Source/JavaScriptCore/dfg/DFGBackwardsPropagationPhase.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2013-2015 Apple Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "DFGBackwardsPropagationPhase.h"

 #if ENABLE(DFG_JIT)

 #include "DFGBasicBlockInlines.h"
 #include "DFGGraph.h"
 #include "DFGPhase.h"
 #include "JSCInlines.h"

 namespace JSC { namespace DFG {

 class BackwardsPropagationPhase : public Phase {
 public:
     BackwardsPropagationPhase(Graph& graph)
         : Phase(graph, "backwards propagation")
     {
     }

     bool run()
     {
         m_changed = true;
         while (m_changed) {
             m_changed = false;
             for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
                 BasicBlock* block = m_graph.block(blockIndex);
                 if (!block)
                     continue;

                 // Prevent a tower of overflowing additions from creating a value that is out of the
                 // safe 2^48 range.
                 m_allowNestedOverflowingAdditions = block->size() < (1 << 16);

                 for (unsigned indexInBlock = block->size(); indexInBlock--;)
                     propagate(block->at(indexInBlock));
             }
         }

         return true;
     }

 private:
     bool isNotNegZero(Node* node)
     {
         if (!node->isNumberConstant())
             return false;
         double value = node->asNumber();
         return (value || 1.0 / value > 0.0);
     }

     bool isNotPosZero(Node* node)
     {
         if (!node->isNumberConstant())
             return false;
         double value = node->asNumber();
         return (value || 1.0 / value < 0.0);
     }

     // Tests if the absolute value is strictly less than the power of two.
     template<int power>
     bool isWithinPowerOfTwoForConstant(Node* node)
     {
         JSValue immediateValue = node->asJSValue();
         if (!immediateValue.isNumber())
             return false;
         double immediate = immediateValue.asNumber();
         return immediate > -(static_cast<int64_t>(1) << power) && immediate < (static_cast<int64_t>(1) << power);
     }

     template<int power>
     bool isWithinPowerOfTwoNonRecursive(Node* node)
     {
         if (!node->isNumberConstant())
             return false;
         return isWithinPowerOfTwoForConstant<power>(node);
     }

     template<int power>
     bool isWithinPowerOfTwo(Node* node)
     {
         switch (node->op()) {
         case DoubleConstant:
         case JSConstant:
         case Int52Constant: {
             return isWithinPowerOfTwoForConstant<power>(node);
         }

         case ValueBitAnd:
         case ArithBitAnd: {
             if (power > 31)
                 return true;

             return isWithinPowerOfTwoNonRecursive<power>(node->child1().node())
                 || isWithinPowerOfTwoNonRecursive<power>(node->child2().node());
         }

         case ArithBitOr:
         case ArithBitXor:
         case ValueBitOr:
         case ValueBitXor:
         case ValueBitLShift:
         case ArithBitLShift: {
             return power > 31;
         }

         case ArithBitRShift:
         case ValueBitRShift:
         case BitURShift: {
             if (power > 31)
                 return true;

             Node* shiftAmount = node->child2().node();
             if (!node->isNumberConstant())
                 return false;
             JSValue immediateValue = shiftAmount->asJSValue();
             if (!immediateValue.isInt32())
                 return false;
             return immediateValue.asInt32() > 32 - power;
         }

         default:
             return false;
         }
     }

     template<int power>
     bool isWithinPowerOfTwo(Edge edge)
     {
         return isWithinPowerOfTwo<power>(edge.node());
     }

     bool mergeDefaultFlags(Node* node)
     {
         bool changed = false;
         if (node->flags() & NodeHasVarArgs) {
             for (unsigned childIdx = node->firstChild();
                 childIdx < node->firstChild() + node->numChildren();
                 childIdx++) {
                 if (!!m_graph.m_varArgChildren[childIdx])
                     changed |= m_graph.m_varArgChildren[childIdx]->mergeFlags(NodeBytecodeUsesAsValue);
             }
         } else {
             if (!node->child1())
                 return changed;
             changed |= node->child1()->mergeFlags(NodeBytecodeUsesAsValue);
             if (!node->child2())
                 return changed;
             changed |= node->child2()->mergeFlags(NodeBytecodeUsesAsValue);
             if (!node->child3())
                 return changed;
             changed |= node->child3()->mergeFlags(NodeBytecodeUsesAsValue);
         }
         return changed;
     }

     void propagate(Node* node)
     {
         NodeFlags flags = node->flags() & NodeBytecodeBackPropMask;

         switch (node->op()) {
         case GetLocal: {
             VariableAccessData* variableAccessData = node->variableAccessData();
             flags &= ~NodeBytecodeUsesAsInt; // We don't care about cross-block uses-as-int.
             m_changed |= variableAccessData->mergeFlags(flags);
             break;
         }

         case SetLocal: {
             VariableAccessData* variableAccessData = node->variableAccessData();
             if (!variableAccessData->isLoadedFrom())
                 break;
             flags = variableAccessData->flags();
             RELEASE_ASSERT(!(flags & ~NodeBytecodeBackPropMask));
             flags |= NodeBytecodeUsesAsNumber; // Account for the fact that control flow may cause overflows that our modeling can't handle.
             node->child1()->mergeFlags(flags);
             break;
         }

         case Flush: {
             VariableAccessData* variableAccessData = node->variableAccessData();
             m_changed |= variableAccessData->mergeFlags(NodeBytecodeUsesAsValue);
             break;
         }

         case MovHint:
         case Check:
         case CheckVarargs:
             break;

         case ValueBitNot:
         case ArithBitNot: {
             flags |= NodeBytecodeUsesAsInt;
             flags &= ~(NodeBytecodeUsesAsNumber | NodeBytecodeNeedsNegZero | NodeBytecodeUsesAsOther);
             flags &= ~NodeBytecodeUsesAsArrayIndex;
             node->child1()->mergeFlags(flags);
             break;
         }

         case ArithBitAnd:
         case ArithBitOr:
         case ArithBitXor:
         case ValueBitAnd:
         case ValueBitOr:
         case ValueBitXor:
         case ValueBitLShift:
         case ArithBitLShift:
         case ArithBitRShift:
         case ValueBitRShift:
         case BitURShift:
         case ArithIMul: {
             flags |= NodeBytecodeUsesAsInt;
             flags &= ~(NodeBytecodeUsesAsNumber | NodeBytecodeNeedsNegZero | NodeBytecodeUsesAsOther);
             flags &= ~NodeBytecodeUsesAsArrayIndex;
             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags);
             break;
         }

         case StringCharAt:
         case StringCharCodeAt:
         case StringCodePointAt: {
             node->child1()->mergeFlags(NodeBytecodeUsesAsValue);
             node->child2()->mergeFlags(NodeBytecodeUsesAsValue | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
             break;
         }

         case StringSlice: {
             node->child1()->mergeFlags(NodeBytecodeUsesAsValue);
             node->child2()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
             if (node->child3())
                 node->child3()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
             break;
         }

         case ArraySlice: {
             m_graph.varArgChild(node, 0)->mergeFlags(NodeBytecodeUsesAsValue);

             if (node->numChildren() == 2)
                 m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsValue);
             else if (node->numChildren() == 3) {
                 m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
                 m_graph.varArgChild(node, 2)->mergeFlags(NodeBytecodeUsesAsValue);
             } else if (node->numChildren() == 4) {
                 m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
                 m_graph.varArgChild(node, 2)->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
                 m_graph.varArgChild(node, 3)->mergeFlags(NodeBytecodeUsesAsValue);
             }
             break;
         }


         case UInt32ToNumber: {
             node->child1()->mergeFlags(flags);
             break;
         }

         case ValueAdd: {
             if (isNotNegZero(node->child1().node()) || isNotNegZero(node->child2().node()))
                 flags &= ~NodeBytecodeNeedsNegZero;
             if (node->child1()->hasNumericResult() || node->child2()->hasNumericResult() || node->child1()->hasNumberResult() || node->child2()->hasNumberResult())
                 flags &= ~NodeBytecodeUsesAsOther;
             if (!isWithinPowerOfTwo<32>(node->child1()) && !isWithinPowerOfTwo<32>(node->child2()))
                 flags |= NodeBytecodeUsesAsNumber;
             if (!m_allowNestedOverflowingAdditions)
                 flags |= NodeBytecodeUsesAsNumber;

             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags);
             break;
         }

         case ArithAdd: {
             flags &= ~NodeBytecodeUsesAsOther;
             if (isNotNegZero(node->child1().node()) || isNotNegZero(node->child2().node()))
                 flags &= ~NodeBytecodeNeedsNegZero;
             if (!isWithinPowerOfTwo<32>(node->child1()) && !isWithinPowerOfTwo<32>(node->child2()))
                 flags |= NodeBytecodeUsesAsNumber;
             if (!m_allowNestedOverflowingAdditions)
                 flags |= NodeBytecodeUsesAsNumber;

             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags);
             break;
         }

         case ArithClz32: {
             flags &= ~(NodeBytecodeUsesAsNumber | NodeBytecodeNeedsNegZero | NodeBytecodeUsesAsOther | ~NodeBytecodeUsesAsArrayIndex);
             flags |= NodeBytecodeUsesAsInt;
             node->child1()->mergeFlags(flags);
             break;
         }

         case ArithSub: {
             flags &= ~NodeBytecodeUsesAsOther;
             if (isNotNegZero(node->child1().node()) || isNotPosZero(node->child2().node()))
                 flags &= ~NodeBytecodeNeedsNegZero;
             if (!isWithinPowerOfTwo<32>(node->child1()) && !isWithinPowerOfTwo<32>(node->child2()))
                 flags |= NodeBytecodeUsesAsNumber;
             if (!m_allowNestedOverflowingAdditions)
                 flags |= NodeBytecodeUsesAsNumber;

             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags);
             break;
         }

         case ArithNegate: {
             flags &= ~NodeBytecodeUsesAsOther;

             node->child1()->mergeFlags(flags);
             break;
         }

         case ValueMul:
         case ArithMul: {
             // As soon as a multiply happens, we can easily end up in the part
             // of the double domain where the point at which you do truncation
             // can change the outcome. So, ArithMul always forces its inputs to
             // check for overflow. Additionally, it will have to check for overflow
             // itself unless we can prove that there is no way for the values
             // produced to cause double rounding.

             if (!isWithinPowerOfTwo<22>(node->child1().node())
                 && !isWithinPowerOfTwo<22>(node->child2().node()))
                 flags |= NodeBytecodeUsesAsNumber;

             node->mergeFlags(flags);

             flags |= NodeBytecodeUsesAsNumber | NodeBytecodeNeedsNegZero;
             flags &= ~NodeBytecodeUsesAsOther;

             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags);
             break;
         }

         case ValueDiv:
         case ArithDiv: {
             flags |= NodeBytecodeUsesAsNumber | NodeBytecodeNeedsNegZero;
             flags &= ~NodeBytecodeUsesAsOther;

             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags);
             break;
         }

         case ValueMod:
         case ArithMod: {
             flags |= NodeBytecodeUsesAsNumber;
             flags &= ~NodeBytecodeUsesAsOther;

             node->child1()->mergeFlags(flags);
             node->child2()->mergeFlags(flags & ~NodeBytecodeNeedsNegZero);
             break;
         }

         case GetByVal: {
             m_graph.varArgChild(node, 0)->mergeFlags(NodeBytecodeUsesAsValue);
             m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
             break;
         }

         case NewTypedArray:
         case NewArrayWithSize: {
             // Negative zero is not observable. NaN versus undefined are only observable
             // in that you would get a different exception message. So, like, whatever: we
             // claim here that NaN v. undefined is observable.
             node->child1()->mergeFlags(NodeBytecodeUsesAsInt | NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsArrayIndex);
             break;
         }

         case ToString:
         case CallStringConstructor: {
             node->child1()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther);
             break;
         }

         case ToPrimitive:
         case ToNumber: {
             node->child1()->mergeFlags(flags);
             break;
         }

         case CompareLess:
         case CompareLessEq:
         case CompareGreater:
         case CompareGreaterEq:
         case CompareBelow:
         case CompareBelowEq:
         case CompareEq:
         case CompareStrictEq: {
             node->child1()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther);
             node->child2()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther);
             break;
         }

         case PutByValDirect:
         case PutByVal: {
             m_graph.varArgChild(node, 0)->mergeFlags(NodeBytecodeUsesAsValue);
             m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther | NodeBytecodeUsesAsInt | NodeBytecodeUsesAsArrayIndex);
             m_graph.varArgChild(node, 2)->mergeFlags(NodeBytecodeUsesAsValue);
             break;
         }

         case Switch: {
             SwitchData* data = node->switchData();
             switch (data->kind) {
             case SwitchImm:
                 // We don't need NodeBytecodeNeedsNegZero because if the cases are all integers
                 // then -0 and 0 are treated the same.  We don't need NodeBytecodeUsesAsOther
                 // because if all of the cases are integers then NaN and undefined are
                 // treated the same (i.e. they will take default).
                 node->child1()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsInt);
                 break;
             case SwitchChar: {
                 // We don't need NodeBytecodeNeedsNegZero because if the cases are all strings
                 // then -0 and 0 are treated the same.  We don't need NodeBytecodeUsesAsOther
                 // because if all of the cases are single-character strings then NaN
                 // and undefined are treated the same (i.e. they will take default).
                 node->child1()->mergeFlags(NodeBytecodeUsesAsNumber);
                 break;
             }
             case SwitchString:
                 // We don't need NodeBytecodeNeedsNegZero because if the cases are all strings
                 // then -0 and 0 are treated the same.
                 node->child1()->mergeFlags(NodeBytecodeUsesAsNumber | NodeBytecodeUsesAsOther);
                 break;
             case SwitchCell:
                 // There is currently no point to being clever here since this is used for switching
                 // on objects.
                 mergeDefaultFlags(node);
                 break;
             }
             break;
         }

         case Identity:
             // This would be trivial to handle but we just assert that we cannot see these yet.
             RELEASE_ASSERT_NOT_REACHED();
             break;

         // Note: ArithSqrt, ArithUnary and other math intrinsics don't have special
         // rules in here because they are always followed by Phantoms to signify that if the
         // method call speculation fails, the bytecode may use the arguments in arbitrary ways.
         // This corresponds to that possibility of someone doing something like:
         // Math.sin = function(x) { doArbitraryThingsTo(x); }

         default:
             mergeDefaultFlags(node);
             break;
         }
     }

     bool m_allowNestedOverflowingAdditions;
     bool m_changed;
 };

 bool performBackwardsPropagation(Graph& graph)
 {
     return runPhase<BackwardsPropagationPhase>(graph);
 }

 } } // namespace JSC::DFG

 #endif // ENABLE(DFG_JIT)
	/*
	* Copyright (C) 2013-2015 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "DFGBackwardsPropagationPhase.h"

	#if ENABLE(DFG_JIT)

	#include "DFGBasicBlockInlines.h"
	#include "DFGGraph.h"
	#include "DFGPhase.h"
	#include "JSCInlines.h"

	namespace JSC { namespace DFG {

	class BackwardsPropagationPhase : public Phase {
	public:
	BackwardsPropagationPhase(Graph& graph)
	: Phase(graph, "backwards propagation")
	{
	}

	bool run()
	{
	m_changed = true;
	while (m_changed) {
	m_changed = false;
	for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) {
	BasicBlock* block = m_graph.block(blockIndex);
	if (!block)
	continue;

	// Prevent a tower of overflowing additions from creating a value that is out of the
	// safe 2^48 range.
	m_allowNestedOverflowingAdditions = block->size() < (1 << 16);

	for (unsigned indexInBlock = block->size(); indexInBlock--;)
	propagate(block->at(indexInBlock));
	}
	}

	return true;
	}

	private:
	bool isNotNegZero(Node* node)
	{
	if (!node->isNumberConstant())
	return false;
	double value = node->asNumber();
	return (value \|\| 1.0 / value > 0.0);
	}

	bool isNotPosZero(Node* node)
	{
	if (!node->isNumberConstant())
	return false;
	double value = node->asNumber();
	return (value \|\| 1.0 / value < 0.0);
	}

	// Tests if the absolute value is strictly less than the power of two.
	template<int power>
	bool isWithinPowerOfTwoForConstant(Node* node)
	{
	JSValue immediateValue = node->asJSValue();
	if (!immediateValue.isNumber())
	return false;
	double immediate = immediateValue.asNumber();
	return immediate > -(static_cast<int64_t>(1) << power) && immediate < (static_cast<int64_t>(1) << power);
	}

	template<int power>
	bool isWithinPowerOfTwoNonRecursive(Node* node)
	{
	if (!node->isNumberConstant())
	return false;
	return isWithinPowerOfTwoForConstant<power>(node);
	}

	template<int power>
	bool isWithinPowerOfTwo(Node* node)
	{
	switch (node->op()) {
	case DoubleConstant:
	case JSConstant:
	case Int52Constant: {
	return isWithinPowerOfTwoForConstant<power>(node);
	}

	case ValueBitAnd:
	case ArithBitAnd: {
	if (power > 31)
	return true;

	return isWithinPowerOfTwoNonRecursive<power>(node->child1().node())
	\|\| isWithinPowerOfTwoNonRecursive<power>(node->child2().node());
	}

	case ArithBitOr:
	case ArithBitXor:
	case ValueBitOr:
	case ValueBitXor:
	case ValueBitLShift:
	case ArithBitLShift: {
	return power > 31;
	}

	case ArithBitRShift:
	case ValueBitRShift:
	case BitURShift: {
	if (power > 31)
	return true;

	Node* shiftAmount = node->child2().node();
	if (!node->isNumberConstant())
	return false;
	JSValue immediateValue = shiftAmount->asJSValue();
	if (!immediateValue.isInt32())
	return false;
	return immediateValue.asInt32() > 32 - power;
	}

	default:
	return false;
	}
	}

	template<int power>
	bool isWithinPowerOfTwo(Edge edge)
	{
	return isWithinPowerOfTwo<power>(edge.node());
	}

	bool mergeDefaultFlags(Node* node)
	{
	bool changed = false;
	if (node->flags() & NodeHasVarArgs) {
	for (unsigned childIdx = node->firstChild();
	childIdx < node->firstChild() + node->numChildren();
	childIdx++) {
	if (!!m_graph.m_varArgChildren[childIdx])
	changed \|= m_graph.m_varArgChildren[childIdx]->mergeFlags(NodeBytecodeUsesAsValue);
	}
	} else {
	if (!node->child1())
	return changed;
	changed \|= node->child1()->mergeFlags(NodeBytecodeUsesAsValue);
	if (!node->child2())
	return changed;
	changed \|= node->child2()->mergeFlags(NodeBytecodeUsesAsValue);
	if (!node->child3())
	return changed;
	changed \|= node->child3()->mergeFlags(NodeBytecodeUsesAsValue);
	}
	return changed;
	}

	void propagate(Node* node)
	{
	NodeFlags flags = node->flags() & NodeBytecodeBackPropMask;

	switch (node->op()) {
	case GetLocal: {
	VariableAccessData* variableAccessData = node->variableAccessData();
	flags &= ~NodeBytecodeUsesAsInt; // We don't care about cross-block uses-as-int.
	m_changed \|= variableAccessData->mergeFlags(flags);
	break;
	}

	case SetLocal: {
	VariableAccessData* variableAccessData = node->variableAccessData();
	if (!variableAccessData->isLoadedFrom())
	break;
	flags = variableAccessData->flags();
	RELEASE_ASSERT(!(flags & ~NodeBytecodeBackPropMask));
	flags \|= NodeBytecodeUsesAsNumber; // Account for the fact that control flow may cause overflows that our modeling can't handle.
	node->child1()->mergeFlags(flags);
	break;
	}

	case Flush: {
	VariableAccessData* variableAccessData = node->variableAccessData();
	m_changed \|= variableAccessData->mergeFlags(NodeBytecodeUsesAsValue);
	break;
	}

	case MovHint:
	case Check:
	case CheckVarargs:
	break;

	case ValueBitNot:
	case ArithBitNot: {
	flags \|= NodeBytecodeUsesAsInt;
	flags &= ~(NodeBytecodeUsesAsNumber \| NodeBytecodeNeedsNegZero \| NodeBytecodeUsesAsOther);
	flags &= ~NodeBytecodeUsesAsArrayIndex;
	node->child1()->mergeFlags(flags);
	break;
	}

	case ArithBitAnd:
	case ArithBitOr:
	case ArithBitXor:
	case ValueBitAnd:
	case ValueBitOr:
	case ValueBitXor:
	case ValueBitLShift:
	case ArithBitLShift:
	case ArithBitRShift:
	case ValueBitRShift:
	case BitURShift:
	case ArithIMul: {
	flags \|= NodeBytecodeUsesAsInt;
	flags &= ~(NodeBytecodeUsesAsNumber \| NodeBytecodeNeedsNegZero \| NodeBytecodeUsesAsOther);
	flags &= ~NodeBytecodeUsesAsArrayIndex;
	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags);
	break;
	}

	case StringCharAt:
	case StringCharCodeAt:
	case StringCodePointAt: {
	node->child1()->mergeFlags(NodeBytecodeUsesAsValue);
	node->child2()->mergeFlags(NodeBytecodeUsesAsValue \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	break;
	}

	case StringSlice: {
	node->child1()->mergeFlags(NodeBytecodeUsesAsValue);
	node->child2()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	if (node->child3())
	node->child3()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	break;
	}

	case ArraySlice: {
	m_graph.varArgChild(node, 0)->mergeFlags(NodeBytecodeUsesAsValue);

	if (node->numChildren() == 2)
	m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsValue);
	else if (node->numChildren() == 3) {
	m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	m_graph.varArgChild(node, 2)->mergeFlags(NodeBytecodeUsesAsValue);
	} else if (node->numChildren() == 4) {
	m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	m_graph.varArgChild(node, 2)->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	m_graph.varArgChild(node, 3)->mergeFlags(NodeBytecodeUsesAsValue);
	}
	break;
	}


	case UInt32ToNumber: {
	node->child1()->mergeFlags(flags);
	break;
	}

	case ValueAdd: {
	if (isNotNegZero(node->child1().node()) \|\| isNotNegZero(node->child2().node()))
	flags &= ~NodeBytecodeNeedsNegZero;
	if (node->child1()->hasNumericResult() \|\| node->child2()->hasNumericResult() \|\| node->child1()->hasNumberResult() \|\| node->child2()->hasNumberResult())
	flags &= ~NodeBytecodeUsesAsOther;
	if (!isWithinPowerOfTwo<32>(node->child1()) && !isWithinPowerOfTwo<32>(node->child2()))
	flags \|= NodeBytecodeUsesAsNumber;
	if (!m_allowNestedOverflowingAdditions)
	flags \|= NodeBytecodeUsesAsNumber;

	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags);
	break;
	}

	case ArithAdd: {
	flags &= ~NodeBytecodeUsesAsOther;
	if (isNotNegZero(node->child1().node()) \|\| isNotNegZero(node->child2().node()))
	flags &= ~NodeBytecodeNeedsNegZero;
	if (!isWithinPowerOfTwo<32>(node->child1()) && !isWithinPowerOfTwo<32>(node->child2()))
	flags \|= NodeBytecodeUsesAsNumber;
	if (!m_allowNestedOverflowingAdditions)
	flags \|= NodeBytecodeUsesAsNumber;

	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags);
	break;
	}

	case ArithClz32: {
	flags &= ~(NodeBytecodeUsesAsNumber \| NodeBytecodeNeedsNegZero \| NodeBytecodeUsesAsOther \| ~NodeBytecodeUsesAsArrayIndex);
	flags \|= NodeBytecodeUsesAsInt;
	node->child1()->mergeFlags(flags);
	break;
	}

	case ArithSub: {
	flags &= ~NodeBytecodeUsesAsOther;
	if (isNotNegZero(node->child1().node()) \|\| isNotPosZero(node->child2().node()))
	flags &= ~NodeBytecodeNeedsNegZero;
	if (!isWithinPowerOfTwo<32>(node->child1()) && !isWithinPowerOfTwo<32>(node->child2()))
	flags \|= NodeBytecodeUsesAsNumber;
	if (!m_allowNestedOverflowingAdditions)
	flags \|= NodeBytecodeUsesAsNumber;

	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags);
	break;
	}

	case ArithNegate: {
	flags &= ~NodeBytecodeUsesAsOther;

	node->child1()->mergeFlags(flags);
	break;
	}

	case ValueMul:
	case ArithMul: {
	// As soon as a multiply happens, we can easily end up in the part
	// of the double domain where the point at which you do truncation
	// can change the outcome. So, ArithMul always forces its inputs to
	// check for overflow. Additionally, it will have to check for overflow
	// itself unless we can prove that there is no way for the values
	// produced to cause double rounding.

	if (!isWithinPowerOfTwo<22>(node->child1().node())
	&& !isWithinPowerOfTwo<22>(node->child2().node()))
	flags \|= NodeBytecodeUsesAsNumber;

	node->mergeFlags(flags);

	flags \|= NodeBytecodeUsesAsNumber \| NodeBytecodeNeedsNegZero;
	flags &= ~NodeBytecodeUsesAsOther;

	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags);
	break;
	}

	case ValueDiv:
	case ArithDiv: {
	flags \|= NodeBytecodeUsesAsNumber \| NodeBytecodeNeedsNegZero;
	flags &= ~NodeBytecodeUsesAsOther;

	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags);
	break;
	}

	case ValueMod:
	case ArithMod: {
	flags \|= NodeBytecodeUsesAsNumber;
	flags &= ~NodeBytecodeUsesAsOther;

	node->child1()->mergeFlags(flags);
	node->child2()->mergeFlags(flags & ~NodeBytecodeNeedsNegZero);
	break;
	}

	case GetByVal: {
	m_graph.varArgChild(node, 0)->mergeFlags(NodeBytecodeUsesAsValue);
	m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	break;
	}

	case NewTypedArray:
	case NewArrayWithSize: {
	// Negative zero is not observable. NaN versus undefined are only observable
	// in that you would get a different exception message. So, like, whatever: we
	// claim here that NaN v. undefined is observable.
	node->child1()->mergeFlags(NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsArrayIndex);
	break;
	}

	case ToString:
	case CallStringConstructor: {
	node->child1()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther);
	break;
	}

	case ToPrimitive:
	case ToNumber: {
	node->child1()->mergeFlags(flags);
	break;
	}

	case CompareLess:
	case CompareLessEq:
	case CompareGreater:
	case CompareGreaterEq:
	case CompareBelow:
	case CompareBelowEq:
	case CompareEq:
	case CompareStrictEq: {
	node->child1()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther);
	node->child2()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther);
	break;
	}

	case PutByValDirect:
	case PutByVal: {
	m_graph.varArgChild(node, 0)->mergeFlags(NodeBytecodeUsesAsValue);
	m_graph.varArgChild(node, 1)->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther \| NodeBytecodeUsesAsInt \| NodeBytecodeUsesAsArrayIndex);
	m_graph.varArgChild(node, 2)->mergeFlags(NodeBytecodeUsesAsValue);
	break;
	}

	case Switch: {
	SwitchData* data = node->switchData();
	switch (data->kind) {
	case SwitchImm:
	// We don't need NodeBytecodeNeedsNegZero because if the cases are all integers
	// then -0 and 0 are treated the same. We don't need NodeBytecodeUsesAsOther
	// because if all of the cases are integers then NaN and undefined are
	// treated the same (i.e. they will take default).
	node->child1()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsInt);
	break;
	case SwitchChar: {
	// We don't need NodeBytecodeNeedsNegZero because if the cases are all strings
	// then -0 and 0 are treated the same. We don't need NodeBytecodeUsesAsOther
	// because if all of the cases are single-character strings then NaN
	// and undefined are treated the same (i.e. they will take default).
	node->child1()->mergeFlags(NodeBytecodeUsesAsNumber);
	break;
	}
	case SwitchString:
	// We don't need NodeBytecodeNeedsNegZero because if the cases are all strings
	// then -0 and 0 are treated the same.
	node->child1()->mergeFlags(NodeBytecodeUsesAsNumber \| NodeBytecodeUsesAsOther);
	break;
	case SwitchCell:
	// There is currently no point to being clever here since this is used for switching
	// on objects.
	mergeDefaultFlags(node);
	break;
	}
	break;
	}

	case Identity:
	// This would be trivial to handle but we just assert that we cannot see these yet.
	RELEASE_ASSERT_NOT_REACHED();
	break;

	// Note: ArithSqrt, ArithUnary and other math intrinsics don't have special
	// rules in here because they are always followed by Phantoms to signify that if the
	// method call speculation fails, the bytecode may use the arguments in arbitrary ways.
	// This corresponds to that possibility of someone doing something like:
	// Math.sin = function(x) { doArbitraryThingsTo(x); }

	default:
	mergeDefaultFlags(node);
	break;
	}
	}

	bool m_allowNestedOverflowingAdditions;
	bool m_changed;
	};

	bool performBackwardsPropagation(Graph& graph)
	{
	return runPhase<BackwardsPropagationPhase>(graph);
	}

	} } // namespace JSC::DFG

	#endif // ENABLE(DFG_JIT)