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dart-sdk/runtime/vm/object.h
Martin Kustermann 430aa20a1f [vm/concurrency] Implement a fast transitive object copy for isolate message passing 
We use message passing as comunication mechanism between isolates.
The transitive closure of an object to be sent is currently serialized
into a snapshot form and deserialized on the receiver side. Furthermore
the receiver side will re-hash any linked hashmaps in that graph.

If isolate gropus are enabled we have all isolates in a group work on
the same heap. That removes the need to use an intermediate
serialization format. It also removes the need for an O(n) step on the
receiver side.

This CL implements a fast transitive object copy implementation and
makes use of it a message that is to be passed to another isolate stays
within the same isolate group.

In the common case the object graph will fit into new space. So the
copy algorithm will try to take advantage of it by having a fast path
and a fallback path. Both of them effectively copy the graph in BFS
order.

The algorithm works effectively like a scavenge operation, but instead
of first copying the from-object to the to-space and then re-writing the
object in to-space to forward the pointers (which requires us writing to
the to-space memory twice), we only reserve space for to-objects and
then initialize the to-objects to it's final contents, including
forwarded pointers (i.e. write the to-space object only once).

Compared with a scavenge operation (which stores forwarding pointers in
the objects themselves), we use a [WeakTable] to store them. This is the
only remaining expensive part of the algorithm and could be further
optimized. To avoid relying on iterating the to-space, we'll remember
[from, to] addresses.

=> All of this works inside a [NoSafepointOperationScope] and avoids
   usages of handles as well as write barriers.

While doing the transitive object copy, we'll share any object we can
safely share (canonical objects, strings, sendports, ...) instead of
copying it.

If the fast path fails (due to allocation failure or hitting) we'll
handlify any raw pointers and continue almost the same algorithm in a
safe way, where GC is possible at every object allocation site and
normal barriers are used for any stores of object pointers.

The copy algorithm uses templates to share the copy logic between the
fast and slow case (same copy routines can work on raw pointers as well
as handles).

There's a few special things to take into consideration:

  * If we copy a view on external typed data we need to know the
    external typed data address to compute the inner pointer of the
    view, so we'll eagerly initialize external typed data.

  * All external typed data needs to get a finalizer attached
    (irrespective if the object copy suceeds or not) to ensure the
    `malloc()`ed data is freed again.

  * Transferables will only be transferred on successful transitive
    copies. Also they need to attach finalizers to objects (which
    requires all objects be in handles).

  * We copy linked hashmaps as they are - instead of compressing the
    data by removing deleted entries. We may need to re-hash those
    hashmaps on the receiver side (similar to the snapshot-based copy
    approach) since new object graph will have no identity hash codes
    assigned to them. Though if the hashmaps only has sharable objects
    as keys (very common, e.g. json) there is no need for re-hashing.


It changes the SendPort.* benchmarks as follows:

```
Benchmark                                     |              default |                        IG |                  IG + FOC
----------------------------------------------------------------------------------------------------------------------------
SendPort.Send.Nop(RunTimeRaw):                |        0.25 us (1 x) |       0.26 us    (0.96 x) |       0.25 us    (1.00 x)
SendPort.Send.Json.400B(RunTimeRaw):          |        4.15 us (1 x) |       1.45 us    (2.86 x) |       1.05 us    (3.95 x)
SendPort.Send.Json.5KB(RunTimeRaw):           |       82.16 us (1 x) |      27.17 us    (3.02 x) |      18.32 us    (4.48 x)
SendPort.Send.Json.50KB(RunTimeRaw):          |      784.70 us (1 x) |     242.10 us    (3.24 x) |     165.50 us    (4.74 x)
SendPort.Send.Json.500KB(RunTimeRaw):         |     8510.4  us (1 x) |    3083.80 us    (2.76 x) |    2311.29 us    (3.68 x)
SendPort.Send.Json.5MB(RunTimeRaw):           |   122381.33 us (1 x) |   62959.40 us    (1.94 x) |   55492.10 us    (2.21 x)
SendPort.Send.BinaryTree.2(RunTimeRaw):       |        1.91 us (1 x) |       0.92 us    (2.08 x) |       0.72 us    (2.65 x)
SendPort.Send.BinaryTree.4(RunTimeRaw):       |        6.32 us (1 x) |       2.70 us    (2.34 x) |       2.10 us    (3.01 x)
SendPort.Send.BinaryTree.6(RunTimeRaw):       |       25.24 us (1 x) |      10.47 us    (2.41 x) |       8.61 us    (2.93 x)
SendPort.Send.BinaryTree.8(RunTimeRaw):       |      104.08 us (1 x) |      41.08 us    (2.53 x) |      33.51 us    (3.11 x)
SendPort.Send.BinaryTree.10(RunTimeRaw):      |      373.39 us (1 x) |     174.11 us    (2.14 x) |     134.75 us    (2.77 x)
SendPort.Send.BinaryTree.12(RunTimeRaw):      |     1588.64 us (1 x) |     893.18 us    (1.78 x) |     532.05 us    (2.99 x)
SendPort.Send.BinaryTree.14(RunTimeRaw):      |     6849.55 us (1 x) |    3705.19 us    (1.85 x) |    2507.90 us    (2.73 x)
SendPort.Receive.Nop(RunTimeRaw):             |        0.67 us (1 x) |       0.69 us    (0.97 x) |       0.68 us    (0.99 x)
SendPort.Receive.Json.400B(RunTimeRaw):       |        4.37 us (1 x) |       0.78 us    (5.60 x) |       0.77 us    (5.68 x)
SendPort.Receive.Json.5KB(RunTimeRaw):        |       45.67 us (1 x) |       0.90 us   (50.74 x) |       0.87 us   (52.49 x)
SendPort.Receive.Json.50KB(RunTimeRaw):       |      498.81 us (1 x) |       1.24 us  (402.27 x) |       1.06 us  (470.58 x)
SendPort.Receive.Json.500KB(RunTimeRaw):      |     5366.02 us (1 x) |       4.22 us (1271.57 x) |       4.65 us (1153.98 x)
SendPort.Receive.Json.5MB(RunTimeRaw):        |   101050.88 us (1 x) |      20.81 us (4855.88 x) |      21.0  us (4811.95 x)
SendPort.Receive.BinaryTree.2(RunTimeRaw):    |        3.91 us (1 x) |       0.76 us    (5.14 x) |       0.74 us    (5.28 x)
SendPort.Receive.BinaryTree.4(RunTimeRaw):    |        9.90 us (1 x) |       0.79 us   (12.53 x) |       0.76 us   (13.03 x)
SendPort.Receive.BinaryTree.6(RunTimeRaw):    |       33.09 us (1 x) |       0.87 us   (38.03 x) |       0.84 us   (39.39 x)
SendPort.Receive.BinaryTree.8(RunTimeRaw):    |      126.77 us (1 x) |       0.92 us  (137.79 x) |       0.88 us  (144.06 x)
SendPort.Receive.BinaryTree.10(RunTimeRaw):   |      533.09 us (1 x) |       0.94 us  (567.12 x) |       0.92 us  (579.45 x)
SendPort.Receive.BinaryTree.12(RunTimeRaw):   |     2223.23 us (1 x) |       3.03 us  (733.74 x) |       3.04 us  (731.33 x)
SendPort.Receive.BinaryTree.14(RunTimeRaw):   |     8945.66 us (1 x) |       4.03 us (2219.77 x) |       4.30 us (2080.39 x)
```

Issue https://github.com/dart-lang/sdk/issues/36097

TEST=vm/dart{,_2}/isolates/fast_object_copy{,2}_test

Change-Id: I835c59dab573d365b8a4b9d7c5359a6ea8d8b0a7
Reviewed-on: https://dart-review.googlesource.com/c/sdk/+/203776
Commit-Queue: Martin Kustermann <kustermann@google.com>
Reviewed-by: Ryan Macnak <rmacnak@google.com>
Reviewed-by: Slava Egorov <vegorov@google.com>
Reviewed-by: Alexander Aprelev <aam@google.com>
2021-07-13 19:04:20 +00:00

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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 RUNTIME_VM_OBJECT_H_
#define RUNTIME_VM_OBJECT_H_
#if defined(SHOULD_NOT_INCLUDE_RUNTIME)
#error "Should not include runtime"
#endif
#include <limits>
#include <tuple>
#include "include/dart_api.h"
#include "platform/assert.h"
#include "platform/atomic.h"
#include "platform/thread_sanitizer.h"
#include "platform/utils.h"
#include "vm/bitmap.h"
#include "vm/code_comments.h"
#include "vm/code_entry_kind.h"
#include "vm/compiler/assembler/object_pool_builder.h"
#include "vm/compiler/method_recognizer.h"
#include "vm/compiler/runtime_api.h"
#include "vm/dart.h"
#include "vm/flags.h"
#include "vm/globals.h"
#include "vm/growable_array.h"
#include "vm/handles.h"
#include "vm/heap/heap.h"
#include "vm/isolate.h"
#include "vm/json_stream.h"
#include "vm/os.h"
#include "vm/raw_object.h"
#include "vm/report.h"
#include "vm/static_type_exactness_state.h"
#include "vm/tags.h"
#include "vm/thread.h"
#include "vm/token_position.h"
namespace dart {
// Forward declarations.
namespace compiler {
class Assembler;
}
namespace kernel {
class Program;
class TreeNode;
} // namespace kernel
#define DEFINE_FORWARD_DECLARATION(clazz) class clazz;
CLASS_LIST(DEFINE_FORWARD_DECLARATION)
#undef DEFINE_FORWARD_DECLARATION
class Api;
class ArgumentsDescriptor;
class Closure;
class Code;
class DeoptInstr;
class DisassemblyFormatter;
class FinalizablePersistentHandle;
class FlowGraphCompiler;
class HierarchyInfo;
class LocalScope;
class CallSiteResetter;
class CodeStatistics;
class IsolateGroupReloadContext;
#define REUSABLE_FORWARD_DECLARATION(name) class Reusable##name##HandleScope;
REUSABLE_HANDLE_LIST(REUSABLE_FORWARD_DECLARATION)
#undef REUSABLE_FORWARD_DECLARATION
class Symbols;
class BaseTextBuffer;
#if defined(DEBUG)
#define CHECK_HANDLE() CheckHandle();
#else
#define CHECK_HANDLE()
#endif
// For AllStatic classes like OneByteString. Checks that
// ContainsCompressedPointers() returns the same value for AllStatic class and
// class used for handles.
#define ALLSTATIC_CONTAINS_COMPRESSED_IMPLEMENTATION(object, handle) \
static_assert(std::is_base_of<dart::handle##Ptr, dart::object##Ptr>::value, \
#object "Ptr must be a subtype of " #handle "Ptr"); \
static_assert(dart::handle::ContainsCompressedPointers() == \
dart::Untagged##object::kContainsCompressedPointers, \
"Pointer compression in Untagged" #object \
" must match pointer compression in Untagged" #handle); \
static constexpr bool ContainsCompressedPointers() { \
return dart::Untagged##object::kContainsCompressedPointers; \
}
#define BASE_OBJECT_IMPLEMENTATION(object, super) \
public: /* NOLINT */ \
using UntaggedObjectType = dart::Untagged##object; \
using ObjectPtrType = dart::object##Ptr; \
static_assert(!dart::super::ContainsCompressedPointers() || \
UntaggedObjectType::kContainsCompressedPointers, \
"Untagged" #object \
" must have compressed pointers, as supertype Untagged" #super \
" has compressed pointers"); \
static constexpr bool ContainsCompressedPointers() { \
return UntaggedObjectType::kContainsCompressedPointers; \
} \
object##Ptr ptr() const { return static_cast<object##Ptr>(ptr_); } \
bool Is##object() const { return true; } \
DART_NOINLINE static object& Handle() { \
return static_cast<object&>( \
HandleImpl(Thread::Current()->zone(), object::null(), kClassId)); \
} \
DART_NOINLINE static object& Handle(Zone* zone) { \
return static_cast<object&>(HandleImpl(zone, object::null(), kClassId)); \
} \
DART_NOINLINE static object& Handle(object##Ptr ptr) { \
return static_cast<object&>( \
HandleImpl(Thread::Current()->zone(), ptr, kClassId)); \
} \
DART_NOINLINE static object& Handle(Zone* zone, object##Ptr ptr) { \
return static_cast<object&>(HandleImpl(zone, ptr, kClassId)); \
} \
DART_NOINLINE static object& ZoneHandle() { \
return static_cast<object&>( \
ZoneHandleImpl(Thread::Current()->zone(), object::null(), kClassId)); \
} \
DART_NOINLINE static object& ZoneHandle(Zone* zone) { \
return static_cast<object&>( \
ZoneHandleImpl(zone, object::null(), kClassId)); \
} \
DART_NOINLINE static object& ZoneHandle(object##Ptr ptr) { \
return static_cast<object&>( \
ZoneHandleImpl(Thread::Current()->zone(), ptr, kClassId)); \
} \
DART_NOINLINE static object& ZoneHandle(Zone* zone, object##Ptr ptr) { \
return static_cast<object&>(ZoneHandleImpl(zone, ptr, kClassId)); \
} \
static object* ReadOnlyHandle() { \
return static_cast<object*>(ReadOnlyHandleImpl(kClassId)); \
} \
DART_NOINLINE static object& CheckedHandle(Zone* zone, ObjectPtr ptr) { \
object* obj = reinterpret_cast<object*>(VMHandles::AllocateHandle(zone)); \
initializeHandle(obj, ptr); \
if (!obj->Is##object()) { \
FATAL2("Handle check failed: saw %s expected %s", obj->ToCString(), \
#object); \
} \
return *obj; \
} \
DART_NOINLINE static object& CheckedZoneHandle(Zone* zone, ObjectPtr ptr) { \
object* obj = \
reinterpret_cast<object*>(VMHandles::AllocateZoneHandle(zone)); \
initializeHandle(obj, ptr); \
if (!obj->Is##object()) { \
FATAL2("Handle check failed: saw %s expected %s", obj->ToCString(), \
#object); \
} \
return *obj; \
} \
DART_NOINLINE static object& CheckedZoneHandle(ObjectPtr ptr) { \
return CheckedZoneHandle(Thread::Current()->zone(), ptr); \
} \
/* T::Cast cannot be applied to a null Object, because the object vtable */ \
/* is not setup for type T, although some methods are supposed to work */ \
/* with null, for example Instance::Equals(). */ \
static const object& Cast(const Object& obj) { \
ASSERT(obj.Is##object()); \
return reinterpret_cast<const object&>(obj); \
} \
static object##Ptr RawCast(ObjectPtr raw) { \
ASSERT(Object::Handle(raw).IsNull() || Object::Handle(raw).Is##object()); \
return static_cast<object##Ptr>(raw); \
} \
static object##Ptr null() { \
return static_cast<object##Ptr>(Object::null()); \
} \
virtual const char* ToCString() const; \
static const ClassId kClassId = k##object##Cid; \
\
private: /* NOLINT */ \
/* Initialize the handle based on the ptr in the presence of null. */ \
static void initializeHandle(object* obj, ObjectPtr ptr) { \
obj->SetPtr(ptr, kClassId); \
} \
/* Disallow allocation, copy constructors and override super assignment. */ \
public: /* NOLINT */ \
void operator delete(void* pointer) { UNREACHABLE(); } \
\
private: /* NOLINT */ \
void* operator new(size_t size); \
object(const object& value) = delete; \
void operator=(super##Ptr value) = delete; \
void operator=(const object& value) = delete; \
void operator=(const super& value) = delete;
// Conditionally include object_service.cc functionality in the vtable to avoid
// link errors like the following:
//
// object.o:(.rodata._ZTVN4....E[_ZTVN4...E]+0x278):
// undefined reference to
// `dart::Instance::PrintSharedInstanceJSON(dart::JSONObject*, bool) const'.
//
#ifndef PRODUCT
#define OBJECT_SERVICE_SUPPORT(object) \
protected: /* NOLINT */ \
/* Object is printed as JSON into stream. If ref is true only a header */ \
/* with an object id is printed. If ref is false the object is fully */ \
/* printed. */ \
virtual void PrintJSONImpl(JSONStream* stream, bool ref) const; \
virtual const char* JSONType() const { return "" #object; }
#else
#define OBJECT_SERVICE_SUPPORT(object) protected: /* NOLINT */
#endif // !PRODUCT
#define SNAPSHOT_READER_SUPPORT(object) \
static object##Ptr ReadFrom(SnapshotReader* reader, intptr_t object_id, \
intptr_t tags, Snapshot::Kind, \
bool as_reference); \
friend class SnapshotReader;
#define OBJECT_IMPLEMENTATION(object, super) \
public: /* NOLINT */ \
DART_NOINLINE void operator=(object##Ptr value) { \
initializeHandle(this, value); \
} \
DART_NOINLINE void operator^=(ObjectPtr value) { \
initializeHandle(this, value); \
ASSERT(IsNull() || Is##object()); \
} \
\
protected: /* NOLINT */ \
object() : super() {} \
BASE_OBJECT_IMPLEMENTATION(object, super) \
OBJECT_SERVICE_SUPPORT(object) \
friend class Object;
#define HEAP_OBJECT_IMPLEMENTATION(object, super) \
OBJECT_IMPLEMENTATION(object, super); \
Untagged##object* untag() const { \
ASSERT(ptr() != null()); \
return const_cast<Untagged##object*>(ptr()->untag()); \
} \
SNAPSHOT_READER_SUPPORT(object) \
friend class StackFrame; \
friend class Thread;
// This macro is used to denote types that do not have a sub-type.
#define FINAL_HEAP_OBJECT_IMPLEMENTATION_HELPER(object, rettype, super) \
public: /* NOLINT */ \
void operator=(object##Ptr value) { \
ptr_ = value; \
CHECK_HANDLE(); \
} \
void operator^=(ObjectPtr value) { \
ptr_ = value; \
CHECK_HANDLE(); \
} \
\
private: /* NOLINT */ \
object() : super() {} \
BASE_OBJECT_IMPLEMENTATION(object, super) \
OBJECT_SERVICE_SUPPORT(object) \
Untagged##object* untag() const { \
ASSERT(ptr() != null()); \
return const_cast<Untagged##object*>(ptr()->untag()); \
} \
static intptr_t NextFieldOffset() { return -kWordSize; } \
SNAPSHOT_READER_SUPPORT(rettype) \
friend class Object; \
friend class StackFrame; \
friend class Thread;
#define FINAL_HEAP_OBJECT_IMPLEMENTATION(object, super) \
FINAL_HEAP_OBJECT_IMPLEMENTATION_HELPER(object, object, super)
#define MINT_OBJECT_IMPLEMENTATION(object, rettype, super) \
FINAL_HEAP_OBJECT_IMPLEMENTATION_HELPER(object, rettype, super)
// In precompiled runtime, there is no access to runtime_api.cc since host
// and target are the same. In those cases, the namespace dart is used to refer
// to the target namespace
#if defined(DART_PRECOMPILED_RUNTIME)
namespace RTN = dart;
#else
namespace RTN = dart::compiler::target;
#endif // defined(DART_PRECOMPILED_RUNTIME)
class Object {
public:
using UntaggedObjectType = UntaggedObject;
using ObjectPtrType = ObjectPtr;
static ObjectPtr RawCast(ObjectPtr obj) { return obj; }
virtual ~Object() {}
static constexpr bool ContainsCompressedPointers() {
return UntaggedObject::kContainsCompressedPointers;
}
ObjectPtr ptr() const { return ptr_; }
void operator=(ObjectPtr value) { initializeHandle(this, value); }
bool IsCanonical() const { return ptr()->untag()->IsCanonical(); }
void SetCanonical() const { ptr()->untag()->SetCanonical(); }
void ClearCanonical() const { ptr()->untag()->ClearCanonical(); }
intptr_t GetClassId() const {
return !ptr()->IsHeapObject() ? static_cast<intptr_t>(kSmiCid)
: ptr()->untag()->GetClassId();
}
inline ClassPtr clazz() const;
static intptr_t tags_offset() { return OFFSET_OF(UntaggedObject, tags_); }
// Class testers.
#define DEFINE_CLASS_TESTER(clazz) \
virtual bool Is##clazz() const { return false; }
CLASS_LIST_FOR_HANDLES(DEFINE_CLASS_TESTER);
#undef DEFINE_CLASS_TESTER
bool IsNull() const { return ptr_ == null_; }
// Matches Object.toString on instances (except String::ToCString, bug 20583).
virtual const char* ToCString() const {
if (IsNull()) {
return "null";
} else {
return "Object";
}
}
#ifndef PRODUCT
void PrintJSON(JSONStream* stream, bool ref = true) const;
virtual void PrintJSONImpl(JSONStream* stream, bool ref) const;
virtual const char* JSONType() const { return IsNull() ? "null" : "Object"; }
#endif
// Returns the name that is used to identify an object in the
// namespace dictionary.
// Object::DictionaryName() returns String::null(). Only subclasses
// of Object that need to be entered in the library and library prefix
// namespaces need to provide an implementation.
virtual StringPtr DictionaryName() const;
bool IsNew() const { return ptr()->IsNewObject(); }
bool IsOld() const { return ptr()->IsOldObject(); }
#if defined(DEBUG)
bool InVMIsolateHeap() const;
#else
bool InVMIsolateHeap() const { return ptr()->untag()->InVMIsolateHeap(); }
#endif // DEBUG
// Print the object on stdout for debugging.
void Print() const;
bool IsZoneHandle() const {
return VMHandles::IsZoneHandle(reinterpret_cast<uword>(this));
}
bool IsReadOnlyHandle() const;
bool IsNotTemporaryScopedHandle() const;
static Object& Handle(Zone* zone, ObjectPtr ptr) {
Object* obj = reinterpret_cast<Object*>(VMHandles::AllocateHandle(zone));
initializeHandle(obj, ptr);
return *obj;
}
static Object* ReadOnlyHandle() {
Object* obj = reinterpret_cast<Object*>(Dart::AllocateReadOnlyHandle());
initializeHandle(obj, Object::null());
return obj;
}
static Object& Handle() { return Handle(Thread::Current()->zone(), null_); }
static Object& Handle(Zone* zone) { return Handle(zone, null_); }
static Object& Handle(ObjectPtr ptr) {
return Handle(Thread::Current()->zone(), ptr);
}
static Object& ZoneHandle(Zone* zone, ObjectPtr ptr) {
Object* obj =
reinterpret_cast<Object*>(VMHandles::AllocateZoneHandle(zone));
initializeHandle(obj, ptr);
return *obj;
}
static Object& ZoneHandle(Zone* zone) { return ZoneHandle(zone, null_); }
static Object& ZoneHandle() {
return ZoneHandle(Thread::Current()->zone(), null_);
}
static Object& ZoneHandle(ObjectPtr ptr) {
return ZoneHandle(Thread::Current()->zone(), ptr);
}
static ObjectPtr null() { return null_; }
#if defined(HASH_IN_OBJECT_HEADER)
static uint32_t GetCachedHash(const ObjectPtr obj) {
return obj->untag()->GetHeaderHash();
}
static uint32_t SetCachedHashIfNotSet(ObjectPtr obj, uint32_t hash) {
return obj->untag()->SetHeaderHashIfNotSet(hash);
}
#endif
// The list below enumerates read-only handles for singleton
// objects that are shared between the different isolates.
//
// - sentinel is a value that cannot be produced by Dart code. It can be used
// to mark special values, for example to distinguish "uninitialized" fields.
// - transition_sentinel is a value marking that we are transitioning from
// sentinel, e.g., computing a field value. Used to detect circular
// initialization.
// - unknown_constant and non_constant are optimizing compiler's constant
// propagation constants.
#define SHARED_READONLY_HANDLES_LIST(V) \
V(Object, null_object) \
V(Class, null_class) \
V(Array, null_array) \
V(String, null_string) \
V(Instance, null_instance) \
V(Function, null_function) \
V(FunctionType, null_function_type) \
V(TypeArguments, null_type_arguments) \
V(CompressedStackMaps, null_compressed_stackmaps) \
V(TypeArguments, empty_type_arguments) \
V(Array, empty_array) \
V(Array, zero_array) \
V(ContextScope, empty_context_scope) \
V(ObjectPool, empty_object_pool) \
V(CompressedStackMaps, empty_compressed_stackmaps) \
V(PcDescriptors, empty_descriptors) \
V(LocalVarDescriptors, empty_var_descriptors) \
V(ExceptionHandlers, empty_exception_handlers) \
V(Array, extractor_parameter_types) \
V(Array, extractor_parameter_names) \
V(Sentinel, sentinel) \
V(Sentinel, transition_sentinel) \
V(Sentinel, unknown_constant) \
V(Sentinel, non_constant) \
V(Bool, bool_true) \
V(Bool, bool_false) \
V(Smi, smi_illegal_cid) \
V(Smi, smi_zero) \
V(ApiError, typed_data_acquire_error) \
V(LanguageError, snapshot_writer_error) \
V(LanguageError, branch_offset_error) \
V(LanguageError, speculative_inlining_error) \
V(LanguageError, background_compilation_error) \
V(LanguageError, out_of_memory_error) \
V(Array, vm_isolate_snapshot_object_table) \
V(Type, dynamic_type) \
V(Type, void_type) \
V(AbstractType, null_abstract_type)
#define DEFINE_SHARED_READONLY_HANDLE_GETTER(Type, name) \
static const Type& name() { \
ASSERT(name##_ != nullptr); \
return *name##_; \
}
SHARED_READONLY_HANDLES_LIST(DEFINE_SHARED_READONLY_HANDLE_GETTER)
#undef DEFINE_SHARED_READONLY_HANDLE_GETTER
static void set_vm_isolate_snapshot_object_table(const Array& table);
static ClassPtr class_class() { return class_class_; }
static ClassPtr dynamic_class() { return dynamic_class_; }
static ClassPtr void_class() { return void_class_; }
static ClassPtr type_parameters_class() { return type_parameters_class_; }
static ClassPtr type_arguments_class() { return type_arguments_class_; }
static ClassPtr patch_class_class() { return patch_class_class_; }
static ClassPtr function_class() { return function_class_; }
static ClassPtr closure_data_class() { return closure_data_class_; }
static ClassPtr ffi_trampoline_data_class() {
return ffi_trampoline_data_class_;
}
static ClassPtr field_class() { return field_class_; }
static ClassPtr script_class() { return script_class_; }
static ClassPtr library_class() { return library_class_; }
static ClassPtr namespace_class() { return namespace_class_; }
static ClassPtr kernel_program_info_class() {
return kernel_program_info_class_;
}
static ClassPtr code_class() { return code_class_; }
static ClassPtr instructions_class() { return instructions_class_; }
static ClassPtr instructions_section_class() {
return instructions_section_class_;
}
static ClassPtr instructions_table_class() {
return instructions_table_class_;
}
static ClassPtr object_pool_class() { return object_pool_class_; }
static ClassPtr pc_descriptors_class() { return pc_descriptors_class_; }
static ClassPtr code_source_map_class() { return code_source_map_class_; }
static ClassPtr compressed_stackmaps_class() {
return compressed_stackmaps_class_;
}
static ClassPtr var_descriptors_class() { return var_descriptors_class_; }
static ClassPtr exception_handlers_class() {
return exception_handlers_class_;
}
static ClassPtr deopt_info_class() { return deopt_info_class_; }
static ClassPtr context_class() { return context_class_; }
static ClassPtr context_scope_class() { return context_scope_class_; }
static ClassPtr sentinel_class() { return sentinel_class_; }
static ClassPtr api_error_class() { return api_error_class_; }
static ClassPtr language_error_class() { return language_error_class_; }
static ClassPtr unhandled_exception_class() {
return unhandled_exception_class_;
}
static ClassPtr unwind_error_class() { return unwind_error_class_; }
static ClassPtr singletargetcache_class() { return singletargetcache_class_; }
static ClassPtr unlinkedcall_class() { return unlinkedcall_class_; }
static ClassPtr monomorphicsmiablecall_class() {
return monomorphicsmiablecall_class_;
}
static ClassPtr icdata_class() { return icdata_class_; }
static ClassPtr megamorphic_cache_class() { return megamorphic_cache_class_; }
static ClassPtr subtypetestcache_class() { return subtypetestcache_class_; }
static ClassPtr loadingunit_class() { return loadingunit_class_; }
static ClassPtr weak_serialization_reference_class() {
return weak_serialization_reference_class_;
}
// Initialize the VM isolate.
static void InitNullAndBool(IsolateGroup* isolate_group);
static void Init(IsolateGroup* isolate_group);
static void InitVtables();
static void FinishInit(IsolateGroup* isolate_group);
static void FinalizeVMIsolate(IsolateGroup* isolate_group);
static void FinalizeReadOnlyObject(ObjectPtr object);
static void Cleanup();
// Initialize a new isolate either from a Kernel IR, from source, or from a
// snapshot.
static ErrorPtr Init(IsolateGroup* isolate_group,
const uint8_t* kernel_buffer,
intptr_t kernel_buffer_size);
static void MakeUnusedSpaceTraversable(const Object& obj,
intptr_t original_size,
intptr_t used_size);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedObject));
}
template <class FakeObject>
static void VerifyBuiltinVtable(intptr_t cid) {
FakeObject fake;
if (cid >= kNumPredefinedCids) {
cid = kInstanceCid;
}
ASSERT(builtin_vtables_[cid] == fake.vtable());
}
static void VerifyBuiltinVtables();
static const ClassId kClassId = kObjectCid;
// Different kinds of name visibility.
enum NameVisibility {
// Internal names are the true names of classes, fields,
// etc. inside the vm. These names include privacy suffixes,
// getter prefixes, and trailing dots on unnamed constructors.
//
// The names of core implementation classes (like _OneByteString)
// are preserved as well.
//
// e.g.
// private getter -> get:foo@6be832b
// private constructor -> _MyClass@6b3832b.
// private named constructor -> _MyClass@6b3832b.named
// core impl class name shown -> _OneByteString
kInternalName = 0,
// Scrubbed names drop privacy suffixes, getter prefixes, and
// trailing dots on unnamed constructors. These names are used in
// the vm service.
//
// e.g.
// get:foo@6be832b -> foo
// _MyClass@6b3832b. -> _MyClass
// _MyClass@6b3832b.named -> _MyClass.named
// _OneByteString -> _OneByteString (not remapped)
kScrubbedName,
// User visible names are appropriate for reporting type errors
// directly to programmers. The names have been scrubbed and
// the names of core implementation classes are remapped to their
// public interface names.
//
// e.g.
// get:foo@6be832b -> foo
// _MyClass@6b3832b. -> _MyClass
// _MyClass@6b3832b.named -> _MyClass.named
// _OneByteString -> String (remapped)
kUserVisibleName
};
// Sometimes simple formating might produce the same name for two different
// entities, for example we might inject a synthetic forwarder into the
// class which has the same name as an already existing function, or
// two different types can be formatted as X<T> because T has different
// meaning (refers to a different type parameter) in these two types.
// Such ambiguity might be acceptable in some contexts but not in others, so
// some formatting methods have two modes - one which tries to be more
// user friendly, and another one which tries to avoid name conflicts by
// emitting longer and less user friendly names.
enum class NameDisambiguation {
kYes,
kNo,
};
protected:
friend ObjectPtr AllocateObject(intptr_t, intptr_t);
// Used for extracting the C++ vtable during bringup.
Object() : ptr_(null_) {}
uword raw_value() const { return static_cast<uword>(ptr()); }
inline void SetPtr(ObjectPtr value, intptr_t default_cid);
void CheckHandle() const;
DART_NOINLINE static Object& HandleImpl(Zone* zone,
ObjectPtr ptr,
intptr_t default_cid) {
Object* obj = reinterpret_cast<Object*>(VMHandles::AllocateHandle(zone));
obj->SetPtr(ptr, default_cid);
return *obj;
}
DART_NOINLINE static Object& ZoneHandleImpl(Zone* zone,
ObjectPtr ptr,
intptr_t default_cid) {
Object* obj =
reinterpret_cast<Object*>(VMHandles::AllocateZoneHandle(zone));
obj->SetPtr(ptr, default_cid);
return *obj;
}
DART_NOINLINE static Object* ReadOnlyHandleImpl(intptr_t cid) {
Object* obj = reinterpret_cast<Object*>(Dart::AllocateReadOnlyHandle());
obj->SetPtr(Object::null(), cid);
return obj;
}
cpp_vtable vtable() const { return bit_copy<cpp_vtable>(*this); }
void set_vtable(cpp_vtable value) { *vtable_address() = value; }
static ObjectPtr Allocate(intptr_t cls_id,
intptr_t size,
Heap::Space space,
bool compressed);
static intptr_t RoundedAllocationSize(intptr_t size) {
return Utils::RoundUp(size, kObjectAlignment);
}
bool Contains(uword addr) const { return ptr()->untag()->Contains(addr); }
// Start of field mutator guards.
//
// All writes to heap objects should ultimately pass through one of the
// methods below or their counterparts in RawObject, to ensure that the
// write barrier is correctly applied.
template <typename type, std::memory_order order = std::memory_order_relaxed>
type LoadPointer(type const* addr) const {
return ptr()->untag()->LoadPointer<type, order>(addr);
}
template <typename type, std::memory_order order = std::memory_order_relaxed>
void StorePointer(type const* addr, type value) const {
ptr()->untag()->StorePointer<type, order>(addr, value);
}
template <typename type,
typename compressed_type,
std::memory_order order = std::memory_order_relaxed>
void StoreCompressedPointer(compressed_type const* addr, type value) const {
ptr()->untag()->StoreCompressedPointer<type, compressed_type, order>(addr,
value);
}
// Use for storing into an explicitly Smi-typed field of an object
// (i.e., both the previous and new value are Smis).
void StoreSmi(SmiPtr const* addr, SmiPtr value) const {
ptr()->untag()->StoreSmi(addr, value);
}
template <typename FieldType>
void StoreSimd128(const FieldType* addr, simd128_value_t value) const {
ASSERT(Contains(reinterpret_cast<uword>(addr)));
value.writeTo(const_cast<FieldType*>(addr));
}
template <typename FieldType>
FieldType LoadNonPointer(const FieldType* addr) const {
return *const_cast<FieldType*>(addr);
}
template <typename FieldType, std::memory_order order>
FieldType LoadNonPointer(const FieldType* addr) const {
return reinterpret_cast<std::atomic<FieldType>*>(
const_cast<FieldType*>(addr))
->load(order);
}
// Needs two template arguments to allow assigning enums to fixed-size ints.
template <typename FieldType, typename ValueType>
void StoreNonPointer(const FieldType* addr, ValueType value) const {
// Can't use Contains, as it uses tags_, which is set through this method.
ASSERT(reinterpret_cast<uword>(addr) >= UntaggedObject::ToAddr(ptr()));
*const_cast<FieldType*>(addr) = value;
}
template <typename FieldType, typename ValueType, std::memory_order order>
void StoreNonPointer(const FieldType* addr, ValueType value) const {
// Can't use Contains, as it uses tags_, which is set through this method.
ASSERT(reinterpret_cast<uword>(addr) >= UntaggedObject::ToAddr(ptr()));
reinterpret_cast<std::atomic<FieldType>*>(const_cast<FieldType*>(addr))
->store(value, order);
}
// Provides non-const access to non-pointer fields within the object. Such
// access does not need a write barrier, but it is *not* GC-safe, since the
// object might move, hence must be fully contained within a NoSafepointScope.
template <typename FieldType>
FieldType* UnsafeMutableNonPointer(const FieldType* addr) const {
// Allow pointers at the end of variable-length data, and disallow pointers
// within the header word.
ASSERT(Contains(reinterpret_cast<uword>(addr) - 1) &&
Contains(reinterpret_cast<uword>(addr) - kWordSize));
// At least check that there is a NoSafepointScope and hope it's big enough.
ASSERT(Thread::Current()->no_safepoint_scope_depth() > 0);
return const_cast<FieldType*>(addr);
}
// Fail at link time if StoreNonPointer or UnsafeMutableNonPointer is
// instantiated with an object pointer type.
#define STORE_NON_POINTER_ILLEGAL_TYPE(type) \
template <typename ValueType> \
void StoreNonPointer(type##Ptr const* addr, ValueType value) const { \
UnimplementedMethod(); \
} \
type##Ptr* UnsafeMutableNonPointer(type##Ptr const* addr) const { \
UnimplementedMethod(); \
return NULL; \
}
CLASS_LIST(STORE_NON_POINTER_ILLEGAL_TYPE);
void UnimplementedMethod() const;
#undef STORE_NON_POINTER_ILLEGAL_TYPE
// Allocate an object and copy the body of 'orig'.
static ObjectPtr Clone(const Object& orig,
Heap::Space space,
bool load_with_relaxed_atomics = false);
// End of field mutator guards.
ObjectPtr ptr_; // The raw object reference.
protected:
void AddCommonObjectProperties(JSONObject* jsobj,
const char* protocol_type,
bool ref) const;
private:
static intptr_t NextFieldOffset() {
// Indicates this class cannot be extended by dart code.
return -kWordSize;
}
static void InitializeObject(uword address,
intptr_t id,
intptr_t size,
bool compressed);
static void RegisterClass(const Class& cls,
const String& name,
const Library& lib);
static void RegisterPrivateClass(const Class& cls,
const String& name,
const Library& lib);
/* Initialize the handle based on the ptr in the presence of null. */
static void initializeHandle(Object* obj, ObjectPtr ptr) {
obj->SetPtr(ptr, kObjectCid);
}
cpp_vtable* vtable_address() const {
uword vtable_addr = reinterpret_cast<uword>(this);
return reinterpret_cast<cpp_vtable*>(vtable_addr);
}
static cpp_vtable builtin_vtables_[kNumPredefinedCids];
// The static values below are singletons shared between the different
// isolates. They are all allocated in the non-GC'd Dart::vm_isolate_.
static ObjectPtr null_;
static BoolPtr true_;
static BoolPtr false_;
static ClassPtr class_class_; // Class of the Class vm object.
static ClassPtr dynamic_class_; // Class of the 'dynamic' type.
static ClassPtr void_class_; // Class of the 'void' type.
static ClassPtr type_parameters_class_; // Class of TypeParameters vm object.
static ClassPtr type_arguments_class_; // Class of TypeArguments vm object.
static ClassPtr patch_class_class_; // Class of the PatchClass vm object.
static ClassPtr function_class_; // Class of the Function vm object.
static ClassPtr closure_data_class_; // Class of ClosureData vm obj.
static ClassPtr ffi_trampoline_data_class_; // Class of FfiTrampolineData
// vm obj.
static ClassPtr field_class_; // Class of the Field vm object.
static ClassPtr script_class_; // Class of the Script vm object.
static ClassPtr library_class_; // Class of the Library vm object.
static ClassPtr namespace_class_; // Class of Namespace vm object.
static ClassPtr kernel_program_info_class_; // Class of KernelProgramInfo vm
// object.
static ClassPtr code_class_; // Class of the Code vm object.
static ClassPtr instructions_class_; // Class of the Instructions vm object.
static ClassPtr instructions_section_class_; // Class of InstructionsSection.
static ClassPtr instructions_table_class_; // Class of InstructionsTable.
static ClassPtr object_pool_class_; // Class of the ObjectPool vm object.
static ClassPtr pc_descriptors_class_; // Class of PcDescriptors vm object.
static ClassPtr code_source_map_class_; // Class of CodeSourceMap vm object.
static ClassPtr compressed_stackmaps_class_; // Class of CompressedStackMaps.
static ClassPtr var_descriptors_class_; // Class of LocalVarDescriptors.
static ClassPtr exception_handlers_class_; // Class of ExceptionHandlers.
static ClassPtr deopt_info_class_; // Class of DeoptInfo.
static ClassPtr context_class_; // Class of the Context vm object.
static ClassPtr context_scope_class_; // Class of ContextScope vm object.
static ClassPtr sentinel_class_; // Class of Sentinel vm object.
static ClassPtr singletargetcache_class_; // Class of SingleTargetCache.
static ClassPtr unlinkedcall_class_; // Class of UnlinkedCall.
static ClassPtr
monomorphicsmiablecall_class_; // Class of MonomorphicSmiableCall.
static ClassPtr icdata_class_; // Class of ICData.
static ClassPtr megamorphic_cache_class_; // Class of MegamorphiCache.
static ClassPtr subtypetestcache_class_; // Class of SubtypeTestCache.
static ClassPtr loadingunit_class_; // Class of LoadingUnit.
static ClassPtr api_error_class_; // Class of ApiError.
static ClassPtr language_error_class_; // Class of LanguageError.
static ClassPtr unhandled_exception_class_; // Class of UnhandledException.
static ClassPtr unwind_error_class_; // Class of UnwindError.
// Class of WeakSerializationReference.
static ClassPtr weak_serialization_reference_class_;
#define DECLARE_SHARED_READONLY_HANDLE(Type, name) static Type* name##_;
SHARED_READONLY_HANDLES_LIST(DECLARE_SHARED_READONLY_HANDLE)
#undef DECLARE_SHARED_READONLY_HANDLE
friend void ClassTable::Register(const Class& cls);
friend void UntaggedObject::Validate(IsolateGroup* isolate_group) const;
friend class Closure;
friend class SnapshotReader;
friend class InstanceDeserializationCluster;
friend class OneByteString;
friend class TwoByteString;
friend class ExternalOneByteString;
friend class ExternalTwoByteString;
friend class Thread;
#define REUSABLE_FRIEND_DECLARATION(name) \
friend class Reusable##name##HandleScope;
REUSABLE_HANDLE_LIST(REUSABLE_FRIEND_DECLARATION)
#undef REUSABLE_FRIEND_DECLARATION
DISALLOW_ALLOCATION();
DISALLOW_COPY_AND_ASSIGN(Object);
};
#if defined(DART_PRECOMPILER)
#define PRECOMPILER_WSR_FIELD_DECLARATION(Type, Name) \
Type##Ptr Name() const; \
void set_##Name(const Object& value) const { \
untag()->set_##Name(value.ptr()); \
}
#else
#define PRECOMPILER_WSR_FIELD_DECLARATION(Type, Name) \
Type##Ptr Name() const { return untag()->Name(); } \
void set_##Name(const Type& value) const;
#endif
class PassiveObject : public Object {
public:
void operator=(ObjectPtr value) { ptr_ = value; }
void operator^=(ObjectPtr value) { ptr_ = value; }
static PassiveObject& Handle(Zone* zone, ObjectPtr ptr) {
PassiveObject* obj =
reinterpret_cast<PassiveObject*>(VMHandles::AllocateHandle(zone));
obj->ptr_ = ptr;
obj->set_vtable(0);
return *obj;
}
static PassiveObject& Handle(ObjectPtr ptr) {
return Handle(Thread::Current()->zone(), ptr);
}
static PassiveObject& Handle() {
return Handle(Thread::Current()->zone(), Object::null());
}
static PassiveObject& Handle(Zone* zone) {
return Handle(zone, Object::null());
}
static PassiveObject& ZoneHandle(Zone* zone, ObjectPtr ptr) {
PassiveObject* obj =
reinterpret_cast<PassiveObject*>(VMHandles::AllocateZoneHandle(zone));
obj->ptr_ = ptr;
obj->set_vtable(0);
return *obj;
}
static PassiveObject& ZoneHandle(ObjectPtr ptr) {
return ZoneHandle(Thread::Current()->zone(), ptr);
}
static PassiveObject& ZoneHandle() {
return ZoneHandle(Thread::Current()->zone(), Object::null());
}
static PassiveObject& ZoneHandle(Zone* zone) {
return ZoneHandle(zone, Object::null());
}
private:
PassiveObject() : Object() {}
DISALLOW_ALLOCATION();
DISALLOW_COPY_AND_ASSIGN(PassiveObject);
};
typedef ZoneGrowableHandlePtrArray<const AbstractType> Trail;
typedef ZoneGrowableHandlePtrArray<const AbstractType>* TrailPtr;
// A URIs array contains triplets of strings.
// The first string in the triplet is a type name (usually a class).
// The second string in the triplet is the URI of the type.
// The third string in the triplet is "print" if the triplet should be printed.
typedef ZoneGrowableHandlePtrArray<const String> URIs;
enum class Nullability : uint8_t {
kNullable = 0,
kNonNullable = 1,
kLegacy = 2,
// Adjust kNullabilityBitSize in clustered_snapshot.cc if adding new values.
};
// Equality kind between types.
enum class TypeEquality {
kCanonical = 0,
kSyntactical = 1,
kInSubtypeTest = 2,
};
// The NNBDMode reflects the opted-in status of libraries.
// Note that the weak or strong checking mode is not reflected in NNBDMode.
enum class NNBDMode {
// Status of the library:
kLegacyLib = 0, // Library is legacy.
kOptedInLib = 1, // Library is opted-in.
};
// The NNBDCompiledMode reflects the mode in which constants of the library were
// compiled by CFE.
enum class NNBDCompiledMode {
kWeak = 0,
kStrong = 1,
kAgnostic = 2,
kInvalid = 3,
};
class Class : public Object {
public:
enum InvocationDispatcherEntry {
kInvocationDispatcherName,
kInvocationDispatcherArgsDesc,
kInvocationDispatcherFunction,
kInvocationDispatcherEntrySize,
};
bool HasCompressedPointers() const;
intptr_t host_instance_size() const {
ASSERT(is_finalized() || is_prefinalized());
return (untag()->host_instance_size_in_words_ * kCompressedWordSize);
}
intptr_t target_instance_size() const {
ASSERT(is_finalized() || is_prefinalized());
#if defined(DART_PRECOMPILER)
return (untag()->target_instance_size_in_words_ *
compiler::target::kCompressedWordSize);
#else
return host_instance_size();
#endif // defined(DART_PRECOMPILER)
}
static intptr_t host_instance_size(ClassPtr clazz) {
return (clazz->untag()->host_instance_size_in_words_ * kCompressedWordSize);
}
static intptr_t target_instance_size(ClassPtr clazz) {
#if defined(DART_PRECOMPILER)
return (clazz->untag()->target_instance_size_in_words_ *
compiler::target::kCompressedWordSize);
#else
return host_instance_size(clazz);
#endif // defined(DART_PRECOMPILER)
}
void set_instance_size(intptr_t host_value_in_bytes,
intptr_t target_value_in_bytes) const {
ASSERT(kCompressedWordSize != 0);
set_instance_size_in_words(
host_value_in_bytes / kCompressedWordSize,
target_value_in_bytes / compiler::target::kCompressedWordSize);
}
void set_instance_size_in_words(intptr_t host_value,
intptr_t target_value) const {
ASSERT(
Utils::IsAligned((host_value * kCompressedWordSize), kObjectAlignment));
StoreNonPointer(&untag()->host_instance_size_in_words_, host_value);
#if defined(DART_PRECOMPILER)
ASSERT(
Utils::IsAligned((target_value * compiler::target::kCompressedWordSize),
compiler::target::kObjectAlignment));
StoreNonPointer(&untag()->target_instance_size_in_words_, target_value);
#else
// Could be different only during cross-compilation.
ASSERT_EQUAL(host_value, target_value);
#endif // defined(DART_PRECOMPILER)
}
intptr_t host_next_field_offset() const {
return untag()->host_next_field_offset_in_words_ * kCompressedWordSize;
}
intptr_t target_next_field_offset() const {
#if defined(DART_PRECOMPILER)
return untag()->target_next_field_offset_in_words_ *
compiler::target::kCompressedWordSize;
#else
return host_next_field_offset();
#endif // defined(DART_PRECOMPILER)
}
void set_next_field_offset(intptr_t host_value_in_bytes,
intptr_t target_value_in_bytes) const {
set_next_field_offset_in_words(
host_value_in_bytes / kCompressedWordSize,
target_value_in_bytes / compiler::target::kCompressedWordSize);
}
void set_next_field_offset_in_words(intptr_t host_value,
intptr_t target_value) const {
// Assert that the next field offset is either negative (ie, this object
// can't be extended by dart code), or rounds up to the kObjectAligned
// instance size.
ASSERT((host_value < 0) ||
((host_value <= untag()->host_instance_size_in_words_) &&
(host_value + (kObjectAlignment / kCompressedWordSize) >
untag()->host_instance_size_in_words_)));
StoreNonPointer(&untag()->host_next_field_offset_in_words_, host_value);
#if defined(DART_PRECOMPILER)
ASSERT((target_value < 0) ||
((target_value <= untag()->target_instance_size_in_words_) &&
(target_value + (compiler::target::kObjectAlignment /
compiler::target::kCompressedWordSize) >
untag()->target_instance_size_in_words_)));
StoreNonPointer(&untag()->target_next_field_offset_in_words_, target_value);
#else
// Could be different only during cross-compilation.
ASSERT_EQUAL(host_value, target_value);
#endif // defined(DART_PRECOMPILER)
}
static bool is_valid_id(intptr_t value) {
return UntaggedObject::ClassIdTag::is_valid(value);
}
intptr_t id() const { return untag()->id_; }
void set_id(intptr_t value) const {
ASSERT(value >= 0 && value < std::numeric_limits<classid_t>::max());
StoreNonPointer(&untag()->id_, value);
}
static intptr_t id_offset() { return OFFSET_OF(UntaggedClass, id_); }
static intptr_t num_type_arguments_offset() {
return OFFSET_OF(UntaggedClass, num_type_arguments_);
}
StringPtr Name() const;
StringPtr ScrubbedName() const;
const char* ScrubbedNameCString() const;
StringPtr UserVisibleName() const;
const char* UserVisibleNameCString() const;
const char* NameCString(NameVisibility name_visibility) const;
// The mixin for this class if one exists. Otherwise, returns a raw pointer
// to this class.
ClassPtr Mixin() const;
// The NNBD mode of the library declaring this class.
NNBDMode nnbd_mode() const;
bool IsInFullSnapshot() const;
virtual StringPtr DictionaryName() const { return Name(); }
ScriptPtr script() const { return untag()->script(); }
void set_script(const Script& value) const;
TokenPosition token_pos() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return TokenPosition::kNoSource;
#else
return untag()->token_pos_;
#endif // defined(DART_PRECOMPILED_RUNTIME)
}
#if !defined(DART_PRECOMPILED_RUNTIME)
void set_token_pos(TokenPosition value) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
TokenPosition end_token_pos() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return TokenPosition::kNoSource;
#else
return untag()->end_token_pos_;
#endif // defined(DART_PRECOMPILED_RUNTIME)
}
#if !defined(DART_PRECOMPILED_RUNTIME)
void set_end_token_pos(TokenPosition value) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
int32_t SourceFingerprint() const;
// Return the Type with type parameters declared by this class filled in with
// dynamic and type parameters declared in superclasses filled in as declared
// in superclass clauses.
AbstractTypePtr RareType() const;
// Return the Type whose arguments are the type parameters declared by this
// class preceded by the type arguments declared for superclasses, etc.
// e.g. given
// class B<T, S>
// class C<R> extends B<R, int>
// C.DeclarationType() --> C [R, int, R]
// The declaration type's nullability is either legacy or non-nullable when
// the non-nullable experiment is enabled.
TypePtr DeclarationType() const;
static intptr_t declaration_type_offset() {
return OFFSET_OF(UntaggedClass, declaration_type_);
}
LibraryPtr library() const { return untag()->library(); }
void set_library(const Library& value) const;
// The formal type parameters and their bounds (no defaults), are specified as
// an object of type TypeParameters.
TypeParametersPtr type_parameters() const {
ASSERT(is_declaration_loaded());
return untag()->type_parameters();
}
void set_type_parameters(const TypeParameters& value) const;
intptr_t NumTypeParameters(Thread* thread) const;
intptr_t NumTypeParameters() const {
return NumTypeParameters(Thread::Current());
}
// Return the type parameter declared at index.
TypeParameterPtr TypeParameterAt(
intptr_t index,
Nullability nullability = Nullability::kNonNullable) const;
// The type argument vector is flattened and includes the type arguments of
// the super class.
intptr_t NumTypeArguments() const;
// Return true if this class declares type parameters.
bool IsGeneric() const { return NumTypeParameters(Thread::Current()) > 0; }
// Returns a canonicalized vector of the type parameters instantiated
// to bounds. If non-generic, the empty type arguments vector is returned.
TypeArgumentsPtr InstantiateToBounds(Thread* thread) const;
// If this class is parameterized, each instance has a type_arguments field.
static const intptr_t kNoTypeArguments = -1;
intptr_t host_type_arguments_field_offset() const {
ASSERT(is_type_finalized() || is_prefinalized());
if (untag()->host_type_arguments_field_offset_in_words_ ==
kNoTypeArguments) {
return kNoTypeArguments;
}
return untag()->host_type_arguments_field_offset_in_words_ *
kCompressedWordSize;
}
intptr_t target_type_arguments_field_offset() const {
#if defined(DART_PRECOMPILER)
ASSERT(is_type_finalized() || is_prefinalized());
if (untag()->target_type_arguments_field_offset_in_words_ ==
compiler::target::Class::kNoTypeArguments) {
return compiler::target::Class::kNoTypeArguments;
}
return untag()->target_type_arguments_field_offset_in_words_ *
compiler::target::kCompressedWordSize;
#else
return host_type_arguments_field_offset();
#endif // defined(DART_PRECOMPILER)
}
void set_type_arguments_field_offset(intptr_t host_value_in_bytes,
intptr_t target_value_in_bytes) const {
intptr_t host_value, target_value;
if (host_value_in_bytes == kNoTypeArguments ||
target_value_in_bytes == RTN::Class::kNoTypeArguments) {
ASSERT(host_value_in_bytes == kNoTypeArguments &&
target_value_in_bytes == RTN::Class::kNoTypeArguments);
host_value = kNoTypeArguments;
target_value = RTN::Class::kNoTypeArguments;
} else {
ASSERT(kCompressedWordSize != 0 && compiler::target::kCompressedWordSize);
host_value = host_value_in_bytes / kCompressedWordSize;
target_value =
target_value_in_bytes / compiler::target::kCompressedWordSize;
}
set_type_arguments_field_offset_in_words(host_value, target_value);
}
void set_type_arguments_field_offset_in_words(intptr_t host_value,
intptr_t target_value) const {
StoreNonPointer(&untag()->host_type_arguments_field_offset_in_words_,
host_value);
#if defined(DART_PRECOMPILER)
StoreNonPointer(&untag()->target_type_arguments_field_offset_in_words_,
target_value);
#else
// Could be different only during cross-compilation.
ASSERT_EQUAL(host_value, target_value);
#endif // defined(DART_PRECOMPILER)
}
static intptr_t host_type_arguments_field_offset_in_words_offset() {
return OFFSET_OF(UntaggedClass, host_type_arguments_field_offset_in_words_);
}
// The super type of this class, Object type if not explicitly specified.
AbstractTypePtr super_type() const {
ASSERT(is_declaration_loaded());
return untag()->super_type();
}
void set_super_type(const AbstractType& value) const;
static intptr_t super_type_offset() {
return OFFSET_OF(UntaggedClass, super_type_);
}
// Asserts that the class of the super type has been resolved.
// |original_classes| only has an effect when reloading. If true and we
// are reloading, it will prefer the original classes to the replacement
// classes.
ClassPtr SuperClass(bool original_classes = false) const;
// Interfaces is an array of Types.
ArrayPtr interfaces() const {
ASSERT(is_declaration_loaded());
return untag()->interfaces();
}
void set_interfaces(const Array& value) const;
#if !defined(PRODUCT) || !defined(DART_PRECOMPILED_RUNTIME)
// Returns the list of classes directly implementing this class.
GrowableObjectArrayPtr direct_implementors() const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadReader());
return untag()->direct_implementors();
}
GrowableObjectArrayPtr direct_implementors_unsafe() const {
return untag()->direct_implementors();
}
#endif // !defined(PRODUCT) || !defined(DART_PRECOMPILED_RUNTIME)
#if !defined(DART_PRECOMPILED_RUNTIME)
void set_direct_implementors(const GrowableObjectArray& implementors) const;
void AddDirectImplementor(const Class& subclass, bool is_mixin) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
#if !defined(PRODUCT) || !defined(DART_PRECOMPILED_RUNTIME)
// Returns the list of classes having this class as direct superclass.
GrowableObjectArrayPtr direct_subclasses() const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadReader());
return direct_subclasses_unsafe();
}
GrowableObjectArrayPtr direct_subclasses_unsafe() const {
return untag()->direct_subclasses();
}
#endif // !defined(PRODUCT) || !defined(DART_PRECOMPILED_RUNTIME)
#if !defined(DART_PRECOMPILED_RUNTIME)
void set_direct_subclasses(const GrowableObjectArray& subclasses) const;
void AddDirectSubclass(const Class& subclass) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
// Check if this class represents the class of null.
bool IsNullClass() const { return id() == kNullCid; }
// Check if this class represents the 'dynamic' class.
bool IsDynamicClass() const { return id() == kDynamicCid; }
// Check if this class represents the 'void' class.
bool IsVoidClass() const { return id() == kVoidCid; }
// Check if this class represents the 'Never' class.
bool IsNeverClass() const { return id() == kNeverCid; }
// Check if this class represents the 'Object' class.
bool IsObjectClass() const { return id() == kInstanceCid; }
// Check if this class represents the 'Function' class.
bool IsDartFunctionClass() const;
// Check if this class represents the 'Future' class.
bool IsFutureClass() const;
// Check if this class represents the 'FutureOr' class.
bool IsFutureOrClass() const { return id() == kFutureOrCid; }
// Check if this class represents the 'Closure' class.
bool IsClosureClass() const { return id() == kClosureCid; }
static bool IsClosureClass(ClassPtr cls) {
NoSafepointScope no_safepoint;
return cls->untag()->id_ == kClosureCid;
}
static bool IsInFullSnapshot(ClassPtr cls) {
NoSafepointScope no_safepoint;
return UntaggedLibrary::InFullSnapshotBit::decode(
cls->untag()->library()->untag()->flags_);
}
// Returns true if the type specified by cls, type_arguments, and nullability
// is a subtype of the other type.
static bool IsSubtypeOf(const Class& cls,
const TypeArguments& type_arguments,
Nullability nullability,
const AbstractType& other,
Heap::Space space,
TrailPtr trail = nullptr);
// Check if this is the top level class.
bool IsTopLevel() const;
bool IsPrivate() const;
DART_WARN_UNUSED_RESULT
ErrorPtr VerifyEntryPoint() const;
// Returns an array of instance and static fields defined by this class.
ArrayPtr fields() const {
// We rely on the fact that any loads from the array are dependent loads
// and avoid the load-acquire barrier here.
return untag()->fields();
}
void SetFields(const Array& value) const;
void AddField(const Field& field) const;
void AddFields(const GrowableArray<const Field*>& fields) const;
// If this is a dart:internal.ClassID class, then inject our own const
// fields. Returns true if synthetic fields are injected and regular
// field declarations should be ignored.
bool InjectCIDFields() const;
// Returns an array of all instance fields of this class and its superclasses
// indexed by offset in words.
// |original_classes| only has an effect when reloading. If true and we
// are reloading, it will prefer the original classes to the replacement
// classes.
ArrayPtr OffsetToFieldMap(bool original_classes = false) const;
// Returns true if non-static fields are defined.
bool HasInstanceFields() const;
ArrayPtr current_functions() const {
// We rely on the fact that any loads from the array are dependent loads
// and avoid the load-acquire barrier here.
return untag()->functions();
}
ArrayPtr functions() const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadReader());
return current_functions();
}
void SetFunctions(const Array& value) const;
void AddFunction(const Function& function) const;
FunctionPtr FunctionFromIndex(intptr_t idx) const;
intptr_t FindImplicitClosureFunctionIndex(const Function& needle) const;
FunctionPtr ImplicitClosureFunctionFromIndex(intptr_t idx) const;
FunctionPtr LookupFunctionReadLocked(const String& name) const;
FunctionPtr LookupDynamicFunctionUnsafe(const String& name) const;
FunctionPtr LookupDynamicFunctionAllowPrivate(const String& name) const;
FunctionPtr LookupStaticFunction(const String& name) const;
FunctionPtr LookupStaticFunctionAllowPrivate(const String& name) const;
FunctionPtr LookupConstructor(const String& name) const;
FunctionPtr LookupConstructorAllowPrivate(const String& name) const;
FunctionPtr LookupFactory(const String& name) const;
FunctionPtr LookupFactoryAllowPrivate(const String& name) const;
FunctionPtr LookupFunctionAllowPrivate(const String& name) const;
FunctionPtr LookupGetterFunction(const String& name) const;
FunctionPtr LookupSetterFunction(const String& name) const;
FieldPtr LookupInstanceField(const String& name) const;
FieldPtr LookupStaticField(const String& name) const;
FieldPtr LookupField(const String& name) const;
FieldPtr LookupFieldAllowPrivate(const String& name,
bool instance_only = false) const;
FieldPtr LookupInstanceFieldAllowPrivate(const String& name) const;
FieldPtr LookupStaticFieldAllowPrivate(const String& name) const;
DoublePtr LookupCanonicalDouble(Zone* zone, double value) const;
MintPtr LookupCanonicalMint(Zone* zone, int64_t value) const;
// The methods above are more efficient than this generic one.
InstancePtr LookupCanonicalInstance(Zone* zone, const Instance& value) const;
InstancePtr InsertCanonicalConstant(Zone* zone,
const Instance& constant) const;
void InsertCanonicalDouble(Zone* zone, const Double& constant) const;
void InsertCanonicalMint(Zone* zone, const Mint& constant) const;
void RehashConstants(Zone* zone) const;
bool RequireCanonicalTypeErasureOfConstants(Zone* zone) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedClass));
}
bool is_implemented() const { return ImplementedBit::decode(state_bits()); }
void set_is_implemented() const;
void set_is_implemented_unsafe() const;
bool is_abstract() const { return AbstractBit::decode(state_bits()); }
void set_is_abstract() const;
UntaggedClass::ClassLoadingState class_loading_state() const {
return ClassLoadingBits::decode(state_bits());
}
bool is_declaration_loaded() const {
return class_loading_state() >= UntaggedClass::kDeclarationLoaded;
}
void set_is_declaration_loaded() const;
void set_is_declaration_loaded_unsafe() const;
bool is_type_finalized() const {
return class_loading_state() >= UntaggedClass::kTypeFinalized;
}
void set_is_type_finalized() const;
bool is_synthesized_class() const {
return SynthesizedClassBit::decode(state_bits());
}
void set_is_synthesized_class() const;
void set_is_synthesized_class_unsafe() const;
bool is_enum_class() const { return EnumBit::decode(state_bits()); }
void set_is_enum_class() const;
bool is_finalized() const {
return ClassFinalizedBits::decode(state_bits()) ==
UntaggedClass::kFinalized ||
ClassFinalizedBits::decode(state_bits()) ==
UntaggedClass::kAllocateFinalized;
}
void set_is_finalized() const;
void set_is_finalized_unsafe() const;
bool is_allocate_finalized() const {
return ClassFinalizedBits::decode(state_bits()) ==
UntaggedClass::kAllocateFinalized;
}
void set_is_allocate_finalized() const;
bool is_prefinalized() const {
return ClassFinalizedBits::decode(state_bits()) ==
UntaggedClass::kPreFinalized;
}
void set_is_prefinalized() const;
bool is_const() const { return ConstBit::decode(state_bits()); }
void set_is_const() const;
// Tests if this is a mixin application class which was desugared
// to a normal class by kernel mixin transformation
// (pkg/kernel/lib/transformations/mixin_full_resolution.dart).
//
// In such case, its mixed-in type was pulled into the end of
// interfaces list.
bool is_transformed_mixin_application() const {
return TransformedMixinApplicationBit::decode(state_bits());
}
void set_is_transformed_mixin_application() const;
bool is_fields_marked_nullable() const {
return FieldsMarkedNullableBit::decode(state_bits());
}
void set_is_fields_marked_nullable() const;
bool is_allocated() const { return IsAllocatedBit::decode(state_bits()); }
void set_is_allocated(bool value) const;
void set_is_allocated_unsafe(bool value) const;
bool is_loaded() const { return IsLoadedBit::decode(state_bits()); }
void set_is_loaded(bool value) const;
uint16_t num_native_fields() const { return untag()->num_native_fields_; }
void set_num_native_fields(uint16_t value) const {
StoreNonPointer(&untag()->num_native_fields_, value);
}
static uint16_t NumNativeFieldsOf(ClassPtr clazz) {
return clazz->untag()->num_native_fields_;
}
#if !defined(DART_PRECOMPILED_RUNTIME)
CodePtr allocation_stub() const { return untag()->allocation_stub(); }
void set_allocation_stub(const Code& value) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
intptr_t kernel_offset() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return 0;
#else
return untag()->kernel_offset_;
#endif
}
void set_kernel_offset(intptr_t value) const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
#else
ASSERT(value >= 0);
StoreNonPointer(&untag()->kernel_offset_, value);
#endif
}
void DisableAllocationStub() const;
ArrayPtr constants() const;
void set_constants(const Array& value) const;
intptr_t FindInvocationDispatcherFunctionIndex(const Function& needle) const;
FunctionPtr InvocationDispatcherFunctionFromIndex(intptr_t idx) const;
FunctionPtr GetInvocationDispatcher(const String& target_name,
const Array& args_desc,
UntaggedFunction::Kind kind,
bool create_if_absent) const;
void Finalize() const;
ObjectPtr Invoke(const String& selector,
const Array& arguments,
const Array& argument_names,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
ObjectPtr InvokeGetter(const String& selector,
bool throw_nsm_if_absent,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
ObjectPtr InvokeSetter(const String& selector,
const Instance& argument,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
// Evaluate the given expression as if it appeared in a static method of this
// class and return the resulting value, or an error object if evaluating the
// expression fails. The method has the formal (type) parameters given in
// (type_)param_names, and is invoked with the (type)argument values given in
// (type_)param_values.
ObjectPtr EvaluateCompiledExpression(
const ExternalTypedData& kernel_buffer,
const Array& type_definitions,
const Array& param_values,
const TypeArguments& type_param_values) const;
// Load class declaration (super type, interfaces, type parameters and
// number of type arguments) if it is not loaded yet.
void EnsureDeclarationLoaded() const;
ErrorPtr EnsureIsFinalized(Thread* thread) const;
ErrorPtr EnsureIsAllocateFinalized(Thread* thread) const;
// Allocate a class used for VM internal objects.
template <class FakeObject, class TargetFakeObject>
static ClassPtr New(IsolateGroup* isolate_group, bool register_class = true);
// Allocate instance classes.
static ClassPtr New(const Library& lib,
const String& name,
const Script& script,
TokenPosition token_pos,
bool register_class = true);
static ClassPtr NewNativeWrapper(const Library& library,
const String& name,
int num_fields);
// Allocate the raw string classes.
static ClassPtr NewStringClass(intptr_t class_id,
IsolateGroup* isolate_group);
// Allocate the raw TypedData classes.
static ClassPtr NewTypedDataClass(intptr_t class_id,
IsolateGroup* isolate_group);
// Allocate the raw TypedDataView/ByteDataView classes.
static ClassPtr NewTypedDataViewClass(intptr_t class_id,
IsolateGroup* isolate_group);
// Allocate the raw ExternalTypedData classes.
static ClassPtr NewExternalTypedDataClass(intptr_t class_id,
IsolateGroup* isolate);
// Allocate the raw Pointer classes.
static ClassPtr NewPointerClass(intptr_t class_id,
IsolateGroup* isolate_group);
#if !defined(DART_PRECOMPILED_RUNTIME)
// Register code that has used CHA for optimization.
// TODO(srdjan): Also register kind of CHA optimization (e.g.: leaf class,
// leaf method, ...).
void RegisterCHACode(const Code& code);
void DisableCHAOptimizedCode(const Class& subclass);
void DisableAllCHAOptimizedCode();
void DisableCHAImplementorUsers() { DisableAllCHAOptimizedCode(); }
// Return the list of code objects that were compiled using CHA of this class.
// These code objects will be invalidated if new subclasses of this class
// are finalized.
ArrayPtr dependent_code() const;
void set_dependent_code(const Array& array) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
bool TraceAllocation(IsolateGroup* isolate_group) const;
void SetTraceAllocation(bool trace_allocation) const;
void ReplaceEnum(ProgramReloadContext* reload_context,
const Class& old_enum) const;
void CopyStaticFieldValues(ProgramReloadContext* reload_context,
const Class& old_cls) const;
void PatchFieldsAndFunctions() const;
void MigrateImplicitStaticClosures(ProgramReloadContext* context,
const Class& new_cls) const;
void CopyCanonicalConstants(const Class& old_cls) const;
void CopyDeclarationType(const Class& old_cls) const;
void CheckReload(const Class& replacement,
ProgramReloadContext* context) const;
void AddInvocationDispatcher(const String& target_name,
const Array& args_desc,
const Function& dispatcher) const;
static int32_t host_instance_size_in_words(const ClassPtr cls) {
return cls->untag()->host_instance_size_in_words_;
}
static int32_t target_instance_size_in_words(const ClassPtr cls) {
#if defined(DART_PRECOMPILER)
return cls->untag()->target_instance_size_in_words_;
#else
return host_instance_size_in_words(cls);
#endif // defined(DART_PRECOMPILER)
}
static int32_t host_next_field_offset_in_words(const ClassPtr cls) {
return cls->untag()->host_next_field_offset_in_words_;
}
static int32_t target_next_field_offset_in_words(const ClassPtr cls) {
#if defined(DART_PRECOMPILER)
return cls->untag()->target_next_field_offset_in_words_;
#else
return host_next_field_offset_in_words(cls);
#endif // defined(DART_PRECOMPILER)
}
static int32_t host_type_arguments_field_offset_in_words(const ClassPtr cls) {
return cls->untag()->host_type_arguments_field_offset_in_words_;
}
static int32_t target_type_arguments_field_offset_in_words(
const ClassPtr cls) {
#if defined(DART_PRECOMPILER)
return cls->untag()->target_type_arguments_field_offset_in_words_;
#else
return host_type_arguments_field_offset_in_words(cls);
#endif // defined(DART_PRECOMPILER)
}
private:
TypePtr declaration_type() const {
return untag()->declaration_type<std::memory_order_acquire>();
}
// Caches the declaration type of this class.
void set_declaration_type(const Type& type) const;
bool CanReloadFinalized(const Class& replacement,
ProgramReloadContext* context) const;
bool CanReloadPreFinalized(const Class& replacement,
ProgramReloadContext* context) const;
// Tells whether instances need morphing for reload.
bool RequiresInstanceMorphing(const Class& replacement) const;
template <class FakeInstance, class TargetFakeInstance>
static ClassPtr NewCommon(intptr_t index);
enum MemberKind {
kAny = 0,
kStatic,
kInstance,
kInstanceAllowAbstract,
kConstructor,
kFactory,
};
enum StateBits {
kConstBit = 0,
kImplementedBit = 1,
kClassFinalizedPos = 2,
kClassFinalizedSize = 2,
kClassLoadingPos = kClassFinalizedPos + kClassFinalizedSize, // = 4
kClassLoadingSize = 2,
kAbstractBit = kClassLoadingPos + kClassLoadingSize, // = 6
kSynthesizedClassBit,
kMixinAppAliasBit,
kMixinTypeAppliedBit,
kFieldsMarkedNullableBit,
kEnumBit,
kTransformedMixinApplicationBit,
kIsAllocatedBit,
kIsLoadedBit,
kHasPragmaBit,
};
class ConstBit : public BitField<uint32_t, bool, kConstBit, 1> {};
class ImplementedBit : public BitField<uint32_t, bool, kImplementedBit, 1> {};
class ClassFinalizedBits : public BitField<uint32_t,
UntaggedClass::ClassFinalizedState,
kClassFinalizedPos,
kClassFinalizedSize> {};
class ClassLoadingBits : public BitField<uint32_t,
UntaggedClass::ClassLoadingState,
kClassLoadingPos,
kClassLoadingSize> {};
class AbstractBit : public BitField<uint32_t, bool, kAbstractBit, 1> {};
class SynthesizedClassBit
: public BitField<uint32_t, bool, kSynthesizedClassBit, 1> {};
class FieldsMarkedNullableBit
: public BitField<uint32_t, bool, kFieldsMarkedNullableBit, 1> {};
class EnumBit : public BitField<uint32_t, bool, kEnumBit, 1> {};
class TransformedMixinApplicationBit
: public BitField<uint32_t, bool, kTransformedMixinApplicationBit, 1> {};
class IsAllocatedBit : public BitField<uint32_t, bool, kIsAllocatedBit, 1> {};
class IsLoadedBit : public BitField<uint32_t, bool, kIsLoadedBit, 1> {};
class HasPragmaBit : public BitField<uint32_t, bool, kHasPragmaBit, 1> {};
void set_name(const String& value) const;
void set_user_name(const String& value) const;
const char* GenerateUserVisibleName() const;
void set_state_bits(intptr_t bits) const;
FunctionPtr CreateInvocationDispatcher(const String& target_name,
const Array& args_desc,
UntaggedFunction::Kind kind) const;
// Returns the bitmap of unboxed fields
UnboxedFieldBitmap CalculateFieldOffsets() const;
// functions_hash_table is in use iff there are at least this many functions.
static const intptr_t kFunctionLookupHashTreshold = 16;
// Initial value for the cached number of type arguments.
static const intptr_t kUnknownNumTypeArguments = -1;
int16_t num_type_arguments() const {
return LoadNonPointer<int16_t, std::memory_order_relaxed>(
&untag()->num_type_arguments_);
}
uint32_t state_bits() const {
// Ensure any following load instructions do not get performed before this
// one.
return LoadNonPointer<uint32_t, std::memory_order_acquire>(
&untag()->state_bits_);
}
public:
void set_num_type_arguments(intptr_t value) const;
void set_num_type_arguments_unsafe(intptr_t value) const;
bool has_pragma() const { return HasPragmaBit::decode(state_bits()); }
void set_has_pragma(bool has_pragma) const;
private:
void set_functions(const Array& value) const;
void set_fields(const Array& value) const;
void set_invocation_dispatcher_cache(const Array& cache) const;
ArrayPtr invocation_dispatcher_cache() const;
// Calculates number of type arguments of this class.
// This includes type arguments of a superclass and takes overlapping
// of type arguments into account.
intptr_t ComputeNumTypeArguments() const;
// Assigns empty array to all raw class array fields.
void InitEmptyFields();
static FunctionPtr CheckFunctionType(const Function& func, MemberKind kind);
FunctionPtr LookupFunctionReadLocked(const String& name,
MemberKind kind) const;
FunctionPtr LookupFunctionAllowPrivate(const String& name,
MemberKind kind) const;
FieldPtr LookupField(const String& name, MemberKind kind) const;
FunctionPtr LookupAccessorFunction(const char* prefix,
intptr_t prefix_length,
const String& name) const;
// Allocate an instance class which has a VM implementation.
template <class FakeInstance, class TargetFakeInstance>
static ClassPtr New(intptr_t id,
IsolateGroup* isolate_group,
bool register_class = true,
bool is_abstract = false);
// Helper that calls 'Class::New<Instance>(kIllegalCid)'.
static ClassPtr NewInstanceClass();
FINAL_HEAP_OBJECT_IMPLEMENTATION(Class, Object);
friend class AbstractType;
friend class Instance;
friend class Object;
friend class Type;
friend class Intrinsifier;
friend class ProgramWalker;
friend class Precompiler;
friend class ClassFinalizer;
};
// Classification of type genericity according to type parameter owners.
enum Genericity {
kAny, // Consider type params of current class and functions.
kCurrentClass, // Consider type params of current class only.
kFunctions, // Consider type params of current and parent functions.
};
class PatchClass : public Object {
public:
ClassPtr patched_class() const { return untag()->patched_class(); }
ClassPtr origin_class() const { return untag()->origin_class(); }
ScriptPtr script() const { return untag()->script(); }
ExternalTypedDataPtr library_kernel_data() const {
return untag()->library_kernel_data();
}
void set_library_kernel_data(const ExternalTypedData& data) const;
intptr_t library_kernel_offset() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
return untag()->library_kernel_offset_;
#else
return -1;
#endif
}
void set_library_kernel_offset(intptr_t offset) const {
NOT_IN_PRECOMPILED(
StoreNonPointer(&untag()->library_kernel_offset_, offset));
}
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedPatchClass));
}
static bool IsInFullSnapshot(PatchClassPtr cls) {
NoSafepointScope no_safepoint;
return Class::IsInFullSnapshot(cls->untag()->patched_class());
}
static PatchClassPtr New(const Class& patched_class,
const Class& origin_class);
static PatchClassPtr New(const Class& patched_class, const Script& source);
private:
void set_patched_class(const Class& value) const;
void set_origin_class(const Class& value) const;
void set_script(const Script& value) const;
static PatchClassPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(PatchClass, Object);
friend class Class;
};
class SingleTargetCache : public Object {
public:
CodePtr target() const { return untag()->target(); }
void set_target(const Code& target) const;
static intptr_t target_offset() {
return OFFSET_OF(UntaggedSingleTargetCache, target_);
}
#define DEFINE_NON_POINTER_FIELD_ACCESSORS(type, name) \
type name() const { return untag()->name##_; } \
void set_##name(type value) const { \
StoreNonPointer(&untag()->name##_, value); \
} \
static intptr_t name##_offset() { \
return OFFSET_OF(UntaggedSingleTargetCache, name##_); \
}
DEFINE_NON_POINTER_FIELD_ACCESSORS(uword, entry_point);
DEFINE_NON_POINTER_FIELD_ACCESSORS(intptr_t, lower_limit);
DEFINE_NON_POINTER_FIELD_ACCESSORS(intptr_t, upper_limit);
#undef DEFINE_NON_POINTER_FIELD_ACCESSORS
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedSingleTargetCache));
}
static SingleTargetCachePtr New();
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(SingleTargetCache, Object);
friend class Class;
};
class MonomorphicSmiableCall : public Object {
public:
CodePtr target() const { return untag()->target(); }
classid_t expected_cid() const { return untag()->expected_cid_; }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedMonomorphicSmiableCall));
}
static MonomorphicSmiableCallPtr New(classid_t expected_cid,
const Code& target);
static intptr_t expected_cid_offset() {
return OFFSET_OF(UntaggedMonomorphicSmiableCall, expected_cid_);
}
static intptr_t target_offset() {
return OFFSET_OF(UntaggedMonomorphicSmiableCall, target_);
}
static intptr_t entrypoint_offset() {
return OFFSET_OF(UntaggedMonomorphicSmiableCall, entrypoint_);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(MonomorphicSmiableCall, Object);
friend class Class;
};
class CallSiteData : public Object {
public:
StringPtr target_name() const { return untag()->target_name(); }
ArrayPtr arguments_descriptor() const { return untag()->args_descriptor(); }
intptr_t TypeArgsLen() const;
intptr_t CountWithTypeArgs() const;
intptr_t CountWithoutTypeArgs() const;
intptr_t SizeWithoutTypeArgs() const;
intptr_t SizeWithTypeArgs() const;
static intptr_t target_name_offset() {
return OFFSET_OF(UntaggedCallSiteData, target_name_);
}
static intptr_t arguments_descriptor_offset() {
return OFFSET_OF(UntaggedCallSiteData, args_descriptor_);
}
private:
void set_target_name(const String& value) const;
void set_arguments_descriptor(const Array& value) const;
HEAP_OBJECT_IMPLEMENTATION(CallSiteData, Object)
friend class ICData;
friend class MegamorphicCache;
};
class UnlinkedCall : public CallSiteData {
public:
bool can_patch_to_monomorphic() const {
return untag()->can_patch_to_monomorphic_;
}
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedUnlinkedCall));
}
uword Hash() const;
bool Equals(const UnlinkedCall& other) const;
static UnlinkedCallPtr New();
private:
friend class ICData; // For set_*() methods.
void set_can_patch_to_monomorphic(bool value) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(UnlinkedCall, CallSiteData);
friend class Class;
};
// Object holding information about an IC: test classes and their
// corresponding targets. The owner of the ICData can be either the function
// or the original ICData object. In case of background compilation we
// copy the ICData in a child object, thus freezing it during background
// compilation. Code may contain only original ICData objects.
class ICData : public CallSiteData {
public:
FunctionPtr Owner() const;
ICDataPtr Original() const;
void SetOriginal(const ICData& value) const;
bool IsOriginal() const { return Original() == this->ptr(); }
intptr_t NumArgsTested() const;
intptr_t deopt_id() const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
return -1;
#else
return untag()->deopt_id_;
#endif
}
bool IsImmutable() const;
#if !defined(DART_PRECOMPILED_RUNTIME)
AbstractTypePtr receivers_static_type() const {
return untag()->receivers_static_type();
}
bool is_tracking_exactness() const {
return untag()->state_bits_.Read<TrackingExactnessBit>();
}
#else
bool is_tracking_exactness() const { return false; }
#endif
// Note: only deopts with reasons before Unknown in this list are recorded in
// the ICData. All other reasons are used purely for informational messages
// printed during deoptimization itself.
#define DEOPT_REASONS(V) \
V(BinarySmiOp) \
V(BinaryInt64Op) \
V(DoubleToSmi) \
V(CheckSmi) \
V(CheckClass) \
V(Unknown) \
V(PolymorphicInstanceCallTestFail) \
V(UnaryInt64Op) \
V(BinaryDoubleOp) \
V(UnaryOp) \
V(UnboxInteger) \
V(Unbox) \
V(CheckArrayBound) \
V(AtCall) \
V(GuardField) \
V(TestCids) \
V(NumReasons)
enum DeoptReasonId {
#define DEFINE_ENUM_LIST(name) kDeopt##name,
DEOPT_REASONS(DEFINE_ENUM_LIST)
#undef DEFINE_ENUM_LIST
};
static const intptr_t kLastRecordedDeoptReason = kDeoptUnknown - 1;
enum DeoptFlags {
// Deoptimization is caused by an optimistically hoisted instruction.
kHoisted = 1 << 0,
// Deoptimization is caused by an optimistically generalized bounds check.
kGeneralized = 1 << 1
};
bool HasDeoptReasons() const { return DeoptReasons() != 0; }
uint32_t DeoptReasons() const;
void SetDeoptReasons(uint32_t reasons) const;
bool HasDeoptReason(ICData::DeoptReasonId reason) const;
void AddDeoptReason(ICData::DeoptReasonId reason) const;
// Call site classification that is helpful for hot-reload. Call sites with
// different `RebindRule` have to be rebound differently.
#define FOR_EACH_REBIND_RULE(V) \
V(Instance) \
V(NoRebind) \
V(NSMDispatch) \
V(Optimized) \
V(Static) \
V(Super)
enum RebindRule {
#define REBIND_ENUM_DEF(name) k##name,
FOR_EACH_REBIND_RULE(REBIND_ENUM_DEF)
#undef REBIND_ENUM_DEF
kNumRebindRules,
};
static const char* RebindRuleToCString(RebindRule r);
static bool ParseRebindRule(const char* str, RebindRule* out);
RebindRule rebind_rule() const;
void set_is_megamorphic(bool value) const {
untag()->state_bits_.UpdateBool<MegamorphicBit, std::memory_order_release>(
value);
}
// The length of the array. This includes all sentinel entries including
// the final one.
intptr_t Length() const;
// Takes O(result) time!
intptr_t NumberOfChecks() const;
// Discounts any checks with usage of zero.
// Takes O(result)) time!
intptr_t NumberOfUsedChecks() const;
// Takes O(n) time!
bool NumberOfChecksIs(intptr_t n) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedICData));
}
static intptr_t state_bits_offset() {
return OFFSET_OF(UntaggedICData, state_bits_);
}
static intptr_t NumArgsTestedShift() { return kNumArgsTestedPos; }
static intptr_t NumArgsTestedMask() {
return ((1 << kNumArgsTestedSize) - 1) << kNumArgsTestedPos;
}
static intptr_t entries_offset() {
return OFFSET_OF(UntaggedICData, entries_);
}
static intptr_t owner_offset() { return OFFSET_OF(UntaggedICData, owner_); }
#if !defined(DART_PRECOMPILED_RUNTIME)
static intptr_t receivers_static_type_offset() {
return OFFSET_OF(UntaggedICData, receivers_static_type_);
}
#endif
// Replaces entry |index| with the sentinel.
// NOTE: Can only be called during reload.
void WriteSentinelAt(intptr_t index,
const CallSiteResetter& proof_of_reload) const;
// Clears the count for entry |index|.
// NOTE: Can only be called during reload.
void ClearCountAt(intptr_t index,
const CallSiteResetter& proof_of_reload) const;
// Clear all entries with the sentinel value and reset the first entry
// with the dummy target entry.
// NOTE: Can only be called during reload.
void ClearAndSetStaticTarget(const Function& func,
const CallSiteResetter& proof_of_reload) const;
void DebugDump() const;
// Adding checks.
// Ensures there is a check for [class_ids].
//
// Calls [AddCheck] iff there is no existing check. Ensures test (and
// potential update) will be performed under exclusive lock to guard against
// multiple threads trying to add the same check.
void EnsureHasCheck(const GrowableArray<intptr_t>& class_ids,
const Function& target,
intptr_t count = 1) const;
// Adds one more class test to ICData. Length of 'classes' must be equal to
// the number of arguments tested. Use only for num_args_tested > 1.
void AddCheck(const GrowableArray<intptr_t>& class_ids,
const Function& target,
intptr_t count = 1) const;
StaticTypeExactnessState GetExactnessAt(intptr_t count) const;
// Ensures there is a receiver check for [receiver_class_id].
//
// Calls [AddCheckReceiverCheck] iff there is no existing check. Ensures
// test (and potential update) will be performed under exclusive lock to
// guard against multiple threads trying to add the same check.
void EnsureHasReceiverCheck(
intptr_t receiver_class_id,
const Function& target,
intptr_t count = 1,
StaticTypeExactnessState exactness =
StaticTypeExactnessState::NotTracking()) const;
// Adds sorted so that Smi is the first class-id. Use only for
// num_args_tested == 1.
void AddReceiverCheck(intptr_t receiver_class_id,
const Function& target,
intptr_t count = 1,
StaticTypeExactnessState exactness =
StaticTypeExactnessState::NotTracking()) const;
// Retrieving checks.
void GetCheckAt(intptr_t index,
GrowableArray<intptr_t>* class_ids,
Function* target) const;
void GetClassIdsAt(intptr_t index, GrowableArray<intptr_t>* class_ids) const;
// Only for 'num_args_checked == 1'.
void GetOneClassCheckAt(intptr_t index,
intptr_t* class_id,
Function* target) const;
// Only for 'num_args_checked == 1'.
intptr_t GetCidAt(intptr_t index) const;
intptr_t GetReceiverClassIdAt(intptr_t index) const;
intptr_t GetClassIdAt(intptr_t index, intptr_t arg_nr) const;
FunctionPtr GetTargetAt(intptr_t index) const;
void IncrementCountAt(intptr_t index, intptr_t value) const;
void SetCountAt(intptr_t index, intptr_t value) const;
intptr_t GetCountAt(intptr_t index) const;
intptr_t AggregateCount() const;
// Returns this->untag() if num_args_tested == 1 and arg_nr == 1, otherwise
// returns a new ICData object containing only unique arg_nr checks.
// Returns only used entries.
ICDataPtr AsUnaryClassChecksForArgNr(intptr_t arg_nr) const;
ICDataPtr AsUnaryClassChecks() const { return AsUnaryClassChecksForArgNr(0); }
// Returns ICData with aggregated receiver count, sorted by highest count.
// Smi not first!! (the convention for ICData used in code generation is that
// Smi check is first)
// Used for printing and optimizations.
ICDataPtr AsUnaryClassChecksSortedByCount() const;
UnlinkedCallPtr AsUnlinkedCall() const;
bool HasReceiverClassId(intptr_t class_id) const;
// Note: passing non-null receiver_type enables exactness tracking for
// the receiver type. Receiver type is expected to be a fully
// instantiated generic (but not a FutureOr).
// See StaticTypeExactnessState for more information.
static ICDataPtr New(
const Function& owner,
const String& target_name,
const Array& arguments_descriptor,
intptr_t deopt_id,
intptr_t num_args_tested,
RebindRule rebind_rule,
const AbstractType& receiver_type = Object::null_abstract_type());
// Similar to [New] makes the ICData have an initial (cids, target) entry.
static ICDataPtr NewWithCheck(
const Function& owner,
const String& target_name,
const Array& arguments_descriptor,
intptr_t deopt_id,
intptr_t num_args_tested,
RebindRule rebind_rule,
GrowableArray<intptr_t>* cids,
const Function& target,
const AbstractType& receiver_type = Object::null_abstract_type());
static ICDataPtr NewForStaticCall(const Function& owner,
const Function& target,
const Array& arguments_descriptor,
intptr_t deopt_id,
intptr_t num_args_tested,
RebindRule rebind_rule);
static ICDataPtr NewFrom(const ICData& from, intptr_t num_args_tested);
// Generates a new ICData with descriptor and data array copied (deep clone).
static ICDataPtr Clone(const ICData& from);
static intptr_t TestEntryLengthFor(intptr_t num_args,
bool tracking_exactness);
static intptr_t CountIndexFor(intptr_t num_args) { return num_args; }
static intptr_t EntryPointIndexFor(intptr_t num_args) { return num_args; }
static intptr_t TargetIndexFor(intptr_t num_args) { return num_args + 1; }
static intptr_t CodeIndexFor(intptr_t num_args) { return num_args + 1; }
static intptr_t ExactnessIndexFor(intptr_t num_args) { return num_args + 2; }
bool IsUsedAt(intptr_t i) const;
void PrintToJSONArray(const JSONArray& jsarray,
TokenPosition token_pos) const;
// Initialize the preallocated empty ICData entry arrays.
static void Init();
// Clear the preallocated empty ICData entry arrays.
static void Cleanup();
// We cache ICData with 0, 1, 2 arguments tested without exactness
// tracking and with 1 argument tested with exactness tracking.
enum {
kCachedICDataZeroArgTestedWithoutExactnessTrackingIdx = 0,
kCachedICDataMaxArgsTestedWithoutExactnessTracking = 2,
kCachedICDataOneArgWithExactnessTrackingIdx =
kCachedICDataZeroArgTestedWithoutExactnessTrackingIdx +
kCachedICDataMaxArgsTestedWithoutExactnessTracking + 1,
kCachedICDataArrayCount = kCachedICDataOneArgWithExactnessTrackingIdx + 1,
};
bool is_static_call() const;
intptr_t FindCheck(const GrowableArray<intptr_t>& cids) const;
ArrayPtr entries() const {
return untag()->entries<std::memory_order_acquire>();
}
bool receiver_cannot_be_smi() const {
return untag()->state_bits_.Read<ReceiverCannotBeSmiBit>();
}
void set_receiver_cannot_be_smi(bool value) const {
untag()->state_bits_.UpdateBool<ReceiverCannotBeSmiBit>(value);
}
private:
static ICDataPtr New();
// Grows the array and also sets the argument to the index that should be used
// for the new entry.
ArrayPtr Grow(intptr_t* index) const;
void set_deopt_id(intptr_t value) const;
void set_entries(const Array& value) const;
void set_owner(const Function& value) const;
void set_rebind_rule(uint32_t rebind_rule) const;
void clear_state_bits() const;
void set_tracking_exactness(bool value) const {
untag()->state_bits_.UpdateBool<TrackingExactnessBit>(value);
}
// Does entry |index| contain the sentinel value?
bool IsSentinelAt(intptr_t index) const;
void SetNumArgsTested(intptr_t value) const;
void SetReceiversStaticType(const AbstractType& type) const;
static void SetTargetAtPos(const Array& data,
intptr_t data_pos,
intptr_t num_args_tested,
const Function& target);
void AddCheckInternal(const GrowableArray<intptr_t>& class_ids,
const Function& target,
intptr_t count) const;
void AddReceiverCheckInternal(intptr_t receiver_class_id,
const Function& target,
intptr_t count,
StaticTypeExactnessState exactness) const;
// This bit is set when a call site becomes megamorphic and starts using a
// MegamorphicCache instead of ICData. It means that the entries in the
// ICData are incomplete and the MegamorphicCache needs to also be consulted
// to list the call site's observed receiver classes and targets.
// In the compiler, this should only be read once by CallTargets to avoid the
// compiler seeing an unstable set of feedback.
bool is_megamorphic() const {
// Ensure any following load instructions do not get performed before this
// one.
return untag()
->state_bits_.Read<MegamorphicBit, std::memory_order_acquire>();
}
bool ValidateInterceptor(const Function& target) const;
enum {
kNumArgsTestedPos = 0,
kNumArgsTestedSize = 2,
kTrackingExactnessPos = kNumArgsTestedPos + kNumArgsTestedSize,
kTrackingExactnessSize = 1,
kDeoptReasonPos = kTrackingExactnessPos + kTrackingExactnessSize,
kDeoptReasonSize = kLastRecordedDeoptReason + 1,
kRebindRulePos = kDeoptReasonPos + kDeoptReasonSize,
kRebindRuleSize = 3,
kMegamorphicPos = kRebindRulePos + kRebindRuleSize,
kMegamorphicSize = 1,
kReceiverCannotBeSmiPos = kMegamorphicPos + kMegamorphicSize,
kReceiverCannotBeSmiSize = 1,
};
COMPILE_ASSERT(kReceiverCannotBeSmiPos + kReceiverCannotBeSmiSize <=
sizeof(UntaggedICData::state_bits_) * kBitsPerWord);
COMPILE_ASSERT(kNumRebindRules <= (1 << kRebindRuleSize));
class NumArgsTestedBits : public BitField<uint32_t,
uint32_t,
kNumArgsTestedPos,
kNumArgsTestedSize> {};
class TrackingExactnessBit : public BitField<uint32_t,
bool,
kTrackingExactnessPos,
kTrackingExactnessSize> {};
class DeoptReasonBits : public BitField<uint32_t,
uint32_t,
ICData::kDeoptReasonPos,
ICData::kDeoptReasonSize> {};
class RebindRuleBits : public BitField<uint32_t,
uint32_t,
ICData::kRebindRulePos,
ICData::kRebindRuleSize> {};
class MegamorphicBit
: public BitField<uint32_t, bool, kMegamorphicPos, kMegamorphicSize> {};
class ReceiverCannotBeSmiBit : public BitField<uint32_t,
bool,
kReceiverCannotBeSmiPos,
kReceiverCannotBeSmiSize> {};
#if defined(DEBUG)
// Used in asserts to verify that a check is not added twice.
bool HasCheck(const GrowableArray<intptr_t>& cids) const;
#endif // DEBUG
intptr_t TestEntryLength() const;
static ArrayPtr NewNonCachedEmptyICDataArray(intptr_t num_args_tested,
bool tracking_exactness);
static ArrayPtr CachedEmptyICDataArray(intptr_t num_args_tested,
bool tracking_exactness);
static ICDataPtr NewDescriptor(Zone* zone,
const Function& owner,
const String& target_name,
const Array& arguments_descriptor,
intptr_t deopt_id,
intptr_t num_args_tested,
RebindRule rebind_rule,
const AbstractType& receiver_type);
static void WriteSentinel(const Array& data, intptr_t test_entry_length);
// A cache of VM heap allocated preinitialized empty ic data entry arrays.
static ArrayPtr cached_icdata_arrays_[kCachedICDataArrayCount];
FINAL_HEAP_OBJECT_IMPLEMENTATION(ICData, CallSiteData);
friend class CallSiteResetter;
friend class CallTargets;
friend class Class;
friend class VMDeserializationRoots;
friend class ICDataTestTask;
friend class VMSerializationRoots;
friend class SnapshotWriter;
};
// Often used constants for number of free function type parameters.
enum {
kNoneFree = 0,
// 'kCurrentAndEnclosingFree' is used when partially applying a signature
// function to a set of type arguments. It indicates that the set of type
// parameters declared by the current function and enclosing functions should
// be considered free, and the current function type parameters should be
// substituted as well.
//
// For instance, if the signature "<T>(T, R) => T" is instantiated with
// function type arguments [int, String] and kCurrentAndEnclosingFree is
// supplied, the result of the instantiation will be "(String, int) => int".
kCurrentAndEnclosingFree = kMaxInt32 - 1,
// Only parameters declared by enclosing functions are free.
kAllFree = kMaxInt32,
};
// Formatting configuration for Function::PrintName.
struct NameFormattingParams {
Object::NameVisibility name_visibility;
bool disambiguate_names;
// By default function name includes the name of the enclosing class if any.
// However in some contexts this information is redundant and class name
// is already known. In this case setting |include_class_name| to false
// allows you to exclude this information from the formatted name.
bool include_class_name = true;
// By default function name includes the name of the enclosing function if
// any. However in some contexts this information is redundant and
// the name of the enclosing function is already known. In this case
// setting |include_parent_name| to false allows to exclude this information
// from the formatted name.
bool include_parent_name = true;
NameFormattingParams(Object::NameVisibility visibility,
Object::NameDisambiguation name_disambiguation =
Object::NameDisambiguation::kNo)
: name_visibility(visibility),
disambiguate_names(name_disambiguation ==
Object::NameDisambiguation::kYes) {}
static NameFormattingParams DisambiguatedWithoutClassName(
Object::NameVisibility visibility) {
NameFormattingParams params(visibility, Object::NameDisambiguation::kYes);
params.include_class_name = false;
return params;
}
static NameFormattingParams DisambiguatedUnqualified(
Object::NameVisibility visibility) {
NameFormattingParams params(visibility, Object::NameDisambiguation::kYes);
params.include_class_name = false;
params.include_parent_name = false;
return params;
}
};
class Function : public Object {
public:
StringPtr name() const { return untag()->name(); }
StringPtr UserVisibleName() const; // Same as scrubbed name.
const char* UserVisibleNameCString() const;
const char* NameCString(NameVisibility name_visibility) const;
void PrintName(const NameFormattingParams& params,
BaseTextBuffer* printer) const;
StringPtr QualifiedScrubbedName() const;
StringPtr QualifiedUserVisibleName() const;
const char* QualifiedUserVisibleNameCString() const;
virtual StringPtr DictionaryName() const { return name(); }
StringPtr GetSource() const;
// Set the "C signature" for an FFI trampoline.
// Can only be used on FFI trampolines.
void SetFfiCSignature(const FunctionType& sig) const;
// Retrieves the "C signature" for an FFI trampoline.
// Can only be used on FFI trampolines.
FunctionTypePtr FfiCSignature() const;
bool FfiCSignatureContainsHandles() const;
bool FfiCSignatureReturnsStruct() const;
// Can only be called on FFI trampolines.
// -1 for Dart -> native calls.
int32_t FfiCallbackId() const;
// Can only be called on FFI trampolines.
void SetFfiCallbackId(int32_t value) const;
// Can only be called on FFI trampolines.
bool FfiIsLeaf() const;
// Can only be called on FFI trampolines.
void SetFfiIsLeaf(bool is_leaf) const;
// Can only be called on FFI trampolines.
// Null for Dart -> native calls.
FunctionPtr FfiCallbackTarget() const;
// Can only be called on FFI trampolines.
void SetFfiCallbackTarget(const Function& target) const;
// Can only be called on FFI trampolines.
// Null for Dart -> native calls.
InstancePtr FfiCallbackExceptionalReturn() const;
// Can only be called on FFI trampolines.
void SetFfiCallbackExceptionalReturn(const Instance& value) const;
// Return the signature of this function.
PRECOMPILER_WSR_FIELD_DECLARATION(FunctionType, signature);
void SetSignature(const FunctionType& value) const;
static intptr_t signature_offset() {
return OFFSET_OF(UntaggedFunction, signature_);
}
// Build a string of the form '<T>(T, {B b, C c}) => R' representing the
// internal signature of the given function. In this example, T is a type
// parameter of this function and R is a type parameter of class C, the owner
// of the function. B and C are not type parameters.
StringPtr InternalSignature() const;
// Build a string of the form '<T>(T, {B b, C c}) => R' representing the
// user visible signature of the given function. In this example, T is a type
// parameter of this function and R is a type parameter of class C, the owner
// of the function. B and C are not type parameters.
// Implicit parameters are hidden.
StringPtr UserVisibleSignature() const;
// Returns true if the signature of this function is instantiated, i.e. if it
// does not involve generic parameter types or generic result type.
// Note that function type parameters declared by this function do not make
// its signature uninstantiated, only type parameters declared by parent
// generic functions or class type parameters.
bool HasInstantiatedSignature(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
ClassPtr Owner() const;
void set_owner(const Object& value) const;
ClassPtr origin() const;
ScriptPtr script() const;
ObjectPtr RawOwner() const { return untag()->owner(); }
// The NNBD mode of the library declaring this function.
// TODO(alexmarkov): nnbd_mode() doesn't work for mixins.
// It should be either removed or fixed.
NNBDMode nnbd_mode() const { return Class::Handle(origin()).nnbd_mode(); }
RegExpPtr regexp() const;
intptr_t string_specialization_cid() const;
bool is_sticky_specialization() const;
void SetRegExpData(const RegExp& regexp,
intptr_t string_specialization_cid,
bool sticky) const;
StringPtr native_name() const;
void set_native_name(const String& name) const;
AbstractTypePtr result_type() const {
return signature()->untag()->result_type();
}
// The parameters, starting with NumImplicitParameters() parameters which are
// only visible to the VM, but not to Dart users.
// Note that type checks exclude implicit parameters.
AbstractTypePtr ParameterTypeAt(intptr_t index) const;
ArrayPtr parameter_types() const {
return signature()->untag()->parameter_types();
}
// Outside of the AOT runtime, functions store the names for their positional
// parameters, and delegate storage of the names for named parameters to
// their signature. These methods handle fetching the name from and
// setting the name to the correct location.
StringPtr ParameterNameAt(intptr_t index) const;
// Only valid for positional parameter indexes, as this should be called
// explicitly on the signature for named parameters.
void SetParameterNameAt(intptr_t index, const String& value) const;
// Creates an appropriately sized array in the function to hold positional
// parameter names, using the positional parameter count in the signature.
// Uses same default space as Function::New.
void CreateNameArray(Heap::Space space = Heap::kOld) const;
// Delegates to the signature, which stores the named parameter flags.
bool IsRequiredAt(intptr_t index) const;
// The formal type parameters, their bounds, and defaults, are specified as an
// object of type TypeParameters stored in the signature.
TypeParametersPtr type_parameters() const {
return signature()->untag()->type_parameters();
}
intptr_t NumTypeParameters() const {
return signature()
->untag()
->packed_type_parameter_counts_
.Read<UntaggedFunctionType::PackedNumTypeParameters>();
}
// Return the cumulative number of type arguments in all parent functions.
intptr_t NumParentTypeArguments() const;
// Return the cumulative number of type arguments in all parent functions and
// own type arguments.
intptr_t NumTypeArguments() const {
return NumParentTypeArguments() + NumTypeParameters();
}
// Return the type parameter declared at index.
TypeParameterPtr TypeParameterAt(
intptr_t index,
Nullability nullability = Nullability::kNonNullable) const;
// Return true if this function declares type parameters.
// Generic dispatchers only set the number without actual type parameters.
bool IsGeneric() const { return NumTypeParameters() > 0; }
// Return true if any parent function of this function is generic.
bool HasGenericParent() const { return NumParentTypeArguments() > 0; }
// Not thread-safe; must be called in the main thread.
// Sets function's code and code's function.
void InstallOptimizedCode(const Code& code) const;
void AttachCode(const Code& value) const;
void SetInstructions(const Code& value) const;
void SetInstructionsSafe(const Code& value) const;
void ClearCode() const;
void ClearCodeSafe() const;
// Disables optimized code and switches to unoptimized code.
void SwitchToUnoptimizedCode() const;
// Ensures that the function has code. If there is no code it compiles the
// unoptimized version of the code. If the code contains errors, it calls
// Exceptions::PropagateError and does not return. Normally returns the
// current code, whether it is optimized or unoptimized.
CodePtr EnsureHasCode() const;
// Disables optimized code and switches to unoptimized code (or the lazy
// compilation stub).
void SwitchToLazyCompiledUnoptimizedCode() const;
// Compiles unoptimized code (if necessary) and attaches it to the function.
void EnsureHasCompiledUnoptimizedCode() const;
// Return the most recently compiled and installed code for this function.
// It is not the only Code object that points to this function.
CodePtr CurrentCode() const { return CurrentCodeOf(ptr()); }
bool SafeToClosurize() const;
static CodePtr CurrentCodeOf(const FunctionPtr function) {
return function->untag()->code();
}
CodePtr unoptimized_code() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return static_cast<CodePtr>(Object::null());
#else
return untag()->unoptimized_code();
#endif
}
void set_unoptimized_code(const Code& value) const;
bool HasCode() const;
static bool HasCode(FunctionPtr function);
static intptr_t code_offset() { return OFFSET_OF(UntaggedFunction, code_); }
uword entry_point() const { return untag()->entry_point_; }
static intptr_t entry_point_offset(
CodeEntryKind entry_kind = CodeEntryKind::kNormal) {
switch (entry_kind) {
case CodeEntryKind::kNormal:
return OFFSET_OF(UntaggedFunction, entry_point_);
case CodeEntryKind::kUnchecked:
return OFFSET_OF(UntaggedFunction, unchecked_entry_point_);
default:
UNREACHABLE();
}
}
static intptr_t unchecked_entry_point_offset() {
return OFFSET_OF(UntaggedFunction, unchecked_entry_point_);
}
virtual uword Hash() const;
// Returns true if there is at least one debugger breakpoint
// set in this function.
bool HasBreakpoint() const;
ContextScopePtr context_scope() const;
void set_context_scope(const ContextScope& value) const;
// Enclosing function of this local function.
FunctionPtr parent_function() const;
using DefaultTypeArgumentsKind =
UntaggedClosureData::DefaultTypeArgumentsKind;
// Returns a canonicalized vector of the type parameters instantiated
// to bounds. If non-generic, the empty type arguments vector is returned.
TypeArgumentsPtr InstantiateToBounds(
Thread* thread,
DefaultTypeArgumentsKind* kind_out = nullptr) const;
// Only usable for closure functions.
DefaultTypeArgumentsKind default_type_arguments_kind() const;
void set_default_type_arguments_kind(DefaultTypeArgumentsKind value) const;
// Enclosing outermost function of this local function.
FunctionPtr GetOutermostFunction() const;
void set_extracted_method_closure(const Function& function) const;
FunctionPtr extracted_method_closure() const;
void set_saved_args_desc(const Array& array) const;
ArrayPtr saved_args_desc() const;
bool HasSavedArgumentsDescriptor() const {
return IsInvokeFieldDispatcher() || IsNoSuchMethodDispatcher();
}
void set_accessor_field(const Field& value) const;
FieldPtr accessor_field() const;
bool IsRegularFunction() const {
return kind() == UntaggedFunction::kRegularFunction;
}
bool IsMethodExtractor() const {
return kind() == UntaggedFunction::kMethodExtractor;
}
bool IsNoSuchMethodDispatcher() const {
return kind() == UntaggedFunction::kNoSuchMethodDispatcher;
}
bool IsInvokeFieldDispatcher() const {
return kind() == UntaggedFunction::kInvokeFieldDispatcher;
}
bool IsDynamicInvokeFieldDispatcher() const {
return IsInvokeFieldDispatcher() &&
IsDynamicInvocationForwarderName(name());
}
// Performs all the checks that don't require the current thread first, to
// avoid retrieving it unless they all pass. If you have a handle on the
// current thread, call the version that takes one instead.
bool IsDynamicClosureCallDispatcher() const {
if (!IsDynamicInvokeFieldDispatcher()) return false;
return IsDynamicClosureCallDispatcher(Thread::Current());
}
bool IsDynamicClosureCallDispatcher(Thread* thread) const;
bool IsDynamicInvocationForwarder() const {
return kind() == UntaggedFunction::kDynamicInvocationForwarder;
}
bool IsImplicitGetterOrSetter() const {
return kind() == UntaggedFunction::kImplicitGetter ||
kind() == UntaggedFunction::kImplicitSetter ||
kind() == UntaggedFunction::kImplicitStaticGetter;
}
// Returns true iff an implicit closure function has been created
// for this function.
bool HasImplicitClosureFunction() const {
return implicit_closure_function() != null();
}
// Returns the closure function implicitly created for this function. If none
// exists yet, create one and remember it. Implicit closure functions are
// used in VM Closure instances that represent results of tear-off operations.
FunctionPtr ImplicitClosureFunction() const;
void DropUncompiledImplicitClosureFunction() const;
// Return the closure implicitly created for this function.
// If none exists yet, create one and remember it.
ClosurePtr ImplicitStaticClosure() const;
ClosurePtr ImplicitInstanceClosure(const Instance& receiver) const;
// Returns the target of the implicit closure or null if the target is now
// invalid (e.g., mismatched argument shapes after a reload).
FunctionPtr ImplicitClosureTarget(Zone* zone) const;
intptr_t ComputeClosureHash() const;
FunctionPtr ForwardingTarget() const;
void SetForwardingChecks(const Array& checks) const;
UntaggedFunction::Kind kind() const {
return untag()->kind_tag_.Read<KindBits>();
}
UntaggedFunction::AsyncModifier modifier() const {
return untag()->kind_tag_.Read<ModifierBits>();
}
static const char* KindToCString(UntaggedFunction::Kind kind);
bool IsGenerativeConstructor() const {
return (kind() == UntaggedFunction::kConstructor) && !is_static();
}
bool IsImplicitConstructor() const;
bool IsFactory() const {
return (kind() == UntaggedFunction::kConstructor) && is_static();
}
bool HasThisParameter() const {
return IsDynamicFunction(/*allow_abstract=*/true) ||
IsGenerativeConstructor() || (IsFieldInitializer() && !is_static());
}
bool IsDynamicFunction(bool allow_abstract = false) const {
if (is_static() || (!allow_abstract && is_abstract())) {
return false;
}
switch (kind()) {
case UntaggedFunction::kRegularFunction:
case UntaggedFunction::kGetterFunction:
case UntaggedFunction::kSetterFunction:
case UntaggedFunction::kImplicitGetter:
case UntaggedFunction::kImplicitSetter:
case UntaggedFunction::kMethodExtractor:
case UntaggedFunction::kNoSuchMethodDispatcher:
case UntaggedFunction::kInvokeFieldDispatcher:
case UntaggedFunction::kDynamicInvocationForwarder:
return true;
case UntaggedFunction::kClosureFunction:
case UntaggedFunction::kImplicitClosureFunction:
case UntaggedFunction::kConstructor:
case UntaggedFunction::kImplicitStaticGetter:
case UntaggedFunction::kFieldInitializer:
case UntaggedFunction::kIrregexpFunction:
return false;
default:
UNREACHABLE();
return false;
}
}
bool IsStaticFunction() const {
if (!is_static()) {
return false;
}
switch (kind()) {
case UntaggedFunction::kRegularFunction:
case UntaggedFunction::kGetterFunction:
case UntaggedFunction::kSetterFunction:
case UntaggedFunction::kImplicitGetter:
case UntaggedFunction::kImplicitSetter:
case UntaggedFunction::kImplicitStaticGetter:
case UntaggedFunction::kFieldInitializer:
case UntaggedFunction::kIrregexpFunction:
return true;
case UntaggedFunction::kClosureFunction:
case UntaggedFunction::kImplicitClosureFunction:
case UntaggedFunction::kConstructor:
case UntaggedFunction::kMethodExtractor:
case UntaggedFunction::kNoSuchMethodDispatcher:
case UntaggedFunction::kInvokeFieldDispatcher:
case UntaggedFunction::kDynamicInvocationForwarder:
return false;
default:
UNREACHABLE();
return false;
}
}
bool NeedsTypeArgumentTypeChecks() const {
return !(is_static() || (kind() == UntaggedFunction::kConstructor));
}
bool NeedsArgumentTypeChecks() const {
return !(is_static() || (kind() == UntaggedFunction::kConstructor));
}
bool NeedsMonomorphicCheckedEntry(Zone* zone) const;
bool HasDynamicCallers(Zone* zone) const;
bool PrologueNeedsArgumentsDescriptor() const;
bool MayHaveUncheckedEntryPoint() const;
TokenPosition token_pos() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return TokenPosition::kNoSource;
#else
return untag()->token_pos_;
#endif
}
void set_token_pos(TokenPosition value) const;
TokenPosition end_token_pos() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return TokenPosition::kNoSource;
#else
return untag()->end_token_pos_;
#endif
}
void set_end_token_pos(TokenPosition value) const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
#else
StoreNonPointer(&untag()->end_token_pos_, value);
#endif
}
// Returns the size of the source for this function.
intptr_t SourceSize() const;
uint32_t packed_fields() const { return untag()->packed_fields_; }
void set_packed_fields(uint32_t packed_fields) const;
static intptr_t packed_fields_offset() {
return OFFSET_OF(UntaggedFunction, packed_fields_);
}
intptr_t num_fixed_parameters() const {
return signature()
->untag()
->packed_parameter_counts_
.Read<UntaggedFunctionType::PackedNumFixedParameters>();
}
bool HasOptionalParameters() const {
return signature()
->untag()
->packed_parameter_counts_
.Read<UntaggedFunctionType::PackedNumOptionalParameters>() > 0;
}
bool HasOptionalNamedParameters() const {
return HasOptionalParameters() &&
signature()
->untag()
->packed_parameter_counts_
.Read<UntaggedFunctionType::PackedHasNamedOptionalParameters>();
}
bool HasRequiredNamedParameters() const;
bool HasOptionalPositionalParameters() const {
return HasOptionalParameters() && !HasOptionalNamedParameters();
}
intptr_t NumOptionalParameters() const {
return signature()
->untag()
->packed_parameter_counts_
.Read<UntaggedFunctionType::PackedNumOptionalParameters>();
}
intptr_t NumOptionalPositionalParameters() const {
return HasOptionalPositionalParameters() ? NumOptionalParameters() : 0;
}
intptr_t NumOptionalNamedParameters() const {
return HasOptionalNamedParameters() ? NumOptionalParameters() : 0;
}
intptr_t NumParameters() const;
intptr_t NumImplicitParameters() const;
#if defined(DART_PRECOMPILED_RUNTIME)
#define DEFINE_GETTERS_AND_SETTERS(return_type, type, name) \
static intptr_t name##_offset() { \
UNREACHABLE(); \
return 0; \
} \
return_type name() const { return 0; } \
\
void set_##name(type value) const { UNREACHABLE(); }
#else
#define DEFINE_GETTERS_AND_SETTERS(return_type, type, name) \
static intptr_t name##_offset() { \
return OFFSET_OF(UntaggedFunction, name##_); \
} \
return_type name() const { \
return LoadNonPointer<type, std::memory_order_relaxed>(&untag()->name##_); \
} \
\
void set_##name(type value) const { \
StoreNonPointer<type, type, std::memory_order_relaxed>(&untag()->name##_, \
value); \
}
#endif
JIT_FUNCTION_COUNTERS(DEFINE_GETTERS_AND_SETTERS)
#undef DEFINE_GETTERS_AND_SETTERS
intptr_t kernel_offset() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return 0;
#else
return untag()->kernel_offset_;
#endif
}
void set_kernel_offset(intptr_t value) const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
#else
ASSERT(value >= 0);
StoreNonPointer(&untag()->kernel_offset_, value);
#endif
}
void InheritKernelOffsetFrom(const Function& src) const;
void InheritKernelOffsetFrom(const Field& src) const;
static const intptr_t kMaxInstructionCount = (1 << 16) - 1;
void SetOptimizedInstructionCountClamped(uintptr_t value) const {
if (value > kMaxInstructionCount) value = kMaxInstructionCount;
set_optimized_instruction_count(value);
}
void SetOptimizedCallSiteCountClamped(uintptr_t value) const {
if (value > kMaxInstructionCount) value = kMaxInstructionCount;
set_optimized_call_site_count(value);
}
void SetKernelDataAndScript(const Script& script,
const ExternalTypedData& data,
intptr_t offset) const;
intptr_t KernelDataProgramOffset() const;
ExternalTypedDataPtr KernelData() const;
bool IsOptimizable() const;
void SetIsOptimizable(bool value) const;
// Whether this function must be optimized immediately and cannot be compiled
// with the unoptimizing compiler. Such a function must be sure to not
// deoptimize, since we won't generate deoptimization info or register
// dependencies. It will be compiled into optimized code immediately when it's
// run.
bool ForceOptimize() const {
return IsFfiFromAddress() || IsFfiGetAddress() || IsFfiLoad() ||
IsFfiStore() || IsFfiTrampoline() || IsTypedDataViewFactory() ||
IsUtf8Scan();
}
bool CanBeInlined() const;
MethodRecognizer::Kind recognized_kind() const {
return untag()->kind_tag_.Read<RecognizedBits>();
}
void set_recognized_kind(MethodRecognizer::Kind value) const;
bool IsRecognized() const {
return recognized_kind() != MethodRecognizer::kUnknown;
}
bool HasOptimizedCode() const;
// Returns true if the argument counts are valid for calling this function.
// Otherwise, it returns false and the reason (if error_message is not NULL).
bool AreValidArgumentCounts(intptr_t num_type_arguments,
intptr_t num_arguments,
intptr_t num_named_arguments,
String* error_message) const;
// Returns a TypeError if the provided arguments don't match the function
// parameter types, null otherwise. Assumes AreValidArguments is called first.
//
// If the function has a non-null receiver in the arguments, the instantiator
// type arguments are retrieved from the receiver, otherwise the null type
// arguments vector is used.
//
// If the function is generic, the appropriate function type arguments are
// retrieved either from the arguments array or the receiver (if a closure).
// If no function type arguments are available in either location, the bounds
// of the function type parameters are instantiated and used as the function
// type arguments.
//
// The local function type arguments (_not_ parent function type arguments)
// are also checked against the bounds of the corresponding parameters to
// ensure they are appropriate subtypes if the function is generic.
ObjectPtr DoArgumentTypesMatch(const Array& args,
const ArgumentsDescriptor& arg_names) const;
// Returns a TypeError if the provided arguments don't match the function
// parameter types, null otherwise. Assumes AreValidArguments is called first.
//
// If the function is generic, the appropriate function type arguments are
// retrieved either from the arguments array or the receiver (if a closure).
// If no function type arguments are available in either location, the bounds
// of the function type parameters are instantiated and used as the function
// type arguments.
//
// The local function type arguments (_not_ parent function type arguments)
// are also checked against the bounds of the corresponding parameters to
// ensure they are appropriate subtypes if the function is generic.
ObjectPtr DoArgumentTypesMatch(
const Array& args,
const ArgumentsDescriptor& arg_names,
const TypeArguments& instantiator_type_args) const;
// Returns a TypeError if the provided arguments don't match the function
// parameter types, null otherwise. Assumes AreValidArguments is called first.
//
// The local function type arguments (_not_ parent function type arguments)
// are also checked against the bounds of the corresponding parameters to
// ensure they are appropriate subtypes if the function is generic.
ObjectPtr DoArgumentTypesMatch(const Array& args,
const ArgumentsDescriptor& arg_names,
const TypeArguments& instantiator_type_args,
const TypeArguments& function_type_args) const;
// Returns true if the type argument count, total argument count and the names
// of optional arguments are valid for calling this function.
// Otherwise, it returns false and the reason (if error_message is not NULL).
bool AreValidArguments(intptr_t num_type_arguments,
intptr_t num_arguments,
const Array& argument_names,
String* error_message) const;
bool AreValidArguments(const ArgumentsDescriptor& args_desc,
String* error_message) const;
// Fully qualified name uniquely identifying the function under gdb and during
// ast printing. The special ':' character, if present, is replaced by '_'.
const char* ToFullyQualifiedCString() const;
const char* ToLibNamePrefixedQualifiedCString() const;
const char* ToQualifiedCString() const;
static constexpr intptr_t maximum_unboxed_parameter_count() {
// Subtracts one that represents the return value
return UntaggedFunction::UnboxedParameterBitmap::kCapacity - 1;
}
void reset_unboxed_parameters_and_return() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
StoreNonPointer(&untag()->unboxed_parameters_info_,
UntaggedFunction::UnboxedParameterBitmap());
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
void set_unboxed_integer_parameter_at(intptr_t index) const {
#if !defined(DART_PRECOMPILED_RUNTIME)
ASSERT(index >= 0 && index < maximum_unboxed_parameter_count());
index++; // position 0 is reserved for the return value
const_cast<UntaggedFunction::UnboxedParameterBitmap*>(
&untag()->unboxed_parameters_info_)
->SetUnboxedInteger(index);
#else
UNREACHABLE();
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
void set_unboxed_double_parameter_at(intptr_t index) const {
#if !defined(DART_PRECOMPILED_RUNTIME)
ASSERT(index >= 0 && index < maximum_unboxed_parameter_count());
index++; // position 0 is reserved for the return value
const_cast<UntaggedFunction::UnboxedParameterBitmap*>(
&untag()->unboxed_parameters_info_)
->SetUnboxedDouble(index);
#else
UNREACHABLE();
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
void set_unboxed_integer_return() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
const_cast<UntaggedFunction::UnboxedParameterBitmap*>(
&untag()->unboxed_parameters_info_)
->SetUnboxedInteger(0);
#else
UNREACHABLE();
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
void set_unboxed_double_return() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
const_cast<UntaggedFunction::UnboxedParameterBitmap*>(
&untag()->unboxed_parameters_info_)
->SetUnboxedDouble(0);
#else
UNREACHABLE();
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
bool is_unboxed_parameter_at(intptr_t index) const {
#if !defined(DART_PRECOMPILED_RUNTIME)
ASSERT(index >= 0);
index++; // position 0 is reserved for the return value
return untag()->unboxed_parameters_info_.IsUnboxed(index);
#else
return false;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
bool is_unboxed_integer_parameter_at(intptr_t index) const {
#if !defined(DART_PRECOMPILED_RUNTIME)
ASSERT(index >= 0);
index++; // position 0 is reserved for the return value
return untag()->unboxed_parameters_info_.IsUnboxedInteger(index);
#else
return false;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
bool is_unboxed_double_parameter_at(intptr_t index) const {
#if !defined(DART_PRECOMPILED_RUNTIME)
ASSERT(index >= 0);
index++; // position 0 is reserved for the return value
return untag()->unboxed_parameters_info_.IsUnboxedDouble(index);
#else
return false;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
bool has_unboxed_return() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
return untag()->unboxed_parameters_info_.IsUnboxed(0);
#else
return false;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
bool has_unboxed_integer_return() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
return untag()->unboxed_parameters_info_.IsUnboxedInteger(0);
#else
return false;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
bool has_unboxed_double_return() const {
#if !defined(DART_PRECOMPILED_RUNTIME)
return untag()->unboxed_parameters_info_.IsUnboxedDouble(0);
#else
return false;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
#if !defined(DART_PRECOMPILED_RUNTIME)
bool HasUnboxedParameters() const {
return untag()->unboxed_parameters_info_.HasUnboxedParameters();
}
bool HasUnboxedReturnValue() const {
return untag()->unboxed_parameters_info_.HasUnboxedReturnValue();
}
#endif // !defined(DART_PRECOMPILED_RUNTIME)
bool IsDispatcherOrImplicitAccessor() const {
switch (kind()) {
case UntaggedFunction::kImplicitGetter:
case UntaggedFunction::kImplicitSetter:
case UntaggedFunction::kImplicitStaticGetter:
case UntaggedFunction::kNoSuchMethodDispatcher:
case UntaggedFunction::kInvokeFieldDispatcher:
case UntaggedFunction::kDynamicInvocationForwarder:
return true;
default:
return false;
}
}
// Returns true if this function represents an explicit getter function.
bool IsGetterFunction() const {
return kind() == UntaggedFunction::kGetterFunction;
}
// Returns true if this function represents an implicit getter function.
bool IsImplicitGetterFunction() const {
return kind() == UntaggedFunction::kImplicitGetter;
}
// Returns true if this function represents an implicit static getter
// function.
bool IsImplicitStaticGetterFunction() const {
return kind() == UntaggedFunction::kImplicitStaticGetter;
}
// Returns true if this function represents an explicit setter function.
bool IsSetterFunction() const {
return kind() == UntaggedFunction::kSetterFunction;
}
// Returns true if this function represents an implicit setter function.
bool IsImplicitSetterFunction() const {
return kind() == UntaggedFunction::kImplicitSetter;
}
// Returns true if this function represents an initializer for a static or
// instance field. The function returns the initial value and the caller is
// responsible for setting the field.
bool IsFieldInitializer() const {
return kind() == UntaggedFunction::kFieldInitializer;
}
// Returns true if this function represents a (possibly implicit) closure
// function.
bool IsClosureFunction() const {
UntaggedFunction::Kind k = kind();
return (k == UntaggedFunction::kClosureFunction) ||
(k == UntaggedFunction::kImplicitClosureFunction);
}
// Returns true if this function represents a generated irregexp function.
bool IsIrregexpFunction() const {
return kind() == UntaggedFunction::kIrregexpFunction;
}
// Returns true if this function represents an implicit closure function.
bool IsImplicitClosureFunction() const {
return kind() == UntaggedFunction::kImplicitClosureFunction;
}
// Returns true if this function represents a non implicit closure function.
bool IsNonImplicitClosureFunction() const {
return IsClosureFunction() && !IsImplicitClosureFunction();
}
// Returns true if this function represents an implicit static closure
// function.
bool IsImplicitStaticClosureFunction() const {
return IsImplicitClosureFunction() && is_static();
}
static bool IsImplicitStaticClosureFunction(FunctionPtr func);
// Returns true if this function represents an implicit instance closure
// function.
bool IsImplicitInstanceClosureFunction() const {
return IsImplicitClosureFunction() && !is_static();
}
// Returns true if this function has a parent function.
bool HasParent() const { return parent_function() != Function::null(); }
// Returns true if this function is a local function.
bool IsLocalFunction() const {
return !IsImplicitClosureFunction() && HasParent();
}
// Returns true if this function represents an ffi trampoline.
bool IsFfiTrampoline() const {
return kind() == UntaggedFunction::kFfiTrampoline;
}
static bool IsFfiTrampoline(FunctionPtr function) {
NoSafepointScope no_safepoint;
return function->untag()->kind_tag_.Read<KindBits>() ==
UntaggedFunction::kFfiTrampoline;
}
bool IsFfiLoad() const {
const auto kind = recognized_kind();
return MethodRecognizer::kFfiLoadInt8 <= kind &&
kind <= MethodRecognizer::kFfiLoadPointer;
}
bool IsFfiStore() const {
const auto kind = recognized_kind();
return MethodRecognizer::kFfiStoreInt8 <= kind &&
kind <= MethodRecognizer::kFfiStorePointer;
}
bool IsFfiFromAddress() const {
const auto kind = recognized_kind();
return kind == MethodRecognizer::kFfiFromAddress;
}
bool IsFfiGetAddress() const {
const auto kind = recognized_kind();
return kind == MethodRecognizer::kFfiGetAddress;
}
bool IsUtf8Scan() const {
const auto kind = recognized_kind();
return kind == MethodRecognizer::kUtf8DecoderScan;
}
// Recognise async functions like:
// user_func async {
// // ...
// }
bool IsAsyncFunction() const {
return modifier() == UntaggedFunction::kAsync;
}
// Recognise synthetic sync-yielding functions like the inner-most:
// user_func /* was async */ {
// :async_op(..) yielding {
// // ...
// }
// }
bool IsAsyncClosure() const {
return is_generated_body() &&
Function::Handle(parent_function()).IsAsyncFunction();
}
// Recognise sync* functions like:
// user_func sync* {
// // ...
// }
bool IsSyncGenerator() const {
return modifier() == UntaggedFunction::kSyncGen;
}
// Recognise synthetic :sync_op_gen()s like:
// user_func /* was sync* */ {
// :sync_op_gen() {
// // ...
// }
// }
bool IsSyncGenClosureMaker() const {
return is_generated_body() &&
Function::Handle(parent_function()).IsSyncGenerator();
}
// Recognise async* functions like:
// user_func async* {
// // ...
// }
bool IsAsyncGenerator() const {
return modifier() == UntaggedFunction::kAsyncGen;
}
// Recognise synthetic sync-yielding functions like the inner-most:
// user_func /* originally async* */ {
// :async_op(..) yielding {
// // ...
// }
// }
bool IsAsyncGenClosure() const {
return is_generated_body() &&
Function::Handle(parent_function()).IsAsyncGenerator();
}
bool IsAsyncOrGenerator() const {
return modifier() != UntaggedFunction::kNoModifier;
}
// Recognise synthetic sync-yielding functions like the inner-most:
// user_func /* was sync* */ {
// :sync_op_gen() {
// :sync_op(..) yielding {
// // ...
// }
// }
// }
bool IsSyncGenClosure() const {
return is_generated_body() &&
Function::Handle(parent_function()).IsSyncGenClosureMaker();
}
bool IsTypedDataViewFactory() const {
if (is_native() && kind() == UntaggedFunction::kConstructor) {
// This is a native factory constructor.
const Class& klass = Class::Handle(Owner());
return IsTypedDataViewClassId(klass.id());
}
return false;
}
DART_WARN_UNUSED_RESULT
ErrorPtr VerifyCallEntryPoint() const;
DART_WARN_UNUSED_RESULT
ErrorPtr VerifyClosurizedEntryPoint() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedFunction));
}
static FunctionPtr New(const FunctionType& signature,
const String& name,
UntaggedFunction::Kind kind,
bool is_static,
bool is_const,
bool is_abstract,
bool is_external,
bool is_native,
const Object& owner,
TokenPosition token_pos,
Heap::Space space = Heap::kOld);
// Allocates a new Function object representing a closure function
// with given kind - kClosureFunction or kImplicitClosureFunction.
static FunctionPtr NewClosureFunctionWithKind(UntaggedFunction::Kind kind,
const String& name,
const Function& parent,
TokenPosition token_pos,
const Object& owner);
// Allocates a new Function object representing a closure function.
static FunctionPtr NewClosureFunction(const String& name,
const Function& parent,
TokenPosition token_pos);
// Allocates a new Function object representing an implicit closure function.
static FunctionPtr NewImplicitClosureFunction(const String& name,
const Function& parent,
TokenPosition token_pos);
FunctionPtr CreateMethodExtractor(const String& getter_name) const;
FunctionPtr GetMethodExtractor(const String& getter_name) const;
static bool IsDynamicInvocationForwarderName(const String& name);
static bool IsDynamicInvocationForwarderName(StringPtr name);
static StringPtr DemangleDynamicInvocationForwarderName(const String& name);
static StringPtr CreateDynamicInvocationForwarderName(const String& name);
#if !defined(DART_PRECOMPILED_RUNTIME)
FunctionPtr CreateDynamicInvocationForwarder(
const String& mangled_name) const;
FunctionPtr GetDynamicInvocationForwarder(const String& mangled_name,
bool allow_add = true) const;
#endif
// Slow function, use in asserts to track changes in important library
// functions.
int32_t SourceFingerprint() const;
// Return false and report an error if the fingerprint does not match.
bool CheckSourceFingerprint(int32_t fp, const char* kind = nullptr) const;
// Works with map [deopt-id] -> ICData.
void SaveICDataMap(
const ZoneGrowableArray<const ICData*>& deopt_id_to_ic_data,
const Array& edge_counters_array) const;
// Uses 'ic_data_array' to populate the table 'deopt_id_to_ic_data'. Clone
// ic_data (array and descriptor) if 'clone_ic_data' is true.
void RestoreICDataMap(ZoneGrowableArray<const ICData*>* deopt_id_to_ic_data,
bool clone_ic_data) const;
ArrayPtr ic_data_array() const;
void ClearICDataArray() const;
ICDataPtr FindICData(intptr_t deopt_id) const;
// Sets deopt reason in all ICData-s with given deopt_id.
void SetDeoptReasonForAll(intptr_t deopt_id, ICData::DeoptReasonId reason);
void set_modifier(UntaggedFunction::AsyncModifier value) const;
// 'WasCompiled' is true if the function was compiled once in this
// VM instantiation. It is independent from presence of type feedback
// (ic_data_array) and code, which may be loaded from a snapshot.
// 'WasExecuted' is true if the usage counter has ever been positive.
// 'ProhibitsHoistingCheckClass' is true if this function deoptimized before on
// a hoisted check class instruction.
// 'ProhibitsBoundsCheckGeneralization' is true if this function deoptimized
// before on a generalized bounds check.
#define STATE_BITS_LIST(V) \
V(WasCompiled) \
V(WasExecutedBit) \
V(ProhibitsHoistingCheckClass) \
V(ProhibitsBoundsCheckGeneralization)
enum StateBits {
#define DECLARE_FLAG_POS(Name) k##Name##Pos,
STATE_BITS_LIST(DECLARE_FLAG_POS)
#undef DECLARE_FLAG_POS
};
#define DEFINE_FLAG_BIT(Name) \
class Name##Bit : public BitField<uint8_t, bool, k##Name##Pos, 1> {};
STATE_BITS_LIST(DEFINE_FLAG_BIT)
#undef DEFINE_FLAG_BIT
#define DEFINE_FLAG_ACCESSORS(Name) \
void Set##Name(bool value) const { \
set_state_bits(Name##Bit::update(value, state_bits())); \
} \
bool Name() const { return Name##Bit::decode(state_bits()); }
STATE_BITS_LIST(DEFINE_FLAG_ACCESSORS)
#undef DEFINE_FLAG_ACCESSORS
void SetUsageCounter(intptr_t value) const {
if (usage_counter() > 0) {
SetWasExecuted(true);
}
set_usage_counter(value);
}
bool WasExecuted() const { return (usage_counter() > 0) || WasExecutedBit(); }
void SetWasExecuted(bool value) const { SetWasExecutedBit(value); }
static intptr_t data_offset() { return OFFSET_OF(UntaggedFunction, data_); }
static intptr_t kind_tag_offset() {
return OFFSET_OF(UntaggedFunction, kind_tag_);
}
// static: Considered during class-side or top-level resolution rather than
// instance-side resolution.
// const: Valid target of a const constructor call.
// abstract: Skipped during instance-side resolution.
// reflectable: Enumerated by mirrors, invocable by mirrors. False for private
// functions of dart: libraries.
// debuggable: Valid location of a breakpoint. Synthetic code is not
// debuggable.
// visible: Frame is included in stack traces. Synthetic code such as
// dispatchers is not visible. Synthetic code that can trigger
// exceptions such as the outer async functions that create Futures
// is visible.
// instrinsic: Has a hand-written assembly prologue.
// inlinable: Candidate for inlining. False for functions with features we
// don't support during inlining (e.g., optional parameters),
// functions which are too big, etc.
// native: Bridge to C/C++ code.
// external: Just a declaration that expects to be defined in another patch
// file.
// generated_body: Has a generated body.
// polymorphic_target: A polymorphic method.
// has_pragma: Has a @pragma decoration.
// no_such_method_forwarder: A stub method that just calls noSuchMethod.
// Bits that are set when function is created, don't have to worry about
// concurrent updates.
#define FOR_EACH_FUNCTION_KIND_BIT(V) \
V(Static, is_static) \
V(Const, is_const) \
V(Abstract, is_abstract) \
V(Reflectable, is_reflectable) \
V(Visible, is_visible) \
V(Debuggable, is_debuggable) \
V(Intrinsic, is_intrinsic) \
V(Native, is_native) \
V(External, is_external) \
V(GeneratedBody, is_generated_body) \
V(PolymorphicTarget, is_polymorphic_target) \
V(HasPragma, has_pragma) \
V(IsSynthetic, is_synthetic) \
V(IsExtensionMember, is_extension_member)
// Bit that is updated after function is constructed, has to be updated in
// concurrent-safe manner.
#define FOR_EACH_FUNCTION_VOLATILE_KIND_BIT(V) V(Inlinable, is_inlinable)
#define DEFINE_ACCESSORS(name, accessor_name) \
void set_##accessor_name(bool value) const { \
untag()->kind_tag_.UpdateUnsynchronized<name##Bit>(value); \
} \
bool accessor_name() const { return untag()->kind_tag_.Read<name##Bit>(); }
FOR_EACH_FUNCTION_KIND_BIT(DEFINE_ACCESSORS)
#undef DEFINE_ACCESSORS
#define DEFINE_ACCESSORS(name, accessor_name) \
void set_##accessor_name(bool value) const { \
untag()->kind_tag_.UpdateBool<name##Bit>(value); \
} \
bool accessor_name() const { return untag()->kind_tag_.Read<name##Bit>(); }
FOR_EACH_FUNCTION_VOLATILE_KIND_BIT(DEFINE_ACCESSORS)
#undef DEFINE_ACCESSORS
// optimizable: Candidate for going through the optimizing compiler. False for
// some functions known to be execute infrequently and functions
// which have been de-optimized too many times.
bool is_optimizable() const {
return untag()->packed_fields_.Read<UntaggedFunction::PackedOptimizable>();
}
void set_is_optimizable(bool value) const {
untag()->packed_fields_.UpdateBool<UntaggedFunction::PackedOptimizable>(
value);
}
enum KindTagBits {
kKindTagPos = 0,
kKindTagSize = 5,
kRecognizedTagPos = kKindTagPos + kKindTagSize,
kRecognizedTagSize = 9,
kModifierPos = kRecognizedTagPos + kRecognizedTagSize,
kModifierSize = 2,
kLastModifierBitPos = kModifierPos + (kModifierSize - 1),
// Single bit sized fields start here.
#define DECLARE_BIT(name, _) k##name##Bit,
FOR_EACH_FUNCTION_KIND_BIT(DECLARE_BIT)
FOR_EACH_FUNCTION_VOLATILE_KIND_BIT(DECLARE_BIT)
#undef DECLARE_BIT
kNumTagBits
};
COMPILE_ASSERT(MethodRecognizer::kNumRecognizedMethods <
(1 << kRecognizedTagSize));
COMPILE_ASSERT(kNumTagBits <=
(kBitsPerByte *
sizeof(decltype(UntaggedFunction::kind_tag_))));
class KindBits : public BitField<uint32_t,
UntaggedFunction::Kind,
kKindTagPos,
kKindTagSize> {};
class RecognizedBits : public BitField<uint32_t,
MethodRecognizer::Kind,
kRecognizedTagPos,
kRecognizedTagSize> {};
class ModifierBits : public BitField<uint32_t,
UntaggedFunction::AsyncModifier,
kModifierPos,
kModifierSize> {};
#define DEFINE_BIT(name, _) \
class name##Bit : public BitField<uint32_t, bool, k##name##Bit, 1> {};
FOR_EACH_FUNCTION_KIND_BIT(DEFINE_BIT)
FOR_EACH_FUNCTION_VOLATILE_KIND_BIT(DEFINE_BIT)
#undef DEFINE_BIT
private:
// Given the provided defaults type arguments, determines which
// DefaultTypeArgumentsKind applies.
DefaultTypeArgumentsKind DefaultTypeArgumentsKindFor(
const TypeArguments& defaults) const;
void set_ic_data_array(const Array& value) const;
void set_name(const String& value) const;
void set_kind(UntaggedFunction::Kind value) const;
void set_parent_function(const Function& value) const;
FunctionPtr implicit_closure_function() const;
void set_implicit_closure_function(const Function& value) const;
ClosurePtr implicit_static_closure() const;
void set_implicit_static_closure(const Closure& closure) const;
ScriptPtr eval_script() const;
void set_eval_script(const Script& value) const;
void set_num_optional_parameters(intptr_t value) const; // Encoded value.
void set_kind_tag(uint32_t value) const;
#if !defined(DART_PRECOMPILED_RUNTIME)
ArrayPtr positional_parameter_names() const {
return untag()->positional_parameter_names();
}
void set_positional_parameter_names(const Array& value) const;
#endif
ObjectPtr data() const { return untag()->data<std::memory_order_acquire>(); }
void set_data(const Object& value) const;
static FunctionPtr New(Heap::Space space = Heap::kOld);
FINAL_HEAP_OBJECT_IMPLEMENTATION(Function, Object);
friend class Class;
friend class SnapshotWriter;
friend class Parser; // For set_eval_script.
// UntaggedFunction::VisitFunctionPointers accesses the private constructor of
// Function.
friend class UntaggedFunction;
friend class ClassFinalizer; // To reset parent_function.
friend class Type; // To adjust parent_function.
friend class Precompiler; // To access closure data.
friend class ProgramVisitor; // For set_parameter_types/names.
};
class ClosureData : public Object {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedClosureData));
}
static intptr_t default_type_arguments_kind_offset() {
return OFFSET_OF(UntaggedClosureData, default_type_arguments_kind_);
}
using DefaultTypeArgumentsKind =
UntaggedClosureData::DefaultTypeArgumentsKind;
private:
ContextScopePtr context_scope() const { return untag()->context_scope(); }
void set_context_scope(const ContextScope& value) const;
// Enclosing function of this local function.
PRECOMPILER_WSR_FIELD_DECLARATION(Function, parent_function)
ClosurePtr implicit_static_closure() const {
return untag()->closure<std::memory_order_acquire>();
}
void set_implicit_static_closure(const Closure& closure) const;
DefaultTypeArgumentsKind default_type_arguments_kind() const;
void set_default_type_arguments_kind(DefaultTypeArgumentsKind value) const;
static ClosureDataPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(ClosureData, Object);
friend class Class;
friend class Function;
friend class HeapProfiler;
friend class Precompiler; // To wrap parent functions in WSRs.
};
enum class EntryPointPragma {
kAlways,
kNever,
kGetterOnly,
kSetterOnly,
kCallOnly
};
class FfiTrampolineData : public Object {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedFfiTrampolineData));
}
private:
FunctionTypePtr c_signature() const { return untag()->c_signature(); }
void set_c_signature(const FunctionType& value) const;
FunctionPtr callback_target() const { return untag()->callback_target(); }
void set_callback_target(const Function& value) const;
InstancePtr callback_exceptional_return() const {
return untag()->callback_exceptional_return();
}
void set_callback_exceptional_return(const Instance& value) const;
int32_t callback_id() const { return untag()->callback_id_; }
void set_callback_id(int32_t value) const;
bool is_leaf() const { return untag()->is_leaf_; }
void set_is_leaf(bool value) const;
static FfiTrampolineDataPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(FfiTrampolineData, Object);
friend class Class;
friend class Function;
friend class HeapProfiler;
};
class Field : public Object {
public:
// The field that this field was cloned from, or this field itself if it isn't
// a clone. The purpose of cloning is that the fields the background compiler
// sees are consistent.
FieldPtr Original() const;
// Set the original field that this field was cloned from.
void SetOriginal(const Field& value) const;
// Returns whether this field is an original or a clone.
bool IsOriginal() const {
if (IsNull()) {
return true;
}
NoSafepointScope no_safepoint;
return !untag()->owner()->IsField();
}
// Mark previously unboxed field boxed. Only operates on clones, updates
// original as well as this clone.
void DisableFieldUnboxing() const;
// Returns a field cloned from 'this'. 'this' is set as the
// original field of result.
FieldPtr CloneFromOriginal() const;
StringPtr name() const { return untag()->name(); }
StringPtr UserVisibleName() const; // Same as scrubbed name.
const char* UserVisibleNameCString() const;
virtual StringPtr DictionaryName() const { return name(); }
uint16_t kind_bits() const {
return LoadNonPointer<uint16_t, std::memory_order_acquire>(
&untag()->kind_bits_);
}
bool is_static() const { return StaticBit::decode(kind_bits()); }
bool is_instance() const { return !is_static(); }
bool is_final() const { return FinalBit::decode(kind_bits()); }
bool is_const() const { return ConstBit::decode(kind_bits()); }
bool is_late() const { return IsLateBit::decode(kind_bits()); }
bool is_extension_member() const {
return IsExtensionMemberBit::decode(kind_bits());
}
bool needs_load_guard() const {
return NeedsLoadGuardBit::decode(kind_bits());
}
bool is_reflectable() const { return ReflectableBit::decode(kind_bits()); }
void set_is_reflectable(bool value) const {
ASSERT(IsOriginal());
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(ReflectableBit::update(value, untag()->kind_bits_));
}
bool is_double_initialized() const {
return DoubleInitializedBit::decode(kind_bits());
}
// Called in parser after allocating field, immutable property otherwise.
// Marks fields that are initialized with a simple double constant.
void set_is_double_initialized_unsafe(bool value) const {
ASSERT(IsOriginal());
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(DoubleInitializedBit::update(value, untag()->kind_bits_));
}
void set_is_double_initialized(bool value) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_is_double_initialized_unsafe(value);
}
bool initializer_changed_after_initialization() const {
return InitializerChangedAfterInitializatonBit::decode(kind_bits());
}
void set_initializer_changed_after_initialization(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(InitializerChangedAfterInitializatonBit::update(
value, untag()->kind_bits_));
}
bool has_pragma() const { return HasPragmaBit::decode(kind_bits()); }
void set_has_pragma(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(HasPragmaBit::update(value, untag()->kind_bits_));
}
bool is_covariant() const { return CovariantBit::decode(kind_bits()); }
void set_is_covariant(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(CovariantBit::update(value, untag()->kind_bits_));
}
bool is_generic_covariant_impl() const {
return GenericCovariantImplBit::decode(kind_bits());
}
void set_is_generic_covariant_impl(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(GenericCovariantImplBit::update(value, untag()->kind_bits_));
}
intptr_t kernel_offset() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return 0;
#else
return untag()->kernel_offset_;
#endif
}
void set_kernel_offset(intptr_t value) const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
#else
ASSERT(value >= 0);
StoreNonPointer(&untag()->kernel_offset_, value);
#endif
}
void InheritKernelOffsetFrom(const Field& src) const;
ExternalTypedDataPtr KernelData() const;
intptr_t KernelDataProgramOffset() const;
// Called during class finalization.
inline void SetOffset(intptr_t host_offset_in_bytes,
intptr_t target_offset_in_bytes) const;
inline intptr_t HostOffset() const;
static intptr_t host_offset_or_field_id_offset() {
return OFFSET_OF(UntaggedField, host_offset_or_field_id_);
}
inline intptr_t TargetOffset() const;
static inline intptr_t TargetOffsetOf(FieldPtr field);
ObjectPtr StaticConstFieldValue() const;
void SetStaticConstFieldValue(const Instance& value,
bool assert_initializing_store = true) const;
inline ObjectPtr StaticValue() const;
void SetStaticValue(const Object& value) const;
inline intptr_t field_id() const;
inline void set_field_id(intptr_t field_id) const;
inline void set_field_id_unsafe(intptr_t field_id) const;
ClassPtr Owner() const;
ClassPtr Origin() const; // Either mixin class, or same as owner().
ScriptPtr Script() const;
ObjectPtr RawOwner() const;
AbstractTypePtr type() const { return untag()->type(); }
// Used by class finalizer, otherwise initialized in constructor.
void SetFieldType(const AbstractType& value) const;
void SetFieldTypeSafe(const AbstractType& value) const;
DART_WARN_UNUSED_RESULT
ErrorPtr VerifyEntryPoint(EntryPointPragma kind) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedField));
}
static FieldPtr New(const String& name,
bool is_static,
bool is_final,
bool is_const,
bool is_reflectable,
bool is_late,
const Object& owner,
const AbstractType& type,
TokenPosition token_pos,
TokenPosition end_token_pos);
static FieldPtr NewTopLevel(const String& name,
bool is_final,
bool is_const,
bool is_late,
const Object& owner,
TokenPosition token_pos,
TokenPosition end_token_pos);
// Allocate new field object, clone values from this field. The
// original is specified.
FieldPtr Clone(const Field& original) const;
static intptr_t kind_bits_offset() {
return OFFSET_OF(UntaggedField, kind_bits_);
}
TokenPosition token_pos() const { return untag()->token_pos_; }
TokenPosition end_token_pos() const { return untag()->end_token_pos_; }
int32_t SourceFingerprint() const;
StringPtr InitializingExpression() const;
bool has_nontrivial_initializer() const {
return HasNontrivialInitializerBit::decode(kind_bits());
}
// Called by parser after allocating field.
void set_has_nontrivial_initializer_unsafe(
bool has_nontrivial_initializer) const {
ASSERT(IsOriginal());
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(HasNontrivialInitializerBit::update(
has_nontrivial_initializer, untag()->kind_bits_));
}
void set_has_nontrivial_initializer(bool has_nontrivial_initializer) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_has_nontrivial_initializer_unsafe(has_nontrivial_initializer);
}
bool has_initializer() const {
return HasInitializerBit::decode(kind_bits());
}
// Called by parser after allocating field.
void set_has_initializer_unsafe(bool has_initializer) const {
ASSERT(IsOriginal());
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(
HasInitializerBit::update(has_initializer, untag()->kind_bits_));
}
void set_has_initializer(bool has_initializer) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_has_initializer_unsafe(has_initializer);
}
bool has_trivial_initializer() const {
return has_initializer() && !has_nontrivial_initializer();
}
bool is_non_nullable_integer() const {
return IsNonNullableIntBit::decode(kind_bits());
}
void set_is_non_nullable_integer(bool is_non_nullable_integer) const {
ASSERT(Thread::Current()->IsMutatorThread());
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(IsNonNullableIntBit::update(is_non_nullable_integer,
untag()->kind_bits_));
}
StaticTypeExactnessState static_type_exactness_state() const {
return StaticTypeExactnessState::Decode(
LoadNonPointer<int8_t, std::memory_order_relaxed>(
&untag()->static_type_exactness_state_));
}
void set_static_type_exactness_state(StaticTypeExactnessState state) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_static_type_exactness_state_unsafe(state);
}
void set_static_type_exactness_state_unsafe(
StaticTypeExactnessState state) const {
StoreNonPointer<int8_t, int8_t, std::memory_order_relaxed>(
&untag()->static_type_exactness_state_, state.Encode());
}
static intptr_t static_type_exactness_state_offset() {
return OFFSET_OF(UntaggedField, static_type_exactness_state_);
}
// Return class id that any non-null value read from this field is guaranteed
// to have or kDynamicCid if such class id is not known.
// Stores to this field must update this information hence the name.
intptr_t guarded_cid() const;
void set_guarded_cid(intptr_t cid) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_guarded_cid_unsafe(cid);
}
void set_guarded_cid_unsafe(intptr_t cid) const {
StoreNonPointer<ClassIdTagType, ClassIdTagType, std::memory_order_relaxed>(
&untag()->guarded_cid_, cid);
}
static intptr_t guarded_cid_offset() {
return OFFSET_OF(UntaggedField, guarded_cid_);
}
// Return the list length that any list stored in this field is guaranteed
// to have. If length is kUnknownFixedLength the length has not
// been determined. If length is kNoFixedLength this field has multiple
// list lengths associated with it and cannot be predicted.
intptr_t guarded_list_length() const;
void set_guarded_list_length_unsafe(intptr_t list_length) const;
void set_guarded_list_length(intptr_t list_length) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_guarded_list_length_unsafe(list_length);
}
static intptr_t guarded_list_length_offset() {
return OFFSET_OF(UntaggedField, guarded_list_length_);
}
intptr_t guarded_list_length_in_object_offset() const;
void set_guarded_list_length_in_object_offset_unsafe(intptr_t offset) const;
void set_guarded_list_length_in_object_offset(intptr_t offset) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_guarded_list_length_in_object_offset_unsafe(offset);
}
static intptr_t guarded_list_length_in_object_offset_offset() {
return OFFSET_OF(UntaggedField, guarded_list_length_in_object_offset_);
}
bool needs_length_check() const {
const bool r = guarded_list_length() >= Field::kUnknownFixedLength;
ASSERT(!r || is_final());
return r;
}
bool NeedsSetter() const;
bool NeedsGetter() const;
bool NeedsInitializationCheckOnLoad() const {
return needs_load_guard() || (is_late() && !has_trivial_initializer());
}
const char* GuardedPropertiesAsCString() const;
intptr_t UnboxedFieldCid() const { return guarded_cid(); }
bool is_unboxing_candidate() const {
return UnboxingCandidateBit::decode(kind_bits());
}
// Default 'true', set to false once optimizing compiler determines it should
// be boxed.
void set_is_unboxing_candidate_unsafe(bool b) const {
set_kind_bits(UnboxingCandidateBit::update(b, untag()->kind_bits_));
}
void set_is_unboxing_candidate(bool b) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_is_unboxing_candidate_unsafe(b);
}
enum {
kUnknownLengthOffset = -1,
kUnknownFixedLength = -1,
kNoFixedLength = -2,
};
void set_is_late(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(IsLateBit::update(value, untag()->kind_bits_));
}
void set_is_extension_member(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(IsExtensionMemberBit::update(value, untag()->kind_bits_));
}
void set_needs_load_guard(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(NeedsLoadGuardBit::update(value, untag()->kind_bits_));
}
// Returns false if any value read from this field is guaranteed to be
// not null.
// Internally we is_nullable_ field contains either kNullCid (nullable) or
// kIllegalCid (non-nullable) instead of boolean. This is done to simplify
// guarding sequence in the generated code.
bool is_nullable() const;
void set_is_nullable(bool val) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_is_nullable_unsafe(val);
}
bool is_nullable_unsafe() const {
return LoadNonPointer<ClassIdTagType, std::memory_order_relaxed>(
&untag()->is_nullable_) == kNullCid;
}
void set_is_nullable_unsafe(bool val) const {
StoreNonPointer<ClassIdTagType, ClassIdTagType, std::memory_order_relaxed>(
&untag()->is_nullable_, val ? kNullCid : kIllegalCid);
}
static intptr_t is_nullable_offset() {
return OFFSET_OF(UntaggedField, is_nullable_);
}
// Record store of the given value into this field. May trigger
// deoptimization of dependent optimized code.
void RecordStore(const Object& value) const;
void InitializeGuardedListLengthInObjectOffset(bool unsafe = false) const;
// Return the list of optimized code objects that were optimized under
// assumptions about guarded class id and nullability of this field.
// These code objects must be deoptimized when field's properties change.
// Code objects are held weakly via an indirection through WeakProperty.
ArrayPtr dependent_code() const;
void set_dependent_code(const Array& array) const;
// Add the given code object to the list of dependent ones.
void RegisterDependentCode(const Code& code) const;
// Deoptimize all dependent code objects.
void DeoptimizeDependentCode() const;
// Used by background compiler to check consistency of field copy with its
// original.
bool IsConsistentWith(const Field& field) const;
bool IsUninitialized() const;
// Run initializer and set field value.
DART_WARN_UNUSED_RESULT ErrorPtr
InitializeInstance(const Instance& instance) const;
DART_WARN_UNUSED_RESULT ErrorPtr InitializeStatic() const;
// Run initializer only.
DART_WARN_UNUSED_RESULT ObjectPtr EvaluateInitializer() const;
FunctionPtr EnsureInitializerFunction() const;
FunctionPtr InitializerFunction() const {
return untag()->initializer_function<std::memory_order_acquire>();
}
void SetInitializerFunction(const Function& initializer) const;
bool HasInitializerFunction() const;
static intptr_t initializer_function_offset() {
return OFFSET_OF(UntaggedField, initializer_function_);
}
// For static fields only. Constructs a closure that gets/sets the
// field value.
InstancePtr GetterClosure() const;
InstancePtr SetterClosure() const;
InstancePtr AccessorClosure(bool make_setter) const;
// Constructs getter and setter names for fields and vice versa.
static StringPtr GetterName(const String& field_name);
static StringPtr GetterSymbol(const String& field_name);
// Returns String::null() if getter symbol does not exist.
static StringPtr LookupGetterSymbol(const String& field_name);
static StringPtr SetterName(const String& field_name);
static StringPtr SetterSymbol(const String& field_name);
// Returns String::null() if setter symbol does not exist.
static StringPtr LookupSetterSymbol(const String& field_name);
static StringPtr NameFromGetter(const String& getter_name);
static StringPtr NameFromSetter(const String& setter_name);
static StringPtr NameFromInit(const String& init_name);
static bool IsGetterName(const String& function_name);
static bool IsSetterName(const String& function_name);
static bool IsInitName(const String& function_name);
#if !defined(DART_PRECOMPILED_RUNTIME)
SubtypeTestCachePtr type_test_cache() const {
return untag()->type_test_cache();
}
void set_type_test_cache(const SubtypeTestCache& cache) const;
#endif
// Unboxed fields require exclusive ownership of the box.
// Ensure this by cloning the box if necessary.
const Object* CloneForUnboxed(const Object& value) const;
private:
static void InitializeNew(const Field& result,
const String& name,
bool is_static,
bool is_final,
bool is_const,
bool is_reflectable,
bool is_late,
const Object& owner,
TokenPosition token_pos,
TokenPosition end_token_pos);
friend class StoreInstanceFieldInstr; // Generated code access to bit field.
enum {
kConstBit = 0,
kStaticBit,
kFinalBit,
kHasNontrivialInitializerBit,
kUnboxingCandidateBit,
kReflectableBit,
kDoubleInitializedBit,
kInitializerChangedAfterInitializatonBit,
kHasPragmaBit,
kCovariantBit,
kGenericCovariantImplBit,
kIsLateBit,
kIsExtensionMemberBit,
kNeedsLoadGuardBit,
kHasInitializerBit,
kIsNonNullableIntBit,
};
class ConstBit : public BitField<uint16_t, bool, kConstBit, 1> {};
class StaticBit : public BitField<uint16_t, bool, kStaticBit, 1> {};
class FinalBit : public BitField<uint16_t, bool, kFinalBit, 1> {};
class HasNontrivialInitializerBit
: public BitField<uint16_t, bool, kHasNontrivialInitializerBit, 1> {};
class UnboxingCandidateBit
: public BitField<uint16_t, bool, kUnboxingCandidateBit, 1> {};
class ReflectableBit : public BitField<uint16_t, bool, kReflectableBit, 1> {};
class DoubleInitializedBit
: public BitField<uint16_t, bool, kDoubleInitializedBit, 1> {};
class InitializerChangedAfterInitializatonBit
: public BitField<uint16_t,
bool,
kInitializerChangedAfterInitializatonBit,
1> {};
class HasPragmaBit : public BitField<uint16_t, bool, kHasPragmaBit, 1> {};
class CovariantBit : public BitField<uint16_t, bool, kCovariantBit, 1> {};
class GenericCovariantImplBit
: public BitField<uint16_t, bool, kGenericCovariantImplBit, 1> {};
class IsLateBit : public BitField<uint16_t, bool, kIsLateBit, 1> {};
class IsExtensionMemberBit
: public BitField<uint16_t, bool, kIsExtensionMemberBit, 1> {};
class NeedsLoadGuardBit
: public BitField<uint16_t, bool, kNeedsLoadGuardBit, 1> {};
class HasInitializerBit
: public BitField<uint16_t, bool, kHasInitializerBit, 1> {};
class IsNonNullableIntBit
: public BitField<uint16_t, bool, kIsNonNullableIntBit, 1> {};
// Update guarded cid and guarded length for this field. Returns true, if
// deoptimization of dependent code is required.
bool UpdateGuardedCidAndLength(const Object& value) const;
// Update guarded exactness state for this field. Returns true, if
// deoptimization of dependent code is required.
// Assumes that guarded cid was already updated.
bool UpdateGuardedExactnessState(const Object& value) const;
// Force this field's guard to be dynamic and deoptimize dependent code.
void ForceDynamicGuardedCidAndLength() const;
void set_name(const String& value) const;
void set_is_static(bool is_static) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(StaticBit::update(is_static, untag()->kind_bits_));
}
void set_is_final(bool is_final) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(FinalBit::update(is_final, untag()->kind_bits_));
}
void set_is_const(bool value) const {
// TODO(36097): Once concurrent access is possible ensure updates are safe.
set_kind_bits(ConstBit::update(value, untag()->kind_bits_));
}
void set_owner(const Object& value) const { untag()->set_owner(value.ptr()); }
void set_token_pos(TokenPosition token_pos) const {
StoreNonPointer(&untag()->token_pos_, token_pos);
}
void set_end_token_pos(TokenPosition token_pos) const {
StoreNonPointer(&untag()->end_token_pos_, token_pos);
}
void set_kind_bits(uint16_t value) const {
StoreNonPointer<uint16_t, uint16_t, std::memory_order_release>(
&untag()->kind_bits_, value);
}
static FieldPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(Field, Object);
friend class Class;
friend class HeapProfiler;
friend class UntaggedField;
friend class FieldSerializationCluster;
friend class FieldDeserializationCluster;
};
class Script : public Object {
public:
StringPtr url() const { return untag()->url(); }
void set_url(const String& value) const;
// The actual url which was loaded from disk, if provided by the embedder.
StringPtr resolved_url() const;
bool HasSource() const;
StringPtr Source() const;
bool IsPartOfDartColonLibrary() const;
void LookupSourceAndLineStarts(Zone* zone) const;
GrowableObjectArrayPtr GenerateLineNumberArray() const;
intptr_t line_offset() const { return 0; }
intptr_t col_offset() const { return 0; }
// Returns the max real token position for this script, or kNoSource
// if there is no line starts information.
TokenPosition MaxPosition() const;
// The load time in milliseconds since epoch.
int64_t load_timestamp() const { return untag()->load_timestamp_; }
KernelProgramInfoPtr kernel_program_info() const {
return untag()->kernel_program_info();
}
void set_kernel_program_info(const KernelProgramInfo& info) const;
intptr_t kernel_script_index() const { return untag()->kernel_script_index_; }
void set_kernel_script_index(const intptr_t kernel_script_index) const;
TypedDataPtr kernel_string_offsets() const;
TypedDataPtr line_starts() const;
#if !defined(PRODUCT) && !defined(DART_PRECOMPILED_RUNTIME)
ExternalTypedDataPtr constant_coverage() const;
void set_constant_coverage(const ExternalTypedData& value) const;
#endif // !defined(PRODUCT) && !defined(DART_PRECOMPILED_RUNTIME)
void set_line_starts(const TypedData& value) const;
void set_debug_positions(const Array& value) const;
LibraryPtr FindLibrary() const;
StringPtr GetLine(intptr_t line_number, Heap::Space space = Heap::kNew) const;
StringPtr GetSnippet(intptr_t from_line,
intptr_t from_column,
intptr_t to_line,
intptr_t to_column) const;
// For real token positions when line starts are available, returns whether or
// not a GetTokenLocation call would succeed. Returns true for non-real token
// positions or if there is no line starts information.
bool IsValidTokenPosition(TokenPosition token_pos) const;
// Returns whether a line and column could be computed for the given token
// position and, if so, sets *line and *column (if not nullptr).
bool GetTokenLocation(const TokenPosition& token_pos,
intptr_t* line,
intptr_t* column = nullptr) const;
// Returns the length of the token at the given position. If the length cannot
// be determined, returns a negative value.
intptr_t GetTokenLength(const TokenPosition& token_pos) const;
// Returns whether any tokens were found for the given line. When found,
// *first_token_index and *last_token_index are set to the first and
// last token on the line, respectively.
bool TokenRangeAtLine(intptr_t line_number,
TokenPosition* first_token_index,
TokenPosition* last_token_index) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedScript));
}
static ScriptPtr New(const String& url, const String& source);
static ScriptPtr New(const String& url,
const String& resolved_url,
const String& source);
#if !defined(DART_PRECOMPILED_RUNTIME)
void LoadSourceFromKernel(const uint8_t* kernel_buffer,
intptr_t kernel_buffer_len) const;
bool IsLazyLookupSourceAndLineStarts() const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
private:
#if !defined(DART_PRECOMPILED_RUNTIME)
bool HasCachedMaxPosition() const;
void SetLazyLookupSourceAndLineStarts(bool value) const;
void SetHasCachedMaxPosition(bool value) const;
void SetCachedMaxPosition(intptr_t value) const;
#endif // !defined(DART_PRECOMPILED_RUNTIME)
void set_resolved_url(const String& value) const;
void set_source(const String& value) const;
void set_load_timestamp(int64_t value) const;
ArrayPtr debug_positions() const;
static ScriptPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(Script, Object);
friend class Class;
friend class Precompiler;
};
class DictionaryIterator : public ValueObject {
public:
explicit DictionaryIterator(const Library& library);
bool HasNext() const { return next_ix_ < size_; }
// Returns next non-null raw object.
ObjectPtr GetNext();
private:
void MoveToNextObject();
const Array& array_;
const int size_; // Number of elements to iterate over.
int next_ix_; // Index of next element.
friend class ClassDictionaryIterator;
DISALLOW_COPY_AND_ASSIGN(DictionaryIterator);
};
class ClassDictionaryIterator : public DictionaryIterator {
public:
enum IterationKind {
// TODO(hausner): fix call sites that use kIteratePrivate. There is only
// one top-level class per library left, not an array to iterate over.
kIteratePrivate,
kNoIteratePrivate
};
ClassDictionaryIterator(const Library& library,
IterationKind kind = kNoIteratePrivate);
bool HasNext() const {
return (next_ix_ < size_) || !toplevel_class_.IsNull();
}
// Returns a non-null raw class.
ClassPtr GetNextClass();
private:
void MoveToNextClass();
Class& toplevel_class_;
DISALLOW_COPY_AND_ASSIGN(ClassDictionaryIterator);
};
class Library : public Object {
public:
StringPtr name() const { return untag()->name(); }
void SetName(const String& name) const;
StringPtr url() const { return untag()->url(); }
StringPtr private_key() const { return untag()->private_key(); }
bool LoadNotStarted() const {
return untag()->load_state_ == UntaggedLibrary::kAllocated;
}
bool LoadRequested() const {
return untag()->load_state_ == UntaggedLibrary::kLoadRequested;
}
bool LoadInProgress() const {
return untag()->load_state_ == UntaggedLibrary::kLoadInProgress;
}
void SetLoadRequested() const;
void SetLoadInProgress() const;
bool Loaded() const {
return untag()->load_state_ == UntaggedLibrary::kLoaded;
}
void SetLoaded() const;
LoadingUnitPtr loading_unit() const { return untag()->loading_unit(); }
void set_loading_unit(const LoadingUnit& value) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLibrary));
}
static LibraryPtr New(const String& url);
ObjectPtr Invoke(const String& selector,
const Array& arguments,
const Array& argument_names,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
ObjectPtr InvokeGetter(const String& selector,
bool throw_nsm_if_absent,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
ObjectPtr InvokeSetter(const String& selector,
const Instance& argument,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
// Evaluate the given expression as if it appeared in an top-level method of
// this library and return the resulting value, or an error object if
// evaluating the expression fails. The method has the formal (type)
// parameters given in (type_)param_names, and is invoked with the (type)
// argument values given in (type_)param_values.
ObjectPtr EvaluateCompiledExpression(
const ExternalTypedData& kernel_buffer,
const Array& type_definitions,
const Array& param_values,
const TypeArguments& type_param_values) const;
// Library scope name dictionary.
//
// TODO(turnidge): The Lookup functions are not consistent in how
// they deal with private names. Go through and make them a bit
// more regular.
void AddClass(const Class& cls) const;
void AddObject(const Object& obj, const String& name) const;
ObjectPtr LookupReExport(const String& name,
ZoneGrowableArray<intptr_t>* visited = NULL) const;
ObjectPtr LookupObjectAllowPrivate(const String& name) const;
ObjectPtr LookupLocalOrReExportObject(const String& name) const;
ObjectPtr LookupImportedObject(const String& name) const;
ClassPtr LookupClass(const String& name) const;
ClassPtr LookupClassAllowPrivate(const String& name) const;
ClassPtr SlowLookupClassAllowMultiPartPrivate(const String& name) const;
ClassPtr LookupLocalClass(const String& name) const;
FieldPtr LookupFieldAllowPrivate(const String& name) const;
FieldPtr LookupLocalField(const String& name) const;
FunctionPtr LookupFunctionAllowPrivate(const String& name) const;
FunctionPtr LookupLocalFunction(const String& name) const;
LibraryPrefixPtr LookupLocalLibraryPrefix(const String& name) const;
// Look up a Script based on a url. If 'useResolvedUri' is not provided or is
// false, 'url' should have a 'dart:' scheme for Dart core libraries,
// a 'package:' scheme for packages, and 'file:' scheme otherwise.
//
// If 'useResolvedUri' is true, 'url' should have a 'org-dartlang-sdk:' scheme
// for Dart core libraries and a 'file:' scheme otherwise.
ScriptPtr LookupScript(const String& url, bool useResolvedUri = false) const;
ArrayPtr LoadedScripts() const;
// Resolve name in the scope of this library. First check the cache
// of already resolved names for this library. Then look in the
// local dictionary for the unmangled name N, the getter name get:N
// and setter name set:N.
// If the local dictionary contains no entry for these names,
// look in the scopes of all libraries that are imported
// without a library prefix.
ObjectPtr ResolveName(const String& name) const;
void AddAnonymousClass(const Class& cls) const;
void AddExport(const Namespace& ns) const;
void AddMetadata(const Object& declaration, intptr_t kernel_offset) const;
ObjectPtr GetMetadata(const Object& declaration) const;
// Tries to finds a @pragma annotation on [object].
//
// If successful returns `true`. If an error happens during constant
// evaluation, returns `false.
//
// If [only_core] is true, then the annotations on the object will only
// be inspected if it is part of a core library.
//
// If [multiple] is true, then sets [options] to an GrowableObjectArray
// containing all results and [options] may not be nullptr.
//
// WARNING: If the isolate received an [UnwindError] this function will not
// return and rather unwinds until the enclosing setjmp() handler.
static bool FindPragma(Thread* T,
bool only_core,
const Object& object,
const String& pragma_name,
bool multiple = false,
Object* options = nullptr);
ClassPtr toplevel_class() const { return untag()->toplevel_class(); }
void set_toplevel_class(const Class& value) const;
GrowableObjectArrayPtr used_scripts() const {
return untag()->used_scripts();
}
// Library imports.
ArrayPtr imports() const { return untag()->imports(); }
ArrayPtr exports() const { return untag()->exports(); }
void AddImport(const Namespace& ns) const;
intptr_t num_imports() const { return untag()->num_imports_; }
NamespacePtr ImportAt(intptr_t index) const;
LibraryPtr ImportLibraryAt(intptr_t index) const;
ArrayPtr dependencies() const { return untag()->dependencies(); }
void set_dependencies(const Array& deps) const;
void DropDependenciesAndCaches() const;
// Resolving native methods for script loaded in the library.
Dart_NativeEntryResolver native_entry_resolver() const {
return LoadNonPointer<Dart_NativeEntryResolver, std::memory_order_relaxed>(
&untag()->native_entry_resolver_);
}
void set_native_entry_resolver(Dart_NativeEntryResolver value) const {
StoreNonPointer<Dart_NativeEntryResolver, Dart_NativeEntryResolver,
std::memory_order_relaxed>(&untag()->native_entry_resolver_,
value);
}
Dart_NativeEntrySymbol native_entry_symbol_resolver() const {
return LoadNonPointer<Dart_NativeEntrySymbol, std::memory_order_relaxed>(
&untag()->native_entry_symbol_resolver_);
}
void set_native_entry_symbol_resolver(
Dart_NativeEntrySymbol native_symbol_resolver) const {
StoreNonPointer<Dart_NativeEntrySymbol, Dart_NativeEntrySymbol,
std::memory_order_relaxed>(
&untag()->native_entry_symbol_resolver_, native_symbol_resolver);
}
// Resolver for FFI native function pointers.
Dart_FfiNativeResolver ffi_native_resolver() const {
return LoadNonPointer<Dart_FfiNativeResolver, std::memory_order_relaxed>(
&untag()->ffi_native_resolver_);
}
void set_ffi_native_resolver(Dart_FfiNativeResolver value) const {
StoreNonPointer<Dart_FfiNativeResolver, Dart_FfiNativeResolver,
std::memory_order_relaxed>(&untag()->ffi_native_resolver_,
value);
}
bool is_in_fullsnapshot() const {
return UntaggedLibrary::InFullSnapshotBit::decode(untag()->flags_);
}
void set_is_in_fullsnapshot(bool value) const {
set_flags(
UntaggedLibrary::InFullSnapshotBit::update(value, untag()->flags_));
}
bool is_nnbd() const {
return UntaggedLibrary::NnbdBit::decode(untag()->flags_);
}
void set_is_nnbd(bool value) const {
set_flags(UntaggedLibrary::NnbdBit::update(value, untag()->flags_));
}
NNBDMode nnbd_mode() const {
return is_nnbd() ? NNBDMode::kOptedInLib : NNBDMode::kLegacyLib;
}
NNBDCompiledMode nnbd_compiled_mode() const {
return static_cast<NNBDCompiledMode>(
UntaggedLibrary::NnbdCompiledModeBits::decode(untag()->flags_));
}
void set_nnbd_compiled_mode(NNBDCompiledMode value) const {
set_flags(UntaggedLibrary::NnbdCompiledModeBits::update(
static_cast<uint8_t>(value), untag()->flags_));
}
StringPtr PrivateName(const String& name) const;
intptr_t index() const { return untag()->index_; }
void set_index(intptr_t value) const {
ASSERT((value == -1) ||
((value >= 0) && (value < std::numeric_limits<classid_t>::max())));
StoreNonPointer(&untag()->index_, value);
}
void Register(Thread* thread) const;
static void RegisterLibraries(Thread* thread,
const GrowableObjectArray& libs);
bool IsDebuggable() const {
return UntaggedLibrary::DebuggableBit::decode(untag()->flags_);
}
void set_debuggable(bool value) const {
set_flags(UntaggedLibrary::DebuggableBit::update(value, untag()->flags_));
}
bool is_dart_scheme() const {
return UntaggedLibrary::DartSchemeBit::decode(untag()->flags_);
}
void set_is_dart_scheme(bool value) const {
set_flags(UntaggedLibrary::DartSchemeBit::update(value, untag()->flags_));
}
// Includes 'dart:async', 'dart:typed_data', etc.
bool IsAnyCoreLibrary() const;
inline intptr_t UrlHash() const;
ExternalTypedDataPtr kernel_data() const { return untag()->kernel_data(); }
void set_kernel_data(const ExternalTypedData& data) const;
intptr_t kernel_offset() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return 0;
#else
return untag()->kernel_offset_;
#endif
}
void set_kernel_offset(intptr_t value) const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
#else
ASSERT(value >= 0);
StoreNonPointer(&untag()->kernel_offset_, value);
#endif
}
static LibraryPtr LookupLibrary(Thread* thread, const String& url);
static LibraryPtr GetLibrary(intptr_t index);
static void InitCoreLibrary(IsolateGroup* isolate_group);
static void InitNativeWrappersLibrary(IsolateGroup* isolate_group,
bool is_kernel_file);
static LibraryPtr AsyncLibrary();
static LibraryPtr ConvertLibrary();
static LibraryPtr CoreLibrary();
static LibraryPtr CollectionLibrary();
static LibraryPtr DeveloperLibrary();
static LibraryPtr FfiLibrary();
static LibraryPtr InternalLibrary();
static LibraryPtr IsolateLibrary();
static LibraryPtr MathLibrary();
#if !defined(DART_PRECOMPILED_RUNTIME)
static LibraryPtr MirrorsLibrary();
#endif
static LibraryPtr NativeWrappersLibrary();
static LibraryPtr ProfilerLibrary();
static LibraryPtr TypedDataLibrary();
static LibraryPtr VMServiceLibrary();
// Eagerly compile all classes and functions in the library.
static ErrorPtr CompileAll(bool ignore_error = false);
#if !defined(DART_PRECOMPILED_RUNTIME)
// Finalize all classes in all libraries.
static ErrorPtr FinalizeAllClasses();
#endif
#if defined(DEBUG) && !defined(DART_PRECOMPILED_RUNTIME)
// Checks function fingerprints. Prints mismatches and aborts if
// mismatch found.
static void CheckFunctionFingerprints();
#endif // defined(DEBUG) && !defined(DART_PRECOMPILED_RUNTIME).
static bool IsPrivate(const String& name);
// Construct the full name of a corelib member.
static const String& PrivateCoreLibName(const String& member);
// Returns true if [name] matches full name of corelib [member].
static bool IsPrivateCoreLibName(const String& name, const String& member);
// Lookup class in the core lib which also contains various VM
// helper methods and classes. Allow look up of private classes.
static ClassPtr LookupCoreClass(const String& class_name);
// Return Function::null() if function does not exist in libs.
static FunctionPtr GetFunction(const GrowableArray<Library*>& libs,
const char* class_name,
const char* function_name);
// Character used to indicate a private identifier.
static const char kPrivateIdentifierStart = '_';
// Character used to separate private identifiers from
// the library-specific key.
static const char kPrivateKeySeparator = '@';
void CheckReload(const Library& replacement,
ProgramReloadContext* context) const;
// Returns a closure of top level function 'name' in the exported namespace
// of this library. If a top level function 'name' does not exist we look
// for a top level getter 'name' that returns a closure.
ObjectPtr GetFunctionClosure(const String& name) const;
// Ensures that all top-level functions and variables (fields) are loaded.
void EnsureTopLevelClassIsFinalized() const;
private:
static const int kInitialImportsCapacity = 4;
static const int kImportsCapacityIncrement = 8;
static LibraryPtr New();
// These methods are only used by the Precompiler to obfuscate
// the name and url.
void set_name(const String& name) const;
void set_url(const String& url) const;
void set_num_imports(intptr_t value) const;
void set_flags(uint8_t flags) const;
bool HasExports() const;
ArrayPtr loaded_scripts() const { return untag()->loaded_scripts(); }
ArrayPtr metadata() const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadReader());
return untag()->metadata();
}
void set_metadata(const Array& value) const;
ArrayPtr dictionary() const { return untag()->dictionary(); }
void InitClassDictionary() const;
ArrayPtr resolved_names() const { return untag()->resolved_names(); }
bool LookupResolvedNamesCache(const String& name, Object* obj) const;
void AddToResolvedNamesCache(const String& name, const Object& obj) const;
void InitResolvedNamesCache() const;
void ClearResolvedNamesCache() const;
void InvalidateResolvedName(const String& name) const;
void InvalidateResolvedNamesCache() const;
ArrayPtr exported_names() const { return untag()->exported_names(); }
bool LookupExportedNamesCache(const String& name, Object* obj) const;
void AddToExportedNamesCache(const String& name, const Object& obj) const;
void InitExportedNamesCache() const;
void ClearExportedNamesCache() const;
static void InvalidateExportedNamesCaches();
void InitImportList() const;
void RehashDictionary(const Array& old_dict, intptr_t new_dict_size) const;
static LibraryPtr NewLibraryHelper(const String& url, bool import_core_lib);
ObjectPtr LookupEntry(const String& name, intptr_t* index) const;
ObjectPtr LookupLocalObjectAllowPrivate(const String& name) const;
ObjectPtr LookupLocalObject(const String& name) const;
void AllocatePrivateKey() const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(Library, Object);
friend class Bootstrap;
friend class Class;
friend class Debugger;
friend class DictionaryIterator;
friend class Isolate;
friend class LibraryDeserializationCluster;
friend class Namespace;
friend class Object;
friend class Precompiler;
};
// A Namespace contains the names in a library dictionary, filtered by
// the show/hide combinators.
class Namespace : public Object {
public:
LibraryPtr target() const { return untag()->target(); }
ArrayPtr show_names() const { return untag()->show_names(); }
ArrayPtr hide_names() const { return untag()->hide_names(); }
LibraryPtr owner() const { return untag()->owner(); }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedNamespace));
}
bool HidesName(const String& name) const;
ObjectPtr Lookup(const String& name,
ZoneGrowableArray<intptr_t>* trail = nullptr) const;
static NamespacePtr New(const Library& library,
const Array& show_names,
const Array& hide_names,
const Library& owner);
private:
static NamespacePtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(Namespace, Object);
friend class Class;
friend class Precompiler;
};
class KernelProgramInfo : public Object {
public:
static KernelProgramInfoPtr New(const TypedData& string_offsets,
const ExternalTypedData& string_data,
const TypedData& canonical_names,
const ExternalTypedData& metadata_payload,
const ExternalTypedData& metadata_mappings,
const ExternalTypedData& constants_table,
const Array& scripts,
const Array& libraries_cache,
const Array& classes_cache,
const Object& retained_kernel_blob,
const uint32_t binary_version);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedKernelProgramInfo));
}
TypedDataPtr string_offsets() const { return untag()->string_offsets(); }
ExternalTypedDataPtr string_data() const { return untag()->string_data(); }
TypedDataPtr canonical_names() const { return untag()->canonical_names(); }
ExternalTypedDataPtr metadata_payloads() const {
return untag()->metadata_payloads();
}
ExternalTypedDataPtr metadata_mappings() const {
return untag()->metadata_mappings();
}
ExternalTypedDataPtr constants_table() const {
return untag()->constants_table();
}
void set_constants_table(const ExternalTypedData& value) const;
ArrayPtr scripts() const { return untag()->scripts(); }
void set_scripts(const Array& scripts) const;
ArrayPtr constants() const { return untag()->constants(); }
void set_constants(const Array& constants) const;
uint32_t kernel_binary_version() const {
return untag()->kernel_binary_version_;
}
void set_kernel_binary_version(uint32_t version) const;
// If we load a kernel blob with evaluated constants, then we delay setting
// the native names of [Function] objects until we've read the constant table
// (since native names are encoded as constants).
//
// This array will hold the functions which might need their native name set.
GrowableObjectArrayPtr potential_natives() const {
return untag()->potential_natives();
}
void set_potential_natives(const GrowableObjectArray& candidates) const;
GrowableObjectArrayPtr potential_pragma_functions() const {
return untag()->potential_pragma_functions();
}
void set_potential_pragma_functions(
const GrowableObjectArray& candidates) const;
ScriptPtr ScriptAt(intptr_t index) const;
ArrayPtr libraries_cache() const { return untag()->libraries_cache(); }
void set_libraries_cache(const Array& cache) const;
LibraryPtr LookupLibrary(Thread* thread, const Smi& name_index) const;
LibraryPtr InsertLibrary(Thread* thread,
const Smi& name_index,
const Library& lib) const;
ArrayPtr classes_cache() const { return untag()->classes_cache(); }
void set_classes_cache(const Array& cache) const;
ClassPtr LookupClass(Thread* thread, const Smi& name_index) const;
ClassPtr InsertClass(Thread* thread,
const Smi& name_index,
const Class& klass) const;
private:
static KernelProgramInfoPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(KernelProgramInfo, Object);
friend class Class;
};
// ObjectPool contains constants, immediates and addresses referenced by
// generated code and deoptimization infos. Each entry has an type associated
// with it which is stored in-inline after all the entries.
class ObjectPool : public Object {
public:
using EntryType = compiler::ObjectPoolBuilderEntry::EntryType;
using Patchability = compiler::ObjectPoolBuilderEntry::Patchability;
using TypeBits = compiler::ObjectPoolBuilderEntry::TypeBits;
using PatchableBit = compiler::ObjectPoolBuilderEntry::PatchableBit;
struct Entry {
Entry() : raw_value_(), type_() {}
explicit Entry(const Object* obj)
: obj_(obj), type_(EntryType::kTaggedObject) {}
Entry(uword value, EntryType info) : raw_value_(value), type_(info) {}
union {
const Object* obj_;
uword raw_value_;
};
EntryType type_;
};
intptr_t Length() const { return untag()->length_; }
void SetLength(intptr_t value) const {
StoreNonPointer(&untag()->length_, value);
}
static intptr_t length_offset() {
return OFFSET_OF(UntaggedObjectPool, length_);
}
static intptr_t data_offset() {
return OFFSET_OF_RETURNED_VALUE(UntaggedObjectPool, data);
}
static intptr_t element_offset(intptr_t index) {
return OFFSET_OF_RETURNED_VALUE(UntaggedObjectPool, data) +
sizeof(UntaggedObjectPool::Entry) * index;
}
struct ArrayTraits {
static intptr_t elements_start_offset() {
return ObjectPool::data_offset();
}
static constexpr intptr_t kElementSize = sizeof(UntaggedObjectPool::Entry);
};
EntryType TypeAt(intptr_t index) const {
ASSERT((index >= 0) && (index <= Length()));
return TypeBits::decode(untag()->entry_bits()[index]);
}
Patchability PatchableAt(intptr_t index) const {
ASSERT((index >= 0) && (index <= Length()));
return PatchableBit::decode(untag()->entry_bits()[index]);
}
void SetTypeAt(intptr_t index, EntryType type, Patchability patchable) const {
ASSERT(index >= 0 && index <= Length());
const uint8_t bits =
PatchableBit::encode(patchable) | TypeBits::encode(type);
StoreNonPointer(&untag()->entry_bits()[index], bits);
}
template <std::memory_order order = std::memory_order_relaxed>
ObjectPtr ObjectAt(intptr_t index) const {
ASSERT(TypeAt(index) == EntryType::kTaggedObject);
return LoadPointer<ObjectPtr, order>(&(EntryAddr(index)->raw_obj_));
}
template <std::memory_order order = std::memory_order_relaxed>
void SetObjectAt(intptr_t index, const Object& obj) const {
ASSERT((TypeAt(index) == EntryType::kTaggedObject) ||
(TypeAt(index) == EntryType::kImmediate && obj.IsSmi()));
StorePointer<ObjectPtr, order>(&EntryAddr(index)->raw_obj_, obj.ptr());
}
uword RawValueAt(intptr_t index) const {
ASSERT(TypeAt(index) != EntryType::kTaggedObject);
return EntryAddr(index)->raw_value_;
}
void SetRawValueAt(intptr_t index, uword raw_value) const {
ASSERT(TypeAt(index) != EntryType::kTaggedObject);
StoreNonPointer(&EntryAddr(index)->raw_value_, raw_value);
}
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedObjectPool) ==
OFFSET_OF_RETURNED_VALUE(UntaggedObjectPool, data));
return 0;
}
static const intptr_t kBytesPerElement =
sizeof(UntaggedObjectPool::Entry) + sizeof(uint8_t);
static const intptr_t kMaxElements = kSmiMax / kBytesPerElement;
static intptr_t InstanceSize(intptr_t len) {
// Ensure that variable length data is not adding to the object length.
ASSERT(sizeof(UntaggedObjectPool) ==
(sizeof(UntaggedObject) + (1 * kWordSize)));
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(sizeof(UntaggedObjectPool) +
(len * kBytesPerElement));
}
static ObjectPoolPtr NewFromBuilder(
const compiler::ObjectPoolBuilder& builder);
static ObjectPoolPtr New(intptr_t len);
void CopyInto(compiler::ObjectPoolBuilder* builder) const;
// Returns the pool index from the offset relative to a tagged ObjectPoolPtr,
// adjusting for the tag-bit.
static intptr_t IndexFromOffset(intptr_t offset) {
ASSERT(
Utils::IsAligned(offset + kHeapObjectTag, compiler::target::kWordSize));
#if defined(DART_PRECOMPILER)
return (offset + kHeapObjectTag -
compiler::target::ObjectPool::element_offset(0)) /
compiler::target::kWordSize;
#else
return (offset + kHeapObjectTag - element_offset(0)) / kWordSize;
#endif
}
static intptr_t OffsetFromIndex(intptr_t index) {
return element_offset(index) - kHeapObjectTag;
}
void DebugPrint() const;
private:
UntaggedObjectPool::Entry const* EntryAddr(intptr_t index) const {
ASSERT((index >= 0) && (index < Length()));
return &untag()->data()[index];
}
FINAL_HEAP_OBJECT_IMPLEMENTATION(ObjectPool, Object);
friend class Class;
friend class Object;
friend class UntaggedObjectPool;
};
class Instructions : public Object {
public:
enum {
kSizePos = 0,
kSizeSize = 31,
kFlagsPos = kSizePos + kSizeSize,
kFlagsSize = 1, // Currently, only flag is single entry flag.
};
class SizeBits : public BitField<uint32_t, uint32_t, kSizePos, kSizeSize> {};
class FlagsBits : public BitField<uint32_t, bool, kFlagsPos, kFlagsSize> {};
// Excludes HeaderSize().
intptr_t Size() const { return SizeBits::decode(untag()->size_and_flags_); }
static intptr_t Size(const InstructionsPtr instr) {
return SizeBits::decode(instr->untag()->size_and_flags_);
}
bool HasMonomorphicEntry() const {
return FlagsBits::decode(untag()->size_and_flags_);
}
static bool HasMonomorphicEntry(const InstructionsPtr instr) {
return FlagsBits::decode(instr->untag()->size_and_flags_);
}
uword PayloadStart() const { return PayloadStart(ptr()); }
uword MonomorphicEntryPoint() const { return MonomorphicEntryPoint(ptr()); }
uword EntryPoint() const { return EntryPoint(ptr()); }
static uword PayloadStart(const InstructionsPtr instr) {
return reinterpret_cast<uword>(instr->untag()) + HeaderSize();
}
// Note: We keep the checked entrypoint offsets even (emitting NOPs if
// necessary) to allow them to be seen as Smis by the GC.
#if defined(TARGET_ARCH_IA32)
static const intptr_t kMonomorphicEntryOffsetJIT = 6;
static const intptr_t kPolymorphicEntryOffsetJIT = 34;
static const intptr_t kMonomorphicEntryOffsetAOT = 0;
static const intptr_t kPolymorphicEntryOffsetAOT = 0;
#elif defined(TARGET_ARCH_X64)
static const intptr_t kMonomorphicEntryOffsetJIT = 8;
static const intptr_t kPolymorphicEntryOffsetJIT = 40;
static const intptr_t kMonomorphicEntryOffsetAOT = 8;
static const intptr_t kPolymorphicEntryOffsetAOT = 22;
#elif defined(TARGET_ARCH_ARM)
static const intptr_t kMonomorphicEntryOffsetJIT = 0;
static const intptr_t kPolymorphicEntryOffsetJIT = 40;
static const intptr_t kMonomorphicEntryOffsetAOT = 0;
static const intptr_t kPolymorphicEntryOffsetAOT = 12;
#elif defined(TARGET_ARCH_ARM64)
static const intptr_t kMonomorphicEntryOffsetJIT = 8;
static const intptr_t kPolymorphicEntryOffsetJIT = 48;
static const intptr_t kMonomorphicEntryOffsetAOT = 8;
static const intptr_t kPolymorphicEntryOffsetAOT = 20;
#else
#error Missing entry offsets for current architecture
#endif
static uword MonomorphicEntryPoint(const InstructionsPtr instr) {
uword entry = PayloadStart(instr);
if (HasMonomorphicEntry(instr)) {
entry += !FLAG_precompiled_mode ? kMonomorphicEntryOffsetJIT
: kMonomorphicEntryOffsetAOT;
}
return entry;
}
static uword EntryPoint(const InstructionsPtr instr) {
uword entry = PayloadStart(instr);
if (HasMonomorphicEntry(instr)) {
entry += !FLAG_precompiled_mode ? kPolymorphicEntryOffsetJIT
: kPolymorphicEntryOffsetAOT;
}
return entry;
}
static const intptr_t kMaxElements =
(kMaxInt32 - (sizeof(UntaggedInstructions) + sizeof(UntaggedObject) +
(2 * kMaxObjectAlignment)));
// Currently, we align bare instruction payloads on 4 byte boundaries.
//
// If we later decide to align on larger boundaries to put entries at the
// start of cache lines, make sure to account for entry points that are
// _not_ at the start of the payload.
static const intptr_t kBarePayloadAlignment = 4;
// In non-bare mode, we align the payloads on word boundaries.
static const intptr_t kNonBarePayloadAlignment = kWordSize;
// In the precompiled runtime when running in bare instructions mode,
// Instructions objects don't exist, just their bare payloads, so we
// mark them as unreachable in that case.
static intptr_t HeaderSize() {
#if defined(DART_PRECOMPILED_RUNTIME)
if (FLAG_use_bare_instructions) {
UNREACHABLE();
}
#endif
return Utils::RoundUp(sizeof(UntaggedInstructions),
kNonBarePayloadAlignment);
}
static intptr_t InstanceSize() {
ASSERT_EQUAL(sizeof(UntaggedInstructions),
OFFSET_OF_RETURNED_VALUE(UntaggedInstructions, data));
return 0;
}
static intptr_t InstanceSize(intptr_t size) {
#if defined(DART_PRECOMPILED_RUNTIME)
if (FLAG_use_bare_instructions) {
UNREACHABLE();
}
#endif
return RoundedAllocationSize(HeaderSize() + size);
}
static InstructionsPtr FromPayloadStart(uword payload_start) {
#if defined(DART_PRECOMPILED_RUNTIME)
if (FLAG_use_bare_instructions) {
UNREACHABLE();
}
#endif
return static_cast<InstructionsPtr>(payload_start - HeaderSize() +
kHeapObjectTag);
}
bool Equals(const Instructions& other) const {
return Equals(ptr(), other.ptr());
}
static bool Equals(InstructionsPtr a, InstructionsPtr b) {
if (Size(a) != Size(b)) return false;
NoSafepointScope no_safepoint;
return memcmp(a->untag(), b->untag(), InstanceSize(Size(a))) == 0;
}
uint32_t Hash() const {
return HashBytes(reinterpret_cast<const uint8_t*>(PayloadStart()), Size());
}
CodeStatistics* stats() const;
void set_stats(CodeStatistics* stats) const;
private:
friend struct RelocatorTestHelper;
void SetSize(intptr_t value) const {
ASSERT(value >= 0);
StoreNonPointer(&untag()->size_and_flags_,
SizeBits::update(value, untag()->size_and_flags_));
}
void SetHasMonomorphicEntry(bool value) const {
StoreNonPointer(&untag()->size_and_flags_,
FlagsBits::update(value, untag()->size_and_flags_));
}
// New is a private method as RawInstruction and RawCode objects should
// only be created using the Code::FinalizeCode method. This method creates
// the RawInstruction and RawCode objects, sets up the pointer offsets
// and links the two in a GC safe manner.
static InstructionsPtr New(intptr_t size, bool has_monomorphic_entry);
FINAL_HEAP_OBJECT_IMPLEMENTATION(Instructions, Object);
friend class Class;
friend class Code;
friend class AssemblyImageWriter;
friend class BlobImageWriter;
friend class ImageWriter;
};
// An InstructionsSection contains extra information about serialized AOT
// snapshots.
//
// To avoid changing the embedder to return more information about an AOT
// snapshot and possibly disturbing existing clients of that interface, we
// serialize a single InstructionsSection object at the start of any text
// segments. In bare instructions mode, it also has the benefit of providing
// memory accounting for the instructions payloads and avoiding special casing
// Images with bare instructions payloads in the GC. Otherwise, it is empty
// and the Instructions objects come after it in the Image.
class InstructionsSection : public Object {
public:
// Excludes HeaderSize().
static intptr_t Size(const InstructionsSectionPtr instr) {
return instr->untag()->payload_length_;
}
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedInstructionsSection) ==
OFFSET_OF_RETURNED_VALUE(UntaggedInstructionsSection, data));
return 0;
}
static intptr_t InstanceSize(intptr_t size) {
return Utils::RoundUp(HeaderSize() + size, kObjectAlignment);
}
static intptr_t HeaderSize() {
return Utils::RoundUp(sizeof(UntaggedInstructionsSection),
Instructions::kBarePayloadAlignment);
}
// There are no public instance methods for the InstructionsSection class, as
// all access to the contents is handled by methods on the Image class.
private:
// Note there are no New() methods for InstructionsSection. Instead, the
// serializer writes the UntaggedInstructionsSection object manually at the
// start of instructions Images in precompiled snapshots.
FINAL_HEAP_OBJECT_IMPLEMENTATION(InstructionsSection, Object);
friend class Class;
};
// Table which maps ranges of machine code to [Code] or
// [CompressedStackMaps] objects.
// Used in AOT in bare instructions mode.
class InstructionsTable : public Object {
public:
static const intptr_t kBytesPerElement = sizeof(uint32_t);
static const intptr_t kMaxElements = kIntptrMax / kBytesPerElement;
static const uint32_t kHasMonomorphicEntrypointFlag = 0x1;
static const uint32_t kPayloadAlignment = Instructions::kBarePayloadAlignment;
static const uint32_t kPayloadMask = ~(kPayloadAlignment - 1);
COMPILE_ASSERT((kPayloadMask & kHasMonomorphicEntrypointFlag) == 0);
struct ArrayTraits {
static intptr_t elements_start_offset() {
return sizeof(UntaggedInstructionsTable);
}
static constexpr intptr_t kElementSize = kBytesPerElement;
};
static intptr_t InstanceSize() {
ASSERT_EQUAL(sizeof(UntaggedInstructionsTable),
OFFSET_OF_RETURNED_VALUE(UntaggedInstructionsTable, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(sizeof(UntaggedInstructionsTable) +
len * kBytesPerElement);
}
static InstructionsTablePtr New(intptr_t length,
uword start_pc,
uword end_pc);
void SetEntryAt(intptr_t index,
uword payload_start,
bool has_monomorphic_entrypoint,
ObjectPtr descriptor) const;
bool ContainsPc(uword pc) const { return ContainsPc(ptr(), pc); }
static bool ContainsPc(InstructionsTablePtr table, uword pc);
// Looks for the entry in the [table] by the given [pc].
// Returns index of an entry which contains [pc], or -1 if not found.
static intptr_t FindEntry(InstructionsTablePtr table, uword pc);
intptr_t length() const { return InstructionsTable::length(this->ptr()); }
static intptr_t length(InstructionsTablePtr table) {
return table->untag()->length_;
}
// Returns descriptor object for the entry with given index.
ObjectPtr DescriptorAt(intptr_t index) const {
return InstructionsTable::DescriptorAt(this->ptr(), index);
}
static ObjectPtr DescriptorAt(InstructionsTablePtr table, intptr_t index);
// Returns start address of the instructions entry with given index.
uword PayloadStartAt(intptr_t index) const {
return InstructionsTable::PayloadStartAt(this->ptr(), index);
}
static uword PayloadStartAt(InstructionsTablePtr table, intptr_t index);
// Returns entry point of the instructions with given index.
uword EntryPointAt(intptr_t index) const;
private:
uword start_pc() const { return InstructionsTable::start_pc(this->ptr()); }
static uword start_pc(InstructionsTablePtr table) {
return table->untag()->start_pc_;
}
uword end_pc() const { return InstructionsTable::end_pc(this->ptr()); }
static uword end_pc(InstructionsTablePtr table) {
return table->untag()->end_pc_;
}
ArrayPtr descriptors() const { return untag()->descriptors_; }
static uint32_t DataAt(InstructionsTablePtr table, intptr_t index) {
ASSERT((0 <= index) && (index < InstructionsTable::length(table)));
return table->untag()->data()[index];
}
uint32_t PcOffsetAt(intptr_t index) const {
return InstructionsTable::PcOffsetAt(this->ptr(), index);
}
static uint32_t PcOffsetAt(InstructionsTablePtr table, intptr_t index) {
return DataAt(table, index) & kPayloadMask;
}
bool HasMonomorphicEntryPointAt(intptr_t index) const {
return (DataAt(this->ptr(), index) & kHasMonomorphicEntrypointFlag) != 0;
}
void set_length(intptr_t value) const;
void set_start_pc(uword value) const;
void set_end_pc(uword value) const;
void set_descriptors(const Array& value) const;
uint32_t ConvertPcToOffset(uword pc) const {
return InstructionsTable::ConvertPcToOffset(this->ptr(), pc);
}
static uint32_t ConvertPcToOffset(InstructionsTablePtr table, uword pc);
FINAL_HEAP_OBJECT_IMPLEMENTATION(InstructionsTable, Object);
friend class Class;
};
class LocalVarDescriptors : public Object {
public:
intptr_t Length() const;
StringPtr GetName(intptr_t var_index) const;
void SetVar(intptr_t var_index,
const String& name,
UntaggedLocalVarDescriptors::VarInfo* info) const;
void GetInfo(intptr_t var_index,
UntaggedLocalVarDescriptors::VarInfo* info) const;
static const intptr_t kBytesPerElement =
sizeof(UntaggedLocalVarDescriptors::VarInfo);
static const intptr_t kMaxElements = UntaggedLocalVarDescriptors::kMaxIndex;
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedLocalVarDescriptors) ==
OFFSET_OF_RETURNED_VALUE(UntaggedLocalVarDescriptors, names));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(
sizeof(UntaggedLocalVarDescriptors) +
(len * kWordSize) // RawStrings for names.
+ (len * sizeof(UntaggedLocalVarDescriptors::VarInfo)));
}
static LocalVarDescriptorsPtr New(intptr_t num_variables);
static const char* KindToCString(
UntaggedLocalVarDescriptors::VarInfoKind kind);
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(LocalVarDescriptors, Object);
friend class Class;
friend class Object;
};
class PcDescriptors : public Object {
public:
static const intptr_t kBytesPerElement = 1;
static const intptr_t kMaxElements = kMaxInt32 / kBytesPerElement;
static intptr_t HeaderSize() { return sizeof(UntaggedPcDescriptors); }
static intptr_t UnroundedSize(PcDescriptorsPtr desc) {
return UnroundedSize(desc->untag()->length_);
}
static intptr_t UnroundedSize(intptr_t len) { return HeaderSize() + len; }
static intptr_t InstanceSize() {
ASSERT_EQUAL(sizeof(UntaggedPcDescriptors),
OFFSET_OF_RETURNED_VALUE(UntaggedPcDescriptors, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(UnroundedSize(len));
}
static PcDescriptorsPtr New(const void* delta_encoded_data, intptr_t size);
// Verify (assert) assumptions about pc descriptors in debug mode.
void Verify(const Function& function) const;
static void PrintHeaderString();
void PrintToJSONObject(JSONObject* jsobj, bool ref) const;
// We would have a VisitPointers function here to traverse the
// pc descriptors table to visit objects if any in the table.
// Note: never return a reference to a UntaggedPcDescriptors::PcDescriptorRec
// as the object can move.
class Iterator : ValueObject {
public:
Iterator(const PcDescriptors& descriptors, intptr_t kind_mask)
: descriptors_(descriptors),
kind_mask_(kind_mask),
byte_index_(0),
cur_pc_offset_(0),
cur_kind_(0),
cur_deopt_id_(0),
cur_token_pos_(0),
cur_try_index_(0),
cur_yield_index_(UntaggedPcDescriptors::kInvalidYieldIndex) {}
bool MoveNext() {
NoSafepointScope scope;
ReadStream stream(descriptors_.untag()->data(), descriptors_.Length(),
byte_index_);
// Moves to record that matches kind_mask_.
while (byte_index_ < descriptors_.Length()) {
const int32_t kind_and_metadata = stream.ReadSLEB128<int32_t>();
cur_kind_ = UntaggedPcDescriptors::KindAndMetadata::DecodeKind(
kind_and_metadata);
cur_try_index_ = UntaggedPcDescriptors::KindAndMetadata::DecodeTryIndex(
kind_and_metadata);
cur_yield_index_ =
UntaggedPcDescriptors::KindAndMetadata::DecodeYieldIndex(
kind_and_metadata);
cur_pc_offset_ += stream.ReadSLEB128();
if (!FLAG_precompiled_mode) {
cur_deopt_id_ += stream.ReadSLEB128();
cur_token_pos_ = Utils::AddWithWrapAround(
cur_token_pos_, stream.ReadSLEB128<int32_t>());
}
byte_index_ = stream.Position();
if ((cur_kind_ & kind_mask_) != 0) {
return true; // Current is valid.
}
}
return false;
}
uword PcOffset() const { return cur_pc_offset_; }
intptr_t DeoptId() const { return cur_deopt_id_; }
TokenPosition TokenPos() const {
return TokenPosition::Deserialize(cur_token_pos_);
}
intptr_t TryIndex() const { return cur_try_index_; }
intptr_t YieldIndex() const { return cur_yield_index_; }
UntaggedPcDescriptors::Kind Kind() const {
return static_cast<UntaggedPcDescriptors::Kind>(cur_kind_);
}
private:
friend class PcDescriptors;
// For nested iterations, starting at element after.
explicit Iterator(const Iterator& iter)
: ValueObject(),
descriptors_(iter.descriptors_),
kind_mask_(iter.kind_mask_),
byte_index_(iter.byte_index_),
cur_pc_offset_(iter.cur_pc_offset_),
cur_kind_(iter.cur_kind_),
cur_deopt_id_(iter.cur_deopt_id_),
cur_token_pos_(iter.cur_token_pos_),
cur_try_index_(iter.cur_try_index_),
cur_yield_index_(iter.cur_yield_index_) {}
const PcDescriptors& descriptors_;
const intptr_t kind_mask_;
intptr_t byte_index_;
intptr_t cur_pc_offset_;
intptr_t cur_kind_;
intptr_t cur_deopt_id_;
int32_t cur_token_pos_;
intptr_t cur_try_index_;
intptr_t cur_yield_index_;
};
intptr_t Length() const;
bool Equals(const PcDescriptors& other) const {
if (Length() != other.Length()) {
return false;
}
NoSafepointScope no_safepoint;
return memcmp(untag(), other.untag(), InstanceSize(Length())) == 0;
}
private:
static const char* KindAsStr(UntaggedPcDescriptors::Kind kind);
static PcDescriptorsPtr New(intptr_t length);
void SetLength(intptr_t value) const;
void CopyData(const void* bytes, intptr_t size);
FINAL_HEAP_OBJECT_IMPLEMENTATION(PcDescriptors, Object);
friend class Class;
friend class Object;
};
class CodeSourceMap : public Object {
public:
static const intptr_t kBytesPerElement = 1;
static const intptr_t kMaxElements = kMaxInt32 / kBytesPerElement;
static intptr_t HeaderSize() { return sizeof(UntaggedCodeSourceMap); }
static intptr_t UnroundedSize(CodeSourceMapPtr map) {
return UnroundedSize(map->untag()->length_);
}
static intptr_t UnroundedSize(intptr_t len) { return HeaderSize() + len; }
static intptr_t InstanceSize() {
ASSERT_EQUAL(sizeof(UntaggedCodeSourceMap),
OFFSET_OF_RETURNED_VALUE(UntaggedCodeSourceMap, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(UnroundedSize(len));
}
static CodeSourceMapPtr New(intptr_t length);
intptr_t Length() const { return untag()->length_; }
uint8_t* Data() const { return UnsafeMutableNonPointer(&untag()->data()[0]); }
bool Equals(const CodeSourceMap& other) const {
if (Length() != other.Length()) {
return false;
}
NoSafepointScope no_safepoint;
return memcmp(untag(), other.untag(), InstanceSize(Length())) == 0;
}
void PrintToJSONObject(JSONObject* jsobj, bool ref) const;
private:
void SetLength(intptr_t value) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(CodeSourceMap, Object);
friend class Class;
friend class Object;
};
class CompressedStackMaps : public Object {
public:
static const intptr_t kHashBits = 30;
uintptr_t payload_size() const { return PayloadSizeOf(ptr()); }
static uintptr_t PayloadSizeOf(const CompressedStackMapsPtr raw) {
return UntaggedCompressedStackMaps::SizeField::decode(
raw->untag()->flags_and_size_);
}
// Methods to allow use with PointerKeyValueTrait to create sets of CSMs.
bool Equals(const CompressedStackMaps& other) const {
// All of the table flags and payload size must match.
if (untag()->flags_and_size_ != other.untag()->flags_and_size_) {
return false;
}
NoSafepointScope no_safepoint;
return memcmp(untag(), other.untag(), InstanceSize(payload_size())) == 0;
}
uword Hash() const;
static intptr_t HeaderSize() { return sizeof(UntaggedCompressedStackMaps); }
static intptr_t UnroundedSize(CompressedStackMapsPtr maps) {
return UnroundedSize(CompressedStackMaps::PayloadSizeOf(maps));
}
static intptr_t UnroundedSize(intptr_t length) {
return HeaderSize() + length;
}
static intptr_t InstanceSize() {
ASSERT_EQUAL(sizeof(UntaggedCompressedStackMaps),
OFFSET_OF_RETURNED_VALUE(UntaggedCompressedStackMaps, data));
return 0;
}
static intptr_t InstanceSize(intptr_t length) {
return RoundedAllocationSize(UnroundedSize(length));
}
bool UsesGlobalTable() const { return UsesGlobalTable(ptr()); }
static bool UsesGlobalTable(const CompressedStackMapsPtr raw) {
return UntaggedCompressedStackMaps::UsesTableBit::decode(
raw->untag()->flags_and_size_);
}
bool IsGlobalTable() const { return IsGlobalTable(ptr()); }
static bool IsGlobalTable(const CompressedStackMapsPtr raw) {
return UntaggedCompressedStackMaps::GlobalTableBit::decode(
raw->untag()->flags_and_size_);
}
static CompressedStackMapsPtr NewInlined(const void* payload, intptr_t size) {
return New(payload, size, /*is_global_table=*/false,
/*uses_global_table=*/false);
}
static CompressedStackMapsPtr NewUsingTable(const void* payload,
intptr_t size) {
return New(payload, size, /*is_global_table=*/false,
/*uses_global_table=*/true);
}
static CompressedStackMapsPtr NewGlobalTable(const void* payload,
intptr_t size) {
return New(payload, size, /*is_global_table=*/true,
/*uses_global_table=*/false);
}
class Iterator {
public:
Iterator(const CompressedStackMaps& maps,
const CompressedStackMaps& global_table);
Iterator(Thread* thread, const CompressedStackMaps& maps);
explicit Iterator(const CompressedStackMaps::Iterator& it);
// Loads the next entry from [maps_], if any. If [maps_] is the null value,
// this always returns false.
bool MoveNext();
// Finds the entry with the given PC offset starting at the current position
// of the iterator. If [maps_] is the null value, this always returns false.
bool Find(uint32_t pc_offset) {
// We should never have an entry with a PC offset of 0 inside an
// non-empty CSM, so fail.
if (pc_offset == 0) return false;
do {
if (current_pc_offset_ >= pc_offset) break;
} while (MoveNext());
return current_pc_offset_ == pc_offset;
}
// Methods for accessing parts of an entry should not be called until
// a successful MoveNext() or Find() call has been made.
// Returns the PC offset of the loaded entry.
uint32_t pc_offset() const {
ASSERT(HasLoadedEntry());
return current_pc_offset_;
}
// Returns the bit length of the loaded entry.
intptr_t Length() const;
// Returns the number of spill slot bits of the loaded entry.
intptr_t SpillSlotBitCount() const;
// Returns whether the stack entry represented by the offset contains
// a tagged objecet.
bool IsObject(intptr_t bit_offset) const;
void WriteToBuffer(BaseTextBuffer* buffer, const char* separator) const;
private:
bool HasLoadedEntry() const { return next_offset_ > 0; }
// Caches the corresponding values from the global table in the mutable
// fields. We lazily load these as some clients only need the PC offset.
void LazyLoadGlobalTableEntry() const;
void EnsureFullyLoadedEntry() const {
ASSERT(HasLoadedEntry());
if (current_spill_slot_bit_count_ < 0) {
LazyLoadGlobalTableEntry();
ASSERT(current_spill_slot_bit_count_ >= 0);
}
}
const CompressedStackMaps& maps_;
const CompressedStackMaps& bits_container_;
uintptr_t next_offset_ = 0;
uint32_t current_pc_offset_ = 0;
// Only used when looking up non-PC information in the global table.
uintptr_t current_global_table_offset_ = 0;
// Marked as mutable as these fields may be updated with lazily loaded
// values from the global table when their associated accessor is called,
// but those values will never change for a given entry once loaded..
mutable intptr_t current_spill_slot_bit_count_ = -1;
mutable intptr_t current_non_spill_slot_bit_count_ = -1;
mutable intptr_t current_bits_offset_ = -1;
friend class StackMapEntry;
};
private:
static CompressedStackMapsPtr New(const void* payload,
intptr_t size,
bool is_global_table,
bool uses_global_table);
FINAL_HEAP_OBJECT_IMPLEMENTATION(CompressedStackMaps, Object);
friend class Class;
};
class ExceptionHandlers : public Object {
public:
static const intptr_t kInvalidPcOffset = 0;
intptr_t num_entries() const;
void GetHandlerInfo(intptr_t try_index, ExceptionHandlerInfo* info) const;
uword HandlerPCOffset(intptr_t try_index) const;
intptr_t OuterTryIndex(intptr_t try_index) const;
bool NeedsStackTrace(intptr_t try_index) const;
bool IsGenerated(intptr_t try_index) const;
void SetHandlerInfo(intptr_t try_index,
intptr_t outer_try_index,
uword handler_pc_offset,
bool needs_stacktrace,
bool has_catch_all,
bool is_generated) const;
ArrayPtr GetHandledTypes(intptr_t try_index) const;
void SetHandledTypes(intptr_t try_index, const Array& handled_types) const;
bool HasCatchAll(intptr_t try_index) const;
struct ArrayTraits {
static intptr_t elements_start_offset() {
return sizeof(UntaggedExceptionHandlers);
}
static constexpr intptr_t kElementSize = sizeof(ExceptionHandlerInfo);
};
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedExceptionHandlers) ==
OFFSET_OF_RETURNED_VALUE(UntaggedExceptionHandlers, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
return RoundedAllocationSize(sizeof(UntaggedExceptionHandlers) +
(len * sizeof(ExceptionHandlerInfo)));
}
static ExceptionHandlersPtr New(intptr_t num_handlers);
static ExceptionHandlersPtr New(const Array& handled_types_data);
// We would have a VisitPointers function here to traverse the
// exception handler table to visit objects if any in the table.
private:
// Pick somewhat arbitrary maximum number of exception handlers
// for a function. This value is used to catch potentially
// malicious code.
static const intptr_t kMaxHandlers = 1024 * 1024;
void set_handled_types_data(const Array& value) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(ExceptionHandlers, Object);
friend class Class;
friend class Object;
};
// A WeakSerializationReference (WSR) denotes a type of weak reference to a
// target object. In particular, objects that can only be reached from roots via
// WSR edges during serialization of AOT snapshots should not be serialized, but
// instead references to these objects should be replaced with a reference to
// the provided replacement object.
//
// Of course, the target object may still be serialized if there are paths to
// the object from the roots that do not go through one of these objects. In
// this case, references through WSRs are serialized as direct references to
// the target.
//
// Unfortunately a WSR is not a proxy for the original object, so WSRs may
// only currently be used with ObjectPtr fields. To ease this situation for
// fields that are normally a non-ObjectPtr type outside of the precompiler,
// use the following macros, which avoid the need to adjust other code to
// handle the WSR case:
//
// * WSR_*POINTER_FIELD() in raw_object.h (i.e., just append WSR_ to the
// original field declaration).
// * PRECOMPILER_WSR_FIELD_DECLARATION() in object.h
// * PRECOMPILER_WSR_FIELD_DEFINITION() in object.cc
class WeakSerializationReference : public Object {
public:
ObjectPtr target() const { return TargetOf(ptr()); }
static ObjectPtr TargetOf(const WeakSerializationReferencePtr obj) {
return obj->untag()->target();
}
static ObjectPtr Unwrap(ObjectPtr obj) {
#if defined(DART_PRECOMPILER)
if (obj->IsHeapObject() && obj->IsWeakSerializationReference()) {
return TargetOf(static_cast<WeakSerializationReferencePtr>(obj));
}
#endif
return obj;
}
static ObjectPtr Unwrap(const Object& obj) { return Unwrap(obj.ptr()); }
static ObjectPtr UnwrapIfTarget(ObjectPtr obj) { return Unwrap(obj); }
static ObjectPtr UnwrapIfTarget(const Object& obj) { return Unwrap(obj); }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedWeakSerializationReference));
}
// Returns an ObjectPtr as the target may not need wrapping (e.g., it
// is guaranteed to be serialized).
static ObjectPtr New(const Object& target, const Object& replacement);
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(WeakSerializationReference, Object);
ObjectPtr replacement() const { return untag()->replacement(); }
friend class Class;
};
class Code : public Object {
public:
// When dual mapping, this returns the executable view.
InstructionsPtr active_instructions() const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
return NULL;
#else
return untag()->active_instructions();
#endif
}
// When dual mapping, these return the executable view.
InstructionsPtr instructions() const { return untag()->instructions(); }
static InstructionsPtr InstructionsOf(const CodePtr code) {
return code->untag()->instructions();
}
static intptr_t saved_instructions_offset() {
return OFFSET_OF(UntaggedCode, instructions_);
}
using EntryKind = CodeEntryKind;
static const char* EntryKindToCString(EntryKind kind);
static bool ParseEntryKind(const char* str, EntryKind* out);
static intptr_t entry_point_offset(EntryKind kind = EntryKind::kNormal) {
switch (kind) {
case EntryKind::kNormal:
return OFFSET_OF(UntaggedCode, entry_point_);
case EntryKind::kUnchecked:
return OFFSET_OF(UntaggedCode, unchecked_entry_point_);
case EntryKind::kMonomorphic:
return OFFSET_OF(UntaggedCode, monomorphic_entry_point_);
case EntryKind::kMonomorphicUnchecked:
return OFFSET_OF(UntaggedCode, monomorphic_unchecked_entry_point_);
default:
UNREACHABLE();
}
}
ObjectPoolPtr object_pool() const { return untag()->object_pool(); }
static intptr_t object_pool_offset() {
return OFFSET_OF(UntaggedCode, object_pool_);
}
intptr_t pointer_offsets_length() const {
return PtrOffBits::decode(untag()->state_bits_);
}
bool is_optimized() const {
return OptimizedBit::decode(untag()->state_bits_);
}
void set_is_optimized(bool value) const;
static bool IsOptimized(CodePtr code) {
return Code::OptimizedBit::decode(code->untag()->state_bits_);
}
bool is_force_optimized() const {
return ForceOptimizedBit::decode(untag()->state_bits_);
}
void set_is_force_optimized(bool value) const;
bool is_alive() const { return AliveBit::decode(untag()->state_bits_); }
void set_is_alive(bool value) const;
bool is_discarded() const { return IsDiscarded(ptr()); }
static bool IsDiscarded(const CodePtr code) {
return DiscardedBit::decode(code->untag()->state_bits_);
}
void set_is_discarded(bool value) const;
bool HasMonomorphicEntry() const { return HasMonomorphicEntry(ptr()); }
static bool HasMonomorphicEntry(const CodePtr code) {
#if defined(DART_PRECOMPILED_RUNTIME)
return code->untag()->entry_point_ !=
code->untag()->monomorphic_entry_point_;
#else
return Instructions::HasMonomorphicEntry(InstructionsOf(code));
#endif
}
// Returns the payload start of [instructions()].
uword PayloadStart() const { return PayloadStartOf(ptr()); }
static uword PayloadStartOf(const CodePtr code) {
#if defined(DART_PRECOMPILED_RUNTIME)
if (IsUnknownDartCode(code)) return 0;
const uword entry_offset = HasMonomorphicEntry(code)
? Instructions::kPolymorphicEntryOffsetAOT
: 0;
return EntryPointOf(code) - entry_offset;
#else
return Instructions::PayloadStart(InstructionsOf(code));
#endif
}
// Returns the entry point of [instructions()].
uword EntryPoint() const { return EntryPointOf(ptr()); }
static uword EntryPointOf(const CodePtr code) {
#if defined(DART_PRECOMPILED_RUNTIME)
return code->untag()->entry_point_;
#else
return Instructions::EntryPoint(InstructionsOf(code));
#endif
}
// Returns the unchecked entry point of [instructions()].
uword UncheckedEntryPoint() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return untag()->unchecked_entry_point_;
#else
return EntryPoint() + untag()->unchecked_offset_;
#endif
}
// Returns the monomorphic entry point of [instructions()].
uword MonomorphicEntryPoint() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return untag()->monomorphic_entry_point_;
#else
return Instructions::MonomorphicEntryPoint(instructions());
#endif
}
// Returns the unchecked monomorphic entry point of [instructions()].
uword MonomorphicUncheckedEntryPoint() const {
#if defined(DART_PRECOMPILED_RUNTIME)
return untag()->monomorphic_unchecked_entry_point_;
#else
return MonomorphicEntryPoint() + untag()->unchecked_offset_;
#endif
}
// Returns the size of [instructions()].
uword Size() const { return PayloadSizeOf(ptr()); }
static uword PayloadSizeOf(const CodePtr code) {
#if defined(DART_PRECOMPILED_RUNTIME)
if (IsUnknownDartCode(code)) return kUwordMax;
return code->untag()->instructions_length_;
#else
return Instructions::Size(InstructionsOf(code));
#endif
}
ObjectPoolPtr GetObjectPool() const;
// Returns whether the given PC address is in [instructions()].
bool ContainsInstructionAt(uword addr) const {
return ContainsInstructionAt(ptr(), addr);
}
// Returns whether the given PC address is in [InstructionsOf(code)].
static bool ContainsInstructionAt(const CodePtr code, uword pc) {
return UntaggedCode::ContainsPC(code, pc);
}
// Returns true if there is a debugger breakpoint set in this code object.
bool HasBreakpoint() const;
PcDescriptorsPtr pc_descriptors() const { return untag()->pc_descriptors(); }
void set_pc_descriptors(const PcDescriptors& descriptors) const {
ASSERT(descriptors.IsOld());
untag()->set_pc_descriptors(descriptors.ptr());
}
CodeSourceMapPtr code_source_map() const {
return untag()->code_source_map();
}
void set_code_source_map(const CodeSourceMap& code_source_map) const {
ASSERT(code_source_map.IsOld());
untag()->set_code_source_map(code_source_map.ptr());
}
// Array of DeoptInfo objects.
ArrayPtr deopt_info_array() const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
return NULL;
#else
return untag()->deopt_info_array();
#endif
}
void set_deopt_info_array(const Array& array) const;
#if !defined(DART_PRECOMPILED_RUNTIME)
intptr_t num_variables() const;
void set_num_variables(intptr_t num_variables) const;
#endif
#if defined(DART_PRECOMPILED_RUNTIME) || defined(DART_PRECOMPILER)
TypedDataPtr catch_entry_moves_maps() const;
void set_catch_entry_moves_maps(const TypedData& maps) const;
#endif
CompressedStackMapsPtr compressed_stackmaps() const {
return untag()->compressed_stackmaps();
}
void set_compressed_stackmaps(const CompressedStackMaps& maps) const;
enum CallKind {
kPcRelativeCall = 1,
kPcRelativeTTSCall = 2,
kPcRelativeTailCall = 3,
kCallViaCode = 4,
};
enum CallEntryPoint {
kDefaultEntry,
kUncheckedEntry,
};
enum SCallTableEntry {
kSCallTableKindAndOffset = 0,
kSCallTableCodeOrTypeTarget = 1,
kSCallTableFunctionTarget = 2,
kSCallTableEntryLength = 3,
};
enum class PoolAttachment {
kAttachPool,
kNotAttachPool,
};
class KindField : public BitField<intptr_t, CallKind, 0, 3> {};
class EntryPointField
: public BitField<intptr_t, CallEntryPoint, KindField::kNextBit, 1> {};
class OffsetField
: public BitField<intptr_t, intptr_t, EntryPointField::kNextBit, 26> {};
void set_static_calls_target_table(const Array& value) const;
ArrayPtr static_calls_target_table() const {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
return NULL;
#else
return untag()->static_calls_target_table();
#endif
}
TypedDataPtr GetDeoptInfoAtPc(uword pc,
ICData::DeoptReasonId* deopt_reason,
uint32_t* deopt_flags) const;
// Returns null if there is no static call at 'pc'.
FunctionPtr GetStaticCallTargetFunctionAt(uword pc) const;
// Aborts if there is no static call at 'pc'.
void SetStaticCallTargetCodeAt(uword pc, const Code& code) const;
void SetStubCallTargetCodeAt(uword pc, const Code& code) const;
void Disassemble(DisassemblyFormatter* formatter = NULL) const;
#if defined(INCLUDE_IL_PRINTER)
class Comments : public ZoneAllocated, public CodeComments {
public:
static Comments& New(intptr_t count);
intptr_t Length() const override;
void SetPCOffsetAt(intptr_t idx, intptr_t pc_offset);
void SetCommentAt(intptr_t idx, const String& comment);
intptr_t PCOffsetAt(intptr_t idx) const override;
const char* CommentAt(intptr_t idx) const override;
private:
explicit Comments(const Array& comments);
// Layout of entries describing comments.
enum {kPCOffsetEntry = 0, // PC offset to a comment as a Smi.
kCommentEntry, // Comment text as a String.
kNumberOfEntries};
const Array& comments_;
String& string_;
friend class Code;
DISALLOW_COPY_AND_ASSIGN(Comments);
};
const CodeComments& comments() const;
void set_comments(const CodeComments& comments) const;
#endif // defined(INCLUDE_IL_PRINTER)
ObjectPtr return_address_metadata() const {
#if defined(PRODUCT)
UNREACHABLE();
return NULL;
#else
return untag()->return_address_metadata();
#endif
}
// Sets |return_address_metadata|.
void SetPrologueOffset(intptr_t offset) const;
// Returns -1 if no prologue offset is available.
intptr_t GetPrologueOffset() const;
ArrayPtr inlined_id_to_function() const;
void set_inlined_id_to_function(const Array& value) const;
// Provides the call stack at the given pc offset, with the top-of-stack in
// the last element and the root function (this) as the first element, along
// with the corresponding source positions. Note the token position for each
// function except the top-of-stack is the position of the call to the next
// function. The stack will be empty if we lack the metadata to produce it,
// which happens for stub code.
// The pc offset is interpreted as an instruction address (as needed by the
// disassembler or the top frame of a profiler sample).
void GetInlinedFunctionsAtInstruction(
intptr_t pc_offset,
GrowableArray<const Function*>* functions,
GrowableArray<TokenPosition>* token_positions) const;
// Same as above, except the pc is interpreted as a return address (as needed
// for a stack trace or the bottom frames of a profiler sample).
void GetInlinedFunctionsAtReturnAddress(
intptr_t pc_offset,
GrowableArray<const Function*>* functions,
GrowableArray<TokenPosition>* token_positions) const {
GetInlinedFunctionsAtInstruction(pc_offset - 1, functions, token_positions);
}
NOT_IN_PRODUCT(void PrintJSONInlineIntervals(JSONObject* object) const);
void DumpInlineIntervals() const;
void DumpSourcePositions(bool relative_addresses = false) const;
LocalVarDescriptorsPtr var_descriptors() const {
#if defined(PRODUCT)
UNREACHABLE();
return NULL;
#else
return untag()->var_descriptors();
#endif
}
void set_var_descriptors(const LocalVarDescriptors& value) const {
#if defined(PRODUCT)
UNREACHABLE();
#else
ASSERT(value.IsOld());
untag()->set_var_descriptors(value.ptr());
#endif
}
// Will compute local var descriptors if necessary.
LocalVarDescriptorsPtr GetLocalVarDescriptors() const;
ExceptionHandlersPtr exception_handlers() const {
return untag()->exception_handlers();
}
void set_exception_handlers(const ExceptionHandlers& handlers) const {
ASSERT(handlers.IsOld());
untag()->set_exception_handlers(handlers.ptr());
}
// WARNING: function() returns the owner which is not guaranteed to be
// a Function. It is up to the caller to guarantee it isn't a stub, class,
// or something else.
// TODO(turnidge): Consider dropping this function and making
// everybody use owner(). Currently this function is misused - even
// while generating the snapshot.
FunctionPtr function() const {
ASSERT(IsFunctionCode());
return Function::RawCast(owner());
}
ObjectPtr owner() const {
return WeakSerializationReference::Unwrap(untag()->owner());
}
void set_owner(const Object& owner) const;
classid_t OwnerClassId() const { return OwnerClassIdOf(ptr()); }
static classid_t OwnerClassIdOf(CodePtr raw) {
ObjectPtr owner = WeakSerializationReference::Unwrap(raw->untag()->owner());
if (!owner->IsHeapObject()) {
return RawSmiValue(static_cast<SmiPtr>(owner));
}
return owner->GetClassId();
}
static intptr_t owner_offset() { return OFFSET_OF(UntaggedCode, owner_); }
// We would have a VisitPointers function here to traverse all the
// embedded objects in the instructions using pointer_offsets.
static const intptr_t kBytesPerElement =
sizeof(reinterpret_cast<UntaggedCode*>(0)->data()[0]);
static const intptr_t kMaxElements = kSmiMax / kBytesPerElement;
struct ArrayTraits {
static intptr_t elements_start_offset() { return sizeof(UntaggedCode); }
static constexpr intptr_t kElementSize = kBytesPerElement;
};
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedCode) ==
OFFSET_OF_RETURNED_VALUE(UntaggedCode, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(sizeof(UntaggedCode) +
(len * kBytesPerElement));
}
#if !defined(DART_PRECOMPILED_RUNTIME)
// Finalizes the generated code, by generating various kinds of metadata (e.g.
// stack maps, pc descriptors, ...) and attach them to a newly generated
// [Code] object.
//
// If Code::PoolAttachment::kAttachPool is specified for [pool_attachment]
// then a new [ObjectPool] will be attached to the code object as well.
// Otherwise the caller is responsible for doing this via
// `Object::set_object_pool()`.
static CodePtr FinalizeCode(FlowGraphCompiler* compiler,
compiler::Assembler* assembler,
PoolAttachment pool_attachment,
bool optimized,
CodeStatistics* stats);
// Notifies all active [CodeObserver]s.
static void NotifyCodeObservers(const Code& code, bool optimized);
static void NotifyCodeObservers(const Function& function,
const Code& code,
bool optimized);
static void NotifyCodeObservers(const char* name,
const Code& code,
bool optimized);
// Calls [FinalizeCode] and also notifies [CodeObserver]s.
static CodePtr FinalizeCodeAndNotify(const Function& function,
FlowGraphCompiler* compiler,
compiler::Assembler* assembler,
PoolAttachment pool_attachment,
bool optimized = false,
CodeStatistics* stats = nullptr);
static CodePtr FinalizeCodeAndNotify(const char* name,
FlowGraphCompiler* compiler,
compiler::Assembler* assembler,
PoolAttachment pool_attachment,
bool optimized = false,
CodeStatistics* stats = nullptr);
#endif
static CodePtr LookupCode(uword pc);
static CodePtr LookupCodeInVmIsolate(uword pc);
static CodePtr FindCode(uword pc, int64_t timestamp);
int32_t GetPointerOffsetAt(int index) const {
NoSafepointScope no_safepoint;
return *PointerOffsetAddrAt(index);
}
TokenPosition GetTokenIndexOfPC(uword pc) const;
// Find pc, return 0 if not found.
uword GetPcForDeoptId(intptr_t deopt_id,
UntaggedPcDescriptors::Kind kind) const;
intptr_t GetDeoptIdForOsr(uword pc) const;
const char* Name() const;
const char* QualifiedName(const NameFormattingParams& params) const;
int64_t compile_timestamp() const {
#if defined(PRODUCT)
return 0;
#else
return untag()->compile_timestamp_;
#endif
}
bool IsStubCode() const;
bool IsAllocationStubCode() const;
bool IsTypeTestStubCode() const;
bool IsFunctionCode() const;
// Returns true if this Code object represents
// Dart function code without any additional information.
bool IsUnknownDartCode() const { return IsUnknownDartCode(ptr()); }
static bool IsUnknownDartCode(CodePtr code);
void DisableDartCode() const;
void DisableStubCode() const;
void Enable() const {
if (!IsDisabled()) return;
ResetActiveInstructions();
}
bool IsDisabled() const { return IsDisabled(ptr()); }
static bool IsDisabled(CodePtr code) {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
return false;
#else
return code->untag()->instructions() !=
code->untag()->active_instructions();
#endif
}
void set_object_pool(ObjectPoolPtr object_pool) const {
untag()->set_object_pool(object_pool);
}
private:
void set_state_bits(intptr_t bits) const;
friend class UntaggedObject; // For UntaggedObject::SizeFromClass().
friend class UntaggedCode;
friend struct RelocatorTestHelper;
enum {
kOptimizedBit = 0,
kForceOptimizedBit = 1,
kAliveBit = 2,
kDiscardedBit = 3,
kPtrOffBit = 4,
kPtrOffSize = kBitsPerInt32 - kPtrOffBit,
};
class OptimizedBit : public BitField<int32_t, bool, kOptimizedBit, 1> {};
// Force-optimized is true if the Code was generated for a function with
// Function::ForceOptimize().
class ForceOptimizedBit
: public BitField<int32_t, bool, kForceOptimizedBit, 1> {};
class AliveBit : public BitField<int32_t, bool, kAliveBit, 1> {};
// Set by precompiler if this Code object doesn't contain
// useful information besides instructions and compressed stack map.
// Such objects are serialized in a shorter form and replaced with
// StubCode::UnknownDartCode() during snapshot deserialization.
class DiscardedBit : public BitField<int32_t, bool, kDiscardedBit, 1> {};
class PtrOffBits
: public BitField<int32_t, intptr_t, kPtrOffBit, kPtrOffSize> {};
class SlowFindRawCodeVisitor : public FindObjectVisitor {
public:
explicit SlowFindRawCodeVisitor(uword pc) : pc_(pc) {}
virtual ~SlowFindRawCodeVisitor() {}
// Check if object matches find condition.
virtual bool FindObject(ObjectPtr obj) const;
private:
const uword pc_;
DISALLOW_COPY_AND_ASSIGN(SlowFindRawCodeVisitor);
};
static const intptr_t kEntrySize = sizeof(int32_t); // NOLINT
void set_compile_timestamp(int64_t timestamp) const {
#if defined(PRODUCT)
UNREACHABLE();
#else
StoreNonPointer(&untag()->compile_timestamp_, timestamp);
#endif
}
// Initializes the cached entrypoint addresses in [code] as calculated
// from [instructions] and [unchecked_offset].
static void InitializeCachedEntryPointsFrom(CodePtr code,
InstructionsPtr instructions,
uint32_t unchecked_offset);
// Sets [active_instructions_] to [instructions] and updates the cached
// entry point addresses.
void SetActiveInstructions(const Instructions& instructions,
uint32_t unchecked_offset) const;
void SetActiveInstructionsSafe(const Instructions& instructions,
uint32_t unchecked_offset) const;
// Resets [active_instructions_] to its original value of [instructions_] and
// updates the cached entry point addresses to match.
void ResetActiveInstructions() const;
void set_instructions(const Instructions& instructions) const {
ASSERT(Thread::Current()->IsMutatorThread() || !is_alive());
untag()->set_instructions(instructions.ptr());
}
#if !defined(DART_PRECOMPILED_RUNTIME)
void set_unchecked_offset(uword offset) const {
StoreNonPointer(&untag()->unchecked_offset_, offset);
}
#endif
// Returns the unchecked entry point offset for [instructions_].
uint32_t UncheckedEntryPointOffset() const {
return UncheckedEntryPointOffsetOf(ptr());
}
static uint32_t UncheckedEntryPointOffsetOf(CodePtr code) {
#if defined(DART_PRECOMPILED_RUNTIME)
UNREACHABLE();
#else
return code->untag()->unchecked_offset_;
#endif
}
void set_pointer_offsets_length(intptr_t value) {
// The number of fixups is limited to 1-billion.
ASSERT(Utils::IsUint(30, value));
set_state_bits(PtrOffBits::update(value, untag()->state_bits_));
}
int32_t* PointerOffsetAddrAt(int index) const {
ASSERT(index >= 0);
ASSERT(index < pointer_offsets_length());
// TODO(iposva): Unit test is missing for this functionality.
return &UnsafeMutableNonPointer(untag()->data())[index];
}
void SetPointerOffsetAt(int index, int32_t offset_in_instructions) {
NoSafepointScope no_safepoint;
*PointerOffsetAddrAt(index) = offset_in_instructions;
}
intptr_t BinarySearchInSCallTable(uword pc) const;
static CodePtr LookupCodeInIsolateGroup(IsolateGroup* isolate_group,
uword pc);
// New is a private method as RawInstruction and RawCode objects should
// only be created using the Code::FinalizeCode method. This method creates
// the RawInstruction and RawCode objects, sets up the pointer offsets
// and links the two in a GC safe manner.
static CodePtr New(intptr_t pointer_offsets_length);
FINAL_HEAP_OBJECT_IMPLEMENTATION(Code, Object);
friend class Class;
friend class CodeTestHelper;
friend class SnapshotWriter;
friend class StubCode; // for set_object_pool
friend class Precompiler; // for set_object_pool
friend class FunctionSerializationCluster;
friend class CodeSerializationCluster;
friend class CodeDeserializationCluster;
friend class Deserializer; // for InitializeCachedEntryPointsFrom
friend class StubCode; // for set_object_pool
friend class MegamorphicCacheTable; // for set_object_pool
friend class CodePatcher; // for set_instructions
friend class ProgramVisitor; // for set_instructions
// So that the UntaggedFunction pointer visitor can determine whether code the
// function points to is optimized.
friend class UntaggedFunction;
friend class CallSiteResetter;
friend class CodeKeyValueTrait; // for UncheckedEntryPointOffset
};
class Context : public Object {
public:
ContextPtr parent() const { return untag()->parent(); }
void set_parent(const Context& parent) const {
untag()->set_parent(parent.ptr());
}
static intptr_t parent_offset() {
return OFFSET_OF(UntaggedContext, parent_);
}
intptr_t num_variables() const { return untag()->num_variables_; }
static intptr_t num_variables_offset() {
return OFFSET_OF(UntaggedContext, num_variables_);
}
static intptr_t NumVariables(const ContextPtr context) {
return context->untag()->num_variables_;
}
ObjectPtr At(intptr_t context_index) const {
return untag()->element(context_index);
}
inline void SetAt(intptr_t context_index, const Object& value) const;
intptr_t GetLevel() const;
void Dump(int indent = 0) const;
static const intptr_t kBytesPerElement = kWordSize;
static const intptr_t kMaxElements = kSmiMax / kBytesPerElement;
static const intptr_t kAwaitJumpVarIndex = 0;
static const intptr_t kAsyncFutureIndex = 1;
static const intptr_t kControllerIndex = 1;
// Expected context index of chained futures in recognized async functions.
// These are used to unwind async stacks.
static const intptr_t kFutureTimeoutFutureIndex = 2;
static const intptr_t kFutureWaitFutureIndex = 2;
static const intptr_t kIsSyncIndex = 2;
struct ArrayTraits {
static intptr_t elements_start_offset() { return sizeof(UntaggedContext); }
static constexpr intptr_t kElementSize = kBytesPerElement;
};
static intptr_t variable_offset(intptr_t context_index) {
return OFFSET_OF_RETURNED_VALUE(UntaggedContext, data) +
(kWordSize * context_index);
}
static bool IsValidLength(intptr_t len) {
return 0 <= len && len <= compiler::target::Array::kMaxElements;
}
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedContext) ==
OFFSET_OF_RETURNED_VALUE(UntaggedContext, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(IsValidLength(len));
return RoundedAllocationSize(sizeof(UntaggedContext) +
(len * kBytesPerElement));
}
static ContextPtr New(intptr_t num_variables, Heap::Space space = Heap::kNew);
private:
void set_num_variables(intptr_t num_variables) const {
StoreNonPointer(&untag()->num_variables_, num_variables);
}
FINAL_HEAP_OBJECT_IMPLEMENTATION(Context, Object);
friend class Class;
friend class Object;
};
// The ContextScope class makes it possible to delay the compilation of a local
// function until it is invoked. A ContextScope instance collects the local
// variables that are referenced by the local function to be compiled and that
// belong to the outer scopes, that is, to the local scopes of (possibly nested)
// functions enclosing the local function. Each captured variable is represented
// by its token position in the source, its name, its type, its allocation index
// in the context, and its context level. The function nesting level and loop
// nesting level are not preserved, since they are only used until the context
// level is assigned. In addition the ContextScope has a field 'is_implicit'
// which is true if the ContextScope was created for an implicit closure.
class ContextScope : public Object {
public:
intptr_t num_variables() const { return untag()->num_variables_; }
TokenPosition TokenIndexAt(intptr_t scope_index) const;
void SetTokenIndexAt(intptr_t scope_index, TokenPosition token_pos) const;
TokenPosition DeclarationTokenIndexAt(intptr_t scope_index) const;
void SetDeclarationTokenIndexAt(intptr_t scope_index,
TokenPosition declaration_token_pos) const;
StringPtr NameAt(intptr_t scope_index) const;
void SetNameAt(intptr_t scope_index, const String& name) const;
void ClearFlagsAt(intptr_t scope_index) const;
bool IsFinalAt(intptr_t scope_index) const;
void SetIsFinalAt(intptr_t scope_index, bool is_final) const;
bool IsLateAt(intptr_t scope_index) const;
void SetIsLateAt(intptr_t scope_index, bool is_late) const;
intptr_t LateInitOffsetAt(intptr_t scope_index) const;
void SetLateInitOffsetAt(intptr_t scope_index,
intptr_t late_init_offset) const;
bool IsConstAt(intptr_t scope_index) const;
void SetIsConstAt(intptr_t scope_index, bool is_const) const;
AbstractTypePtr TypeAt(intptr_t scope_index) const;
void SetTypeAt(intptr_t scope_index, const AbstractType& type) const;
InstancePtr ConstValueAt(intptr_t scope_index) const;
void SetConstValueAt(intptr_t scope_index, const Instance& value) const;
intptr_t ContextIndexAt(intptr_t scope_index) const;
void SetContextIndexAt(intptr_t scope_index, intptr_t context_index) const;
intptr_t ContextLevelAt(intptr_t scope_index) const;
void SetContextLevelAt(intptr_t scope_index, intptr_t context_level) const;
static const intptr_t kBytesPerElement =
sizeof(UntaggedContextScope::VariableDesc);
static const intptr_t kMaxElements = kSmiMax / kBytesPerElement;
struct ArrayTraits {
static intptr_t elements_start_offset() {
return sizeof(UntaggedContextScope);
}
static constexpr intptr_t kElementSize = kBytesPerElement;
};
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedContextScope) ==
OFFSET_OF_RETURNED_VALUE(UntaggedContextScope, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(sizeof(UntaggedContextScope) +
(len * kBytesPerElement));
}
static ContextScopePtr New(intptr_t num_variables, bool is_implicit);
private:
void set_num_variables(intptr_t num_variables) const {
StoreNonPointer(&untag()->num_variables_, num_variables);
}
void set_is_implicit(bool is_implicit) const {
StoreNonPointer(&untag()->is_implicit_, is_implicit);
}
const UntaggedContextScope::VariableDesc* VariableDescAddr(
intptr_t index) const {
ASSERT((index >= 0) && (index < num_variables()));
return untag()->VariableDescAddr(index);
}
bool GetFlagAt(intptr_t scope_index, intptr_t mask) const;
void SetFlagAt(intptr_t scope_index, intptr_t mask, bool value) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(ContextScope, Object);
friend class Class;
friend class Object;
};
// Class of special sentinel values:
// - Object::sentinel() is a value that cannot be produced by Dart code.
// It can be used to mark special values, for example to distinguish
// "uninitialized" fields.
// - Object::transition_sentinel() is a value marking that we are transitioning
// from sentinel, e.g., computing a field value. Used to detect circular
// initialization of static fields.
// - Object::unknown_constant() and Object::non_constant() are optimizing
// compiler's constant propagation constants.
class Sentinel : public Object {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedSentinel));
}
static SentinelPtr New();
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Sentinel, Object);
friend class Class;
friend class Object;
};
class MegamorphicCache : public CallSiteData {
public:
static const intptr_t kInitialCapacity = 16;
static const intptr_t kSpreadFactor = 7;
static const double kLoadFactor;
enum EntryType {
kClassIdIndex,
kTargetFunctionIndex,
kEntryLength,
};
ArrayPtr buckets() const;
void set_buckets(const Array& buckets) const;
intptr_t mask() const;
void set_mask(intptr_t mask) const;
intptr_t filled_entry_count() const;
void set_filled_entry_count(intptr_t num) const;
static intptr_t buckets_offset() {
return OFFSET_OF(UntaggedMegamorphicCache, buckets_);
}
static intptr_t mask_offset() {
return OFFSET_OF(UntaggedMegamorphicCache, mask_);
}
static intptr_t arguments_descriptor_offset() {
return OFFSET_OF(UntaggedMegamorphicCache, args_descriptor_);
}
static MegamorphicCachePtr New(const String& target_name,
const Array& arguments_descriptor);
void EnsureContains(const Smi& class_id, const Object& target) const;
ObjectPtr Lookup(const Smi& class_id) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedMegamorphicCache));
}
private:
friend class Class;
friend class MegamorphicCacheTable;
friend class ProgramVisitor;
static MegamorphicCachePtr New();
// The caller must hold IsolateGroup::type_feedback_mutex().
void InsertLocked(const Smi& class_id, const Object& target) const;
void EnsureCapacityLocked() const;
ObjectPtr LookupLocked(const Smi& class_id) const;
void InsertEntryLocked(const Smi& class_id, const Object& target) const;
static inline void SetEntry(const Array& array,
intptr_t index,
const Smi& class_id,
const Object& target);
static inline ObjectPtr GetClassId(const Array& array, intptr_t index);
static inline ObjectPtr GetTargetFunction(const Array& array, intptr_t index);
FINAL_HEAP_OBJECT_IMPLEMENTATION(MegamorphicCache, CallSiteData);
};
class SubtypeTestCache : public Object {
public:
enum Entries {
kTestResult = 0,
kInstanceCidOrSignature = 1,
kDestinationType = 2,
kInstanceTypeArguments = 3,
kInstantiatorTypeArguments = 4,
kFunctionTypeArguments = 5,
kInstanceParentFunctionTypeArguments = 6,
kInstanceDelayedFunctionTypeArguments = 7,
kTestEntryLength = 8,
};
virtual intptr_t NumberOfChecks() const;
void AddCheck(const Object& instance_class_id_or_signature,
const AbstractType& destination_type,
const TypeArguments& instance_type_arguments,
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
const TypeArguments& instance_parent_function_type_arguments,
const TypeArguments& instance_delayed_type_arguments,
const Bool& test_result) const;
void GetCheck(intptr_t ix,
Object* instance_class_id_or_signature,
AbstractType* destination_type,
TypeArguments* instance_type_arguments,
TypeArguments* instantiator_type_arguments,
TypeArguments* function_type_arguments,
TypeArguments* instance_parent_function_type_arguments,
TypeArguments* instance_delayed_type_arguments,
Bool* test_result) const;
// Like GetCheck(), but does not require the subtype test cache mutex and so
// may see an outdated view of the cache.
void GetCurrentCheck(intptr_t ix,
Object* instance_class_id_or_signature,
AbstractType* destination_type,
TypeArguments* instance_type_arguments,
TypeArguments* instantiator_type_arguments,
TypeArguments* function_type_arguments,
TypeArguments* instance_parent_function_type_arguments,
TypeArguments* instance_delayed_type_arguments,
Bool* test_result) const;
// Returns whether all the elements of an existing cache entry, excluding
// the result, match the non-pointer arguments. The pointer arguments are
// out parameters as follows:
//
// If [index] is not nullptr, then it is set to the matching entry's index.
// If [result] is not nullptr, then it is set to the matching entry's result.
bool HasCheck(const Object& instance_class_id_or_signature,
const AbstractType& destination_type,
const TypeArguments& instance_type_arguments,
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
const TypeArguments& instance_parent_function_type_arguments,
const TypeArguments& instance_delayed_type_arguments,
intptr_t* index,
Bool* result) const;
// Writes the cache entry at index [index] to the given text buffer.
//
// The output is comma separated on a single line if [line_prefix] is nullptr,
// otherwise line breaks followed by [line_prefix] is used as a separator.
void WriteEntryToBuffer(Zone* zone,
BaseTextBuffer* buffer,
intptr_t index,
const char* line_prefix = nullptr) const;
// Like WriteEntryToBuffer(), but does not require the subtype test cache
// mutex and so may see an outdated view of the cache.
void WriteCurrentEntryToBuffer(Zone* zone,
BaseTextBuffer* buffer,
intptr_t index,
const char* line_prefix = nullptr) const;
void Reset() const;
static SubtypeTestCachePtr New();
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedSubtypeTestCache));
}
static intptr_t cache_offset() {
return OFFSET_OF(UntaggedSubtypeTestCache, cache_);
}
static void Init();
static void Cleanup();
ArrayPtr cache() const;
private:
void set_cache(const Array& value) const;
// A VM heap allocated preinitialized empty subtype entry array.
static ArrayPtr cached_array_;
FINAL_HEAP_OBJECT_IMPLEMENTATION(SubtypeTestCache, Object);
friend class Class;
friend class VMSerializationRoots;
friend class VMDeserializationRoots;
};
class LoadingUnit : public Object {
public:
static constexpr intptr_t kIllegalId = 0;
COMPILE_ASSERT(kIllegalId == WeakTable::kNoValue);
static constexpr intptr_t kRootId = 1;
static LoadingUnitPtr New();
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLoadingUnit));
}
LoadingUnitPtr parent() const;
void set_parent(const LoadingUnit& value) const;
ArrayPtr base_objects() const;
void set_base_objects(const Array& value) const;
intptr_t id() const { return untag()->id_; }
void set_id(intptr_t id) const { StoreNonPointer(&untag()->id_, id); }
// True once the VM deserializes this unit's snapshot.
bool loaded() const { return untag()->loaded_; }
void set_loaded(bool value) const {
StoreNonPointer(&untag()->loaded_, value);
}
// True once the VM invokes the embedder's deferred load callback until the
// embedder calls Dart_DeferredLoadComplete[Error].
bool load_outstanding() const { return untag()->load_outstanding_; }
void set_load_outstanding(bool value) const {
StoreNonPointer(&untag()->load_outstanding_, value);
}
ObjectPtr IssueLoad() const;
ObjectPtr CompleteLoad(const String& error_message,
bool transient_error) const;
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(LoadingUnit, Object);
friend class Class;
};
class Error : public Object {
public:
virtual const char* ToErrorCString() const;
private:
HEAP_OBJECT_IMPLEMENTATION(Error, Object);
};
class ApiError : public Error {
public:
StringPtr message() const { return untag()->message(); }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedApiError));
}
static ApiErrorPtr New(const String& message, Heap::Space space = Heap::kNew);
virtual const char* ToErrorCString() const;
private:
void set_message(const String& message) const;
static ApiErrorPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(ApiError, Error);
friend class Class;
};
class LanguageError : public Error {
public:
Report::Kind kind() const {
return static_cast<Report::Kind>(untag()->kind_);
}
// Build, cache, and return formatted message.
StringPtr FormatMessage() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLanguageError));
}
// A null script means no source and a negative token_pos means no position.
static LanguageErrorPtr NewFormatted(const Error& prev_error,
const Script& script,
TokenPosition token_pos,
bool report_after_token,
Report::Kind kind,
Heap::Space space,
const char* format,
...) PRINTF_ATTRIBUTE(7, 8);
static LanguageErrorPtr NewFormattedV(const Error& prev_error,
const Script& script,
TokenPosition token_pos,
bool report_after_token,
Report::Kind kind,
Heap::Space space,
const char* format,
va_list args);
static LanguageErrorPtr New(const String& formatted_message,
Report::Kind kind = Report::kError,
Heap::Space space = Heap::kNew);
virtual const char* ToErrorCString() const;
TokenPosition token_pos() const { return untag()->token_pos_; }
private:
ErrorPtr previous_error() const { return untag()->previous_error(); }
void set_previous_error(const Error& value) const;
ScriptPtr script() const { return untag()->script(); }
void set_script(const Script& value) const;
void set_token_pos(TokenPosition value) const;
bool report_after_token() const { return untag()->report_after_token_; }
void set_report_after_token(bool value);
void set_kind(uint8_t value) const;
StringPtr message() const { return untag()->message(); }
void set_message(const String& value) const;
StringPtr formatted_message() const { return untag()->formatted_message(); }
void set_formatted_message(const String& value) const;
static LanguageErrorPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(LanguageError, Error);
friend class Class;
};
class UnhandledException : public Error {
public:
InstancePtr exception() const { return untag()->exception(); }
static intptr_t exception_offset() {
return OFFSET_OF(UntaggedUnhandledException, exception_);
}
InstancePtr stacktrace() const { return untag()->stacktrace(); }
static intptr_t stacktrace_offset() {
return OFFSET_OF(UntaggedUnhandledException, stacktrace_);
}
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedUnhandledException));
}
static UnhandledExceptionPtr New(const Instance& exception,
const Instance& stacktrace,
Heap::Space space = Heap::kNew);
virtual const char* ToErrorCString() const;
private:
static UnhandledExceptionPtr New(Heap::Space space = Heap::kNew);
void set_exception(const Instance& exception) const;
void set_stacktrace(const Instance& stacktrace) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(UnhandledException, Error);
friend class Class;
friend class ObjectStore;
};
class UnwindError : public Error {
public:
bool is_user_initiated() const { return untag()->is_user_initiated_; }
void set_is_user_initiated(bool value) const;
StringPtr message() const { return untag()->message(); }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedUnwindError));
}
static UnwindErrorPtr New(const String& message,
Heap::Space space = Heap::kNew);
virtual const char* ToErrorCString() const;
private:
void set_message(const String& message) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(UnwindError, Error);
friend class Class;
};
// Instance is the base class for all instance objects (aka the Object class
// in Dart source code.
class Instance : public Object {
public:
// Equality and identity testing.
// 1. OperatorEquals: true iff 'this == other' is true in Dart code.
// 2. IsIdenticalTo: true iff 'identical(this, other)' is true in Dart code.
// 3. CanonicalizeEquals: used to canonicalize compile-time constants, e.g.,
// using bitwise equality of fields and list elements.
// Subclasses where 1 and 3 coincide may also define a plain Equals, e.g.,
// String and Integer.
virtual bool OperatorEquals(const Instance& other) const;
bool IsIdenticalTo(const Instance& other) const;
virtual bool CanonicalizeEquals(const Instance& other) const;
virtual uint32_t CanonicalizeHash() const;
intptr_t SizeFromClass() const {
#if defined(DEBUG)
const Class& cls = Class::Handle(clazz());
ASSERT(cls.is_finalized() || cls.is_prefinalized());
#endif
return (clazz()->untag()->host_instance_size_in_words_ *
kCompressedWordSize);
}
InstancePtr Canonicalize(Thread* thread) const;
// Caller must hold IsolateGroup::constant_canonicalization_mutex_.
virtual InstancePtr CanonicalizeLocked(Thread* thread) const;
virtual void CanonicalizeFieldsLocked(Thread* thread) const;
InstancePtr CopyShallowToOldSpace(Thread* thread) const;
#if defined(DEBUG)
// Check if instance is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
ObjectPtr GetField(const Field& field) const;
void SetField(const Field& field, const Object& value) const;
AbstractTypePtr GetType(Heap::Space space) const;
// Access the arguments of the [Type] of this [Instance].
// Note: for [Type]s instead of [Instance]s with a [Type] attached, use
// [arguments()] and [set_arguments()]
virtual TypeArgumentsPtr GetTypeArguments() const;
virtual void SetTypeArguments(const TypeArguments& value) const;
// Check if the type of this instance is a subtype of the given other type.
// The type argument vectors are used to instantiate the other type if needed.
bool IsInstanceOf(const AbstractType& other,
const TypeArguments& other_instantiator_type_arguments,
const TypeArguments& other_function_type_arguments) const;
// Check if this instance is assignable to the given other type.
// The type argument vectors are used to instantiate the other type if needed.
bool IsAssignableTo(const AbstractType& other,
const TypeArguments& other_instantiator_type_arguments,
const TypeArguments& other_function_type_arguments) const;
// Return true if the null instance can be assigned to a variable of [other]
// type. Return false if null cannot be assigned or we cannot tell (if
// [other] is a type parameter in NNBD strong mode). Only used for checks at
// compile time.
static bool NullIsAssignableTo(const AbstractType& other);
// Return true if the null instance can be assigned to a variable of [other]
// type. Return false if null cannot be assigned. Used for checks at runtime,
// when the instantiator and function type argument vectors are available.
static bool NullIsAssignableTo(
const AbstractType& other,
const TypeArguments& other_instantiator_type_arguments,
const TypeArguments& other_function_type_arguments);
bool IsValidNativeIndex(int index) const {
return ((index >= 0) && (index < clazz()->untag()->num_native_fields_));
}
intptr_t* NativeFieldsDataAddr() const;
inline intptr_t GetNativeField(int index) const;
inline void GetNativeFields(uint16_t num_fields,
intptr_t* field_values) const;
void SetNativeFields(uint16_t num_fields, const intptr_t* field_values) const;
uint16_t NumNativeFields() const {
return clazz()->untag()->num_native_fields_;
}
void SetNativeField(int index, intptr_t value) const;
// If the instance is a callable object, i.e. a closure or the instance of a
// class implementing a 'call' method, return true and set the function
// (if not NULL) to call.
bool IsCallable(Function* function) const;
ObjectPtr Invoke(const String& selector,
const Array& arguments,
const Array& argument_names,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
ObjectPtr InvokeGetter(const String& selector,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
ObjectPtr InvokeSetter(const String& selector,
const Instance& argument,
bool respect_reflectable = true,
bool check_is_entrypoint = false) const;
// Evaluate the given expression as if it appeared in an instance method of
// this instance and return the resulting value, or an error object if
// evaluating the expression fails. The method has the formal (type)
// parameters given in (type_)param_names, and is invoked with the (type)
// argument values given in (type_)param_values.
ObjectPtr EvaluateCompiledExpression(
const Class& method_cls,
const ExternalTypedData& kernel_buffer,
const Array& type_definitions,
const Array& param_values,
const TypeArguments& type_param_values) const;
// Equivalent to invoking hashCode on this instance.
virtual ObjectPtr HashCode() const;
// Equivalent to invoking identityHashCode with this instance.
ObjectPtr IdentityHashCode() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedInstance));
}
static InstancePtr New(const Class& cls, Heap::Space space = Heap::kNew);
// Array/list element address computations.
static intptr_t DataOffsetFor(intptr_t cid);
static intptr_t ElementSizeFor(intptr_t cid);
// Pointers may be subtyped, but their subtypes may not get extra fields.
// The subtype runtime representation has exactly the same object layout,
// only the class_id is different. So, it is safe to use subtype instances in
// Pointer handles.
virtual bool IsPointer() const;
static intptr_t NextFieldOffset() { return sizeof(UntaggedInstance); }
protected:
#ifndef PRODUCT
virtual void PrintSharedInstanceJSON(JSONObject* jsobj, bool ref) const;
#endif
private:
// Return true if the runtimeType of this instance is a subtype of other type.
bool RuntimeTypeIsSubtypeOf(
const AbstractType& other,
const TypeArguments& other_instantiator_type_arguments,
const TypeArguments& other_function_type_arguments) const;
// Returns true if the type of this instance is a subtype of FutureOr<T>
// specified by instantiated type 'other'.
// Returns false if other type is not a FutureOr.
bool RuntimeTypeIsSubtypeOfFutureOr(Zone* zone,
const AbstractType& other) const;
// Return true if the null instance is an instance of other type.
static bool NullIsInstanceOf(
const AbstractType& other,
const TypeArguments& other_instantiator_type_arguments,
const TypeArguments& other_function_type_arguments);
CompressedObjectPtr* FieldAddrAtOffset(intptr_t offset) const {
ASSERT(IsValidFieldOffset(offset));
return reinterpret_cast<CompressedObjectPtr*>(raw_value() - kHeapObjectTag +
offset);
}
CompressedObjectPtr* FieldAddr(const Field& field) const {
return FieldAddrAtOffset(field.HostOffset());
}
CompressedObjectPtr* NativeFieldsAddr() const {
return FieldAddrAtOffset(sizeof(UntaggedObject));
}
void SetFieldAtOffset(intptr_t offset, const Object& value) const {
StoreCompressedPointer(FieldAddrAtOffset(offset), value.ptr());
}
bool IsValidFieldOffset(intptr_t offset) const;
// The following raw methods are used for morphing.
// They are needed due to the extraction of the class in IsValidFieldOffset.
CompressedObjectPtr* RawFieldAddrAtOffset(intptr_t offset) const {
return reinterpret_cast<CompressedObjectPtr*>(raw_value() - kHeapObjectTag +
offset);
}
ObjectPtr RawGetFieldAtOffset(intptr_t offset) const {
return RawFieldAddrAtOffset(offset)->Decompress(untag()->heap_base());
}
void RawSetFieldAtOffset(intptr_t offset, const Object& value) const {
StoreCompressedPointer(RawFieldAddrAtOffset(offset), value.ptr());
}
static InstancePtr NewFromCidAndSize(SharedClassTable* shared_class_table,
classid_t cid,
Heap::Space heap = Heap::kNew);
// TODO(iposva): Determine if this gets in the way of Smi.
HEAP_OBJECT_IMPLEMENTATION(Instance, Object);
friend class ByteBuffer;
friend class Class;
friend class Closure;
friend class Pointer;
friend class DeferredObject;
friend class RegExp;
friend class SnapshotWriter;
friend class StubCode;
friend class TypedDataView;
friend class InstanceSerializationCluster;
friend class InstanceDeserializationCluster;
friend class ClassDeserializationCluster; // vtable
friend class InstanceMorpher;
friend class Obfuscator; // RawGetFieldAtOffset, RawSetFieldAtOffset
};
class LibraryPrefix : public Instance {
public:
StringPtr name() const { return untag()->name(); }
virtual StringPtr DictionaryName() const { return name(); }
ArrayPtr imports() const { return untag()->imports(); }
intptr_t num_imports() const { return untag()->num_imports_; }
LibraryPtr importer() const { return untag()->importer(); }
LibraryPtr GetLibrary(int index) const;
void AddImport(const Namespace& import) const;
bool is_deferred_load() const { return untag()->is_deferred_load_; }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLibraryPrefix));
}
static LibraryPrefixPtr New(const String& name,
const Namespace& import,
bool deferred_load,
const Library& importer);
private:
static const int kInitialSize = 2;
static const int kIncrementSize = 2;
void set_name(const String& value) const;
void set_imports(const Array& value) const;
void set_num_imports(intptr_t value) const;
void set_importer(const Library& value) const;
static LibraryPrefixPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(LibraryPrefix, Instance);
friend class Class;
};
// TypeParameters represents a list of formal type parameters with their bounds
// and their default values as calculated by CFE.
class TypeParameters : public Object {
public:
intptr_t Length() const;
static intptr_t names_offset() {
return OFFSET_OF(UntaggedTypeParameters, names_);
}
StringPtr NameAt(intptr_t index) const;
void SetNameAt(intptr_t index, const String& value) const;
static intptr_t flags_offset() {
return OFFSET_OF(UntaggedTypeParameters, flags_);
}
static intptr_t bounds_offset() {
return OFFSET_OF(UntaggedTypeParameters, bounds_);
}
AbstractTypePtr BoundAt(intptr_t index) const;
void SetBoundAt(intptr_t index, const AbstractType& value) const;
bool AllDynamicBounds() const;
static intptr_t defaults_offset() {
return OFFSET_OF(UntaggedTypeParameters, defaults_);
}
AbstractTypePtr DefaultAt(intptr_t index) const;
void SetDefaultAt(intptr_t index, const AbstractType& value) const;
bool AllDynamicDefaults() const;
// The isGenericCovariantImpl bits are packed into SMIs in the flags array,
// but omitted if they're 0.
bool IsGenericCovariantImplAt(intptr_t index) const;
void SetIsGenericCovariantImplAt(intptr_t index, bool value) const;
// The number of flags per Smi should be a power of 2 in order to simplify the
// generated code accessing the flags array.
#if !defined(DART_COMPRESSED_POINTERS)
static const intptr_t kFlagsPerSmiShift = kBitsPerWordLog2 - 1;
#else
static const intptr_t kFlagsPerSmiShift = kBitsPerWordLog2 - 2;
#endif
static const intptr_t kFlagsPerSmi = 1LL << kFlagsPerSmiShift;
COMPILE_ASSERT(kFlagsPerSmi < kSmiBits);
static const intptr_t kFlagsPerSmiMask = kFlagsPerSmi - 1;
void Print(Thread* thread,
Zone* zone,
bool are_class_type_parameters,
intptr_t base,
NameVisibility name_visibility,
BaseTextBuffer* printer) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedTypeParameters));
}
static TypeParametersPtr New(Heap::Space space = Heap::kOld);
static TypeParametersPtr New(intptr_t count, Heap::Space space = Heap::kOld);
private:
ArrayPtr names() const { return untag()->names(); }
void set_names(const Array& value) const;
ArrayPtr flags() const { return untag()->flags(); }
void set_flags(const Array& value) const;
TypeArgumentsPtr bounds() const { return untag()->bounds(); }
void set_bounds(const TypeArguments& value) const;
TypeArgumentsPtr defaults() const { return untag()->defaults(); }
void set_defaults(const TypeArguments& value) const;
// Allocate and initialize the flags array to zero.
void AllocateFlags(Heap::Space space) const;
// Reset the flags array to null if all flags are zero.
void OptimizeFlags() const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(TypeParameters, Object);
friend class Class;
friend class ClassFinalizer;
friend class Function;
friend class FunctionType;
friend class Object;
friend class Precompiler;
};
// A TypeArguments is an array of AbstractType.
class TypeArguments : public Instance {
public:
// We use 30 bits for the hash code so hashes in a snapshot taken on a
// 64-bit architecture stay in Smi range when loaded on a 32-bit
// architecture.
static const intptr_t kHashBits = 30;
// Hash value for a type argument vector consisting solely of dynamic types.
static const intptr_t kAllDynamicHash = 1;
// Returns whether this TypeArguments vector can be used in a context that
// expects a vector of length [count]. Always true for the null vector.
bool HasCount(intptr_t count) const;
static intptr_t length_offset() {
return OFFSET_OF(UntaggedTypeArguments, length_);
}
intptr_t Length() const;
AbstractTypePtr TypeAt(intptr_t index) const;
AbstractTypePtr TypeAtNullSafe(intptr_t index) const;
static intptr_t types_offset() {
return OFFSET_OF_RETURNED_VALUE(UntaggedTypeArguments, types);
}
static intptr_t type_at_offset(intptr_t index) {
return types_offset() + index * kCompressedWordSize;
}
void SetTypeAt(intptr_t index, const AbstractType& value) const;
struct ArrayTraits {
static intptr_t elements_start_offset() {
return TypeArguments::types_offset();
}
static constexpr intptr_t kElementSize = kCompressedWordSize;
};
// The nullability of a type argument vector represents the nullability of its
// type elements (up to a maximum number of them, i.e. kNullabilityMaxTypes).
// It is used at runtime in some cases (predetermined by the compiler) to
// decide whether the instantiator type arguments (ITA) can be shared instead
// of performing a more costly instantiation of the uninstantiated type
// arguments (UTA).
// The vector nullability is stored as a bit vector (in a Smi field), using
// 2 bits per type:
// - the high bit is set if the type is nullable or legacy.
// - the low bit is set if the type is nullable.
// The nullability is 0 if the vector is longer than kNullabilityMaxTypes.
// The condition evaluated at runtime to decide whether UTA can share ITA is
// (UTA.nullability & ITA.nullability) == UTA.nullability
// Note that this allows for ITA to be longer than UTA (the bit vector must be
// stored in the same order as the corresponding type vector, i.e. with the
// least significant 2 bits representing the nullability of the first type).
static const intptr_t kNullabilityBitsPerType = 2;
static const intptr_t kNullabilityMaxTypes =
kSmiBits / kNullabilityBitsPerType;
static const intptr_t kNonNullableBits = 0;
static const intptr_t kNullableBits = 3;
static const intptr_t kLegacyBits = 2;
intptr_t nullability() const;
static intptr_t nullability_offset() {
return OFFSET_OF(UntaggedTypeArguments, nullability_);
}
// The name of this type argument vector, e.g. "<T, dynamic, List<T>, Smi>".
StringPtr Name() const;
// The name of this type argument vector, e.g. "<T, dynamic, List<T>, int>".
// Names of internal classes are mapped to their public interfaces.
StringPtr UserVisibleName() const;
// Print the internal or public name of a subvector of this type argument
// vector, e.g. "<T, dynamic, List<T>, int>".
void PrintSubvectorName(intptr_t from_index,
intptr_t len,
NameVisibility name_visibility,
BaseTextBuffer* printer) const;
void PrintTo(BaseTextBuffer* printer) const;
// Check if the subvector of length 'len' starting at 'from_index' of this
// type argument vector consists solely of DynamicType.
bool IsRaw(intptr_t from_index, intptr_t len) const {
return IsDynamicTypes(false, from_index, len);
}
// Check if this type argument vector would consist solely of DynamicType if
// it was instantiated from both a raw (null) instantiator type arguments and
// a raw (null) function type arguments, i.e. consider each class type
// parameter and function type parameters as it would be first instantiated
// from a vector of dynamic types.
// Consider only a prefix of length 'len'.
bool IsRawWhenInstantiatedFromRaw(intptr_t len) const {
return IsDynamicTypes(true, 0, len);
}
// Return true if this vector contains a TypeRef.
bool IsRecursive(TrailPtr trail = nullptr) const;
// Return true if this vector contains a non-nullable type.
bool RequireConstCanonicalTypeErasure(Zone* zone,
intptr_t from_index,
intptr_t len,
TrailPtr trail = nullptr) const;
TypeArgumentsPtr Prepend(Zone* zone,
const TypeArguments& other,
intptr_t other_length,
intptr_t total_length) const;
// Concatenate [this] and [other] vectors of type parameters.
TypeArgumentsPtr ConcatenateTypeParameters(Zone* zone,
const TypeArguments& other) const;
// Check if the vectors are equal (they may be null).
bool Equals(const TypeArguments& other) const {
return IsSubvectorEquivalent(other, 0, IsNull() ? 0 : Length(),
TypeEquality::kCanonical);
}
bool IsEquivalent(const TypeArguments& other,
TypeEquality kind,
TrailPtr trail = nullptr) const {
// Make a null vector a vector of dynamic as long as the other vector.
return IsSubvectorEquivalent(other, 0, IsNull() ? other.Length() : Length(),
kind, trail);
}
bool IsSubvectorEquivalent(const TypeArguments& other,
intptr_t from_index,
intptr_t len,
TypeEquality kind,
TrailPtr trail = nullptr) const;
// Check if the vector is instantiated (it must not be null).
bool IsInstantiated(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const {
return IsSubvectorInstantiated(0, Length(), genericity,
num_free_fun_type_params, trail);
}
bool IsSubvectorInstantiated(intptr_t from_index,
intptr_t len,
Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
bool IsUninstantiatedIdentity() const;
// Determine whether this uninstantiated type argument vector can share its
// instantiator (resp. function) type argument vector instead of being
// instantiated at runtime.
// If null is passed in for 'with_runtime_check', the answer is unconditional
// (i.e. the answer will be false even if a runtime check may allow sharing),
// otherwise, in case the function returns true, 'with_runtime_check'
// indicates if a check is still required at runtime before allowing sharing.
bool CanShareInstantiatorTypeArguments(
const Class& instantiator_class,
bool* with_runtime_check = nullptr) const;
bool CanShareFunctionTypeArguments(const Function& function,
bool* with_runtime_check = nullptr) const;
// Return true if all types of this vector are finalized.
bool IsFinalized() const;
// Caller must hold IsolateGroup::constant_canonicalization_mutex_.
virtual InstancePtr CanonicalizeLocked(Thread* thread) const {
return Canonicalize(thread, nullptr);
}
// Canonicalize only if instantiated, otherwise returns 'this'.
TypeArgumentsPtr Canonicalize(Thread* thread, TrailPtr trail = nullptr) const;
// Add the class name and URI of each type argument of this vector to the uris
// list and mark ambiguous triplets to be printed.
void EnumerateURIs(URIs* uris) const;
// Return 'this' if this type argument vector is instantiated, i.e. if it does
// not refer to type parameters. Otherwise, return a new type argument vector
// where each reference to a type parameter is replaced with the corresponding
// type from the various type argument vectors (class instantiator, function,
// or parent functions via the current context).
TypeArgumentsPtr InstantiateFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
intptr_t num_free_fun_type_params,
Heap::Space space,
TrailPtr trail = nullptr) const;
// Runtime instantiation with canonicalization. Not to be used during type
// finalization at compile time.
TypeArgumentsPtr InstantiateAndCanonicalizeFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments) const;
// Each cached instantiation consists of a 3-tuple in the instantiations_
// array stored in each canonical uninstantiated type argument vector.
enum Instantiation {
kInstantiatorTypeArgsIndex = 0,
kFunctionTypeArgsIndex,
kInstantiatedTypeArgsIndex,
kSizeInWords,
};
// The array is terminated by the value kNoInstantiator occuring in place of
// the instantiator type args of the 4-tuple that would otherwise follow.
// Therefore, kNoInstantiator must be distinct from any type arguments vector,
// even a null one. Since arrays are initialized with 0, the instantiations_
// array is properly terminated upon initialization.
static const intptr_t kNoInstantiator = 0;
// Return true if this type argument vector has cached instantiations.
bool HasInstantiations() const;
// Return the number of cached instantiations for this type argument vector.
intptr_t NumInstantiations() const;
static intptr_t instantiations_offset() {
return OFFSET_OF(UntaggedTypeArguments, instantiations_);
}
static const intptr_t kBytesPerElement = kCompressedWordSize;
static const intptr_t kMaxElements = kSmiMax / kBytesPerElement;
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedTypeArguments) ==
OFFSET_OF_RETURNED_VALUE(UntaggedTypeArguments, types));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
// Ensure that the types() is not adding to the object size, which includes
// 4 fields: instantiations_, length_, hash_, and nullability_.
ASSERT(sizeof(UntaggedTypeArguments) ==
(sizeof(UntaggedObject) + (kNumFields * kCompressedWordSize)));
ASSERT(0 <= len && len <= kMaxElements);
return RoundedAllocationSize(sizeof(UntaggedTypeArguments) +
(len * kBytesPerElement));
}
virtual uint32_t CanonicalizeHash() const {
// Hash() is not stable until finalization is done.
return 0;
}
uword Hash() const;
uword HashForRange(intptr_t from_index, intptr_t len) const;
static TypeArgumentsPtr New(intptr_t len, Heap::Space space = Heap::kOld);
private:
intptr_t ComputeNullability() const;
void set_nullability(intptr_t value) const;
uword ComputeHash() const;
void SetHash(intptr_t value) const;
// Check if the subvector of length 'len' starting at 'from_index' of this
// type argument vector consists solely of DynamicType.
// If raw_instantiated is true, consider each class type parameter to be first
// instantiated from a vector of dynamic types.
bool IsDynamicTypes(bool raw_instantiated,
intptr_t from_index,
intptr_t len) const;
ArrayPtr instantiations() const;
void set_instantiations(const Array& value) const;
void SetLength(intptr_t value) const;
// Number of fields in the raw object is 4:
// instantiations_, length_, hash_ and nullability_.
static const int kNumFields = 4;
FINAL_HEAP_OBJECT_IMPLEMENTATION(TypeArguments, Instance);
friend class AbstractType;
friend class Class;
friend class ClearTypeHashVisitor;
friend class Object;
};
// AbstractType is an abstract superclass.
// Subclasses of AbstractType are Type and TypeParameter.
class AbstractType : public Instance {
public:
// We use 30 bits for the hash code so hashes in a snapshot taken on a
// 64-bit architecture stay in Smi range when loaded on a 32-bit
// architecture.
static const intptr_t kHashBits = 30;
virtual bool IsFinalized() const;
virtual void SetIsFinalized() const;
virtual bool IsBeingFinalized() const;
virtual void SetIsBeingFinalized() const;
virtual Nullability nullability() const;
// Returns true if type has '?' nullability suffix, or it is a
// built-in type which is always nullable (Null, dynamic or void).
bool IsNullable() const { return nullability() == Nullability::kNullable; }
// Returns true if type does not have any nullability suffix.
// This function also returns true for type parameters without
// nullability suffix ("T") which can be instantiated with
// nullable or legacy types.
bool IsNonNullable() const {
return nullability() == Nullability::kNonNullable;
}
// Returns true if type has '*' nullability suffix, i.e.
// it is from a legacy (opted-out) library.
bool IsLegacy() const { return nullability() == Nullability::kLegacy; }
// Returns true if it is guaranteed that null cannot be
// assigned to this type.
bool IsStrictlyNonNullable() const;
virtual AbstractTypePtr SetInstantiatedNullability(
const TypeParameter& type_param,
Heap::Space space) const;
virtual AbstractTypePtr NormalizeFutureOrType(Heap::Space space) const;
virtual bool HasTypeClass() const { return type_class_id() != kIllegalCid; }
virtual classid_t type_class_id() const;
virtual ClassPtr type_class() const;
virtual TypeArgumentsPtr arguments() const;
virtual void set_arguments(const TypeArguments& value) const;
virtual bool IsInstantiated(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
virtual bool CanonicalizeEquals(const Instance& other) const {
return Equals(other);
}
virtual uint32_t CanonicalizeHash() const { return Hash(); }
virtual bool Equals(const Instance& other) const {
return IsEquivalent(other, TypeEquality::kCanonical);
}
virtual bool IsEquivalent(const Instance& other,
TypeEquality kind,
TrailPtr trail = nullptr) const;
virtual bool IsRecursive(TrailPtr trail = nullptr) const;
virtual bool RequireConstCanonicalTypeErasure(Zone* zone,
TrailPtr trail = nullptr) const;
// Instantiate this type using the given type argument vectors.
//
// Note that some type parameters appearing in this type may not require
// instantiation. Consider a class C<T> declaring a non-generic method
// foo(bar<B>(T t, B b)). Although foo is not a generic method, it takes a
// generic function bar<B> as argument and its function type refers to class
// type parameter T and function type parameter B. When instantiating the
// function type of foo for a particular value of T, function type parameter B
// must remain uninstantiated, because only T is a free variable in this type.
//
// Return a new type, or return 'this' if it is already instantiated.
virtual AbstractTypePtr InstantiateFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
intptr_t num_free_fun_type_params,
Heap::Space space,
TrailPtr trail = nullptr) const;
// Caller must hold IsolateGroup::constant_canonicalization_mutex_.
virtual InstancePtr CanonicalizeLocked(Thread* thread) const {
return Canonicalize(thread, nullptr);
}
// Return the canonical version of this type.
virtual AbstractTypePtr Canonicalize(Thread* thread, TrailPtr trail) const;
#if defined(DEBUG)
// Check if abstract type is canonical.
virtual bool CheckIsCanonical(Thread* thread) const {
UNREACHABLE();
return false;
}
#endif // DEBUG
// Return the object associated with the receiver in the trail or
// AbstractType::null() if the receiver is not contained in the trail.
AbstractTypePtr OnlyBuddyInTrail(TrailPtr trail) const;
// If the trail is null, allocate a trail, add the pair <receiver, buddy> to
// the trail. The receiver may only be added once with its only buddy.
void AddOnlyBuddyToTrail(TrailPtr* trail, const AbstractType& buddy) const;
// Return true if the receiver is contained in the trail.
// Otherwise, if the trail is null, allocate a trail, then add the receiver to
// the trail and return false.
bool TestAndAddToTrail(TrailPtr* trail) const;
// Return true if the pair <receiver, buddy> is contained in the trail.
// Otherwise, if the trail is null, allocate a trail, add the pair <receiver,
// buddy> to the trail and return false.
// The receiver may be added several times, each time with a different buddy.
bool TestAndAddBuddyToTrail(TrailPtr* trail, const AbstractType& buddy) const;
// Add the pair <name, uri> to the list, if not already present.
static void AddURI(URIs* uris, const String& name, const String& uri);
// Return a formatted string of the uris.
static StringPtr PrintURIs(URIs* uris);
// Returns a C-String (possibly "") representing the nullability of this type.
// Legacy and undetermined suffixes are only displayed with kInternalName.
virtual const char* NullabilitySuffix(NameVisibility name_visibility) const;
// The name of this type, including the names of its type arguments, if any.
virtual StringPtr Name() const;
// The name of this type, including the names of its type arguments, if any.
// Names of internal classes are mapped to their public interfaces.
virtual StringPtr UserVisibleName() const;
// The name of this type, including the names of its type arguments, if any.
// Privacy suffixes are dropped.
virtual StringPtr ScrubbedName() const;
// Return the internal or public name of this type, including the names of its
// type arguments, if any.
void PrintName(NameVisibility visibility, BaseTextBuffer* printer) const;
// Add the class name and URI of each occuring type to the uris
// list and mark ambiguous triplets to be printed.
virtual void EnumerateURIs(URIs* uris) const;
virtual uword Hash() const;
// The name of this type's class, i.e. without the type argument names of this
// type.
StringPtr ClassName() const;
// Check if this type is a still uninitialized TypeRef.
bool IsNullTypeRef() const;
// Check if this type represents the 'dynamic' type.
bool IsDynamicType() const { return type_class_id() == kDynamicCid; }
// Check if this type represents the 'void' type.
bool IsVoidType() const { return type_class_id() == kVoidCid; }
// Check if this type represents the 'Null' type.
bool IsNullType() const;
// Check if this type represents the 'Never' type.
bool IsNeverType() const;
// Check if this type represents the 'Sentinel' type.
bool IsSentinelType() const;
// Check if this type represents the 'Object' type.
bool IsObjectType() const { return type_class_id() == kInstanceCid; }
// Check if this type represents a top type for subtyping,
// assignability and 'as' type tests.
//
// Returns true if
// - any type is a subtype of this type;
// - any value can be assigned to a variable of this type;
// - 'as' type test always succeeds for this type.
bool IsTopTypeForSubtyping() const;
// Check if this type represents a top type for 'is' type tests.
// Returns true if 'is' type test always returns true for this type.
bool IsTopTypeForInstanceOf() const;
// Check if this type represents the 'bool' type.
bool IsBoolType() const { return type_class_id() == kBoolCid; }
// Check if this type represents the 'int' type.
bool IsIntType() const;
// Check if this type represents the '_IntegerImplementation' type.
bool IsIntegerImplementationType() const;
// Check if this type represents the 'double' type.
bool IsDoubleType() const;
// Check if this type represents the 'Float32x4' type.
bool IsFloat32x4Type() const;
// Check if this type represents the 'Float64x2' type.
bool IsFloat64x2Type() const;
// Check if this type represents the 'Int32x4' type.
bool IsInt32x4Type() const;
// Check if this type represents the 'num' type.
bool IsNumberType() const { return type_class_id() == kNumberCid; }
// Check if this type represents the '_Smi' type.
bool IsSmiType() const { return type_class_id() == kSmiCid; }
// Check if this type represents the '_Mint' type.
bool IsMintType() const { return type_class_id() == kMintCid; }
// Check if this type represents the 'String' type.
bool IsStringType() const;
// Check if this type represents the Dart 'Function' type.
bool IsDartFunctionType() const;
// Check if this type represents the Dart '_Closure' type.
bool IsDartClosureType() const;
// Check if this type represents the 'Pointer' type from "dart:ffi".
bool IsFfiPointerType() const;
// Check if this type represents the 'FutureOr' type.
bool IsFutureOrType() const { return type_class_id() == kFutureOrCid; }
// Returns the type argument of this (possibly nested) 'FutureOr' type.
// Returns unmodified type if this type is not a 'FutureOr' type.
AbstractTypePtr UnwrapFutureOr() const;
// Returns true if catching this type will catch all exceptions.
// Exception objects are guaranteed to be non-nullable, so
// non-nullable Object is also a catch-all type.
bool IsCatchAllType() const { return IsDynamicType() || IsObjectType(); }
// Check the subtype relationship.
bool IsSubtypeOf(const AbstractType& other,
Heap::Space space,
TrailPtr trail = nullptr) const;
// Returns true iff subtype is a subtype of supertype, false otherwise or if
// an error occurred.
static bool InstantiateAndTestSubtype(
AbstractType* subtype,
AbstractType* supertype,
const TypeArguments& instantiator_type_args,
const TypeArguments& function_type_args);
static intptr_t type_test_stub_entry_point_offset() {
return OFFSET_OF(UntaggedAbstractType, type_test_stub_entry_point_);
}
uword type_test_stub_entry_point() const {
return untag()->type_test_stub_entry_point_;
}
CodePtr type_test_stub() const { return untag()->type_test_stub(); }
// Sets the TTS to [stub].
//
// The update will ensure both fields (code as well as the cached entrypoint)
// are updated together.
//
// Can be used concurrently by multiple threads - the updates will be applied
// in undetermined order - but always consistently.
void SetTypeTestingStub(const Code& stub) const;
// Sets the TTS to the [stub].
//
// The caller has to ensure no other thread can concurrently try to update the
// TTS. This should mainly be used when initializing newly allocated Type
// objects.
void InitializeTypeTestingStubNonAtomic(const Code& stub) const;
void UpdateTypeTestingStubEntryPoint() const {
StoreNonPointer(&untag()->type_test_stub_entry_point_,
Code::EntryPointOf(untag()->type_test_stub()));
}
// No instances of type AbstractType are allocated, but InstanceSize() and
// NextFieldOffset() are required to register class _AbstractType.
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedAbstractType));
}
static intptr_t NextFieldOffset() { return -kWordSize; }
private:
// Returns true if this type is a subtype of FutureOr<T> specified by 'other'.
// Returns false if other type is not a FutureOr.
bool IsSubtypeOfFutureOr(Zone* zone,
const AbstractType& other,
Heap::Space space,
TrailPtr trail = nullptr) const;
protected:
HEAP_OBJECT_IMPLEMENTATION(AbstractType, Instance);
friend class Class;
friend class Function;
friend class TypeArguments;
};
// A Type consists of a class, possibly parameterized with type
// arguments. Example: C<T1, T2>.
class Type : public AbstractType {
public:
static intptr_t type_class_id_offset() {
return OFFSET_OF(UntaggedType, type_class_id_);
}
static intptr_t arguments_offset() {
return OFFSET_OF(UntaggedType, arguments_);
}
static intptr_t type_state_offset() {
return OFFSET_OF(UntaggedType, type_state_);
}
static intptr_t hash_offset() { return OFFSET_OF(UntaggedType, hash_); }
static intptr_t nullability_offset() {
return OFFSET_OF(UntaggedType, nullability_);
}
virtual bool IsFinalized() const {
return (untag()->type_state_ == UntaggedType::kFinalizedInstantiated) ||
(untag()->type_state_ == UntaggedType::kFinalizedUninstantiated);
}
virtual void SetIsFinalized() const;
virtual bool IsBeingFinalized() const {
return untag()->type_state_ == UntaggedType::kBeingFinalized;
}
virtual void SetIsBeingFinalized() const;
virtual bool HasTypeClass() const {
ASSERT(type_class_id() != kIllegalCid);
return true;
}
virtual Nullability nullability() const {
return static_cast<Nullability>(untag()->nullability_);
}
TypePtr ToNullability(Nullability value, Heap::Space space) const;
virtual classid_t type_class_id() const;
virtual ClassPtr type_class() const;
void set_type_class(const Class& value) const;
virtual TypeArgumentsPtr arguments() const { return untag()->arguments(); }
virtual void set_arguments(const TypeArguments& value) const;
virtual bool IsInstantiated(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
virtual bool IsEquivalent(const Instance& other,
TypeEquality kind,
TrailPtr trail = nullptr) const;
virtual bool IsRecursive(TrailPtr trail = nullptr) const;
virtual bool RequireConstCanonicalTypeErasure(Zone* zone,
TrailPtr trail = nullptr) const;
// Return true if this type can be used as the declaration type of cls after
// canonicalization (passed-in cls must match type_class()).
bool IsDeclarationTypeOf(const Class& cls) const;
virtual AbstractTypePtr InstantiateFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
intptr_t num_free_fun_type_params,
Heap::Space space,
TrailPtr trail = nullptr) const;
virtual AbstractTypePtr Canonicalize(Thread* thread, TrailPtr trail) const;
#if defined(DEBUG)
// Check if type is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
virtual void EnumerateURIs(URIs* uris) const;
virtual uword Hash() const;
uword ComputeHash() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedType));
}
// The type of the literal 'null'.
static TypePtr NullType();
// The 'dynamic' type.
static TypePtr DynamicType();
// The 'void' type.
static TypePtr VoidType();
// The 'Never' type.
static TypePtr NeverType();
// The 'Object' type.
static TypePtr ObjectType();
// The 'bool' type.
static TypePtr BoolType();
// The 'int' type.
static TypePtr IntType();
// The 'int?' type.
static TypePtr NullableIntType();
// The 'Smi' type.
static TypePtr SmiType();
// The 'Mint' type.
static TypePtr MintType();
// The 'double' type.
static TypePtr Double();
// The 'double?' type.
static TypePtr NullableDouble();
// The 'Float32x4' type.
static TypePtr Float32x4();
// The 'Float64x2' type.
static TypePtr Float64x2();
// The 'Int32x4' type.
static TypePtr Int32x4();
// The 'num' type.
static TypePtr Number();
// The 'String' type.
static TypePtr StringType();
// The 'Array' type.
static TypePtr ArrayType();
// The 'Function' type.
static TypePtr DartFunctionType();
// The 'Type' type.
static TypePtr DartTypeType();
// The finalized type of the given non-parameterized class.
static TypePtr NewNonParameterizedType(const Class& type_class);
static TypePtr New(const Class& clazz,
const TypeArguments& arguments,
Nullability nullability = Nullability::kLegacy,
Heap::Space space = Heap::kOld);
private:
void SetHash(intptr_t value) const;
void set_type_state(uint8_t state) const;
void set_nullability(Nullability value) const {
ASSERT(!IsCanonical());
StoreNonPointer(&untag()->nullability_, static_cast<uint8_t>(value));
}
static TypePtr New(Heap::Space space = Heap::kOld);
FINAL_HEAP_OBJECT_IMPLEMENTATION(Type, AbstractType);
friend class Class;
friend class TypeArguments;
friend class ClearTypeHashVisitor;
};
// A FunctionType represents the type of a function. It describes most of the
// signature of a function, excluding the names of type parameters and names
// of parameters, but includes the names of optional named parameters.
class FunctionType : public AbstractType {
public:
// Reexported so they can be used by the flow graph builders.
using PackedNumParentTypeArguments =
UntaggedFunctionType::PackedNumParentTypeArguments;
using PackedNumTypeParameters = UntaggedFunctionType::PackedNumTypeParameters;
using PackedHasNamedOptionalParameters =
UntaggedFunctionType::PackedHasNamedOptionalParameters;
using PackedNumImplicitParameters =
UntaggedFunctionType::PackedNumImplicitParameters;
using PackedNumFixedParameters =
UntaggedFunctionType::PackedNumFixedParameters;
using PackedNumOptionalParameters =
UntaggedFunctionType::PackedNumOptionalParameters;
static intptr_t type_state_offset() {
return OFFSET_OF(UntaggedFunctionType, type_state_);
}
static intptr_t hash_offset() {
return OFFSET_OF(UntaggedFunctionType, hash_);
}
static intptr_t nullability_offset() {
return OFFSET_OF(UntaggedFunctionType, nullability_);
}
virtual bool IsFinalized() const {
return (untag()->type_state_ == UntaggedType::kFinalizedInstantiated) ||
(untag()->type_state_ == UntaggedType::kFinalizedUninstantiated);
}
virtual void SetIsFinalized() const;
virtual bool IsBeingFinalized() const {
return untag()->type_state_ == UntaggedType::kBeingFinalized;
}
virtual void SetIsBeingFinalized() const;
virtual bool HasTypeClass() const { return false; }
virtual Nullability nullability() const {
return static_cast<Nullability>(untag()->nullability_);
}
FunctionTypePtr ToNullability(Nullability value, Heap::Space space) const;
virtual classid_t type_class_id() const { return kIllegalCid; }
virtual bool IsInstantiated(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
virtual bool IsEquivalent(const Instance& other,
TypeEquality kind,
TrailPtr trail = nullptr) const;
virtual bool IsRecursive(TrailPtr trail = nullptr) const;
virtual bool RequireConstCanonicalTypeErasure(Zone* zone,
TrailPtr trail = nullptr) const;
virtual AbstractTypePtr InstantiateFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
intptr_t num_free_fun_type_params,
Heap::Space space,
TrailPtr trail = nullptr) const;
virtual AbstractTypePtr Canonicalize(Thread* thread, TrailPtr trail) const;
#if defined(DEBUG)
// Check if type is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
virtual void EnumerateURIs(URIs* uris) const;
virtual uword Hash() const;
uword ComputeHash() const;
bool IsSubtypeOf(const FunctionType& other, Heap::Space space) const;
intptr_t NumParameters() const;
// Return the number of type arguments in enclosing signature.
intptr_t NumParentTypeArguments() const {
return untag()
->packed_type_parameter_counts_.Read<PackedNumParentTypeArguments>();
}
void SetNumParentTypeArguments(intptr_t value) const;
intptr_t NumTypeParameters() const {
return PackedNumTypeParameters::decode(
untag()->packed_type_parameter_counts_);
}
intptr_t NumTypeArguments() const {
return NumParentTypeArguments() + NumTypeParameters();
}
intptr_t num_implicit_parameters() const {
return untag()
->packed_parameter_counts_.Read<PackedNumImplicitParameters>();
}
void set_num_implicit_parameters(intptr_t value) const;
intptr_t num_fixed_parameters() const {
return untag()->packed_parameter_counts_.Read<PackedNumFixedParameters>();
}
void set_num_fixed_parameters(intptr_t value) const;
bool HasOptionalParameters() const {
return untag()
->packed_parameter_counts_.Read<PackedNumOptionalParameters>() >
0;
}
bool HasOptionalNamedParameters() const {
return HasOptionalParameters() &&
untag()
->packed_parameter_counts_
.Read<PackedHasNamedOptionalParameters>();
}
bool HasOptionalPositionalParameters() const {
return HasOptionalParameters() && !HasOptionalNamedParameters();
}
intptr_t NumOptionalParameters() const {
return untag()
->packed_parameter_counts_.Read<PackedNumOptionalParameters>();
}
void SetNumOptionalParameters(intptr_t num_optional_parameters,
bool are_optional_positional) const;
intptr_t NumOptionalPositionalParameters() const {
return HasOptionalPositionalParameters() ? NumOptionalParameters() : 0;
}
intptr_t NumOptionalNamedParameters() const {
return HasOptionalNamedParameters() ? NumOptionalParameters() : 0;
}
uint32_t packed_parameter_counts() const {
return untag()->packed_parameter_counts_;
}
void set_packed_parameter_counts(uint32_t packed_parameter_counts) const;
static intptr_t packed_parameter_counts_offset() {
return OFFSET_OF(UntaggedFunctionType, packed_parameter_counts_);
}
uint16_t packed_type_parameter_counts() const {
return untag()->packed_type_parameter_counts_;
}
void set_packed_type_parameter_counts(uint16_t packed_parameter_counts) const;
static intptr_t packed_type_parameter_counts_offset() {
return OFFSET_OF(UntaggedFunctionType, packed_type_parameter_counts_);
}
// Return the type parameter declared at index.
TypeParameterPtr TypeParameterAt(
intptr_t index,
Nullability nullability = Nullability::kNonNullable) const;
AbstractTypePtr result_type() const { return untag()->result_type(); }
void set_result_type(const AbstractType& value) const;
// The parameters, starting with NumImplicitParameters() parameters which are
// only visible to the VM, but not to Dart users.
// Note that type checks exclude implicit parameters.
AbstractTypePtr ParameterTypeAt(intptr_t index) const;
void SetParameterTypeAt(intptr_t index, const AbstractType& value) const;
ArrayPtr parameter_types() const { return untag()->parameter_types(); }
void set_parameter_types(const Array& value) const;
static intptr_t parameter_types_offset() {
return OFFSET_OF(UntaggedFunctionType, parameter_types_);
}
// Parameter names are only stored for named parameters. If there are no named
// parameters, named_parameter_names() is null.
// If there are parameter flags (eg required) they're stored at the end of
// this array, so the size of this array isn't necessarily
// NumOptionalNamedParameters(), but the first NumOptionalNamedParameters()
// elements are the names.
ArrayPtr named_parameter_names() const {
return untag()->named_parameter_names();
}
void set_named_parameter_names(const Array& value) const;
static intptr_t named_parameter_names_offset() {
return OFFSET_OF(UntaggedFunctionType, named_parameter_names_);
}
// The index for these operations is the absolute index of the parameter, not
// the index relative to the start of the named parameters (if any).
StringPtr ParameterNameAt(intptr_t index) const;
// Only valid for absolute indexes of named parameters.
void SetParameterNameAt(intptr_t index, const String& value) const;
// The required flags are stored at the end of the parameter_names. The flags
// are packed into SMIs, but omitted if they're 0.
bool IsRequiredAt(intptr_t index) const;
void SetIsRequiredAt(intptr_t index) const;
// Sets up the signature's parameter name array, including appropriate space
// for any possible parameter flags. This may be an overestimate if some
// parameters don't have flags, and so FinalizeNameArray() should
// be called after all parameter flags have been appropriately set.
//
// Assumes that the number of fixed and optional parameters for the signature
// has already been set. Uses same default space as FunctionType::New.
void CreateNameArrayIncludingFlags(Heap::Space space = Heap::kOld) const;
// Truncate the parameter names array to remove any unused flag slots. Make
// sure to only do this after calling SetIsRequiredAt as necessary.
void FinalizeNameArray() const;
// Returns the length of the parameter names array that is required to store
// all the names plus all their flags. This may be an overestimate if some
// parameters don't have flags.
static intptr_t NameArrayLengthIncludingFlags(intptr_t num_parameters);
// The formal type parameters, their bounds, and defaults, are specified as an
// object of type TypeParameters.
TypeParametersPtr type_parameters() const {
return untag()->type_parameters();
}
void SetTypeParameters(const TypeParameters& value) const;
static intptr_t type_parameters_offset() {
return OFFSET_OF(UntaggedFunctionType, type_parameters_);
}
// Returns true if this function type has the same number of type parameters
// with equal bounds as the other function type. Type parameter names and
// parameter names (unless optional named) are ignored.
bool HasSameTypeParametersAndBounds(const FunctionType& other,
TypeEquality kind,
TrailPtr trail = nullptr) const;
// Return true if this function type declares type parameters.
bool IsGeneric() const { return NumTypeParameters() > 0; }
// Return true if any enclosing signature of this signature is generic.
bool HasGenericParent() const { return NumParentTypeArguments() > 0; }
// Returns true if the type of the formal parameter at the given position in
// this function type is contravariant with the type of the other formal
// parameter at the given position in the other function type.
bool IsContravariantParameter(intptr_t parameter_position,
const FunctionType& other,
intptr_t other_parameter_position,
Heap::Space space) const;
// Returns the index in the parameter names array of the corresponding flag
// for the given parametere index. Also returns (via flag_mask) the
// corresponding mask within the flag.
intptr_t GetRequiredFlagIndex(intptr_t index, intptr_t* flag_mask) const;
void Print(NameVisibility name_visibility, BaseTextBuffer* printer) const;
void PrintParameters(Thread* thread,
Zone* zone,
NameVisibility name_visibility,
BaseTextBuffer* printer) const;
StringPtr ToUserVisibleString() const;
const char* ToUserVisibleCString() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedFunctionType));
}
static FunctionTypePtr New(intptr_t num_parent_type_arguments = 0,
Nullability nullability = Nullability::kLegacy,
Heap::Space space = Heap::kOld);
private:
void SetHash(intptr_t value) const;
void set_type_state(uint8_t state) const;
void set_nullability(Nullability value) const {
ASSERT(!IsCanonical());
StoreNonPointer(&untag()->nullability_, static_cast<uint8_t>(value));
}
static FunctionTypePtr New(Heap::Space space);
FINAL_HEAP_OBJECT_IMPLEMENTATION(FunctionType, AbstractType);
friend class Class;
friend class ClearTypeHashVisitor;
friend class Function;
};
// A TypeRef is used to break cycles in the representation of recursive types.
// Its only field is the recursive AbstractType it refers to, which can
// temporarily be null during finalization.
// Note that the cycle always involves type arguments.
class TypeRef : public AbstractType {
public:
static intptr_t type_offset() { return OFFSET_OF(UntaggedTypeRef, type_); }
virtual bool IsFinalized() const {
const AbstractType& ref_type = AbstractType::Handle(type());
return !ref_type.IsNull() && ref_type.IsFinalized();
}
virtual bool IsBeingFinalized() const {
const AbstractType& ref_type = AbstractType::Handle(type());
return ref_type.IsNull() || ref_type.IsBeingFinalized();
}
virtual Nullability nullability() const {
const AbstractType& ref_type = AbstractType::Handle(type());
ASSERT(!ref_type.IsNull());
return ref_type.nullability();
}
virtual bool HasTypeClass() const {
return (type() != AbstractType::null()) &&
AbstractType::Handle(type()).HasTypeClass();
}
AbstractTypePtr type() const { return untag()->type(); }
void set_type(const AbstractType& value) const;
virtual classid_t type_class_id() const {
return AbstractType::Handle(type()).type_class_id();
}
virtual ClassPtr type_class() const {
return AbstractType::Handle(type()).type_class();
}
virtual TypeArgumentsPtr arguments() const {
return AbstractType::Handle(type()).arguments();
}
virtual bool IsInstantiated(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
virtual bool IsEquivalent(const Instance& other,
TypeEquality kind,
TrailPtr trail = nullptr) const;
virtual bool IsRecursive(TrailPtr trail = nullptr) const { return true; }
virtual bool RequireConstCanonicalTypeErasure(Zone* zone,
TrailPtr trail = nullptr) const;
virtual AbstractTypePtr InstantiateFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
intptr_t num_free_fun_type_params,
Heap::Space space,
TrailPtr trail = nullptr) const;
virtual AbstractTypePtr Canonicalize(Thread* thread, TrailPtr trail) const;
#if defined(DEBUG)
// Check if typeref is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
virtual void EnumerateURIs(URIs* uris) const;
virtual uword Hash() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedTypeRef));
}
static TypeRefPtr New(const AbstractType& type);
private:
static TypeRefPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(TypeRef, AbstractType);
friend class Class;
};
// A TypeParameter represents a type parameter of a parameterized class.
// It specifies its index (and its name for debugging purposes), as well as its
// upper bound.
// For example, the type parameter 'V' is specified as index 1 in the context of
// the class HashMap<K, V>. At compile time, the TypeParameter is not
// instantiated yet, i.e. it is only a place holder.
// Upon finalization, the TypeParameter index is changed to reflect its position
// as type argument (rather than type parameter) of the parameterized class.
// If the type parameter is declared without an extends clause, its bound is set
// to the ObjectType.
class TypeParameter : public AbstractType {
public:
virtual bool IsFinalized() const {
return UntaggedTypeParameter::FinalizedBit::decode(untag()->flags_);
}
virtual void SetIsFinalized() const;
virtual bool IsBeingFinalized() const {
return UntaggedTypeParameter::BeingFinalizedBit::decode(untag()->flags_);
}
virtual void SetIsBeingFinalized() const;
static intptr_t flags_offset() {
return OFFSET_OF(UntaggedTypeParameter, flags_);
}
static intptr_t nullability_offset() {
return OFFSET_OF(UntaggedTypeParameter, nullability_);
}
virtual Nullability nullability() const {
return static_cast<Nullability>(untag()->nullability_);
}
TypeParameterPtr ToNullability(Nullability value, Heap::Space space) const;
virtual bool HasTypeClass() const { return false; }
virtual classid_t type_class_id() const { return kIllegalCid; }
classid_t parameterized_class_id() const;
void set_parameterized_class_id(classid_t value) const;
ClassPtr parameterized_class() const;
bool IsClassTypeParameter() const {
return parameterized_class_id() != kFunctionCid;
}
bool IsFunctionTypeParameter() const {
return parameterized_class_id() == kFunctionCid;
}
static intptr_t parameterized_class_id_offset() {
return OFFSET_OF(UntaggedTypeParameter, parameterized_class_id_);
}
intptr_t base() const { return untag()->base_; }
void set_base(intptr_t value) const;
intptr_t index() const { return untag()->index_; }
void set_index(intptr_t value) const;
static intptr_t index_offset() {
return OFFSET_OF(UntaggedTypeParameter, index_);
}
AbstractTypePtr bound() const { return untag()->bound(); }
void set_bound(const AbstractType& value) const;
static intptr_t bound_offset() {
return OFFSET_OF(UntaggedTypeParameter, bound_);
}
virtual bool IsInstantiated(Genericity genericity = kAny,
intptr_t num_free_fun_type_params = kAllFree,
TrailPtr trail = nullptr) const;
virtual bool IsEquivalent(const Instance& other,
TypeEquality kind,
TrailPtr trail = nullptr) const;
virtual bool IsRecursive(TrailPtr trail = nullptr) const;
virtual bool RequireConstCanonicalTypeErasure(
Zone* zone,
TrailPtr trail = nullptr) const {
return IsNonNullable();
}
virtual AbstractTypePtr InstantiateFrom(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
intptr_t num_free_fun_type_params,
Heap::Space space,
TrailPtr trail = nullptr) const;
virtual AbstractTypePtr Canonicalize(Thread* thread, TrailPtr trail) const;
#if defined(DEBUG)
// Check if type parameter is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
virtual void EnumerateURIs(URIs* uris) const { return; }
virtual uword Hash() const;
// Returns type corresponding to [this] type parameter from the
// given [instantiator_type_arguments] and [function_type_arguments].
// Unlike InstantiateFrom, nullability of type parameter is not applied to
// the result.
AbstractTypePtr GetFromTypeArguments(
const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments) const;
// Return a constructed name for this nameless type parameter.
const char* CanonicalNameCString() const {
return CanonicalNameCString(IsClassTypeParameter(), base(), index());
}
static const char* CanonicalNameCString(bool is_class_type_parameter,
intptr_t base,
intptr_t index);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedTypeParameter));
}
// 'parameterized_class' is null for a function type parameter.
static TypeParameterPtr New(const Class& parameterized_class,
intptr_t base,
intptr_t index,
const AbstractType& bound,
Nullability nullability);
private:
uword ComputeHash() const;
void SetHash(intptr_t value) const;
void set_parameterized_class(const Class& value) const;
void set_name(const String& value) const;
void set_flags(uint8_t flags) const;
void set_nullability(Nullability value) const;
static TypeParameterPtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(TypeParameter, AbstractType);
friend class Class;
friend class ClearTypeHashVisitor;
};
class Number : public Instance {
public:
// TODO(iposva): Add more useful Number methods.
StringPtr ToString(Heap::Space space) const;
// Numbers are canonicalized differently from other instances/strings.
// Caller must hold IsolateGroup::constant_canonicalization_mutex_.
virtual InstancePtr CanonicalizeLocked(Thread* thread) const;
#if defined(DEBUG)
// Check if number is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
private:
OBJECT_IMPLEMENTATION(Number, Instance);
friend class Class;
};
class Integer : public Number {
public:
static IntegerPtr New(const String& str, Heap::Space space = Heap::kNew);
// Creates a new Integer by given uint64_t value.
// Silently casts value to int64_t with wrap-around if it is greater
// than kMaxInt64.
static IntegerPtr NewFromUint64(uint64_t value,
Heap::Space space = Heap::kNew);
// Returns a canonical Integer object allocated in the old gen space.
// Returns null if integer is out of range.
static IntegerPtr NewCanonical(const String& str);
static IntegerPtr NewCanonical(int64_t value);
static IntegerPtr New(int64_t value, Heap::Space space = Heap::kNew);
// Returns true iff the given uint64_t value is representable as Dart integer.
static bool IsValueInRange(uint64_t value);
virtual bool OperatorEquals(const Instance& other) const {
return Equals(other);
}
virtual bool CanonicalizeEquals(const Instance& other) const {
return Equals(other);
}
virtual uint32_t CanonicalizeHash() const { return AsTruncatedUint32Value(); }
virtual bool Equals(const Instance& other) const;
virtual ObjectPtr HashCode() const { return ptr(); }
virtual bool IsZero() const;
virtual bool IsNegative() const;
virtual double AsDoubleValue() const;
virtual int64_t AsInt64Value() const;
virtual int64_t AsTruncatedInt64Value() const { return AsInt64Value(); }
virtual uint32_t AsTruncatedUint32Value() const;
virtual bool FitsIntoSmi() const;
// Returns 0, -1 or 1.
virtual int CompareWith(const Integer& other) const;
// Converts integer to hex string.
const char* ToHexCString(Zone* zone) const;
// Return the most compact presentation of an integer.
IntegerPtr AsValidInteger() const;
// Returns null to indicate that a bigint operation is required.
IntegerPtr ArithmeticOp(Token::Kind operation,
const Integer& other,
Heap::Space space = Heap::kNew) const;
IntegerPtr BitOp(Token::Kind operation,
const Integer& other,
Heap::Space space = Heap::kNew) const;
IntegerPtr ShiftOp(Token::Kind operation,
const Integer& other,
Heap::Space space = Heap::kNew) const;
static int64_t GetInt64Value(const IntegerPtr obj) {
if (obj->IsSmi()) {
return RawSmiValue(static_cast<const SmiPtr>(obj));
} else {
ASSERT(obj->IsMint());
return static_cast<const MintPtr>(obj)->untag()->value_;
}
}
private:
OBJECT_IMPLEMENTATION(Integer, Number);
friend class Class;
};
class Smi : public Integer {
public:
static const intptr_t kBits = kSmiBits;
static const intptr_t kMaxValue = kSmiMax;
static const intptr_t kMinValue = kSmiMin;
intptr_t Value() const { return RawSmiValue(ptr()); }
virtual bool Equals(const Instance& other) const;
virtual bool IsZero() const { return Value() == 0; }
virtual bool IsNegative() const { return Value() < 0; }
virtual double AsDoubleValue() const;
virtual int64_t AsInt64Value() const;
virtual uint32_t AsTruncatedUint32Value() const;
virtual bool FitsIntoSmi() const { return true; }
virtual int CompareWith(const Integer& other) const;
static intptr_t InstanceSize() { return 0; }
static SmiPtr New(intptr_t value) {
SmiPtr raw_smi = static_cast<SmiPtr>(
(static_cast<uintptr_t>(value) << kSmiTagShift) | kSmiTag);
ASSERT(RawSmiValue(raw_smi) == value);
return raw_smi;
}
static SmiPtr FromAlignedAddress(uword address) {
ASSERT((address & kSmiTagMask) == kSmiTag);
return static_cast<SmiPtr>(address);
}
static ClassPtr Class();
static intptr_t Value(const SmiPtr raw_smi) { return RawSmiValue(raw_smi); }
#if defined(DART_COMPRESSED_POINTERS)
static intptr_t Value(const CompressedSmiPtr raw_smi) {
return Smi::Value(static_cast<SmiPtr>(raw_smi.DecompressSmi()));
}
#endif
static intptr_t RawValue(intptr_t value) {
return static_cast<intptr_t>(New(value));
}
static bool IsValid(int64_t value) { return compiler::target::IsSmi(value); }
void operator=(SmiPtr value) {
ptr_ = value;
CHECK_HANDLE();
}
void operator^=(ObjectPtr value) {
ptr_ = value;
CHECK_HANDLE();
}
private:
static intptr_t NextFieldOffset() {
// Indicates this class cannot be extended by dart code.
return -kWordSize;
}
Smi() : Integer() {}
BASE_OBJECT_IMPLEMENTATION(Smi, Integer);
OBJECT_SERVICE_SUPPORT(Smi);
friend class Api; // For ValueFromRaw
friend class Class;
friend class Object;
friend class ReusableSmiHandleScope;
friend class Thread;
};
class SmiTraits : AllStatic {
public:
static const char* Name() { return "SmiTraits"; }
static bool ReportStats() { return false; }
static bool IsMatch(const Object& a, const Object& b) {
return Smi::Cast(a).Value() == Smi::Cast(b).Value();
}
static uword Hash(const Object& obj) { return Smi::Cast(obj).Value(); }
};
class Mint : public Integer {
public:
static const intptr_t kBits = 63; // 64-th bit is sign.
static const int64_t kMaxValue =
static_cast<int64_t>(DART_2PART_UINT64_C(0x7FFFFFFF, FFFFFFFF));
static const int64_t kMinValue =
static_cast<int64_t>(DART_2PART_UINT64_C(0x80000000, 00000000));
int64_t value() const { return untag()->value_; }
static intptr_t value_offset() { return OFFSET_OF(UntaggedMint, value_); }
virtual bool IsZero() const { return value() == 0; }
virtual bool IsNegative() const { return value() < 0; }
virtual bool Equals(const Instance& other) const;
virtual double AsDoubleValue() const;
virtual int64_t AsInt64Value() const;
virtual uint32_t AsTruncatedUint32Value() const;
virtual bool FitsIntoSmi() const;
virtual int CompareWith(const Integer& other) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedMint));
}
protected:
// Only Integer::NewXXX is allowed to call Mint::NewXXX directly.
friend class Integer;
static MintPtr New(int64_t value, Heap::Space space = Heap::kNew);
static MintPtr NewCanonical(int64_t value);
static MintPtr NewCanonicalLocked(Thread* thread, int64_t value);
private:
void set_value(int64_t value) const;
MINT_OBJECT_IMPLEMENTATION(Mint, Integer, Integer);
friend class Class;
friend class Number;
};
// Class Double represents class Double in corelib_impl, which implements
// abstract class double in corelib.
class Double : public Number {
public:
double value() const { return untag()->value_; }
bool BitwiseEqualsToDouble(double value) const;
virtual bool OperatorEquals(const Instance& other) const;
virtual bool CanonicalizeEquals(const Instance& other) const;
virtual uint32_t CanonicalizeHash() const;
static DoublePtr New(double d, Heap::Space space = Heap::kNew);
static DoublePtr New(const String& str, Heap::Space space = Heap::kNew);
// Returns a canonical double object allocated in the old gen space.
static DoublePtr NewCanonical(double d);
static DoublePtr NewCanonicalLocked(Thread* thread, double d);
// Returns a canonical double object (allocated in the old gen space) or
// Double::null() if str points to a string that does not convert to a
// double value.
static DoublePtr NewCanonical(const String& str);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedDouble));
}
static intptr_t value_offset() { return OFFSET_OF(UntaggedDouble, value_); }
private:
void set_value(double value) const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(Double, Number);
friend class Class;
friend class Number;
};
// String may not be '\0' terminated.
class String : public Instance {
public:
// We use 30 bits for the hash code so hashes in a snapshot taken on a
// 64-bit architecture stay in Smi range when loaded on a 32-bit
// architecture.
static const intptr_t kHashBits = 30;
static const intptr_t kOneByteChar = 1;
static const intptr_t kTwoByteChar = 2;
// All strings share the same maximum element count to keep things
// simple. We choose a value that will prevent integer overflow for
// 2 byte strings, since it is the worst case.
#if defined(HASH_IN_OBJECT_HEADER)
static const intptr_t kSizeofRawString = sizeof(UntaggedInstance) + kWordSize;
#else
static const intptr_t kSizeofRawString =
sizeof(UntaggedInstance) + 2 * kWordSize;
#endif
static const intptr_t kMaxElements = kSmiMax / kTwoByteChar;
static intptr_t HeaderSize() { return String::kSizeofRawString; }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedString));
}
class CodePointIterator : public ValueObject {
public:
explicit CodePointIterator(const String& str)
: str_(str), ch_(0), index_(-1), end_(str.Length()) {
ASSERT(!str_.IsNull());
}
CodePointIterator(const String& str, intptr_t start, intptr_t length)
: str_(str), ch_(0), index_(start - 1), end_(start + length) {
ASSERT(start >= 0);
ASSERT(end_ <= str.Length());
}
int32_t Current() const {
ASSERT(index_ >= 0);
ASSERT(index_ < end_);
return ch_;
}
bool Next();
private:
const String& str_;
int32_t ch_;
intptr_t index_;
intptr_t end_;
DISALLOW_IMPLICIT_CONSTRUCTORS(CodePointIterator);
};
intptr_t Length() const { return LengthOf(ptr()); }
static intptr_t LengthOf(StringPtr obj) {
return Smi::Value(obj->untag()->length());
}
static intptr_t length_offset() { return OFFSET_OF(UntaggedString, length_); }
uword Hash() const {
uword result = GetCachedHash(ptr());
if (result != 0) {
return result;
}
result = String::Hash(*this, 0, this->Length());
uword set_hash = SetCachedHashIfNotSet(ptr(), result);
ASSERT(set_hash == result);
return result;
}
static uword Hash(StringPtr raw);
bool HasHash() const {
ASSERT(Smi::New(0) == nullptr);
return GetCachedHash(ptr()) != 0;
}
bool IsRecursive() const { return false; } // Required by HashSet templates.
static intptr_t hash_offset() {
#if defined(HASH_IN_OBJECT_HEADER)
COMPILE_ASSERT(UntaggedObject::kHashTagPos % kBitsPerByte == 0);
return OFFSET_OF(UntaggedObject, tags_) +
UntaggedObject::kHashTagPos / kBitsPerByte;
#else
return OFFSET_OF(UntaggedString, hash_);
#endif
}
static uword Hash(const String& str, intptr_t begin_index, intptr_t len);
static uword Hash(const char* characters, intptr_t len);
static uword Hash(const uint16_t* characters, intptr_t len);
static uword Hash(const int32_t* characters, intptr_t len);
static uword HashRawSymbol(const StringPtr symbol) {
ASSERT(symbol->untag()->IsCanonical());
const uword result = GetCachedHash(symbol);
ASSERT(result != 0);
return result;
}
// Returns the hash of str1 + str2.
static uword HashConcat(const String& str1, const String& str2);
virtual ObjectPtr HashCode() const { return Integer::New(Hash()); }
uint16_t CharAt(intptr_t index) const { return CharAt(ptr(), index); }
static uint16_t CharAt(StringPtr str, intptr_t index);
intptr_t CharSize() const;
inline bool Equals(const String& str) const;
bool Equals(const String& str,
intptr_t begin_index, // begin index on 'str'.
intptr_t len) const; // len on 'str'.
// Compares to a '\0' terminated array of UTF-8 encoded characters.
bool Equals(const char* cstr) const;
// Compares to an array of Latin-1 encoded characters.
bool EqualsLatin1(const uint8_t* characters, intptr_t len) const {
return Equals(characters, len);
}
// Compares to an array of UTF-16 encoded characters.
bool Equals(const uint16_t* characters, intptr_t len) const;
// Compares to an array of UTF-32 encoded characters.
bool Equals(const int32_t* characters, intptr_t len) const;
// True iff this string equals str1 + str2.
bool EqualsConcat(const String& str1, const String& str2) const;
virtual bool OperatorEquals(const Instance& other) const {
return Equals(other);
}
virtual bool CanonicalizeEquals(const Instance& other) const {
return Equals(other);
}
virtual uint32_t CanonicalizeHash() const { return Hash(); }
virtual bool Equals(const Instance& other) const;
intptr_t CompareTo(const String& other) const;
bool StartsWith(const String& other) const {
NoSafepointScope no_safepoint;
return StartsWith(ptr(), other.ptr());
}
static bool StartsWith(StringPtr str, StringPtr prefix);
bool EndsWith(const String& other) const;
// Strings are canonicalized using the symbol table.
// Caller must hold IsolateGroup::constant_canonicalization_mutex_.
virtual InstancePtr CanonicalizeLocked(Thread* thread) const;
#if defined(DEBUG)
// Check if string is canonical.
virtual bool CheckIsCanonical(Thread* thread) const;
#endif // DEBUG
bool IsSymbol() const { return ptr()->untag()->IsCanonical(); }
bool IsOneByteString() const {
return ptr()->GetClassId() == kOneByteStringCid;
}
bool IsTwoByteString() const {
return ptr()->GetClassId() == kTwoByteStringCid;
}
bool IsExternalOneByteString() const {
return ptr()->GetClassId() == kExternalOneByteStringCid;
}
bool IsExternalTwoByteString() const {
return ptr()->GetClassId() == kExternalTwoByteStringCid;
}
bool IsExternal() const {
return IsExternalStringClassId(ptr()->GetClassId());
}
void* GetPeer() const;
char* ToMallocCString() const;
void ToUTF8(uint8_t* utf8_array, intptr_t array_len) const;
static const char* ToCString(Thread* thread, StringPtr ptr);
// Creates a new String object from a C string that is assumed to contain
// UTF-8 encoded characters and '\0' is considered a termination character.
// TODO(7123) - Rename this to FromCString(....).
static StringPtr New(const char* cstr, Heap::Space space = Heap::kNew);
// Creates a new String object from an array of UTF-8 encoded characters.
static StringPtr FromUTF8(const uint8_t* utf8_array,
intptr_t array_len,
Heap::Space space = Heap::kNew);
// Creates a new String object from an array of Latin-1 encoded characters.
static StringPtr FromLatin1(const uint8_t* latin1_array,
intptr_t array_len,
Heap::Space space = Heap::kNew);
// Creates a new String object from an array of UTF-16 encoded characters.
static StringPtr FromUTF16(const uint16_t* utf16_array,
intptr_t array_len,
Heap::Space space = Heap::kNew);
// Creates a new String object from an array of UTF-32 encoded characters.
static StringPtr FromUTF32(const int32_t* utf32_array,
intptr_t array_len,
Heap::Space space = Heap::kNew);
// Create a new String object from another Dart String instance.
static StringPtr New(const String& str, Heap::Space space = Heap::kNew);
// Creates a new External String object using the specified array of
// UTF-8 encoded characters as the external reference.
static StringPtr NewExternal(const uint8_t* utf8_array,
intptr_t array_len,
void* peer,
intptr_t external_allocation_size,
Dart_HandleFinalizer callback,
Heap::Space = Heap::kNew);
// Creates a new External String object using the specified array of
// UTF-16 encoded characters as the external reference.
static StringPtr NewExternal(const uint16_t* utf16_array,
intptr_t array_len,
void* peer,
intptr_t external_allocation_size,
Dart_HandleFinalizer callback,
Heap::Space = Heap::kNew);
static void Copy(const String& dst,
intptr_t dst_offset,
const uint8_t* characters,
intptr_t len);
static void Copy(const String& dst,
intptr_t dst_offset,
const uint16_t* characters,
intptr_t len);
static void Copy(const String& dst,
intptr_t dst_offset,
const String& src,
intptr_t src_offset,
intptr_t len);
static StringPtr EscapeSpecialCharacters(const String& str);
// Encodes 'str' for use in an Internationalized Resource Identifier (IRI),
// a generalization of URI (percent-encoding). See RFC 3987.
static const char* EncodeIRI(const String& str);
// Returns null if 'str' is not a valid encoding.
static StringPtr DecodeIRI(const String& str);
static StringPtr Concat(const String& str1,
const String& str2,
Heap::Space space = Heap::kNew);
static StringPtr ConcatAll(const Array& strings,
Heap::Space space = Heap::kNew);
// Concat all strings in 'strings' from 'start' to 'end' (excluding).
static StringPtr ConcatAllRange(const Array& strings,
intptr_t start,
intptr_t end,
Heap::Space space = Heap::kNew);
static StringPtr SubString(const String& str,
intptr_t begin_index,
Heap::Space space = Heap::kNew);
static StringPtr SubString(const String& str,
intptr_t begin_index,
intptr_t length,
Heap::Space space = Heap::kNew) {
return SubString(Thread::Current(), str, begin_index, length, space);
}
static StringPtr SubString(Thread* thread,
const String& str,
intptr_t begin_index,
intptr_t length,
Heap::Space space = Heap::kNew);
static StringPtr Transform(int32_t (*mapping)(int32_t ch),
const String& str,
Heap::Space space = Heap::kNew);
static StringPtr ToUpperCase(const String& str,
Heap::Space space = Heap::kNew);
static StringPtr ToLowerCase(const String& str,
Heap::Space space = Heap::kNew);
static StringPtr RemovePrivateKey(const String& name);
static const char* ScrubName(const String& name, bool is_extension = false);
static StringPtr ScrubNameRetainPrivate(const String& name,
bool is_extension = false);
static bool EqualsIgnoringPrivateKey(const String& str1, const String& str2);
static StringPtr NewFormatted(const char* format, ...) PRINTF_ATTRIBUTE(1, 2);
static StringPtr NewFormatted(Heap::Space space, const char* format, ...)
PRINTF_ATTRIBUTE(2, 3);
static StringPtr NewFormattedV(const char* format,
va_list args,
Heap::Space space = Heap::kNew);
static bool ParseDouble(const String& str,
intptr_t start,
intptr_t end,
double* result);
#if !defined(HASH_IN_OBJECT_HEADER)
static uint32_t GetCachedHash(const StringPtr obj) {
return Smi::Value(obj->untag()->hash_);
}
static uint32_t SetCachedHashIfNotSet(StringPtr obj, uint32_t hash) {
ASSERT(Smi::Value(obj->untag()->hash_) == 0 ||
Smi::Value(obj->untag()->hash_) == static_cast<intptr_t>(hash));
return SetCachedHash(obj, hash);
}
static uint32_t SetCachedHash(StringPtr obj, uint32_t hash) {
obj->untag()->hash_ = Smi::New(hash);
return hash;
}
#else
static uint32_t SetCachedHash(StringPtr obj, uint32_t hash) {
return Object::SetCachedHashIfNotSet(obj, hash);
}
#endif
protected:
// These two operate on an array of Latin-1 encoded characters.
// They are protected to avoid mistaking Latin-1 for UTF-8, but used
// by friendly templated code (e.g., Symbols).
bool Equals(const uint8_t* characters, intptr_t len) const;
static uword Hash(const uint8_t* characters, intptr_t len);
void SetLength(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
untag()->set_length(Smi::New(value));
}
void SetHash(intptr_t value) const {
const intptr_t hash_set = SetCachedHashIfNotSet(ptr(), value);
ASSERT(hash_set == value);
}
template <typename HandleType, typename ElementType, typename CallbackType>
static void ReadFromImpl(SnapshotReader* reader,
String* str_obj,
intptr_t len,
intptr_t tags,
CallbackType new_symbol,
Snapshot::Kind kind);
FINAL_HEAP_OBJECT_IMPLEMENTATION(String, Instance);
friend class Class;
friend class Symbols;
friend class StringSlice; // SetHash
template <typename CharType>
friend class CharArray; // SetHash
friend class ConcatString; // SetHash
friend class OneByteString;
friend class TwoByteString;
friend class ExternalOneByteString;
friend class ExternalTwoByteString;
friend class UntaggedOneByteString;
friend class RODataSerializationCluster; // SetHash
friend class Pass2Visitor; // Stack "handle"
};
// Synchronize with implementation in compiler (intrinsifier).
class StringHasher : ValueObject {
public:
StringHasher() : hash_(0) {}
void Add(uint16_t code_unit) { hash_ = CombineHashes(hash_, code_unit); }
void Add(const uint8_t* code_units, intptr_t len) {
while (len > 0) {
Add(*code_units);
code_units++;
len--;
}
}
void Add(const uint16_t* code_units, intptr_t len) {
while (len > 0) {
Add(LoadUnaligned(code_units));
code_units++;
len--;
}
}
void Add(const String& str, intptr_t begin_index, intptr_t len);
intptr_t Finalize() { return FinalizeHash(hash_, String::kHashBits); }
private:
uint32_t hash_;
};
class OneByteString : public AllStatic {
public:
ALLSTATIC_CONTAINS_COMPRESSED_IMPLEMENTATION(OneByteString, String);
static uint16_t CharAt(const String& str, intptr_t index) {
ASSERT(str.IsOneByteString());
NoSafepointScope no_safepoint;
return OneByteString::CharAt(static_cast<OneByteStringPtr>(str.ptr()),
index);
}
static uint16_t CharAt(OneByteStringPtr str, intptr_t index) {
ASSERT(index >= 0 && index < String::LengthOf(str));
return str->untag()->data()[index];
}
static void SetCharAt(const String& str, intptr_t index, uint8_t code_unit) {
NoSafepointScope no_safepoint;
*CharAddr(str, index) = code_unit;
}
static OneByteStringPtr EscapeSpecialCharacters(const String& str);
// We use the same maximum elements for all strings.
static const intptr_t kBytesPerElement = 1;
static const intptr_t kMaxElements = String::kMaxElements;
struct ArrayTraits {
static intptr_t elements_start_offset() {
return sizeof(UntaggedOneByteString);
}
static constexpr intptr_t kElementSize = kBytesPerElement;
};
static intptr_t data_offset() {
return OFFSET_OF_RETURNED_VALUE(UntaggedOneByteString, data);
}
static intptr_t UnroundedSize(OneByteStringPtr str) {
return UnroundedSize(Smi::Value(str->untag()->length()));
}
static intptr_t UnroundedSize(intptr_t len) {
return sizeof(UntaggedOneByteString) + (len * kBytesPerElement);
}
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedOneByteString) ==
OFFSET_OF_RETURNED_VALUE(UntaggedOneByteString, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(sizeof(UntaggedOneByteString) == String::kSizeofRawString);
ASSERT(0 <= len && len <= kMaxElements);
return String::RoundedAllocationSize(UnroundedSize(len));
}
static OneByteStringPtr New(intptr_t len, Heap::Space space);
static OneByteStringPtr New(const char* c_string,
Heap::Space space = Heap::kNew) {
return New(reinterpret_cast<const uint8_t*>(c_string), strlen(c_string),
space);
}
static OneByteStringPtr New(const uint8_t* characters,
intptr_t len,
Heap::Space space);
static OneByteStringPtr New(const uint16_t* characters,
intptr_t len,
Heap::Space space);
static OneByteStringPtr New(const int32_t* characters,
intptr_t len,
Heap::Space space);
static OneByteStringPtr New(const String& str, Heap::Space space);
// 'other' must be OneByteString.
static OneByteStringPtr New(const String& other_one_byte_string,
intptr_t other_start_index,
intptr_t other_len,
Heap::Space space);
static OneByteStringPtr New(const TypedDataBase& other_typed_data,
intptr_t other_start_index,
intptr_t other_len,
Heap::Space space = Heap::kNew);
static OneByteStringPtr Concat(const String& str1,
const String& str2,
Heap::Space space);
static OneByteStringPtr ConcatAll(const Array& strings,
intptr_t start,
intptr_t end,
intptr_t len,
Heap::Space space);
static OneByteStringPtr Transform(int32_t (*mapping)(int32_t ch),
const String& str,
Heap::Space space);
// High performance version of substring for one-byte strings.
// "str" must be OneByteString.
static OneByteStringPtr SubStringUnchecked(const String& str,
intptr_t begin_index,
intptr_t length,
Heap::Space space);
static const ClassId kClassId = kOneByteStringCid;
static OneByteStringPtr null() {
return static_cast<OneByteStringPtr>(Object::null());
}
private:
static OneByteStringPtr raw(const String& str) {
return static_cast<OneByteStringPtr>(str.ptr());
}
static const UntaggedOneByteString* untag(const String& str) {
return reinterpret_cast<const UntaggedOneByteString*>(str.untag());
}
static uint8_t* CharAddr(const String& str, intptr_t index) {
ASSERT((index >= 0) && (index < str.Length()));
ASSERT(str.IsOneByteString());
return &str.UnsafeMutableNonPointer(untag(str)->data())[index];
}
static uint8_t* DataStart(const String& str) {
ASSERT(str.IsOneByteString());
return &str.UnsafeMutableNonPointer(untag(str)->data())[0];
}
static OneByteStringPtr ReadFrom(SnapshotReader* reader,
intptr_t object_id,
intptr_t tags,
Snapshot::Kind kind,
bool as_reference);
friend class Class;
friend class ExternalOneByteString;
friend class ImageWriter;
friend class SnapshotReader;
friend class String;
friend class StringHasher;
friend class Symbols;
friend class Utf8;
};
class TwoByteString : public AllStatic {
public:
ALLSTATIC_CONTAINS_COMPRESSED_IMPLEMENTATION(TwoByteString, String);
static uint16_t CharAt(const String& str, intptr_t index) {
ASSERT(str.IsTwoByteString());
NoSafepointScope no_safepoint;
return TwoByteString::CharAt(static_cast<TwoByteStringPtr>(str.ptr()),
index);
}
static uint16_t CharAt(TwoByteStringPtr str, intptr_t index) {
ASSERT(index >= 0 && index < String::LengthOf(str));
return str->untag()->data()[index];
}
static void SetCharAt(const String& str, intptr_t index, uint16_t ch) {
NoSafepointScope no_safepoint;
*CharAddr(str, index) = ch;
}
static TwoByteStringPtr EscapeSpecialCharacters(const String& str);
// We use the same maximum elements for all strings.
static const intptr_t kBytesPerElement = 2;
static const intptr_t kMaxElements = String::kMaxElements;
struct ArrayTraits {
static intptr_t elements_start_offset() {
return sizeof(UntaggedTwoByteString);
}
static constexpr intptr_t kElementSize = kBytesPerElement;
};
static intptr_t data_offset() {
return OFFSET_OF_RETURNED_VALUE(UntaggedTwoByteString, data);
}
static intptr_t UnroundedSize(TwoByteStringPtr str) {
return UnroundedSize(Smi::Value(str->untag()->length()));
}
static intptr_t UnroundedSize(intptr_t len) {
return sizeof(UntaggedTwoByteString) + (len * kBytesPerElement);
}
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedTwoByteString) ==
OFFSET_OF_RETURNED_VALUE(UntaggedTwoByteString, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
ASSERT(sizeof(UntaggedTwoByteString) == String::kSizeofRawString);
ASSERT(0 <= len && len <= kMaxElements);
return String::RoundedAllocationSize(UnroundedSize(len));
}
static TwoByteStringPtr New(intptr_t len, Heap::Space space);
static TwoByteStringPtr New(const uint16_t* characters,
intptr_t len,
Heap::Space space);
static TwoByteStringPtr New(intptr_t utf16_len,
const int32_t* characters,
intptr_t len,
Heap::Space space);
static TwoByteStringPtr New(const String& str, Heap::Space space);
static TwoByteStringPtr New(const TypedDataBase& other_typed_data,
intptr_t other_start_index,
intptr_t other_len,
Heap::Space space = Heap::kNew);
static TwoByteStringPtr Concat(const String& str1,
const String& str2,
Heap::Space space);
static TwoByteStringPtr ConcatAll(const Array& strings,
intptr_t start,
intptr_t end,
intptr_t len,
Heap::Space space);
static TwoByteStringPtr Transform(int32_t (*mapping)(int32_t ch),
const String& str,
Heap::Space space);
static TwoByteStringPtr null() {
return static_cast<TwoByteStringPtr>(Object::null());
}
static const ClassId kClassId = kTwoByteStringCid;
private:
static TwoByteStringPtr raw(const String& str) {
return static_cast<TwoByteStringPtr>(str.ptr());
}
static const UntaggedTwoByteString* untag(const String& str) {
return reinterpret_cast<const UntaggedTwoByteString*>(str.untag());
}
static uint16_t* CharAddr(const String& str, intptr_t index) {
ASSERT((index >= 0) && (index < str.Length()));
ASSERT(str.IsTwoByteString());
return &str.UnsafeMutableNonPointer(untag(str)->data())[index];
}
// Use this instead of CharAddr(0). It will not assert that the index is <
// length.
static uint16_t* DataStart(const String& str) {
ASSERT(str.IsTwoByteString());
return &str.UnsafeMutableNonPointer(untag(str)->data())[0];
}
static TwoByteStringPtr ReadFrom(SnapshotReader* reader,
intptr_t object_id,
intptr_t tags,
Snapshot::Kind kind,
bool as_reference);
friend class Class;
friend class ImageWriter;
friend class SnapshotReader;
friend class String;
friend class StringHasher;
friend class Symbols;
};
class ExternalOneByteString : public AllStatic {
public:
ALLSTATIC_CONTAINS_COMPRESSED_IMPLEMENTATION(ExternalOneByteString, String);
static uint16_t CharAt(const String& str, intptr_t index) {
ASSERT(str.IsExternalOneByteString());
NoSafepointScope no_safepoint;
return ExternalOneByteString::CharAt(
static_cast<ExternalOneByteStringPtr>(str.ptr()), index);
}
static uint16_t CharAt(ExternalOneByteStringPtr str, intptr_t index) {
ASSERT(index >= 0 && index < String::LengthOf(str));
return str->untag()->external_data_[index];
}
static void* GetPeer(const String& str) { return untag(str)->peer_; }
static intptr_t external_data_offset() {
return OFFSET_OF(UntaggedExternalOneByteString, external_data_);
}
// We use the same maximum elements for all strings.
static const intptr_t kBytesPerElement = 1;
static const intptr_t kMaxElements = String::kMaxElements;
static intptr_t InstanceSize() {
return String::RoundedAllocationSize(sizeof(UntaggedExternalOneByteString));
}
static ExternalOneByteStringPtr New(const uint8_t* characters,
intptr_t len,
void* peer,
intptr_t external_allocation_size,
Dart_HandleFinalizer callback,
Heap::Space space);
static ExternalOneByteStringPtr null() {
return static_cast<ExternalOneByteStringPtr>(Object::null());
}
static OneByteStringPtr EscapeSpecialCharacters(const String& str);
static OneByteStringPtr EncodeIRI(const String& str);
static OneByteStringPtr DecodeIRI(const String& str);
static const ClassId kClassId = kExternalOneByteStringCid;
private:
static ExternalOneByteStringPtr raw(const String& str) {
return static_cast<ExternalOneByteStringPtr>(str.ptr());
}
static const UntaggedExternalOneByteString* untag(const String& str) {
return reinterpret_cast<const UntaggedExternalOneByteString*>(str.untag());
}
static const uint8_t* CharAddr(const String& str, intptr_t index) {
ASSERT((index >= 0) && (index < str.Length()));
ASSERT(str.IsExternalOneByteString());
return &(untag(str)->external_data_[index]);
}
static const uint8_t* DataStart(const String& str) {
ASSERT(str.IsExternalOneByteString());
return untag(str)->external_data_;
}
static void SetExternalData(const String& str,
const uint8_t* data,
void* peer) {
ASSERT(str.IsExternalOneByteString());
ASSERT(!IsolateGroup::Current()->heap()->Contains(
reinterpret_cast<uword>(data)));
str.StoreNonPointer(&untag(str)->external_data_, data);
str.StoreNonPointer(&untag(str)->peer_, peer);
}
static void Finalize(void* isolate_callback_data,
Dart_WeakPersistentHandle handle,
void* peer);
static ExternalOneByteStringPtr ReadFrom(SnapshotReader* reader,
intptr_t object_id,
intptr_t tags,
Snapshot::Kind kind,
bool as_reference);
static intptr_t NextFieldOffset() {
// Indicates this class cannot be extended by dart code.
return -kWordSize;
}
friend class Class;
friend class String;
friend class StringHasher;
friend class SnapshotReader;
friend class Symbols;
friend class Utf8;
};
class ExternalTwoByteString : public AllStatic {
public:
ALLSTATIC_CONTAINS_COMPRESSED_IMPLEMENTATION(ExternalTwoByteString, String);
static uint16_t CharAt(const String& str, intptr_t index) {
ASSERT(str.IsExternalTwoByteString());
NoSafepointScope no_safepoint;
return ExternalTwoByteString::CharAt(
static_cast<ExternalTwoByteStringPtr>(str.ptr()), index);
}
static uint16_t CharAt(ExternalTwoByteStringPtr str, intptr_t index) {
ASSERT(index >= 0 && index < String::LengthOf(str));
return str->untag()->external_data_[index];
}
static void* GetPeer(const String& str) { return untag(str)->peer_; }
static intptr_t external_data_offset() {
return OFFSET_OF(UntaggedExternalTwoByteString, external_data_);
}
// We use the same maximum elements for all strings.
static const intptr_t kBytesPerElement = 2;
static const intptr_t kMaxElements = String::kMaxElements;
static intptr_t InstanceSize() {
return String::RoundedAllocationSize(sizeof(UntaggedExternalTwoByteString));
}
static ExternalTwoByteStringPtr New(const uint16_t* characters,
intptr_t len,
void* peer,
intptr_t external_allocation_size,
Dart_HandleFinalizer callback,
Heap::Space space = Heap::kNew);
static ExternalTwoByteStringPtr null() {
return static_cast<ExternalTwoByteStringPtr>(Object::null());
}
static const ClassId kClassId = kExternalTwoByteStringCid;
private:
static ExternalTwoByteStringPtr raw(const String& str) {
return static_cast<ExternalTwoByteStringPtr>(str.ptr());
}
static const UntaggedExternalTwoByteString* untag(const String& str) {
return reinterpret_cast<const UntaggedExternalTwoByteString*>(str.untag());
}
static const uint16_t* CharAddr(const String& str, intptr_t index) {
ASSERT((index >= 0) && (index < str.Length()));
ASSERT(str.IsExternalTwoByteString());
return &(untag(str)->external_data_[index]);
}
static const uint16_t* DataStart(const String& str) {
ASSERT(str.IsExternalTwoByteString());
return untag(str)->external_data_;
}
static void SetExternalData(const String& str,
const uint16_t* data,
void* peer) {
ASSERT(str.IsExternalTwoByteString());
ASSERT(!IsolateGroup::Current()->heap()->Contains(
reinterpret_cast<uword>(data)));
str.StoreNonPointer(&untag(str)->external_data_, data);
str.StoreNonPointer(&untag(str)->peer_, peer);
}
static void Finalize(void* isolate_callback_data,
Dart_WeakPersistentHandle handle,
void* peer);
static ExternalTwoByteStringPtr ReadFrom(SnapshotReader* reader,
intptr_t object_id,
intptr_t tags,
Snapshot::Kind kind,
bool as_reference);
static intptr_t NextFieldOffset() {
// Indicates this class cannot be extended by dart code.
return -kWordSize;
}
friend class Class;
friend class String;
friend class StringHasher;
friend class SnapshotReader;
friend class Symbols;
};
// Class Bool implements Dart core class bool.
class Bool : public Instance {
public:
bool value() const { return untag()->value_; }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedBool));
}
static const Bool& True() { return Object::bool_true(); }
static const Bool& False() { return Object::bool_false(); }
static const Bool& Get(bool value) {
return value ? Bool::True() : Bool::False();
}
virtual uint32_t CanonicalizeHash() const {
return ptr() == True().ptr() ? 1231 : 1237;
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Bool, Instance);
friend class Class;
friend class Object; // To initialize the true and false values.
};
class Array : public Instance {
public:
// We use 30 bits for the hash code so hashes in a snapshot taken on a
// 64-bit architecture stay in Smi range when loaded on a 32-bit
// architecture.
static const intptr_t kHashBits = 30;
// Returns `true` if we use card marking for arrays of length [array_length].
static bool UseCardMarkingForAllocation(const intptr_t array_length) {
return Array::InstanceSize(array_length) > Heap::kNewAllocatableSize;
}
intptr_t Length() const { return LengthOf(ptr()); }
static intptr_t LengthOf(const ArrayPtr array) {
return Smi::Value(array->untag()->length());
}
static intptr_t length_offset() { return OFFSET_OF(UntaggedArray, length_); }
static intptr_t data_offset() {
return OFFSET_OF_RETURNED_VALUE(UntaggedArray, data);
}
static intptr_t element_offset(intptr_t index) {
return OFFSET_OF_RETURNED_VALUE(UntaggedArray, data) +
kBytesPerElement * index;
}
static intptr_t index_at_offset(intptr_t offset_in_bytes) {
intptr_t index = (offset_in_bytes - data_offset()) / kBytesPerElement;
ASSERT(index >= 0);
return index;
}
struct ArrayTraits {
static intptr_t elements_start_offset() { return Array::data_offset(); }
static constexpr intptr_t kElementSize = kCompressedWordSize;
};
static bool Equals(ArrayPtr a, ArrayPtr b) {
if (a == b) return true;
if (a->IsRawNull() || b->IsRawNull()) return false;
if (a->untag()->length() != b->untag()->length()) return false;
if (a->untag()->type_arguments() != b->untag()->type_arguments()) {
return false;
}
const intptr_t length = LengthOf(a);
return memcmp(a->untag()->data(), b->untag()->data(),
kBytesPerElement * length) == 0;
}
static CompressedObjectPtr* DataOf(ArrayPtr array) {
return array->untag()->data();
}
template <std::memory_order order = std::memory_order_relaxed>
ObjectPtr At(intptr_t index) const {
return untag()->element<order>(index);
}
template <std::memory_order order = std::memory_order_relaxed>
void SetAt(intptr_t index, const Object& value) const {
// TODO(iposva): Add storing NoSafepointScope.
untag()->set_element<order>(index, value.ptr());
}
// Access to the array with acquire release semantics.
ObjectPtr AtAcquire(intptr_t index) const {
return untag()->element<std::memory_order_acquire>(index);
}
void SetAtRelease(intptr_t index, const Object& value) const {
untag()->set_element<std::memory_order_release>(index, value.ptr());
}
bool IsImmutable() const { return ptr()->GetClassId() == kImmutableArrayCid; }
// Position of element type in type arguments.
static const intptr_t kElementTypeTypeArgPos = 0;
virtual TypeArgumentsPtr GetTypeArguments() const {
return untag()->type_arguments();
}
virtual void SetTypeArguments(const TypeArguments& value) const {
// An Array is raw or takes one type argument. However, its type argument
// vector may be longer than 1 due to a type optimization reusing the type
// argument vector of the instantiator.
ASSERT(value.IsNull() ||
((value.Length() >= 1) &&
value.IsInstantiated() /*&& value.IsCanonical()*/));
// TODO(asiva): Values read from a message snapshot are not properly marked
// as canonical. See for example tests/isolate/mandel_isolate_test.dart.
StoreArrayPointer(&untag()->type_arguments_, value.ptr());
}
virtual bool CanonicalizeEquals(const Instance& other) const;
virtual uint32_t CanonicalizeHash() const;
static const intptr_t kBytesPerElement = ArrayTraits::kElementSize;
static const intptr_t kMaxElements = kSmiMax / kBytesPerElement;
static const intptr_t kMaxNewSpaceElements =
(Heap::kNewAllocatableSize - sizeof(UntaggedArray)) / kBytesPerElement;
static intptr_t type_arguments_offset() {
return OFFSET_OF(UntaggedArray, type_arguments_);
}
static bool IsValidLength(intptr_t len) {
return 0 <= len && len <= kMaxElements;
}
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedArray) ==
OFFSET_OF_RETURNED_VALUE(UntaggedArray, data));
return 0;
}
static intptr_t InstanceSize(intptr_t len) {
// Ensure that variable length data is not adding to the object length.
ASSERT(sizeof(UntaggedArray) ==
(sizeof(UntaggedInstance) + (2 * kBytesPerElement)));
ASSERT(IsValidLength(len));
return RoundedAllocationSize(sizeof(UntaggedArray) +
(len * kBytesPerElement));
}
virtual void CanonicalizeFieldsLocked(Thread* thread) const;
// Make the array immutable to Dart code by switching the class pointer
// to ImmutableArray.
void MakeImmutable() const;
static ArrayPtr New(intptr_t len, Heap::Space space = Heap::kNew);
static ArrayPtr New(intptr_t len,
const AbstractType& element_type,
Heap::Space space = Heap::kNew);
// Creates and returns a new array with 'new_length'. Copies all elements from
// 'source' to the new array. 'new_length' must be greater than or equal to
// 'source.Length()'. 'source' can be null.
static ArrayPtr Grow(const Array& source,
intptr_t new_length,
Heap::Space space = Heap::kNew);
// Truncates the array to a given length. 'new_length' must be less than
// or equal to 'source.Length()'. The remaining unused part of the array is
// marked as an Array object or a regular Object so that it can be traversed
// during garbage collection.
void Truncate(intptr_t new_length) const;
// Return an Array object that contains all the elements currently present
// in the specified Growable Object Array. This is done by first truncating
// the Growable Object Array's backing array to the currently used size and
// returning the truncated backing array.
// The backing array of the original Growable Object Array is
// set to an empty array.
// If the unique parameter is false, the function is allowed to return
// a shared Array instance.
static ArrayPtr MakeFixedLength(const GrowableObjectArray& growable_array,
bool unique = false);
ArrayPtr Slice(intptr_t start, intptr_t count, bool with_type_argument) const;
protected:
static ArrayPtr New(intptr_t class_id,
intptr_t len,
Heap::Space space = Heap::kNew);
private:
CompressedObjectPtr const* ObjectAddr(intptr_t index) const {
// TODO(iposva): Determine if we should throw an exception here.
ASSERT((index >= 0) && (index < Length()));
return &untag()->data()[index];
}
void SetLength(intptr_t value) const { untag()->set_length(Smi::New(value)); }
void SetLengthRelease(intptr_t value) const {
untag()->set_length<std::memory_order_release>(Smi::New(value));
}
template <typename type,
std::memory_order order = std::memory_order_relaxed,
typename value_type>
void StoreArrayPointer(type const* addr, value_type value) const {
ptr()->untag()->StoreArrayPointer<type, order, value_type>(addr, value);
}
// Store a range of pointers [from, from + count) into [to, to + count).
// TODO(koda): Use this to fix Object::Clone's broken store buffer logic.
void StoreArrayPointers(CompressedObjectPtr const* to,
CompressedObjectPtr const* from,
intptr_t count) {
ASSERT(Contains(reinterpret_cast<uword>(to)));
if (ptr()->IsNewObject()) {
memmove(const_cast<CompressedObjectPtr*>(to), from,
count * kBytesPerElement);
} else {
const uword heap_base = ptr()->heap_base();
for (intptr_t i = 0; i < count; ++i) {
StoreArrayPointer(&to[i], from[i].Decompress(heap_base));
}
}
}
FINAL_HEAP_OBJECT_IMPLEMENTATION(Array, Instance);
friend class Class;
friend class ImmutableArray;
friend class Object;
friend class String;
};
class ImmutableArray : public AllStatic {
public:
static constexpr bool ContainsCompressedPointers() {
return Array::ContainsCompressedPointers();
}
static ImmutableArrayPtr New(intptr_t len, Heap::Space space = Heap::kNew);
static ImmutableArrayPtr ReadFrom(SnapshotReader* reader,
intptr_t object_id,
intptr_t tags,
Snapshot::Kind kind,
bool as_reference);
static const ClassId kClassId = kImmutableArrayCid;
static intptr_t InstanceSize() { return Array::InstanceSize(); }
static intptr_t InstanceSize(intptr_t len) {
return Array::InstanceSize(len);
}
private:
static intptr_t NextFieldOffset() {
// Indicates this class cannot be extended by dart code.
return -kWordSize;
}
static ImmutableArrayPtr raw(const Array& array) {
return static_cast<ImmutableArrayPtr>(array.ptr());
}
friend class Class;
};
class GrowableObjectArray : public Instance {
public:
intptr_t Capacity() const {
NoSafepointScope no_safepoint;
ASSERT(!IsNull());
return Smi::Value(DataArray()->length());
}
intptr_t Length() const {
ASSERT(!IsNull());
return Smi::Value(untag()->length());
}
void SetLength(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
untag()->set_length(Smi::New(value));
}
ArrayPtr data() const { return untag()->data(); }
void SetData(const Array& value) const { untag()->set_data(value.ptr()); }
ObjectPtr At(intptr_t index) const {
NoSafepointScope no_safepoint;
ASSERT(!IsNull());
ASSERT(index < Length());
return data()->untag()->element(index);
}
void SetAt(intptr_t index, const Object& value) const {
ASSERT(!IsNull());
ASSERT(index < Length());
// TODO(iposva): Add storing NoSafepointScope.
data()->untag()->set_element(index, value.ptr());
}
void Add(const Object& value, Heap::Space space = Heap::kNew) const;
void Grow(intptr_t new_capacity, Heap::Space space = Heap::kNew) const;
ObjectPtr RemoveLast() const;
virtual TypeArgumentsPtr GetTypeArguments() const {
return untag()->type_arguments();
}
virtual void SetTypeArguments(const TypeArguments& value) const {
// A GrowableObjectArray is raw or takes one type argument. However, its
// type argument vector may be longer than 1 due to a type optimization
// reusing the type argument vector of the instantiator.
ASSERT(value.IsNull() || ((value.Length() >= 1) && value.IsInstantiated() &&
value.IsCanonical()));
untag()->set_type_arguments(value.ptr());
}
// We don't expect a growable object array to be canonicalized.
virtual bool CanonicalizeEquals(const Instance& other) const {
UNREACHABLE();
return false;
}
// We don't expect a growable object array to be canonicalized.
virtual InstancePtr CanonicalizeLocked(Thread* thread) const {
UNREACHABLE();
return Instance::null();
}
static intptr_t type_arguments_offset() {
return OFFSET_OF(UntaggedGrowableObjectArray, type_arguments_);
}
static intptr_t length_offset() {
return OFFSET_OF(UntaggedGrowableObjectArray, length_);
}
static intptr_t data_offset() {
return OFFSET_OF(UntaggedGrowableObjectArray, data_);
}
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedGrowableObjectArray));
}
static GrowableObjectArrayPtr New(Heap::Space space = Heap::kNew) {
return New(kDefaultInitialCapacity, space);
}
static GrowableObjectArrayPtr New(intptr_t capacity,
Heap::Space space = Heap::kNew);
static GrowableObjectArrayPtr New(const Array& array,
Heap::Space space = Heap::kNew);
static SmiPtr NoSafepointLength(const GrowableObjectArrayPtr array) {
return array->untag()->length();
}
static ArrayPtr NoSafepointData(const GrowableObjectArrayPtr array) {
return array->untag()->data();
}
private:
UntaggedArray* DataArray() const { return data()->untag(); }
static const int kDefaultInitialCapacity = 0;
FINAL_HEAP_OBJECT_IMPLEMENTATION(GrowableObjectArray, Instance);
friend class Array;
friend class Class;
};
class Float32x4 : public Instance {
public:
static Float32x4Ptr New(float value0,
float value1,
float value2,
float value3,
Heap::Space space = Heap::kNew);
static Float32x4Ptr New(simd128_value_t value,
Heap::Space space = Heap::kNew);
float x() const;
float y() const;
float z() const;
float w() const;
void set_x(float x) const;
void set_y(float y) const;
void set_z(float z) const;
void set_w(float w) const;
simd128_value_t value() const;
void set_value(simd128_value_t value) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedFloat32x4));
}
static intptr_t value_offset() {
return OFFSET_OF(UntaggedFloat32x4, value_);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Float32x4, Instance);
friend class Class;
};
class Int32x4 : public Instance {
public:
static Int32x4Ptr New(int32_t value0,
int32_t value1,
int32_t value2,
int32_t value3,
Heap::Space space = Heap::kNew);
static Int32x4Ptr New(simd128_value_t value, Heap::Space space = Heap::kNew);
int32_t x() const;
int32_t y() const;
int32_t z() const;
int32_t w() const;
void set_x(int32_t x) const;
void set_y(int32_t y) const;
void set_z(int32_t z) const;
void set_w(int32_t w) const;
simd128_value_t value() const;
void set_value(simd128_value_t value) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedInt32x4));
}
static intptr_t value_offset() { return OFFSET_OF(UntaggedInt32x4, value_); }
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Int32x4, Instance);
friend class Class;
};
class Float64x2 : public Instance {
public:
static Float64x2Ptr New(double value0,
double value1,
Heap::Space space = Heap::kNew);
static Float64x2Ptr New(simd128_value_t value,
Heap::Space space = Heap::kNew);
double x() const;
double y() const;
void set_x(double x) const;
void set_y(double y) const;
simd128_value_t value() const;
void set_value(simd128_value_t value) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedFloat64x2));
}
static intptr_t value_offset() {
return OFFSET_OF(UntaggedFloat64x2, value_);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Float64x2, Instance);
friend class Class;
};
class PointerBase : public Instance {
public:
static intptr_t data_field_offset() {
return OFFSET_OF(UntaggedPointerBase, data_);
}
};
class TypedDataBase : public PointerBase {
public:
static intptr_t length_offset() {
return OFFSET_OF(UntaggedTypedDataBase, length_);
}
SmiPtr length() const { return untag()->length(); }
intptr_t Length() const {
ASSERT(!IsNull());
return Smi::Value(untag()->length());
}
intptr_t LengthInBytes() const {
return ElementSizeInBytes(ptr()->GetClassId()) * Length();
}
TypedDataElementType ElementType() const {
return ElementType(ptr()->GetClassId());
}
intptr_t ElementSizeInBytes() const {
return element_size(ElementType(ptr()->GetClassId()));
}
static intptr_t ElementSizeInBytes(classid_t cid) {
return element_size(ElementType(cid));
}
static TypedDataElementType ElementType(classid_t cid) {
if (cid == kByteDataViewCid) {
return kUint8ArrayElement;
} else if (IsTypedDataClassId(cid)) {
const intptr_t index =
(cid - kTypedDataInt8ArrayCid - kTypedDataCidRemainderInternal) / 3;
return static_cast<TypedDataElementType>(index);
} else if (IsTypedDataViewClassId(cid)) {
const intptr_t index =
(cid - kTypedDataInt8ArrayCid - kTypedDataCidRemainderView) / 3;
return static_cast<TypedDataElementType>(index);
} else {
ASSERT(IsExternalTypedDataClassId(cid));
const intptr_t index =
(cid - kTypedDataInt8ArrayCid - kTypedDataCidRemainderExternal) / 3;
return static_cast<TypedDataElementType>(index);
}
}
void* DataAddr(intptr_t byte_offset) const {
ASSERT((byte_offset == 0) ||
((byte_offset > 0) && (byte_offset < LengthInBytes())));
return reinterpret_cast<void*>(Validate(untag()->data_) + byte_offset);
}
#define TYPED_GETTER_SETTER(name, type) \
type Get##name(intptr_t byte_offset) const { \
NoSafepointScope no_safepoint; \
return LoadUnaligned(reinterpret_cast<type*>(DataAddr(byte_offset))); \
} \
void Set##name(intptr_t byte_offset, type value) const { \
NoSafepointScope no_safepoint; \
StoreUnaligned(reinterpret_cast<type*>(DataAddr(byte_offset)), value); \
}
TYPED_GETTER_SETTER(Int8, int8_t)
TYPED_GETTER_SETTER(Uint8, uint8_t)
TYPED_GETTER_SETTER(Int16, int16_t)
TYPED_GETTER_SETTER(Uint16, uint16_t)
TYPED_GETTER_SETTER(Int32, int32_t)
TYPED_GETTER_SETTER(Uint32, uint32_t)
TYPED_GETTER_SETTER(Int64, int64_t)
TYPED_GETTER_SETTER(Uint64, uint64_t)
TYPED_GETTER_SETTER(Float32, float)
TYPED_GETTER_SETTER(Float64, double)
TYPED_GETTER_SETTER(Float32x4, simd128_value_t)
TYPED_GETTER_SETTER(Int32x4, simd128_value_t)
TYPED_GETTER_SETTER(Float64x2, simd128_value_t)
#undef TYPED_GETTER_SETTER
protected:
void SetLength(intptr_t value) const {
ASSERT(value <= Smi::kMaxValue);
untag()->set_length(Smi::New(value));
}
virtual uint8_t* Validate(uint8_t* data) const {
return UnsafeMutableNonPointer(data);
}
private:
friend class Class;
static intptr_t element_size(intptr_t index) {
ASSERT(0 <= index && index < kNumElementSizes);
intptr_t size = element_size_table[index];
ASSERT(size != 0);
return size;
}
static const intptr_t kNumElementSizes =
(kTypedDataFloat64x2ArrayCid - kTypedDataInt8ArrayCid) / 3 + 1;
static const intptr_t element_size_table[kNumElementSizes];
HEAP_OBJECT_IMPLEMENTATION(TypedDataBase, PointerBase);
};
class TypedData : public TypedDataBase {
public:
// We use 30 bits for the hash code so hashes in a snapshot taken on a
// 64-bit architecture stay in Smi range when loaded on a 32-bit
// architecture.
static const intptr_t kHashBits = 30;
virtual bool CanonicalizeEquals(const Instance& other) const;
virtual uint32_t CanonicalizeHash() const;
#define TYPED_GETTER_SETTER(name, type) \
type Get##name(intptr_t byte_offset) const { \
ASSERT((byte_offset >= 0) && \
(byte_offset + static_cast<intptr_t>(sizeof(type)) - 1) < \
LengthInBytes()); \
return LoadUnaligned(ReadOnlyDataAddr<type>(byte_offset)); \
} \
void Set##name(intptr_t byte_offset, type value) const { \
NoSafepointScope no_safepoint; \
StoreUnaligned(reinterpret_cast<type*>(DataAddr(byte_offset)), value); \
}
TYPED_GETTER_SETTER(Int8, int8_t)
TYPED_GETTER_SETTER(Uint8, uint8_t)
TYPED_GETTER_SETTER(Int16, int16_t)
TYPED_GETTER_SETTER(Uint16, uint16_t)
TYPED_GETTER_SETTER(Int32, int32_t)
TYPED_GETTER_SETTER(Uint32, uint32_t)
TYPED_GETTER_SETTER(Int64, int64_t)
TYPED_GETTER_SETTER(Uint64, uint64_t)
TYPED_GETTER_SETTER(Float32, float)
TYPED_GETTER_SETTER(Float64, double)
TYPED_GETTER_SETTER(Float32x4, simd128_value_t)
TYPED_GETTER_SETTER(Int32x4, simd128_value_t)
TYPED_GETTER_SETTER(Float64x2, simd128_value_t)
#undef TYPED_GETTER_SETTER
static intptr_t data_offset() { return UntaggedTypedData::payload_offset(); }
static intptr_t InstanceSize() {
ASSERT(sizeof(UntaggedTypedData) ==
OFFSET_OF_RETURNED_VALUE(UntaggedTypedData, internal_data));
return 0;
}
static intptr_t InstanceSize(intptr_t lengthInBytes) {
ASSERT(0 <= lengthInBytes && lengthInBytes <= kSmiMax);
return RoundedAllocationSize(sizeof(UntaggedTypedData) + lengthInBytes);
}
static intptr_t MaxElements(intptr_t class_id) {
ASSERT(IsTypedDataClassId(class_id));
return (kSmiMax / ElementSizeInBytes(class_id));
}
static intptr_t MaxNewSpaceElements(intptr_t class_id) {
ASSERT(IsTypedDataClassId(class_id));
return (Heap::kNewAllocatableSize - sizeof(UntaggedTypedData)) /
ElementSizeInBytes(class_id);
}
static TypedDataPtr New(intptr_t class_id,
intptr_t len,
Heap::Space space = Heap::kNew);
static void Copy(const TypedDataBase& dst,
intptr_t dst_offset_in_bytes,
const TypedDataBase& src,
intptr_t src_offset_in_bytes,
intptr_t length_in_bytes) {
ASSERT(Utils::RangeCheck(src_offset_in_bytes, length_in_bytes,
src.LengthInBytes()));
ASSERT(Utils::RangeCheck(dst_offset_in_bytes, length_in_bytes,
dst.LengthInBytes()));
{
NoSafepointScope no_safepoint;
if (length_in_bytes > 0) {
memmove(dst.DataAddr(dst_offset_in_bytes),
src.DataAddr(src_offset_in_bytes), length_in_bytes);
}
}
}
static void ClampedCopy(const TypedDataBase& dst,
intptr_t dst_offset_in_bytes,
const TypedDataBase& src,
intptr_t src_offset_in_bytes,
intptr_t length_in_bytes) {
ASSERT(Utils::RangeCheck(src_offset_in_bytes, length_in_bytes,
src.LengthInBytes()));
ASSERT(Utils::RangeCheck(dst_offset_in_bytes, length_in_bytes,
dst.LengthInBytes()));
{
NoSafepointScope no_safepoint;
if (length_in_bytes > 0) {
uint8_t* dst_data =
reinterpret_cast<uint8_t*>(dst.DataAddr(dst_offset_in_bytes));
int8_t* src_data =
reinterpret_cast<int8_t*>(src.DataAddr(src_offset_in_bytes));
for (intptr_t ix = 0; ix < length_in_bytes; ix++) {
int8_t v = *src_data;
if (v < 0) v = 0;
*dst_data = v;
src_data++;
dst_data++;
}
}
}
}
static bool IsTypedData(const Instance& obj) {
ASSERT(!obj.IsNull());
intptr_t cid = obj.ptr()->GetClassId();
return IsTypedDataClassId(cid);
}
protected:
void RecomputeDataField() { ptr()->untag()->RecomputeDataField(); }
private:
// Provides const access to non-pointer, non-aligned data within the object.
// Such access does not need a write barrier, but it is *not* GC-safe, since
// the object might move.
//
// Therefore this method is private and the call-sites in this class need to
// ensure the returned pointer does not escape.
template <typename FieldType>
const FieldType* ReadOnlyDataAddr(intptr_t byte_offset) const {
return reinterpret_cast<const FieldType*>((untag()->data()) + byte_offset);
}
FINAL_HEAP_OBJECT_IMPLEMENTATION(TypedData, TypedDataBase);
friend class Class;
friend class ExternalTypedData;
friend class TypedDataView;
};
class ExternalTypedData : public TypedDataBase {
public:
// Alignment of data when serializing ExternalTypedData in a clustered
// snapshot. Should be independent of word size.
static const int kDataSerializationAlignment = 8;
FinalizablePersistentHandle* AddFinalizer(void* peer,
Dart_HandleFinalizer callback,
intptr_t external_size) const;
static intptr_t data_offset() {
return OFFSET_OF(UntaggedExternalTypedData, data_);
}
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedExternalTypedData));
}
static intptr_t MaxElements(intptr_t class_id) {
ASSERT(IsExternalTypedDataClassId(class_id));
return (kSmiMax / ElementSizeInBytes(class_id));
}
static ExternalTypedDataPtr New(
intptr_t class_id,
uint8_t* data,
intptr_t len,
Heap::Space space = Heap::kNew,
bool perform_eager_msan_initialization_check = true);
static ExternalTypedDataPtr NewFinalizeWithFree(uint8_t* data, intptr_t len);
static bool IsExternalTypedData(const Instance& obj) {
ASSERT(!obj.IsNull());
intptr_t cid = obj.ptr()->GetClassId();
return IsExternalTypedDataClassId(cid);
}
protected:
virtual uint8_t* Validate(uint8_t* data) const { return data; }
void SetLength(intptr_t value) const {
ASSERT(value <= Smi::kMaxValue);
untag()->set_length(Smi::New(value));
}
void SetData(uint8_t* data) const {
ASSERT(!IsolateGroup::Current()->heap()->Contains(
reinterpret_cast<uword>(data)));
StoreNonPointer(&untag()->data_, data);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(ExternalTypedData, TypedDataBase);
friend class Class;
};
class TypedDataView : public TypedDataBase {
public:
static TypedDataViewPtr New(intptr_t class_id,
Heap::Space space = Heap::kNew);
static TypedDataViewPtr New(intptr_t class_id,
const TypedDataBase& typed_data,
intptr_t offset_in_bytes,
intptr_t length,
Heap::Space space = Heap::kNew);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedTypedDataView));
}
static InstancePtr Data(const TypedDataView& view) {
return view.typed_data();
}
static SmiPtr OffsetInBytes(const TypedDataView& view) {
return view.offset_in_bytes();
}
static bool IsExternalTypedDataView(const TypedDataView& view_obj) {
const auto& data = Instance::Handle(Data(view_obj));
intptr_t cid = data.ptr()->GetClassId();
ASSERT(IsTypedDataClassId(cid) || IsExternalTypedDataClassId(cid));
return IsExternalTypedDataClassId(cid);
}
static intptr_t data_offset() {
return OFFSET_OF(UntaggedTypedDataView, typed_data_);
}
static intptr_t offset_in_bytes_offset() {
return OFFSET_OF(UntaggedTypedDataView, offset_in_bytes_);
}
InstancePtr typed_data() const { return untag()->typed_data(); }
void InitializeWith(const TypedDataBase& typed_data,
intptr_t offset_in_bytes,
intptr_t length) {
const classid_t cid = typed_data.GetClassId();
ASSERT(IsTypedDataClassId(cid) || IsExternalTypedDataClassId(cid));
untag()->set_typed_data(typed_data.ptr());
untag()->set_length(Smi::New(length));
untag()->set_offset_in_bytes(Smi::New(offset_in_bytes));
// Update the inner pointer.
RecomputeDataField();
}
SmiPtr offset_in_bytes() const { return untag()->offset_in_bytes(); }
protected:
virtual uint8_t* Validate(uint8_t* data) const { return data; }
private:
void RecomputeDataField() { ptr()->untag()->RecomputeDataField(); }
void Clear() {
untag()->set_length(Smi::New(0));
untag()->set_offset_in_bytes(Smi::New(0));
StoreNonPointer(&untag()->data_, nullptr);
untag()->set_typed_data(TypedDataBase::RawCast(Object::null()));
}
FINAL_HEAP_OBJECT_IMPLEMENTATION(TypedDataView, TypedDataBase);
friend class Class;
friend class Object;
friend class TypedDataViewDeserializationCluster;
};
class ByteBuffer : public AllStatic {
public:
static constexpr bool ContainsCompressedPointers() {
return Instance::ContainsCompressedPointers();
}
static InstancePtr Data(const Instance& view_obj) {
ASSERT(!view_obj.IsNull());
return reinterpret_cast<CompressedInstancePtr*>(
reinterpret_cast<uword>(view_obj.untag()) + data_offset())
->Decompress(view_obj.untag()->heap_base());
}
static intptr_t NumberOfFields() { return kNumFields; }
static intptr_t data_offset() {
return sizeof(UntaggedObject) + (kCompressedWordSize * kDataIndex);
}
private:
enum {
kDataIndex = 0,
kNumFields = 1,
};
};
class Pointer : public Instance {
public:
static PointerPtr New(const AbstractType& type_arg,
uword native_address,
Heap::Space space = Heap::kNew);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedPointer));
}
static bool IsPointer(const Instance& obj);
size_t NativeAddress() const {
return reinterpret_cast<size_t>(untag()->data_);
}
void SetNativeAddress(size_t address) const {
uint8_t* value = reinterpret_cast<uint8_t*>(address);
StoreNonPointer(&untag()->data_, value);
}
static intptr_t type_arguments_offset() {
return OFFSET_OF(UntaggedPointer, type_arguments_);
}
static const intptr_t kNativeTypeArgPos = 0;
// Fetches the NativeType type argument.
AbstractTypePtr type_argument() const {
TypeArguments& type_args = TypeArguments::Handle(GetTypeArguments());
return type_args.TypeAtNullSafe(Pointer::kNativeTypeArgPos);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Pointer, Instance);
friend class Class;
};
class DynamicLibrary : public Instance {
public:
static DynamicLibraryPtr New(void* handle, Heap::Space space = Heap::kNew);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedDynamicLibrary));
}
static bool IsDynamicLibrary(const Instance& obj) {
ASSERT(!obj.IsNull());
intptr_t cid = obj.ptr()->GetClassId();
return IsFfiDynamicLibraryClassId(cid);
}
void* GetHandle() const {
ASSERT(!IsNull());
return untag()->handle_;
}
void SetHandle(void* value) const {
StoreNonPointer(&untag()->handle_, value);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(DynamicLibrary, Instance);
friend class Class;
};
class LinkedHashBase : public Instance {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLinkedHashBase));
}
static intptr_t type_arguments_offset() {
return OFFSET_OF(UntaggedLinkedHashBase, type_arguments_);
}
static intptr_t index_offset() {
return OFFSET_OF(UntaggedLinkedHashBase, index_);
}
static intptr_t data_offset() {
return OFFSET_OF(UntaggedLinkedHashBase, data_);
}
static intptr_t hash_mask_offset() {
return OFFSET_OF(UntaggedLinkedHashBase, hash_mask_);
}
static intptr_t used_data_offset() {
return OFFSET_OF(UntaggedLinkedHashBase, used_data_);
}
static intptr_t deleted_keys_offset() {
return OFFSET_OF(UntaggedLinkedHashBase, deleted_keys_);
}
protected:
// Keep this in sync with Dart implementation (lib/compact_hash.dart).
static const intptr_t kInitialIndexBits = 2;
static const intptr_t kInitialIndexSize = 1 << (kInitialIndexBits + 1);
friend class Class;
friend class LinkedHashBaseDeserializationCluster;
};
// Corresponds to
// - "new Map()",
// - non-const map literals, and
// - the default constructor of LinkedHashMap in dart:collection.
class LinkedHashMap : public LinkedHashBase {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLinkedHashMap));
}
// Allocates a map with some default capacity, just like "new Map()".
static LinkedHashMapPtr NewDefault(Heap::Space space = Heap::kNew);
static LinkedHashMapPtr New(const Array& data,
const TypedData& index,
intptr_t hash_mask,
intptr_t used_data,
intptr_t deleted_keys,
Heap::Space space = Heap::kNew);
virtual TypeArgumentsPtr GetTypeArguments() const {
return untag()->type_arguments();
}
virtual void SetTypeArguments(const TypeArguments& value) const {
ASSERT(value.IsNull() ||
((value.Length() >= 2) &&
value.IsInstantiated() /*&& value.IsCanonical()*/));
// TODO(asiva): Values read from a message snapshot are not properly marked
// as canonical. See for example tests/isolate/message3_test.dart.
untag()->set_type_arguments(value.ptr());
}
TypedDataPtr index() const { return untag()->index(); }
void SetIndex(const TypedData& value) const {
ASSERT(!value.IsNull());
untag()->set_index(value.ptr());
}
ArrayPtr data() const { return untag()->data(); }
void SetData(const Array& value) const { untag()->set_data(value.ptr()); }
SmiPtr hash_mask() const { return untag()->hash_mask(); }
void SetHashMask(intptr_t value) const {
untag()->set_hash_mask(Smi::New(value));
}
SmiPtr used_data() const { return untag()->used_data(); }
void SetUsedData(intptr_t value) const {
untag()->set_used_data(Smi::New(value));
}
SmiPtr deleted_keys() const { return untag()->deleted_keys(); }
void SetDeletedKeys(intptr_t value) const {
untag()->set_deleted_keys(Smi::New(value));
}
intptr_t Length() const {
// The map may be uninitialized.
if (untag()->used_data() == Object::null()) return 0;
if (untag()->deleted_keys() == Object::null()) return 0;
intptr_t used = Smi::Value(untag()->used_data());
intptr_t deleted = Smi::Value(untag()->deleted_keys());
return (used >> 1) - deleted;
}
// This iterator differs somewhat from its Dart counterpart (_CompactIterator
// in runtime/lib/compact_hash.dart):
// - There are no checks for concurrent modifications.
// - Accessing a key or value before the first call to MoveNext and after
// MoveNext returns false will result in crashes.
class Iterator : ValueObject {
public:
explicit Iterator(const LinkedHashMap& map)
: data_(Array::Handle(map.data())),
scratch_(Object::Handle()),
offset_(-2),
length_(Smi::Value(map.used_data())) {}
bool MoveNext() {
while (true) {
offset_ += 2;
if (offset_ >= length_) {
return false;
}
scratch_ = data_.At(offset_);
if (scratch_.ptr() != data_.ptr()) {
// Slot is not deleted (self-reference indicates deletion).
return true;
}
}
}
ObjectPtr CurrentKey() const { return data_.At(offset_); }
ObjectPtr CurrentValue() const { return data_.At(offset_ + 1); }
private:
const Array& data_;
Object& scratch_;
intptr_t offset_;
const intptr_t length_;
};
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(LinkedHashMap, LinkedHashBase);
// Allocate a map, but leave all fields set to null.
// Used during deserialization (since map might contain itself as key/value).
static LinkedHashMapPtr NewUninitialized(Heap::Space space = Heap::kNew);
friend class Class;
friend class LinkedHashMapDeserializationCluster;
};
class LinkedHashSet : public LinkedHashBase {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedLinkedHashSet));
}
// Allocates a set with some default capacity, just like "new Set()".
static LinkedHashSetPtr NewDefault(Heap::Space space = Heap::kNew);
static LinkedHashSetPtr New(const Array& data,
const TypedData& index,
intptr_t hash_mask,
intptr_t used_data,
intptr_t deleted_keys,
Heap::Space space = Heap::kNew);
virtual TypeArgumentsPtr GetTypeArguments() const {
return untag()->type_arguments();
}
virtual void SetTypeArguments(const TypeArguments& value) const {
ASSERT(value.IsNull() ||
((value.Length() >= 1) &&
value.IsInstantiated() /*&& value.IsCanonical()*/));
// TODO(asiva): Values read from a message snapshot are not properly marked
// as canonical. See for example tests/isolate/message3_test.dart.
untag()->set_type_arguments(value.ptr());
}
TypedDataPtr index() const { return untag()->index(); }
void SetIndex(const TypedData& value) const {
ASSERT(!value.IsNull());
untag()->set_index(value.ptr());
}
ArrayPtr data() const { return untag()->data(); }
void SetData(const Array& value) const { untag()->set_data(value.ptr()); }
SmiPtr hash_mask() const { return untag()->hash_mask(); }
void SetHashMask(intptr_t value) const {
untag()->set_hash_mask(Smi::New(value));
}
SmiPtr used_data() const { return untag()->used_data(); }
void SetUsedData(intptr_t value) const {
untag()->set_used_data(Smi::New(value));
}
SmiPtr deleted_keys() const { return untag()->deleted_keys(); }
void SetDeletedKeys(intptr_t value) const {
untag()->set_deleted_keys(Smi::New(value));
}
intptr_t Length() const {
// The map may be uninitialized.
if (untag()->used_data() == Object::null()) return 0;
if (untag()->deleted_keys() == Object::null()) return 0;
intptr_t used = Smi::Value(untag()->used_data());
intptr_t deleted = Smi::Value(untag()->deleted_keys());
return used - deleted;
}
// This iterator differs somewhat from its Dart counterpart (_CompactIterator
// in runtime/lib/compact_hash.dart):
// - There are no checks for concurrent modifications.
// - Accessing a key or value before the first call to MoveNext and after
// MoveNext returns false will result in crashes.
class Iterator : ValueObject {
public:
explicit Iterator(const LinkedHashSet& set)
: data_(Array::Handle(set.data())),
scratch_(Object::Handle()),
offset_(-1),
length_(Smi::Value(set.used_data())) {}
bool MoveNext() {
while (true) {
offset_++;
if (offset_ >= length_) {
return false;
}
scratch_ = data_.At(offset_);
if (scratch_.ptr() != data_.ptr()) {
// Slot is not deleted (self-reference indicates deletion).
return true;
}
}
}
ObjectPtr CurrentKey() const { return data_.At(offset_); }
private:
const Array& data_;
Object& scratch_;
intptr_t offset_;
const intptr_t length_;
};
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(LinkedHashSet, LinkedHashBase);
// Allocate a set, but leave all fields set to null.
// Used during deserialization (since set might contain itself as key/value).
static LinkedHashSetPtr NewUninitialized(Heap::Space space = Heap::kNew);
friend class Class;
};
class Closure : public Instance {
public:
#if defined(DART_PRECOMPILED_RUNTIME)
uword entry_point() const { return untag()->entry_point_; }
void set_entry_point(uword entry_point) const {
StoreNonPointer(&untag()->entry_point_, entry_point);
}
static intptr_t entry_point_offset() {
return OFFSET_OF(UntaggedClosure, entry_point_);
}
#endif
TypeArgumentsPtr instantiator_type_arguments() const {
return untag()->instantiator_type_arguments();
}
void set_instantiator_type_arguments(const TypeArguments& args) const {
untag()->set_instantiator_type_arguments(args.ptr());
}
static intptr_t instantiator_type_arguments_offset() {
return OFFSET_OF(UntaggedClosure, instantiator_type_arguments_);
}
TypeArgumentsPtr function_type_arguments() const {
return untag()->function_type_arguments();
}
void set_function_type_arguments(const TypeArguments& args) const {
untag()->set_function_type_arguments(args.ptr());
}
static intptr_t function_type_arguments_offset() {
return OFFSET_OF(UntaggedClosure, function_type_arguments_);
}
TypeArgumentsPtr delayed_type_arguments() const {
return untag()->delayed_type_arguments();
}
void set_delayed_type_arguments(const TypeArguments& args) const {
untag()->set_delayed_type_arguments(args.ptr());
}
static intptr_t delayed_type_arguments_offset() {
return OFFSET_OF(UntaggedClosure, delayed_type_arguments_);
}
FunctionPtr function() const { return untag()->function(); }
static intptr_t function_offset() {
return OFFSET_OF(UntaggedClosure, function_);
}
static FunctionPtr FunctionOf(ClosurePtr closure) {
return closure.untag()->function();
}
#if defined(DART_PRECOMPILER)
FunctionTypePtr signature() const {
return FunctionType::RawCast(WeakSerializationReference::Unwrap(
untag()->function()->untag()->signature()));
}
#else
FunctionTypePtr signature() const {
return untag()->function()->untag()->signature();
}
#endif
ContextPtr context() const { return untag()->context(); }
static intptr_t context_offset() {
return OFFSET_OF(UntaggedClosure, context_);
}
static ContextPtr ContextOf(ClosurePtr closure) {
return closure.untag()->context();
}
bool IsGeneric(Thread* thread) const { return NumTypeParameters(thread) > 0; }
intptr_t NumTypeParameters(Thread* thread) const;
// No need for num_parent_type_arguments, as a closure is always closed
// over its parents type parameters (i.e., function_type_parameters() above).
SmiPtr hash() const { return untag()->hash(); }
static intptr_t hash_offset() { return OFFSET_OF(UntaggedClosure, hash_); }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedClosure));
}
virtual void CanonicalizeFieldsLocked(Thread* thread) const;
virtual bool CanonicalizeEquals(const Instance& other) const;
virtual uint32_t CanonicalizeHash() const {
return Function::Handle(function()).Hash();
}
uword ComputeHash() const;
static ClosurePtr New(const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
const Function& function,
const Context& context,
Heap::Space space = Heap::kNew);
static ClosurePtr New(const TypeArguments& instantiator_type_arguments,
const TypeArguments& function_type_arguments,
const TypeArguments& delayed_type_arguments,
const Function& function,
const Context& context,
Heap::Space space = Heap::kNew);
FunctionTypePtr GetInstantiatedSignature(Zone* zone) const;
private:
static ClosurePtr New();
FINAL_HEAP_OBJECT_IMPLEMENTATION(Closure, Instance);
friend class Class;
};
class Capability : public Instance {
public:
uint64_t Id() const { return untag()->id_; }
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedCapability));
}
static CapabilityPtr New(uint64_t id, Heap::Space space = Heap::kNew);
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(Capability, Instance);
friend class Class;
};
class ReceivePort : public Instance {
public:
SendPortPtr send_port() const { return untag()->send_port(); }
Dart_Port Id() const { return send_port()->untag()->id_; }
InstancePtr handler() const { return untag()->handler(); }
void set_handler(const Instance& value) const;
#if !defined(PRODUCT)
StackTracePtr allocation_location() const {
return untag()->allocation_location();
}
StringPtr debug_name() const { return untag()->debug_name(); }
#endif
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedReceivePort));
}
static ReceivePortPtr New(Dart_Port id,
const String& debug_name,
bool is_control_port,
Heap::Space space = Heap::kNew);
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(ReceivePort, Instance);
friend class Class;
};
class SendPort : public Instance {
public:
Dart_Port Id() const { return untag()->id_; }
Dart_Port origin_id() const { return untag()->origin_id_; }
void set_origin_id(Dart_Port id) const {
ASSERT(origin_id() == 0);
StoreNonPointer(&(untag()->origin_id_), id);
}
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedSendPort));
}
static SendPortPtr New(Dart_Port id, Heap::Space space = Heap::kNew);
static SendPortPtr New(Dart_Port id,
Dart_Port origin_id,
Heap::Space space = Heap::kNew);
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(SendPort, Instance);
friend class Class;
};
// This is allocated when new instance of TransferableTypedData is created in
// [TransferableTypedData::New].
class TransferableTypedDataPeer {
public:
// [data] backing store should be malloc'ed, not new'ed.
TransferableTypedDataPeer(uint8_t* data, intptr_t length)
: data_(data), length_(length), handle_(nullptr) {}
~TransferableTypedDataPeer() { free(data_); }
uint8_t* data() const { return data_; }
intptr_t length() const { return length_; }
FinalizablePersistentHandle* handle() const { return handle_; }
void set_handle(FinalizablePersistentHandle* handle) { handle_ = handle; }
void ClearData() {
data_ = nullptr;
length_ = 0;
handle_ = nullptr;
}
private:
uint8_t* data_;
intptr_t length_;
FinalizablePersistentHandle* handle_;
DISALLOW_COPY_AND_ASSIGN(TransferableTypedDataPeer);
};
class TransferableTypedData : public Instance {
public:
static TransferableTypedDataPtr New(uint8_t* data, intptr_t len);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedTransferableTypedData));
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(TransferableTypedData, Instance);
friend class Class;
};
class DebuggerStackTrace;
// Internal stacktrace object used in exceptions for printing stack traces.
class StackTrace : public Instance {
public:
static const int kPreallocatedStackdepth = 90;
intptr_t Length() const;
StackTracePtr async_link() const { return untag()->async_link(); }
void set_async_link(const StackTrace& async_link) const;
void set_expand_inlined(bool value) const;
ArrayPtr code_array() const { return untag()->code_array(); }
ObjectPtr CodeAtFrame(intptr_t frame_index) const;
void SetCodeAtFrame(intptr_t frame_index, const Object& code) const;
TypedDataPtr pc_offset_array() const { return untag()->pc_offset_array(); }
uword PcOffsetAtFrame(intptr_t frame_index) const;
void SetPcOffsetAtFrame(intptr_t frame_index, uword pc_offset) const;
bool skip_sync_start_in_parent_stack() const;
void set_skip_sync_start_in_parent_stack(bool value) const;
// The number of frames that should be cut off the top of an async stack trace
// if it's appended to a synchronous stack trace along a sync-async call.
//
// Without cropping, the border would look like:
//
// <async function>
// ---------------------------
// <asynchronous gap marker>
// <async function>
//
// Since it's not actually an async call, we crop off the last two
// frames when concatenating the sync and async stacktraces.
static constexpr intptr_t kSyncAsyncCroppedFrames = 2;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedStackTrace));
}
static StackTracePtr New(const Array& code_array,
const TypedData& pc_offset_array,
Heap::Space space = Heap::kNew);
static StackTracePtr New(const Array& code_array,
const TypedData& pc_offset_array,
const StackTrace& async_link,
bool skip_sync_start_in_parent_stack,
Heap::Space space = Heap::kNew);
private:
void set_code_array(const Array& code_array) const;
void set_pc_offset_array(const TypedData& pc_offset_array) const;
bool expand_inlined() const;
FINAL_HEAP_OBJECT_IMPLEMENTATION(StackTrace, Instance);
friend class Class;
friend class DebuggerStackTrace;
};
class RegExpFlags {
public:
// Flags are passed to a regex object as follows:
// 'i': ignore case, 'g': do global matches, 'm': pattern is multi line,
// 'u': pattern is full Unicode, not just BMP, 's': '.' in pattern matches
// all characters including line terminators.
enum Flags {
kNone = 0,
kGlobal = 1,
kIgnoreCase = 2,
kMultiLine = 4,
kUnicode = 8,
kDotAll = 16,
};
static const int kDefaultFlags = 0;
RegExpFlags() : value_(kDefaultFlags) {}
explicit RegExpFlags(int value) : value_(value) {}
inline bool IsGlobal() const { return (value_ & kGlobal) != 0; }
inline bool IgnoreCase() const { return (value_ & kIgnoreCase) != 0; }
inline bool IsMultiLine() const { return (value_ & kMultiLine) != 0; }
inline bool IsUnicode() const { return (value_ & kUnicode) != 0; }
inline bool IsDotAll() const { return (value_ & kDotAll) != 0; }
inline bool NeedsUnicodeCaseEquivalents() {
// Both unicode and ignore_case flags are set. We need to use ICU to find
// the closure over case equivalents.
return IsUnicode() && IgnoreCase();
}
void SetGlobal() { value_ |= kGlobal; }
void SetIgnoreCase() { value_ |= kIgnoreCase; }
void SetMultiLine() { value_ |= kMultiLine; }
void SetUnicode() { value_ |= kUnicode; }
void SetDotAll() { value_ |= kDotAll; }
const char* ToCString() const;
int value() const { return value_; }
bool operator==(const RegExpFlags& other) { return value_ == other.value_; }
bool operator!=(const RegExpFlags& other) { return value_ != other.value_; }
private:
int value_;
};
// Internal JavaScript regular expression object.
class RegExp : public Instance {
public:
// Meaning of RegExType:
// kUninitialized: the type of th regexp has not been initialized yet.
// kSimple: A simple pattern to match against, using string indexOf operation.
// kComplex: A complex pattern to match.
enum RegExType {
kUninitialized = 0,
kSimple = 1,
kComplex = 2,
};
enum {
kTypePos = 0,
kTypeSize = 2,
kFlagsPos = 2,
kFlagsSize = 5,
};
class TypeBits : public BitField<int8_t, RegExType, kTypePos, kTypeSize> {};
class FlagsBits : public BitField<int8_t, intptr_t, kFlagsPos, kFlagsSize> {};
bool is_initialized() const { return (type() != kUninitialized); }
bool is_simple() const { return (type() == kSimple); }
bool is_complex() const { return (type() == kComplex); }
intptr_t num_registers(bool is_one_byte) const {
return is_one_byte ? untag()->num_one_byte_registers_
: untag()->num_two_byte_registers_;
}
StringPtr pattern() const { return untag()->pattern(); }
intptr_t num_bracket_expressions() const {
return untag()->num_bracket_expressions_;
}
ArrayPtr capture_name_map() const { return untag()->capture_name_map(); }
TypedDataPtr bytecode(bool is_one_byte, bool sticky) const {
if (sticky) {
return TypedData::RawCast(is_one_byte ? untag()->one_byte_sticky()
: untag()->two_byte_sticky());
} else {
return TypedData::RawCast(is_one_byte ? untag()->one_byte()
: untag()->two_byte());
}
}
static intptr_t function_offset(intptr_t cid, bool sticky) {
if (sticky) {
switch (cid) {
case kOneByteStringCid:
return OFFSET_OF(UntaggedRegExp, one_byte_sticky_);
case kTwoByteStringCid:
return OFFSET_OF(UntaggedRegExp, two_byte_sticky_);
case kExternalOneByteStringCid:
return OFFSET_OF(UntaggedRegExp, external_one_byte_sticky_);
case kExternalTwoByteStringCid:
return OFFSET_OF(UntaggedRegExp, external_two_byte_sticky_);
}
} else {
switch (cid) {
case kOneByteStringCid:
return OFFSET_OF(UntaggedRegExp, one_byte_);
case kTwoByteStringCid:
return OFFSET_OF(UntaggedRegExp, two_byte_);
case kExternalOneByteStringCid:
return OFFSET_OF(UntaggedRegExp, external_one_byte_);
case kExternalTwoByteStringCid:
return OFFSET_OF(UntaggedRegExp, external_two_byte_);
}
}
UNREACHABLE();
return -1;
}
FunctionPtr function(intptr_t cid, bool sticky) const {
if (sticky) {
switch (cid) {
case kOneByteStringCid:
return static_cast<FunctionPtr>(untag()->one_byte_sticky());
case kTwoByteStringCid:
return static_cast<FunctionPtr>(untag()->two_byte_sticky());
case kExternalOneByteStringCid:
return static_cast<FunctionPtr>(untag()->external_one_byte_sticky());
case kExternalTwoByteStringCid:
return static_cast<FunctionPtr>(untag()->external_two_byte_sticky());
}
} else {
switch (cid) {
case kOneByteStringCid:
return static_cast<FunctionPtr>(untag()->one_byte());
case kTwoByteStringCid:
return static_cast<FunctionPtr>(untag()->two_byte());
case kExternalOneByteStringCid:
return static_cast<FunctionPtr>(untag()->external_one_byte());
case kExternalTwoByteStringCid:
return static_cast<FunctionPtr>(untag()->external_two_byte());
}
}
UNREACHABLE();
return Function::null();
}
void set_pattern(const String& pattern) const;
void set_function(intptr_t cid, bool sticky, const Function& value) const;
void set_bytecode(bool is_one_byte,
bool sticky,
const TypedData& bytecode) const;
void set_num_bracket_expressions(SmiPtr value) const;
void set_num_bracket_expressions(const Smi& value) const;
void set_num_bracket_expressions(intptr_t value) const;
void set_capture_name_map(const Array& array) const;
void set_is_global() const {
RegExpFlags f = flags();
f.SetGlobal();
set_flags(f);
}
void set_is_ignore_case() const {
RegExpFlags f = flags();
f.SetIgnoreCase();
set_flags(f);
}
void set_is_multi_line() const {
RegExpFlags f = flags();
f.SetMultiLine();
set_flags(f);
}
void set_is_unicode() const {
RegExpFlags f = flags();
f.SetUnicode();
set_flags(f);
}
void set_is_dot_all() const {
RegExpFlags f = flags();
f.SetDotAll();
set_flags(f);
}
void set_is_simple() const { set_type(kSimple); }
void set_is_complex() const { set_type(kComplex); }
void set_num_registers(bool is_one_byte, intptr_t value) const {
if (is_one_byte) {
StoreNonPointer(&untag()->num_one_byte_registers_, value);
} else {
StoreNonPointer(&untag()->num_two_byte_registers_, value);
}
}
RegExpFlags flags() const {
return RegExpFlags(FlagsBits::decode(untag()->type_flags_));
}
void set_flags(RegExpFlags flags) const {
StoreNonPointer(&untag()->type_flags_,
FlagsBits::update(flags.value(), untag()->type_flags_));
}
const char* Flags() const;
virtual bool CanonicalizeEquals(const Instance& other) const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedRegExp));
}
static RegExpPtr New(Zone* zone, Heap::Space space = Heap::kNew);
private:
void set_type(RegExType type) const {
StoreNonPointer(&untag()->type_flags_,
TypeBits::update(type, untag()->type_flags_));
}
RegExType type() const { return TypeBits::decode(untag()->type_flags_); }
FINAL_HEAP_OBJECT_IMPLEMENTATION(RegExp, Instance);
friend class Class;
};
class WeakProperty : public Instance {
public:
ObjectPtr key() const { return untag()->key(); }
void set_key(const Object& key) const { untag()->set_key(key.ptr()); }
static intptr_t key_offset() { return OFFSET_OF(UntaggedWeakProperty, key_); }
ObjectPtr value() const { return untag()->value(); }
void set_value(const Object& value) const { untag()->set_value(value.ptr()); }
static intptr_t value_offset() {
return OFFSET_OF(UntaggedWeakProperty, value_);
}
static WeakPropertyPtr New(Heap::Space space = Heap::kNew);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedWeakProperty));
}
static void Clear(WeakPropertyPtr raw_weak) {
ASSERT(raw_weak->untag()->next_ ==
CompressedWeakPropertyPtr(WeakProperty::null()));
// This action is performed by the GC. No barrier.
raw_weak->untag()->key_ = Object::null();
raw_weak->untag()->value_ = Object::null();
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(WeakProperty, Instance);
friend class Class;
};
class MirrorReference : public Instance {
public:
ObjectPtr referent() const { return untag()->referent(); }
void set_referent(const Object& referent) const {
untag()->set_referent(referent.ptr());
}
AbstractTypePtr GetAbstractTypeReferent() const;
ClassPtr GetClassReferent() const;
FieldPtr GetFieldReferent() const;
FunctionPtr GetFunctionReferent() const;
FunctionTypePtr GetFunctionTypeReferent() const;
LibraryPtr GetLibraryReferent() const;
TypeParameterPtr GetTypeParameterReferent() const;
static MirrorReferencePtr New(const Object& referent,
Heap::Space space = Heap::kNew);
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedMirrorReference));
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(MirrorReference, Instance);
friend class Class;
};
class UserTag : public Instance {
public:
uword tag() const { return untag()->tag(); }
void set_tag(uword t) const {
ASSERT(t >= UserTags::kUserTagIdOffset);
ASSERT(t < UserTags::kUserTagIdOffset + UserTags::kMaxUserTags);
StoreNonPointer(&untag()->tag_, t);
}
static intptr_t tag_offset() { return OFFSET_OF(UntaggedUserTag, tag_); }
StringPtr label() const { return untag()->label(); }
UserTagPtr MakeActive() const;
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedUserTag));
}
static UserTagPtr New(const String& label, Heap::Space space = Heap::kOld);
static UserTagPtr DefaultTag();
static bool TagTableIsFull(Thread* thread);
static UserTagPtr FindTagById(uword tag_id);
private:
static UserTagPtr FindTagInIsolate(Thread* thread, const String& label);
static void AddTagToIsolate(Thread* thread, const UserTag& tag);
void set_label(const String& tag_label) const {
untag()->set_label(tag_label.ptr());
}
FINAL_HEAP_OBJECT_IMPLEMENTATION(UserTag, Instance);
friend class Class;
};
// Represents abstract FutureOr class in dart:async.
class FutureOr : public Instance {
public:
static intptr_t InstanceSize() {
return RoundedAllocationSize(sizeof(UntaggedFutureOr));
}
virtual TypeArgumentsPtr GetTypeArguments() const {
return untag()->type_arguments();
}
static intptr_t type_arguments_offset() {
return OFFSET_OF(UntaggedFutureOr, type_arguments_);
}
private:
FINAL_HEAP_OBJECT_IMPLEMENTATION(FutureOr, Instance);
friend class Class;
};
// Breaking cycles and loops.
ClassPtr Object::clazz() const {
uword raw_value = static_cast<uword>(ptr_);
if ((raw_value & kSmiTagMask) == kSmiTag) {
return Smi::Class();
}
ASSERT(!IsolateGroup::Current()->compaction_in_progress());
return IsolateGroup::Current()->class_table()->At(ptr()->GetClassId());
}
DART_FORCE_INLINE
void Object::SetPtr(ObjectPtr value, intptr_t default_cid) {
ptr_ = value;
intptr_t cid = value->GetClassIdMayBeSmi();
// Free-list elements cannot be wrapped in a handle.
ASSERT(cid != kFreeListElement);
ASSERT(cid != kForwardingCorpse);
if (cid == kNullCid) {
cid = default_cid;
} else if (cid >= kNumPredefinedCids) {
cid = kInstanceCid;
}
set_vtable(builtin_vtables_[cid]);
#if defined(DEBUG)
if (FLAG_verify_handles && ptr_->IsHeapObject() && (ptr_ != Object::null())) {
Heap* isolate_heap = IsolateGroup::Current()->heap();
// TODO(rmacnak): Remove after rewriting StackFrame::VisitObjectPointers
// to not use handles.
if (!isolate_heap->new_space()->scavenging()) {
Heap* vm_isolate_heap = Dart::vm_isolate_group()->heap();
uword addr = UntaggedObject::ToAddr(ptr_);
if (!isolate_heap->Contains(addr) && !vm_isolate_heap->Contains(addr)) {
ASSERT(FLAG_write_protect_code);
addr = UntaggedObject::ToAddr(OldPage::ToWritable(ptr_));
ASSERT(isolate_heap->Contains(addr) || vm_isolate_heap->Contains(addr));
}
}
}
#endif
}
intptr_t Field::HostOffset() const {
ASSERT(is_instance()); // Valid only for dart instance fields.
return (Smi::Value(untag()->host_offset_or_field_id()) * kCompressedWordSize);
}
intptr_t Field::TargetOffset() const {
ASSERT(is_instance()); // Valid only for dart instance fields.
#if !defined(DART_PRECOMPILED_RUNTIME)
return (untag()->target_offset_ * compiler::target::kCompressedWordSize);
#else
return HostOffset();
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
inline intptr_t Field::TargetOffsetOf(const FieldPtr field) {
#if !defined(DART_PRECOMPILED_RUNTIME)
return field->untag()->target_offset_;
#else
return Smi::Value(field->untag()->host_offset_or_field_id());
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
void Field::SetOffset(intptr_t host_offset_in_bytes,
intptr_t target_offset_in_bytes) const {
ASSERT(is_instance()); // Valid only for dart instance fields.
ASSERT(kCompressedWordSize != 0);
untag()->set_host_offset_or_field_id(
Smi::New(host_offset_in_bytes / kCompressedWordSize));
#if !defined(DART_PRECOMPILED_RUNTIME)
ASSERT(compiler::target::kCompressedWordSize != 0);
StoreNonPointer(
&untag()->target_offset_,
target_offset_in_bytes / compiler::target::kCompressedWordSize);
#else
ASSERT(host_offset_in_bytes == target_offset_in_bytes);
#endif // !defined(DART_PRECOMPILED_RUNTIME)
}
ObjectPtr Field::StaticValue() const {
ASSERT(is_static()); // Valid only for static dart fields.
return Isolate::Current()->field_table()->At(field_id());
}
inline intptr_t Field::field_id() const {
return Smi::Value(untag()->host_offset_or_field_id());
}
void Field::set_field_id(intptr_t field_id) const {
DEBUG_ASSERT(
IsolateGroup::Current()->program_lock()->IsCurrentThreadWriter());
set_field_id_unsafe(field_id);
}
void Field::set_field_id_unsafe(intptr_t field_id) const {
ASSERT(is_static());
untag()->set_host_offset_or_field_id(Smi::New(field_id));
}
void Context::SetAt(intptr_t index, const Object& value) const {
untag()->set_element(index, value.ptr());
}
intptr_t Instance::GetNativeField(int index) const {
ASSERT(IsValidNativeIndex(index));
NoSafepointScope no_safepoint;
TypedDataPtr native_fields = static_cast<TypedDataPtr>(
NativeFieldsAddr()->Decompress(untag()->heap_base()));
if (native_fields == TypedData::null()) {
return 0;
}
return reinterpret_cast<intptr_t*>(native_fields->untag()->data())[index];
}
void Instance::GetNativeFields(uint16_t num_fields,
intptr_t* field_values) const {
NoSafepointScope no_safepoint;
ASSERT(num_fields == NumNativeFields());
ASSERT(field_values != NULL);
TypedDataPtr native_fields = static_cast<TypedDataPtr>(
NativeFieldsAddr()->Decompress(untag()->heap_base()));
if (native_fields == TypedData::null()) {
for (intptr_t i = 0; i < num_fields; i++) {
field_values[i] = 0;
}
}
intptr_t* fields =
reinterpret_cast<intptr_t*>(native_fields->untag()->data());
for (intptr_t i = 0; i < num_fields; i++) {
field_values[i] = fields[i];
}
}
bool String::Equals(const String& str) const {
if (ptr() == str.ptr()) {
return true; // Both handles point to the same raw instance.
}
if (str.IsNull()) {
return false;
}
if (IsCanonical() && str.IsCanonical()) {
return false; // Two symbols that aren't identical aren't equal.
}
if (HasHash() && str.HasHash() && (Hash() != str.Hash())) {
return false; // Both sides have hash codes and they do not match.
}
return Equals(str, 0, str.Length());
}
intptr_t Library::UrlHash() const {
intptr_t result = String::GetCachedHash(url());
ASSERT(result != 0);
return result;
}
void MegamorphicCache::SetEntry(const Array& array,
intptr_t index,
const Smi& class_id,
const Object& target) {
ASSERT(target.IsNull() || target.IsFunction() || target.IsSmi());
array.SetAt((index * kEntryLength) + kClassIdIndex, class_id);
array.SetAt((index * kEntryLength) + kTargetFunctionIndex, target);
}
ObjectPtr MegamorphicCache::GetClassId(const Array& array, intptr_t index) {
return array.At((index * kEntryLength) + kClassIdIndex);
}
ObjectPtr MegamorphicCache::GetTargetFunction(const Array& array,
intptr_t index) {
return array.At((index * kEntryLength) + kTargetFunctionIndex);
}
inline uword Type::Hash() const {
ASSERT(IsFinalized());
intptr_t result = Smi::Value(untag()->hash());
if (result != 0) {
return result;
}
return ComputeHash();
}
inline void Type::SetHash(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
untag()->set_hash(Smi::New(value));
}
inline uword FunctionType::Hash() const {
ASSERT(IsFinalized());
intptr_t result = Smi::Value(untag()->hash());
if (result != 0) {
return result;
}
return ComputeHash();
}
inline void FunctionType::SetHash(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
untag()->set_hash(Smi::New(value));
}
inline uword TypeParameter::Hash() const {
ASSERT(IsFinalized() || IsBeingFinalized()); // Bound may not be finalized.
intptr_t result = Smi::Value(untag()->hash());
if (result != 0) {
return result;
}
return ComputeHash();
}
inline void TypeParameter::SetHash(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
untag()->set_hash(Smi::New(value));
}
inline uword TypeArguments::Hash() const {
if (IsNull()) return kAllDynamicHash;
intptr_t result = Smi::Value(untag()->hash());
if (result != 0) {
return result;
}
return ComputeHash();
}
inline void TypeArguments::SetHash(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
untag()->set_hash(Smi::New(value));
}
inline uint16_t String::CharAt(StringPtr str, intptr_t index) {
switch (str->GetClassId()) {
case kOneByteStringCid:
return OneByteString::CharAt(static_cast<OneByteStringPtr>(str), index);
case kTwoByteStringCid:
return TwoByteString::CharAt(static_cast<TwoByteStringPtr>(str), index);
case kExternalOneByteStringCid:
return ExternalOneByteString::CharAt(
static_cast<ExternalOneByteStringPtr>(str), index);
case kExternalTwoByteStringCid:
return ExternalTwoByteString::CharAt(
static_cast<ExternalTwoByteStringPtr>(str), index);
}
UNREACHABLE();
return 0;
}
// A view on an [Array] as a list of tuples, optionally starting at an offset.
//
// Example: We store a list of (kind, function, code) tuples into the
// [Code::static_calls_target_table] array of type [Array].
//
// This helper class can then be used via
//
// using CallTableView = ArrayOfTuplesVied<
// Code::Kind, std::tuple<Smi, Function, Code>>;
//
// auto& array = Array::Handle(code.static_calls_targets_table());
// CallTableView static_calls(array);
//
// // Using convenient for loop.
// auto& function = Function::Handle();
// for (auto& call : static_calls) {
// function = call.Get<Code::kSCallTableFunctionTarget>();
// call.Set<Code::kSCallTableFunctionTarget>(function);
// }
//
// // Using manual loop.
// auto& function = Function::Handle();
// for (intptr_t i = 0; i < static_calls.Length(); ++i) {
// auto call = static_calls[i];
// function = call.Get<Code::kSCallTableFunctionTarget>();
// call.Set<Code::kSCallTableFunctionTarget>(function);
// }
//
//
// Template parameters:
//
// * [EnumType] must be a normal enum which enumerates the entries of the
// tuple
//
// * [kStartOffset] is the offset at which the first tuple in the array
// starts (can be 0).
//
// * [TupleT] must be a std::tuple<...> where "..." are the heap object handle
// classes (e.g. 'Code', 'Smi', 'Object')
template <typename EnumType, typename TupleT, int kStartOffset = 0>
class ArrayOfTuplesView {
public:
static constexpr intptr_t EntrySize = std::tuple_size<TupleT>::value;
class Iterator;
class TupleView {
public:
TupleView(const Array& array, intptr_t index)
: array_(array), index_(index) {}
template <EnumType kElement,
std::memory_order order = std::memory_order_relaxed>
typename std::tuple_element<kElement, TupleT>::type::ObjectPtrType Get()
const {
using object_type = typename std::tuple_element<kElement, TupleT>::type;
return object_type::RawCast(array_.At<order>(index_ + kElement));
}
template <EnumType kElement,
std::memory_order order = std::memory_order_relaxed>
void Set(const typename std::tuple_element<kElement, TupleT>::type& value)
const {
array_.SetAt<order>(index_ + kElement, value);
}
intptr_t index() const { return (index_ - kStartOffset) / EntrySize; }
private:
const Array& array_;
intptr_t index_;
friend class Iterator;
};
class Iterator {
public:
Iterator(const Array& array, intptr_t index) : entry_(array, index) {}
bool operator==(const Iterator& other) {
return entry_.index_ == other.entry_.index_;
}
bool operator!=(const Iterator& other) {
return entry_.index_ != other.entry_.index_;
}
const TupleView& operator*() const { return entry_; }
Iterator& operator++() {
entry_.index_ += EntrySize;
return *this;
}
private:
TupleView entry_;
};
explicit ArrayOfTuplesView(const Array& array) : array_(array), index_(-1) {
ASSERT(!array.IsNull());
ASSERT(array.Length() >= kStartOffset);
ASSERT((array.Length() - kStartOffset) % EntrySize == kStartOffset);
}
intptr_t Length() const {
return (array_.Length() - kStartOffset) / EntrySize;
}
TupleView At(intptr_t i) const {
return TupleView(array_, kStartOffset + i * EntrySize);
}
TupleView operator[](intptr_t i) const { return At(i); }
Iterator begin() const { return Iterator(array_, kStartOffset); }
Iterator end() const {
return Iterator(array_, kStartOffset + Length() * EntrySize);
}
private:
const Array& array_;
intptr_t index_;
};
using InvocationDispatcherTable =
ArrayOfTuplesView<Class::InvocationDispatcherEntry,
std::tuple<String, Array, Function>>;
using StaticCallsTable =
ArrayOfTuplesView<Code::SCallTableEntry, std::tuple<Smi, Object, Function>>;
using StaticCallsTableEntry = StaticCallsTable::TupleView;
using SubtypeTestCacheTable = ArrayOfTuplesView<SubtypeTestCache::Entries,
std::tuple<Object,
Object,
AbstractType,
TypeArguments,
TypeArguments,
TypeArguments,
TypeArguments,
TypeArguments>>;
using MegamorphicCacheEntries =
ArrayOfTuplesView<MegamorphicCache::EntryType, std::tuple<Smi, Object>>;
void DumpTypeTable(Isolate* isolate);
void DumpTypeParameterTable(Isolate* isolate);
void DumpTypeArgumentsTable(Isolate* isolate);
EntryPointPragma FindEntryPointPragma(IsolateGroup* isolate_group,
const Array& metadata,
Field* reusable_field_handle,
Object* reusable_object_handle);
DART_WARN_UNUSED_RESULT
ErrorPtr EntryPointFieldInvocationError(const String& getter_name);
DART_WARN_UNUSED_RESULT
ErrorPtr EntryPointMemberInvocationError(const Object& member);
#undef PRECOMPILER_WSR_FIELD_DECLARATION
} // namespace dart
#endif // RUNTIME_VM_OBJECT_H_
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