// Copyright 2012 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_TRANSITIONS_H_
#define V8_TRANSITIONS_H_
#include "src/checks.h"
#include "src/elements-kind.h"
#include "src/objects.h"
#include "src/objects/descriptor-array.h"
#include "src/objects/map.h"
#include "src/objects/name.h"
namespace v8 {
namespace internal {
// TransitionsAccessor is a helper class to encapsulate access to the various
// ways a Map can store transitions to other maps in its respective field at
// Map::kTransitionsOrPrototypeInfo.
// It caches state information internally, which becomes stale when a Map's
// transitions storage changes or when a GC cycle clears dead transitions;
// so while a TransitionsAccessor instance can be used for several read-only
// operations in a row (provided no GC happens between them), it must be
// discarded and recreated after "Insert" and "UpdateHandler" operations.
//
// Internal details: a Map's field either holds a WeakCell to a transition
// target, or a StoreIC handler for a transitioning store (which in turn points
// to its target map), or a TransitionArray for several target maps and/or
// handlers as well as prototype and ElementsKind transitions.
// Property details (and in case of inline target storage, the key) are
// retrieved from the target map's descriptor array.
// Stored transitions are weak in the GC sense: both single transitions stored
// inline and TransitionArray fields are cleared when the map they refer to
// is not otherwise reachable.
class TransitionsAccessor {
public:
TransitionsAccessor(Map* map, DisallowHeapAllocation* no_gc) : map_(map) {
Initialize();
USE(no_gc);
}
explicit TransitionsAccessor(Handle<Map> map) : map_handle_(map), map_(*map) {
Initialize();
}
// Insert a new transition into |map|'s transition array, extending it
// as necessary.
// Requires the constructor that takes a Handle<Map> to have been used.
// This TransitionsAccessor instance is unusable after this operation.
void Insert(Handle<Name> name, Handle<Map> target, SimpleTransitionFlag flag);
Map* SearchTransition(Name* name, PropertyKind kind,
PropertyAttributes attributes);
// This TransitionsAccessor instance is unusable after this operation.
void UpdateHandler(Name* name, Object* handler);
// If a valid handler is found, returns the transition target in
// |out_transition|.
Object* SearchHandler(Name* name, Handle<Map>* out_transition);
Map* SearchSpecial(Symbol* name);
// Returns true for non-property transitions like elements kind, or
// or frozen/sealed transitions.
static bool IsSpecialTransition(Name* name);
Handle<Map> FindTransitionToField(Handle<Name> name);
Handle<String> ExpectedTransitionKey();
Handle<Map> ExpectedTransitionTarget();
int NumberOfTransitions();
// The size of transition arrays are limited so they do not end up in large
// object space. Otherwise ClearNonLiveReferences would leak memory while
// applying in-place right trimming.
static const int kMaxNumberOfTransitions = 1024 + 512;
bool CanHaveMoreTransitions();
inline Name* GetKey(int transition_number);
inline Map* GetTarget(int transition_number);
static inline PropertyDetails GetTargetDetails(Name* name, Map* target);
static bool IsMatchingMap(WeakCell* target_cell, Name* name,
PropertyKind kind, PropertyAttributes attributes);
// ===== ITERATION =====
typedef void (*TraverseCallback)(Map* map, void* data);
// Traverse the transition tree in postorder.
void TraverseTransitionTree(TraverseCallback callback, void* data) {
// Make sure that we do not allocate in the callback.
DisallowHeapAllocation no_allocation;
TraverseTransitionTreeInternal(callback, data, &no_allocation);
}
// ===== PROTOTYPE TRANSITIONS =====
// When you set the prototype of an object using the __proto__ accessor you
// need a new map for the object (the prototype is stored in the map). In
// order not to multiply maps unnecessarily we store these as transitions in
// the original map. That way we can transition to the same map if the same
// prototype is set, rather than creating a new map every time. The
// transitions are in the form of a map where the keys are prototype objects
// and the values are the maps they transition to.
void PutPrototypeTransition(Handle<Object> prototype, Handle<Map> target_map);
Handle<Map> GetPrototypeTransition(Handle<Object> prototype);
#if DEBUG || OBJECT_PRINT
void PrintTransitions(std::ostream& os);
static void PrintOneTransition(std::ostream& os, Name* key, Map* target,
Object* raw_target);
void PrintTransitionTree();
void PrintTransitionTree(std::ostream& os, int level,
DisallowHeapAllocation* no_gc);
#endif
#if DEBUG
void CheckNewTransitionsAreConsistent(TransitionArray* old_transitions,
Object* transitions);
bool IsConsistentWithBackPointers();
bool IsSortedNoDuplicates();
#endif
protected:
// Allow tests to use inheritance to access internals.
enum Encoding {
kPrototypeInfo,
kUninitialized,
kWeakCell,
kTuple3Handler,
kFixedArrayHandler,
kFullTransitionArray,
};
void Reload() {
DCHECK(!map_handle_.is_null());
map_ = *map_handle_;
Initialize();
}
inline Encoding encoding() {
DCHECK(!needs_reload_);
return encoding_;
}
private:
friend class MarkCompactCollector; // For HasSimpleTransitionTo.
friend class TransitionArray;
static inline PropertyDetails GetSimpleTargetDetails(Map* transition) {
return transition->GetLastDescriptorDetails();
}
static inline Name* GetSimpleTransitionKey(Map* transition) {
int descriptor = transition->LastAdded();
return transition->instance_descriptors()->GetKey(descriptor);
}
static inline Map* GetTargetFromRaw(Object* raw);
void MarkNeedsReload() {
#if DEBUG
needs_reload_ = true;
#endif
}
void Initialize();
inline Map* GetSimpleTransition();
bool HasSimpleTransitionTo(WeakCell* cell);
void ReplaceTransitions(Object* new_transitions);
template <Encoding enc>
inline WeakCell* GetTargetCell();
void EnsureHasFullTransitionArray();
void SetPrototypeTransitions(Handle<FixedArray> proto_transitions);
FixedArray* GetPrototypeTransitions();
void TraverseTransitionTreeInternal(TraverseCallback callback, void* data,
DisallowHeapAllocation* no_gc);
inline TransitionArray* transitions();
Handle<Map> map_handle_;
Map* map_;
Object* raw_transitions_;
Encoding encoding_;
WeakCell* target_cell_;
#if DEBUG
bool needs_reload_;
#endif
DISALLOW_IMPLICIT_CONSTRUCTORS(TransitionsAccessor);
};
// TransitionArrays are fixed arrays used to hold map transitions for property,
// constant, and element changes.
// The TransitionArray class exposes a very low-level interface. Most clients
// should use TransitionsAccessors.
// TransitionArrays have the following format:
// [0] Link to next TransitionArray (for weak handling support)
// [1] Smi(0) or fixed array of prototype transitions
// [2] Number of transitions (can be zero after trimming)
// [3] First transition key
// [4] First transition target
// ...
// [3 + number of transitions * kTransitionSize]: start of slack
class TransitionArray : public FixedArray {
public:
inline static TransitionArray* cast(Object* object);
inline FixedArray* GetPrototypeTransitions();
inline Object** GetPrototypeTransitionsSlot();
inline bool HasPrototypeTransitions();
// Accessors for fetching instance transition at transition number.
inline void SetKey(int transition_number, Name* value);
inline Name* GetKey(int transition_number);
inline Object** GetKeySlot(int transition_number);
inline Map* GetTarget(int transition_number);
inline void SetTarget(int transition_number, Object* target);
inline Object* GetRawTarget(int transition_number);
inline Object** GetTargetSlot(int transition_number);
// Required for templatized Search interface.
static const int kNotFound = -1;
Name* GetSortedKey(int transition_number) {
return GetKey(transition_number);
}
int GetSortedKeyIndex(int transition_number) { return transition_number; }
inline int number_of_entries() { return number_of_transitions(); }
#ifdef DEBUG
bool IsSortedNoDuplicates(int valid_entries = -1);
#endif
void Sort();
#if defined(DEBUG) || defined(OBJECT_PRINT)
// For our gdb macros.
void Print();
void Print(std::ostream& os);
#endif
#ifdef OBJECT_PRINT
void TransitionArrayPrint(std::ostream& os); // NOLINT
#endif
#ifdef VERIFY_HEAP
void TransitionArrayVerify();
#endif
private:
friend class MarkCompactCollector;
friend class TransitionsAccessor;
static const int kTransitionSize = 2;
inline void SetNumberOfTransitions(int number_of_transitions);
inline int Capacity();
// ===== PROTOTYPE TRANSITIONS =====
// Cache format:
// 0: finger - index of the first free cell in the cache
// 1 + i: target map
static const int kProtoTransitionHeaderSize = 1;
static const int kMaxCachedPrototypeTransitions = 256;
inline void SetPrototypeTransitions(FixedArray* prototype_transitions);
static int NumberOfPrototypeTransitions(FixedArray* proto_transitions) {
if (proto_transitions->length() == 0) return 0;
Object* raw = proto_transitions->get(kProtoTransitionNumberOfEntriesOffset);
return Smi::ToInt(raw);
}
static void SetNumberOfPrototypeTransitions(FixedArray* proto_transitions,
int value);
// Layout for full transition arrays.
static const int kPrototypeTransitionsIndex = 0;
static const int kTransitionLengthIndex = 1;
static const int kFirstIndex = 2;
// Layout of map transition entries in full transition arrays.
static const int kTransitionKey = 0;
static const int kTransitionTarget = 1;
STATIC_ASSERT(kTransitionSize == 2);
static const int kProtoTransitionNumberOfEntriesOffset = 0;
STATIC_ASSERT(kProtoTransitionHeaderSize == 1);
// Conversion from transition number to array indices.
static int ToKeyIndex(int transition_number) {
return kFirstIndex +
(transition_number * kTransitionSize) +
kTransitionKey;
}
static int ToTargetIndex(int transition_number) {
return kFirstIndex +
(transition_number * kTransitionSize) +
kTransitionTarget;
}
// Returns the fixed array length required to hold number_of_transitions
// transitions.
static int LengthFor(int number_of_transitions) {
return ToKeyIndex(number_of_transitions);
}
// Allocates a TransitionArray.
static Handle<TransitionArray> Allocate(Isolate* isolate,
int number_of_transitions,
int slack = 0);
// Search a transition for a given kind, property name and attributes.
int Search(PropertyKind kind, Name* name, PropertyAttributes attributes,
int* out_insertion_index = NULL);
// Search a non-property transition (like elements kind, observe or frozen
// transitions).
inline int SearchSpecial(Symbol* symbol, int* out_insertion_index = NULL) {
return SearchName(symbol, out_insertion_index);
}
// Search a first transition for a given property name.
inline int SearchName(Name* name, int* out_insertion_index = NULL);
int SearchDetails(int transition, PropertyKind kind,
PropertyAttributes attributes, int* out_insertion_index);
int number_of_transitions() {
if (length() < kFirstIndex) return 0;
return Smi::ToInt(get(kTransitionLengthIndex));
}
static bool CompactPrototypeTransitionArray(FixedArray* array);
static Handle<FixedArray> GrowPrototypeTransitionArray(
Handle<FixedArray> array, int new_capacity, Isolate* isolate);
// Compares two tuples <key, kind, attributes>, returns -1 if
// tuple1 is "less" than tuple2, 0 if tuple1 equal to tuple2 and 1 otherwise.
static inline int CompareKeys(Name* key1, uint32_t hash1, PropertyKind kind1,
PropertyAttributes attributes1, Name* key2,
uint32_t hash2, PropertyKind kind2,
PropertyAttributes attributes2);
// Compares keys, returns -1 if key1 is "less" than key2,
// 0 if key1 equal to key2 and 1 otherwise.
static inline int CompareNames(Name* key1, uint32_t hash1, Name* key2,
uint32_t hash2);
// Compares two details, returns -1 if details1 is "less" than details2,
// 0 if details1 equal to details2 and 1 otherwise.
static inline int CompareDetails(PropertyKind kind1,
PropertyAttributes attributes1,
PropertyKind kind2,
PropertyAttributes attributes2);
inline void Set(int transition_number, Name* key, Object* target);
void Zap();
DISALLOW_IMPLICIT_CONSTRUCTORS(TransitionArray);
};
} // namespace internal
} // namespace v8
#endif // V8_TRANSITIONS_H_