Source/JavaScriptCore/b3/air/AirCode.h - WebKit - Git at Google

 /*
  * Copyright (C) 2015-2018 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

 #if ENABLE(B3_JIT)

 #include "AirArg.h"
 #include "AirBasicBlock.h"
 #include "AirDisassembler.h"
 #include "AirSpecial.h"
 #include "AirStackSlot.h"
 #include "AirTmp.h"
 #include "B3SparseCollection.h"
 #include "CCallHelpers.h"
 #include "RegisterAtOffsetList.h"
 #include "StackAlignment.h"
 #include <wtf/IndexMap.h>
 #include <wtf/WeakRandom.h>

 namespace JSC { namespace B3 {

 class Procedure;

 #if ASSERT_DISABLED
 IGNORE_RETURN_TYPE_WARNINGS_BEGIN
 #endif

 namespace Air {

 class GenerateAndAllocateRegisters;
 class BlockInsertionSet;
 class CCallSpecial;
 class CFG;
 class Code;
 class Disassembler;

 typedef void WasmBoundsCheckGeneratorFunction(CCallHelpers&, GPRReg);
 typedef SharedTask<WasmBoundsCheckGeneratorFunction> WasmBoundsCheckGenerator;

 typedef void PrologueGeneratorFunction(CCallHelpers&, Code&);
 typedef SharedTask<PrologueGeneratorFunction> PrologueGenerator;

 // This is an IR that is very close to the bare metal. It requires about 40x more bytes than the
 // generated machine code - for example if you're generating 1MB of machine code, you need about
 // 40MB of Air.

 class Code {
     WTF_MAKE_NONCOPYABLE(Code);
     WTF_MAKE_FAST_ALLOCATED;
 public:
     ~Code();

     Procedure& proc() { return m_proc; }

     const Vector<Reg>& regsInPriorityOrder(Bank bank) const
     {
         switch (bank) {
         case GP:
             return m_gpRegsInPriorityOrder;
         case FP:
             return m_fpRegsInPriorityOrder;
         }
         ASSERT_NOT_REACHED();
     }

     // This is the set of registers that Air is allowed to emit code to mutate. It's derived from
     // regsInPriorityOrder. Any registers not in this set are said to be "pinned".
     const RegisterSet& mutableRegs() const { return m_mutableRegs; }

     bool isPinned(Reg reg) const { return !mutableRegs().get(reg); }
     void pinRegister(Reg);

     void setOptLevel(unsigned optLevel) { m_optLevel = optLevel; }
     unsigned optLevel() const { return m_optLevel; }

     bool needsUsedRegisters() const;

     JS_EXPORT_PRIVATE BasicBlock* addBlock(double frequency = 1);

     // Note that you can rely on stack slots always getting indices that are larger than the index
     // of any prior stack slot. In fact, all stack slots you create in the future will have an index
     // that is >= stackSlots().size().
     JS_EXPORT_PRIVATE StackSlot* addStackSlot(
         unsigned byteSize, StackSlotKind, B3::StackSlot* = nullptr);
     StackSlot* addStackSlot(B3::StackSlot*);

     JS_EXPORT_PRIVATE Special* addSpecial(std::unique_ptr<Special>);

     // This is the special you need to make a C call!
     CCallSpecial* cCallSpecial();

     Tmp newTmp(Bank bank)
     {
         switch (bank) {
         case GP:
             return Tmp::gpTmpForIndex(m_numGPTmps++);
         case FP:
             return Tmp::fpTmpForIndex(m_numFPTmps++);
         }
         ASSERT_NOT_REACHED();
     }

     unsigned numTmps(Bank bank)
     {
         switch (bank) {
         case GP:
             return m_numGPTmps;
         case FP:
             return m_numFPTmps;
         }
         ASSERT_NOT_REACHED();
     }

     template<typename Func>
     void forEachTmp(const Func& func)
     {
         for (unsigned bankIndex = 0; bankIndex < numBanks; ++bankIndex) {
             Bank bank = static_cast<Bank>(bankIndex);
             unsigned numTmps = this->numTmps(bank);
             for (unsigned i = 0; i < numTmps; ++i)
                 func(Tmp::tmpForIndex(bank, i));
         }
     }

     unsigned callArgAreaSizeInBytes() const { return m_callArgAreaSize; }

     // You can call this before code generation to force a minimum call arg area size.
     void requestCallArgAreaSizeInBytes(unsigned size)
     {
         m_callArgAreaSize = std::max(
             m_callArgAreaSize,
             static_cast<unsigned>(WTF::roundUpToMultipleOf(stackAlignmentBytes(), size)));
     }

     unsigned frameSize() const { return m_frameSize; }

     // Only phases that do stack allocation are allowed to set this. Currently, only
     // Air::allocateStack() does this.
     void setFrameSize(unsigned frameSize)
     {
         m_frameSize = frameSize;
     }

     // Note that this is not the same thing as proc().numEntrypoints(). This value here may be zero
     // until we lower EntrySwitch.
     unsigned numEntrypoints() const { return m_entrypoints.size(); }
     const Vector<FrequentedBlock>& entrypoints() const { return m_entrypoints; }
     const FrequentedBlock& entrypoint(unsigned index) const { return m_entrypoints[index]; }
     bool isEntrypoint(BasicBlock*) const;
     // Note: It is only valid to call this function after LowerEntrySwitch.
     Optional<unsigned> entrypointIndex(BasicBlock*) const;

     // Note: We allow this to be called even before we set m_entrypoints just for convenience to users of this API.
     // However, if you call this before setNumEntrypoints, setNumEntrypoints will overwrite this value.
     void setPrologueForEntrypoint(unsigned entrypointIndex, Ref<PrologueGenerator>&& generator)
     {
         m_prologueGenerators[entrypointIndex] = WTFMove(generator);
     }
     const Ref<PrologueGenerator>& prologueGeneratorForEntrypoint(unsigned entrypointIndex)
     {
         return m_prologueGenerators[entrypointIndex];
     }

     void setNumEntrypoints(unsigned);

     // This is used by lowerEntrySwitch().
     template<typename Vector>
     void setEntrypoints(Vector&& vector)
     {
         m_entrypoints = std::forward<Vector>(vector);
         RELEASE_ASSERT(m_entrypoints.size() == m_prologueGenerators.size());
     }

     CCallHelpers::Label entrypointLabel(unsigned index) const
     {
         return m_entrypointLabels[index];
     }

     // This is used by generate().
     template<typename Vector>
     void setEntrypointLabels(Vector&& vector)
     {
         m_entrypointLabels = std::forward<Vector>(vector);
         RELEASE_ASSERT(m_entrypointLabels.size() == m_prologueGenerators.size());
     }

     void setStackIsAllocated(bool value)
     {
         m_stackIsAllocated = value;
     }

     bool stackIsAllocated() const { return m_stackIsAllocated; }

     // This sets the callee save registers.
     void setCalleeSaveRegisterAtOffsetList(RegisterAtOffsetList&&, StackSlot*);

     // This returns the correctly offset list of callee save registers.
     RegisterAtOffsetList calleeSaveRegisterAtOffsetList() const;

     // This just tells you what the callee saves are.
     RegisterSet calleeSaveRegisters() const { return m_calleeSaveRegisters; }

     // Recomputes predecessors and deletes unreachable blocks.
     JS_EXPORT_PRIVATE void resetReachability();

     JS_EXPORT_PRIVATE void dump(PrintStream&) const;

     unsigned size() const { return m_blocks.size(); }
     BasicBlock* at(unsigned index) const { return m_blocks[index].get(); }
     BasicBlock* operator[](unsigned index) const { return at(index); }

     // This is used by phases that optimize the block list. You shouldn't use this unless you really know
     // what you're doing.
     Vector<std::unique_ptr<BasicBlock>>& blockList() { return m_blocks; }

     // Finds the smallest index' such that at(index') != null and index' >= index.
     JS_EXPORT_PRIVATE unsigned findFirstBlockIndex(unsigned index) const;

     // Finds the smallest index' such that at(index') != null and index' > index.
     unsigned findNextBlockIndex(unsigned index) const;

     BasicBlock* findNextBlock(BasicBlock*) const;

     class iterator {
     public:
         iterator()
             : m_code(nullptr)
             , m_index(0)
         {
         }

         iterator(const Code& code, unsigned index)
             : m_code(&code)
             , m_index(m_code->findFirstBlockIndex(index))
         {
         }

         BasicBlock* operator*()
         {
             return m_code->at(m_index);
         }

         iterator& operator++()
         {
             m_index = m_code->findFirstBlockIndex(m_index + 1);
             return *this;
         }

         bool operator==(const iterator& other) const
         {
             return m_index == other.m_index;
         }

         bool operator!=(const iterator& other) const
         {
             return !(*this == other);
         }

     private:
         const Code* m_code;
         unsigned m_index;
     };

     iterator begin() const { return iterator(*this, 0); }
     iterator end() const { return iterator(*this, size()); }

     const SparseCollection<StackSlot>& stackSlots() const { return m_stackSlots; }
     SparseCollection<StackSlot>& stackSlots() { return m_stackSlots; }

     const SparseCollection<Special>& specials() const { return m_specials; }
     SparseCollection<Special>& specials() { return m_specials; }

     template<typename Callback>
     void forAllTmps(const Callback& callback) const
     {
         for (unsigned i = m_numGPTmps; i--;)
             callback(Tmp::gpTmpForIndex(i));
         for (unsigned i = m_numFPTmps; i--;)
             callback(Tmp::fpTmpForIndex(i));
     }

     void addFastTmp(Tmp);
     bool isFastTmp(Tmp tmp) const { return m_fastTmps.contains(tmp); }

     CFG& cfg() const { return *m_cfg; }

     void* addDataSection(size_t);

     // The name has to be a string literal, since we don't do any memory management for the string.
     void setLastPhaseName(const char* name)
     {
         m_lastPhaseName = name;
     }

     const char* lastPhaseName() const { return m_lastPhaseName; }

     void setWasmBoundsCheckGenerator(RefPtr<WasmBoundsCheckGenerator> generator)
     {
         m_wasmBoundsCheckGenerator = generator;
     }

     RefPtr<WasmBoundsCheckGenerator> wasmBoundsCheckGenerator() const { return m_wasmBoundsCheckGenerator; }

     // This is a hash of the code. You can use this if you want to put code into a hashtable, but
     // it's mainly for validating the results from JSAir.
     unsigned jsHash() const;

     void setDisassembler(std::unique_ptr<Disassembler>&& disassembler) { m_disassembler = WTFMove(disassembler); }
     Disassembler* disassembler() { return m_disassembler.get(); }

     RegisterSet mutableGPRs();
     RegisterSet mutableFPRs();
     RegisterSet pinnedRegisters() const { return m_pinnedRegs; }

     WeakRandom& weakRandom() { return m_weakRandom; }

     void emitDefaultPrologue(CCallHelpers&);

     std::unique_ptr<GenerateAndAllocateRegisters> m_generateAndAllocateRegisters;

 private:
     friend class ::JSC::B3::Procedure;
     friend class BlockInsertionSet;

     Code(Procedure&);

     void setRegsInPriorityOrder(Bank, const Vector<Reg>&);

     Vector<Reg>& regsInPriorityOrderImpl(Bank bank)
     {
         switch (bank) {
         case GP:
             return m_gpRegsInPriorityOrder;
         case FP:
             return m_fpRegsInPriorityOrder;
         }
         ASSERT_NOT_REACHED();
     }

     WeakRandom m_weakRandom;
     Procedure& m_proc; // Some meta-data, like byproducts, is stored in the Procedure.
     Vector<Reg> m_gpRegsInPriorityOrder;
     Vector<Reg> m_fpRegsInPriorityOrder;
     RegisterSet m_mutableRegs;
     RegisterSet m_pinnedRegs;
     SparseCollection<StackSlot> m_stackSlots;
     Vector<std::unique_ptr<BasicBlock>> m_blocks;
     SparseCollection<Special> m_specials;
     std::unique_ptr<CFG> m_cfg;
     HashSet<Tmp> m_fastTmps;
     CCallSpecial* m_cCallSpecial { nullptr };
     unsigned m_numGPTmps { 0 };
     unsigned m_numFPTmps { 0 };
     unsigned m_frameSize { 0 };
     unsigned m_callArgAreaSize { 0 };
     bool m_stackIsAllocated { false };
     RegisterAtOffsetList m_uncorrectedCalleeSaveRegisterAtOffsetList;
     RegisterSet m_calleeSaveRegisters;
     StackSlot* m_calleeSaveStackSlot { nullptr };
     Vector<FrequentedBlock> m_entrypoints; // This is empty until after lowerEntrySwitch().
     Vector<CCallHelpers::Label> m_entrypointLabels; // This is empty until code generation.
     Vector<Ref<PrologueGenerator>, 1> m_prologueGenerators;
     RefPtr<WasmBoundsCheckGenerator> m_wasmBoundsCheckGenerator;
     const char* m_lastPhaseName;
     std::unique_ptr<Disassembler> m_disassembler;
     unsigned m_optLevel { defaultOptLevel() };
     Ref<PrologueGenerator> m_defaultPrologueGenerator;
 };

 } } } // namespace JSC::B3::Air

 #if ASSERT_DISABLED
 IGNORE_RETURN_TYPE_WARNINGS_END
 #endif

 #endif // ENABLE(B3_JIT)
	/*
	* Copyright (C) 2015-2018 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

	#if ENABLE(B3_JIT)

	#include "AirArg.h"
	#include "AirBasicBlock.h"
	#include "AirDisassembler.h"
	#include "AirSpecial.h"
	#include "AirStackSlot.h"
	#include "AirTmp.h"
	#include "B3SparseCollection.h"
	#include "CCallHelpers.h"
	#include "RegisterAtOffsetList.h"
	#include "StackAlignment.h"
	#include <wtf/IndexMap.h>
	#include <wtf/WeakRandom.h>

	namespace JSC { namespace B3 {

	class Procedure;

	#if ASSERT_DISABLED
	IGNORE_RETURN_TYPE_WARNINGS_BEGIN
	#endif

	namespace Air {

	class GenerateAndAllocateRegisters;
	class BlockInsertionSet;
	class CCallSpecial;
	class CFG;
	class Code;
	class Disassembler;

	typedef void WasmBoundsCheckGeneratorFunction(CCallHelpers&, GPRReg);
	typedef SharedTask<WasmBoundsCheckGeneratorFunction> WasmBoundsCheckGenerator;

	typedef void PrologueGeneratorFunction(CCallHelpers&, Code&);
	typedef SharedTask<PrologueGeneratorFunction> PrologueGenerator;

	// This is an IR that is very close to the bare metal. It requires about 40x more bytes than the
	// generated machine code - for example if you're generating 1MB of machine code, you need about
	// 40MB of Air.

	class Code {
	WTF_MAKE_NONCOPYABLE(Code);
	WTF_MAKE_FAST_ALLOCATED;
	public:
	~Code();

	Procedure& proc() { return m_proc; }

	const Vector<Reg>& regsInPriorityOrder(Bank bank) const
	{
	switch (bank) {
	case GP:
	return m_gpRegsInPriorityOrder;
	case FP:
	return m_fpRegsInPriorityOrder;
	}
	ASSERT_NOT_REACHED();
	}

	// This is the set of registers that Air is allowed to emit code to mutate. It's derived from
	// regsInPriorityOrder. Any registers not in this set are said to be "pinned".
	const RegisterSet& mutableRegs() const { return m_mutableRegs; }

	bool isPinned(Reg reg) const { return !mutableRegs().get(reg); }
	void pinRegister(Reg);

	void setOptLevel(unsigned optLevel) { m_optLevel = optLevel; }
	unsigned optLevel() const { return m_optLevel; }

	bool needsUsedRegisters() const;

	JS_EXPORT_PRIVATE BasicBlock* addBlock(double frequency = 1);

	// Note that you can rely on stack slots always getting indices that are larger than the index
	// of any prior stack slot. In fact, all stack slots you create in the future will have an index
	// that is >= stackSlots().size().
	JS_EXPORT_PRIVATE StackSlot* addStackSlot(
	unsigned byteSize, StackSlotKind, B3::StackSlot* = nullptr);
	StackSlot* addStackSlot(B3::StackSlot*);

	JS_EXPORT_PRIVATE Special* addSpecial(std::unique_ptr<Special>);

	// This is the special you need to make a C call!
	CCallSpecial* cCallSpecial();

	Tmp newTmp(Bank bank)
	{
	switch (bank) {
	case GP:
	return Tmp::gpTmpForIndex(m_numGPTmps++);
	case FP:
	return Tmp::fpTmpForIndex(m_numFPTmps++);
	}
	ASSERT_NOT_REACHED();
	}

	unsigned numTmps(Bank bank)
	{
	switch (bank) {
	case GP:
	return m_numGPTmps;
	case FP:
	return m_numFPTmps;
	}
	ASSERT_NOT_REACHED();
	}

	template<typename Func>
	void forEachTmp(const Func& func)
	{
	for (unsigned bankIndex = 0; bankIndex < numBanks; ++bankIndex) {
	Bank bank = static_cast<Bank>(bankIndex);
	unsigned numTmps = this->numTmps(bank);
	for (unsigned i = 0; i < numTmps; ++i)
	func(Tmp::tmpForIndex(bank, i));
	}
	}

	unsigned callArgAreaSizeInBytes() const { return m_callArgAreaSize; }

	// You can call this before code generation to force a minimum call arg area size.
	void requestCallArgAreaSizeInBytes(unsigned size)
	{
	m_callArgAreaSize = std::max(
	m_callArgAreaSize,
	static_cast<unsigned>(WTF::roundUpToMultipleOf(stackAlignmentBytes(), size)));
	}

	unsigned frameSize() const { return m_frameSize; }

	// Only phases that do stack allocation are allowed to set this. Currently, only
	// Air::allocateStack() does this.
	void setFrameSize(unsigned frameSize)
	{
	m_frameSize = frameSize;
	}

	// Note that this is not the same thing as proc().numEntrypoints(). This value here may be zero
	// until we lower EntrySwitch.
	unsigned numEntrypoints() const { return m_entrypoints.size(); }
	const Vector<FrequentedBlock>& entrypoints() const { return m_entrypoints; }
	const FrequentedBlock& entrypoint(unsigned index) const { return m_entrypoints[index]; }
	bool isEntrypoint(BasicBlock*) const;
	// Note: It is only valid to call this function after LowerEntrySwitch.
	Optional<unsigned> entrypointIndex(BasicBlock*) const;

	// Note: We allow this to be called even before we set m_entrypoints just for convenience to users of this API.
	// However, if you call this before setNumEntrypoints, setNumEntrypoints will overwrite this value.
	void setPrologueForEntrypoint(unsigned entrypointIndex, Ref<PrologueGenerator>&& generator)
	{
	m_prologueGenerators[entrypointIndex] = WTFMove(generator);
	}
	const Ref<PrologueGenerator>& prologueGeneratorForEntrypoint(unsigned entrypointIndex)
	{
	return m_prologueGenerators[entrypointIndex];
	}

	void setNumEntrypoints(unsigned);

	// This is used by lowerEntrySwitch().
	template<typename Vector>
	void setEntrypoints(Vector&& vector)
	{
	m_entrypoints = std::forward<Vector>(vector);
	RELEASE_ASSERT(m_entrypoints.size() == m_prologueGenerators.size());
	}

	CCallHelpers::Label entrypointLabel(unsigned index) const
	{
	return m_entrypointLabels[index];
	}

	// This is used by generate().
	template<typename Vector>
	void setEntrypointLabels(Vector&& vector)
	{
	m_entrypointLabels = std::forward<Vector>(vector);
	RELEASE_ASSERT(m_entrypointLabels.size() == m_prologueGenerators.size());
	}

	void setStackIsAllocated(bool value)
	{
	m_stackIsAllocated = value;
	}

	bool stackIsAllocated() const { return m_stackIsAllocated; }

	// This sets the callee save registers.
	void setCalleeSaveRegisterAtOffsetList(RegisterAtOffsetList&&, StackSlot*);

	// This returns the correctly offset list of callee save registers.
	RegisterAtOffsetList calleeSaveRegisterAtOffsetList() const;

	// This just tells you what the callee saves are.
	RegisterSet calleeSaveRegisters() const { return m_calleeSaveRegisters; }

	// Recomputes predecessors and deletes unreachable blocks.
	JS_EXPORT_PRIVATE void resetReachability();

	JS_EXPORT_PRIVATE void dump(PrintStream&) const;

	unsigned size() const { return m_blocks.size(); }
	BasicBlock* at(unsigned index) const { return m_blocks[index].get(); }
	BasicBlock* operator[](unsigned index) const { return at(index); }

	// This is used by phases that optimize the block list. You shouldn't use this unless you really know
	// what you're doing.
	Vector<std::unique_ptr<BasicBlock>>& blockList() { return m_blocks; }

	// Finds the smallest index' such that at(index') != null and index' >= index.
	JS_EXPORT_PRIVATE unsigned findFirstBlockIndex(unsigned index) const;

	// Finds the smallest index' such that at(index') != null and index' > index.
	unsigned findNextBlockIndex(unsigned index) const;

	BasicBlock* findNextBlock(BasicBlock*) const;

	class iterator {
	public:
	iterator()
	: m_code(nullptr)
	, m_index(0)
	{
	}

	iterator(const Code& code, unsigned index)
	: m_code(&code)
	, m_index(m_code->findFirstBlockIndex(index))
	{
	}

	BasicBlock* operator*()
	{
	return m_code->at(m_index);
	}

	iterator& operator++()
	{
	m_index = m_code->findFirstBlockIndex(m_index + 1);
	return *this;
	}

	bool operator==(const iterator& other) const
	{
	return m_index == other.m_index;
	}

	bool operator!=(const iterator& other) const
	{
	return !(*this == other);
	}

	private:
	const Code* m_code;
	unsigned m_index;
	};

	iterator begin() const { return iterator(*this, 0); }
	iterator end() const { return iterator(*this, size()); }

	const SparseCollection<StackSlot>& stackSlots() const { return m_stackSlots; }
	SparseCollection<StackSlot>& stackSlots() { return m_stackSlots; }

	const SparseCollection<Special>& specials() const { return m_specials; }
	SparseCollection<Special>& specials() { return m_specials; }

	template<typename Callback>
	void forAllTmps(const Callback& callback) const
	{
	for (unsigned i = m_numGPTmps; i--;)
	callback(Tmp::gpTmpForIndex(i));
	for (unsigned i = m_numFPTmps; i--;)
	callback(Tmp::fpTmpForIndex(i));
	}

	void addFastTmp(Tmp);
	bool isFastTmp(Tmp tmp) const { return m_fastTmps.contains(tmp); }

	CFG& cfg() const { return *m_cfg; }

	void* addDataSection(size_t);

	// The name has to be a string literal, since we don't do any memory management for the string.
	void setLastPhaseName(const char* name)
	{
	m_lastPhaseName = name;
	}

	const char* lastPhaseName() const { return m_lastPhaseName; }

	void setWasmBoundsCheckGenerator(RefPtr<WasmBoundsCheckGenerator> generator)
	{
	m_wasmBoundsCheckGenerator = generator;
	}

	RefPtr<WasmBoundsCheckGenerator> wasmBoundsCheckGenerator() const { return m_wasmBoundsCheckGenerator; }

	// This is a hash of the code. You can use this if you want to put code into a hashtable, but
	// it's mainly for validating the results from JSAir.
	unsigned jsHash() const;

	void setDisassembler(std::unique_ptr<Disassembler>&& disassembler) { m_disassembler = WTFMove(disassembler); }
	Disassembler* disassembler() { return m_disassembler.get(); }

	RegisterSet mutableGPRs();
	RegisterSet mutableFPRs();
	RegisterSet pinnedRegisters() const { return m_pinnedRegs; }

	WeakRandom& weakRandom() { return m_weakRandom; }

	void emitDefaultPrologue(CCallHelpers&);

	std::unique_ptr<GenerateAndAllocateRegisters> m_generateAndAllocateRegisters;

	private:
	friend class ::JSC::B3::Procedure;
	friend class BlockInsertionSet;

	Code(Procedure&);

	void setRegsInPriorityOrder(Bank, const Vector<Reg>&);

	Vector<Reg>& regsInPriorityOrderImpl(Bank bank)
	{
	switch (bank) {
	case GP:
	return m_gpRegsInPriorityOrder;
	case FP:
	return m_fpRegsInPriorityOrder;
	}
	ASSERT_NOT_REACHED();
	}

	WeakRandom m_weakRandom;
	Procedure& m_proc; // Some meta-data, like byproducts, is stored in the Procedure.
	Vector<Reg> m_gpRegsInPriorityOrder;
	Vector<Reg> m_fpRegsInPriorityOrder;
	RegisterSet m_mutableRegs;
	RegisterSet m_pinnedRegs;
	SparseCollection<StackSlot> m_stackSlots;
	Vector<std::unique_ptr<BasicBlock>> m_blocks;
	SparseCollection<Special> m_specials;
	std::unique_ptr<CFG> m_cfg;
	HashSet<Tmp> m_fastTmps;
	CCallSpecial* m_cCallSpecial { nullptr };
	unsigned m_numGPTmps { 0 };
	unsigned m_numFPTmps { 0 };
	unsigned m_frameSize { 0 };
	unsigned m_callArgAreaSize { 0 };
	bool m_stackIsAllocated { false };
	RegisterAtOffsetList m_uncorrectedCalleeSaveRegisterAtOffsetList;
	RegisterSet m_calleeSaveRegisters;
	StackSlot* m_calleeSaveStackSlot { nullptr };
	Vector<FrequentedBlock> m_entrypoints; // This is empty until after lowerEntrySwitch().
	Vector<CCallHelpers::Label> m_entrypointLabels; // This is empty until code generation.
	Vector<Ref<PrologueGenerator>, 1> m_prologueGenerators;
	RefPtr<WasmBoundsCheckGenerator> m_wasmBoundsCheckGenerator;
	const char* m_lastPhaseName;
	std::unique_ptr<Disassembler> m_disassembler;
	unsigned m_optLevel { defaultOptLevel() };
	Ref<PrologueGenerator> m_defaultPrologueGenerator;
	};

	} } } // namespace JSC::B3::Air

	#if ASSERT_DISABLED
	IGNORE_RETURN_TYPE_WARNINGS_END
	#endif

	#endif // ENABLE(B3_JIT)