// // Copyright (c) 2002-2013 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. // #include "compiler/translator/ValidateLimitations.h" #include "angle_gl.h" #include "compiler/translator/Diagnostics.h" #include "compiler/translator/ParseContext.h" #include "compiler/translator/tree_util/IntermTraverse.h" namespace sh { namespace { int GetLoopSymbolId(TIntermLoop *loop) { // Here we assume all the operations are valid, because the loop node is // already validated before this call. TIntermSequence *declSeq = loop->getInit()->getAsDeclarationNode()->getSequence(); TIntermBinary *declInit = (*declSeq)[0]->getAsBinaryNode(); TIntermSymbol *symbol = declInit->getLeft()->getAsSymbolNode(); return symbol->uniqueId().get(); } // Traverses a node to check if it represents a constant index expression. // Definition: // constant-index-expressions are a superset of constant-expressions. // Constant-index-expressions can include loop indices as defined in // GLSL ES 1.0 spec, Appendix A, section 4. // The following are constant-index-expressions: // - Constant expressions // - Loop indices as defined in section 4 // - Expressions composed of both of the above class ValidateConstIndexExpr : public TIntermTraverser { public: ValidateConstIndexExpr(const std::vector &loopSymbols) : TIntermTraverser(true, false, false), mValid(true), mLoopSymbolIds(loopSymbols) {} // Returns true if the parsed node represents a constant index expression. bool isValid() const { return mValid; } void visitSymbol(TIntermSymbol *symbol) override { // Only constants and loop indices are allowed in a // constant index expression. if (mValid) { bool isLoopSymbol = std::find(mLoopSymbolIds.begin(), mLoopSymbolIds.end(), symbol->uniqueId().get()) != mLoopSymbolIds.end(); mValid = (symbol->getQualifier() == EvqConst) || isLoopSymbol; } } private: bool mValid; const std::vector mLoopSymbolIds; }; // Traverses intermediate tree to ensure that the shader does not exceed the // minimum functionality mandated in GLSL 1.0 spec, Appendix A. class ValidateLimitationsTraverser : public TLValueTrackingTraverser { public: ValidateLimitationsTraverser(sh::GLenum shaderType, TSymbolTable *symbolTable, TDiagnostics *diagnostics); void visitSymbol(TIntermSymbol *node) override; bool visitBinary(Visit, TIntermBinary *) override; bool visitLoop(Visit, TIntermLoop *) override; private: void error(TSourceLoc loc, const char *reason, const char *token); void error(TSourceLoc loc, const char *reason, const ImmutableString &token); bool isLoopIndex(TIntermSymbol *symbol); bool validateLoopType(TIntermLoop *node); bool validateForLoopHeader(TIntermLoop *node); // If valid, return the index symbol id; Otherwise, return -1. int validateForLoopInit(TIntermLoop *node); bool validateForLoopCond(TIntermLoop *node, int indexSymbolId); bool validateForLoopExpr(TIntermLoop *node, int indexSymbolId); // Returns true if indexing does not exceed the minimum functionality // mandated in GLSL 1.0 spec, Appendix A, Section 5. bool isConstExpr(TIntermNode *node); bool isConstIndexExpr(TIntermNode *node); bool validateIndexing(TIntermBinary *node); sh::GLenum mShaderType; TDiagnostics *mDiagnostics; std::vector mLoopSymbolIds; }; ValidateLimitationsTraverser::ValidateLimitationsTraverser(sh::GLenum shaderType, TSymbolTable *symbolTable, TDiagnostics *diagnostics) : TLValueTrackingTraverser(true, false, false, symbolTable), mShaderType(shaderType), mDiagnostics(diagnostics) { ASSERT(diagnostics); } void ValidateLimitationsTraverser::visitSymbol(TIntermSymbol *node) { if (isLoopIndex(node) && isLValueRequiredHere()) { error(node->getLine(), "Loop index cannot be statically assigned to within the body of the loop", node->getName()); } } bool ValidateLimitationsTraverser::visitBinary(Visit, TIntermBinary *node) { // Check indexing. switch (node->getOp()) { case EOpIndexDirect: case EOpIndexIndirect: validateIndexing(node); break; default: break; } return true; } bool ValidateLimitationsTraverser::visitLoop(Visit, TIntermLoop *node) { if (!validateLoopType(node)) return false; if (!validateForLoopHeader(node)) return false; TIntermNode *body = node->getBody(); if (body != nullptr) { mLoopSymbolIds.push_back(GetLoopSymbolId(node)); body->traverse(this); mLoopSymbolIds.pop_back(); } // The loop is fully processed - no need to visit children. return false; } void ValidateLimitationsTraverser::error(TSourceLoc loc, const char *reason, const char *token) { mDiagnostics->error(loc, reason, token); } void ValidateLimitationsTraverser::error(TSourceLoc loc, const char *reason, const ImmutableString &token) { error(loc, reason, token.data()); } bool ValidateLimitationsTraverser::isLoopIndex(TIntermSymbol *symbol) { return std::find(mLoopSymbolIds.begin(), mLoopSymbolIds.end(), symbol->uniqueId().get()) != mLoopSymbolIds.end(); } bool ValidateLimitationsTraverser::validateLoopType(TIntermLoop *node) { TLoopType type = node->getType(); if (type == ELoopFor) return true; // Reject while and do-while loops. error(node->getLine(), "This type of loop is not allowed", type == ELoopWhile ? "while" : "do"); return false; } bool ValidateLimitationsTraverser::validateForLoopHeader(TIntermLoop *node) { ASSERT(node->getType() == ELoopFor); // // The for statement has the form: // for ( init-declaration ; condition ; expression ) statement // int indexSymbolId = validateForLoopInit(node); if (indexSymbolId < 0) return false; if (!validateForLoopCond(node, indexSymbolId)) return false; if (!validateForLoopExpr(node, indexSymbolId)) return false; return true; } int ValidateLimitationsTraverser::validateForLoopInit(TIntermLoop *node) { TIntermNode *init = node->getInit(); if (init == nullptr) { error(node->getLine(), "Missing init declaration", "for"); return -1; } // // init-declaration has the form: // type-specifier identifier = constant-expression // TIntermDeclaration *decl = init->getAsDeclarationNode(); if (decl == nullptr) { error(init->getLine(), "Invalid init declaration", "for"); return -1; } // To keep things simple do not allow declaration list. TIntermSequence *declSeq = decl->getSequence(); if (declSeq->size() != 1) { error(decl->getLine(), "Invalid init declaration", "for"); return -1; } TIntermBinary *declInit = (*declSeq)[0]->getAsBinaryNode(); if ((declInit == nullptr) || (declInit->getOp() != EOpInitialize)) { error(decl->getLine(), "Invalid init declaration", "for"); return -1; } TIntermSymbol *symbol = declInit->getLeft()->getAsSymbolNode(); if (symbol == nullptr) { error(declInit->getLine(), "Invalid init declaration", "for"); return -1; } // The loop index has type int or float. TBasicType type = symbol->getBasicType(); if ((type != EbtInt) && (type != EbtUInt) && (type != EbtFloat)) { error(symbol->getLine(), "Invalid type for loop index", getBasicString(type)); return -1; } // The loop index is initialized with constant expression. if (!isConstExpr(declInit->getRight())) { error(declInit->getLine(), "Loop index cannot be initialized with non-constant expression", symbol->getName()); return -1; } return symbol->uniqueId().get(); } bool ValidateLimitationsTraverser::validateForLoopCond(TIntermLoop *node, int indexSymbolId) { TIntermNode *cond = node->getCondition(); if (cond == nullptr) { error(node->getLine(), "Missing condition", "for"); return false; } // // condition has the form: // loop_index relational_operator constant_expression // TIntermBinary *binOp = cond->getAsBinaryNode(); if (binOp == nullptr) { error(node->getLine(), "Invalid condition", "for"); return false; } // Loop index should be to the left of relational operator. TIntermSymbol *symbol = binOp->getLeft()->getAsSymbolNode(); if (symbol == nullptr) { error(binOp->getLine(), "Invalid condition", "for"); return false; } if (symbol->uniqueId().get() != indexSymbolId) { error(symbol->getLine(), "Expected loop index", symbol->getName()); return false; } // Relational operator is one of: > >= < <= == or !=. switch (binOp->getOp()) { case EOpEqual: case EOpNotEqual: case EOpLessThan: case EOpGreaterThan: case EOpLessThanEqual: case EOpGreaterThanEqual: break; default: error(binOp->getLine(), "Invalid relational operator", GetOperatorString(binOp->getOp())); break; } // Loop index must be compared with a constant. if (!isConstExpr(binOp->getRight())) { error(binOp->getLine(), "Loop index cannot be compared with non-constant expression", symbol->getName()); return false; } return true; } bool ValidateLimitationsTraverser::validateForLoopExpr(TIntermLoop *node, int indexSymbolId) { TIntermNode *expr = node->getExpression(); if (expr == nullptr) { error(node->getLine(), "Missing expression", "for"); return false; } // for expression has one of the following forms: // loop_index++ // loop_index-- // loop_index += constant_expression // loop_index -= constant_expression // ++loop_index // --loop_index // The last two forms are not specified in the spec, but I am assuming // its an oversight. TIntermUnary *unOp = expr->getAsUnaryNode(); TIntermBinary *binOp = unOp ? nullptr : expr->getAsBinaryNode(); TOperator op = EOpNull; TIntermSymbol *symbol = nullptr; if (unOp != nullptr) { op = unOp->getOp(); symbol = unOp->getOperand()->getAsSymbolNode(); } else if (binOp != nullptr) { op = binOp->getOp(); symbol = binOp->getLeft()->getAsSymbolNode(); } // The operand must be loop index. if (symbol == nullptr) { error(expr->getLine(), "Invalid expression", "for"); return false; } if (symbol->uniqueId().get() != indexSymbolId) { error(symbol->getLine(), "Expected loop index", symbol->getName()); return false; } // The operator is one of: ++ -- += -=. switch (op) { case EOpPostIncrement: case EOpPostDecrement: case EOpPreIncrement: case EOpPreDecrement: ASSERT((unOp != nullptr) && (binOp == nullptr)); break; case EOpAddAssign: case EOpSubAssign: ASSERT((unOp == nullptr) && (binOp != nullptr)); break; default: error(expr->getLine(), "Invalid operator", GetOperatorString(op)); return false; } // Loop index must be incremented/decremented with a constant. if (binOp != nullptr) { if (!isConstExpr(binOp->getRight())) { error(binOp->getLine(), "Loop index cannot be modified by non-constant expression", symbol->getName()); return false; } } return true; } bool ValidateLimitationsTraverser::isConstExpr(TIntermNode *node) { ASSERT(node != nullptr); return node->getAsConstantUnion() != nullptr && node->getAsTyped()->getQualifier() == EvqConst; } bool ValidateLimitationsTraverser::isConstIndexExpr(TIntermNode *node) { ASSERT(node != nullptr); ValidateConstIndexExpr validate(mLoopSymbolIds); node->traverse(&validate); return validate.isValid(); } bool ValidateLimitationsTraverser::validateIndexing(TIntermBinary *node) { ASSERT((node->getOp() == EOpIndexDirect) || (node->getOp() == EOpIndexIndirect)); bool valid = true; TIntermTyped *index = node->getRight(); // The index expession must be a constant-index-expression unless // the operand is a uniform in a vertex shader. TIntermTyped *operand = node->getLeft(); bool skip = (mShaderType == GL_VERTEX_SHADER) && (operand->getQualifier() == EvqUniform); if (!skip && !isConstIndexExpr(index)) { error(index->getLine(), "Index expression must be constant", "[]"); valid = false; } return valid; } } // namespace bool ValidateLimitations(TIntermNode *root, GLenum shaderType, TSymbolTable *symbolTable, TDiagnostics *diagnostics) { ValidateLimitationsTraverser validate(shaderType, symbolTable, diagnostics); root->traverse(&validate); return diagnostics->numErrors() == 0; } } // namespace sh