third_party/subzero/src/IceDefs.h - SwiftShader - Git at Google

 //===- subzero/src/IceDefs.h - Common Subzero declarations ------*- C++ -*-===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Declares various useful types and classes that have widespread use
 /// across Subzero.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef SUBZERO_SRC_ICEDEFS_H
 #define SUBZERO_SRC_ICEDEFS_H

 #include "IceBuildDefs.h" // TODO(stichnot): move into individual files
 #include "IceMemory.h"
 #include "IceTLS.h"

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/ilist.h"
 #include "llvm/ADT/ilist_node.h"
 #include "llvm/ADT/iterator_range.h"
 #include "llvm/Support/Casting.h"
 #include "llvm/Support/ELF.h"
 #include "llvm/Support/raw_ostream.h"

 #include <cassert>
 #include <cstdint>
 #include <cstdio>     // snprintf
 #include <functional> // std::less
 #include <limits>
 #include <list>
 #include <map>
 #include <memory>
 #include <mutex>
 #include <set>
 #include <string>
 #include <system_error>
 #include <unordered_map>
 #include <unordered_set>
 #include <utility>
 #include <vector>

 #define XSTRINGIFY(x) STRINGIFY(x)
 #define STRINGIFY(x) #x

 namespace Ice {

 class Assembler;
 template <template <typename> class> class BitVectorTmpl;
 class Cfg;
 class CfgNode;
 class Constant;
 class ELFFileStreamer;
 class ELFObjectWriter;
 class ELFStreamer;
 class FunctionDeclaration;
 class GlobalContext;
 class GlobalDeclaration;
 class Inst;
 class InstAssign;
 class InstJumpTable;
 class InstPhi;
 class InstSwitch;
 class InstTarget;
 class LiveRange;
 class Liveness;
 class Operand;
 class TargetDataLowering;
 class TargetLowering;
 class Variable;
 class VariableDeclaration;
 class VariablesMetadata;

 /// SizeT is for holding small-ish limits like number of source operands in an
 /// instruction. It is used instead of size_t (which may be 64-bits wide) when
 /// we want to save space.
 using SizeT = uint32_t;

 constexpr char GlobalOffsetTable[] = "_GLOBAL_OFFSET_TABLE_";
 // makeUnique should be used when memory is expected to be allocated from the
 // heap (as opposed to allocated from some Allocator.) It is intended to be
 // used instead of new.
 //
 // The expected usage is as follows
 //
 // class MyClass {
 // public:
 //   static std::unique_ptr<MyClass> create(<ctor_args>) {
 //     return makeUnique<MyClass>(<ctor_args>);
 //   }
 //
 // private:
 //   ENABLE_MAKE_UNIQUE;
 //
 //   MyClass(<ctor_args>) ...
 // }
 //
 // ENABLE_MAKE_UNIQUE is a trick that is necessary if MyClass' ctor is private.
 // Private ctors are highly encouraged when you're writing a class that you'd
 // like to have allocated with makeUnique as it would prevent users from
 // declaring stack allocated variables.
 namespace Internal {
 struct MakeUniqueEnabler {
   template <class T, class... Args>
   static std::unique_ptr<T> create(Args &&... TheArgs) {
     std::unique_ptr<T> Unique(new T(std::forward<Args>(TheArgs)...));
     return Unique;
   }
 };
 } // end of namespace Internal

 template <class T, class... Args>
 static std::unique_ptr<T> makeUnique(Args &&... TheArgs) {
   return ::Ice::Internal::MakeUniqueEnabler::create<T>(
       std::forward<Args>(TheArgs)...);
 }

 #define ENABLE_MAKE_UNIQUE friend struct ::Ice::Internal::MakeUniqueEnabler

 using InstList = llvm::ilist<Inst>;
 // Ideally PhiList would be llvm::ilist<InstPhi>, and similar for AssignList,
 // but this runs into issues with SFINAE.
 using PhiList = InstList;
 using AssignList = InstList;

 // Standard library containers with CfgLocalAllocator.
 template <typename T> using CfgList = std::list<T, CfgLocalAllocator<T>>;
 template <typename T, typename H = std::hash<T>, typename Eq = std::equal_to<T>>
 using CfgUnorderedSet = std::unordered_set<T, H, Eq, CfgLocalAllocator<T>>;
 template <typename T, typename Cmp = std::less<T>>
 using CfgSet = std::set<T, Cmp, CfgLocalAllocator<T>>;
 template <typename T, typename U, typename H = std::hash<T>,
           typename Eq = std::equal_to<T>>
 using CfgUnorderedMap =
     std::unordered_map<T, U, H, Eq, CfgLocalAllocator<std::pair<const T, U>>>;
 template <typename T> using CfgVector = std::vector<T, CfgLocalAllocator<T>>;

 // Containers that are arena-allocated from the Cfg's allocator.
 using OperandList = CfgVector<Operand *>;
 using VarList = CfgVector<Variable *>;
 using NodeList = CfgVector<CfgNode *>;

 // Containers that use the default (global) allocator.
 using ConstantList = std::vector<Constant *>;
 using FunctionDeclarationList = std::vector<FunctionDeclaration *>;

 /// VariableDeclarationList is a container for holding VariableDeclarations --
 /// i.e., Global Variables. It is also used to create said variables, and their
 /// initializers in an arena.
 class VariableDeclarationList {
   VariableDeclarationList(const VariableDeclarationList &) = delete;
   VariableDeclarationList &operator=(const VariableDeclarationList &) = delete;
   VariableDeclarationList(VariableDeclarationList &&) = delete;
   VariableDeclarationList &operator=(VariableDeclarationList &&) = delete;

 public:
   using VariableDeclarationArray = std::vector<VariableDeclaration *>;

   VariableDeclarationList() : Arena(new ArenaAllocator()) {}

   ~VariableDeclarationList() { clearAndPurge(); }

   template <typename T> T *allocate_initializer(SizeT Count = 1) {
     static_assert(
         std::is_trivially_destructible<T>::value,
         "allocate_initializer can only allocate trivially destructible types.");
     return Arena->Allocate<T>(Count);
   }

   template <typename T> T *allocate_variable_declaration() {
     static_assert(!std::is_trivially_destructible<T>::value,
                   "allocate_variable_declaration expects non-trivially "
                   "destructible types.");
     T *Ret = Arena->Allocate<T>();
     Dtors.emplace_back([Ret]() { Ret->~T(); });
     return Ret;
   }

   // This do nothing method is invoked when a global variable is created, but it
   // will not be emitted. If we ever need to track the created variable, having
   // this hook is handy.
   void willNotBeEmitted(VariableDeclaration *) {}

   /// Merges Other with this, effectively resetting Other to an empty state.
   void merge(VariableDeclarationList *Other) {
     assert(Other != nullptr);
     addArena(std::move(Other->Arena));
     for (std::size_t i = 0; i < Other->MergedArenas.size(); ++i) {
       addArena(std::move(Other->MergedArenas[i]));
     }
     Other->MergedArenas.clear();

     Dtors.insert(Dtors.end(), Other->Dtors.begin(), Other->Dtors.end());
     Other->Dtors.clear();

     Globals.insert(Globals.end(), Other->Globals.begin(), Other->Globals.end());
     Other->Globals.clear();
   }

   /// Destroys all GlobalVariables and initializers that this knows about
   /// (including those merged with it), and releases memory.
   void clearAndPurge() {
     if (Arena == nullptr) {
       // Arena is only null if this was merged, so we ensure there's no state
       // being held by this.
       assert(Dtors.empty());
       assert(Globals.empty());
       assert(MergedArenas.empty());
       return;
     }
     // Invokes destructors in reverse creation order.
     for (auto Dtor = Dtors.rbegin(); Dtor != Dtors.rend(); ++Dtor) {
       (*Dtor)();
     }
     Dtors.clear();
     Globals.clear();
     MergedArenas.clear();
     Arena->Reset();
   }

   /// Adapt the relevant parts of the std::vector<VariableDeclaration *>
   /// interface.
   /// @{
   VariableDeclarationArray::iterator begin() { return Globals.begin(); }

   VariableDeclarationArray::iterator end() { return Globals.end(); }

   VariableDeclarationArray::const_iterator begin() const {
     return Globals.begin();
   }

   VariableDeclarationArray::const_iterator end() const { return Globals.end(); }

   bool empty() const { return Globals.empty(); }

   VariableDeclarationArray::size_type size() const { return Globals.size(); }

   VariableDeclarationArray::reference
   at(VariableDeclarationArray::size_type Pos) {
     return Globals.at(Pos);
   }

   void push_back(VariableDeclaration *Global) { Globals.push_back(Global); }

   void reserve(VariableDeclarationArray::size_type Capacity) {
     Globals.reserve(Capacity);
   }

   void clear() { Globals.clear(); }

   VariableDeclarationArray::reference back() { return Globals.back(); }
   /// @}

 private:
   using ArenaPtr = std::unique_ptr<ArenaAllocator>;
   using DestructorsArray = std::vector<std::function<void()>>;

   void addArena(ArenaPtr NewArena) {
     MergedArenas.emplace_back(std::move(NewArena));
   }

   ArenaPtr Arena;
   VariableDeclarationArray Globals;
   DestructorsArray Dtors;
   std::vector<ArenaPtr> MergedArenas;
 };

 /// InstNumberT is for holding an instruction number. Instruction numbers are
 /// used for representing Variable live ranges.
 using InstNumberT = int32_t;

 /// A LiveBeginEndMapEntry maps a Variable::Number value to an Inst::Number
 /// value, giving the instruction number that begins or ends a variable's live
 /// range.
 template <typename T>
 using LivenessVector = std::vector<T, LivenessAllocator<T>>;
 using LiveBeginEndMapEntry = std::pair<SizeT, InstNumberT>;
 using LiveBeginEndMap = LivenessVector<LiveBeginEndMapEntry>;
 using LivenessBV = BitVectorTmpl<LivenessAllocator>;

 using TimerStackIdT = uint32_t;
 using TimerIdT = uint32_t;

 /// Use alignas(MaxCacheLineSize) to isolate variables/fields that might be
 /// contended while multithreading. Assumes the maximum cache line size is 64.
 enum { MaxCacheLineSize = 64 };
 // Use ICE_CACHELINE_BOUNDARY to force the next field in a declaration
 // list to be aligned to the next cache line.
 #if defined(_MSC_VER)
 #define ICE_CACHELINE_BOUNDARY __declspec(align(MaxCacheLineSize)) int : 0;
 #else // !defined(_MSC_VER)
 // Note: zero is added to work around the following GCC 4.8 bug (fixed in 4.9):
 //       https://gcc.gnu.org/bugzilla/show_bug.cgi?id=55382
 #define ICE_CACHELINE_BOUNDARY                                                 \
   __attribute__((aligned(MaxCacheLineSize + 0))) int : 0
 #endif // !defined(_MSC_VER)

 /// PNaCl is ILP32, so theoretically we should only need 32-bit offsets.
 using RelocOffsetT = int32_t;
 enum { RelocAddrSize = 4 };

 enum LivenessMode {
   /// Basic version of live-range-end calculation. Marks the last uses of
   /// variables based on dataflow analysis. Records the set of live-in and
   /// live-out variables for each block. Identifies and deletes dead
   /// instructions (primarily stores).
   Liveness_Basic,

   /// In addition to Liveness_Basic, also calculate the complete live range for
   /// each variable in a form suitable for interference calculation and register
   /// allocation.
   Liveness_Intervals
 };

 enum LCSEOptions {
   LCSE_Disabled,
   LCSE_EnabledSSA,  // Default Mode, assumes SSA.
   LCSE_EnabledNoSSA // Does not assume SSA, to be enabled if CSE is done later.
 };

 enum RegAllocKind {
   RAK_Unknown,
   RAK_Global,       /// full, global register allocation
   RAK_SecondChance, /// second-chance bin-packing after full regalloc attempt
   RAK_Phi,          /// infinite-weight Variables with active spilling/filling
   RAK_InfOnly       /// allocation only for infinite-weight Variables
 };

 enum VerboseItem {
   IceV_None = 0,
   IceV_Instructions = 1 << 0,
   IceV_Deleted = 1 << 1,
   IceV_InstNumbers = 1 << 2,
   IceV_Preds = 1 << 3,
   IceV_Succs = 1 << 4,
   IceV_Liveness = 1 << 5,
   IceV_RegOrigins = 1 << 6,
   IceV_LinearScan = 1 << 7,
   IceV_Frame = 1 << 8,
   IceV_AddrOpt = 1 << 9,
   IceV_Folding = 1 << 10,
   IceV_RMW = 1 << 11,
   IceV_Loop = 1 << 12,
   IceV_Mem = 1 << 13,
   // Leave some extra space to make it easier to add new per-pass items.
   IceV_NO_PER_PASS_DUMP_BEYOND = 1 << 19,
   // Items greater than IceV_NO_PER_PASS_DUMP_BEYOND don't by themselves trigger
   // per-pass Cfg dump output.
   IceV_Status = 1 << 20,
   IceV_AvailableRegs = 1 << 21,
   IceV_GlobalInit = 1 << 22,
   IceV_ConstPoolStats = 1 << 23,
   IceV_Wasm = 1 << 24,
   IceV_ShufMat = 1 << 25,
   IceV_All = ~IceV_None,
   IceV_Most =
       IceV_All & ~IceV_LinearScan & ~IceV_GlobalInit & ~IceV_ConstPoolStats
 };
 using VerboseMask = uint32_t;

 enum FileType {
   FT_Elf, /// ELF .o file
   FT_Asm, /// Assembly .s file
   FT_Iasm /// "Integrated assembler" .byte-style .s file
 };

 enum ABI {
   ABI_PNaCl,   /// x32 for unsandboxed 64-bit x86
   ABI_Platform /// Native executable ABI
 };

 using Ostream = llvm::raw_ostream;
 using Fdstream = llvm::raw_fd_ostream;

 using GlobalLockType = std::mutex;

 /// LockedPtr is an RAII wrapper that allows automatically locked access to a
 /// given pointer, automatically unlocking it when when the LockedPtr goes out
 /// of scope.
 template <typename T> class LockedPtr {
   LockedPtr() = delete;
   LockedPtr(const LockedPtr &) = delete;
   LockedPtr &operator=(const LockedPtr &) = delete;

 public:
   LockedPtr(T *Value, GlobalLockType *Lock) : Value(Value), Lock(Lock) {
     Lock->lock();
   }
   LockedPtr(LockedPtr &&Other) : Value(Other.Value), Lock(Other.Lock) {
     Other.Value = nullptr;
     Other.Lock = nullptr;
   }
   ~LockedPtr() {
     if (Lock != nullptr)
       Lock->unlock();
   }
   T *operator->() const { return Value; }
   T &operator*() const { return *Value; }
   T *get() { return Value; }

 private:
   T *Value;
   GlobalLockType *Lock;
 };

 enum ErrorCodes { EC_None = 0, EC_Args, EC_Bitcode, EC_Translation };

 /// Wrapper around std::error_code for allowing multiple errors to be folded
 /// into one. The current implementation keeps track of the first error, which
 /// is likely to be the most useful one, and this could be extended to e.g.
 /// collect a vector of errors.
 class ErrorCode : public std::error_code {
   ErrorCode(const ErrorCode &) = delete;
   ErrorCode &operator=(const ErrorCode &) = delete;

 public:
   ErrorCode() = default;
   void assign(ErrorCodes Code) {
     if (!HasError) {
       HasError = true;
       std::error_code::assign(Code, std::generic_category());
     }
   }
   void assign(int Code) { assign(static_cast<ErrorCodes>(Code)); }

 private:
   bool HasError = false;
 };

 /// Reverse range adaptors written in terms of llvm::make_range().
 template <typename T>
 llvm::iterator_range<typename T::const_reverse_iterator>
 reverse_range(const T &Container) {
   return llvm::make_range(Container.rbegin(), Container.rend());
 }
 template <typename T>
 llvm::iterator_range<typename T::reverse_iterator> reverse_range(T &Container) {
   return llvm::make_range(Container.rbegin(), Container.rend());
 }

 using RelocOffsetArray = llvm::SmallVector<class RelocOffset *, 4>;

 } // end of namespace Ice

 #endif // SUBZERO_SRC_ICEDEFS_H
	//===- subzero/src/IceDefs.h - Common Subzero declarations ------- C++ --===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Declares various useful types and classes that have widespread use
	/// across Subzero.
	///
	//===----------------------------------------------------------------------===//

	#ifndef SUBZERO_SRC_ICEDEFS_H
	#define SUBZERO_SRC_ICEDEFS_H

	#include "IceBuildDefs.h" // TODO(stichnot): move into individual files
	#include "IceMemory.h"
	#include "IceTLS.h"

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/ilist.h"
	#include "llvm/ADT/ilist_node.h"
	#include "llvm/ADT/iterator_range.h"
	#include "llvm/Support/Casting.h"
	#include "llvm/Support/ELF.h"
	#include "llvm/Support/raw_ostream.h"

	#include <cassert>
	#include <cstdint>
	#include <cstdio> // snprintf
	#include <functional> // std::less
	#include <limits>
	#include <list>
	#include <map>
	#include <memory>
	#include <mutex>
	#include <set>
	#include <string>
	#include <system_error>
	#include <unordered_map>
	#include <unordered_set>
	#include <utility>
	#include <vector>

	#define XSTRINGIFY(x) STRINGIFY(x)
	#define STRINGIFY(x) #x

	namespace Ice {

	class Assembler;
	template <template <typename> class> class BitVectorTmpl;
	class Cfg;
	class CfgNode;
	class Constant;
	class ELFFileStreamer;
	class ELFObjectWriter;
	class ELFStreamer;
	class FunctionDeclaration;
	class GlobalContext;
	class GlobalDeclaration;
	class Inst;
	class InstAssign;
	class InstJumpTable;
	class InstPhi;
	class InstSwitch;
	class InstTarget;
	class LiveRange;
	class Liveness;
	class Operand;
	class TargetDataLowering;
	class TargetLowering;
	class Variable;
	class VariableDeclaration;
	class VariablesMetadata;

	/// SizeT is for holding small-ish limits like number of source operands in an
	/// instruction. It is used instead of size_t (which may be 64-bits wide) when
	/// we want to save space.
	using SizeT = uint32_t;

	constexpr char GlobalOffsetTable[] = "_GLOBAL_OFFSET_TABLE_";
	// makeUnique should be used when memory is expected to be allocated from the
	// heap (as opposed to allocated from some Allocator.) It is intended to be
	// used instead of new.
	//
	// The expected usage is as follows
	//
	// class MyClass {
	// public:
	// static std::unique_ptr<MyClass> create(<ctor_args>) {
	// return makeUnique<MyClass>(<ctor_args>);
	// }
	//
	// private:
	// ENABLE_MAKE_UNIQUE;
	//
	// MyClass(<ctor_args>) ...
	// }
	//
	// ENABLE_MAKE_UNIQUE is a trick that is necessary if MyClass' ctor is private.
	// Private ctors are highly encouraged when you're writing a class that you'd
	// like to have allocated with makeUnique as it would prevent users from
	// declaring stack allocated variables.
	namespace Internal {
	struct MakeUniqueEnabler {
	template <class T, class... Args>
	static std::unique_ptr<T> create(Args &&... TheArgs) {
	std::unique_ptr<T> Unique(new T(std::forward<Args>(TheArgs)...));
	return Unique;
	}
	};
	} // end of namespace Internal

	template <class T, class... Args>
	static std::unique_ptr<T> makeUnique(Args &&... TheArgs) {
	return ::Ice::Internal::MakeUniqueEnabler::create<T>(
	std::forward<Args>(TheArgs)...);
	}

	#define ENABLE_MAKE_UNIQUE friend struct ::Ice::Internal::MakeUniqueEnabler

	using InstList = llvm::ilist<Inst>;
	// Ideally PhiList would be llvm::ilist<InstPhi>, and similar for AssignList,
	// but this runs into issues with SFINAE.
	using PhiList = InstList;
	using AssignList = InstList;

	// Standard library containers with CfgLocalAllocator.
	template <typename T> using CfgList = std::list<T, CfgLocalAllocator<T>>;
	template <typename T, typename H = std::hash<T>, typename Eq = std::equal_to<T>>
	using CfgUnorderedSet = std::unordered_set<T, H, Eq, CfgLocalAllocator<T>>;
	template <typename T, typename Cmp = std::less<T>>
	using CfgSet = std::set<T, Cmp, CfgLocalAllocator<T>>;
	template <typename T, typename U, typename H = std::hash<T>,
	typename Eq = std::equal_to<T>>
	using CfgUnorderedMap =
	std::unordered_map<T, U, H, Eq, CfgLocalAllocator<std::pair<const T, U>>>;
	template <typename T> using CfgVector = std::vector<T, CfgLocalAllocator<T>>;

	// Containers that are arena-allocated from the Cfg's allocator.
	using OperandList = CfgVector<Operand *>;
	using VarList = CfgVector<Variable *>;
	using NodeList = CfgVector<CfgNode *>;

	// Containers that use the default (global) allocator.
	using ConstantList = std::vector<Constant *>;
	using FunctionDeclarationList = std::vector<FunctionDeclaration *>;

	/// VariableDeclarationList is a container for holding VariableDeclarations --
	/// i.e., Global Variables. It is also used to create said variables, and their
	/// initializers in an arena.
	class VariableDeclarationList {
	VariableDeclarationList(const VariableDeclarationList &) = delete;
	VariableDeclarationList &operator=(const VariableDeclarationList &) = delete;
	VariableDeclarationList(VariableDeclarationList &&) = delete;
	VariableDeclarationList &operator=(VariableDeclarationList &&) = delete;

	public:
	using VariableDeclarationArray = std::vector<VariableDeclaration *>;

	VariableDeclarationList() : Arena(new ArenaAllocator()) {}

	~VariableDeclarationList() { clearAndPurge(); }

	template <typename T> T *allocate_initializer(SizeT Count = 1) {
	static_assert(
	std::is_trivially_destructible<T>::value,
	"allocate_initializer can only allocate trivially destructible types.");
	return Arena->Allocate<T>(Count);
	}

	template <typename T> T *allocate_variable_declaration() {
	static_assert(!std::is_trivially_destructible<T>::value,
	"allocate_variable_declaration expects non-trivially "
	"destructible types.");
	T *Ret = Arena->Allocate<T>();
	Dtors.emplace_back([Ret]() { Ret->~T(); });
	return Ret;
	}

	// This do nothing method is invoked when a global variable is created, but it
	// will not be emitted. If we ever need to track the created variable, having
	// this hook is handy.
	void willNotBeEmitted(VariableDeclaration *) {}

	/// Merges Other with this, effectively resetting Other to an empty state.
	void merge(VariableDeclarationList *Other) {
	assert(Other != nullptr);
	addArena(std::move(Other->Arena));
	for (std::size_t i = 0; i < Other->MergedArenas.size(); ++i) {
	addArena(std::move(Other->MergedArenas[i]));
	}
	Other->MergedArenas.clear();

	Dtors.insert(Dtors.end(), Other->Dtors.begin(), Other->Dtors.end());
	Other->Dtors.clear();

	Globals.insert(Globals.end(), Other->Globals.begin(), Other->Globals.end());
	Other->Globals.clear();
	}

	/// Destroys all GlobalVariables and initializers that this knows about
	/// (including those merged with it), and releases memory.
	void clearAndPurge() {
	if (Arena == nullptr) {
	// Arena is only null if this was merged, so we ensure there's no state
	// being held by this.
	assert(Dtors.empty());
	assert(Globals.empty());
	assert(MergedArenas.empty());
	return;
	}
	// Invokes destructors in reverse creation order.
	for (auto Dtor = Dtors.rbegin(); Dtor != Dtors.rend(); ++Dtor) {
	(*Dtor)();
	}
	Dtors.clear();
	Globals.clear();
	MergedArenas.clear();
	Arena->Reset();
	}

	/// Adapt the relevant parts of the std::vector<VariableDeclaration *>
	/// interface.
	/// @{
	VariableDeclarationArray::iterator begin() { return Globals.begin(); }

	VariableDeclarationArray::iterator end() { return Globals.end(); }

	VariableDeclarationArray::const_iterator begin() const {
	return Globals.begin();
	}

	VariableDeclarationArray::const_iterator end() const { return Globals.end(); }

	bool empty() const { return Globals.empty(); }

	VariableDeclarationArray::size_type size() const { return Globals.size(); }

	VariableDeclarationArray::reference
	at(VariableDeclarationArray::size_type Pos) {
	return Globals.at(Pos);
	}

	void push_back(VariableDeclaration *Global) { Globals.push_back(Global); }

	void reserve(VariableDeclarationArray::size_type Capacity) {
	Globals.reserve(Capacity);
	}

	void clear() { Globals.clear(); }

	VariableDeclarationArray::reference back() { return Globals.back(); }
	/// @}

	private:
	using ArenaPtr = std::unique_ptr<ArenaAllocator>;
	using DestructorsArray = std::vector<std::function<void()>>;

	void addArena(ArenaPtr NewArena) {
	MergedArenas.emplace_back(std::move(NewArena));
	}

	ArenaPtr Arena;
	VariableDeclarationArray Globals;
	DestructorsArray Dtors;
	std::vector<ArenaPtr> MergedArenas;
	};

	/// InstNumberT is for holding an instruction number. Instruction numbers are
	/// used for representing Variable live ranges.
	using InstNumberT = int32_t;

	/// A LiveBeginEndMapEntry maps a Variable::Number value to an Inst::Number
	/// value, giving the instruction number that begins or ends a variable's live
	/// range.
	template <typename T>
	using LivenessVector = std::vector<T, LivenessAllocator<T>>;
	using LiveBeginEndMapEntry = std::pair<SizeT, InstNumberT>;
	using LiveBeginEndMap = LivenessVector<LiveBeginEndMapEntry>;
	using LivenessBV = BitVectorTmpl<LivenessAllocator>;

	using TimerStackIdT = uint32_t;
	using TimerIdT = uint32_t;

	/// Use alignas(MaxCacheLineSize) to isolate variables/fields that might be
	/// contended while multithreading. Assumes the maximum cache line size is 64.
	enum { MaxCacheLineSize = 64 };
	// Use ICE_CACHELINE_BOUNDARY to force the next field in a declaration
	// list to be aligned to the next cache line.
	#if defined(_MSC_VER)
	#define ICE_CACHELINE_BOUNDARY __declspec(align(MaxCacheLineSize)) int : 0;
	#else // !defined(_MSC_VER)
	// Note: zero is added to work around the following GCC 4.8 bug (fixed in 4.9):
	// https://gcc.gnu.org/bugzilla/show_bug.cgi?id=55382
	#define ICE_CACHELINE_BOUNDARY \
	__attribute__((aligned(MaxCacheLineSize + 0))) int : 0
	#endif // !defined(_MSC_VER)

	/// PNaCl is ILP32, so theoretically we should only need 32-bit offsets.
	using RelocOffsetT = int32_t;
	enum { RelocAddrSize = 4 };

	enum LivenessMode {
	/// Basic version of live-range-end calculation. Marks the last uses of
	/// variables based on dataflow analysis. Records the set of live-in and
	/// live-out variables for each block. Identifies and deletes dead
	/// instructions (primarily stores).
	Liveness_Basic,

	/// In addition to Liveness_Basic, also calculate the complete live range for
	/// each variable in a form suitable for interference calculation and register
	/// allocation.
	Liveness_Intervals
	};

	enum LCSEOptions {
	LCSE_Disabled,
	LCSE_EnabledSSA, // Default Mode, assumes SSA.
	LCSE_EnabledNoSSA // Does not assume SSA, to be enabled if CSE is done later.
	};

	enum RegAllocKind {
	RAK_Unknown,
	RAK_Global, /// full, global register allocation
	RAK_SecondChance, /// second-chance bin-packing after full regalloc attempt
	RAK_Phi, /// infinite-weight Variables with active spilling/filling
	RAK_InfOnly /// allocation only for infinite-weight Variables
	};

	enum VerboseItem {
	IceV_None = 0,
	IceV_Instructions = 1 << 0,
	IceV_Deleted = 1 << 1,
	IceV_InstNumbers = 1 << 2,
	IceV_Preds = 1 << 3,
	IceV_Succs = 1 << 4,
	IceV_Liveness = 1 << 5,
	IceV_RegOrigins = 1 << 6,
	IceV_LinearScan = 1 << 7,
	IceV_Frame = 1 << 8,
	IceV_AddrOpt = 1 << 9,
	IceV_Folding = 1 << 10,
	IceV_RMW = 1 << 11,
	IceV_Loop = 1 << 12,
	IceV_Mem = 1 << 13,
	// Leave some extra space to make it easier to add new per-pass items.
	IceV_NO_PER_PASS_DUMP_BEYOND = 1 << 19,
	// Items greater than IceV_NO_PER_PASS_DUMP_BEYOND don't by themselves trigger
	// per-pass Cfg dump output.
	IceV_Status = 1 << 20,
	IceV_AvailableRegs = 1 << 21,
	IceV_GlobalInit = 1 << 22,
	IceV_ConstPoolStats = 1 << 23,
	IceV_Wasm = 1 << 24,
	IceV_ShufMat = 1 << 25,
	IceV_All = ~IceV_None,
	IceV_Most =
	IceV_All & ~IceV_LinearScan & ~IceV_GlobalInit & ~IceV_ConstPoolStats
	};
	using VerboseMask = uint32_t;

	enum FileType {
	FT_Elf, /// ELF .o file
	FT_Asm, /// Assembly .s file
	FT_Iasm /// "Integrated assembler" .byte-style .s file
	};

	enum ABI {
	ABI_PNaCl, /// x32 for unsandboxed 64-bit x86
	ABI_Platform /// Native executable ABI
	};

	using Ostream = llvm::raw_ostream;
	using Fdstream = llvm::raw_fd_ostream;

	using GlobalLockType = std::mutex;

	/// LockedPtr is an RAII wrapper that allows automatically locked access to a
	/// given pointer, automatically unlocking it when when the LockedPtr goes out
	/// of scope.
	template <typename T> class LockedPtr {
	LockedPtr() = delete;
	LockedPtr(const LockedPtr &) = delete;
	LockedPtr &operator=(const LockedPtr &) = delete;

	public:
	LockedPtr(T Value, GlobalLockType Lock) : Value(Value), Lock(Lock) {
	Lock->lock();
	}
	LockedPtr(LockedPtr &&Other) : Value(Other.Value), Lock(Other.Lock) {
	Other.Value = nullptr;
	Other.Lock = nullptr;
	}
	~LockedPtr() {
	if (Lock != nullptr)
	Lock->unlock();
	}
	T *operator->() const { return Value; }
	T &operator() const { return Value; }
	T *get() { return Value; }

	private:
	T *Value;
	GlobalLockType *Lock;
	};

	enum ErrorCodes { EC_None = 0, EC_Args, EC_Bitcode, EC_Translation };

	/// Wrapper around std::error_code for allowing multiple errors to be folded
	/// into one. The current implementation keeps track of the first error, which
	/// is likely to be the most useful one, and this could be extended to e.g.
	/// collect a vector of errors.
	class ErrorCode : public std::error_code {
	ErrorCode(const ErrorCode &) = delete;
	ErrorCode &operator=(const ErrorCode &) = delete;

	public:
	ErrorCode() = default;
	void assign(ErrorCodes Code) {
	if (!HasError) {
	HasError = true;
	std::error_code::assign(Code, std::generic_category());
	}
	}
	void assign(int Code) { assign(static_cast<ErrorCodes>(Code)); }

	private:
	bool HasError = false;
	};

	/// Reverse range adaptors written in terms of llvm::make_range().
	template <typename T>
	llvm::iterator_range<typename T::const_reverse_iterator>
	reverse_range(const T &Container) {
	return llvm::make_range(Container.rbegin(), Container.rend());
	}
	template <typename T>
	llvm::iterator_range<typename T::reverse_iterator> reverse_range(T &Container) {
	return llvm::make_range(Container.rbegin(), Container.rend());
	}

	using RelocOffsetArray = llvm::SmallVector<class RelocOffset *, 4>;

	} // end of namespace Ice

	#endif // SUBZERO_SRC_ICEDEFS_H