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//
// Copyright (c) 2016 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.
//
// SimplifyLoopConditions is an AST traverser that converts loop conditions and loop expressions
// to regular statements inside the loop. This way further transformations that generate statements
// from loop conditions and loop expressions work correctly.
//
#include "compiler/translator/SimplifyLoopConditions.h"
#include "compiler/translator/IntermNode.h"
#include "compiler/translator/IntermNodePatternMatcher.h"
namespace
{
TIntermConstantUnion *CreateBoolConstantNode(bool value)
{
TConstantUnion *u = new TConstantUnion;
u->setBConst(value);
TIntermConstantUnion *node =
new TIntermConstantUnion(u, TType(EbtBool, EbpUndefined, EvqConst, 1));
return node;
}
class SimplifyLoopConditionsTraverser : public TLValueTrackingTraverser
{
public:
SimplifyLoopConditionsTraverser(unsigned int conditionsToSimplifyMask,
const TSymbolTable &symbolTable,
int shaderVersion);
void traverseLoop(TIntermLoop *node) override;
bool visitBinary(Visit visit, TIntermBinary *node) override;
bool visitAggregate(Visit visit, TIntermAggregate *node) override;
bool visitSelection(Visit visit, TIntermSelection *node) override;
void nextIteration();
bool foundLoopToChange() const { return mFoundLoopToChange; }
protected:
// Marked to true once an operation that needs to be hoisted out of the expression has been
// found. After that, no more AST updates are performed on that traversal.
bool mFoundLoopToChange;
bool mInsideLoopConditionOrExpression;
IntermNodePatternMatcher mConditionsToSimplify;
};
SimplifyLoopConditionsTraverser::SimplifyLoopConditionsTraverser(
unsigned int conditionsToSimplifyMask,
const TSymbolTable &symbolTable,
int shaderVersion)
: TLValueTrackingTraverser(true, false, false, symbolTable, shaderVersion),
mFoundLoopToChange(false),
mInsideLoopConditionOrExpression(false),
mConditionsToSimplify(conditionsToSimplifyMask)
{
}
void SimplifyLoopConditionsTraverser::nextIteration()
{
mFoundLoopToChange = false;
mInsideLoopConditionOrExpression = false;
nextTemporaryIndex();
}
bool SimplifyLoopConditionsTraverser::visitBinary(Visit visit, TIntermBinary *node)
{
// The visit functions operate in three modes:
// 1. If a matching expression has already been found, we return early since only one loop can
// be transformed on one traversal.
// 2. We try to find loops. In case a node is not inside a loop and can not contain loops, we
// stop traversing the subtree.
// 3. If we're inside a loop condition or expression, we check for expressions that should be
// moved out of the loop condition or expression. If one is found, the loop is processed.
if (mFoundLoopToChange)
return false;
if (!mInsideLoopConditionOrExpression)
return false;
mFoundLoopToChange = mConditionsToSimplify.match(node, getParentNode(), isLValueRequiredHere());
return !mFoundLoopToChange;
}
bool SimplifyLoopConditionsTraverser::visitAggregate(Visit visit, TIntermAggregate *node)
{
if (mFoundLoopToChange)
return false;
// If we're outside a loop condition, we only need to traverse nodes that may contain loops.
if (!mInsideLoopConditionOrExpression)
return (node->getOp() == EOpSequence || node->getOp() == EOpFunction);
mFoundLoopToChange = mConditionsToSimplify.match(node, getParentNode());
return !mFoundLoopToChange;
}
bool SimplifyLoopConditionsTraverser::visitSelection(Visit visit, TIntermSelection *node)
{
if (mFoundLoopToChange)
return false;
// Don't traverse ternary operators outside loop conditions.
if (!mInsideLoopConditionOrExpression)
return !node->usesTernaryOperator();
mFoundLoopToChange = mConditionsToSimplify.match(node);
return !mFoundLoopToChange;
}
void SimplifyLoopConditionsTraverser::traverseLoop(TIntermLoop *node)
{
if (mFoundLoopToChange)
return;
// Mark that we're inside a loop condition or expression, and transform the loop if needed.
incrementDepth(node);
// Note: No need to traverse the loop init node.
mInsideLoopConditionOrExpression = true;
TLoopType loopType = node->getType();
if (node->getCondition())
{
node->getCondition()->traverse(this);
if (mFoundLoopToChange)
{
// Replace the loop condition with a boolean variable that's updated on each iteration.
if (loopType == ELoopWhile)
{
// Transform:
// while (expr) { body; }
// into
// bool s0 = expr;
// while (s0) { { body; } s0 = expr; }
TIntermSequence tempInitSeq;
tempInitSeq.push_back(createTempInitDeclaration(node->getCondition()->deepCopy()));
insertStatementsInParentBlock(tempInitSeq);
TIntermAggregate *newBody = new TIntermAggregate(EOpSequence);
if (node->getBody())
{
ASSERT(node->getBody()->getOp() == EOpSequence);
newBody->getSequence()->push_back(node->getBody());
}
newBody->getSequence()->push_back(
createTempAssignment(node->getCondition()->deepCopy()));
// Can't use queueReplacement to replace old body, since it may have been nullptr.
// It's safe to do the replacements in place here - this node won't be traversed
// further.
node->setBody(newBody);
node->setCondition(createTempSymbol(node->getCondition()->getType()));
}
else if (loopType == ELoopDoWhile)
{
// Transform:
// do {
// body;
// } while (expr);
// into
// bool s0 = true;
// do {
// { body; }
// s0 = expr;
// while (s0);
TIntermSequence tempInitSeq;
tempInitSeq.push_back(createTempInitDeclaration(CreateBoolConstantNode(true)));
insertStatementsInParentBlock(tempInitSeq);
TIntermAggregate *newBody = new TIntermAggregate(EOpSequence);
if (node->getBody())
{
ASSERT(node->getBody()->getOp() == EOpSequence);
newBody->getSequence()->push_back(node->getBody());
}
newBody->getSequence()->push_back(
createTempAssignment(node->getCondition()->deepCopy()));
// Can't use queueReplacement to replace old body, since it may have been nullptr.
// It's safe to do the replacements in place here - this node won't be traversed
// further.
node->setBody(newBody);
node->setCondition(createTempSymbol(node->getCondition()->getType()));
}
else if (loopType == ELoopFor)
{
// Move the loop condition inside the loop.
// Transform:
// for (init; expr; exprB) { body; }
// into
// {
// init;
// bool s0 = expr;
// while (s0) { { body; } exprB; s0 = expr; }
// }
TIntermAggregate *loopScope = new TIntermAggregate(EOpSequence);
if (node->getInit())
{
loopScope->getSequence()->push_back(node->getInit());
}
loopScope->getSequence()->push_back(
createTempInitDeclaration(node->getCondition()->deepCopy()));
TIntermAggregate *whileLoopBody = new TIntermAggregate(EOpSequence);
if (node->getBody())
{
whileLoopBody->getSequence()->push_back(node->getBody());
}
whileLoopBody->getSequence()->push_back(node->getExpression());
whileLoopBody->getSequence()->push_back(
createTempAssignment(node->getCondition()->deepCopy()));
TIntermLoop *whileLoop = new TIntermLoop(
ELoopWhile, nullptr, createTempSymbol(node->getCondition()->getType()), nullptr,
whileLoopBody);
loopScope->getSequence()->push_back(whileLoop);
queueReplacementWithParent(getAncestorNode(1), node, loopScope,
OriginalNode::IS_DROPPED);
}
}
}
if (!mFoundLoopToChange && node->getExpression())
{
node->getExpression()->traverse(this);
if (mFoundLoopToChange)
{
ASSERT(loopType == ELoopFor);
// Move the loop expression to inside the loop.
// Transform:
// for (init; expr; exprB) { body; }
// into
// for (init; expr; ) { { body; } exprB; }
TIntermTyped *loopExpression = node->getExpression();
node->setExpression(nullptr);
TIntermAggregate *oldBody = node->getBody();
node->setBody(new TIntermAggregate(EOpSequence));
if (oldBody != nullptr)
{
node->getBody()->getSequence()->push_back(oldBody);
}
node->getBody()->getSequence()->push_back(loopExpression);
}
}
mInsideLoopConditionOrExpression = false;
if (!mFoundLoopToChange && node->getBody())
node->getBody()->traverse(this);
decrementDepth();
}
} // namespace
void SimplifyLoopConditions(TIntermNode *root,
unsigned int conditionsToSimplifyMask,
unsigned int *temporaryIndex,
const TSymbolTable &symbolTable,
int shaderVersion)
{
SimplifyLoopConditionsTraverser traverser(conditionsToSimplifyMask, symbolTable, shaderVersion);
ASSERT(temporaryIndex != nullptr);
traverser.useTemporaryIndex(temporaryIndex);
// Process one loop at a time, and reset the traverser between iterations.
do
{
traverser.nextIteration();
root->traverse(&traverser);
if (traverser.foundLoopToChange())
traverser.updateTree();
} while (traverser.foundLoopToChange());
}
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