src/handler-table.h - v8/v8.git - Git at Google

 // Copyright 2018 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_HANDLER_TABLE_H_
 #define V8_HANDLER_TABLE_H_

 #include "src/assert-scope.h"
 #include "src/globals.h"
 #include "src/utils.h"

 namespace v8 {
 namespace internal {

 class Assembler;
 class ByteArray;
 class BytecodeArray;

 // HandlerTable is a byte array containing entries for exception handlers in
 // the code object it is associated with. The tables come in two flavors:
 // 1) Based on ranges: Used for unoptimized code. Stored in a {ByteArray} that
 //    is attached to each {BytecodeArray}. Contains one entry per exception
 //    handler and a range representing the try-block covered by that handler.
 //    Layout looks as follows:
 //      [ range-start , range-end , handler-offset , handler-data ]
 // 2) Based on return addresses: Used for turbofanned code. Stored directly in
 //    the instruction stream of the {Code} object. Contains one entry per
 //    call-site that could throw an exception. Layout looks as follows:
 //      [ return-address-offset , handler-offset ]
 class V8_EXPORT_PRIVATE HandlerTable {
  public:
   // Conservative prediction whether a given handler will locally catch an
   // exception or cause a re-throw to outside the code boundary. Since this is
   // undecidable it is merely an approximation (e.g. useful for debugger).
   enum CatchPrediction {
     UNCAUGHT,     // The handler will (likely) rethrow the exception.
     CAUGHT,       // The exception will be caught by the handler.
     PROMISE,      // The exception will be caught and cause a promise rejection.
     DESUGARING,   // The exception will be caught, but both the exception and
                   // the catching are part of a desugaring and should therefore
                   // not be visible to the user (we won't notify the debugger of
                   // such exceptions).
     ASYNC_AWAIT,  // The exception will be caught and cause a promise rejection
                   // in the desugaring of an async function, so special
                   // async/await handling in the debugger can take place.
   };

   // Constructors for the various encodings.
   explicit HandlerTable(Code* code);
   explicit HandlerTable(ByteArray* byte_array);
   explicit HandlerTable(BytecodeArray* bytecode_array);
   explicit HandlerTable(Address instruction_start, size_t handler_table_offset);

   // Getters for handler table based on ranges.
   int GetRangeStart(int index) const;
   int GetRangeEnd(int index) const;
   int GetRangeHandler(int index) const;
   int GetRangeData(int index) const;

   // Setters for handler table based on ranges.
   void SetRangeStart(int index, int value);
   void SetRangeEnd(int index, int value);
   void SetRangeHandler(int index, int offset, CatchPrediction pred);
   void SetRangeData(int index, int value);

   // Returns the required length of the underlying byte array.
   static int LengthForRange(int entries);

   // Emitters for handler table based on return addresses.
   static int EmitReturnTableStart(Assembler* masm, int entries);
   static void EmitReturnEntry(Assembler* masm, int offset, int handler);

   // Lookup handler in a table based on ranges. The {pc_offset} is an offset to
   // the start of the potentially throwing instruction (using return addresses
   // for this value would be invalid).
   int LookupRange(int pc_offset, int* data, CatchPrediction* prediction);

   // Lookup handler in a table based on return addresses.
   int LookupReturn(int pc_offset);

   // Returns the number of entries in the table.
   int NumberOfRangeEntries() const;
   int NumberOfReturnEntries() const;

 #ifdef ENABLE_DISASSEMBLER
   void HandlerTableRangePrint(std::ostream& os);   // NOLINT
   void HandlerTableReturnPrint(std::ostream& os);  // NOLINT
 #endif

  private:
   enum EncodingMode { kRangeBasedEncoding, kReturnAddressBasedEncoding };

   // Getters for handler table based on ranges.
   CatchPrediction GetRangePrediction(int index) const;

   // Getters for handler table based on return addresses.
   int GetReturnOffset(int index) const;
   int GetReturnHandler(int index) const;

   // Number of entries in the loaded handler table.
   int number_of_entries_;

 #ifdef DEBUG
   // The encoding mode of the table. Mostly useful for debugging to check that
   // used accessors and constructors fit together.
   EncodingMode mode_;
 #endif

   // Direct pointer into the encoded data. This pointer points into object on
   // the GC heap (either {ByteArray} or {Code}) and hence would become stale
   // during a collection. Hence we disallow any allocation.
   Address raw_encoded_data_;
   DisallowHeapAllocation no_gc_;

   // Layout description for handler table based on ranges.
   static const int kRangeStartIndex = 0;
   static const int kRangeEndIndex = 1;
   static const int kRangeHandlerIndex = 2;
   static const int kRangeDataIndex = 3;
   static const int kRangeEntrySize = 4;

   // Layout description for handler table based on return addresses.
   static const int kReturnOffsetIndex = 0;
   static const int kReturnHandlerIndex = 1;
   static const int kReturnEntrySize = 2;

   // Encoding of the {handler} field.
   class HandlerPredictionField : public BitField<CatchPrediction, 0, 3> {};
   class HandlerOffsetField : public BitField<int, 3, 29> {};
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_HANDLER_TABLE_H_
	// Copyright 2018 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_HANDLER_TABLE_H_
	#define V8_HANDLER_TABLE_H_

	#include "src/assert-scope.h"
	#include "src/globals.h"
	#include "src/utils.h"

	namespace v8 {
	namespace internal {

	class Assembler;
	class ByteArray;
	class BytecodeArray;

	// HandlerTable is a byte array containing entries for exception handlers in
	// the code object it is associated with. The tables come in two flavors:
	// 1) Based on ranges: Used for unoptimized code. Stored in a {ByteArray} that
	// is attached to each {BytecodeArray}. Contains one entry per exception
	// handler and a range representing the try-block covered by that handler.
	// Layout looks as follows:
	// [ range-start , range-end , handler-offset , handler-data ]
	// 2) Based on return addresses: Used for turbofanned code. Stored directly in
	// the instruction stream of the {Code} object. Contains one entry per
	// call-site that could throw an exception. Layout looks as follows:
	// [ return-address-offset , handler-offset ]
	class V8_EXPORT_PRIVATE HandlerTable {
	public:
	// Conservative prediction whether a given handler will locally catch an
	// exception or cause a re-throw to outside the code boundary. Since this is
	// undecidable it is merely an approximation (e.g. useful for debugger).
	enum CatchPrediction {
	UNCAUGHT, // The handler will (likely) rethrow the exception.
	CAUGHT, // The exception will be caught by the handler.
	PROMISE, // The exception will be caught and cause a promise rejection.
	DESUGARING, // The exception will be caught, but both the exception and
	// the catching are part of a desugaring and should therefore
	// not be visible to the user (we won't notify the debugger of
	// such exceptions).
	ASYNC_AWAIT, // The exception will be caught and cause a promise rejection
	// in the desugaring of an async function, so special
	// async/await handling in the debugger can take place.
	};

	// Constructors for the various encodings.
	explicit HandlerTable(Code* code);
	explicit HandlerTable(ByteArray* byte_array);
	explicit HandlerTable(BytecodeArray* bytecode_array);
	explicit HandlerTable(Address instruction_start, size_t handler_table_offset);

	// Getters for handler table based on ranges.
	int GetRangeStart(int index) const;
	int GetRangeEnd(int index) const;
	int GetRangeHandler(int index) const;
	int GetRangeData(int index) const;

	// Setters for handler table based on ranges.
	void SetRangeStart(int index, int value);
	void SetRangeEnd(int index, int value);
	void SetRangeHandler(int index, int offset, CatchPrediction pred);
	void SetRangeData(int index, int value);

	// Returns the required length of the underlying byte array.
	static int LengthForRange(int entries);

	// Emitters for handler table based on return addresses.
	static int EmitReturnTableStart(Assembler* masm, int entries);
	static void EmitReturnEntry(Assembler* masm, int offset, int handler);

	// Lookup handler in a table based on ranges. The {pc_offset} is an offset to
	// the start of the potentially throwing instruction (using return addresses
	// for this value would be invalid).
	int LookupRange(int pc_offset, int* data, CatchPrediction* prediction);

	// Lookup handler in a table based on return addresses.
	int LookupReturn(int pc_offset);

	// Returns the number of entries in the table.
	int NumberOfRangeEntries() const;
	int NumberOfReturnEntries() const;

	#ifdef ENABLE_DISASSEMBLER
	void HandlerTableRangePrint(std::ostream& os); // NOLINT
	void HandlerTableReturnPrint(std::ostream& os); // NOLINT
	#endif

	private:
	enum EncodingMode { kRangeBasedEncoding, kReturnAddressBasedEncoding };

	// Getters for handler table based on ranges.
	CatchPrediction GetRangePrediction(int index) const;

	// Getters for handler table based on return addresses.
	int GetReturnOffset(int index) const;
	int GetReturnHandler(int index) const;

	// Number of entries in the loaded handler table.
	int number_of_entries_;

	#ifdef DEBUG
	// The encoding mode of the table. Mostly useful for debugging to check that
	// used accessors and constructors fit together.
	EncodingMode mode_;
	#endif

	// Direct pointer into the encoded data. This pointer points into object on
	// the GC heap (either {ByteArray} or {Code}) and hence would become stale
	// during a collection. Hence we disallow any allocation.
	Address raw_encoded_data_;
	DisallowHeapAllocation no_gc_;

	// Layout description for handler table based on ranges.
	static const int kRangeStartIndex = 0;
	static const int kRangeEndIndex = 1;
	static const int kRangeHandlerIndex = 2;
	static const int kRangeDataIndex = 3;
	static const int kRangeEntrySize = 4;

	// Layout description for handler table based on return addresses.
	static const int kReturnOffsetIndex = 0;
	static const int kReturnHandlerIndex = 1;
	static const int kReturnEntrySize = 2;

	// Encoding of the {handler} field.
	class HandlerPredictionField : public BitField<CatchPrediction, 0, 3> {};
	class HandlerOffsetField : public BitField<int, 3, 29> {};
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_HANDLER_TABLE_H_