src/interpreter/bytecode-pipeline.h - v8/v8 - Git at Google

 // Copyright 2015 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_INTERPRETER_BYTECODE_PIPELINE_H_
 #define V8_INTERPRETER_BYTECODE_PIPELINE_H_

 #include "src/interpreter/bytecode-register-allocator.h"
 #include "src/interpreter/bytecode-register.h"
 #include "src/interpreter/bytecodes.h"
 #include "src/objects.h"
 #include "src/zone-containers.h"

 namespace v8 {
 namespace internal {
 namespace interpreter {

 class BytecodeLabel;
 class BytecodeNode;
 class BytecodeSourceInfo;

 // Interface for bytecode pipeline stages.
 class BytecodePipelineStage {
  public:
   virtual ~BytecodePipelineStage() {}

   // Write bytecode node |node| into pipeline. The node is only valid
   // for the duration of the call. Callee's should clone it if
   // deferring Write() to the next stage.
   virtual void Write(BytecodeNode* node) = 0;

   // Write jump bytecode node |node| which jumps to |label| into pipeline.
   // The node and label are only valid for the duration of the call. This call
   // implicitly ends the current basic block so should always write to the next
   // stage.
   virtual void WriteJump(BytecodeNode* node, BytecodeLabel* label) = 0;

   // Binds |label| to the current bytecode location. This call implicitly
   // ends the current basic block and so any deferred bytecodes should be
   // written to the next stage.
   virtual void BindLabel(BytecodeLabel* label) = 0;

   // Binds |label| to the location of |target|. This call implicitly
   // ends the current basic block and so any deferred bytecodes should be
   // written to the next stage.
   virtual void BindLabel(const BytecodeLabel& target, BytecodeLabel* label) = 0;

   // Flush the pipeline and generate a bytecode array.
   virtual Handle<BytecodeArray> ToBytecodeArray(
       int fixed_register_count, int parameter_count,
       Handle<FixedArray> handler_table) = 0;
 };

 // Source code position information.
 class BytecodeSourceInfo final {
  public:
   static const int kUninitializedPosition = -1;

   BytecodeSourceInfo()
       : position_type_(PositionType::kNone),
         source_position_(kUninitializedPosition) {}

   BytecodeSourceInfo(int source_position, bool is_statement)
       : position_type_(is_statement ? PositionType::kStatement
                                     : PositionType::kExpression),
         source_position_(source_position) {
     DCHECK_GE(source_position, 0);
   }

   // Makes instance into a statement position.
   void MakeStatementPosition(int source_position) {
     // Statement positions can be replaced by other statement
     // positions. For example , "for (x = 0; x < 3; ++x) 7;" has a
     // statement position associated with 7 but no bytecode associated
     // with it. Then Next is emitted after the body and has
     // statement position and overrides the existing one.
     position_type_ = PositionType::kStatement;
     source_position_ = source_position;
   }

   // Makes instance into an expression position. Instance should not
   // be a statement position otherwise it could be lost and impair the
   // debugging experience.
   void MakeExpressionPosition(int source_position) {
     DCHECK(!is_statement());
     position_type_ = PositionType::kExpression;
     source_position_ = source_position;
   }

   // Forces an instance into an expression position.
   void ForceExpressionPosition(int source_position) {
     position_type_ = PositionType::kExpression;
     source_position_ = source_position;
   }

   // Clones a source position. The current instance is expected to be
   // invalid.
   void Clone(const BytecodeSourceInfo& other) {
     DCHECK(!is_valid());
     position_type_ = other.position_type_;
     source_position_ = other.source_position_;
   }

   int source_position() const {
     DCHECK(is_valid());
     return source_position_;
   }

   bool is_statement() const {
     return position_type_ == PositionType::kStatement;
   }
   bool is_expression() const {
     return position_type_ == PositionType::kExpression;
   }

   bool is_valid() const { return position_type_ != PositionType::kNone; }
   void set_invalid() {
     position_type_ = PositionType::kNone;
     source_position_ = kUninitializedPosition;
   }

   bool operator==(const BytecodeSourceInfo& other) const {
     return position_type_ == other.position_type_ &&
            source_position_ == other.source_position_;
   }

   bool operator!=(const BytecodeSourceInfo& other) const {
     return position_type_ != other.position_type_ ||
            source_position_ != other.source_position_;
   }

  private:
   enum class PositionType : uint8_t { kNone, kExpression, kStatement };

   PositionType position_type_;
   int source_position_;

   DISALLOW_COPY_AND_ASSIGN(BytecodeSourceInfo);
 };

 // A container for a generated bytecode, it's operands, and source information.
 // These must be allocated by a BytecodeNodeAllocator instance.
 class BytecodeNode final : ZoneObject {
  public:
   explicit BytecodeNode(Bytecode bytecode = Bytecode::kIllegal);
   BytecodeNode(Bytecode bytecode, uint32_t operand0);
   BytecodeNode(Bytecode bytecode, uint32_t operand0, uint32_t operand1);
   BytecodeNode(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
                uint32_t operand2);
   BytecodeNode(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
                uint32_t operand2, uint32_t operand3);

   BytecodeNode(const BytecodeNode& other);
   BytecodeNode& operator=(const BytecodeNode& other);

   void set_bytecode(Bytecode bytecode) {
     DCHECK_EQ(Bytecodes::NumberOfOperands(bytecode), 0);
     bytecode_ = bytecode;
   }
   void set_bytecode(Bytecode bytecode, uint32_t operand0) {
     DCHECK_EQ(Bytecodes::NumberOfOperands(bytecode), 1);
     bytecode_ = bytecode;
     operands_[0] = operand0;
   }
   void set_bytecode(Bytecode bytecode, uint32_t operand0, uint32_t operand1) {
     DCHECK_EQ(Bytecodes::NumberOfOperands(bytecode), 2);
     bytecode_ = bytecode;
     operands_[0] = operand0;
     operands_[1] = operand1;
   }

   // Clone |other|.
   void Clone(const BytecodeNode* const other);

   // Print to stream |os|.
   void Print(std::ostream& os) const;

   // Transform to a node representing |new_bytecode| which has one
   // operand more than the current bytecode.
   void Transform(Bytecode new_bytecode, uint32_t extra_operand);

   Bytecode bytecode() const { return bytecode_; }

   uint32_t operand(int i) const {
     DCHECK_LT(i, operand_count());
     return operands_[i];
   }
   uint32_t* operands() { return operands_; }
   const uint32_t* operands() const { return operands_; }

   int operand_count() const { return Bytecodes::NumberOfOperands(bytecode_); }

   const BytecodeSourceInfo& source_info() const { return source_info_; }
   BytecodeSourceInfo& source_info() { return source_info_; }

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

  private:
   static const int kInvalidPosition = kMinInt;

   Bytecode bytecode_;
   uint32_t operands_[Bytecodes::kMaxOperands];
   BytecodeSourceInfo source_info_;
 };

 std::ostream& operator<<(std::ostream& os, const BytecodeSourceInfo& info);
 std::ostream& operator<<(std::ostream& os, const BytecodeNode& node);

 }  // namespace interpreter
 }  // namespace internal
 }  // namespace v8

 #endif  // V8_INTERPRETER_BYTECODE_PIPELINE_H_
	// Copyright 2015 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_INTERPRETER_BYTECODE_PIPELINE_H_
	#define V8_INTERPRETER_BYTECODE_PIPELINE_H_

	#include "src/interpreter/bytecode-register-allocator.h"
	#include "src/interpreter/bytecode-register.h"
	#include "src/interpreter/bytecodes.h"
	#include "src/objects.h"
	#include "src/zone-containers.h"

	namespace v8 {
	namespace internal {
	namespace interpreter {

	class BytecodeLabel;
	class BytecodeNode;
	class BytecodeSourceInfo;

	// Interface for bytecode pipeline stages.
	class BytecodePipelineStage {
	public:
	virtual ~BytecodePipelineStage() {}

	// Write bytecode node \|node\| into pipeline. The node is only valid
	// for the duration of the call. Callee's should clone it if
	// deferring Write() to the next stage.
	virtual void Write(BytecodeNode* node) = 0;

	// Write jump bytecode node \|node\| which jumps to \|label\| into pipeline.
	// The node and label are only valid for the duration of the call. This call
	// implicitly ends the current basic block so should always write to the next
	// stage.
	virtual void WriteJump(BytecodeNode* node, BytecodeLabel* label) = 0;

	// Binds \|label\| to the current bytecode location. This call implicitly
	// ends the current basic block and so any deferred bytecodes should be
	// written to the next stage.
	virtual void BindLabel(BytecodeLabel* label) = 0;

	// Binds \|label\| to the location of \|target\|. This call implicitly
	// ends the current basic block and so any deferred bytecodes should be
	// written to the next stage.
	virtual void BindLabel(const BytecodeLabel& target, BytecodeLabel* label) = 0;

	// Flush the pipeline and generate a bytecode array.
	virtual Handle<BytecodeArray> ToBytecodeArray(
	int fixed_register_count, int parameter_count,
	Handle<FixedArray> handler_table) = 0;
	};

	// Source code position information.
	class BytecodeSourceInfo final {
	public:
	static const int kUninitializedPosition = -1;

	BytecodeSourceInfo()
	: position_type_(PositionType::kNone),
	source_position_(kUninitializedPosition) {}

	BytecodeSourceInfo(int source_position, bool is_statement)
	: position_type_(is_statement ? PositionType::kStatement
	: PositionType::kExpression),
	source_position_(source_position) {
	DCHECK_GE(source_position, 0);
	}

	// Makes instance into a statement position.
	void MakeStatementPosition(int source_position) {
	// Statement positions can be replaced by other statement
	// positions. For example , "for (x = 0; x < 3; ++x) 7;" has a
	// statement position associated with 7 but no bytecode associated
	// with it. Then Next is emitted after the body and has
	// statement position and overrides the existing one.
	position_type_ = PositionType::kStatement;
	source_position_ = source_position;
	}

	// Makes instance into an expression position. Instance should not
	// be a statement position otherwise it could be lost and impair the
	// debugging experience.
	void MakeExpressionPosition(int source_position) {
	DCHECK(!is_statement());
	position_type_ = PositionType::kExpression;
	source_position_ = source_position;
	}

	// Forces an instance into an expression position.
	void ForceExpressionPosition(int source_position) {
	position_type_ = PositionType::kExpression;
	source_position_ = source_position;
	}

	// Clones a source position. The current instance is expected to be
	// invalid.
	void Clone(const BytecodeSourceInfo& other) {
	DCHECK(!is_valid());
	position_type_ = other.position_type_;
	source_position_ = other.source_position_;
	}

	int source_position() const {
	DCHECK(is_valid());
	return source_position_;
	}

	bool is_statement() const {
	return position_type_ == PositionType::kStatement;
	}
	bool is_expression() const {
	return position_type_ == PositionType::kExpression;
	}

	bool is_valid() const { return position_type_ != PositionType::kNone; }
	void set_invalid() {
	position_type_ = PositionType::kNone;
	source_position_ = kUninitializedPosition;
	}

	bool operator==(const BytecodeSourceInfo& other) const {
	return position_type_ == other.position_type_ &&
	source_position_ == other.source_position_;
	}

	bool operator!=(const BytecodeSourceInfo& other) const {
	return position_type_ != other.position_type_ \|\|
	source_position_ != other.source_position_;
	}

	private:
	enum class PositionType : uint8_t { kNone, kExpression, kStatement };

	PositionType position_type_;
	int source_position_;

	DISALLOW_COPY_AND_ASSIGN(BytecodeSourceInfo);
	};

	// A container for a generated bytecode, it's operands, and source information.
	// These must be allocated by a BytecodeNodeAllocator instance.
	class BytecodeNode final : ZoneObject {
	public:
	explicit BytecodeNode(Bytecode bytecode = Bytecode::kIllegal);
	BytecodeNode(Bytecode bytecode, uint32_t operand0);
	BytecodeNode(Bytecode bytecode, uint32_t operand0, uint32_t operand1);
	BytecodeNode(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
	uint32_t operand2);
	BytecodeNode(Bytecode bytecode, uint32_t operand0, uint32_t operand1,
	uint32_t operand2, uint32_t operand3);

	BytecodeNode(const BytecodeNode& other);
	BytecodeNode& operator=(const BytecodeNode& other);

	void set_bytecode(Bytecode bytecode) {
	DCHECK_EQ(Bytecodes::NumberOfOperands(bytecode), 0);
	bytecode_ = bytecode;
	}
	void set_bytecode(Bytecode bytecode, uint32_t operand0) {
	DCHECK_EQ(Bytecodes::NumberOfOperands(bytecode), 1);
	bytecode_ = bytecode;
	operands_[0] = operand0;
	}
	void set_bytecode(Bytecode bytecode, uint32_t operand0, uint32_t operand1) {
	DCHECK_EQ(Bytecodes::NumberOfOperands(bytecode), 2);
	bytecode_ = bytecode;
	operands_[0] = operand0;
	operands_[1] = operand1;
	}

	// Clone \|other\|.
	void Clone(const BytecodeNode* const other);

	// Print to stream \|os\|.
	void Print(std::ostream& os) const;

	// Transform to a node representing \|new_bytecode\| which has one
	// operand more than the current bytecode.
	void Transform(Bytecode new_bytecode, uint32_t extra_operand);

	Bytecode bytecode() const { return bytecode_; }

	uint32_t operand(int i) const {
	DCHECK_LT(i, operand_count());
	return operands_[i];
	}
	uint32_t* operands() { return operands_; }
	const uint32_t* operands() const { return operands_; }

	int operand_count() const { return Bytecodes::NumberOfOperands(bytecode_); }

	const BytecodeSourceInfo& source_info() const { return source_info_; }
	BytecodeSourceInfo& source_info() { return source_info_; }

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

	private:
	static const int kInvalidPosition = kMinInt;

	Bytecode bytecode_;
	uint32_t operands_[Bytecodes::kMaxOperands];
	BytecodeSourceInfo source_info_;
	};

	std::ostream& operator<<(std::ostream& os, const BytecodeSourceInfo& info);
	std::ostream& operator<<(std::ostream& os, const BytecodeNode& node);

	} // namespace interpreter
	} // namespace internal
	} // namespace v8

	#endif // V8_INTERPRETER_BYTECODE_PIPELINE_H_