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kc3-lang/angle/src/compiler/translator/Intermediate.cpp
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Author :
Olli Etuaho
Date : 2015-02-13 10:59:34
Hash : ff805cc3
Message : Separate integer and float modulus Integer and float modulus are separated into Mod and IMod operator types to make the code clearer and to make GetOperatorString return the correct value for both. Change-Id: Ibfbca2c558bf919b0eab6404d7349f87fe47a18c Reviewed-on: https://chromium-review.googlesource.com/249692 Tested-by: Olli Etuaho <oetuaho@nvidia.com> Reviewed-by: Jamie Madill <jmadill@chromium.org> Reviewed-by: Zhenyao Mo <zmo@chromium.org>
- src/compiler/translator/Intermediate.cpp
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// // Copyright (c) 2002-2014 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. // // // Build the intermediate representation. // #include <float.h> #include <limits.h> #include <algorithm> #include "compiler/translator/Intermediate.h" #include "compiler/translator/SymbolTable.h" //////////////////////////////////////////////////////////////////////////// // // First set of functions are to help build the intermediate representation. // These functions are not member functions of the nodes. // They are called from parser productions. // ///////////////////////////////////////////////////////////////////////////// // // Add a terminal node for an identifier in an expression. // // Returns the added node. // TIntermSymbol *TIntermediate::addSymbol( int id, const TString &name, const TType &type, const TSourceLoc &line) { TIntermSymbol *node = new TIntermSymbol(id, name, type); node->setLine(line); return node; } // // Connect two nodes with a new parent that does a binary operation on the nodes. // // Returns the added node. // TIntermTyped *TIntermediate::addBinaryMath( TOperator op, TIntermTyped *left, TIntermTyped *right, const TSourceLoc &line) { switch (op) { case EOpEqual: case EOpNotEqual: if (left->isArray()) return NULL; break; case EOpLessThan: case EOpGreaterThan: case EOpLessThanEqual: case EOpGreaterThanEqual: if (left->isMatrix() || left->isArray() || left->isVector() || left->getBasicType() == EbtStruct) { return NULL; } break; case EOpLogicalOr: case EOpLogicalXor: case EOpLogicalAnd: if (left->getBasicType() != EbtBool || left->isMatrix() || left->isArray() || left->isVector()) { return NULL; } break; case EOpAdd: case EOpSub: case EOpDiv: case EOpMul: if (left->getBasicType() == EbtStruct || left->getBasicType() == EbtBool) { return NULL; } break; case EOpIMod: // Note that this is only for the % operator, not for mod() if (left->getBasicType() == EbtStruct || left->getBasicType() == EbtBool || left->getBasicType() == EbtFloat) { return NULL; } break; // Note that for bitwise ops, type checking is done in promote() to // share code between ops and compound assignment default: break; } // This check is duplicated between here and node->promote() as an optimization. if (left->getBasicType() != right->getBasicType() && op != EOpBitShiftLeft && op != EOpBitShiftRight) { return NULL; } // // Need a new node holding things together then. Make // one and promote it to the right type. // TIntermBinary *node = new TIntermBinary(op); node->setLine(line); node->setLeft(left); node->setRight(right); if (!node->promote(mInfoSink)) return NULL; // // See if we can fold constants. // TIntermConstantUnion *leftTempConstant = left->getAsConstantUnion(); TIntermConstantUnion *rightTempConstant = right->getAsConstantUnion(); if (leftTempConstant && rightTempConstant) { TIntermTyped *typedReturnNode = leftTempConstant->fold(node->getOp(), rightTempConstant, mInfoSink); if (typedReturnNode) return typedReturnNode; } return node; } // // Connect two nodes through an assignment. // // Returns the added node. // TIntermTyped *TIntermediate::addAssign( TOperator op, TIntermTyped *left, TIntermTyped *right, const TSourceLoc &line) { if (left->getType().getStruct() || right->getType().getStruct()) { if (left->getType() != right->getType()) { return NULL; } } TIntermBinary *node = new TIntermBinary(op); node->setLine(line); node->setLeft(left); node->setRight(right); if (!node->promote(mInfoSink)) return NULL; return node; } // // Connect two nodes through an index operator, where the left node is the base // of an array or struct, and the right node is a direct or indirect offset. // // Returns the added node. // The caller should set the type of the returned node. // TIntermTyped *TIntermediate::addIndex( TOperator op, TIntermTyped *base, TIntermTyped *index, const TSourceLoc &line) { TIntermBinary *node = new TIntermBinary(op); node->setLine(line); node->setLeft(base); node->setRight(index); // caller should set the type return node; } // // Add one node as the parent of another that it operates on. // // Returns the added node. // TIntermTyped *TIntermediate::addUnaryMath( TOperator op, TIntermNode *childNode, const TSourceLoc &line) { TIntermUnary *node; TIntermTyped *child = childNode->getAsTyped(); if (child == NULL) { mInfoSink.info.message(EPrefixInternalError, line, "Bad type in AddUnaryMath"); return NULL; } switch (op) { case EOpLogicalNot: if (child->getBasicType() != EbtBool || child->isMatrix() || child->isArray() || child->isVector()) { return NULL; } break; case EOpBitwiseNot: if ((child->getBasicType() != EbtInt && child->getBasicType() != EbtUInt) || child->isMatrix() || child->isArray()) { return NULL; } break; case EOpPostIncrement: case EOpPreIncrement: case EOpPostDecrement: case EOpPreDecrement: case EOpNegative: case EOpPositive: if (child->getBasicType() == EbtStruct || child->isArray()) { return NULL; } default: break; } TIntermConstantUnion *childTempConstant = 0; if (child->getAsConstantUnion()) childTempConstant = child->getAsConstantUnion(); // // Make a new node for the operator. // node = new TIntermUnary(op); node->setLine(line); node->setOperand(child); if (!node->promote(mInfoSink)) return 0; switch (op) { case EOpPackSnorm2x16: case EOpPackUnorm2x16: case EOpPackHalf2x16: case EOpUnpackSnorm2x16: case EOpUnpackUnorm2x16: node->getTypePointer()->setPrecision(EbpHigh); break; case EOpUnpackHalf2x16: node->getTypePointer()->setPrecision(EbpMedium); break; default: break; } if (childTempConstant) { TIntermTyped *newChild = childTempConstant->fold(op, 0, mInfoSink); if (newChild) return newChild; } return node; } // // This is the safe way to change the operator on an aggregate, as it // does lots of error checking and fixing. Especially for establishing // a function call's operation on it's set of parameters. Sequences // of instructions are also aggregates, but they just direnctly set // their operator to EOpSequence. // // Returns an aggregate node, which could be the one passed in if // it was already an aggregate but no operator was set. // TIntermAggregate *TIntermediate::setAggregateOperator( TIntermNode *node, TOperator op, const TSourceLoc &line) { TIntermAggregate *aggNode; // // Make sure we have an aggregate. If not turn it into one. // if (node) { aggNode = node->getAsAggregate(); if (aggNode == NULL || aggNode->getOp() != EOpNull) { // // Make an aggregate containing this node. // aggNode = new TIntermAggregate(); aggNode->getSequence()->push_back(node); } } else { aggNode = new TIntermAggregate(); } // // Set the operator. // aggNode->setOp(op); aggNode->setLine(line); return aggNode; } // // Safe way to combine two nodes into an aggregate. Works with null pointers, // a node that's not a aggregate yet, etc. // // Returns the resulting aggregate, unless 0 was passed in for // both existing nodes. // TIntermAggregate *TIntermediate::growAggregate( TIntermNode *left, TIntermNode *right, const TSourceLoc &line) { if (left == NULL && right == NULL) return NULL; TIntermAggregate *aggNode = NULL; if (left) aggNode = left->getAsAggregate(); if (!aggNode || aggNode->getOp() != EOpNull) { aggNode = new TIntermAggregate; if (left) aggNode->getSequence()->push_back(left); } if (right) aggNode->getSequence()->push_back(right); aggNode->setLine(line); return aggNode; } // // Turn an existing node into an aggregate. // // Returns an aggregate, unless NULL was passed in for the existing node. // TIntermAggregate *TIntermediate::makeAggregate( TIntermNode *node, const TSourceLoc &line) { if (node == NULL) return NULL; TIntermAggregate *aggNode = new TIntermAggregate; aggNode->getSequence()->push_back(node); aggNode->setLine(line); return aggNode; } // // For "if" test nodes. There are three children; a condition, // a true path, and a false path. The two paths are in the // nodePair. // // Returns the selection node created. // TIntermNode *TIntermediate::addSelection( TIntermTyped *cond, TIntermNodePair nodePair, const TSourceLoc &line) { // // For compile time constant selections, prune the code and // test now. // if (cond->getAsTyped() && cond->getAsTyped()->getAsConstantUnion()) { if (cond->getAsConstantUnion()->getBConst(0) == true) { return nodePair.node1 ? setAggregateOperator( nodePair.node1, EOpSequence, nodePair.node1->getLine()) : NULL; } else { return nodePair.node2 ? setAggregateOperator( nodePair.node2, EOpSequence, nodePair.node2->getLine()) : NULL; } } TIntermSelection *node = new TIntermSelection( cond, nodePair.node1, nodePair.node2); node->setLine(line); return node; } TIntermTyped *TIntermediate::addComma( TIntermTyped *left, TIntermTyped *right, const TSourceLoc &line) { if (left->getType().getQualifier() == EvqConst && right->getType().getQualifier() == EvqConst) { return right; } else { TIntermTyped *commaAggregate = growAggregate(left, right, line); commaAggregate->getAsAggregate()->setOp(EOpComma); commaAggregate->setType(right->getType()); commaAggregate->getTypePointer()->setQualifier(EvqTemporary); return commaAggregate; } } // // For "?:" test nodes. There are three children; a condition, // a true path, and a false path. The two paths are specified // as separate parameters. // // Returns the selection node created, or 0 if one could not be. // TIntermTyped *TIntermediate::addSelection( TIntermTyped *cond, TIntermTyped *trueBlock, TIntermTyped *falseBlock, const TSourceLoc &line) { if (!cond || !trueBlock || !falseBlock || trueBlock->getType() != falseBlock->getType()) { return NULL; } // // See if all the operands are constant, then fold it otherwise not. // if (cond->getAsConstantUnion() && trueBlock->getAsConstantUnion() && falseBlock->getAsConstantUnion()) { if (cond->getAsConstantUnion()->getBConst(0)) return trueBlock; else return falseBlock; } // // Make a selection node. // TIntermSelection *node = new TIntermSelection( cond, trueBlock, falseBlock, trueBlock->getType()); node->getTypePointer()->setQualifier(EvqTemporary); node->setLine(line); return node; } // // Constant terminal nodes. Has a union that contains bool, float or int constants // // Returns the constant union node created. // TIntermConstantUnion *TIntermediate::addConstantUnion( ConstantUnion *unionArrayPointer, const TType &t, const TSourceLoc &line) { TIntermConstantUnion *node = new TIntermConstantUnion(unionArrayPointer, t); node->setLine(line); return node; } TIntermTyped *TIntermediate::addSwizzle( TVectorFields &fields, const TSourceLoc &line) { TIntermAggregate *node = new TIntermAggregate(EOpSequence); node->setLine(line); TIntermConstantUnion *constIntNode; TIntermSequence *sequenceVector = node->getSequence(); ConstantUnion *unionArray; for (int i = 0; i < fields.num; i++) { unionArray = new ConstantUnion[1]; unionArray->setIConst(fields.offsets[i]); constIntNode = addConstantUnion( unionArray, TType(EbtInt, EbpUndefined, EvqConst), line); sequenceVector->push_back(constIntNode); } return node; } // // Create loop nodes. // TIntermNode *TIntermediate::addLoop( TLoopType type, TIntermNode *init, TIntermTyped *cond, TIntermTyped *expr, TIntermNode *body, const TSourceLoc &line) { TIntermNode *node = new TIntermLoop(type, init, cond, expr, body); node->setLine(line); return node; } // // Add branches. // TIntermBranch* TIntermediate::addBranch( TOperator branchOp, const TSourceLoc &line) { return addBranch(branchOp, 0, line); } TIntermBranch* TIntermediate::addBranch( TOperator branchOp, TIntermTyped *expression, const TSourceLoc &line) { TIntermBranch *node = new TIntermBranch(branchOp, expression); node->setLine(line); return node; } // // This is to be executed once the final root is put on top by the parsing // process. // bool TIntermediate::postProcess(TIntermNode *root) { if (root == NULL) return true; // // First, finish off the top level sequence, if any // TIntermAggregate *aggRoot = root->getAsAggregate(); if (aggRoot && aggRoot->getOp() == EOpNull) aggRoot->setOp(EOpSequence); return true; }