runtime/vm/assembler.h - sdk.git - Git at Google

 // 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.

 #ifndef VM_ASSEMBLER_H_
 #define VM_ASSEMBLER_H_

 #include "platform/assert.h"
 #include "vm/allocation.h"
 #include "vm/globals.h"
 #include "vm/growable_array.h"
 #include "vm/object.h"

 namespace dart {

 // Forward declarations.
 class Assembler;
 class AssemblerFixup;
 class AssemblerBuffer;
 class MemoryRegion;


 // External labels keep a function pointer to allow them
 // to be called from code generated by the assembler.
 class ExternalLabel : public ValueObject {
  public:
   ExternalLabel(const char* name, uword address)
       : name_(name), address_(address) {
     ASSERT(name != NULL);
   }

   const char* name() const { return name_; }
   bool is_resolved() const { return address_ != 0; }
   uword address() const {
     ASSERT(is_resolved());
     return address_;
   }

  private:
   const char* name_;
   const uword address_;
 };


 // Assembler fixups are positions in generated code that hold relocation
 // information that needs to be processed before finalizing the code
 // into executable memory.
 class AssemblerFixup : public ZoneAllocated {
  public:
   virtual void Process(const MemoryRegion& region, int position) = 0;

   // It would be ideal if the destructor method could be made private,
   // but the g++ compiler complains when this is subclassed.
   virtual ~AssemblerFixup() { UNREACHABLE(); }

  private:
   AssemblerFixup* previous_;
   int position_;

   AssemblerFixup* previous() const { return previous_; }
   void set_previous(AssemblerFixup* previous) { previous_ = previous; }

   int position() const { return position_; }
   void set_position(int position) { position_ = position; }

   friend class AssemblerBuffer;
 };


 // Assembler buffers are used to emit binary code. They grow on demand.
 class AssemblerBuffer : public ValueObject {
  public:
   AssemblerBuffer();
   ~AssemblerBuffer();

   // Basic support for emitting, loading, and storing.
   template<typename T> void Emit(T value) {
     ASSERT(HasEnsuredCapacity());
     *reinterpret_cast<T*>(cursor_) = value;
     cursor_ += sizeof(T);
   }

   template<typename T> void Remit() {
     ASSERT(Size() >= static_cast<intptr_t>(sizeof(T)));
     cursor_ -= sizeof(T);
   }

   template<typename T> T Load(int position) {
     ASSERT(position >= 0 && position <= (Size() - static_cast<int>(sizeof(T))));
     return *reinterpret_cast<T*>(contents_ + position);
   }

   template<typename T> void Store(int position, T value) {
     ASSERT(position >= 0 && position <= (Size() - static_cast<int>(sizeof(T))));
     *reinterpret_cast<T*>(contents_ + position) = value;
   }

   const ZoneGrowableArray<int>& pointer_offsets() const {
 #if defined(DEBUG)
     ASSERT(fixups_processed_);
 #endif
     return *pointer_offsets_;
   }

   // Emit an object pointer directly in the code.
   void EmitObject(const Object& object);

   // Emit a fixup at the current location.
   void EmitFixup(AssemblerFixup* fixup) {
     fixup->set_previous(fixup_);
     fixup->set_position(Size());
     fixup_ = fixup;
   }

   // Get the size of the emitted code.
   intptr_t Size() const { return cursor_ - contents_; }
   uword contents() const { return contents_; }

   // Copy the assembled instructions into the specified memory block
   // and apply all fixups.
   void FinalizeInstructions(const MemoryRegion& region);

   // 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 ...

 #if defined(DEBUG)
   class EnsureCapacity : public ValueObject {
    public:
     explicit EnsureCapacity(AssemblerBuffer* buffer);
     ~EnsureCapacity();

    private:
     AssemblerBuffer* buffer_;
     intptr_t gap_;

     intptr_t ComputeGap() { return buffer_->Capacity() - buffer_->Size(); }
   };

   bool has_ensured_capacity_;
   bool HasEnsuredCapacity() const { return has_ensured_capacity_; }
 #else
   class EnsureCapacity : public ValueObject {
    public:
     explicit EnsureCapacity(AssemblerBuffer* buffer) {
       if (buffer->cursor() >= buffer->limit()) buffer->ExtendCapacity();
     }
   };

   // When building the C++ tests, assertion code is enabled. To allow
   // asserting that the user of the assembler buffer has ensured the
   // capacity needed for emitting, we add a dummy method in non-debug mode.
   bool HasEnsuredCapacity() const { return true; }
 #endif

   // Returns the position in the instruction stream.
   intptr_t GetPosition() const { return cursor_ - contents_; }

  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 const intptr_t kMinimumGap = 32;

   uword contents_;
   uword cursor_;
   uword limit_;
   AssemblerFixup* fixup_;
   ZoneGrowableArray<int>* pointer_offsets_;
 #if defined(DEBUG)
   bool fixups_processed_;
 #endif

   uword cursor() const { return cursor_; }
   uword limit() const { return limit_; }
   intptr_t Capacity() const {
     ASSERT(limit_ >= contents_);
     return (limit_ - contents_) + kMinimumGap;
   }

   // Process the fixup chain.
   void ProcessFixups(const MemoryRegion& region);

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

   void ExtendCapacity();

   friend class AssemblerFixup;
 };

 }  // namespace dart


 #if defined(TARGET_ARCH_IA32)
 #include "vm/assembler_ia32.h"
 #elif defined(TARGET_ARCH_X64)
 #include "vm/assembler_x64.h"
 #elif defined(TARGET_ARCH_ARM)
 #include "vm/assembler_arm.h"
 #elif defined(TARGET_ARCH_MIPS)
 #include "vm/assembler_mips.h"
 #else
 #error Unknown architecture.
 #endif

 #endif  // VM_ASSEMBLER_H_
	// 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.

	#ifndef VM_ASSEMBLER_H_
	#define VM_ASSEMBLER_H_

	#include "platform/assert.h"
	#include "vm/allocation.h"
	#include "vm/globals.h"
	#include "vm/growable_array.h"
	#include "vm/object.h"

	namespace dart {

	// Forward declarations.
	class Assembler;
	class AssemblerFixup;
	class AssemblerBuffer;
	class MemoryRegion;


	// External labels keep a function pointer to allow them
	// to be called from code generated by the assembler.
	class ExternalLabel : public ValueObject {
	public:
	ExternalLabel(const char* name, uword address)
	: name_(name), address_(address) {
	ASSERT(name != NULL);
	}

	const char* name() const { return name_; }
	bool is_resolved() const { return address_ != 0; }
	uword address() const {
	ASSERT(is_resolved());
	return address_;
	}

	private:
	const char* name_;
	const uword address_;
	};


	// Assembler fixups are positions in generated code that hold relocation
	// information that needs to be processed before finalizing the code
	// into executable memory.
	class AssemblerFixup : public ZoneAllocated {
	public:
	virtual void Process(const MemoryRegion& region, int position) = 0;

	// It would be ideal if the destructor method could be made private,
	// but the g++ compiler complains when this is subclassed.
	virtual ~AssemblerFixup() { UNREACHABLE(); }

	private:
	AssemblerFixup* previous_;
	int position_;

	AssemblerFixup* previous() const { return previous_; }
	void set_previous(AssemblerFixup* previous) { previous_ = previous; }

	int position() const { return position_; }
	void set_position(int position) { position_ = position; }

	friend class AssemblerBuffer;
	};


	// Assembler buffers are used to emit binary code. They grow on demand.
	class AssemblerBuffer : public ValueObject {
	public:
	AssemblerBuffer();
	~AssemblerBuffer();

	// Basic support for emitting, loading, and storing.
	template<typename T> void Emit(T value) {
	ASSERT(HasEnsuredCapacity());
	reinterpret_cast<T>(cursor_) = value;
	cursor_ += sizeof(T);
	}

	template<typename T> void Remit() {
	ASSERT(Size() >= static_cast<intptr_t>(sizeof(T)));
	cursor_ -= sizeof(T);
	}

	template<typename T> T Load(int position) {
	ASSERT(position >= 0 && position <= (Size() - static_cast<int>(sizeof(T))));
	return reinterpret_cast<T>(contents_ + position);
	}

	template<typename T> void Store(int position, T value) {
	ASSERT(position >= 0 && position <= (Size() - static_cast<int>(sizeof(T))));
	reinterpret_cast<T>(contents_ + position) = value;
	}

	const ZoneGrowableArray<int>& pointer_offsets() const {
	#if defined(DEBUG)
	ASSERT(fixups_processed_);
	#endif
	return *pointer_offsets_;
	}

	// Emit an object pointer directly in the code.
	void EmitObject(const Object& object);

	// Emit a fixup at the current location.
	void EmitFixup(AssemblerFixup* fixup) {
	fixup->set_previous(fixup_);
	fixup->set_position(Size());
	fixup_ = fixup;
	}

	// Get the size of the emitted code.
	intptr_t Size() const { return cursor_ - contents_; }
	uword contents() const { return contents_; }

	// Copy the assembled instructions into the specified memory block
	// and apply all fixups.
	void FinalizeInstructions(const MemoryRegion& region);

	// 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 ...

	#if defined(DEBUG)
	class EnsureCapacity : public ValueObject {
	public:
	explicit EnsureCapacity(AssemblerBuffer* buffer);
	~EnsureCapacity();

	private:
	AssemblerBuffer* buffer_;
	intptr_t gap_;

	intptr_t ComputeGap() { return buffer_->Capacity() - buffer_->Size(); }
	};

	bool has_ensured_capacity_;
	bool HasEnsuredCapacity() const { return has_ensured_capacity_; }
	#else
	class EnsureCapacity : public ValueObject {
	public:
	explicit EnsureCapacity(AssemblerBuffer* buffer) {
	if (buffer->cursor() >= buffer->limit()) buffer->ExtendCapacity();
	}
	};

	// When building the C++ tests, assertion code is enabled. To allow
	// asserting that the user of the assembler buffer has ensured the
	// capacity needed for emitting, we add a dummy method in non-debug mode.
	bool HasEnsuredCapacity() const { return true; }
	#endif

	// Returns the position in the instruction stream.
	intptr_t GetPosition() const { return cursor_ - contents_; }

	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 const intptr_t kMinimumGap = 32;

	uword contents_;
	uword cursor_;
	uword limit_;
	AssemblerFixup* fixup_;
	ZoneGrowableArray<int>* pointer_offsets_;
	#if defined(DEBUG)
	bool fixups_processed_;
	#endif

	uword cursor() const { return cursor_; }
	uword limit() const { return limit_; }
	intptr_t Capacity() const {
	ASSERT(limit_ >= contents_);
	return (limit_ - contents_) + kMinimumGap;
	}

	// Process the fixup chain.
	void ProcessFixups(const MemoryRegion& region);

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

	void ExtendCapacity();

	friend class AssemblerFixup;
	};

	} // namespace dart


	#if defined(TARGET_ARCH_IA32)
	#include "vm/assembler_ia32.h"
	#elif defined(TARGET_ARCH_X64)
	#include "vm/assembler_x64.h"
	#elif defined(TARGET_ARCH_ARM)
	#include "vm/assembler_arm.h"
	#elif defined(TARGET_ARCH_MIPS)
	#include "vm/assembler_mips.h"
	#else
	#error Unknown architecture.
	#endif

	#endif // VM_ASSEMBLER_H_