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// 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 VM_RAW_OBJECT_H_
#define VM_RAW_OBJECT_H_
#include "platform/assert.h"
#include "vm/atomic.h"
#include "vm/globals.h"
#include "vm/snapshot.h"
#include "vm/token.h"
#include "vm/verified_memory.h"
namespace dart {
// Macrobatics to define the Object hierarchy of VM implementation classes.
#define CLASS_LIST_NO_OBJECT_NOR_STRING_NOR_ARRAY(V) \
V(Class) \
V(UnresolvedClass) \
V(TypeArguments) \
V(PatchClass) \
V(Function) \
V(ClosureData) \
V(RedirectionData) \
V(Field) \
V(LiteralToken) \
V(TokenStream) \
V(Script) \
V(Library) \
V(Namespace) \
V(Code) \
V(Instructions) \
V(ObjectPool) \
V(PcDescriptors) \
V(Stackmap) \
V(LocalVarDescriptors) \
V(ExceptionHandlers) \
V(Context) \
V(ContextScope) \
V(ICData) \
V(MegamorphicCache) \
V(SubtypeTestCache) \
V(Error) \
V(ApiError) \
V(LanguageError) \
V(UnhandledException) \
V(UnwindError) \
V(Instance) \
V(LibraryPrefix) \
V(AbstractType) \
V(Type) \
V(TypeRef) \
V(TypeParameter) \
V(BoundedType) \
V(MixinAppType) \
V(Number) \
V(Integer) \
V(Smi) \
V(Mint) \
V(Bigint) \
V(Double) \
V(Bool) \
V(GrowableObjectArray) \
V(Float32x4) \
V(Int32x4) \
V(Float64x2) \
V(TypedData) \
V(ExternalTypedData) \
V(Capability) \
V(ReceivePort) \
V(SendPort) \
V(Stacktrace) \
V(JSRegExp) \
V(WeakProperty) \
V(MirrorReference) \
V(LinkedHashMap) \
V(UserTag) \
#define CLASS_LIST_ARRAYS(V) \
V(Array) \
V(ImmutableArray) \
#define CLASS_LIST_STRINGS(V) \
V(String) \
V(OneByteString) \
V(TwoByteString) \
V(ExternalOneByteString) \
V(ExternalTwoByteString)
#define CLASS_LIST_TYPED_DATA(V) \
V(Int8Array) \
V(Uint8Array) \
V(Uint8ClampedArray) \
V(Int16Array) \
V(Uint16Array) \
V(Int32Array) \
V(Uint32Array) \
V(Int64Array) \
V(Uint64Array) \
V(Float32Array) \
V(Float64Array) \
V(Float32x4Array) \
V(Int32x4Array) \
V(Float64x2Array) \
#define CLASS_LIST_FOR_HANDLES(V) \
CLASS_LIST_NO_OBJECT_NOR_STRING_NOR_ARRAY(V) \
V(Array) \
V(String)
#define CLASS_LIST_NO_OBJECT(V) \
CLASS_LIST_NO_OBJECT_NOR_STRING_NOR_ARRAY(V) \
CLASS_LIST_ARRAYS(V) \
CLASS_LIST_STRINGS(V)
#define CLASS_LIST(V) \
V(Object) \
CLASS_LIST_NO_OBJECT(V)
// Forward declarations.
class Isolate;
#define DEFINE_FORWARD_DECLARATION(clazz) \
class Raw##clazz;
CLASS_LIST(DEFINE_FORWARD_DECLARATION)
#undef DEFINE_FORWARD_DECLARATION
enum ClassId {
// Illegal class id.
kIllegalCid = 0,
// List of Ids for predefined classes.
#define DEFINE_OBJECT_KIND(clazz) \
k##clazz##Cid,
CLASS_LIST(DEFINE_OBJECT_KIND)
#undef DEFINE_OBJECT_KIND
#define DEFINE_OBJECT_KIND(clazz) \
kTypedData##clazz##Cid,
CLASS_LIST_TYPED_DATA(DEFINE_OBJECT_KIND)
#undef DEFINE_OBJECT_KIND
#define DEFINE_OBJECT_KIND(clazz) \
kTypedData##clazz##ViewCid,
CLASS_LIST_TYPED_DATA(DEFINE_OBJECT_KIND)
kByteDataViewCid,
#undef DEFINE_OBJECT_KIND
#define DEFINE_OBJECT_KIND(clazz) \
kExternalTypedData##clazz##Cid,
CLASS_LIST_TYPED_DATA(DEFINE_OBJECT_KIND)
#undef DEFINE_OBJECT_KIND
kByteBufferCid,
// The following entries do not describe a predefined class, but instead
// are class indexes for pre-allocated instance (Null, dynamic and Void).
kNullCid,
kDynamicCid,
kVoidCid,
// The following entry does not describe a real class, but instead it is an
// id which is used to identify free list elements in the heap.
kFreeListElement,
kNumPredefinedCids,
};
enum ObjectAlignment {
// Alignment offsets are used to determine object age.
kNewObjectAlignmentOffset = kWordSize,
kOldObjectAlignmentOffset = 0,
// Object sizes are aligned to kObjectAlignment.
kObjectAlignment = 2 * kWordSize,
kObjectAlignmentLog2 = kWordSizeLog2 + 1,
kObjectAlignmentMask = kObjectAlignment - 1,
};
enum {
kSmiTag = 0,
kHeapObjectTag = 1,
kSmiTagSize = 1,
kSmiTagMask = 1,
kSmiTagShift = 1,
};
enum TypedDataElementType {
#define V(name) k##name##Element,
CLASS_LIST_TYPED_DATA(V)
#undef V
};
#define SNAPSHOT_WRITER_SUPPORT() \
void WriteTo( \
SnapshotWriter* writer, intptr_t object_id, \
Snapshot::Kind kind, bool as_reference); \
friend class SnapshotWriter; \
#define VISITOR_SUPPORT(object) \
static intptr_t Visit##object##Pointers(Raw##object* raw_obj, \
ObjectPointerVisitor* visitor);
#define HEAP_PROFILER_SUPPORT() \
friend class HeapProfiler; \
#define RAW_OBJECT_IMPLEMENTATION(object) \
private: /* NOLINT */ \
VISITOR_SUPPORT(object) \
friend class object; \
friend class RawObject; \
friend class Heap; \
DISALLOW_ALLOCATION(); \
DISALLOW_IMPLICIT_CONSTRUCTORS(Raw##object)
// TODO(koda): Make ptr() return const*, like Object::raw_ptr().
#define RAW_HEAP_OBJECT_IMPLEMENTATION(object) \
private: \
RAW_OBJECT_IMPLEMENTATION(object); \
Raw##object* ptr() const { \
ASSERT(IsHeapObject()); \
return reinterpret_cast<Raw##object*>( \
reinterpret_cast<uword>(this) - kHeapObjectTag); \
} \
SNAPSHOT_WRITER_SUPPORT() \
HEAP_PROFILER_SUPPORT() \
// RawObject is the base class of all raw objects, even though it carries the
// class_ field not all raw objects are allocated in the heap and thus cannot
// be dereferenced (e.g. RawSmi).
class RawObject {
public:
// The tags field which is a part of the object header uses the following
// bit fields for storing tags.
enum TagBits {
kWatchedBit = 0,
kMarkBit = 1,
kCanonicalBit = 2,
kVMHeapObjectBit = 3,
kRememberedBit = 4,
#if defined(ARCH_IS_32_BIT)
kReservedTagPos = 5, // kReservedBit{100K,1M,10M}
kReservedTagSize = 3,
kSizeTagPos = kReservedTagPos + kReservedTagSize, // = 8
kSizeTagSize = 8,
kClassIdTagPos = kSizeTagPos + kSizeTagSize, // = 16
kClassIdTagSize = 16,
#elif defined(ARCH_IS_64_BIT)
kReservedTagPos = 5, // kReservedBit{100K,1M,10M}
kReservedTagSize = 11,
kSizeTagPos = kReservedTagPos + kReservedTagSize, // = 16
kSizeTagSize = 16,
kClassIdTagPos = kSizeTagPos + kSizeTagSize, // = 32
kClassIdTagSize = 32,
#else
#error Unexpected architecture word size
#endif
};
COMPILE_ASSERT(kClassIdTagSize == (sizeof(classid_t) * kBitsPerByte));
// Encodes the object size in the tag in units of object alignment.
class SizeTag {
public:
static const intptr_t kMaxSizeTag =
((1 << RawObject::kSizeTagSize) - 1) << kObjectAlignmentLog2;
static uword encode(intptr_t size) {
return SizeBits::encode(SizeToTagValue(size));
}
static intptr_t decode(uword tag) {
return TagValueToSize(SizeBits::decode(tag));
}
static uword update(intptr_t size, uword tag) {
return SizeBits::update(SizeToTagValue(size), tag);
}
private:
// The actual unscaled bit field used within the tag field.
class SizeBits : public BitField<intptr_t, kSizeTagPos, kSizeTagSize> {};
static intptr_t SizeToTagValue(intptr_t size) {
ASSERT(Utils::IsAligned(size, kObjectAlignment));
return (size > kMaxSizeTag) ? 0 : (size >> kObjectAlignmentLog2);
}
static intptr_t TagValueToSize(intptr_t value) {
return value << kObjectAlignmentLog2;
}
};
class ClassIdTag :
public BitField<intptr_t, kClassIdTagPos, kClassIdTagSize> {}; // NOLINT
bool IsWellFormed() const {
uword value = reinterpret_cast<uword>(this);
return (value & kSmiTagMask) == 0 ||
Utils::IsAligned(value - kHeapObjectTag, kWordSize);
}
bool IsHeapObject() const {
ASSERT(IsWellFormed());
uword value = reinterpret_cast<uword>(this);
return (value & kSmiTagMask) == kHeapObjectTag;
}
// Assumes this is a heap object.
bool IsNewObject() const {
ASSERT(IsHeapObject());
uword addr = reinterpret_cast<uword>(this);
return (addr & kNewObjectAlignmentOffset) == kNewObjectAlignmentOffset;
}
// Assumes this is a heap object.
bool IsOldObject() const {
ASSERT(IsHeapObject());
uword addr = reinterpret_cast<uword>(this);
return (addr & kNewObjectAlignmentOffset) == kOldObjectAlignmentOffset;
}
// Like !IsHeapObject() || IsOldObject(), but compiles to a single branch.
bool IsSmiOrOldObject() const {
ASSERT(IsWellFormed());
COMPILE_ASSERT(kHeapObjectTag == 1);
COMPILE_ASSERT(kNewObjectAlignmentOffset == kWordSize);
static const uword kNewObjectBits =
(kNewObjectAlignmentOffset | kHeapObjectTag);
const uword addr = reinterpret_cast<uword>(this);
return (addr & kNewObjectBits) != kNewObjectBits;
}
// Support for GC marking bit.
bool IsMarked() const {
return MarkBit::decode(ptr()->tags_);
}
void SetMarkBit() {
ASSERT(!IsMarked());
UpdateTagBit<MarkBit>(true);
}
void SetMarkBitUnsynchronized() {
ASSERT(!IsMarked());
uword tags = ptr()->tags_;
ptr()->tags_ = MarkBit::update(true, tags);
}
void ClearMarkBit() {
ASSERT(IsMarked());
UpdateTagBit<MarkBit>(false);
}
// Returns false if the bit was already set.
// TODO(koda): Add "must use result" annotation here, after we add support.
bool TryAcquireMarkBit() {
return TryAcquireTagBit<MarkBit>();
}
// Support for GC watched bit.
// TODO(iposva): Get rid of this.
bool IsWatched() const {
return WatchedBit::decode(ptr()->tags_);
}
void SetWatchedBitUnsynchronized() {
ASSERT(!IsWatched());
uword tags = ptr()->tags_;
ptr()->tags_ = WatchedBit::update(true, tags);
}
void ClearWatchedBitUnsynchronized() {
uword tags = ptr()->tags_;
ptr()->tags_ = WatchedBit::update(false, tags);
}
// Support for object tags.
bool IsCanonical() const {
return CanonicalObjectTag::decode(ptr()->tags_);
}
void SetCanonical() {
UpdateTagBit<CanonicalObjectTag>(true);
}
void ClearCanonical() {
UpdateTagBit<CanonicalObjectTag>(false);
}
bool IsVMHeapObject() const {
return VMHeapObjectTag::decode(ptr()->tags_);
}
void SetVMHeapObject() {
UpdateTagBit<VMHeapObjectTag>(true);
}
// Support for GC remembered bit.
bool IsRemembered() const {
return RememberedBit::decode(ptr()->tags_);
}
void SetRememberedBit() {
ASSERT(!IsRemembered());
UpdateTagBit<RememberedBit>(true);
}
void SetRememberedBitUnsynchronized() {
ASSERT(!IsRemembered());
uword tags = ptr()->tags_;
ptr()->tags_ = RememberedBit::update(true, tags);
}
void ClearRememberedBit() {
UpdateTagBit<RememberedBit>(false);
}
void ClearRememberedBitUnsynchronized() {
uword tags = ptr()->tags_;
ptr()->tags_ = RememberedBit::update(false, tags);
}
// Returns false if the bit was already set.
// TODO(koda): Add "must use result" annotation here, after we add support.
bool TryAcquireRememberedBit() {
return TryAcquireTagBit<RememberedBit>();
}
bool IsDartInstance() {
return (!IsHeapObject() || (GetClassId() >= kInstanceCid));
}
bool IsFreeListElement() {
return ((GetClassId() == kFreeListElement));
}
bool IsScript() {
return ((GetClassId() == kScriptCid));
}
bool IsFunction() {
return ((GetClassId() == kFunctionCid));
}
bool IsInstructions() {
return ((GetClassId() == kInstructionsCid));
}
bool IsCode() {
return ((GetClassId() == kCodeCid));
}
intptr_t Size() const {
uword tags = ptr()->tags_;
intptr_t result = SizeTag::decode(tags);
if (result != 0) {
ASSERT(result == SizeFromClass());
return result;
}
result = SizeFromClass();
ASSERT(result > SizeTag::kMaxSizeTag);
return result;
}
bool Contains(uword addr) const {
intptr_t this_size = Size();
uword this_addr = RawObject::ToAddr(this);
return (addr >= this_addr) && (addr < (this_addr + this_size));
}
void Validate(Isolate* isolate) const;
intptr_t VisitPointers(ObjectPointerVisitor* visitor);
bool FindObject(FindObjectVisitor* visitor);
static RawObject* FromAddr(uword addr) {
// We expect the untagged address here.
ASSERT((addr & kSmiTagMask) != kHeapObjectTag);
return reinterpret_cast<RawObject*>(addr + kHeapObjectTag);
}
static uword ToAddr(const RawObject* raw_obj) {
return reinterpret_cast<uword>(raw_obj->ptr());
}
static bool IsVMHeapObject(intptr_t value) {
return VMHeapObjectTag::decode(value);
}
static bool IsCanonical(intptr_t value) {
return CanonicalObjectTag::decode(value);
}
// Class Id predicates.
static bool IsErrorClassId(intptr_t index);
static bool IsNumberClassId(intptr_t index);
static bool IsIntegerClassId(intptr_t index);
static bool IsStringClassId(intptr_t index);
static bool IsOneByteStringClassId(intptr_t index);
static bool IsTwoByteStringClassId(intptr_t index);
static bool IsExternalStringClassId(intptr_t index);
static bool IsBuiltinListClassId(intptr_t index);
static bool IsTypedDataClassId(intptr_t index);
static bool IsTypedDataViewClassId(intptr_t index);
static bool IsExternalTypedDataClassId(intptr_t index);
static bool IsInternalVMdefinedClassId(intptr_t index);
static bool IsVariableSizeClassId(intptr_t index);
static bool IsImplicitFieldClassId(intptr_t index);
static intptr_t NumberOfTypedDataClasses();
private:
uword tags_; // Various object tags (bits).
class WatchedBit : public BitField<bool, kWatchedBit, 1> {};
class MarkBit : public BitField<bool, kMarkBit, 1> {};
class RememberedBit : public BitField<bool, kRememberedBit, 1> {};
class CanonicalObjectTag : public BitField<bool, kCanonicalBit, 1> {};
class VMHeapObjectTag : public BitField<bool, kVMHeapObjectBit, 1> {};
class ReservedBits : public
BitField<intptr_t, kReservedTagPos, kReservedTagSize> {}; // NOLINT
// TODO(koda): After handling tags_, return const*, like Object::raw_ptr().
RawObject* ptr() const {
ASSERT(IsHeapObject());
return reinterpret_cast<RawObject*>(
reinterpret_cast<uword>(this) - kHeapObjectTag);
}
intptr_t SizeFromClass() const;
intptr_t GetClassId() const {
uword tags = ptr()->tags_;
return ClassIdTag::decode(tags);
}
template<class TagBitField>
void UpdateTagBit(bool value) {
uword tags = ptr()->tags_;
uword old_tags;
do {
old_tags = tags;
uword new_tags = TagBitField::update(value, old_tags);
tags = AtomicOperations::CompareAndSwapWord(
&ptr()->tags_, old_tags, new_tags);
} while (tags != old_tags);
}
template<class TagBitField>
bool TryAcquireTagBit() {
uword tags = ptr()->tags_;
uword old_tags;
do {
old_tags = tags;
if (TagBitField::decode(tags)) return false;
uword new_tags = TagBitField::update(true, old_tags);
tags = AtomicOperations::CompareAndSwapWord(
&ptr()->tags_, old_tags, new_tags);
} while (tags != old_tags);
return true;
}
// All writes to heap objects should ultimately pass through one of the
// methods below or their counterparts in Object, to ensure that the
// write barrier is correctly applied.
template<typename type>
void StorePointer(type const* addr, type value) {
#if defined(DEBUG)
ValidateOverwrittenPointer(*addr);
#endif // DEBUG
VerifiedMemory::Write(const_cast<type*>(addr), value);
// Filter stores based on source and target.
if (!value->IsHeapObject()) return;
if (value->IsNewObject() && this->IsOldObject() &&
!this->IsRemembered()) {
this->SetRememberedBit();
Thread::Current()->StoreBufferAddObject(this);
}
}
// Use for storing into an explicitly Smi-typed field of an object
// (i.e., both the previous and new value are Smis).
void StoreSmi(RawSmi* const* addr, RawSmi* value) {
#if defined(DEBUG)
ValidateOverwrittenSmi(*addr);
#endif // DEBUG
// Can't use Contains, as array length is initialized through this method.
ASSERT(reinterpret_cast<uword>(addr) >= RawObject::ToAddr(this));
VerifiedMemory::Write(const_cast<RawSmi**>(addr), value);
}
void InitializeSmi(RawSmi* const* addr, RawSmi* value) {
// Can't use Contains, as array length is initialized through this method.
ASSERT(reinterpret_cast<uword>(addr) >= RawObject::ToAddr(this));
// This is an initializing store, so any previous content is OK.
VerifiedMemory::Accept(reinterpret_cast<uword>(addr), kWordSize);
VerifiedMemory::Write(const_cast<RawSmi**>(addr), value);
}
#if defined(DEBUG)
static void ValidateOverwrittenPointer(RawObject* raw);
static void ValidateOverwrittenSmi(RawSmi* raw);
#endif // DEBUG
friend class Api;
friend class ApiMessageReader; // GetClassId
friend class Array;
friend class Bigint;
friend class ByteBuffer;
friend class Code;
friend class Closure;
friend class Double;
friend class FreeListElement;
friend class Function;
friend class GCMarker;
friend class ExternalTypedData;
friend class ForwardList;
friend class GrowableObjectArray; // StorePointer
friend class Heap;
friend class HeapMapAsJSONVisitor;
friend class ClassStatsVisitor;
template<bool> friend class MarkingVisitorBase;
friend class Mint;
friend class Object;
friend class OneByteString; // StoreSmi
friend class RawCode;
friend class RawExternalTypedData;
friend class RawInstructions;
friend class RawInstance;
friend class RawTypedData;
friend class Scavenger;
friend class ScavengerVisitor;
friend class SizeExcludingClassVisitor; // GetClassId
friend class RetainingPathVisitor; // GetClassId
friend class SkippedCodeFunctions; // StorePointer
friend class InstructionsReader; // tags_ check
friend class InstructionsWriter;
friend class SnapshotReader;
friend class SnapshotWriter;
friend class String;
friend class TypedData;
friend class TypedDataView;
friend class WeakProperty; // StorePointer
friend class Instance; // StorePointer
friend class StackFrame; // GetCodeObject assertion.
DISALLOW_ALLOCATION();
DISALLOW_IMPLICIT_CONSTRUCTORS(RawObject);
};
class RawClass : public RawObject {
public:
enum ClassFinalizedState {
kAllocated = 0, // Initial state.
kPreFinalized, // VM classes: size precomputed, but no checks done.
kFinalized, // Class parsed, finalized and ready for use.
};
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(Class);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->name_); }
RawString* name_;
RawString* user_name_;
RawArray* functions_;
RawArray* functions_hash_table_;
RawArray* fields_;
RawArray* offset_in_words_to_field_;
RawGrowableObjectArray* closure_functions_; // Local functions and literals.
RawArray* interfaces_; // Array of AbstractType.
RawGrowableObjectArray* direct_subclasses_; // Array of Class.
RawScript* script_;
RawLibrary* library_;
RawTypeArguments* type_parameters_; // Array of TypeParameter.
RawAbstractType* super_type_;
RawType* mixin_; // Generic mixin type, e.g. M<T>, not M<int>.
RawClass* patch_class_;
RawFunction* signature_function_; // Associated function for signature class.
RawArray* constants_; // Canonicalized values of this class.
RawObject* canonical_types_; // An array of canonicalized types of this class
// or the canonical type.
RawArray* invocation_dispatcher_cache_; // Cache for dispatcher functions.
RawArray* cha_codes_; // CHA optimized codes.
RawCode* allocation_stub_; // Stub code for allocation of instances.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->allocation_stub_);
}
cpp_vtable handle_vtable_;
int32_t token_pos_;
int32_t instance_size_in_words_; // Size if fixed len or 0 if variable len.
int32_t type_arguments_field_offset_in_words_; // Offset of type args fld.
int32_t next_field_offset_in_words_; // Offset of the next instance field.
classid_t id_; // Class Id, also index in the class table.
int16_t num_type_arguments_; // Number of type arguments in flattened vector.
int16_t num_own_type_arguments_; // Number of non-overlapping type arguments.
uint16_t num_native_fields_; // Number of native fields in class.
uint16_t state_bits_;
friend class Instance;
friend class Object;
friend class RawInstance;
friend class RawInstructions;
friend class SnapshotReader;
};
class RawUnresolvedClass : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(UnresolvedClass);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->library_prefix_);
}
RawLibraryPrefix* library_prefix_; // Library prefix qualifier for the ident.
RawString* ident_; // Name of the unresolved identifier.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->ident_);
}
int32_t token_pos_;
};
class RawTypeArguments : public RawObject {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(TypeArguments);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->instantiations_);
}
// The instantiations_ array remains empty for instantiated type arguments.
RawArray* instantiations_; // Array of paired canonical vectors:
// Even index: instantiator.
// Odd index: instantiated (without bound error).
// Instantiations leading to bound errors do not get cached.
RawSmi* length_;
// Variable length data follows here.
RawAbstractType* const* types() const {
OPEN_ARRAY_START(RawAbstractType*, RawAbstractType*);
}
RawAbstractType** types() {
OPEN_ARRAY_START(RawAbstractType*, RawAbstractType*);
}
RawObject** to(intptr_t length) {
return reinterpret_cast<RawObject**>(&ptr()->types()[length - 1]);
}
friend class SnapshotReader;
};
class RawPatchClass : public RawObject {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(PatchClass);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->patched_class_);
}
RawClass* patched_class_;
RawClass* source_class_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->source_class_);
}
friend class Function;
};
class RawFunction : public RawObject {
public:
enum Kind {
kRegularFunction,
kClosureFunction,
kSignatureFunction, // represents a signature only without actual code.
kGetterFunction, // represents getter functions e.g: get foo() { .. }.
kSetterFunction, // represents setter functions e.g: set foo(..) { .. }.
kConstructor,
kImplicitGetter, // represents an implicit getter for fields.
kImplicitSetter, // represents an implicit setter for fields.
kImplicitStaticFinalGetter, // represents an implicit getter for static
// final fields (incl. static const fields).
kMethodExtractor, // converts method into implicit closure on the receiver.
kNoSuchMethodDispatcher, // invokes noSuchMethod.
kInvokeFieldDispatcher, // invokes a field as a closure.
kIrregexpFunction, // represents a generated irregexp matcher function.
};
enum AsyncModifier {
kNoModifier = 0x0,
kAsyncBit = 0x1,
kGeneratorBit = 0x2,
kAsync = kAsyncBit,
kSyncGen = kGeneratorBit,
kAsyncGen = kAsyncBit | kGeneratorBit,
};
private:
// So that the SkippedCodeFunctions::DetachCode can null out the code fields.
friend class SkippedCodeFunctions;
friend class Class;
RAW_HEAP_OBJECT_IMPLEMENTATION(Function);
static bool ShouldVisitCode(RawCode* raw_code);
static bool CheckUsageCounter(RawFunction* raw_fun);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->name_); }
RawString* name_;
RawObject* owner_; // Class or patch class or mixin class
// where this function is defined.
RawAbstractType* result_type_;
RawArray* parameter_types_;
RawArray* parameter_names_;
RawObject* data_; // Additional data specific to the function kind.
RawObject** to_snapshot() {
return reinterpret_cast<RawObject**>(&ptr()->data_);
}
RawArray* ic_data_array_; // ICData of unoptimized code.
RawObject** to_no_code() {
return reinterpret_cast<RawObject**>(&ptr()->ic_data_array_);
}
RawCode* code_; // Currently active code.
RawCode* unoptimized_code_; // Unoptimized code, keep it after optimization.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->unoptimized_code_);
}
uword entry_point_;
int32_t token_pos_;
int32_t end_token_pos_;
int32_t usage_counter_; // Incremented while function is running.
int16_t num_fixed_parameters_;
int16_t num_optional_parameters_; // > 0: positional; < 0: named.
int16_t deoptimization_counter_;
uint32_t kind_tag_; // See Function::KindTagBits.
uint16_t optimized_instruction_count_;
uint16_t optimized_call_site_count_;
};
class RawClosureData : public RawObject {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(ClosureData);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->context_scope_);
}
RawContextScope* context_scope_;
RawFunction* parent_function_; // Enclosing function of this local function.
RawClass* signature_class_;
RawInstance* closure_; // Closure object for static implicit closures.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->closure_);
}
friend class Function;
};
class RawRedirectionData : public RawObject {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(RedirectionData);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_);
}
RawType* type_;
RawString* identifier_;
RawFunction* target_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->target_);
}
};
class RawField : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Field);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->name_); }
RawString* name_;
RawObject* owner_; // Class or patch class or mixin class
// where this field is defined.
RawAbstractType* type_;
union {
RawInstance* static_value_; // Value for static fields.
RawSmi* offset_; // Offset in words for instance fields.
} value_;
RawArray* dependent_code_;
union {
// When precompiling we need to save the static initializer function here
// so that code for it can be generated.
RawFunction* precompiled_; // Static initializer function - precompiling.
// When generating script snapshots after running the application it is
// necessary to save the initial value of static fields so that we can
// restore the value back to the original initial value.
RawInstance* saved_value_; // Saved initial value - static fields.
} initializer_;
RawSmi* guarded_list_length_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->guarded_list_length_);
}
int32_t token_pos_;
classid_t guarded_cid_;
classid_t is_nullable_; // kNullCid if field can contain null value and
// any other value otherwise.
// Offset to the guarded length field inside an instance of class matching
// guarded_cid_. Stored corrected by -kHeapObjectTag to simplify code
// generated on platforms with weak addressing modes (ARM, MIPS).
int8_t guarded_list_length_in_object_offset_;
uint8_t kind_bits_; // static, final, const, has initializer....
};
class RawLiteralToken : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(LiteralToken);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->literal_);
}
RawString* literal_; // Literal characters as they appear in source text.
RawObject* value_; // The actual object corresponding to the token.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->value_);
}
Token::Kind kind_; // The literal kind (string, integer, double).
friend class SnapshotReader;
};
class RawTokenStream : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(TokenStream);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->private_key_);
}
RawString* private_key_; // Key used for private identifiers.
RawArray* token_objects_;
RawExternalTypedData* stream_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->stream_);
}
friend class SnapshotReader;
};
class RawScript : public RawObject {
public:
enum Kind {
kScriptTag = 0,
kLibraryTag,
kSourceTag,
kPatchTag,
kEvaluateTag,
};
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(Script);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->url_); }
RawString* url_;
RawTokenStream* tokens_;
RawObject** to_snapshot() {
return reinterpret_cast<RawObject**>(&ptr()->tokens_);
}
RawString* source_;
RawObject** to() { return reinterpret_cast<RawObject**>(&ptr()->source_); }
int32_t line_offset_;
int32_t col_offset_;
int8_t kind_; // Of type Kind.
};
class RawLibrary : public RawObject {
enum LibraryState {
kAllocated, // Initial state.
kLoadRequested, // Compiler or script requested load of library.
kLoadInProgress, // Library is in the process of being loaded.
kLoaded, // Library is loaded.
kLoadError, // Error occurred during load of the Library.
};
RAW_HEAP_OBJECT_IMPLEMENTATION(Library);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->name_); }
RawString* name_;
RawString* url_;
RawScript* script_;
RawString* private_key_;
RawArray* dictionary_; // Top-level names in this library.
RawGrowableObjectArray* metadata_; // Metadata on classes, methods etc.
RawArray* anonymous_classes_; // Classes containing top-level elements.
RawArray* imports_; // List of Namespaces imported without prefix.
RawArray* exports_; // List of re-exported Namespaces.
RawInstance* load_error_; // Error iff load_state_ == kLoadError.
RawObject** to_snapshot() {
return reinterpret_cast<RawObject**>(&ptr()->load_error_);
}
RawArray* resolved_names_; // Cache of resolved names in library scope.
RawArray* loaded_scripts_; // Array of scripts loaded in this library.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->loaded_scripts_);
}
Dart_NativeEntryResolver native_entry_resolver_; // Resolves natives.
Dart_NativeEntrySymbol native_entry_symbol_resolver_;
classid_t index_; // Library id number.
classid_t num_anonymous_; // Number of entries in anonymous_classes_.
uint16_t num_imports_; // Number of entries in imports_.
int8_t load_state_; // Of type LibraryState.
bool corelib_imported_;
bool is_dart_scheme_;
bool debuggable_; // True if debugger can stop in library.
bool is_in_fullsnapshot_; // True if library is in a full snapshot.
friend class Class;
friend class Isolate;
};
class RawNamespace : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Namespace);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->library_);
}
RawLibrary* library_; // library with name dictionary.
RawArray* show_names_; // list of names that are exported.
RawArray* hide_names_; // blacklist of names that are not exported.
RawField* metadata_field_; // remembers the token pos of metadata if any,
// and the metadata values if computed.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->metadata_field_);
}
};
class RawCode : public RawObject {
enum InlinedMetadataIndex {
kInlinedIntervalsIndex = 0,
kInlinedIdToFunctionIndex = 1,
kInlinedCallerIdMapIndex = 2,
kInlinedMetadataSize = 3,
};
RAW_HEAP_OBJECT_IMPLEMENTATION(Code);
uword entry_point_;
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->active_instructions_);
}
RawInstructions* active_instructions_;
RawInstructions* instructions_;
RawObjectPool* object_pool_;
// If owner_ is Function::null() the owner is a regular stub.
// If owner_ is a Class the owner is the allocation stub for that class.
// Else, owner_ is a regular Dart Function.
RawObject* owner_; // Function, Null, or a Class.
RawExceptionHandlers* exception_handlers_;
RawPcDescriptors* pc_descriptors_;
RawArray* deopt_info_array_;
RawArray* static_calls_target_table_; // (code-offset, function, code).
RawArray* stackmaps_;
RawLocalVarDescriptors* var_descriptors_;
RawArray* inlined_metadata_;
RawArray* comments_;
// If return_address_metadata_ is a Smi, it is the offset to the prologue.
// Else, return_address_metadata_ is null.
RawObject* return_address_metadata_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->return_address_metadata_);
}
// Compilation timestamp.
int64_t compile_timestamp_;
// state_bits_ is a bitfield with three fields:
// The optimized bit, the alive bit, and a count of the number of pointer
// offsets.
// Alive: If true, the embedded object pointers will be visited during GC.
int32_t state_bits_;
// PC offsets for code patching.
int32_t lazy_deopt_pc_offset_;
// Variable length data follows here.
int32_t* data() { OPEN_ARRAY_START(int32_t, int32_t); }
const int32_t* data() const { OPEN_ARRAY_START(int32_t, int32_t); }
static bool ContainsPC(RawObject* raw_obj, uword pc);
friend class Function;
template<bool> friend class MarkingVisitorBase;
friend class SkippedCodeFunctions;
friend class StackFrame;
friend class Profiler;
};
class RawObjectPool : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(ObjectPool);
intptr_t length_;
RawTypedData* info_array_;
struct Entry {
union {
RawObject* raw_obj_;
uword raw_value_;
};
};
Entry* data() { OPEN_ARRAY_START(Entry, Entry); }
Entry const* data() const { OPEN_ARRAY_START(Entry, Entry); }
Entry* first_entry() { return &ptr()->data()[0]; }
friend class Object;
friend class SnapshotReader;
};
class RawInstructions : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Instructions);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->code_);
}
RawCode* code_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->code_);
}
int32_t size_;
// Variable length data follows here.
uint8_t* data() { OPEN_ARRAY_START(uint8_t, uint8_t); }
// Private helper function used while visiting stack frames. The
// code which iterates over dart frames is also called during GC and
// is not allowed to create handles.
static bool ContainsPC(RawInstructions* raw_instr, uword pc);
friend class RawCode;
friend class RawFunction;
friend class Code;
friend class StackFrame;
template<bool> friend class MarkingVisitorBase;
friend class SkippedCodeFunctions;
friend class Function;
friend class InstructionsReader;
friend class InstructionsWriter;
};
class RawPcDescriptors : public RawObject {
public:
enum Kind {
kDeopt = 1, // Deoptimization continuation point.
kIcCall = kDeopt << 1, // IC call.
kUnoptStaticCall = kIcCall << 1, // Call to a known target via stub.
kRuntimeCall = kUnoptStaticCall << 1, // Runtime call.
kOsrEntry = kRuntimeCall << 1, // OSR entry point in unopt. code.
kOther = kOsrEntry << 1,
kLastKind = kOther,
kAnyKind = -1
};
class MergedKindTry {
public:
// Most of the time try_index will be small and merged field will fit into
// one byte.
static intptr_t Encode(intptr_t kind, intptr_t try_index) {
intptr_t kind_shift = Utils::ShiftForPowerOfTwo(kind);
ASSERT(Utils::IsUint(kKindShiftSize, kind_shift));
ASSERT(Utils::IsInt(kTryIndexSize, try_index));
return (try_index << kTryIndexPos) | (kind_shift << kKindShiftPos);
}
static intptr_t DecodeKind(intptr_t merged_kind_try) {
const intptr_t kKindShiftMask = (1 << kKindShiftSize) - 1;
return 1 << (merged_kind_try & kKindShiftMask);
}
static intptr_t DecodeTryIndex(intptr_t merged_kind_try) {
// Arithmetic shift.
return merged_kind_try >> kTryIndexPos;
}
private:
static const intptr_t kKindShiftPos = 0;
static const intptr_t kKindShiftSize = 3;
// Is kKindShiftSize enough bits?
COMPILE_ASSERT(kLastKind <= 1 << ((1 << kKindShiftSize) - 1));
static const intptr_t kTryIndexPos = kKindShiftSize;
static const intptr_t kTryIndexSize = kBitsPerWord - kKindShiftSize;
};
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(PcDescriptors);
int32_t length_; // Number of descriptors.
// Variable length data follows here.
uint8_t* data() { OPEN_ARRAY_START(uint8_t, intptr_t); }
const uint8_t* data() const { OPEN_ARRAY_START(uint8_t, intptr_t); }
friend class Object;
friend class SnapshotReader;
};
// Stackmap is an immutable representation of the layout of the stack at a
// PC. The stack map representation consists of a bit map which marks each
// live object index starting from the base of the frame.
//
// The bit map representation is optimized for dense and small bit maps, without
// any upper bound.
class RawStackmap : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Stackmap);
// Regarding changing this to a bitfield: ARM64 requires register_bit_count_
// to be as large as 96, meaning 7 bits, leaving 25 bits for the length, or
// as large as ~33 million entries. If that is sufficient, then these two
// fields can be merged into a BitField.
int32_t length_; // Length of payload, in bits.
int32_t register_bit_count_; // Live register bits, included in length_.
// Offset from code entry point corresponding to this stack map
// representation.
uint32_t pc_offset_;
// Variable length data follows here (bitmap of the stack layout).
uint8_t* data() { OPEN_ARRAY_START(uint8_t, uint8_t); }
const uint8_t* data() const { OPEN_ARRAY_START(uint8_t, uint8_t); }
friend class SnapshotReader;
};
class RawLocalVarDescriptors : public RawObject {
public:
enum VarInfoKind {
kStackVar = 1,
kContextVar,
kContextLevel,
kSavedCurrentContext,
};
enum {
kKindPos = 0,
kKindSize = 8,
kIndexPos = kKindPos + kKindSize,
// Since there are 24 bits for the stack slot index, Functions can have
// only ~16.7 million stack slots.
kPayloadSize = sizeof(int32_t) * kBitsPerByte,
kIndexSize = kPayloadSize - kIndexPos,
kIndexBias = 1 << (kIndexSize - 1),
kMaxIndex = (1 << (kIndexSize - 1)) - 1,
};
class IndexBits : public BitField<int32_t, kIndexPos, kIndexSize> {};
class KindBits : public BitField<int8_t, kKindPos, kKindSize>{};
struct VarInfo {
int32_t index_kind; // Bitfield for slot index on stack or in context,
// and Entry kind of type VarInfoKind.
int32_t begin_pos; // Token position of scope start.
int32_t end_pos; // Token position of scope end.
int16_t scope_id; // Scope to which the variable belongs.
VarInfoKind kind() const {
return static_cast<VarInfoKind>(KindBits::decode(index_kind));
}
void set_kind(VarInfoKind kind) {
index_kind = KindBits::update(kind, index_kind);
}
int32_t index() const {
return IndexBits::decode(index_kind) - kIndexBias;
}
void set_index(int32_t index) {
index_kind = IndexBits::update(index + kIndexBias, index_kind);
}
};
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(LocalVarDescriptors);
int32_t num_entries_; // Number of descriptors.
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->names()[0]);
}
RawString** names() {
// Array of [num_entries_] variable names.
OPEN_ARRAY_START(RawString*, RawString*);
}
RawString** nameAddrAt(intptr_t i) {
return &(ptr()->names()[i]);
}
RawObject** to(intptr_t num_entries) {
return reinterpret_cast<RawObject**>(nameAddrAt(num_entries - 1));
}
// Variable info with [num_entries_] entries.
VarInfo* data() {
return reinterpret_cast<VarInfo*>(nameAddrAt(ptr()->num_entries_));
}
friend class Object;
friend class SnapshotReader;
};
class RawExceptionHandlers : public RawObject {
public:
// The index into the ExceptionHandlers table corresponds to
// the try_index of the handler.
struct HandlerInfo {
uint32_t handler_pc_offset; // PC offset value of handler.
int16_t outer_try_index; // Try block index of enclosing try block.
int8_t needs_stacktrace; // True if a stacktrace is needed.
int8_t has_catch_all; // Catches all exceptions.
};
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(ExceptionHandlers);
// Number of exception handler entries.
int32_t num_entries_;
// Array with [num_entries_] entries. Each entry is an array of all handled
// exception types.
RawArray* handled_types_data_;
// Exception handler info of length [num_entries_].
const HandlerInfo* data() const { OPEN_ARRAY_START(HandlerInfo, intptr_t); }
HandlerInfo* data() { OPEN_ARRAY_START(HandlerInfo, intptr_t); }
friend class Object;
friend class SnapshotReader;
};
class RawContext : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Context);
int32_t num_variables_;
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->parent_); }
RawContext* parent_;
// Variable length data follows here.
RawObject** data() { OPEN_ARRAY_START(RawObject*, RawObject*); }
RawObject* const* data() const {
OPEN_ARRAY_START(RawObject*, RawObject*);
}
RawObject** to(intptr_t num_vars) {
return reinterpret_cast<RawObject**>(&ptr()->data()[num_vars - 1]);
}
friend class SnapshotReader;
};
class RawContextScope : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(ContextScope);
// TODO(iposva): Switch to conventional enum offset based structure to avoid
// alignment mishaps.
struct VariableDesc {
RawSmi* token_pos;
RawString* name;
RawBool* is_final;
RawBool* is_const;
union {
RawAbstractType* type;
RawInstance* value; // iff is_const is true
};
RawSmi* context_index;
RawSmi* context_level;
};
int32_t num_variables_;
bool is_implicit_; // true, if this context scope is for an implicit closure.
RawObject** from() {
VariableDesc* begin = const_cast<VariableDesc*>(ptr()->VariableDescAddr(0));
return reinterpret_cast<RawObject**>(begin);
}
// Variable length data follows here.
RawObject* const* data() const { OPEN_ARRAY_START(RawObject*, RawObject*); }
const VariableDesc* VariableDescAddr(intptr_t index) const {
ASSERT((index >= 0) && (index < num_variables_ + 1));
// data() points to the first component of the first descriptor.
return &(reinterpret_cast<const VariableDesc*>(data())[index]);
}
RawObject** to(intptr_t num_vars) {
uword end = reinterpret_cast<uword>(ptr()->VariableDescAddr(num_vars));
// 'end' is the address just beyond the last descriptor, so step back.
return reinterpret_cast<RawObject**>(end - kWordSize);
}
friend class Object;
friend class RawClosureData;
friend class SnapshotReader;
};
class RawICData : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(ICData);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->owner_);
}
RawFunction* owner_; // Parent/calling function of this IC.
RawString* target_name_; // Name of target function.
RawArray* args_descriptor_; // Arguments descriptor.
RawArray* ic_data_; // Contains class-ids, target and count.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->ic_data_);
}
int32_t deopt_id_; // Deoptimization id corresponding to this IC.
uint32_t state_bits_; // Number of arguments tested in IC, deopt reasons,
// is closure call, JS warning issued, range feedback.
};
class RawMegamorphicCache : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(MegamorphicCache);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->buckets_);
}
RawArray* buckets_;
RawSmi* mask_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->mask_);
}
int32_t filled_entry_count_;
};
class RawSubtypeTestCache : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(SubtypeTestCache);
RawArray* cache_;
};
class RawError : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Error);
};
class RawApiError : public RawError {
RAW_HEAP_OBJECT_IMPLEMENTATION(ApiError);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->message_);
}
RawString* message_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->message_);
}
};
class RawLanguageError : public RawError {
RAW_HEAP_OBJECT_IMPLEMENTATION(LanguageError);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->previous_error_);
}
RawError* previous_error_; // May be null.
RawScript* script_;
RawString* message_;
RawString* formatted_message_; // Incl. previous error's formatted message.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->formatted_message_);
}
int32_t token_pos_; // Source position in script_.
int8_t kind_; // Of type LanguageError::Kind.
};
class RawUnhandledException : public RawError {
RAW_HEAP_OBJECT_IMPLEMENTATION(UnhandledException);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->exception_);
}
RawInstance* exception_;
RawInstance* stacktrace_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->stacktrace_);
}
};
class RawUnwindError : public RawError {
RAW_HEAP_OBJECT_IMPLEMENTATION(UnwindError);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->message_);
}
RawString* message_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->message_);
}
bool is_user_initiated_;
bool is_vm_restart_;
};
class RawInstance : public RawObject {
RAW_HEAP_OBJECT_IMPLEMENTATION(Instance);
};
class RawLibraryPrefix : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(LibraryPrefix);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->name_); }
RawString* name_; // Library prefix name.
RawArray* imports_; // Libraries imported with this prefix.
RawLibrary* importer_; // Library which declares this prefix.
RawArray* dependent_code_; // Code that refers to deferred, unloaded
// library prefix.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->dependent_code_);
}
uint16_t num_imports_; // Number of library entries in libraries_.
bool is_deferred_load_;
bool is_loaded_;
};
class RawAbstractType : public RawInstance {
protected:
enum TypeState {
kAllocated, // Initial state.
kResolved, // Type class and type arguments resolved.
kBeingFinalized, // In the process of being finalized.
kFinalizedInstantiated, // Instantiated type ready for use.
kFinalizedUninstantiated, // Uninstantiated type ready for use.
};
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(AbstractType);
friend class ObjectStore;
};
class RawType : public RawAbstractType {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(Type);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_class_);
}
RawObject* type_class_; // Either resolved class or unresolved class.
RawTypeArguments* arguments_;
RawLanguageError* error_; // Error object if type is malformed or malbounded.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->error_);
}
int32_t token_pos_;
int8_t type_state_;
};
class RawTypeRef : public RawAbstractType {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(TypeRef);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_);
}
RawAbstractType* type_; // The referenced type.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->type_);
}
};
class RawTypeParameter : public RawAbstractType {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(TypeParameter);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->parameterized_class_);
}
RawClass* parameterized_class_;
RawString* name_;
RawAbstractType* bound_; // ObjectType if no explicit bound specified.
RawObject** to() { return reinterpret_cast<RawObject**>(&ptr()->bound_); }
int32_t token_pos_;
int16_t index_;
int8_t type_state_;
};
class RawBoundedType : public RawAbstractType {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(BoundedType);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_);
}
RawAbstractType* type_;
RawAbstractType* bound_;
RawTypeParameter* type_parameter_; // For more detailed error reporting.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->type_parameter_);
}
};
class RawMixinAppType : public RawAbstractType {
private:
RAW_HEAP_OBJECT_IMPLEMENTATION(MixinAppType);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->super_type_);
}
RawAbstractType* super_type_;
RawArray* mixin_types_; // Array of AbstractType.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->mixin_types_);
}
};
class RawNumber : public RawInstance {
RAW_OBJECT_IMPLEMENTATION(Number);
};
class RawInteger : public RawNumber {
RAW_OBJECT_IMPLEMENTATION(Integer);
};
class RawSmi : public RawInteger {
RAW_OBJECT_IMPLEMENTATION(Smi);
};
class RawMint : public RawInteger {
RAW_HEAP_OBJECT_IMPLEMENTATION(Mint);
ALIGN8 int64_t value_;
friend class Api;
friend class SnapshotReader;
};
COMPILE_ASSERT(sizeof(RawMint) == 16);
class RawBigint : public RawInteger {
RAW_HEAP_OBJECT_IMPLEMENTATION(Bigint);
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->neg_); }
RawBool* neg_;
RawSmi* used_;
RawTypedData* digits_;
RawObject** to() { return reinterpret_cast<RawObject**>(&ptr()->digits_); }
};
class RawDouble : public RawNumber {
RAW_HEAP_OBJECT_IMPLEMENTATION(Double);
ALIGN8 double value_;
friend class Api;
friend class SnapshotReader;
};
COMPILE_ASSERT(sizeof(RawDouble) == 16);
class RawString : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(String);
protected:
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->length_); }
RawSmi* length_;
RawSmi* hash_;
RawObject** to() { return reinterpret_cast<RawObject**>(&ptr()->hash_); }
friend class Library;
};
class RawOneByteString : public RawString {
RAW_HEAP_OBJECT_IMPLEMENTATION(OneByteString);
// Variable length data follows here.
uint8_t* data() { OPEN_ARRAY_START(uint8_t, uint8_t); }
const uint8_t* data() const { OPEN_ARRAY_START(uint8_t, uint8_t); }
friend class ApiMessageReader;
friend class SnapshotReader;
};
class RawTwoByteString : public RawString {
RAW_HEAP_OBJECT_IMPLEMENTATION(TwoByteString);
// Variable length data follows here.
uint16_t* data() { OPEN_ARRAY_START(uint16_t, uint16_t); }
const uint16_t* data() const { OPEN_ARRAY_START(uint16_t, uint16_t); }
friend class SnapshotReader;
};
template<typename T>
class ExternalStringData {
public:
ExternalStringData(const T* data, void* peer, Dart_PeerFinalizer callback) :
data_(data), peer_(peer), callback_(callback) {
}
~ExternalStringData() {
if (callback_ != NULL) (*callback_)(peer_);
}
const T* data() {
return data_;
}
void* peer() {
return peer_;
}
static intptr_t data_offset() {
return OFFSET_OF(ExternalStringData<T>, data_);
}
private:
const T* data_;
void* peer_;
Dart_PeerFinalizer callback_;
};
class RawExternalOneByteString : public RawString {
RAW_HEAP_OBJECT_IMPLEMENTATION(ExternalOneByteString);
public:
typedef ExternalStringData<uint8_t> ExternalData;
private:
ExternalData* external_data_;
friend class Api;
};
class RawExternalTwoByteString : public RawString {
RAW_HEAP_OBJECT_IMPLEMENTATION(ExternalTwoByteString);
public:
typedef ExternalStringData<uint16_t> ExternalData;
private:
ExternalData* external_data_;
friend class Api;
};
class RawBool : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Bool);
bool value_;
};
class RawArray : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Array);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_arguments_);
}
RawTypeArguments* type_arguments_;
RawSmi* length_;
// Variable length data follows here.
RawObject** data() { OPEN_ARRAY_START(RawObject*, RawObject*); }
RawObject* const* data() const { OPEN_ARRAY_START(RawObject*, RawObject*); }
RawObject** to(intptr_t length) {
return reinterpret_cast<RawObject**>(&ptr()->data()[length - 1]);
}
friend class RawCode;
friend class RawImmutableArray;
friend class SnapshotReader;
friend class GrowableObjectArray;
friend class LinkedHashMap;
friend class RawLinkedHashMap;
friend class Object;
friend class ICData; // For high performance access.
friend class SubtypeTestCache; // For high performance access.
};
class RawImmutableArray : public RawArray {
RAW_HEAP_OBJECT_IMPLEMENTATION(ImmutableArray);
friend class SnapshotReader;
};
class RawGrowableObjectArray : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(GrowableObjectArray);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_arguments_);
}
RawTypeArguments* type_arguments_;
RawSmi* length_;
RawArray* data_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->data_);
}
friend class SnapshotReader;
};
class RawLinkedHashMap : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(LinkedHashMap);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->type_arguments_);
}
RawTypeArguments* type_arguments_;
RawTypedData* index_;
RawSmi* hash_mask_;
RawArray* data_;
RawSmi* used_data_;
RawSmi* deleted_keys_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->deleted_keys_);
}
friend class SnapshotReader;
};
class RawFloat32x4 : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Float32x4);
float value_[4];
friend class SnapshotReader;
public:
float x() const { return value_[0]; }
float y() const { return value_[1]; }
float z() const { return value_[2]; }
float w() const { return value_[3]; }
};
class RawInt32x4 : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Int32x4);
int32_t value_[4];
friend class SnapshotReader;
public:
int32_t x() const { return value_[0]; }
int32_t y() const { return value_[1]; }
int32_t z() const { return value_[2]; }
int32_t w() const { return value_[3]; }
};
class RawFloat64x2 : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Float64x2);
double value_[2];
friend class SnapshotReader;
public:
double x() const { return value_[0]; }
double y() const { return value_[1]; }
};
// Define an aliases for intptr_t.
#if defined(ARCH_IS_32_BIT)
#define kIntPtrCid kTypedDataInt32ArrayCid
#define SetIntPtr SetInt32
#elif defined(ARCH_IS_64_BIT)
#define kIntPtrCid kTypedDataInt64ArrayCid
#define SetIntPtr SetInt64
#else
#error Architecture is not 32-bit or 64-bit.
#endif // ARCH_IS_32_BIT
class RawTypedData : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(TypedData);
protected:
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->length_); }
RawSmi* length_;
// Variable length data follows here.
uint8_t* data() { OPEN_ARRAY_START(uint8_t, uint8_t); }
const uint8_t* data() const { OPEN_ARRAY_START(uint8_t, uint8_t); }
RawObject** to() { return reinterpret_cast<RawObject**>(&ptr()->length_); }
friend class Api;
friend class Object;
friend class Instance;
friend class SnapshotReader;
friend class ObjectPool;
friend class RawObjectPool;
};
class RawExternalTypedData : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(ExternalTypedData);
protected:
RawObject** from() { return reinterpret_cast<RawObject**>(&ptr()->length_); }
RawSmi* length_;
RawObject** to() { return reinterpret_cast<RawObject**>(&ptr()->length_); }
uint8_t* data_;
friend class TokenStream;
friend class RawTokenStream;
};
// VM implementations of the basic types in the isolate.
class RawCapability : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Capability);
uint64_t id_;
};
class RawSendPort : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(SendPort);
Dart_Port id_;
Dart_Port origin_id_;
friend class ReceivePort;
};
class RawReceivePort : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(ReceivePort);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->send_port_);
}
RawSendPort* send_port_;
RawInstance* handler_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->handler_);
}
};
// VM type for capturing stacktraces when exceptions are thrown,
// Currently we don't have any interface that this object is supposed
// to implement so we just support the 'toString' method which
// converts the stack trace into a string.
class RawStacktrace : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(Stacktrace);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->code_array_);
}
RawArray* code_array_; // Code object for each frame in the stack trace.
RawArray* pc_offset_array_; // Offset of PC for each frame.
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->pc_offset_array_);
}
// False for pre-allocated stack trace (used in OOM and Stack overflow).
bool expand_inlined_;
};
// VM type for capturing JS regular expressions.
class RawJSRegExp : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(JSRegExp);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->num_bracket_expressions_);
}
RawSmi* num_bracket_expressions_;
RawString* pattern_; // Pattern to be used for matching.
RawFunction* one_byte_function_;
RawFunction* two_byte_function_;
RawFunction* external_one_byte_function_;
RawFunction* external_two_byte_function_;
RawTypedData* one_byte_bytecode_;
RawTypedData* two_byte_bytecode_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->two_byte_bytecode_);
}
intptr_t num_registers_;
// A bitfield with two fields:
// type: Uninitialized, simple or complex.
// flags: Represents global/local, case insensitive, multiline.
int8_t type_flags_;
};
class RawWeakProperty : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(WeakProperty);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->key_);
}
RawObject* key_;
RawObject* value_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->value_);
}
friend class DelaySet;
friend class GCMarker;
template<bool> friend class MarkingVisitorBase;
friend class Scavenger;
friend class ScavengerVisitor;
};
// MirrorReferences are used by mirrors to hold reflectees that are VM
// internal objects, such as libraries, classes, functions or types.
class RawMirrorReference : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(MirrorReference);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->referent_);
}
RawObject* referent_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->referent_);
}
};
// UserTag are used by the profiler to track Dart script state.
class RawUserTag : public RawInstance {
RAW_HEAP_OBJECT_IMPLEMENTATION(UserTag);
RawObject** from() {
return reinterpret_cast<RawObject**>(&ptr()->label_);
}
RawString* label_;
RawObject** to() {
return reinterpret_cast<RawObject**>(&ptr()->label_);
}
// Isolate unique tag.
uword tag_;
friend class SnapshotReader;
friend class Object;
public:
uword tag() const { return tag_; }
};
// Class Id predicates.
inline bool RawObject::IsErrorClassId(intptr_t index) {
// Make sure this function is updated when new Error types are added.
COMPILE_ASSERT(kApiErrorCid == kErrorCid + 1 &&
kLanguageErrorCid == kErrorCid + 2 &&
kUnhandledExceptionCid == kErrorCid + 3 &&
kUnwindErrorCid == kErrorCid + 4 &&
kInstanceCid == kErrorCid + 5);
return (index >= kErrorCid && index < kInstanceCid);
}
inline bool RawObject::IsNumberClassId(intptr_t index) {
// Make sure this function is updated when new Number types are added.
COMPILE_ASSERT(kIntegerCid == kNumberCid + 1 &&
kSmiCid == kNumberCid + 2 &&
kMintCid == kNumberCid + 3 &&
kBigintCid == kNumberCid + 4 &&
kDoubleCid == kNumberCid + 5);
return (index >= kNumberCid && index < kBoolCid);
}
inline bool RawObject::IsIntegerClassId(intptr_t index) {
// Make sure this function is updated when new Integer types are added.
COMPILE_ASSERT(kSmiCid == kIntegerCid + 1 &&
kMintCid == kIntegerCid + 2 &&
kBigintCid == kIntegerCid + 3 &&
kDoubleCid == kIntegerCid + 4);
return (index >= kIntegerCid && index < kDoubleCid);
}
inline bool RawObject::IsStringClassId(intptr_t index) {
// Make sure this function is updated when new StringCid types are added.
COMPILE_ASSERT(kOneByteStringCid == kStringCid + 1 &&
kTwoByteStringCid == kStringCid + 2 &&
kExternalOneByteStringCid == kStringCid + 3 &&
kExternalTwoByteStringCid == kStringCid + 4);
return (index >= kStringCid && index <= kExternalTwoByteStringCid);
}
inline bool RawObject::IsOneByteStringClassId(intptr_t index) {
// Make sure this function is updated when new StringCid types are added.
COMPILE_ASSERT(kOneByteStringCid == kStringCid + 1 &&
kTwoByteStringCid == kStringCid + 2 &&
kExternalOneByteStringCid == kStringCid + 3 &&
kExternalTwoByteStringCid == kStringCid + 4);
return (index == kOneByteStringCid || index == kExternalOneByteStringCid);
}
inline bool RawObject::IsTwoByteStringClassId(intptr_t index) {
// Make sure this function is updated when new StringCid types are added.
COMPILE_ASSERT(kOneByteStringCid == kStringCid + 1 &&
kTwoByteStringCid == kStringCid + 2 &&
kExternalOneByteStringCid == kStringCid + 3 &&
kExternalTwoByteStringCid == kStringCid + 4);
return (index == kOneByteStringCid ||
index == kTwoByteStringCid ||
index == kExternalOneByteStringCid ||
index == kExternalTwoByteStringCid);
}
inline bool RawObject::IsExternalStringClassId(intptr_t index) {
// Make sure this function is updated when new StringCid types are added.
COMPILE_ASSERT(kOneByteStringCid == kStringCid + 1 &&
kTwoByteStringCid == kStringCid + 2 &&
kExternalOneByteStringCid == kStringCid + 3 &&
kExternalTwoByteStringCid == kStringCid + 4);
return (index == kExternalOneByteStringCid ||
index == kExternalTwoByteStringCid);
}
inline bool RawObject::IsBuiltinListClassId(intptr_t index) {
// Make sure this function is updated when new builtin List types are added.
COMPILE_ASSERT(kImmutableArrayCid == kArrayCid + 1);
return ((index >= kArrayCid && index <= kImmutableArrayCid) ||
(index == kGrowableObjectArrayCid) ||
IsTypedDataClassId(index) ||
IsTypedDataViewClassId(index) ||
IsExternalTypedDataClassId(index) ||
(index == kByteBufferCid));
}
inline bool RawObject::IsTypedDataClassId(intptr_t index) {
// Make sure this is updated when new TypedData types are added.
COMPILE_ASSERT(kTypedDataUint8ArrayCid == kTypedDataInt8ArrayCid + 1 &&
kTypedDataUint8ClampedArrayCid == kTypedDataInt8ArrayCid + 2 &&
kTypedDataInt16ArrayCid == kTypedDataInt8ArrayCid + 3 &&
kTypedDataUint16ArrayCid == kTypedDataInt8ArrayCid + 4 &&
kTypedDataInt32ArrayCid == kTypedDataInt8ArrayCid + 5 &&
kTypedDataUint32ArrayCid == kTypedDataInt8ArrayCid + 6 &&
kTypedDataInt64ArrayCid == kTypedDataInt8ArrayCid + 7 &&
kTypedDataUint64ArrayCid == kTypedDataInt8ArrayCid + 8 &&
kTypedDataFloat32ArrayCid == kTypedDataInt8ArrayCid + 9 &&
kTypedDataFloat64ArrayCid == kTypedDataInt8ArrayCid + 10 &&
kTypedDataFloat32x4ArrayCid == kTypedDataInt8ArrayCid + 11 &&
kTypedDataInt32x4ArrayCid == kTypedDataInt8ArrayCid + 12 &&
kTypedDataFloat64x2ArrayCid == kTypedDataInt8ArrayCid + 13 &&
kTypedDataInt8ArrayViewCid == kTypedDataInt8ArrayCid + 14);
return (index >= kTypedDataInt8ArrayCid &&
index <= kTypedDataFloat64x2ArrayCid);
}
inline bool RawObject::IsTypedDataViewClassId(intptr_t index) {
// Make sure this is updated when new TypedData types are added.
COMPILE_ASSERT(
kTypedDataUint8ArrayViewCid == kTypedDataInt8ArrayViewCid + 1 &&
kTypedDataUint8ClampedArrayViewCid == kTypedDataInt8ArrayViewCid + 2 &&
kTypedDataInt16ArrayViewCid == kTypedDataInt8ArrayViewCid + 3 &&
kTypedDataUint16ArrayViewCid == kTypedDataInt8ArrayViewCid + 4 &&
kTypedDataInt32ArrayViewCid == kTypedDataInt8ArrayViewCid + 5 &&
kTypedDataUint32ArrayViewCid == kTypedDataInt8ArrayViewCid + 6 &&
kTypedDataInt64ArrayViewCid == kTypedDataInt8ArrayViewCid + 7 &&
kTypedDataUint64ArrayViewCid == kTypedDataInt8ArrayViewCid + 8 &&
kTypedDataFloat32ArrayViewCid == kTypedDataInt8ArrayViewCid + 9 &&
kTypedDataFloat64ArrayViewCid == kTypedDataInt8ArrayViewCid + 10 &&
kTypedDataFloat32x4ArrayViewCid == kTypedDataInt8ArrayViewCid + 11 &&
kTypedDataInt32x4ArrayViewCid == kTypedDataInt8ArrayViewCid + 12 &&
kTypedDataFloat64x2ArrayViewCid == kTypedDataInt8ArrayViewCid + 13 &&
kByteDataViewCid == kTypedDataInt8ArrayViewCid + 14 &&
kExternalTypedDataInt8ArrayCid == kTypedDataInt8ArrayViewCid + 15);
return (index >= kTypedDataInt8ArrayViewCid &&
index <= kByteDataViewCid);
}
inline bool RawObject::IsExternalTypedDataClassId(intptr_t index) {
// Make sure this is updated when new ExternalTypedData types are added.
COMPILE_ASSERT(
(kExternalTypedDataUint8ArrayCid ==
kExternalTypedDataInt8ArrayCid + 1) &&
(kExternalTypedDataUint8ClampedArrayCid ==
kExternalTypedDataInt8ArrayCid + 2) &&
(kExternalTypedDataInt16ArrayCid ==
kExternalTypedDataInt8ArrayCid + 3) &&
(kExternalTypedDataUint16ArrayCid ==
kExternalTypedDataInt8ArrayCid + 4) &&
(kExternalTypedDataInt32ArrayCid ==
kExternalTypedDataInt8ArrayCid + 5) &&
(kExternalTypedDataUint32ArrayCid ==
kExternalTypedDataInt8ArrayCid + 6) &&
(kExternalTypedDataInt64ArrayCid ==
kExternalTypedDataInt8ArrayCid + 7) &&
(kExternalTypedDataUint64ArrayCid ==
kExternalTypedDataInt8ArrayCid + 8) &&
(kExternalTypedDataFloat32ArrayCid ==
kExternalTypedDataInt8ArrayCid + 9) &&
(kExternalTypedDataFloat64ArrayCid ==
kExternalTypedDataInt8ArrayCid + 10) &&
(kExternalTypedDataFloat32x4ArrayCid ==
kExternalTypedDataInt8ArrayCid + 11) &&
(kExternalTypedDataInt32x4ArrayCid ==
kExternalTypedDataInt8ArrayCid + 12) &&
(kExternalTypedDataFloat64x2ArrayCid ==
kExternalTypedDataInt8ArrayCid + 13) &&
(kByteBufferCid == kExternalTypedDataInt8ArrayCid + 14));
return (index >= kExternalTypedDataInt8ArrayCid &&
index <= kExternalTypedDataFloat64x2ArrayCid);
}
inline bool RawObject::IsInternalVMdefinedClassId(intptr_t index) {
return ((index < kNumPredefinedCids) &&
!RawObject::IsImplicitFieldClassId(index));
}
inline bool RawObject::IsVariableSizeClassId(intptr_t index) {
return (index == kArrayCid) ||
(index == kImmutableArrayCid) ||
RawObject::IsOneByteStringClassId(index) ||
RawObject::IsTwoByteStringClassId(index) ||
RawObject::IsTypedDataClassId(index) ||
(index == kContextCid) ||
(index == kTypeArgumentsCid) ||
(index == kInstructionsCid) ||
(index == kObjectPoolCid) ||
(index == kPcDescriptorsCid) ||
(index == kStackmapCid) ||
(index == kLocalVarDescriptorsCid) ||
(index == kExceptionHandlersCid) ||
(index == kCodeCid) ||
(index == kContextScopeCid) ||
(index == kInstanceCid) ||
(index == kJSRegExpCid);
}
// This is a set of classes that are not Dart classes whose representation
// is defined by the VM but are used in the VM code by computing the
// implicit field offsets of the various fields in the dart object.
inline bool RawObject::IsImplicitFieldClassId(intptr_t index) {
return (IsTypedDataViewClassId(index) || index == kByteBufferCid);
}
inline intptr_t RawObject::NumberOfTypedDataClasses() {
// Make sure this is updated when new TypedData types are added.
COMPILE_ASSERT(kTypedDataInt8ArrayViewCid == kTypedDataInt8ArrayCid + 14);
COMPILE_ASSERT(kExternalTypedDataInt8ArrayCid ==
kTypedDataInt8ArrayViewCid + 15);
COMPILE_ASSERT(kByteBufferCid == kExternalTypedDataInt8ArrayCid + 14);
COMPILE_ASSERT(kNullCid == kByteBufferCid + 1);
return (kNullCid - kTypedDataInt8ArrayCid);
}
} // namespace dart
#endif // VM_RAW_OBJECT_H_