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

 //===- subzero/src/IceAssembler.h - Integrated assembler --------*- C++ -*-===//
 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 //
 // Modified by the Subzero authors.
 //
 //===----------------------------------------------------------------------===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Declares the Assembler base class.
 ///
 /// Instructions are assembled by architecture-specific assemblers that derive
 /// from this base class. This base class manages buffers and fixups for
 /// emitting code, etc.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef SUBZERO_SRC_ICEASSEMBLER_H
 #define SUBZERO_SRC_ICEASSEMBLER_H

 #include "IceDefs.h"
 #include "IceFixups.h"
 #include "IceStringPool.h"
 #include "IceUtils.h"

 #include "llvm/Support/Allocator.h"

 namespace Ice {

 class Assembler;

 /// A Label can be in one of three states:
 ///  - Unused.
 ///  - Linked, unplaced and tracking the position of branches to the label.
 ///  - Bound, placed and tracking its position.
 class Label {
   Label(const Label &) = delete;
   Label &operator=(const Label &) = delete;

 public:
   Label() = default;
   virtual ~Label() = default;

   virtual void finalCheck() const {
     // Assert if label is being destroyed with unresolved branches pending.
     assert(!isLinked());
   }

   /// Returns the encoded position stored in the label.
   intptr_t getEncodedPosition() const { return Position; }

   /// Returns the position for bound labels (branches that come after this are
   /// considered backward branches). Cannot be used for unused or linked labels.
   intptr_t getPosition() const {
     assert(isBound());
     return -Position - kWordSize;
   }

   /// Returns the position of an earlier branch instruction that was linked to
   /// this label (branches that use this are considered forward branches). The
   /// linked instructions form a linked list, of sorts, using the instruction's
   /// displacement field for the location of the next instruction that is also
   /// linked to this label.
   intptr_t getLinkPosition() const {
     assert(isLinked());
     return Position - kWordSize;
   }

   void setPosition(intptr_t NewValue) { Position = NewValue; }

   bool isBound() const { return Position < 0; }
   bool isLinked() const { return Position > 0; }

   virtual bool isUnused() const { return Position == 0; }

   void bindTo(intptr_t position) {
     assert(!isBound());
     Position = -position - kWordSize;
     assert(isBound());
   }

   void linkTo(const Assembler &Asm, intptr_t position);

 protected:
   intptr_t Position = 0;

   // TODO(jvoung): why are labels offset by this?
   static constexpr uint32_t kWordSize = sizeof(uint32_t);
 };

 /// Assembler buffers are used to emit binary code. They grow on demand.
 class AssemblerBuffer {
   AssemblerBuffer(const AssemblerBuffer &) = delete;
   AssemblerBuffer &operator=(const AssemblerBuffer &) = delete;

 public:
   AssemblerBuffer(Assembler &);
   ~AssemblerBuffer();

   /// \name Basic support for emitting, loading, and storing.
   /// @{
   // These use memcpy instead of assignment to avoid undefined behaviour of
   // assigning to unaligned addresses. Since the size of the copy is known the
   // compiler can inline the memcpy with simple moves.
   template <typename T> void emit(T Value) {
     assert(hasEnsuredCapacity());
     memcpy(reinterpret_cast<void *>(Cursor), &Value, sizeof(T));
     Cursor += sizeof(T);
   }

   template <typename T> T load(intptr_t Position) const {
     assert(Position >= 0 &&
            Position <= (size() - static_cast<intptr_t>(sizeof(T))));
     T Value;
     memcpy(&Value, reinterpret_cast<void *>(Contents + Position), sizeof(T));
     return Value;
   }

   template <typename T> void store(intptr_t Position, T Value) {
     assert(Position >= 0 &&
            Position <= (size() - static_cast<intptr_t>(sizeof(T))));
     memcpy(reinterpret_cast<void *>(Contents + Position), &Value, sizeof(T));
   }
   /// @{

   /// Emit a fixup at the current location.
   void emitFixup(AssemblerFixup *Fixup) { Fixup->set_position(size()); }

   /// Get the size of the emitted code.
   intptr_t size() const { return Cursor - Contents; }
   uintptr_t contents() const { return Contents; }

   /// To emit an instruction to the assembler buffer, the EnsureCapacity helper
   /// must be used to guarantee that the underlying data area is big enough to
   /// hold the emitted instruction. Usage:
   ///
   ///     AssemblerBuffer buffer;
   ///     AssemblerBuffer::EnsureCapacity ensured(&buffer);
   ///     ... emit bytes for single instruction ...
   class EnsureCapacity {
     EnsureCapacity(const EnsureCapacity &) = delete;
     EnsureCapacity &operator=(const EnsureCapacity &) = delete;

   public:
     explicit EnsureCapacity(AssemblerBuffer *Buffer) : Buffer(Buffer) {
       if (Buffer->cursor() >= Buffer->limit())
         Buffer->extendCapacity();
       if (BuildDefs::asserts())
         validate(Buffer);
     }
     ~EnsureCapacity();

   private:
     AssemblerBuffer *Buffer;
     intptr_t Gap = 0;

     void validate(AssemblerBuffer *Buffer);
     intptr_t computeGap() { return Buffer->capacity() - Buffer->size(); }
   };

   bool HasEnsuredCapacity;
   bool hasEnsuredCapacity() const {
     if (BuildDefs::asserts())
       return HasEnsuredCapacity;
     // Disable the actual check in non-debug mode.
     return true;
   }

   /// Returns the position in the instruction stream.
   intptr_t getPosition() const { return Cursor - Contents; }

   /// Create and track a fixup in the current function.
   AssemblerFixup *createFixup(FixupKind Kind, const Constant *Value);

   /// Create and track a textual fixup in the current function.
   AssemblerTextFixup *createTextFixup(const std::string &Text,
                                       size_t BytesUsed);

   /// Mark that an attempt was made to emit, but failed. Hence, in order to
   /// continue, one must emit a text fixup.
   void setNeedsTextFixup() { TextFixupNeeded = true; }
   void resetNeedsTextFixup() { TextFixupNeeded = false; }

   /// Returns true if last emit failed and needs a text fixup.
   bool needsTextFixup() const { return TextFixupNeeded; }

   /// Installs a created fixup, after it has been allocated.
   void installFixup(AssemblerFixup *F);

   const FixupRefList &fixups() const { return Fixups; }

   void setSize(intptr_t NewSize) {
     assert(NewSize <= size());
     Cursor = Contents + NewSize;
   }

 private:
   /// The limit is set to kMinimumGap bytes before the end of the data area.
   /// This leaves enough space for the longest possible instruction and allows
   /// for a single, fast space check per instruction.
   static constexpr intptr_t kMinimumGap = 32;

   uintptr_t Contents;
   uintptr_t Cursor;
   uintptr_t Limit;
   // The member variable is named Assemblr to avoid hiding the class Assembler.
   Assembler &Assemblr;
   /// List of pool-allocated fixups relative to the current function.
   FixupRefList Fixups;
   // True if a textual fixup is needed, because the assembler was unable to
   // emit the last request.
   bool TextFixupNeeded;

   uintptr_t cursor() const { return Cursor; }
   uintptr_t limit() const { return Limit; }
   intptr_t capacity() const {
     assert(Limit >= Contents);
     return (Limit - Contents) + kMinimumGap;
   }

   /// Compute the limit based on the data area and the capacity. See description
   /// of kMinimumGap for the reasoning behind the value.
   static uintptr_t computeLimit(uintptr_t Data, intptr_t Capacity) {
     return Data + Capacity - kMinimumGap;
   }

   void extendCapacity();
 };

 class Assembler {
   Assembler() = delete;
   Assembler(const Assembler &) = delete;
   Assembler &operator=(const Assembler &) = delete;

 public:
   enum AssemblerKind {
     Asm_ARM32,
     Asm_MIPS32,
     Asm_X8632,
     Asm_X8664,
   };

   virtual ~Assembler() = default;

   /// Allocate a chunk of bytes using the per-Assembler allocator.
   uintptr_t allocateBytes(size_t bytes) {
     // For now, alignment is not related to NaCl bundle alignment, since the
     // buffer's GetPosition is relative to the base. So NaCl bundle alignment
     // checks can be relative to that base. Later, the buffer will be copied
     // out to a ".text" section (or an in memory-buffer that can be mprotect'ed
     // with executable permission), and that second buffer should be aligned
     // for NaCl.
     const size_t Alignment = 16;
     return reinterpret_cast<uintptr_t>(Allocator.Allocate(bytes, Alignment));
   }

   /// Allocate data of type T using the per-Assembler allocator.
   template <typename T> T *allocate() { return Allocator.Allocate<T>(); }

   /// Align the tail end of the function to the required target alignment.
   virtual void alignFunction() = 0;
   /// Align the tail end of the basic block to the required target alignment.
   void alignCfgNode() {
     const SizeT Align = 1 << getBundleAlignLog2Bytes();
     padWithNop(Utils::OffsetToAlignment(Buffer.getPosition(), Align));
   }

   /// Add nop padding of a particular width to the current bundle.
   virtual void padWithNop(intptr_t Padding) = 0;

   virtual SizeT getBundleAlignLog2Bytes() const = 0;

   virtual const char *getAlignDirective() const = 0;
   virtual llvm::ArrayRef<uint8_t> getNonExecBundlePadding() const = 0;

   /// Get the label for a CfgNode.
   virtual Label *getCfgNodeLabel(SizeT NodeNumber) = 0;
   /// Mark the current text location as the start of a CFG node.
   virtual void bindCfgNodeLabel(const CfgNode *Node) = 0;

   virtual bool fixupIsPCRel(FixupKind Kind) const = 0;

   /// Return a view of all the bytes of code for the current function.
   llvm::StringRef getBufferView() const;

   /// Return the value of the given type in the corresponding buffer.
   template <typename T> T load(intptr_t Position) const {
     return Buffer.load<T>(Position);
   }

   template <typename T> void store(intptr_t Position, T Value) {
     Buffer.store(Position, Value);
   }

   /// Emit a fixup at the current location.
   void emitFixup(AssemblerFixup *Fixup) { Buffer.emitFixup(Fixup); }

   const FixupRefList &fixups() const { return Buffer.fixups(); }

   AssemblerFixup *createFixup(FixupKind Kind, const Constant *Value) {
     return Buffer.createFixup(Kind, Value);
   }

   AssemblerTextFixup *createTextFixup(const std::string &Text,
                                       size_t BytesUsed) {
     return Buffer.createTextFixup(Text, BytesUsed);
   }

   void bindRelocOffset(RelocOffset *Offset);

   void setNeedsTextFixup() { Buffer.setNeedsTextFixup(); }
   void resetNeedsTextFixup() { Buffer.resetNeedsTextFixup(); }

   bool needsTextFixup() const { return Buffer.needsTextFixup(); }

   void emitIASBytes(GlobalContext *Ctx) const;
   bool getInternal() const { return IsInternal; }
   void setInternal(bool Internal) { IsInternal = Internal; }
   GlobalString getFunctionName() const { return FunctionName; }
   void setFunctionName(GlobalString NewName) { FunctionName = NewName; }
   intptr_t getBufferSize() const { return Buffer.size(); }
   /// Roll back to a (smaller) size.
   void setBufferSize(intptr_t NewSize) { Buffer.setSize(NewSize); }
   void setPreliminary(bool Value) { Preliminary = Value; }
   bool getPreliminary() const { return Preliminary; }

   AssemblerKind getKind() const { return Kind; }

 protected:
   explicit Assembler(AssemblerKind Kind)
       : Kind(Kind), Allocator(), Buffer(*this) {}

 private:
   const AssemblerKind Kind;

   using AssemblerAllocator =
       llvm::BumpPtrAllocatorImpl<llvm::MallocAllocator, /*SlabSize=*/32 * 1024>;
   AssemblerAllocator Allocator;

   /// FunctionName and IsInternal are transferred from the original Cfg object,
   /// since the Cfg object may be deleted by the time the assembler buffer is
   /// emitted.
   GlobalString FunctionName;
   bool IsInternal = false;
   /// Preliminary indicates whether a preliminary pass is being made for
   /// calculating bundle padding (Preliminary=true), versus the final pass where
   /// all changes to label bindings, label links, and relocation fixups are
   /// fully committed (Preliminary=false).
   bool Preliminary = false;

   /// Installs a created fixup, after it has been allocated.
   void installFixup(AssemblerFixup *F) { Buffer.installFixup(F); }

 protected:
   // Buffer's constructor uses the Allocator, so it needs to appear after it.
   // TODO(jpp): dependencies on construction order are a nice way of shooting
   // yourself in the foot. Fix this.
   AssemblerBuffer Buffer;
 };

 } // end of namespace Ice

 #endif // SUBZERO_SRC_ICEASSEMBLER_H_
	//===- subzero/src/IceAssembler.h - Integrated assembler --------- C++ --===//
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	//
	// Modified by the Subzero authors.
	//
	//===----------------------------------------------------------------------===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Declares the Assembler base class.
	///
	/// Instructions are assembled by architecture-specific assemblers that derive
	/// from this base class. This base class manages buffers and fixups for
	/// emitting code, etc.
	///
	//===----------------------------------------------------------------------===//

	#ifndef SUBZERO_SRC_ICEASSEMBLER_H
	#define SUBZERO_SRC_ICEASSEMBLER_H

	#include "IceDefs.h"
	#include "IceFixups.h"
	#include "IceStringPool.h"
	#include "IceUtils.h"

	#include "llvm/Support/Allocator.h"

	namespace Ice {

	class Assembler;

	/// A Label can be in one of three states:
	/// - Unused.
	/// - Linked, unplaced and tracking the position of branches to the label.
	/// - Bound, placed and tracking its position.
	class Label {
	Label(const Label &) = delete;
	Label &operator=(const Label &) = delete;

	public:
	Label() = default;
	virtual ~Label() = default;

	virtual void finalCheck() const {
	// Assert if label is being destroyed with unresolved branches pending.
	assert(!isLinked());
	}

	/// Returns the encoded position stored in the label.
	intptr_t getEncodedPosition() const { return Position; }

	/// Returns the position for bound labels (branches that come after this are
	/// considered backward branches). Cannot be used for unused or linked labels.
	intptr_t getPosition() const {
	assert(isBound());
	return -Position - kWordSize;
	}

	/// Returns the position of an earlier branch instruction that was linked to
	/// this label (branches that use this are considered forward branches). The
	/// linked instructions form a linked list, of sorts, using the instruction's
	/// displacement field for the location of the next instruction that is also
	/// linked to this label.
	intptr_t getLinkPosition() const {
	assert(isLinked());
	return Position - kWordSize;
	}

	void setPosition(intptr_t NewValue) { Position = NewValue; }

	bool isBound() const { return Position < 0; }
	bool isLinked() const { return Position > 0; }

	virtual bool isUnused() const { return Position == 0; }

	void bindTo(intptr_t position) {
	assert(!isBound());
	Position = -position - kWordSize;
	assert(isBound());
	}

	void linkTo(const Assembler &Asm, intptr_t position);

	protected:
	intptr_t Position = 0;

	// TODO(jvoung): why are labels offset by this?
	static constexpr uint32_t kWordSize = sizeof(uint32_t);
	};

	/// Assembler buffers are used to emit binary code. They grow on demand.
	class AssemblerBuffer {
	AssemblerBuffer(const AssemblerBuffer &) = delete;
	AssemblerBuffer &operator=(const AssemblerBuffer &) = delete;

	public:
	AssemblerBuffer(Assembler &);
	~AssemblerBuffer();

	/// \name Basic support for emitting, loading, and storing.
	/// @{
	// These use memcpy instead of assignment to avoid undefined behaviour of
	// assigning to unaligned addresses. Since the size of the copy is known the
	// compiler can inline the memcpy with simple moves.
	template <typename T> void emit(T Value) {
	assert(hasEnsuredCapacity());
	memcpy(reinterpret_cast<void *>(Cursor), &Value, sizeof(T));
	Cursor += sizeof(T);
	}

	template <typename T> T load(intptr_t Position) const {
	assert(Position >= 0 &&
	Position <= (size() - static_cast<intptr_t>(sizeof(T))));
	T Value;
	memcpy(&Value, reinterpret_cast<void *>(Contents + Position), sizeof(T));
	return Value;
	}

	template <typename T> void store(intptr_t Position, T Value) {
	assert(Position >= 0 &&
	Position <= (size() - static_cast<intptr_t>(sizeof(T))));
	memcpy(reinterpret_cast<void *>(Contents + Position), &Value, sizeof(T));
	}
	/// @{

	/// Emit a fixup at the current location.
	void emitFixup(AssemblerFixup *Fixup) { Fixup->set_position(size()); }

	/// Get the size of the emitted code.
	intptr_t size() const { return Cursor - Contents; }
	uintptr_t contents() const { return Contents; }

	/// To emit an instruction to the assembler buffer, the EnsureCapacity helper
	/// must be used to guarantee that the underlying data area is big enough to
	/// hold the emitted instruction. Usage:
	///
	/// AssemblerBuffer buffer;
	/// AssemblerBuffer::EnsureCapacity ensured(&buffer);
	/// ... emit bytes for single instruction ...
	class EnsureCapacity {
	EnsureCapacity(const EnsureCapacity &) = delete;
	EnsureCapacity &operator=(const EnsureCapacity &) = delete;

	public:
	explicit EnsureCapacity(AssemblerBuffer *Buffer) : Buffer(Buffer) {
	if (Buffer->cursor() >= Buffer->limit())
	Buffer->extendCapacity();
	if (BuildDefs::asserts())
	validate(Buffer);
	}
	~EnsureCapacity();

	private:
	AssemblerBuffer *Buffer;
	intptr_t Gap = 0;

	void validate(AssemblerBuffer *Buffer);
	intptr_t computeGap() { return Buffer->capacity() - Buffer->size(); }
	};

	bool HasEnsuredCapacity;
	bool hasEnsuredCapacity() const {
	if (BuildDefs::asserts())
	return HasEnsuredCapacity;
	// Disable the actual check in non-debug mode.
	return true;
	}

	/// Returns the position in the instruction stream.
	intptr_t getPosition() const { return Cursor - Contents; }

	/// Create and track a fixup in the current function.
	AssemblerFixup createFixup(FixupKind Kind, const Constant Value);

	/// Create and track a textual fixup in the current function.
	AssemblerTextFixup *createTextFixup(const std::string &Text,
	size_t BytesUsed);

	/// Mark that an attempt was made to emit, but failed. Hence, in order to
	/// continue, one must emit a text fixup.
	void setNeedsTextFixup() { TextFixupNeeded = true; }
	void resetNeedsTextFixup() { TextFixupNeeded = false; }

	/// Returns true if last emit failed and needs a text fixup.
	bool needsTextFixup() const { return TextFixupNeeded; }

	/// Installs a created fixup, after it has been allocated.
	void installFixup(AssemblerFixup *F);

	const FixupRefList &fixups() const { return Fixups; }

	void setSize(intptr_t NewSize) {
	assert(NewSize <= size());
	Cursor = Contents + NewSize;
	}

	private:
	/// The limit is set to kMinimumGap bytes before the end of the data area.
	/// This leaves enough space for the longest possible instruction and allows
	/// for a single, fast space check per instruction.
	static constexpr intptr_t kMinimumGap = 32;

	uintptr_t Contents;
	uintptr_t Cursor;
	uintptr_t Limit;
	// The member variable is named Assemblr to avoid hiding the class Assembler.
	Assembler &Assemblr;
	/// List of pool-allocated fixups relative to the current function.
	FixupRefList Fixups;
	// True if a textual fixup is needed, because the assembler was unable to
	// emit the last request.
	bool TextFixupNeeded;

	uintptr_t cursor() const { return Cursor; }
	uintptr_t limit() const { return Limit; }
	intptr_t capacity() const {
	assert(Limit >= Contents);
	return (Limit - Contents) + kMinimumGap;
	}

	/// Compute the limit based on the data area and the capacity. See description
	/// of kMinimumGap for the reasoning behind the value.
	static uintptr_t computeLimit(uintptr_t Data, intptr_t Capacity) {
	return Data + Capacity - kMinimumGap;
	}

	void extendCapacity();
	};

	class Assembler {
	Assembler() = delete;
	Assembler(const Assembler &) = delete;
	Assembler &operator=(const Assembler &) = delete;

	public:
	enum AssemblerKind {
	Asm_ARM32,
	Asm_MIPS32,
	Asm_X8632,
	Asm_X8664,
	};

	virtual ~Assembler() = default;

	/// Allocate a chunk of bytes using the per-Assembler allocator.
	uintptr_t allocateBytes(size_t bytes) {
	// For now, alignment is not related to NaCl bundle alignment, since the
	// buffer's GetPosition is relative to the base. So NaCl bundle alignment
	// checks can be relative to that base. Later, the buffer will be copied
	// out to a ".text" section (or an in memory-buffer that can be mprotect'ed
	// with executable permission), and that second buffer should be aligned
	// for NaCl.
	const size_t Alignment = 16;
	return reinterpret_cast<uintptr_t>(Allocator.Allocate(bytes, Alignment));
	}

	/// Allocate data of type T using the per-Assembler allocator.
	template <typename T> T *allocate() { return Allocator.Allocate<T>(); }

	/// Align the tail end of the function to the required target alignment.
	virtual void alignFunction() = 0;
	/// Align the tail end of the basic block to the required target alignment.
	void alignCfgNode() {
	const SizeT Align = 1 << getBundleAlignLog2Bytes();
	padWithNop(Utils::OffsetToAlignment(Buffer.getPosition(), Align));
	}

	/// Add nop padding of a particular width to the current bundle.
	virtual void padWithNop(intptr_t Padding) = 0;

	virtual SizeT getBundleAlignLog2Bytes() const = 0;

	virtual const char *getAlignDirective() const = 0;
	virtual llvm::ArrayRef<uint8_t> getNonExecBundlePadding() const = 0;

	/// Get the label for a CfgNode.
	virtual Label *getCfgNodeLabel(SizeT NodeNumber) = 0;
	/// Mark the current text location as the start of a CFG node.
	virtual void bindCfgNodeLabel(const CfgNode *Node) = 0;

	virtual bool fixupIsPCRel(FixupKind Kind) const = 0;

	/// Return a view of all the bytes of code for the current function.
	llvm::StringRef getBufferView() const;

	/// Return the value of the given type in the corresponding buffer.
	template <typename T> T load(intptr_t Position) const {
	return Buffer.load<T>(Position);
	}

	template <typename T> void store(intptr_t Position, T Value) {
	Buffer.store(Position, Value);
	}

	/// Emit a fixup at the current location.
	void emitFixup(AssemblerFixup *Fixup) { Buffer.emitFixup(Fixup); }

	const FixupRefList &fixups() const { return Buffer.fixups(); }

	AssemblerFixup createFixup(FixupKind Kind, const Constant Value) {
	return Buffer.createFixup(Kind, Value);
	}

	AssemblerTextFixup *createTextFixup(const std::string &Text,
	size_t BytesUsed) {
	return Buffer.createTextFixup(Text, BytesUsed);
	}

	void bindRelocOffset(RelocOffset *Offset);

	void setNeedsTextFixup() { Buffer.setNeedsTextFixup(); }
	void resetNeedsTextFixup() { Buffer.resetNeedsTextFixup(); }

	bool needsTextFixup() const { return Buffer.needsTextFixup(); }

	void emitIASBytes(GlobalContext *Ctx) const;
	bool getInternal() const { return IsInternal; }
	void setInternal(bool Internal) { IsInternal = Internal; }
	GlobalString getFunctionName() const { return FunctionName; }
	void setFunctionName(GlobalString NewName) { FunctionName = NewName; }
	intptr_t getBufferSize() const { return Buffer.size(); }
	/// Roll back to a (smaller) size.
	void setBufferSize(intptr_t NewSize) { Buffer.setSize(NewSize); }
	void setPreliminary(bool Value) { Preliminary = Value; }
	bool getPreliminary() const { return Preliminary; }

	AssemblerKind getKind() const { return Kind; }

	protected:
	explicit Assembler(AssemblerKind Kind)
	: Kind(Kind), Allocator(), Buffer(*this) {}

	private:
	const AssemblerKind Kind;

	using AssemblerAllocator =
	llvm::BumpPtrAllocatorImpl<llvm::MallocAllocator, /SlabSize=/32 * 1024>;
	AssemblerAllocator Allocator;

	/// FunctionName and IsInternal are transferred from the original Cfg object,
	/// since the Cfg object may be deleted by the time the assembler buffer is
	/// emitted.
	GlobalString FunctionName;
	bool IsInternal = false;
	/// Preliminary indicates whether a preliminary pass is being made for
	/// calculating bundle padding (Preliminary=true), versus the final pass where
	/// all changes to label bindings, label links, and relocation fixups are
	/// fully committed (Preliminary=false).
	bool Preliminary = false;

	/// Installs a created fixup, after it has been allocated.
	void installFixup(AssemblerFixup *F) { Buffer.installFixup(F); }

	protected:
	// Buffer's constructor uses the Allocator, so it needs to appear after it.
	// TODO(jpp): dependencies on construction order are a nice way of shooting
	// yourself in the foot. Fix this.
	AssemblerBuffer Buffer;
	};

	} // end of namespace Ice

	#endif // SUBZERO_SRC_ICEASSEMBLER_H_