src/compiler/translator/LoopInfo.cpp - fp2-dev/platform/external/chromium_org/third_party/angle - Gitiles

 //
 // 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.
 //

 #include "compiler/translator/LoopInfo.h"

 namespace
 {

 int EvaluateIntConstant(TIntermConstantUnion *node)
 {
     ASSERT(node && node->getUnionArrayPointer());
     return node->getIConst(0);
 }

 int GetLoopIntIncrement(TIntermLoop *node)
 {
     TIntermNode *expr = node->getExpression();
     // 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 ? NULL : expr->getAsBinaryNode();

     TOperator op = EOpNull;
     TIntermConstantUnion *incrementNode = NULL;
     if (unOp)
     {
         op = unOp->getOp();
     }
     else if (binOp)
     {
         op = binOp->getOp();
         ASSERT(binOp->getRight());
         incrementNode = binOp->getRight()->getAsConstantUnion();
         ASSERT(incrementNode);
     }

     int increment = 0;
     // The operator is one of: ++ -- += -=.
     switch (op)
     {
       case EOpPostIncrement:
       case EOpPreIncrement:
         ASSERT(unOp && !binOp);
         increment = 1;
         break;
       case EOpPostDecrement:
       case EOpPreDecrement:
         ASSERT(unOp && !binOp);
         increment = -1;
         break;
       case EOpAddAssign:
         ASSERT(!unOp && binOp);
         increment = EvaluateIntConstant(incrementNode);
         break;
       case EOpSubAssign:
         ASSERT(!unOp && binOp);
         increment = - EvaluateIntConstant(incrementNode);
         break;
       default:
         UNREACHABLE();
     }

     return increment;
 }

 }  // namespace anonymous

 TLoopIndexInfo::TLoopIndexInfo()
     : mId(-1),
       mType(EbtVoid),
       mInitValue(0),
       mStopValue(0),
       mIncrementValue(0),
       mOp(EOpNull),
       mCurrentValue(0)
 {
 }

 void TLoopIndexInfo::fillInfo(TIntermLoop *node)
 {
     if (node == NULL)
         return;

     // Here we assume all the operations are valid, because the loop node is
     // already validated in ValidateLimitations.
     TIntermSequence &declSeq =
         node->getInit()->getAsAggregate()->getSequence();
     TIntermBinary *declInit = declSeq[0]->getAsBinaryNode();
     TIntermSymbol *symbol = declInit->getLeft()->getAsSymbolNode();

     mId = symbol->getId();
     mType = symbol->getBasicType();

     if (mType == EbtInt)
     {
         TIntermConstantUnion* initNode = declInit->getRight()->getAsConstantUnion();
         mInitValue = EvaluateIntConstant(initNode);
         mCurrentValue = mInitValue;
         mIncrementValue = GetLoopIntIncrement(node);

         TIntermBinary* binOp = node->getCondition()->getAsBinaryNode();
         mStopValue = EvaluateIntConstant(
             binOp->getRight()->getAsConstantUnion());
         mOp = binOp->getOp();
     }
 }

 bool TLoopIndexInfo::satisfiesLoopCondition() const
 {
     // Relational operator is one of: > >= < <= == or !=.
     switch (mOp)
     {
       case EOpEqual:
         return (mCurrentValue == mStopValue);
       case EOpNotEqual:
         return (mCurrentValue != mStopValue);
       case EOpLessThan:
         return (mCurrentValue < mStopValue);
       case EOpGreaterThan:
         return (mCurrentValue > mStopValue);
       case EOpLessThanEqual:
         return (mCurrentValue <= mStopValue);
       case EOpGreaterThanEqual:
         return (mCurrentValue >= mStopValue);
       default:
         UNREACHABLE();
         return false;
     }
 }

 TLoopInfo::TLoopInfo()
     : loop(NULL)
 {
 }

 TLoopInfo::TLoopInfo(TIntermLoop *node)
     : loop(node)
 {
     index.fillInfo(node);
 }

 TIntermLoop *TLoopStack::findLoop(TIntermSymbol *symbol)
 {
     if (!symbol)
         return NULL;
     for (iterator iter = begin(); iter != end(); ++iter)
     {
         if (iter->index.getId() == symbol->getId())
             return iter->loop;
     }
     return NULL;
 }

 TLoopIndexInfo *TLoopStack::getIndexInfo(TIntermSymbol *symbol)
 {
     if (!symbol)
         return NULL;
     for (iterator iter = begin(); iter != end(); ++iter)
     {
         if (iter->index.getId() == symbol->getId())
             return &(iter->index);
     }
     return NULL;
 }

 void TLoopStack::step()
 {
     ASSERT(!empty());
     rbegin()->index.step();
 }

 bool TLoopStack::satisfiesLoopCondition()
 {
     ASSERT(!empty());
     return rbegin()->index.satisfiesLoopCondition();
 }

 bool TLoopStack::needsToReplaceSymbolWithValue(TIntermSymbol *symbol)
 {
     TIntermLoop *loop = findLoop(symbol);
     return loop && loop->getUnrollFlag();
 }

 int TLoopStack::getLoopIndexValue(TIntermSymbol *symbol)
 {
     TLoopIndexInfo *info = getIndexInfo(symbol);
     ASSERT(info);
     return info->getCurrentValue();
 }

 void TLoopStack::push(TIntermLoop *loop)
 {
     TLoopInfo info(loop);
     push_back(info);
 }

 void TLoopStack::pop()
 {
     pop_back();
 }
	//
	// 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.
	//

	#include "compiler/translator/LoopInfo.h"

	namespace
	{

	int EvaluateIntConstant(TIntermConstantUnion *node)
	{
	ASSERT(node && node->getUnionArrayPointer());
	return node->getIConst(0);
	}

	int GetLoopIntIncrement(TIntermLoop *node)
	{
	TIntermNode *expr = node->getExpression();
	// 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 ? NULL : expr->getAsBinaryNode();

	TOperator op = EOpNull;
	TIntermConstantUnion *incrementNode = NULL;
	if (unOp)
	{
	op = unOp->getOp();
	}
	else if (binOp)
	{
	op = binOp->getOp();
	ASSERT(binOp->getRight());
	incrementNode = binOp->getRight()->getAsConstantUnion();
	ASSERT(incrementNode);
	}

	int increment = 0;
	// The operator is one of: ++ -- += -=.
	switch (op)
	{
	case EOpPostIncrement:
	case EOpPreIncrement:
	ASSERT(unOp && !binOp);
	increment = 1;
	break;
	case EOpPostDecrement:
	case EOpPreDecrement:
	ASSERT(unOp && !binOp);
	increment = -1;
	break;
	case EOpAddAssign:
	ASSERT(!unOp && binOp);
	increment = EvaluateIntConstant(incrementNode);
	break;
	case EOpSubAssign:
	ASSERT(!unOp && binOp);
	increment = - EvaluateIntConstant(incrementNode);
	break;
	default:
	UNREACHABLE();
	}

	return increment;
	}

	} // namespace anonymous

	TLoopIndexInfo::TLoopIndexInfo()
	: mId(-1),
	mType(EbtVoid),
	mInitValue(0),
	mStopValue(0),
	mIncrementValue(0),
	mOp(EOpNull),
	mCurrentValue(0)
	{
	}

	void TLoopIndexInfo::fillInfo(TIntermLoop *node)
	{
	if (node == NULL)
	return;

	// Here we assume all the operations are valid, because the loop node is
	// already validated in ValidateLimitations.
	TIntermSequence &declSeq =
	node->getInit()->getAsAggregate()->getSequence();
	TIntermBinary *declInit = declSeq[0]->getAsBinaryNode();
	TIntermSymbol *symbol = declInit->getLeft()->getAsSymbolNode();

	mId = symbol->getId();
	mType = symbol->getBasicType();

	if (mType == EbtInt)
	{
	TIntermConstantUnion* initNode = declInit->getRight()->getAsConstantUnion();
	mInitValue = EvaluateIntConstant(initNode);
	mCurrentValue = mInitValue;
	mIncrementValue = GetLoopIntIncrement(node);

	TIntermBinary* binOp = node->getCondition()->getAsBinaryNode();
	mStopValue = EvaluateIntConstant(
	binOp->getRight()->getAsConstantUnion());
	mOp = binOp->getOp();
	}
	}

	bool TLoopIndexInfo::satisfiesLoopCondition() const
	{
	// Relational operator is one of: > >= < <= == or !=.
	switch (mOp)
	{
	case EOpEqual:
	return (mCurrentValue == mStopValue);
	case EOpNotEqual:
	return (mCurrentValue != mStopValue);
	case EOpLessThan:
	return (mCurrentValue < mStopValue);
	case EOpGreaterThan:
	return (mCurrentValue > mStopValue);
	case EOpLessThanEqual:
	return (mCurrentValue <= mStopValue);
	case EOpGreaterThanEqual:
	return (mCurrentValue >= mStopValue);
	default:
	UNREACHABLE();
	return false;
	}
	}

	TLoopInfo::TLoopInfo()
	: loop(NULL)
	{
	}

	TLoopInfo::TLoopInfo(TIntermLoop *node)
	: loop(node)
	{
	index.fillInfo(node);
	}

	TIntermLoop TLoopStack::findLoop(TIntermSymbol symbol)
	{
	if (!symbol)
	return NULL;
	for (iterator iter = begin(); iter != end(); ++iter)
	{
	if (iter->index.getId() == symbol->getId())
	return iter->loop;
	}
	return NULL;
	}

	TLoopIndexInfo TLoopStack::getIndexInfo(TIntermSymbol symbol)
	{
	if (!symbol)
	return NULL;
	for (iterator iter = begin(); iter != end(); ++iter)
	{
	if (iter->index.getId() == symbol->getId())
	return &(iter->index);
	}
	return NULL;
	}

	void TLoopStack::step()
	{
	ASSERT(!empty());
	rbegin()->index.step();
	}

	bool TLoopStack::satisfiesLoopCondition()
	{
	ASSERT(!empty());
	return rbegin()->index.satisfiesLoopCondition();
	}

	bool TLoopStack::needsToReplaceSymbolWithValue(TIntermSymbol *symbol)
	{
	TIntermLoop *loop = findLoop(symbol);
	return loop && loop->getUnrollFlag();
	}

	int TLoopStack::getLoopIndexValue(TIntermSymbol *symbol)
	{
	TLoopIndexInfo *info = getIndexInfo(symbol);
	ASSERT(info);
	return info->getCurrentValue();
	}

	void TLoopStack::push(TIntermLoop *loop)
	{
	TLoopInfo info(loop);
	push_back(info);
	}

	void TLoopStack::pop()
	{
	pop_back();
	}