, s0);
                  TIntermAggregate *indexingCall = CreateIndexFunctionCall(
                      node, CreateTempSymbolNode(indexVariable), indexingFunction);
                  TIntermDeclaration *fieldVariableDeclaration = nullptr;
                  TVariable *fieldVariable                     = DeclareTempVariable(
                      mSymbolTable, indexingCall, EvqTemporary, &fieldVariableDeclaration);
                  insertionsBefore.push_back(fieldVariableDeclaration);
  
                  // dyn_index_write(v_expr, s0, s1);
                  TIntermAggregate *indexedWriteCall = CreateIndexedWriteFunctionCall(
                      node, indexVariable, fieldVariable, indexedWriteFunction);
                  insertionsAfter.push_back(indexedWriteCall);
                  insertStatementsInParentBlock(insertionsBefore, insertionsAfter);
  
                  // replace the node with s1
                  queueReplacement(CreateTempSymbolNode(fieldVariable), OriginalNode::IS_DROPPED);
                  mUsedTreeInsertion = true;
              }
              else
              {
                  // The indexed value is not being written, so we can simply convert
                  //   v_expr[index_expr]
                  // into
                  //   dyn_index(v_expr, index_expr)
                  // If the index_expr is unsigned, we'll convert it to signed.
                  ASSERT(!mRemoveIndexSideEffectsInSubtree);
                  TIntermAggregate *indexingCall = CreateIndexFunctionCall(
                      node, EnsureSignedInt(node->getRight()), indexingFunction);
                  queueReplacement(indexingCall, OriginalNode::IS_DROPPED);
              }
          }
      }
      return !mUsedTreeInsertion;
  }
  
  void RemoveDynamicIndexingTraverser::nextIteration()
  {
      mUsedTreeInsertion               = false;
      mRemoveIndexSideEffectsInSubtree = false;
  }
  
  bool RemoveDynamicIndexingIf(DynamicIndexingNodeMatcher &&matcher,
                               TCompiler *compiler,
                               TIntermNode *root,
                               TSymbolTable *symbolTable,
                               PerformanceDiagnostics *perfDiagnostics)
  {
      RemoveDynamicIndexingTraverser traverser(std::move(matcher), symbolTable, perfDiagnostics);
      do
      {
          traverser.nextIteration();
          root->traverse(&traverser);
          if (!traverser.updateTree(compiler, root))
          {
              return false;
          }
      } while (traverser.usedTreeInsertion());
      // TODO(oetuaho@nvidia.com): It might be nicer to add the helper definitions also in the middle
      // of traversal. Now the tree ends up in an inconsistent state in the middle, since there are
      // function call nodes with no corresponding definition nodes. This needs special handling in
      // TIntermLValueTrackingTraverser, and creates intricacies that are not easily apparent from a
      // superficial reading of the code.
      traverser.insertHelperDefinitions(root);
      return compiler->validateAST(root);
  }
  
  }  // namespace
  
  ANGLE_NO_DISCARD bool RemoveDynamicIndexingOfNonSSBOVectorOrMatrix(
      TCompiler *compiler,
      TIntermNode *root,
      TSymbolTable *symbolTable,
      PerformanceDiagnostics *perfDiagnostics)
  {
      DynamicIndexingNodeMatcher matcher = [](TIntermBinary *node) {
          return IntermNodePatternMatcher::IsDynamicIndexingOfNonSSBOVectorOrMatrix(node);
      };
      return RemoveDynamicIndexingIf(std::move(matcher), compiler, root, symbolTable,
                                     perfDiagnostics);
  }
  
  ANGLE_NO_DISCARD bool RemoveDynamicIndexingOfSwizzledVector(TCompiler *compiler,
                                                              TIntermNode *root,
                                                              TSymbolTable *symbolTable,
                                                              PerformanceDiagnostics *perfDiagnostics)
  {
      DynamicIndexingNodeMatcher matcher = [](TIntermBinary *node) {
          return IntermNodePatternMatcher::IsDynamicIndexingOfSwizzledVector(node);
      };
      return RemoveDynamicIndexingIf(std::move(matcher), compiler, root, symbolTable,
                                     perfDiagnostics);
  }
  
  }  // namespace sh
  

Download