src/third_party/angle/src/compiler/UnfoldShortCircuit.cpp - cobalt - Git at Google

 //
 // 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.
 //
 // UnfoldShortCircuit is an AST traverser to output short-circuiting operators as if-else statements.
 // The results are assigned to s# temporaries, which are used by the main translator instead of
 // the original expression.
 //

 #include "compiler/UnfoldShortCircuit.h"

 #include "compiler/InfoSink.h"
 #include "compiler/OutputHLSL.h"

 namespace sh
 {
 UnfoldShortCircuit::UnfoldShortCircuit(TParseContext &context, OutputHLSL *outputHLSL) : mContext(context), mOutputHLSL(outputHLSL)
 {
     mTemporaryIndex = 0;
 }

 void UnfoldShortCircuit::traverse(TIntermNode *node)
 {
     int rewindIndex = mTemporaryIndex;
     node->traverse(this);
     mTemporaryIndex = rewindIndex;
 }

 bool UnfoldShortCircuit::visitBinary(Visit visit, TIntermBinary *node)
 {
     TInfoSinkBase &out = mOutputHLSL->getBodyStream();

     switch (node->getOp())
     {
       case EOpLogicalOr:
         // "x || y" is equivalent to "x ? true : y", which unfolds to "bool s; if(x) s = true; else s = y;",
         // and then further simplifies down to "bool s = x; if(!s) s = y;".
         {
             int i = mTemporaryIndex;

             out << "bool s" << i << ";\n";

             out << "{\n";

             mTemporaryIndex = i + 1;
             node->getLeft()->traverse(this);
             out << "s" << i << " = ";
             mTemporaryIndex = i + 1;
             node->getLeft()->traverse(mOutputHLSL);
             out << ";\n";
             out << "if(!s" << i << ")\n"
                    "{\n";
             mTemporaryIndex = i + 1;
             node->getRight()->traverse(this);
             out << "    s" << i << " = ";
             mTemporaryIndex = i + 1;
             node->getRight()->traverse(mOutputHLSL);
             out << ";\n"
                    "}\n";

             out << "}\n";

             mTemporaryIndex = i + 1;
         }
         return false;
       case EOpLogicalAnd:
         // "x && y" is equivalent to "x ? y : false", which unfolds to "bool s; if(x) s = y; else s = false;",
         // and then further simplifies down to "bool s = x; if(s) s = y;".
         {
             int i = mTemporaryIndex;

             out << "bool s" << i << ";\n";

             out << "{\n";

             mTemporaryIndex = i + 1;
             node->getLeft()->traverse(this);
             out << "s" << i << " = ";
             mTemporaryIndex = i + 1;
             node->getLeft()->traverse(mOutputHLSL);
             out << ";\n";
             out << "if(s" << i << ")\n"
                    "{\n";
             mTemporaryIndex = i + 1;
             node->getRight()->traverse(this);
             out << "    s" << i << " = ";
             mTemporaryIndex = i + 1;
             node->getRight()->traverse(mOutputHLSL);
             out << ";\n"
                    "}\n";

             out << "}\n";

             mTemporaryIndex = i + 1;
         }
         return false;
       default:
         return true;
     }
 }

 bool UnfoldShortCircuit::visitSelection(Visit visit, TIntermSelection *node)
 {
     TInfoSinkBase &out = mOutputHLSL->getBodyStream();

     // Unfold "b ? x : y" into "type s; if(b) s = x; else s = y;"
     if (node->usesTernaryOperator())
     {
         int i = mTemporaryIndex;

         out << mOutputHLSL->typeString(node->getType()) << " s" << i << ";\n";

         out << "{\n";

         mTemporaryIndex = i + 1;
         node->getCondition()->traverse(this);
         out << "if(";
         mTemporaryIndex = i + 1;
         node->getCondition()->traverse(mOutputHLSL);
         out << ")\n"
                "{\n";
         mTemporaryIndex = i + 1;
         node->getTrueBlock()->traverse(this);
         out << "    s" << i << " = ";
         mTemporaryIndex = i + 1;
         node->getTrueBlock()->traverse(mOutputHLSL);
         out << ";\n"
                "}\n"
                "else\n"
                "{\n";
         mTemporaryIndex = i + 1;
         node->getFalseBlock()->traverse(this);
         out << "    s" << i << " = ";
         mTemporaryIndex = i + 1;
         node->getFalseBlock()->traverse(mOutputHLSL);
         out << ";\n"
                "}\n";

         out << "}\n";

         mTemporaryIndex = i + 1;
     }

     return false;
 }

 bool UnfoldShortCircuit::visitLoop(Visit visit, TIntermLoop *node)
 {
     int rewindIndex = mTemporaryIndex;

     if (node->getInit())
     {
         node->getInit()->traverse(this);
     }

     if (node->getCondition())
     {
         node->getCondition()->traverse(this);
     }

     if (node->getExpression())
     {
         node->getExpression()->traverse(this);
     }

     mTemporaryIndex = rewindIndex;

     return false;
 }

 int UnfoldShortCircuit::getNextTemporaryIndex()
 {
     return mTemporaryIndex++;
 }
 }
	//
	// 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.
	//
	// UnfoldShortCircuit is an AST traverser to output short-circuiting operators as if-else statements.
	// The results are assigned to s# temporaries, which are used by the main translator instead of
	// the original expression.
	//

	#include "compiler/UnfoldShortCircuit.h"

	#include "compiler/InfoSink.h"
	#include "compiler/OutputHLSL.h"

	namespace sh
	{
	UnfoldShortCircuit::UnfoldShortCircuit(TParseContext &context, OutputHLSL *outputHLSL) : mContext(context), mOutputHLSL(outputHLSL)
	{
	mTemporaryIndex = 0;
	}

	void UnfoldShortCircuit::traverse(TIntermNode *node)
	{
	int rewindIndex = mTemporaryIndex;
	node->traverse(this);
	mTemporaryIndex = rewindIndex;
	}

	bool UnfoldShortCircuit::visitBinary(Visit visit, TIntermBinary *node)
	{
	TInfoSinkBase &out = mOutputHLSL->getBodyStream();

	switch (node->getOp())
	{
	case EOpLogicalOr:
	// "x \|\| y" is equivalent to "x ? true : y", which unfolds to "bool s; if(x) s = true; else s = y;",
	// and then further simplifies down to "bool s = x; if(!s) s = y;".
	{
	int i = mTemporaryIndex;

	out << "bool s" << i << ";\n";

	out << "{\n";

	mTemporaryIndex = i + 1;
	node->getLeft()->traverse(this);
	out << "s" << i << " = ";
	mTemporaryIndex = i + 1;
	node->getLeft()->traverse(mOutputHLSL);
	out << ";\n";
	out << "if(!s" << i << ")\n"
	"{\n";
	mTemporaryIndex = i + 1;
	node->getRight()->traverse(this);
	out << " s" << i << " = ";
	mTemporaryIndex = i + 1;
	node->getRight()->traverse(mOutputHLSL);
	out << ";\n"
	"}\n";

	out << "}\n";

	mTemporaryIndex = i + 1;
	}
	return false;
	case EOpLogicalAnd:
	// "x && y" is equivalent to "x ? y : false", which unfolds to "bool s; if(x) s = y; else s = false;",
	// and then further simplifies down to "bool s = x; if(s) s = y;".
	{
	int i = mTemporaryIndex;

	out << "bool s" << i << ";\n";

	out << "{\n";

	mTemporaryIndex = i + 1;
	node->getLeft()->traverse(this);
	out << "s" << i << " = ";
	mTemporaryIndex = i + 1;
	node->getLeft()->traverse(mOutputHLSL);
	out << ";\n";
	out << "if(s" << i << ")\n"
	"{\n";
	mTemporaryIndex = i + 1;
	node->getRight()->traverse(this);
	out << " s" << i << " = ";
	mTemporaryIndex = i + 1;
	node->getRight()->traverse(mOutputHLSL);
	out << ";\n"
	"}\n";

	out << "}\n";

	mTemporaryIndex = i + 1;
	}
	return false;
	default:
	return true;
	}
	}

	bool UnfoldShortCircuit::visitSelection(Visit visit, TIntermSelection *node)
	{
	TInfoSinkBase &out = mOutputHLSL->getBodyStream();

	// Unfold "b ? x : y" into "type s; if(b) s = x; else s = y;"
	if (node->usesTernaryOperator())
	{
	int i = mTemporaryIndex;

	out << mOutputHLSL->typeString(node->getType()) << " s" << i << ";\n";

	out << "{\n";

	mTemporaryIndex = i + 1;
	node->getCondition()->traverse(this);
	out << "if(";
	mTemporaryIndex = i + 1;
	node->getCondition()->traverse(mOutputHLSL);
	out << ")\n"
	"{\n";
	mTemporaryIndex = i + 1;
	node->getTrueBlock()->traverse(this);
	out << " s" << i << " = ";
	mTemporaryIndex = i + 1;
	node->getTrueBlock()->traverse(mOutputHLSL);
	out << ";\n"
	"}\n"
	"else\n"
	"{\n";
	mTemporaryIndex = i + 1;
	node->getFalseBlock()->traverse(this);
	out << " s" << i << " = ";
	mTemporaryIndex = i + 1;
	node->getFalseBlock()->traverse(mOutputHLSL);
	out << ";\n"
	"}\n";

	out << "}\n";

	mTemporaryIndex = i + 1;
	}

	return false;
	}

	bool UnfoldShortCircuit::visitLoop(Visit visit, TIntermLoop *node)
	{
	int rewindIndex = mTemporaryIndex;

	if (node->getInit())
	{
	node->getInit()->traverse(this);
	}

	if (node->getCondition())
	{
	node->getCondition()->traverse(this);
	}

	if (node->getExpression())
	{
	node->getExpression()->traverse(this);
	}

	mTemporaryIndex = rewindIndex;

	return false;
	}

	int UnfoldShortCircuit::getNextTemporaryIndex()
	{
	return mTemporaryIndex++;
	}
	}