runtime/vm/code_descriptors.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 RUNTIME_VM_CODE_DESCRIPTORS_H_
 #define RUNTIME_VM_CODE_DESCRIPTORS_H_

 #include "vm/datastream.h"
 #include "vm/globals.h"
 #include "vm/growable_array.h"
 #include "vm/log.h"
 #include "vm/object.h"
 #include "vm/runtime_entry.h"

 namespace dart {

 static const intptr_t kInvalidTryIndex = -1;

 class DescriptorList : public ZoneAllocated {
  public:
   explicit DescriptorList(intptr_t initial_capacity)
       : encoded_data_(initial_capacity),
         prev_pc_offset(0),
         prev_deopt_id(0),
         prev_token_pos(0) {}

   ~DescriptorList() {}

   void AddDescriptor(PcDescriptorsLayout::Kind kind,
                      intptr_t pc_offset,
                      intptr_t deopt_id,
                      TokenPosition token_pos,
                      intptr_t try_index,
                      intptr_t yield_index);

   PcDescriptorsPtr FinalizePcDescriptors(uword entry_point);

  private:
   GrowableArray<uint8_t> encoded_data_;

   intptr_t prev_pc_offset;
   intptr_t prev_deopt_id;
   intptr_t prev_token_pos;

   DISALLOW_COPY_AND_ASSIGN(DescriptorList);
 };

 class CompressedStackMapsBuilder : public ZoneAllocated {
  public:
   CompressedStackMapsBuilder() : encoded_bytes_() {}

   static void EncodeLEB128(GrowableArray<uint8_t>* data, uintptr_t value);

   void AddEntry(intptr_t pc_offset,
                 BitmapBuilder* bitmap,
                 intptr_t spill_slot_bit_count);

   CompressedStackMapsPtr Finalize() const;

  private:
   intptr_t last_pc_offset_ = 0;
   GrowableArray<uint8_t> encoded_bytes_;
   DISALLOW_COPY_AND_ASSIGN(CompressedStackMapsBuilder);
 };

 class CompressedStackMapsIterator : public ValueObject {
  public:
   // We use the null value to represent CompressedStackMaps with no
   // entries, so any CompressedStackMaps arguments to constructors can be null.
   CompressedStackMapsIterator(const CompressedStackMaps& maps,
                               const CompressedStackMaps& global_table);
   explicit CompressedStackMapsIterator(const CompressedStackMaps& maps);

   explicit CompressedStackMapsIterator(const CompressedStackMapsIterator& it);

   // Loads the next entry from [maps_], if any. If [maps_] is the null
   // value, this always returns false.
   bool MoveNext();

   // Finds the entry with the given PC offset starting at the current
   // position of the iterator. If [maps_] is the null value, this always
   // returns false.
   bool Find(uint32_t pc_offset) {
     // We should never have an entry with a PC offset of 0 inside an
     // non-empty CSM, so fail.
     if (pc_offset == 0) return false;
     do {
       if (current_pc_offset_ >= pc_offset) break;
     } while (MoveNext());
     return current_pc_offset_ == pc_offset;
   }

   // Methods for accessing parts of an entry should not be called until
   // a successful MoveNext() or Find() call has been made.

   uint32_t pc_offset() const {
     ASSERT(HasLoadedEntry());
     return current_pc_offset_;
   }
   // We lazily load and cache information from the global table if the
   // CSM uses it, so these methods cannot be const.
   intptr_t Length();
   intptr_t SpillSlotBitCount();
   bool IsObject(intptr_t bit_offset);

   void EnsureFullyLoadedEntry() {
     ASSERT(HasLoadedEntry());
     if (current_spill_slot_bit_count_ < 0) {
       LazyLoadGlobalTableEntry();
     }
     ASSERT(current_spill_slot_bit_count_ >= 0);
   }

   const char* ToCString(Zone* zone) const;
   const char* ToCString() const;

  private:
   static uintptr_t DecodeLEB128(const CompressedStackMaps& data,
                                 uintptr_t* byte_index);
   bool HasLoadedEntry() const { return next_offset_ > 0; }
   void LazyLoadGlobalTableEntry();

   const CompressedStackMaps& maps_;
   const CompressedStackMaps& bits_container_;

   uintptr_t next_offset_ = 0;
   uint32_t current_pc_offset_ = 0;
   // Only used when looking up non-PC information in the global table.
   uintptr_t current_global_table_offset_ = 0;
   intptr_t current_spill_slot_bit_count_ = -1;
   intptr_t current_non_spill_slot_bit_count_ = -1;
   intptr_t current_bits_offset_ = -1;

   friend class StackMapEntry;
 };

 class ExceptionHandlerList : public ZoneAllocated {
  public:
   struct HandlerDesc {
     intptr_t outer_try_index;    // Try block in which this try block is nested.
     intptr_t pc_offset;          // Handler PC offset value.
     bool is_generated;           // False if this is directly from Dart code.
     const Array* handler_types;  // Catch clause guards.
     bool needs_stacktrace;
   };

   ExceptionHandlerList() : list_() {}

   intptr_t Length() const { return list_.length(); }

   void AddPlaceHolder() {
     struct HandlerDesc data;
     data.outer_try_index = -1;
     data.pc_offset = ExceptionHandlers::kInvalidPcOffset;
     data.is_generated = true;
     data.handler_types = NULL;
     data.needs_stacktrace = false;
     list_.Add(data);
   }

   void AddHandler(intptr_t try_index,
                   intptr_t outer_try_index,
                   intptr_t pc_offset,
                   bool is_generated,
                   const Array& handler_types,
                   bool needs_stacktrace) {
     ASSERT(try_index >= 0);
     while (Length() <= try_index) {
       AddPlaceHolder();
     }
     list_[try_index].outer_try_index = outer_try_index;
     ASSERT(list_[try_index].pc_offset == ExceptionHandlers::kInvalidPcOffset);
     list_[try_index].pc_offset = pc_offset;
     list_[try_index].is_generated = is_generated;
     ASSERT(handler_types.IsZoneHandle());
     list_[try_index].handler_types = &handler_types;
     list_[try_index].needs_stacktrace |= needs_stacktrace;
   }

   // Called by rethrows, to mark their enclosing handlers.
   void SetNeedsStackTrace(intptr_t try_index) {
     // Rethrows can be generated outside a try by the compiler.
     if (try_index == kInvalidTryIndex) {
       return;
     }
     ASSERT(try_index >= 0);
     while (Length() <= try_index) {
       AddPlaceHolder();
     }
     list_[try_index].needs_stacktrace = true;
   }

   static bool ContainsCatchAllType(const Array& array) {
     auto& type = AbstractType::Handle();
     for (intptr_t i = 0; i < array.Length(); i++) {
       type ^= array.At(i);
       if (type.IsCatchAllType()) {
         return true;
       }
     }
     return false;
   }

   ExceptionHandlersPtr FinalizeExceptionHandlers(uword entry_point) const;

  private:
   GrowableArray<struct HandlerDesc> list_;
   DISALLOW_COPY_AND_ASSIGN(ExceptionHandlerList);
 };

 #if !defined(DART_PRECOMPILED_RUNTIME)
 // Used to construct CatchEntryMoves for the AOT mode of compilation.
 class CatchEntryMovesMapBuilder : public ZoneAllocated {
  public:
   CatchEntryMovesMapBuilder();

   void NewMapping(intptr_t pc_offset);
   void Append(const CatchEntryMove& move);
   void EndMapping();
   TypedDataPtr FinalizeCatchEntryMovesMap();

  private:
   class TrieNode;

   Zone* zone_;
   TrieNode* root_;
   intptr_t current_pc_offset_;
   GrowableArray<CatchEntryMove> moves_;
   ZoneWriteStream stream_;

   DISALLOW_COPY_AND_ASSIGN(CatchEntryMovesMapBuilder);
 };
 #endif  // !defined(DART_PRECOMPILED_RUNTIME)

 // A CodeSourceMap maps from pc offsets to a stack of inlined functions and
 // their positions. This is encoded as a little bytecode that pushes and pops
 // functions and changes the top function's position as the PC advances.
 // Decoding happens by running this bytecode until we reach the desired PC.
 //
 // The implementation keeps track of two sets of state: one written to the byte
 // stream and one that is buffered. On the JIT, this buffering effectively gives
 // us a peephole optimization that merges adjacent advance PC bytecodes. On AOT,
 // this allows to skip encoding our position until we reach a PC where we might
 // throw.
 class CodeSourceMapBuilder : public ZoneAllocated {
  public:
   CodeSourceMapBuilder(
       Zone* zone,
       bool stack_traces_only,
       const GrowableArray<intptr_t>& caller_inline_id,
       const GrowableArray<TokenPosition>& inline_id_to_token_pos,
       const GrowableArray<const Function*>& inline_id_to_function);

   // The position at which a function implicitly starts, for both the root and
   // after a push bytecode. We use the classifying position kDartCodePrologue
   // since it is the most common.
   static const TokenPosition kInitialPosition;

   static const uint8_t kChangePosition = 0;
   static const uint8_t kAdvancePC = 1;
   static const uint8_t kPushFunction = 2;
   static const uint8_t kPopFunction = 3;
   static const uint8_t kNullCheck = 4;

   void StartInliningInterval(int32_t pc_offset, intptr_t inline_id);
   void BeginCodeSourceRange(int32_t pc_offset);
   void EndCodeSourceRange(int32_t pc_offset, TokenPosition pos);
   void NoteDescriptor(PcDescriptorsLayout::Kind kind,
                       int32_t pc_offset,
                       TokenPosition pos);
   void NoteNullCheck(int32_t pc_offset, TokenPosition pos, intptr_t name_index);

   ArrayPtr InliningIdToFunction();
   CodeSourceMapPtr Finalize();

  private:
   intptr_t GetFunctionId(intptr_t inline_id);

   void BufferChangePosition(TokenPosition pos) {
     buffered_token_pos_stack_.Last() = pos;
   }
   void WriteChangePosition(TokenPosition pos);
   void BufferAdvancePC(int32_t distance) { buffered_pc_offset_ += distance; }
   void WriteAdvancePC(int32_t distance) {
     stream_.Write<uint8_t>(kAdvancePC);
     stream_.Write<int32_t>(distance);
     written_pc_offset_ += distance;
   }
   void BufferPush(intptr_t inline_id) {
     buffered_inline_id_stack_.Add(inline_id);
     buffered_token_pos_stack_.Add(kInitialPosition);
   }
   void WritePush(intptr_t inline_id) {
     stream_.Write<uint8_t>(kPushFunction);
     stream_.Write<int32_t>(GetFunctionId(inline_id));
     written_inline_id_stack_.Add(inline_id);
     written_token_pos_stack_.Add(kInitialPosition);
   }
   void BufferPop() {
     buffered_inline_id_stack_.RemoveLast();
     buffered_token_pos_stack_.RemoveLast();
   }
   void WritePop() {
     stream_.Write<uint8_t>(kPopFunction);
     written_inline_id_stack_.RemoveLast();
     written_token_pos_stack_.RemoveLast();
   }
   void WriteNullCheck(int32_t name_index) {
     stream_.Write<uint8_t>(kNullCheck);
     stream_.Write<int32_t>(name_index);
   }

   void FlushBuffer();
   void FlushBufferStack();
   void FlushBufferPosition();
   void FlushBufferPC();

   bool IsOnBufferedStack(intptr_t inline_id) {
     for (intptr_t i = 0; i < buffered_inline_id_stack_.length(); i++) {
       if (buffered_inline_id_stack_[i] == inline_id) return true;
     }
     return false;
   }

   intptr_t buffered_pc_offset_;
   GrowableArray<intptr_t> buffered_inline_id_stack_;
   GrowableArray<TokenPosition> buffered_token_pos_stack_;

   intptr_t written_pc_offset_;
   GrowableArray<intptr_t> written_inline_id_stack_;
   GrowableArray<TokenPosition> written_token_pos_stack_;

   const GrowableArray<intptr_t>& caller_inline_id_;
   const GrowableArray<TokenPosition>& inline_id_to_token_pos_;
   const GrowableArray<const Function*>& inline_id_to_function_;

   const GrowableObjectArray& inlined_functions_;

   ZoneWriteStream stream_;

   const bool stack_traces_only_;

   DISALLOW_COPY_AND_ASSIGN(CodeSourceMapBuilder);
 };

 class CodeSourceMapReader : public ValueObject {
  public:
   CodeSourceMapReader(const CodeSourceMap& map,
                       const Array& functions,
                       const Function& root)
       : map_(map), functions_(functions), root_(root) {}

   void GetInlinedFunctionsAt(int32_t pc_offset,
                              GrowableArray<const Function*>* function_stack,
                              GrowableArray<TokenPosition>* token_positions);
   NOT_IN_PRODUCT(void PrintJSONInlineIntervals(JSONObject* jsobj));
   void DumpInlineIntervals(uword start);
   void DumpSourcePositions(uword start);

   intptr_t GetNullCheckNameIndexAt(int32_t pc_offset);

  private:
   // Reads a TokenPosition value from a CSM, handling the different encoding for
   // when non-symbolic stack traces are enabled.
   static TokenPosition ReadPosition(ReadStream* stream);

   const CodeSourceMap& map_;
   const Array& functions_;
   const Function& root_;

   DISALLOW_COPY_AND_ASSIGN(CodeSourceMapReader);
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_CODE_DESCRIPTORS_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 RUNTIME_VM_CODE_DESCRIPTORS_H_
	#define RUNTIME_VM_CODE_DESCRIPTORS_H_

	#include "vm/datastream.h"
	#include "vm/globals.h"
	#include "vm/growable_array.h"
	#include "vm/log.h"
	#include "vm/object.h"
	#include "vm/runtime_entry.h"

	namespace dart {

	static const intptr_t kInvalidTryIndex = -1;

	class DescriptorList : public ZoneAllocated {
	public:
	explicit DescriptorList(intptr_t initial_capacity)
	: encoded_data_(initial_capacity),
	prev_pc_offset(0),
	prev_deopt_id(0),
	prev_token_pos(0) {}

	~DescriptorList() {}

	void AddDescriptor(PcDescriptorsLayout::Kind kind,
	intptr_t pc_offset,
	intptr_t deopt_id,
	TokenPosition token_pos,
	intptr_t try_index,
	intptr_t yield_index);

	PcDescriptorsPtr FinalizePcDescriptors(uword entry_point);

	private:
	GrowableArray<uint8_t> encoded_data_;

	intptr_t prev_pc_offset;
	intptr_t prev_deopt_id;
	intptr_t prev_token_pos;

	DISALLOW_COPY_AND_ASSIGN(DescriptorList);
	};

	class CompressedStackMapsBuilder : public ZoneAllocated {
	public:
	CompressedStackMapsBuilder() : encoded_bytes_() {}

	static void EncodeLEB128(GrowableArray<uint8_t>* data, uintptr_t value);

	void AddEntry(intptr_t pc_offset,
	BitmapBuilder* bitmap,
	intptr_t spill_slot_bit_count);

	CompressedStackMapsPtr Finalize() const;

	private:
	intptr_t last_pc_offset_ = 0;
	GrowableArray<uint8_t> encoded_bytes_;
	DISALLOW_COPY_AND_ASSIGN(CompressedStackMapsBuilder);
	};

	class CompressedStackMapsIterator : public ValueObject {
	public:
	// We use the null value to represent CompressedStackMaps with no
	// entries, so any CompressedStackMaps arguments to constructors can be null.
	CompressedStackMapsIterator(const CompressedStackMaps& maps,
	const CompressedStackMaps& global_table);
	explicit CompressedStackMapsIterator(const CompressedStackMaps& maps);

	explicit CompressedStackMapsIterator(const CompressedStackMapsIterator& it);

	// Loads the next entry from [maps_], if any. If [maps_] is the null
	// value, this always returns false.
	bool MoveNext();

	// Finds the entry with the given PC offset starting at the current
	// position of the iterator. If [maps_] is the null value, this always
	// returns false.
	bool Find(uint32_t pc_offset) {
	// We should never have an entry with a PC offset of 0 inside an
	// non-empty CSM, so fail.
	if (pc_offset == 0) return false;
	do {
	if (current_pc_offset_ >= pc_offset) break;
	} while (MoveNext());
	return current_pc_offset_ == pc_offset;
	}

	// Methods for accessing parts of an entry should not be called until
	// a successful MoveNext() or Find() call has been made.

	uint32_t pc_offset() const {
	ASSERT(HasLoadedEntry());
	return current_pc_offset_;
	}
	// We lazily load and cache information from the global table if the
	// CSM uses it, so these methods cannot be const.
	intptr_t Length();
	intptr_t SpillSlotBitCount();
	bool IsObject(intptr_t bit_offset);

	void EnsureFullyLoadedEntry() {
	ASSERT(HasLoadedEntry());
	if (current_spill_slot_bit_count_ < 0) {
	LazyLoadGlobalTableEntry();
	}
	ASSERT(current_spill_slot_bit_count_ >= 0);
	}

	const char* ToCString(Zone* zone) const;
	const char* ToCString() const;

	private:
	static uintptr_t DecodeLEB128(const CompressedStackMaps& data,
	uintptr_t* byte_index);
	bool HasLoadedEntry() const { return next_offset_ > 0; }
	void LazyLoadGlobalTableEntry();

	const CompressedStackMaps& maps_;
	const CompressedStackMaps& bits_container_;

	uintptr_t next_offset_ = 0;
	uint32_t current_pc_offset_ = 0;
	// Only used when looking up non-PC information in the global table.
	uintptr_t current_global_table_offset_ = 0;
	intptr_t current_spill_slot_bit_count_ = -1;
	intptr_t current_non_spill_slot_bit_count_ = -1;
	intptr_t current_bits_offset_ = -1;

	friend class StackMapEntry;
	};

	class ExceptionHandlerList : public ZoneAllocated {
	public:
	struct HandlerDesc {
	intptr_t outer_try_index; // Try block in which this try block is nested.
	intptr_t pc_offset; // Handler PC offset value.
	bool is_generated; // False if this is directly from Dart code.
	const Array* handler_types; // Catch clause guards.
	bool needs_stacktrace;
	};

	ExceptionHandlerList() : list_() {}

	intptr_t Length() const { return list_.length(); }

	void AddPlaceHolder() {
	struct HandlerDesc data;
	data.outer_try_index = -1;
	data.pc_offset = ExceptionHandlers::kInvalidPcOffset;
	data.is_generated = true;
	data.handler_types = NULL;
	data.needs_stacktrace = false;
	list_.Add(data);
	}

	void AddHandler(intptr_t try_index,
	intptr_t outer_try_index,
	intptr_t pc_offset,
	bool is_generated,
	const Array& handler_types,
	bool needs_stacktrace) {
	ASSERT(try_index >= 0);
	while (Length() <= try_index) {
	AddPlaceHolder();
	}
	list_[try_index].outer_try_index = outer_try_index;
	ASSERT(list_[try_index].pc_offset == ExceptionHandlers::kInvalidPcOffset);
	list_[try_index].pc_offset = pc_offset;
	list_[try_index].is_generated = is_generated;
	ASSERT(handler_types.IsZoneHandle());
	list_[try_index].handler_types = &handler_types;
	list_[try_index].needs_stacktrace \|= needs_stacktrace;
	}

	// Called by rethrows, to mark their enclosing handlers.
	void SetNeedsStackTrace(intptr_t try_index) {
	// Rethrows can be generated outside a try by the compiler.
	if (try_index == kInvalidTryIndex) {
	return;
	}
	ASSERT(try_index >= 0);
	while (Length() <= try_index) {
	AddPlaceHolder();
	}
	list_[try_index].needs_stacktrace = true;
	}

	static bool ContainsCatchAllType(const Array& array) {
	auto& type = AbstractType::Handle();
	for (intptr_t i = 0; i < array.Length(); i++) {
	type ^= array.At(i);
	if (type.IsCatchAllType()) {
	return true;
	}
	}
	return false;
	}

	ExceptionHandlersPtr FinalizeExceptionHandlers(uword entry_point) const;

	private:
	GrowableArray<struct HandlerDesc> list_;
	DISALLOW_COPY_AND_ASSIGN(ExceptionHandlerList);
	};

	#if !defined(DART_PRECOMPILED_RUNTIME)
	// Used to construct CatchEntryMoves for the AOT mode of compilation.
	class CatchEntryMovesMapBuilder : public ZoneAllocated {
	public:
	CatchEntryMovesMapBuilder();

	void NewMapping(intptr_t pc_offset);
	void Append(const CatchEntryMove& move);
	void EndMapping();
	TypedDataPtr FinalizeCatchEntryMovesMap();

	private:
	class TrieNode;

	Zone* zone_;
	TrieNode* root_;
	intptr_t current_pc_offset_;
	GrowableArray<CatchEntryMove> moves_;
	ZoneWriteStream stream_;

	DISALLOW_COPY_AND_ASSIGN(CatchEntryMovesMapBuilder);
	};
	#endif // !defined(DART_PRECOMPILED_RUNTIME)

	// A CodeSourceMap maps from pc offsets to a stack of inlined functions and
	// their positions. This is encoded as a little bytecode that pushes and pops
	// functions and changes the top function's position as the PC advances.
	// Decoding happens by running this bytecode until we reach the desired PC.
	//
	// The implementation keeps track of two sets of state: one written to the byte
	// stream and one that is buffered. On the JIT, this buffering effectively gives
	// us a peephole optimization that merges adjacent advance PC bytecodes. On AOT,
	// this allows to skip encoding our position until we reach a PC where we might
	// throw.
	class CodeSourceMapBuilder : public ZoneAllocated {
	public:
	CodeSourceMapBuilder(
	Zone* zone,
	bool stack_traces_only,
	const GrowableArray<intptr_t>& caller_inline_id,
	const GrowableArray<TokenPosition>& inline_id_to_token_pos,
	const GrowableArray<const Function*>& inline_id_to_function);

	// The position at which a function implicitly starts, for both the root and
	// after a push bytecode. We use the classifying position kDartCodePrologue
	// since it is the most common.
	static const TokenPosition kInitialPosition;

	static const uint8_t kChangePosition = 0;
	static const uint8_t kAdvancePC = 1;
	static const uint8_t kPushFunction = 2;
	static const uint8_t kPopFunction = 3;
	static const uint8_t kNullCheck = 4;

	void StartInliningInterval(int32_t pc_offset, intptr_t inline_id);
	void BeginCodeSourceRange(int32_t pc_offset);
	void EndCodeSourceRange(int32_t pc_offset, TokenPosition pos);
	void NoteDescriptor(PcDescriptorsLayout::Kind kind,
	int32_t pc_offset,
	TokenPosition pos);
	void NoteNullCheck(int32_t pc_offset, TokenPosition pos, intptr_t name_index);

	ArrayPtr InliningIdToFunction();
	CodeSourceMapPtr Finalize();

	private:
	intptr_t GetFunctionId(intptr_t inline_id);

	void BufferChangePosition(TokenPosition pos) {
	buffered_token_pos_stack_.Last() = pos;
	}
	void WriteChangePosition(TokenPosition pos);
	void BufferAdvancePC(int32_t distance) { buffered_pc_offset_ += distance; }
	void WriteAdvancePC(int32_t distance) {
	stream_.Write<uint8_t>(kAdvancePC);
	stream_.Write<int32_t>(distance);
	written_pc_offset_ += distance;
	}
	void BufferPush(intptr_t inline_id) {
	buffered_inline_id_stack_.Add(inline_id);
	buffered_token_pos_stack_.Add(kInitialPosition);
	}
	void WritePush(intptr_t inline_id) {
	stream_.Write<uint8_t>(kPushFunction);
	stream_.Write<int32_t>(GetFunctionId(inline_id));
	written_inline_id_stack_.Add(inline_id);
	written_token_pos_stack_.Add(kInitialPosition);
	}
	void BufferPop() {
	buffered_inline_id_stack_.RemoveLast();
	buffered_token_pos_stack_.RemoveLast();
	}
	void WritePop() {
	stream_.Write<uint8_t>(kPopFunction);
	written_inline_id_stack_.RemoveLast();
	written_token_pos_stack_.RemoveLast();
	}
	void WriteNullCheck(int32_t name_index) {
	stream_.Write<uint8_t>(kNullCheck);
	stream_.Write<int32_t>(name_index);
	}

	void FlushBuffer();
	void FlushBufferStack();
	void FlushBufferPosition();
	void FlushBufferPC();

	bool IsOnBufferedStack(intptr_t inline_id) {
	for (intptr_t i = 0; i < buffered_inline_id_stack_.length(); i++) {
	if (buffered_inline_id_stack_[i] == inline_id) return true;
	}
	return false;
	}

	intptr_t buffered_pc_offset_;
	GrowableArray<intptr_t> buffered_inline_id_stack_;
	GrowableArray<TokenPosition> buffered_token_pos_stack_;

	intptr_t written_pc_offset_;
	GrowableArray<intptr_t> written_inline_id_stack_;
	GrowableArray<TokenPosition> written_token_pos_stack_;

	const GrowableArray<intptr_t>& caller_inline_id_;
	const GrowableArray<TokenPosition>& inline_id_to_token_pos_;
	const GrowableArray<const Function*>& inline_id_to_function_;

	const GrowableObjectArray& inlined_functions_;

	ZoneWriteStream stream_;

	const bool stack_traces_only_;

	DISALLOW_COPY_AND_ASSIGN(CodeSourceMapBuilder);
	};

	class CodeSourceMapReader : public ValueObject {
	public:
	CodeSourceMapReader(const CodeSourceMap& map,
	const Array& functions,
	const Function& root)
	: map_(map), functions_(functions), root_(root) {}

	void GetInlinedFunctionsAt(int32_t pc_offset,
	GrowableArray<const Function> function_stack,
	GrowableArray<TokenPosition>* token_positions);
	NOT_IN_PRODUCT(void PrintJSONInlineIntervals(JSONObject* jsobj));
	void DumpInlineIntervals(uword start);
	void DumpSourcePositions(uword start);

	intptr_t GetNullCheckNameIndexAt(int32_t pc_offset);

	private:
	// Reads a TokenPosition value from a CSM, handling the different encoding for
	// when non-symbolic stack traces are enabled.
	static TokenPosition ReadPosition(ReadStream* stream);

	const CodeSourceMap& map_;
	const Array& functions_;
	const Function& root_;

	DISALLOW_COPY_AND_ASSIGN(CodeSourceMapReader);
	};

	} // namespace dart

	#endif // RUNTIME_VM_CODE_DESCRIPTORS_H_