Source/JavaScriptCore/dfg/DFGCommon.h - WebKit - Git at Google

 /*
  * Copyright (C) 2011-2019 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.
  */

 #pragma once

 #include "DFGCompilationMode.h"

 #if ENABLE(DFG_JIT)

 #include "Options.h"
 #include <limits.h>
 #include <wtf/text/StringImpl.h>

 namespace JSC { namespace DFG {

 struct Node;

 typedef uint32_t BlockIndex;
 static constexpr BlockIndex NoBlock = UINT_MAX;

 // Use RefChildren if the child ref counts haven't already been adjusted using
 // other means and either of the following is true:
 // - The node you're creating is MustGenerate.
 // - The place where you're inserting a reference to the node you're creating
 //   will not also do RefChildren.
 enum RefChildrenMode {
     RefChildren,
     DontRefChildren
 };

 // Use RefNode if you know that the node will be used from another node, and you
 // will not already be ref'ing the node to account for that use.
 enum RefNodeMode {
     RefNode,
     DontRefNode
 };

 enum SwitchKind {
     SwitchImm,
     SwitchChar,
     SwitchString,
     SwitchCell
 };

 inline bool verboseCompilationEnabled(CompilationMode mode = DFGMode)
 {
     return Options::verboseCompilation() || Options::dumpGraphAtEachPhase() || (isFTL(mode) && Options::verboseFTLCompilation());
 }

 inline bool logCompilationChanges(CompilationMode mode = DFGMode)
 {
     return verboseCompilationEnabled(mode) || Options::logCompilationChanges();
 }

 inline bool shouldDumpGraphAtEachPhase(CompilationMode mode)
 {
     if (isFTL(mode))
         return Options::dumpGraphAtEachPhase() || Options::dumpDFGFTLGraphAtEachPhase();
     return Options::dumpGraphAtEachPhase() || Options::dumpDFGGraphAtEachPhase();
 }

 inline bool validationEnabled()
 {
 #if !ASSERT_DISABLED
     return true;
 #else
     return Options::validateGraph() || Options::validateGraphAtEachPhase();
 #endif
 }

 inline bool enableInt52()
 {
 #if USE(JSVALUE64)
     return true;
 #else
     return false;
 #endif
 }

 // The prediction propagator effectively does four passes, with the last pass
 // being done by the separate FixuPhase.
 enum PredictionPass {
     // We're converging in a straight-forward forward flow fixpoint. This is the
     // most conventional part of the propagator - it makes only monotonic decisions
     // based on value profiles and rare case profiles. It ignores baseline JIT rare
     // case profiles. The goal here is to develop a good guess of which variables
     // are likely to be purely numerical, which generally doesn't require knowing
     // the rare case profiles.
     PrimaryPass,

     // At this point we know what is numerical and what isn't. Non-numerical inputs
     // to arithmetic operations will not have useful information in the Baseline JIT
     // rare case profiles because Baseline may take slow path on non-numerical
     // inputs even if the DFG could handle the input on the fast path. Boolean
     // inputs are the most obvious example. This pass of prediction propagation will
     // use Baseline rare case profiles for purely numerical operations and it will
     // ignore them for everything else. The point of this pass is to develop a good
     // guess of which variables are likely to be doubles.
     //
     // This pass is intentionally weird and goes against what is considered good
     // form when writing a static analysis: a new data flow of booleans will cause
     // us to ignore rare case profiles except that by then, we will have already
     // propagated double types based on our prior assumption that we shouldn't
     // ignore rare cases. This probably won't happen because the PrimaryPass is
     // almost certainly going to establish what is and isn't numerical. But it's
     // conceivable that during this pass we will discover a new boolean data flow.
     // This ends up being sound because the prediction propagator could literally
     // make any guesses it wants and still be sound (worst case, we OSR exit more
     // often or use too general of types are run a bit slower). This will converge
     // because we force monotonicity on the types of nodes and variables. So, the
     // worst thing that can happen is that we violate basic laws of theoretical
     // decency.
     RareCasePass,

     // At this point we know what is numerical and what isn't, and we also know what
     // is a double and what isn't. So, we start forcing variables to be double.
     // Doing so may have a cascading effect so this is a fixpoint. It's monotonic
     // in the sense that once a variable is forced double, it cannot be forced in
     // the other direction.
     DoubleVotingPass,

     // This pass occurs once we have converged. At this point we are just installing
     // type checks based on the conclusions we have already reached. It's important
     // for this pass to reach the same conclusions that DoubleVotingPass reached.
     FixupPass
 };

 enum StructureRegistrationState { HaveNotStartedRegistering, AllStructuresAreRegistered };

 enum StructureRegistrationResult { StructureRegisteredNormally, StructureRegisteredAndWatched };

 enum OptimizationFixpointState { BeforeFixpoint, FixpointNotConverged, FixpointConverged };

 // Describes the form you can expect the entire graph to be in.
 enum GraphForm {
     // LoadStore form means that basic blocks may freely use GetLocal, SetLocal,
     // and Flush for accessing local variables and indicating where their live
     // ranges ought to be. Data flow between local accesses is implicit. Liveness
     // is only explicit at block heads (variablesAtHead). This is only used by
     // the DFG simplifier and is only preserved by same.
     //
     // For example, LoadStore form gives no easy way to determine which SetLocal's
     // flow into a GetLocal. As well, LoadStore form implies no restrictions on
     // redundancy: you can freely emit multiple GetLocals, or multiple SetLocals
     // (or any combination thereof) to the same local in the same block. LoadStore
     // form does not require basic blocks to declare how they affect or use locals,
     // other than implicitly by using the local ops and by preserving
     // variablesAtHead. Finally, LoadStore allows flexibility in how liveness of
     // locals is extended; for example you can replace a GetLocal with a Phantom
     // and so long as the Phantom retains the GetLocal's children (i.e. the Phi
     // most likely) then it implies that the local is still live but that it need
     // not be stored to the stack necessarily. This implies that Phantom can
     // reference nodes that have no result, as long as those nodes are valid
     // GetLocal children (i.e. Phi, SetLocal, SetArgumentDefinitely, SetArgumentMaybe).
     //
     // LoadStore form also implies that Phis need not have children. By default,
     // they end up having no children if you enter LoadStore using the canonical
     // way (call Graph::dethread).
     //
     // LoadStore form is suitable for CFG transformations, as well as strength
     // reduction, folding, and CSE.
     LoadStore,

     // ThreadedCPS form means that basic blocks list up-front which locals they
     // expect to be live at the head, and which locals they make available at the
     // tail. ThreadedCPS form also implies that:
     //
     // - GetLocals and SetLocals are not redundant within a basic block.
     //
     // - All GetLocals and Flushes are linked directly to the last access point
     //   of the variable, which must not be another GetLocal.
     //
     // - Phantom(Phi) is not legal, but PhantomLocal is.
     //
     // ThreadedCPS form is suitable for data flow analysis (CFA, prediction
     // propagation), register allocation, and code generation.
     ThreadedCPS,

     // SSA form. See DFGSSAConversionPhase.h for a description.
     SSA
 };

 // Describes the state of the UnionFind structure of VariableAccessData's.
 enum UnificationState {
     // BasicBlock-local accesses to variables are appropriately unified with each other.
     LocallyUnified,

     // Unification has been performed globally.
     GloballyUnified
 };

 // Describes how reference counts in the graph behave.
 enum RefCountState {
     // Everything has refCount() == 1.
     EverythingIsLive,

     // Set after DCE has run.
     ExactRefCount
 };

 enum OperandSpeculationMode { AutomaticOperandSpeculation, ManualOperandSpeculation };

 enum ProofStatus { NeedsCheck, IsProved };

 inline bool isProved(ProofStatus proofStatus)
 {
     ASSERT(proofStatus == IsProved || proofStatus == NeedsCheck);
     return proofStatus == IsProved;
 }

 inline ProofStatus proofStatusForIsProved(bool isProved)
 {
     return isProved ? IsProved : NeedsCheck;
 }

 enum KillStatus { DoesNotKill, DoesKill };

 inline bool doesKill(KillStatus killStatus)
 {
     ASSERT(killStatus == DoesNotKill || killStatus == DoesKill);
     return killStatus == DoesKill;
 }

 inline KillStatus killStatusForDoesKill(bool doesKill)
 {
     return doesKill ? DoesKill : DoesNotKill;
 }

 enum class PlanStage {
     Initial,
     AfterFixup
 };

 // If possible, this will acquire a lock to make sure that if multiple threads
 // start crashing at the same time, you get coherent dump output. Use this only
 // when you're forcing a crash with diagnostics.
 void startCrashing();

 JS_EXPORT_PRIVATE bool isCrashing();

 struct NodeAndIndex {
     NodeAndIndex()
         : node(nullptr)
         , index(UINT_MAX)
     {
     }

     NodeAndIndex(Node* node, unsigned index)
         : node(node)
         , index(index)
     {
         ASSERT(!node == (index == UINT_MAX));
     }

     bool operator!() const
     {
         return !node;
     }

     Node* node;
     unsigned index;
 };

 // A less-than operator for strings that is useful for generating string switches. Sorts by <
 // relation on characters. Ensures that if a is a prefix of b, then a < b.
 bool stringLessThan(StringImpl& a, StringImpl& b);

 } } // namespace JSC::DFG

 namespace WTF {

 void printInternal(PrintStream&, JSC::DFG::OptimizationFixpointState);
 void printInternal(PrintStream&, JSC::DFG::GraphForm);
 void printInternal(PrintStream&, JSC::DFG::UnificationState);
 void printInternal(PrintStream&, JSC::DFG::RefCountState);
 void printInternal(PrintStream&, JSC::DFG::ProofStatus);

 } // namespace WTF

 #endif // ENABLE(DFG_JIT)

 namespace JSC { namespace DFG {

 // Put things here that must be defined even if ENABLE(DFG_JIT) is false.

 enum CapabilityLevel {
     CannotCompile,
     CanCompile,
     CanCompileAndInline,
     CapabilityLevelNotSet
 };

 inline bool canCompile(CapabilityLevel level)
 {
     switch (level) {
     case CanCompile:
     case CanCompileAndInline:
         return true;
     default:
         return false;
     }
 }

 inline bool canInline(CapabilityLevel level)
 {
     switch (level) {
     case CanCompileAndInline:
         return true;
     default:
         return false;
     }
 }

 inline CapabilityLevel leastUpperBound(CapabilityLevel a, CapabilityLevel b)
 {
     switch (a) {
     case CannotCompile:
         return CannotCompile;
     case CanCompile:
         switch (b) {
         case CanCompile:
         case CanCompileAndInline:
             return CanCompile;
         default:
             return CannotCompile;
         }
     case CanCompileAndInline:
         return b;
     case CapabilityLevelNotSet:
         ASSERT_NOT_REACHED();
         return CannotCompile;
     }
     ASSERT_NOT_REACHED();
     return CannotCompile;
 }

 // Unconditionally disable DFG disassembly support if the DFG is not compiled in.
 inline bool shouldDumpDisassembly(CompilationMode mode = DFGMode)
 {
 #if ENABLE(DFG_JIT)
     return Options::dumpDisassembly() || Options::dumpDFGDisassembly() || (isFTL(mode) && Options::dumpFTLDisassembly());
 #else
     UNUSED_PARAM(mode);
     return false;
 #endif
 }

 } } // namespace JSC::DFG

 namespace WTF {

 void printInternal(PrintStream&, JSC::DFG::CapabilityLevel);

 } // namespace WTF
	/*
	* Copyright (C) 2011-2019 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.
	*/

	#pragma once

	#include "DFGCompilationMode.h"

	#if ENABLE(DFG_JIT)

	#include "Options.h"
	#include <limits.h>
	#include <wtf/text/StringImpl.h>

	namespace JSC { namespace DFG {

	struct Node;

	typedef uint32_t BlockIndex;
	static constexpr BlockIndex NoBlock = UINT_MAX;

	// Use RefChildren if the child ref counts haven't already been adjusted using
	// other means and either of the following is true:
	// - The node you're creating is MustGenerate.
	// - The place where you're inserting a reference to the node you're creating
	// will not also do RefChildren.
	enum RefChildrenMode {
	RefChildren,
	DontRefChildren
	};

	// Use RefNode if you know that the node will be used from another node, and you
	// will not already be ref'ing the node to account for that use.
	enum RefNodeMode {
	RefNode,
	DontRefNode
	};

	enum SwitchKind {
	SwitchImm,
	SwitchChar,
	SwitchString,
	SwitchCell
	};

	inline bool verboseCompilationEnabled(CompilationMode mode = DFGMode)
	{
	return Options::verboseCompilation() \|\| Options::dumpGraphAtEachPhase() \|\| (isFTL(mode) && Options::verboseFTLCompilation());
	}

	inline bool logCompilationChanges(CompilationMode mode = DFGMode)
	{
	return verboseCompilationEnabled(mode) \|\| Options::logCompilationChanges();
	}

	inline bool shouldDumpGraphAtEachPhase(CompilationMode mode)
	{
	if (isFTL(mode))
	return Options::dumpGraphAtEachPhase() \|\| Options::dumpDFGFTLGraphAtEachPhase();
	return Options::dumpGraphAtEachPhase() \|\| Options::dumpDFGGraphAtEachPhase();
	}

	inline bool validationEnabled()
	{
	#if !ASSERT_DISABLED
	return true;
	#else
	return Options::validateGraph() \|\| Options::validateGraphAtEachPhase();
	#endif
	}

	inline bool enableInt52()
	{
	#if USE(JSVALUE64)
	return true;
	#else
	return false;
	#endif
	}

	// The prediction propagator effectively does four passes, with the last pass
	// being done by the separate FixuPhase.
	enum PredictionPass {
	// We're converging in a straight-forward forward flow fixpoint. This is the
	// most conventional part of the propagator - it makes only monotonic decisions
	// based on value profiles and rare case profiles. It ignores baseline JIT rare
	// case profiles. The goal here is to develop a good guess of which variables
	// are likely to be purely numerical, which generally doesn't require knowing
	// the rare case profiles.
	PrimaryPass,

	// At this point we know what is numerical and what isn't. Non-numerical inputs
	// to arithmetic operations will not have useful information in the Baseline JIT
	// rare case profiles because Baseline may take slow path on non-numerical
	// inputs even if the DFG could handle the input on the fast path. Boolean
	// inputs are the most obvious example. This pass of prediction propagation will
	// use Baseline rare case profiles for purely numerical operations and it will
	// ignore them for everything else. The point of this pass is to develop a good
	// guess of which variables are likely to be doubles.
	//
	// This pass is intentionally weird and goes against what is considered good
	// form when writing a static analysis: a new data flow of booleans will cause
	// us to ignore rare case profiles except that by then, we will have already
	// propagated double types based on our prior assumption that we shouldn't
	// ignore rare cases. This probably won't happen because the PrimaryPass is
	// almost certainly going to establish what is and isn't numerical. But it's
	// conceivable that during this pass we will discover a new boolean data flow.
	// This ends up being sound because the prediction propagator could literally
	// make any guesses it wants and still be sound (worst case, we OSR exit more
	// often or use too general of types are run a bit slower). This will converge
	// because we force monotonicity on the types of nodes and variables. So, the
	// worst thing that can happen is that we violate basic laws of theoretical
	// decency.
	RareCasePass,

	// At this point we know what is numerical and what isn't, and we also know what
	// is a double and what isn't. So, we start forcing variables to be double.
	// Doing so may have a cascading effect so this is a fixpoint. It's monotonic
	// in the sense that once a variable is forced double, it cannot be forced in
	// the other direction.
	DoubleVotingPass,

	// This pass occurs once we have converged. At this point we are just installing
	// type checks based on the conclusions we have already reached. It's important
	// for this pass to reach the same conclusions that DoubleVotingPass reached.
	FixupPass
	};

	enum StructureRegistrationState { HaveNotStartedRegistering, AllStructuresAreRegistered };

	enum StructureRegistrationResult { StructureRegisteredNormally, StructureRegisteredAndWatched };

	enum OptimizationFixpointState { BeforeFixpoint, FixpointNotConverged, FixpointConverged };

	// Describes the form you can expect the entire graph to be in.
	enum GraphForm {
	// LoadStore form means that basic blocks may freely use GetLocal, SetLocal,
	// and Flush for accessing local variables and indicating where their live
	// ranges ought to be. Data flow between local accesses is implicit. Liveness
	// is only explicit at block heads (variablesAtHead). This is only used by
	// the DFG simplifier and is only preserved by same.
	//
	// For example, LoadStore form gives no easy way to determine which SetLocal's
	// flow into a GetLocal. As well, LoadStore form implies no restrictions on
	// redundancy: you can freely emit multiple GetLocals, or multiple SetLocals
	// (or any combination thereof) to the same local in the same block. LoadStore
	// form does not require basic blocks to declare how they affect or use locals,
	// other than implicitly by using the local ops and by preserving
	// variablesAtHead. Finally, LoadStore allows flexibility in how liveness of
	// locals is extended; for example you can replace a GetLocal with a Phantom
	// and so long as the Phantom retains the GetLocal's children (i.e. the Phi
	// most likely) then it implies that the local is still live but that it need
	// not be stored to the stack necessarily. This implies that Phantom can
	// reference nodes that have no result, as long as those nodes are valid
	// GetLocal children (i.e. Phi, SetLocal, SetArgumentDefinitely, SetArgumentMaybe).
	//
	// LoadStore form also implies that Phis need not have children. By default,
	// they end up having no children if you enter LoadStore using the canonical
	// way (call Graph::dethread).
	//
	// LoadStore form is suitable for CFG transformations, as well as strength
	// reduction, folding, and CSE.
	LoadStore,

	// ThreadedCPS form means that basic blocks list up-front which locals they
	// expect to be live at the head, and which locals they make available at the
	// tail. ThreadedCPS form also implies that:
	//
	// - GetLocals and SetLocals are not redundant within a basic block.
	//
	// - All GetLocals and Flushes are linked directly to the last access point
	// of the variable, which must not be another GetLocal.
	//
	// - Phantom(Phi) is not legal, but PhantomLocal is.
	//
	// ThreadedCPS form is suitable for data flow analysis (CFA, prediction
	// propagation), register allocation, and code generation.
	ThreadedCPS,

	// SSA form. See DFGSSAConversionPhase.h for a description.
	SSA
	};

	// Describes the state of the UnionFind structure of VariableAccessData's.
	enum UnificationState {
	// BasicBlock-local accesses to variables are appropriately unified with each other.
	LocallyUnified,

	// Unification has been performed globally.
	GloballyUnified
	};

	// Describes how reference counts in the graph behave.
	enum RefCountState {
	// Everything has refCount() == 1.
	EverythingIsLive,

	// Set after DCE has run.
	ExactRefCount
	};

	enum OperandSpeculationMode { AutomaticOperandSpeculation, ManualOperandSpeculation };

	enum ProofStatus { NeedsCheck, IsProved };

	inline bool isProved(ProofStatus proofStatus)
	{
	ASSERT(proofStatus == IsProved \|\| proofStatus == NeedsCheck);
	return proofStatus == IsProved;
	}

	inline ProofStatus proofStatusForIsProved(bool isProved)
	{
	return isProved ? IsProved : NeedsCheck;
	}

	enum KillStatus { DoesNotKill, DoesKill };

	inline bool doesKill(KillStatus killStatus)
	{
	ASSERT(killStatus == DoesNotKill \|\| killStatus == DoesKill);
	return killStatus == DoesKill;
	}

	inline KillStatus killStatusForDoesKill(bool doesKill)
	{
	return doesKill ? DoesKill : DoesNotKill;
	}

	enum class PlanStage {
	Initial,
	AfterFixup
	};

	// If possible, this will acquire a lock to make sure that if multiple threads
	// start crashing at the same time, you get coherent dump output. Use this only
	// when you're forcing a crash with diagnostics.
	void startCrashing();

	JS_EXPORT_PRIVATE bool isCrashing();

	struct NodeAndIndex {
	NodeAndIndex()
	: node(nullptr)
	, index(UINT_MAX)
	{
	}

	NodeAndIndex(Node* node, unsigned index)
	: node(node)
	, index(index)
	{
	ASSERT(!node == (index == UINT_MAX));
	}

	bool operator!() const
	{
	return !node;
	}

	Node* node;
	unsigned index;
	};

	// A less-than operator for strings that is useful for generating string switches. Sorts by <
	// relation on characters. Ensures that if a is a prefix of b, then a < b.
	bool stringLessThan(StringImpl& a, StringImpl& b);

	} } // namespace JSC::DFG

	namespace WTF {

	void printInternal(PrintStream&, JSC::DFG::OptimizationFixpointState);
	void printInternal(PrintStream&, JSC::DFG::GraphForm);
	void printInternal(PrintStream&, JSC::DFG::UnificationState);
	void printInternal(PrintStream&, JSC::DFG::RefCountState);
	void printInternal(PrintStream&, JSC::DFG::ProofStatus);

	} // namespace WTF

	#endif // ENABLE(DFG_JIT)

	namespace JSC { namespace DFG {

	// Put things here that must be defined even if ENABLE(DFG_JIT) is false.

	enum CapabilityLevel {
	CannotCompile,
	CanCompile,
	CanCompileAndInline,
	CapabilityLevelNotSet
	};

	inline bool canCompile(CapabilityLevel level)
	{
	switch (level) {
	case CanCompile:
	case CanCompileAndInline:
	return true;
	default:
	return false;
	}
	}

	inline bool canInline(CapabilityLevel level)
	{
	switch (level) {
	case CanCompileAndInline:
	return true;
	default:
	return false;
	}
	}

	inline CapabilityLevel leastUpperBound(CapabilityLevel a, CapabilityLevel b)
	{
	switch (a) {
	case CannotCompile:
	return CannotCompile;
	case CanCompile:
	switch (b) {
	case CanCompile:
	case CanCompileAndInline:
	return CanCompile;
	default:
	return CannotCompile;
	}
	case CanCompileAndInline:
	return b;
	case CapabilityLevelNotSet:
	ASSERT_NOT_REACHED();
	return CannotCompile;
	}
	ASSERT_NOT_REACHED();
	return CannotCompile;
	}

	// Unconditionally disable DFG disassembly support if the DFG is not compiled in.
	inline bool shouldDumpDisassembly(CompilationMode mode = DFGMode)
	{
	#if ENABLE(DFG_JIT)
	return Options::dumpDisassembly() \|\| Options::dumpDFGDisassembly() \|\| (isFTL(mode) && Options::dumpFTLDisassembly());
	#else
	UNUSED_PARAM(mode);
	return false;
	#endif
	}

	} } // namespace JSC::DFG

	namespace WTF {

	void printInternal(PrintStream&, JSC::DFG::CapabilityLevel);

	} // namespace WTF