third_party/v8/tools/debug_helper/debug-helper.h - cobalt - Git at Google

 // Copyright 2019 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.

 // This file defines the public interface to v8_debug_helper.

 #ifndef V8_TOOLS_DEBUG_HELPER_DEBUG_HELPER_H_
 #define V8_TOOLS_DEBUG_HELPER_DEBUG_HELPER_H_

 #include <cstdint>
 #include <memory>

 #if defined(_WIN32)

 #ifdef BUILDING_V8_DEBUG_HELPER
 #define V8_DEBUG_HELPER_EXPORT __declspec(dllexport)
 #elif USING_V8_DEBUG_HELPER
 #define V8_DEBUG_HELPER_EXPORT __declspec(dllimport)
 #else
 #define V8_DEBUG_HELPER_EXPORT
 #endif

 #else  // defined(_WIN32)

 #ifdef BUILDING_V8_DEBUG_HELPER
 #define V8_DEBUG_HELPER_EXPORT __attribute__((visibility("default")))
 #else
 #define V8_DEBUG_HELPER_EXPORT
 #endif

 #endif  // defined(_WIN32)

 namespace v8 {
 namespace debug_helper {

 // Possible results when attempting to fetch memory from the debuggee.
 enum class MemoryAccessResult {
   kOk,
   kAddressNotValid,
   kAddressValidButInaccessible,  // Possible in incomplete dump.
 };

 // Information about how this tool discovered the type of the object.
 enum class TypeCheckResult {
   // Success cases:
   kSmi,
   kWeakRef,
   kUsedMap,
   kKnownMapPointer,
   kUsedTypeHint,

   // Failure cases:
   kUnableToDecompress,  // Caller must provide the heap range somehow.
   kObjectPointerInvalid,
   kObjectPointerValidButInaccessible,  // Possible in incomplete dump.
   kMapPointerInvalid,
   kMapPointerValidButInaccessible,  // Possible in incomplete dump.
   kUnknownInstanceType,
   kUnknownTypeHint,
 };

 enum class PropertyKind {
   kSingle,
   kArrayOfKnownSize,
   kArrayOfUnknownSizeDueToInvalidMemory,
   kArrayOfUnknownSizeDueToValidButInaccessibleMemory,
 };

 struct PropertyBase {
   const char* name;

   // Statically-determined type, such as from .tq definition. Can be an empty
   // string if this property is itself a Torque-defined struct; in that case use
   // |struct_fields| instead. This type should be treated as if it were used in
   // the v8::internal namespace; that is, type "X::Y" can mean any of the
   // following, in order of decreasing preference:
   // - v8::internal::X::Y
   // - v8::X::Y
   // - X::Y
   const char* type;

   // In some cases, |type| may be a simple type representing a compressed
   // pointer such as v8::internal::TaggedValue. In those cases,
   // |decompressed_type| will contain the type of the object when decompressed.
   // Otherwise, |decompressed_type| will match |type|. In any case, it is safe
   // to pass the |decompressed_type| value as the type_hint on a subsequent call
   // to GetObjectProperties.
   const char* decompressed_type;
 };

 struct StructProperty : public PropertyBase {
   // The offset from the beginning of the struct to this field.
   size_t offset;

   // The number of bits that are present, if this value is a bitfield. Zero
   // indicates that this value is not a bitfield (the full value is stored).
   uint8_t num_bits;

   // The number of bits by which this value has been left-shifted for storage as
   // a bitfield.
   uint8_t shift_bits;
 };

 struct ObjectProperty : public PropertyBase {
   // The address where the property value can be found in the debuggee's address
   // space, or the address of the first value for an array.
   uintptr_t address;

   // If kind indicates an array of unknown size, num_values will be 0 and debug
   // tools should display this property as a raw pointer. Note that there is a
   // semantic difference between num_values=1 and kind=kSingle (normal property)
   // versus num_values=1 and kind=kArrayOfKnownSize (one-element array).
   size_t num_values;

   // The number of bytes occupied by a single instance of the value type for
   // this property. This can also be used as the array stride because arrays are
   // tightly packed like in C.
   size_t size;

   // If the property is a struct made up of several pieces of data packed
   // together, then the |struct_fields| array contains descriptions of those
   // fields.
   size_t num_struct_fields;
   StructProperty** struct_fields;

   PropertyKind kind;
 };

 struct ObjectPropertiesResult {
   TypeCheckResult type_check_result;
   const char* brief;
   const char* type;  // Runtime type of the object.
   size_t num_properties;
   ObjectProperty** properties;

   // If not all relevant memory is available, GetObjectProperties may respond
   // with a technically correct but uninteresting type such as HeapObject, and
   // use other heuristics to make reasonable guesses about what specific type
   // the object actually is. You may request data about the same object again
   // using any of these guesses as the type hint, but the results should be
   // formatted to the user in a way that clearly indicates that they're only
   // guesses.
   size_t num_guessed_types;
   const char** guessed_types;
 };

 struct StackFrameResult {
   size_t num_properties;
   ObjectProperty** properties;
 };

 // Copies byte_count bytes of memory from the given address in the debuggee to
 // the destination buffer.
 typedef MemoryAccessResult (*MemoryAccessor)(uintptr_t address,
                                              void* destination,
                                              size_t byte_count);

 // Additional data that can help GetObjectProperties to be more accurate. Any
 // fields you don't know can be set to zero and this library will do the best it
 // can with the information available.
 struct HeapAddresses {
   // Beginning of allocated space for various kinds of data. These can help us
   // to detect certain common objects that are placed in memory during startup.
   // These values might be provided via name-value pairs in CrashPad dumps.
   // Otherwise, they can be obtained as follows:
   // 1. Get the Isolate pointer for the current thread. It might be somewhere on
   //    the stack, or it might be accessible from thread-local storage with the
   //    key stored in v8::internal::Isolate::isolate_key_.
   // 2. Get isolate->heap_.map_space_->memory_chunk_list_.front_ and similar for
   //    old_space_ and read_only_space_.
   uintptr_t map_space_first_page;
   uintptr_t old_space_first_page;
   uintptr_t read_only_space_first_page;

   // Any valid heap pointer address. On platforms where pointer compression is
   // enabled, this can allow us to get data from compressed pointers even if the
   // other data above is not provided. The Isolate pointer is valid for this
   // purpose if you have it.
   uintptr_t any_heap_pointer;
 };

 // Result type for ListObjectClasses.
 struct ClassList {
   size_t num_class_names;
   const char* const* class_names;  // Fully qualified class names.
 };

 }  // namespace debug_helper
 }  // namespace v8

 extern "C" {
 // Raw library interface. If possible, use functions in v8::debug_helper
 // namespace instead because they use smart pointers to prevent leaks.
 V8_DEBUG_HELPER_EXPORT v8::debug_helper::ObjectPropertiesResult*
 _v8_debug_helper_GetObjectProperties(
     uintptr_t object, v8::debug_helper::MemoryAccessor memory_accessor,
     const v8::debug_helper::HeapAddresses& heap_addresses,
     const char* type_hint);
 V8_DEBUG_HELPER_EXPORT void _v8_debug_helper_Free_ObjectPropertiesResult(
     v8::debug_helper::ObjectPropertiesResult* result);
 V8_DEBUG_HELPER_EXPORT v8::debug_helper::StackFrameResult*
 _v8_debug_helper_GetStackFrame(
     uintptr_t frame_pointer, v8::debug_helper::MemoryAccessor memory_accessor);
 V8_DEBUG_HELPER_EXPORT void _v8_debug_helper_Free_StackFrameResult(
     v8::debug_helper::StackFrameResult* result);
 V8_DEBUG_HELPER_EXPORT const v8::debug_helper::ClassList*
 _v8_debug_helper_ListObjectClasses();
 V8_DEBUG_HELPER_EXPORT const char* _v8_debug_helper_BitsetName(
     uint64_t payload);
 }

 namespace v8 {
 namespace debug_helper {

 struct DebugHelperObjectPropertiesResultDeleter {
   void operator()(v8::debug_helper::ObjectPropertiesResult* ptr) {
     _v8_debug_helper_Free_ObjectPropertiesResult(ptr);
   }
 };
 using ObjectPropertiesResultPtr =
     std::unique_ptr<ObjectPropertiesResult,
                     DebugHelperObjectPropertiesResultDeleter>;

 // Get information about the given object pointer, which could be:
 // - A tagged pointer, strong or weak
 // - A cleared weak pointer
 // - A compressed tagged pointer, zero-extended to 64 bits
 // - A tagged small integer
 // The type hint is only used if the object's Map is missing or corrupt. It
 // should be the fully-qualified name of a class that inherits from
 // v8::internal::Object.
 inline ObjectPropertiesResultPtr GetObjectProperties(
     uintptr_t object, v8::debug_helper::MemoryAccessor memory_accessor,
     const HeapAddresses& heap_addresses, const char* type_hint = nullptr) {
   return ObjectPropertiesResultPtr(_v8_debug_helper_GetObjectProperties(
       object, memory_accessor, heap_addresses, type_hint));
 }

 // Get a list of all class names deriving from v8::internal::Object.
 inline const ClassList* ListObjectClasses() {
   return _v8_debug_helper_ListObjectClasses();
 }

 // Return a bitset name for a v8::internal::compiler::Type with payload or null
 // if the payload is not a bitset.
 inline const char* BitsetName(uint64_t payload) {
   return _v8_debug_helper_BitsetName(payload);
 }

 struct DebugHelperStackFrameResultDeleter {
   void operator()(v8::debug_helper::StackFrameResult* ptr) {
     _v8_debug_helper_Free_StackFrameResult(ptr);
   }
 };
 using StackFrameResultPtr =
     std::unique_ptr<StackFrameResult, DebugHelperStackFrameResultDeleter>;

 inline StackFrameResultPtr GetStackFrame(
     uintptr_t frame_pointer, v8::debug_helper::MemoryAccessor memory_accessor) {
   return StackFrameResultPtr(
       _v8_debug_helper_GetStackFrame(frame_pointer, memory_accessor));
 }

 }  // namespace debug_helper
 }  // namespace v8

 #endif
	// Copyright 2019 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.

	// This file defines the public interface to v8_debug_helper.

	#ifndef V8_TOOLS_DEBUG_HELPER_DEBUG_HELPER_H_
	#define V8_TOOLS_DEBUG_HELPER_DEBUG_HELPER_H_

	#include <cstdint>
	#include <memory>

	#if defined(_WIN32)

	#ifdef BUILDING_V8_DEBUG_HELPER
	#define V8_DEBUG_HELPER_EXPORT __declspec(dllexport)
	#elif USING_V8_DEBUG_HELPER
	#define V8_DEBUG_HELPER_EXPORT __declspec(dllimport)
	#else
	#define V8_DEBUG_HELPER_EXPORT
	#endif

	#else // defined(_WIN32)

	#ifdef BUILDING_V8_DEBUG_HELPER
	#define V8_DEBUG_HELPER_EXPORT __attribute__((visibility("default")))
	#else
	#define V8_DEBUG_HELPER_EXPORT
	#endif

	#endif // defined(_WIN32)

	namespace v8 {
	namespace debug_helper {

	// Possible results when attempting to fetch memory from the debuggee.
	enum class MemoryAccessResult {
	kOk,
	kAddressNotValid,
	kAddressValidButInaccessible, // Possible in incomplete dump.
	};

	// Information about how this tool discovered the type of the object.
	enum class TypeCheckResult {
	// Success cases:
	kSmi,
	kWeakRef,
	kUsedMap,
	kKnownMapPointer,
	kUsedTypeHint,

	// Failure cases:
	kUnableToDecompress, // Caller must provide the heap range somehow.
	kObjectPointerInvalid,
	kObjectPointerValidButInaccessible, // Possible in incomplete dump.
	kMapPointerInvalid,
	kMapPointerValidButInaccessible, // Possible in incomplete dump.
	kUnknownInstanceType,
	kUnknownTypeHint,
	};

	enum class PropertyKind {
	kSingle,
	kArrayOfKnownSize,
	kArrayOfUnknownSizeDueToInvalidMemory,
	kArrayOfUnknownSizeDueToValidButInaccessibleMemory,
	};

	struct PropertyBase {
	const char* name;

	// Statically-determined type, such as from .tq definition. Can be an empty
	// string if this property is itself a Torque-defined struct; in that case use
	// \|struct_fields\| instead. This type should be treated as if it were used in
	// the v8::internal namespace; that is, type "X::Y" can mean any of the
	// following, in order of decreasing preference:
	// - v8::internal::X::Y
	// - v8::X::Y
	// - X::Y
	const char* type;

	// In some cases, \|type\| may be a simple type representing a compressed
	// pointer such as v8::internal::TaggedValue. In those cases,
	// \|decompressed_type\| will contain the type of the object when decompressed.
	// Otherwise, \|decompressed_type\| will match \|type\|. In any case, it is safe
	// to pass the \|decompressed_type\| value as the type_hint on a subsequent call
	// to GetObjectProperties.
	const char* decompressed_type;
	};

	struct StructProperty : public PropertyBase {
	// The offset from the beginning of the struct to this field.
	size_t offset;

	// The number of bits that are present, if this value is a bitfield. Zero
	// indicates that this value is not a bitfield (the full value is stored).
	uint8_t num_bits;

	// The number of bits by which this value has been left-shifted for storage as
	// a bitfield.
	uint8_t shift_bits;
	};

	struct ObjectProperty : public PropertyBase {
	// The address where the property value can be found in the debuggee's address
	// space, or the address of the first value for an array.
	uintptr_t address;

	// If kind indicates an array of unknown size, num_values will be 0 and debug
	// tools should display this property as a raw pointer. Note that there is a
	// semantic difference between num_values=1 and kind=kSingle (normal property)
	// versus num_values=1 and kind=kArrayOfKnownSize (one-element array).
	size_t num_values;

	// The number of bytes occupied by a single instance of the value type for
	// this property. This can also be used as the array stride because arrays are
	// tightly packed like in C.
	size_t size;

	// If the property is a struct made up of several pieces of data packed
	// together, then the \|struct_fields\| array contains descriptions of those
	// fields.
	size_t num_struct_fields;
	StructProperty** struct_fields;

	PropertyKind kind;
	};

	struct ObjectPropertiesResult {
	TypeCheckResult type_check_result;
	const char* brief;
	const char* type; // Runtime type of the object.
	size_t num_properties;
	ObjectProperty** properties;

	// If not all relevant memory is available, GetObjectProperties may respond
	// with a technically correct but uninteresting type such as HeapObject, and
	// use other heuristics to make reasonable guesses about what specific type
	// the object actually is. You may request data about the same object again
	// using any of these guesses as the type hint, but the results should be
	// formatted to the user in a way that clearly indicates that they're only
	// guesses.
	size_t num_guessed_types;
	const char** guessed_types;
	};

	struct StackFrameResult {
	size_t num_properties;
	ObjectProperty** properties;
	};

	// Copies byte_count bytes of memory from the given address in the debuggee to
	// the destination buffer.
	typedef MemoryAccessResult (*MemoryAccessor)(uintptr_t address,
	void* destination,
	size_t byte_count);

	// Additional data that can help GetObjectProperties to be more accurate. Any
	// fields you don't know can be set to zero and this library will do the best it
	// can with the information available.
	struct HeapAddresses {
	// Beginning of allocated space for various kinds of data. These can help us
	// to detect certain common objects that are placed in memory during startup.
	// These values might be provided via name-value pairs in CrashPad dumps.
	// Otherwise, they can be obtained as follows:
	// 1. Get the Isolate pointer for the current thread. It might be somewhere on
	// the stack, or it might be accessible from thread-local storage with the
	// key stored in v8::internal::Isolate::isolate_key_.
	// 2. Get isolate->heap_.map_space_->memory_chunk_list_.front_ and similar for
	// old_space_ and read_only_space_.
	uintptr_t map_space_first_page;
	uintptr_t old_space_first_page;
	uintptr_t read_only_space_first_page;

	// Any valid heap pointer address. On platforms where pointer compression is
	// enabled, this can allow us to get data from compressed pointers even if the
	// other data above is not provided. The Isolate pointer is valid for this
	// purpose if you have it.
	uintptr_t any_heap_pointer;
	};

	// Result type for ListObjectClasses.
	struct ClassList {
	size_t num_class_names;
	const char* const* class_names; // Fully qualified class names.
	};

	} // namespace debug_helper
	} // namespace v8

	extern "C" {
	// Raw library interface. If possible, use functions in v8::debug_helper
	// namespace instead because they use smart pointers to prevent leaks.
	V8_DEBUG_HELPER_EXPORT v8::debug_helper::ObjectPropertiesResult*
	_v8_debug_helper_GetObjectProperties(
	uintptr_t object, v8::debug_helper::MemoryAccessor memory_accessor,
	const v8::debug_helper::HeapAddresses& heap_addresses,
	const char* type_hint);
	V8_DEBUG_HELPER_EXPORT void _v8_debug_helper_Free_ObjectPropertiesResult(
	v8::debug_helper::ObjectPropertiesResult* result);
	V8_DEBUG_HELPER_EXPORT v8::debug_helper::StackFrameResult*
	_v8_debug_helper_GetStackFrame(
	uintptr_t frame_pointer, v8::debug_helper::MemoryAccessor memory_accessor);
	V8_DEBUG_HELPER_EXPORT void _v8_debug_helper_Free_StackFrameResult(
	v8::debug_helper::StackFrameResult* result);
	V8_DEBUG_HELPER_EXPORT const v8::debug_helper::ClassList*
	_v8_debug_helper_ListObjectClasses();
	V8_DEBUG_HELPER_EXPORT const char* _v8_debug_helper_BitsetName(
	uint64_t payload);
	}

	namespace v8 {
	namespace debug_helper {

	struct DebugHelperObjectPropertiesResultDeleter {
	void operator()(v8::debug_helper::ObjectPropertiesResult* ptr) {
	_v8_debug_helper_Free_ObjectPropertiesResult(ptr);
	}
	};
	using ObjectPropertiesResultPtr =
	std::unique_ptr<ObjectPropertiesResult,
	DebugHelperObjectPropertiesResultDeleter>;

	// Get information about the given object pointer, which could be:
	// - A tagged pointer, strong or weak
	// - A cleared weak pointer
	// - A compressed tagged pointer, zero-extended to 64 bits
	// - A tagged small integer
	// The type hint is only used if the object's Map is missing or corrupt. It
	// should be the fully-qualified name of a class that inherits from
	// v8::internal::Object.
	inline ObjectPropertiesResultPtr GetObjectProperties(
	uintptr_t object, v8::debug_helper::MemoryAccessor memory_accessor,
	const HeapAddresses& heap_addresses, const char* type_hint = nullptr) {
	return ObjectPropertiesResultPtr(_v8_debug_helper_GetObjectProperties(
	object, memory_accessor, heap_addresses, type_hint));
	}

	// Get a list of all class names deriving from v8::internal::Object.
	inline const ClassList* ListObjectClasses() {
	return _v8_debug_helper_ListObjectClasses();
	}

	// Return a bitset name for a v8::internal::compiler::Type with payload or null
	// if the payload is not a bitset.
	inline const char* BitsetName(uint64_t payload) {
	return _v8_debug_helper_BitsetName(payload);
	}

	struct DebugHelperStackFrameResultDeleter {
	void operator()(v8::debug_helper::StackFrameResult* ptr) {
	_v8_debug_helper_Free_StackFrameResult(ptr);
	}
	};
	using StackFrameResultPtr =
	std::unique_ptr<StackFrameResult, DebugHelperStackFrameResultDeleter>;

	inline StackFrameResultPtr GetStackFrame(
	uintptr_t frame_pointer, v8::debug_helper::MemoryAccessor memory_accessor) {
	return StackFrameResultPtr(
	_v8_debug_helper_GetStackFrame(frame_pointer, memory_accessor));
	}

	} // namespace debug_helper
	} // namespace v8

	#endif