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dart / sdk.git / d20e6a536cf012b3a966293179154ef9e0e54934 / . / runtime / vm / object.cc
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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.
#include "vm/object.h"
#include "include/dart_api.h"
#include "platform/assert.h"
#include "vm/assembler.h"
#include "vm/cpu.h"
#include "vm/bigint_operations.h"
#include "vm/bootstrap.h"
#include "vm/class_finalizer.h"
#include "vm/code_generator.h"
#include "vm/code_observers.h"
#include "vm/code_patcher.h"
#include "vm/compiler.h"
#include "vm/compiler_stats.h"
#include "vm/dart.h"
#include "vm/dart_api_state.h"
#include "vm/dart_entry.h"
#include "vm/datastream.h"
#include "vm/debugger.h"
#include "vm/deopt_instructions.h"
#include "vm/double_conversion.h"
#include "vm/exceptions.h"
#include "vm/flow_graph_builder.h"
#include "vm/growable_array.h"
#include "vm/heap.h"
#include "vm/intermediate_language.h"
#include "vm/intrinsifier.h"
#include "vm/longjump.h"
#include "vm/object_store.h"
#include "vm/parser.h"
#include "vm/runtime_entry.h"
#include "vm/scopes.h"
#include "vm/stack_frame.h"
#include "vm/symbols.h"
#include "vm/timer.h"
#include "vm/unicode.h"
namespace dart {
DEFINE_FLAG(bool, show_internal_names, false,
"Show names of internal classes (e.g. \"OneByteString\") in error messages "
"instead of showing the corresponding interface names (e.g. \"String\")");
DEFINE_FLAG(bool, trace_disabling_optimized_code, false,
"Trace disabling optimized code.");
DEFINE_FLAG(int, huge_method_cutoff_in_tokens, 20000,
"Huge method cutoff in tokens: Disables optimizations for huge methods.");
DEFINE_FLAG(int, huge_method_cutoff_in_code_size, 200000,
"Huge method cutoff in unoptimized code size (in bytes).");
DEFINE_FLAG(bool, throw_on_javascript_int_overflow, false,
"Throw an exception when integer arithmetic exceeds 53 bits.");
DECLARE_FLAG(bool, trace_compiler);
DECLARE_FLAG(bool, eliminate_type_checks);
DECLARE_FLAG(bool, enable_type_checks);
static const char* kGetterPrefix = "get:";
static const intptr_t kGetterPrefixLength = strlen(kGetterPrefix);
static const char* kSetterPrefix = "set:";
static const intptr_t kSetterPrefixLength = strlen(kSetterPrefix);
cpp_vtable Object::handle_vtable_ = 0;
cpp_vtable Object::builtin_vtables_[kNumPredefinedCids] = { 0 };
cpp_vtable Smi::handle_vtable_ = 0;
// These are initialized to a value that will force a illegal memory access if
// they are being used.
#if defined(RAW_NULL)
#error RAW_NULL should not be defined.
#endif
#define RAW_NULL kHeapObjectTag
Object* Object::null_object_ = NULL;
Array* Object::null_array_ = NULL;
String* Object::null_string_ = NULL;
Instance* Object::null_instance_ = NULL;
AbstractTypeArguments* Object::null_abstract_type_arguments_ = NULL;
Array* Object::empty_array_ = NULL;
Instance* Object::sentinel_ = NULL;
Instance* Object::transition_sentinel_ = NULL;
Instance* Object::unknown_constant_ = NULL;
Instance* Object::non_constant_ = NULL;
Bool* Object::bool_true_ = NULL;
Bool* Object::bool_false_ = NULL;
Smi* Object::smi_illegal_cid_ = NULL;
LanguageError* Object::snapshot_writer_error_ = NULL;
RawObject* Object::null_ = reinterpret_cast<RawObject*>(RAW_NULL);
RawClass* Object::class_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::null_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::dynamic_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::void_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::unresolved_class_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::type_arguments_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::instantiated_type_arguments_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::patch_class_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::function_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::closure_data_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::redirection_data_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::field_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::literal_token_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::token_stream_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::script_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::library_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::library_prefix_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::namespace_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::code_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::instructions_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::pc_descriptors_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::stackmap_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::var_descriptors_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::exception_handlers_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::deopt_info_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::context_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::context_scope_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::icdata_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::megamorphic_cache_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::subtypetestcache_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::api_error_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::language_error_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::unhandled_exception_class_ =
reinterpret_cast<RawClass*>(RAW_NULL);
RawClass* Object::unwind_error_class_ = reinterpret_cast<RawClass*>(RAW_NULL);
#undef RAW_NULL
const double MegamorphicCache::kLoadFactor = 0.75;
// The following functions are marked as invisible, meaning they will be hidden
// in the stack trace.
// (Library, class name, method name)
#define INVISIBLE_LIST(V) \
V(CoreLibrary, Object, _noSuchMethod) \
V(CoreLibrary, Object, _as) \
V(CoreLibrary, Object, _instanceOf) \
V(CoreLibrary, _ObjectArray, _ObjectArray.) \
V(CoreLibrary, AssertionErrorImplementation, _throwNew) \
V(CoreLibrary, TypeErrorImplementation, _throwNew) \
V(CoreLibrary, FallThroughErrorImplementation, _throwNew) \
V(CoreLibrary, AbstractClassInstantiationErrorImplementation, _throwNew) \
V(CoreLibrary, NoSuchMethodError, _throwNew) \
V(CoreLibrary, int, _throwFormatException) \
V(CoreLibrary, int, _parse) \
V(CoreLibrary, StackTrace, _setupFullStackTrace) \
static void MarkFunctionAsInvisible(const Library& lib,
const char* class_name,
const char* function_name) {
ASSERT(!lib.IsNull());
const Class& cls = Class::Handle(
lib.LookupClassAllowPrivate(String::Handle(String::New(class_name))));
ASSERT(!cls.IsNull());
const Function& function =
Function::Handle(
cls.LookupFunctionAllowPrivate(
String::Handle(String::New(function_name))));
ASSERT(!function.IsNull());
function.set_is_visible(false);
}
static void MarkInvisibleFunctions() {
#define MARK_FUNCTION(lib, class_name, function_name) \
MarkFunctionAsInvisible(Library::Handle(Library::lib()), \
#class_name, #function_name); \
INVISIBLE_LIST(MARK_FUNCTION)
#undef MARK_FUNCTION
}
// Takes a vm internal name and makes it suitable for external user.
//
// Examples:
//
// Internal getter and setter prefixes are changed:
//
// get:foo -> foo
// set:foo -> foo=
//
// Private name mangling is removed, possibly twice:
//
// _ReceivePortImpl@6be832b -> _ReceivePortImpl
// _ReceivePortImpl@6be832b._internal@6be832b -> +ReceivePortImpl._internal
//
// The trailing . on the default constructor name is dropped:
//
// List. -> List
//
// And so forth:
//
// get:foo@6be832b -> foo
// _MyClass@6b3832b. -> _MyClass
// _MyClass@6b3832b.named -> _MyClass.named
//
static RawString* IdentifierPrettyName(const String& name) {
intptr_t len = name.Length();
intptr_t start = 0;
intptr_t at_pos = len; // Position of '@' in the name.
intptr_t dot_pos = len; // Position of '.' in the name.
bool is_setter = false;
if (name.Equals(Symbols::TopLevel())) {
// Name of invisible top-level class.
return Symbols::Empty().raw();
}
for (int i = start; i < name.Length(); i++) {
if (name.CharAt(i) == ':') {
ASSERT(start == 0);
if (name.CharAt(0) == 's') {
is_setter = true;
}
start = i + 1;
} else if (name.CharAt(i) == '@') {
ASSERT(at_pos == len);
at_pos = i;
} else if (name.CharAt(i) == '.') {
dot_pos = i;
break;
}
}
intptr_t limit = (at_pos < dot_pos ? at_pos : dot_pos);
if (start == 0 && limit == len) {
// This name is fine as it is.
return name.raw();
}
const String& result =
String::Handle(String::SubString(name, start, (limit - start)));
// Look for a second '@' now to correctly handle names like
// "_ReceivePortImpl@6be832b._internal@6be832b".
at_pos = len;
for (int i = dot_pos; i < name.Length(); i++) {
if (name.CharAt(i) == '@') {
ASSERT(at_pos == len);
at_pos = i;
}
}
intptr_t suffix_len = at_pos - dot_pos;
if (suffix_len > 1) {
// This is a named constructor. Add the name back to the string.
const String& suffix =
String::Handle(String::SubString(name, dot_pos, suffix_len));
return String::Concat(result, suffix);
}
if (is_setter) {
// Setters need to end with '='.
return String::Concat(result, Symbols::Equals());
}
return result.raw();
}
template<typename type>
static bool IsSpecialCharacter(type value) {
return ((value == '"') ||
(value == '\n') ||
(value == '\f') ||
(value == '\b') ||
(value == '\t') ||
(value == '\v') ||
(value == '\r') ||
(value == '\\') ||
(value == '$'));
}
template<typename type>
static type SpecialCharacter(type value) {
if (value == '"') {
return '"';
} else if (value == '\n') {
return 'n';
} else if (value == '\f') {
return 'f';
} else if (value == '\b') {
return 'b';
} else if (value == '\t') {
return 't';
} else if (value == '\v') {
return 'v';
} else if (value == '\r') {
return 'r';
} else if (value == '\\') {
return '\\';
} else if (value == '$') {
return '$';
}
UNREACHABLE();
return '\0';
}
static void DeleteWeakPersistentHandle(Dart_WeakPersistentHandle handle) {
ApiState* state = Isolate::Current()->api_state();
ASSERT(state != NULL);
FinalizablePersistentHandle* weak_ref =
reinterpret_cast<FinalizablePersistentHandle*>(handle);
ASSERT(state->IsValidWeakPersistentHandle(handle));
state->weak_persistent_handles().FreeHandle(weak_ref);
}
void Object::InitOnce() {
// TODO(iposva): NoGCScope needs to be added here.
ASSERT(class_class() == null_);
// Initialize the static vtable values.
{
Object fake_object;
Smi fake_smi;
Object::handle_vtable_ = fake_object.vtable();
Smi::handle_vtable_ = fake_smi.vtable();
}
Isolate* isolate = Isolate::Current();
Heap* heap = isolate->heap();
// Allocate the read only object handles here.
null_object_ = Object::ReadOnlyHandle();
null_array_ = Array::ReadOnlyHandle();
null_string_ = String::ReadOnlyHandle();
null_instance_ = Instance::ReadOnlyHandle();
null_abstract_type_arguments_ = AbstractTypeArguments::ReadOnlyHandle();
empty_array_ = Array::ReadOnlyHandle();
sentinel_ = Instance::ReadOnlyHandle();
transition_sentinel_ = Instance::ReadOnlyHandle();
unknown_constant_ = Instance::ReadOnlyHandle();
non_constant_ = Instance::ReadOnlyHandle();
bool_true_ = Bool::ReadOnlyHandle();
bool_false_ = Bool::ReadOnlyHandle();
smi_illegal_cid_ = Smi::ReadOnlyHandle();
snapshot_writer_error_ = LanguageError::ReadOnlyHandle();
// Allocate and initialize the null instance.
// 'null_' must be the first object allocated as it is used in allocation to
// clear the object.
{
uword address = heap->Allocate(Instance::InstanceSize(), Heap::kOld);
null_ = reinterpret_cast<RawInstance*>(address + kHeapObjectTag);
// The call below is using 'null_' to initialize itself.
InitializeObject(address, kNullCid, Instance::InstanceSize());
}
*null_object_ = Object::null();
*null_array_ = Array::null();
*null_string_ = String::null();
*null_instance_ = Instance::null();
*null_abstract_type_arguments_ = AbstractTypeArguments::null();
// Initialize the empty array handle to null_ in order to be able to check
// if the empty array was allocated (RAW_NULL is not available).
*empty_array_ = Array::null();
Class& cls = Class::Handle();
// Allocate and initialize the class class.
{
intptr_t size = Class::InstanceSize();
uword address = heap->Allocate(size, Heap::kOld);
class_class_ = reinterpret_cast<RawClass*>(address + kHeapObjectTag);
InitializeObject(address, Class::kClassId, size);
Class fake;
// Initialization from Class::New<Class>.
// Directly set raw_ to break a circular dependency: SetRaw will attempt
// to lookup class class in the class table where it is not registered yet.
cls.raw_ = class_class_;
cls.set_handle_vtable(fake.vtable());
cls.set_instance_size(Class::InstanceSize());
cls.set_next_field_offset(Class::InstanceSize());
cls.set_id(Class::kClassId);
cls.raw_ptr()->state_bits_ = 0;
cls.set_is_finalized();
cls.set_is_type_finalized();
cls.raw_ptr()->type_arguments_field_offset_in_words_ =
Class::kNoTypeArguments;
cls.raw_ptr()->num_native_fields_ = 0;
cls.InitEmptyFields();
isolate->RegisterClass(cls);
}
// Allocate and initialize the null class.
cls = Class::New<Instance>(kNullCid);
cls.set_is_finalized();
cls.set_is_type_finalized();
null_class_ = cls.raw();
// Allocate and initialize the free list element class.
cls = Class::New<FreeListElement::FakeInstance>(kFreeListElement);
cls.set_is_finalized();
cls.set_is_type_finalized();
// Allocate and initialize the sentinel values of Null class.
{
*sentinel_ ^=
Object::Allocate(kNullCid, Instance::InstanceSize(), Heap::kOld);
*transition_sentinel_ ^=
Object::Allocate(kNullCid, Instance::InstanceSize(), Heap::kOld);
}
// Allocate and initialize optimizing compiler constants.
{
*unknown_constant_ ^=
Object::Allocate(kNullCid, Instance::InstanceSize(), Heap::kOld);
*non_constant_ ^=
Object::Allocate(kNullCid, Instance::InstanceSize(), Heap::kOld);
}
cls = Class::New<Instance>(kDynamicCid);
cls.set_is_finalized();
cls.set_is_type_finalized();
cls.set_is_abstract();
dynamic_class_ = cls.raw();
// Allocate the remaining VM internal classes.
cls = Class::New<UnresolvedClass>();
unresolved_class_class_ = cls.raw();
cls = Class::New<Instance>(kVoidCid);
cls.set_is_finalized();
cls.set_is_type_finalized();
void_class_ = cls.raw();
cls = Class::New<TypeArguments>();
type_arguments_class_ = cls.raw();
cls = Class::New<InstantiatedTypeArguments>();
instantiated_type_arguments_class_ = cls.raw();
cls = Class::New<PatchClass>();
patch_class_class_ = cls.raw();
cls = Class::New<Function>();
function_class_ = cls.raw();
cls = Class::New<ClosureData>();
closure_data_class_ = cls.raw();
cls = Class::New<RedirectionData>();
redirection_data_class_ = cls.raw();
cls = Class::New<Field>();
field_class_ = cls.raw();
cls = Class::New<LiteralToken>();
literal_token_class_ = cls.raw();
cls = Class::New<TokenStream>();
token_stream_class_ = cls.raw();
cls = Class::New<Script>();
script_class_ = cls.raw();
cls = Class::New<Library>();
library_class_ = cls.raw();
cls = Class::New<LibraryPrefix>();
library_prefix_class_ = cls.raw();
cls = Class::New<Namespace>();
namespace_class_ = cls.raw();
cls = Class::New<Code>();
code_class_ = cls.raw();
cls = Class::New<Instructions>();
instructions_class_ = cls.raw();
cls = Class::New<PcDescriptors>();
pc_descriptors_class_ = cls.raw();
cls = Class::New<Stackmap>();
stackmap_class_ = cls.raw();
cls = Class::New<LocalVarDescriptors>();
var_descriptors_class_ = cls.raw();
cls = Class::New<ExceptionHandlers>();
exception_handlers_class_ = cls.raw();
cls = Class::New<DeoptInfo>();
deopt_info_class_ = cls.raw();
cls = Class::New<Context>();
context_class_ = cls.raw();
cls = Class::New<ContextScope>();
context_scope_class_ = cls.raw();
cls = Class::New<ICData>();
icdata_class_ = cls.raw();
cls = Class::New<MegamorphicCache>();
megamorphic_cache_class_ = cls.raw();
cls = Class::New<SubtypeTestCache>();
subtypetestcache_class_ = cls.raw();
cls = Class::New<ApiError>();
api_error_class_ = cls.raw();
cls = Class::New<LanguageError>();
language_error_class_ = cls.raw();
cls = Class::New<UnhandledException>();
unhandled_exception_class_ = cls.raw();
cls = Class::New<UnwindError>();
unwind_error_class_ = cls.raw();
ASSERT(class_class() != null_);
// Pre-allocate classes in the vm isolate so that we can for example create a
// symbol table and populate it with some frequently used strings as symbols.
cls = Class::New<Array>();
isolate->object_store()->set_array_class(cls);
cls.set_type_arguments_field_offset(Array::type_arguments_offset());
cls = Class::New<Array>(kImmutableArrayCid);
isolate->object_store()->set_immutable_array_class(cls);
cls.set_type_arguments_field_offset(Array::type_arguments_offset());
cls = Class::NewStringClass(kOneByteStringCid);
isolate->object_store()->set_one_byte_string_class(cls);
cls = Class::NewStringClass(kTwoByteStringCid);
isolate->object_store()->set_two_byte_string_class(cls);
// Allocate and initialize the empty_array instance.
{
uword address = heap->Allocate(Array::InstanceSize(0), Heap::kOld);
InitializeObject(address, kArrayCid, Array::InstanceSize(0));
Array::initializeHandle(
empty_array_,
reinterpret_cast<RawArray*>(address + kHeapObjectTag));
empty_array_->raw()->ptr()->length_ = Smi::New(0);
}
// Allocate and initialize singleton true and false boolean objects.
cls = Class::New<Bool>();
isolate->object_store()->set_bool_class(cls);
*bool_true_ = Bool::New(true);
*bool_false_ = Bool::New(false);
*smi_illegal_cid_ = Smi::New(kIllegalCid);
*snapshot_writer_error_ =
LanguageError::New(String::Handle(String::New("SnapshotWriter Error")));
ASSERT(!null_object_->IsSmi());
ASSERT(!null_array_->IsSmi());
ASSERT(null_array_->IsArray());
ASSERT(!null_string_->IsSmi());
ASSERT(null_string_->IsString());
ASSERT(!null_instance_->IsSmi());
ASSERT(null_instance_->IsInstance());
ASSERT(!null_abstract_type_arguments_->IsSmi());
ASSERT(null_abstract_type_arguments_->IsAbstractTypeArguments());
ASSERT(!empty_array_->IsSmi());
ASSERT(empty_array_->IsArray());
ASSERT(!sentinel_->IsSmi());
ASSERT(sentinel_->IsInstance());
ASSERT(!transition_sentinel_->IsSmi());
ASSERT(transition_sentinel_->IsInstance());
ASSERT(!unknown_constant_->IsSmi());
ASSERT(unknown_constant_->IsInstance());
ASSERT(!non_constant_->IsSmi());
ASSERT(non_constant_->IsInstance());
ASSERT(!bool_true_->IsSmi());
ASSERT(bool_true_->IsBool());
ASSERT(!bool_false_->IsSmi());
ASSERT(bool_false_->IsBool());
ASSERT(smi_illegal_cid_->IsSmi());
ASSERT(!snapshot_writer_error_->IsSmi());
ASSERT(snapshot_writer_error_->IsLanguageError());
}
#define SET_CLASS_NAME(class_name, name) \
cls = class_name##_class(); \
cls.set_name(Symbols::name()); \
void Object::RegisterSingletonClassNames() {
Class& cls = Class::Handle();
// Set up names for all VM singleton classes.
SET_CLASS_NAME(class, Class);
SET_CLASS_NAME(null, Null);
SET_CLASS_NAME(dynamic, Dynamic);
SET_CLASS_NAME(void, Void);
SET_CLASS_NAME(unresolved_class, UnresolvedClass);
SET_CLASS_NAME(type_arguments, TypeArguments);
SET_CLASS_NAME(instantiated_type_arguments, InstantiatedTypeArguments);
SET_CLASS_NAME(patch_class, PatchClass);
SET_CLASS_NAME(function, Function);
SET_CLASS_NAME(closure_data, ClosureData);
SET_CLASS_NAME(redirection_data, RedirectionData);
SET_CLASS_NAME(field, Field);
SET_CLASS_NAME(literal_token, LiteralToken);
SET_CLASS_NAME(token_stream, TokenStream);
SET_CLASS_NAME(script, Script);
SET_CLASS_NAME(library, LibraryClass);
SET_CLASS_NAME(library_prefix, LibraryPrefix);
SET_CLASS_NAME(namespace, Namespace);
SET_CLASS_NAME(code, Code);
SET_CLASS_NAME(instructions, Instructions);
SET_CLASS_NAME(pc_descriptors, PcDescriptors);
SET_CLASS_NAME(stackmap, Stackmap);
SET_CLASS_NAME(var_descriptors, LocalVarDescriptors);
SET_CLASS_NAME(exception_handlers, ExceptionHandlers);
SET_CLASS_NAME(deopt_info, DeoptInfo);
SET_CLASS_NAME(context, Context);
SET_CLASS_NAME(context_scope, ContextScope);
SET_CLASS_NAME(icdata, ICData);
SET_CLASS_NAME(megamorphic_cache, MegamorphicCache);
SET_CLASS_NAME(subtypetestcache, SubtypeTestCache);
SET_CLASS_NAME(api_error, ApiError);
SET_CLASS_NAME(language_error, LanguageError);
SET_CLASS_NAME(unhandled_exception, UnhandledException);
SET_CLASS_NAME(unwind_error, UnwindError);
// Set up names for object array and one byte string class which are
// pre-allocated in the vm isolate also.
cls = Dart::vm_isolate()->object_store()->array_class();
cls.set_name(Symbols::ObjectArray());
cls = Dart::vm_isolate()->object_store()->one_byte_string_class();
cls.set_name(Symbols::OneByteString());
}
void Object::CreateInternalMetaData() {
// Initialize meta data for VM internal classes.
Class& cls = Class::Handle();
Array& fields = Array::Handle();
Field& fld = Field::Handle();
String& name = String::Handle();
// TODO(iposva): Add more of the VM classes here.
cls = context_class_;
fields = Array::New(1);
name = Symbols::New("@parent_");
fld = Field::New(name, false, false, false, cls, 0);
fields.SetAt(0, fld);
cls.SetFields(fields);
}
// Make unused space in an object whose type has been transformed safe
// for traversing during GC.
// The unused part of the transformed object is marked as an TypedDataInt8Array
// object.
void Object::MakeUnusedSpaceTraversable(const Object& obj,
intptr_t original_size,
intptr_t used_size) {
ASSERT(Isolate::Current()->no_gc_scope_depth() > 0);
ASSERT(!obj.IsNull());
ASSERT(original_size >= used_size);
if (original_size > used_size) {
intptr_t leftover_size = original_size - used_size;
uword addr = RawObject::ToAddr(obj.raw()) + used_size;
if (leftover_size >= TypedData::InstanceSize(0)) {
// Update the leftover space as an TypedDataInt8Array object.
RawTypedData* raw =
reinterpret_cast<RawTypedData*>(RawObject::FromAddr(addr));
uword tags = 0;
tags = RawObject::SizeTag::update(leftover_size, tags);
tags = RawObject::ClassIdTag::update(kTypedDataInt8ArrayCid, tags);
raw->ptr()->tags_ = tags;
intptr_t leftover_len = (leftover_size - TypedData::InstanceSize(0));
ASSERT(TypedData::InstanceSize(leftover_len) == leftover_size);
raw->ptr()->length_ = Smi::New(leftover_len);
} else {
// Update the leftover space as a basic object.
ASSERT(leftover_size == Object::InstanceSize());
RawObject* raw = reinterpret_cast<RawObject*>(RawObject::FromAddr(addr));
uword tags = 0;
tags = RawObject::SizeTag::update(leftover_size, tags);
tags = RawObject::ClassIdTag::update(kInstanceCid, tags);
raw->ptr()->tags_ = tags;
}
}
}
void Object::VerifyBuiltinVtables() {
#if defined(DEBUG)
Isolate* isolate = Isolate::Current();
ASSERT(isolate != NULL);
Class& cls = Class::Handle(isolate, Class::null());
for (intptr_t cid = (kIllegalCid + 1); cid < kNumPredefinedCids; cid++) {
if (isolate->class_table()->HasValidClassAt(cid)) {
cls ^= isolate->class_table()->At(cid);
ASSERT(builtin_vtables_[cid] == cls.raw_ptr()->handle_vtable_);
}
}
#endif
}
void Object::RegisterClass(const Class& cls,
const String& name,
const Library& lib) {
ASSERT(name.Length() > 0);
ASSERT(name.CharAt(0) != '_');
cls.set_name(name);
lib.AddClass(cls);
}
void Object::RegisterPrivateClass(const Class& cls,
const String& public_class_name,
const Library& lib) {
ASSERT(public_class_name.Length() > 0);
ASSERT(public_class_name.CharAt(0) == '_');
String& str = String::Handle();
str = lib.PrivateName(public_class_name);
cls.set_name(str);
lib.AddClass(cls);
}
RawError* Object::Init(Isolate* isolate) {
TIMERSCOPE(time_bootstrap);
ObjectStore* object_store = isolate->object_store();
Class& cls = Class::Handle();
Type& type = Type::Handle();
Array& array = Array::Handle();
Library& lib = Library::Handle();
// All RawArray fields will be initialized to an empty array, therefore
// initialize array class first.
cls = Class::New<Array>();
object_store->set_array_class(cls);
// Array and ImmutableArray are the only VM classes that are parameterized.
// Since they are pre-finalized, CalculateFieldOffsets() is not called, so we
// need to set the offset of their type_arguments_ field, which is explicitly
// declared in RawArray.
cls.set_type_arguments_field_offset(Array::type_arguments_offset());
// Set up the growable object array class (Has to be done after the array
// class is setup as one of its field is an array object).
cls = Class::New<GrowableObjectArray>();
object_store->set_growable_object_array_class(cls);
cls.set_type_arguments_field_offset(
GrowableObjectArray::type_arguments_offset());
// canonical_type_arguments_ are Smi terminated.
// Last element contains the count of used slots.
const intptr_t kInitialCanonicalTypeArgumentsSize = 4;
array = Array::New(kInitialCanonicalTypeArgumentsSize + 1);
array.SetAt(kInitialCanonicalTypeArgumentsSize, Smi::Handle(Smi::New(0)));
object_store->set_canonical_type_arguments(array);
// Setup type class early in the process.
cls = Class::New<Type>();
object_store->set_type_class(cls);
cls = Class::New<TypeParameter>();
object_store->set_type_parameter_class(cls);
cls = Class::New<BoundedType>();
object_store->set_bounded_type_class(cls);
cls = Class::New<MixinAppType>();
object_store->set_mixin_app_type_class(cls);
// Pre-allocate the OneByteString class needed by the symbol table.
cls = Class::NewStringClass(kOneByteStringCid);
object_store->set_one_byte_string_class(cls);
// Pre-allocate the TwoByteString class needed by the symbol table.
cls = Class::NewStringClass(kTwoByteStringCid);
object_store->set_two_byte_string_class(cls);
// Setup the symbol table for the symbols created in the isolate.
Symbols::SetupSymbolTable(isolate);
// Set up the libraries array before initializing the core library.
const GrowableObjectArray& libraries =
GrowableObjectArray::Handle(GrowableObjectArray::New(Heap::kOld));
object_store->set_libraries(libraries);
// Pre-register the core library.
Library::InitCoreLibrary(isolate);
// Basic infrastructure has been setup, initialize the class dictionary.
Library& core_lib = Library::Handle(Library::CoreLibrary());
ASSERT(!core_lib.IsNull());
const GrowableObjectArray& pending_classes =
GrowableObjectArray::Handle(GrowableObjectArray::New(Heap::kOld));
object_store->set_pending_classes(pending_classes);
Context& context = Context::Handle(Context::New(0, Heap::kOld));
object_store->set_empty_context(context);
// Now that the symbol table is initialized and that the core dictionary as
// well as the core implementation dictionary have been setup, preallocate
// remaining classes and register them by name in the dictionaries.
String& name = String::Handle();
cls = Class::New<Bool>();
object_store->set_bool_class(cls);
RegisterClass(cls, Symbols::Bool(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = object_store->array_class(); // Was allocated above.
RegisterPrivateClass(cls, Symbols::ObjectArray(), core_lib);
pending_classes.Add(cls, Heap::kOld);
// We cannot use NewNonParameterizedType(cls), because Array is parameterized.
type ^= Type::New(Object::Handle(cls.raw()),
TypeArguments::Handle(),
Scanner::kDummyTokenIndex);
type.SetIsFinalized();
type ^= type.Canonicalize();
object_store->set_array_type(type);
cls = object_store->growable_object_array_class(); // Was allocated above.
RegisterPrivateClass(cls, Symbols::GrowableObjectArray(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Array>(kImmutableArrayCid);
object_store->set_immutable_array_class(cls);
cls.set_type_arguments_field_offset(Array::type_arguments_offset());
ASSERT(object_store->immutable_array_class() != object_store->array_class());
cls.set_is_prefinalized();
RegisterPrivateClass(cls, Symbols::ImmutableArray(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = object_store->one_byte_string_class(); // Was allocated above.
RegisterPrivateClass(cls, Symbols::OneByteString(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = object_store->two_byte_string_class(); // Was allocated above.
RegisterPrivateClass(cls, Symbols::TwoByteString(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::NewStringClass(kExternalOneByteStringCid);
object_store->set_external_one_byte_string_class(cls);
RegisterPrivateClass(cls, Symbols::ExternalOneByteString(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::NewStringClass(kExternalTwoByteStringCid);
object_store->set_external_two_byte_string_class(cls);
RegisterPrivateClass(cls, Symbols::ExternalTwoByteString(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Stacktrace>();
object_store->set_stacktrace_class(cls);
RegisterClass(cls, Symbols::StackTrace(), core_lib);
pending_classes.Add(cls, Heap::kOld);
// Super type set below, after Object is allocated.
cls = Class::New<JSRegExp>();
object_store->set_jsregexp_class(cls);
RegisterPrivateClass(cls, Symbols::JSSyntaxRegExp(), core_lib);
pending_classes.Add(cls, Heap::kOld);
// Initialize the base interfaces used by the core VM classes.
// Allocate and initialize the pre-allocated classes in the core library.
// The script and token index of these pre-allocated classes is set up in
// the parser when the corelib script is compiled (see
// Parser::ParseClassDefinition).
cls = Class::New<Instance>(kInstanceCid);
object_store->set_object_class(cls);
cls.set_name(Symbols::Object());
cls.set_is_prefinalized();
core_lib.AddClass(cls);
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_object_type(type);
cls = object_store->type_class();
RegisterPrivateClass(cls, Symbols::Type(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = object_store->type_parameter_class();
RegisterPrivateClass(cls, Symbols::TypeParameter(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = object_store->bounded_type_class();
RegisterPrivateClass(cls, Symbols::BoundedType(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = object_store->mixin_app_type_class();
RegisterPrivateClass(cls, Symbols::MixinAppType(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Integer>();
object_store->set_integer_implementation_class(cls);
RegisterPrivateClass(cls, Symbols::IntegerImplementation(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Smi>();
object_store->set_smi_class(cls);
RegisterPrivateClass(cls, Symbols::_Smi(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Mint>();
object_store->set_mint_class(cls);
RegisterPrivateClass(cls, Symbols::_Mint(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Bigint>();
object_store->set_bigint_class(cls);
RegisterPrivateClass(cls, Symbols::_Bigint(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<Double>();
object_store->set_double_class(cls);
RegisterPrivateClass(cls, Symbols::_Double(), core_lib);
pending_classes.Add(cls, Heap::kOld);
cls = Class::New<WeakProperty>();
object_store->set_weak_property_class(cls);
RegisterPrivateClass(cls, Symbols::_WeakProperty(), core_lib);
// Setup some default native field classes which can be extended for
// specifying native fields in dart classes.
Library::InitNativeWrappersLibrary(isolate);
ASSERT(isolate->object_store()->native_wrappers_library() != Library::null());
// Pre-register the typed_data library so the native class implementations
// can be hooked up before compiling it.
lib = Library::LookupLibrary(Symbols::DartTypedData());
if (lib.IsNull()) {
lib = Library::NewLibraryHelper(Symbols::DartTypedData(), true);
lib.Register();
isolate->object_store()->set_bootstrap_library(ObjectStore::kTypedData,
lib);
}
ASSERT(!lib.IsNull());
ASSERT(lib.raw() == Library::TypedDataLibrary());
const intptr_t typed_data_class_array_length =
RawObject::NumberOfTypedDataClasses();
Array& typed_data_classes =
Array::Handle(Array::New(typed_data_class_array_length));
int index = 0;
#define REGISTER_TYPED_DATA_CLASS(clazz) \
cls = Class::NewTypedDataClass(kTypedData##clazz##Cid); \
index = kTypedData##clazz##Cid - kTypedDataInt8ArrayCid; \
typed_data_classes.SetAt(index, cls); \
RegisterPrivateClass(cls, Symbols::_##clazz(), lib); \
CLASS_LIST_TYPED_DATA(REGISTER_TYPED_DATA_CLASS);
#undef REGISTER_TYPED_DATA_CLASS
#define REGISTER_TYPED_DATA_VIEW_CLASS(clazz) \
cls = Class::NewTypedDataViewClass(kTypedData##clazz##ViewCid); \
index = kTypedData##clazz##ViewCid - kTypedDataInt8ArrayCid; \
typed_data_classes.SetAt(index, cls); \
RegisterPrivateClass(cls, Symbols::_##clazz##View(), lib); \
pending_classes.Add(cls, Heap::kOld); \
CLASS_LIST_TYPED_DATA(REGISTER_TYPED_DATA_VIEW_CLASS);
cls = Class::NewTypedDataViewClass(kByteDataViewCid);
index = kByteDataViewCid - kTypedDataInt8ArrayCid;
typed_data_classes.SetAt(index, cls);
RegisterPrivateClass(cls, Symbols::_ByteDataView(), lib);
pending_classes.Add(cls, Heap::kOld);
#undef REGISTER_TYPED_DATA_VIEW_CLASS
#define REGISTER_EXT_TYPED_DATA_CLASS(clazz) \
cls = Class::NewExternalTypedDataClass(kExternalTypedData##clazz##Cid); \
index = kExternalTypedData##clazz##Cid - kTypedDataInt8ArrayCid; \
typed_data_classes.SetAt(index, cls); \
RegisterPrivateClass(cls, Symbols::_External##clazz(), lib); \
CLASS_LIST_TYPED_DATA(REGISTER_EXT_TYPED_DATA_CLASS);
#undef REGISTER_EXT_TYPED_DATA_CLASS
// Register Float32x4 and Uint32x4 in the object store.
cls = Class::New<Float32x4>();
object_store->set_float32x4_class(cls);
RegisterPrivateClass(cls, Symbols::_Float32x4(), lib);
cls = Class::New<Uint32x4>();
object_store->set_uint32x4_class(cls);
RegisterPrivateClass(cls, Symbols::_Uint32x4(), lib);
cls = Class::New<Instance>(kIllegalCid);
RegisterClass(cls, Symbols::Float32x4(), lib);
cls.set_is_prefinalized();
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_float32x4_type(type);
cls = Class::New<Instance>(kIllegalCid);
RegisterClass(cls, Symbols::Uint32x4(), lib);
cls.set_is_prefinalized();
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_uint32x4_type(type);
object_store->set_typed_data_classes(typed_data_classes);
// Set the super type of class Stacktrace to Object type so that the
// 'toString' method is implemented.
cls = object_store->stacktrace_class();
type = object_store->object_type();
cls.set_super_type(type);
// Note: The abstract class Function is represented by VM class
// DartFunction, not VM class Function.
cls = Class::New<DartFunction>();
RegisterClass(cls, Symbols::Function(), core_lib);
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_function_type(type);
cls = Class::New<Number>();
RegisterClass(cls, Symbols::Number(), core_lib);
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_number_type(type);
cls = Class::New<Instance>(kIllegalCid);
RegisterClass(cls, Symbols::Int(), core_lib);
cls.set_is_prefinalized();
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_int_type(type);
cls = Class::New<Instance>(kIllegalCid);
RegisterClass(cls, Symbols::Double(), core_lib);
cls.set_is_prefinalized();
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_double_type(type);
name = Symbols::New("String");
cls = Class::New<Instance>(kIllegalCid);
cls.set_is_prefinalized();
RegisterClass(cls, name, core_lib);
cls.set_is_prefinalized();
pending_classes.Add(cls, Heap::kOld);
type = Type::NewNonParameterizedType(cls);
object_store->set_string_type(type);
cls = Class::New<Instance>(kIllegalCid);
RegisterClass(cls, Symbols::List(), core_lib);
cls.set_is_prefinalized();
pending_classes.Add(cls, Heap::kOld);
object_store->set_list_class(cls);
cls = object_store->bool_class();
type = Type::NewNonParameterizedType(cls);
object_store->set_bool_type(type);
cls = object_store->smi_class();
type = Type::NewNonParameterizedType(cls);
object_store->set_smi_type(type);
cls = object_store->mint_class();
type = Type::NewNonParameterizedType(cls);
object_store->set_mint_type(type);
// The classes 'Null' and 'void' are not registered in the class dictionary,
// because their names are reserved keywords. Their names are not heap
// allocated, because the classes reside in the VM isolate.
// The corresponding types are stored in the object store.
cls = null_class();
type = Type::NewNonParameterizedType(cls);
object_store->set_null_type(type);
cls = void_class();
type = Type::NewNonParameterizedType(cls);
object_store->set_void_type(type);
// The class 'dynamic' is registered in the class dictionary because its name
// is a built-in identifier, rather than a reserved keyword. Its name is not
// heap allocated, because the class resides in the VM isolate.
// The corresponding type, the "unknown type", is stored in the object store.
cls = dynamic_class();
type = Type::NewNonParameterizedType(cls);
object_store->set_dynamic_type(type);
// Finish the initialization by compiling the bootstrap scripts containing the
// base interfaces and the implementation of the internal classes.
const Error& error = Error::Handle(Bootstrap::LoadandCompileScripts());
if (!error.IsNull()) {
return error.raw();
}
ClassFinalizer::VerifyBootstrapClasses();
MarkInvisibleFunctions();
// Set up the intrinsic state of all functions (core, math and scalar list).
Intrinsifier::InitializeState();
return Error::null();
}
void Object::InitFromSnapshot(Isolate* isolate) {
TIMERSCOPE(time_bootstrap);
ObjectStore* object_store = isolate->object_store();
Class& cls = Class::Handle();
// Set up empty classes in the object store, these will get
// initialized correctly when we read from the snapshot.
// This is done to allow bootstrapping of reading classes from the snapshot.
cls = Class::New<Instance>(kInstanceCid);
object_store->set_object_class(cls);
cls = Class::New<Type>();
object_store->set_type_class(cls);
cls = Class::New<TypeParameter>();
object_store->set_type_parameter_class(cls);
cls = Class::New<BoundedType>();
object_store->set_bounded_type_class(cls);
cls = Class::New<MixinAppType>();
object_store->set_mixin_app_type_class(cls);
cls = Class::New<Array>();
object_store->set_array_class(cls);
cls = Class::New<Array>(kImmutableArrayCid);
object_store->set_immutable_array_class(cls);
cls = Class::New<GrowableObjectArray>();
object_store->set_growable_object_array_class(cls);
cls = Class::New<Float32x4>();
object_store->set_float32x4_class(cls);
cls = Class::New<Uint32x4>();
object_store->set_uint32x4_class(cls);
#define REGISTER_TYPED_DATA_CLASS(clazz) \
cls = Class::NewTypedDataClass(kTypedData##clazz##Cid);
CLASS_LIST_TYPED_DATA(REGISTER_TYPED_DATA_CLASS);
#undef REGISTER_TYPED_DATA_CLASS
#define REGISTER_TYPED_DATA_VIEW_CLASS(clazz) \
cls = Class::NewTypedDataViewClass(kTypedData##clazz##ViewCid);
CLASS_LIST_TYPED_DATA(REGISTER_TYPED_DATA_VIEW_CLASS);
cls = Class::NewTypedDataViewClass(kByteDataViewCid);
#undef REGISTER_TYPED_DATA_VIEW_CLASS
#define REGISTER_EXT_TYPED_DATA_CLASS(clazz) \
cls = Class::NewExternalTypedDataClass(kExternalTypedData##clazz##Cid);
CLASS_LIST_TYPED_DATA(REGISTER_EXT_TYPED_DATA_CLASS);
#undef REGISTER_EXT_TYPED_DATA_CLASS
cls = Class::New<Integer>();
object_store->set_integer_implementation_class(cls);
cls = Class::New<Smi>();
object_store->set_smi_class(cls);
cls = Class::New<Mint>();
object_store->set_mint_class(cls);
cls = Class::New<Double>();
object_store->set_double_class(cls);
cls = Class::New<Bigint>();
object_store->set_bigint_class(cls);
cls = Class::NewStringClass(kOneByteStringCid);
object_store->set_one_byte_string_class(cls);
cls = Class::NewStringClass(kTwoByteStringCid);
object_store->set_two_byte_string_class(cls);
cls = Class::NewStringClass(kExternalOneByteStringCid);
object_store->set_external_one_byte_string_class(cls);
cls = Class::NewStringClass(kExternalTwoByteStringCid);
object_store->set_external_two_byte_string_class(cls);
cls = Class::New<Bool>();
object_store->set_bool_class(cls);
cls = Class::New<Stacktrace>();
object_store->set_stacktrace_class(cls);
cls = Class::New<JSRegExp>();
object_store->set_jsregexp_class(cls);
// Some classes are not stored in the object store. Yet we still need to
// create their Class object so that they get put into the class_table
// (as a side effect of Class::New()).
cls = Class::New<DartFunction>();
cls = Class::New<Number>();
cls = Class::New<WeakProperty>();
object_store->set_weak_property_class(cls);
}
void Object::Print() const {
OS::Print("%s\n", ToCString());
}
RawString* Object::DictionaryName() const {
return String::null();
}
void Object::InitializeObject(uword address, intptr_t class_id, intptr_t size) {
// TODO(iposva): Get a proper halt instruction from the assembler which
// would be needed here for code objects.
uword initial_value = reinterpret_cast<uword>(null_);
uword cur = address;
uword end = address + size;
while (cur < end) {
*reinterpret_cast<uword*>(cur) = initial_value;
cur += kWordSize;
}
uword tags = 0;
ASSERT(class_id != kIllegalCid);
tags = RawObject::ClassIdTag::update(class_id, tags);
tags = RawObject::SizeTag::update(size, tags);
reinterpret_cast<RawObject*>(address)->tags_ = tags;
}
void Object::CheckHandle() const {
#if defined(DEBUG)
if (raw_ != Object::null()) {
if ((reinterpret_cast<uword>(raw_) & kSmiTagMask) == kSmiTag) {
ASSERT(vtable() == Smi::handle_vtable_);
return;
}
intptr_t cid = raw_->GetClassId();
if (cid >= kNumPredefinedCids) {
cid = kInstanceCid;
}
ASSERT(vtable() == builtin_vtables_[cid]);
if (FLAG_verify_handles) {
Isolate* isolate = Isolate::Current();
Heap* isolate_heap = isolate->heap();
Heap* vm_isolate_heap = Dart::vm_isolate()->heap();
ASSERT(isolate_heap->Contains(RawObject::ToAddr(raw_)) ||
vm_isolate_heap->Contains(RawObject::ToAddr(raw_)));
}
}
#endif
}
RawObject* Object::Allocate(intptr_t cls_id,
intptr_t size,
Heap::Space space) {
ASSERT(Utils::IsAligned(size, kObjectAlignment));
Isolate* isolate = Isolate::Current();
ASSERT(isolate->no_callback_scope_depth() == 0);
Heap* heap = isolate->heap();
uword address = heap->Allocate(size, space);
if (address == 0) {
// Use the preallocated out of memory exception to avoid calling
// into dart code or allocating any code.
const Instance& exception =
Instance::Handle(isolate->object_store()->out_of_memory());
Exceptions::Throw(exception);
UNREACHABLE();
}
NoGCScope no_gc;
InitializeObject(address, cls_id, size);
RawObject* raw_obj = reinterpret_cast<RawObject*>(address + kHeapObjectTag);
ASSERT(cls_id == RawObject::ClassIdTag::decode(raw_obj->ptr()->tags_));
return raw_obj;
}
class StoreBufferUpdateVisitor : public ObjectPointerVisitor {
public:
explicit StoreBufferUpdateVisitor(Isolate* isolate, RawObject* obj) :
ObjectPointerVisitor(isolate), old_obj_(obj) {
ASSERT(old_obj_->IsOldObject());
}
void VisitPointers(RawObject** first, RawObject** last) {
for (RawObject** curr = first; curr <= last; ++curr) {
RawObject* raw_obj = *curr;
if (raw_obj->IsHeapObject() && raw_obj->IsNewObject()) {
old_obj_->SetRememberedBit();
isolate()->store_buffer()->AddObject(old_obj_);
// Remembered this object. There is no need to continue searching.
return;
}
}
}
private:
RawObject* old_obj_;
DISALLOW_COPY_AND_ASSIGN(StoreBufferUpdateVisitor);
};
bool Object::IsReadOnlyHandle() const {
return Dart::IsReadOnlyHandle(reinterpret_cast<uword>(this));
}
bool Object::IsNotTemporaryScopedHandle() const {
return (IsZoneHandle() || IsReadOnlyHandle());
}
RawObject* Object::Clone(const Object& src, Heap::Space space) {
const Class& cls = Class::Handle(src.clazz());
intptr_t size = src.raw()->Size();
RawObject* raw_obj = Object::Allocate(cls.id(), size, space);
NoGCScope no_gc;
memmove(raw_obj->ptr(), src.raw()->ptr(), size);
if ((space == Heap::kOld) && !raw_obj->IsRemembered()) {
StoreBufferUpdateVisitor visitor(Isolate::Current(), raw_obj);
raw_obj->VisitPointers(&visitor);
}
return raw_obj;
}
RawString* Class::Name() const {
ASSERT(raw_ptr()->name_ != String::null());
return raw_ptr()->name_;
}
RawString* Class::UserVisibleName() const {
if (FLAG_show_internal_names) {
return Name();
}
switch (id()) {
case kIntegerCid:
case kSmiCid:
case kMintCid:
case kBigintCid:
return Symbols::Int().raw();
case kDoubleCid:
return Symbols::Double().raw();
case kOneByteStringCid:
case kTwoByteStringCid:
case kExternalOneByteStringCid:
case kExternalTwoByteStringCid:
return Symbols::New("String");
case kArrayCid:
case kImmutableArrayCid:
case kGrowableObjectArrayCid:
return Symbols::List().raw();
case kFloat32x4Cid:
return Symbols::Float32x4().raw();
case kUint32x4Cid:
return Symbols::Uint32x4().raw();
case kTypedDataInt8ArrayCid:
case kExternalTypedDataInt8ArrayCid:
return Symbols::Int8List().raw();
case kTypedDataUint8ArrayCid:
case kExternalTypedDataUint8ArrayCid:
return Symbols::Uint8List().raw();
case kTypedDataUint8ClampedArrayCid:
case kExternalTypedDataUint8ClampedArrayCid:
return Symbols::Uint8ClampedList().raw();
case kTypedDataInt16ArrayCid:
case kExternalTypedDataInt16ArrayCid:
return Symbols::Int16List().raw();
case kTypedDataUint16ArrayCid:
case kExternalTypedDataUint16ArrayCid:
return Symbols::Uint16List().raw();
case kTypedDataInt32ArrayCid:
case kExternalTypedDataInt32ArrayCid:
return Symbols::Int32List().raw();
case kTypedDataUint32ArrayCid:
case kExternalTypedDataUint32ArrayCid:
return Symbols::Uint32List().raw();
case kTypedDataInt64ArrayCid:
case kExternalTypedDataInt64ArrayCid:
return Symbols::Int64List().raw();
case kTypedDataUint64ArrayCid:
case kExternalTypedDataUint64ArrayCid:
return Symbols::Uint64List().raw();
case kTypedDataFloat32x4ArrayCid:
case kExternalTypedDataFloat32x4ArrayCid:
return Symbols::Float32x4List().raw();
case kTypedDataFloat32ArrayCid:
case kExternalTypedDataFloat32ArrayCid:
return Symbols::Float32List().raw();
case kTypedDataFloat64ArrayCid:
case kExternalTypedDataFloat64ArrayCid:
return Symbols::Float64List().raw();
default:
if (!IsSignatureClass()) {
const String& name = String::Handle(Name());
return IdentifierPrettyName(name);
} else {
return Name();
}
}
UNREACHABLE();
}
RawType* Class::SignatureType() const {
ASSERT(IsSignatureClass());
const Function& function = Function::Handle(signature_function());
ASSERT(!function.IsNull());
if (function.signature_class() != raw()) {
// This class is a function type alias. Return the canonical signature type.
const Class& canonical_class = Class::Handle(function.signature_class());
return canonical_class.SignatureType();
}
// Return the first canonical signature type if already computed.
const Array& signature_types = Array::Handle(canonical_types());
// The canonical_types array is initialized to the empty array.
ASSERT(!signature_types.IsNull());
if (signature_types.Length() > 0) {
// At most one signature type per signature class.
ASSERT((signature_types.Length() == 1) ||
((signature_types.Length() == 2) &&
(signature_types.At(1) == Type::null())));
Type& signature_type = Type::Handle();
signature_type ^= signature_types.At(0);
ASSERT(!signature_type.IsNull());
return signature_type.raw();
}
// A signature class extends class Instance and is parameterized in the same
// way as the owner class of its non-static signature function.
// It is not type parameterized if its signature function is static.
// See Class::NewSignatureClass() for the setup of its type parameters.
// During type finalization, the type arguments of the super class of the
// owner class of its signature function will be prepended to the type
// argument vector. Therefore, we only need to set the type arguments
// matching the type parameters here.
const TypeArguments& signature_type_arguments =
TypeArguments::Handle(type_parameters());
const Type& signature_type = Type::Handle(
Type::New(*this, signature_type_arguments, token_pos()));
// Return the still unfinalized signature type.
ASSERT(!signature_type.IsFinalized());
return signature_type.raw();
}
template <class FakeObject>
RawClass* Class::New() {
ASSERT(Object::class_class() != Class::null());
Class& result = Class::Handle();
{
RawObject* raw = Object::Allocate(Class::kClassId,
Class::InstanceSize(),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
}
FakeObject fake;
result.set_handle_vtable(fake.vtable());
result.set_instance_size(FakeObject::InstanceSize());
result.set_next_field_offset(FakeObject::InstanceSize());
ASSERT((FakeObject::kClassId != kInstanceCid));
result.set_id(FakeObject::kClassId);
result.raw_ptr()->state_bits_ = 0;
// VM backed classes are almost ready: run checks and resolve class
// references, but do not recompute size.
result.set_is_prefinalized();
result.raw_ptr()->type_arguments_field_offset_in_words_ = kNoTypeArguments;
result.raw_ptr()->num_native_fields_ = 0;
result.raw_ptr()->token_pos_ = Scanner::kDummyTokenIndex;
result.InitEmptyFields();
Isolate::Current()->RegisterClass(result);
return result.raw();
}
// Initialize class fields of type Array with empty array.
void Class::InitEmptyFields() {
if (Object::empty_array().raw() == Array::null()) {
// The empty array has not been initialized yet.
return;
}
StorePointer(&raw_ptr()->interfaces_, Object::empty_array().raw());
StorePointer(&raw_ptr()->constants_, Object::empty_array().raw());
StorePointer(&raw_ptr()->canonical_types_, Object::empty_array().raw());
StorePointer(&raw_ptr()->functions_, Object::empty_array().raw());
StorePointer(&raw_ptr()->fields_, Object::empty_array().raw());
}
bool Class::HasInstanceFields() const {
const Array& field_array = Array::Handle(fields());
Field& field = Field::Handle();
for (intptr_t i = 0; i < field_array.Length(); ++i) {
field ^= field_array.At(i);
if (!field.is_static()) {
return true;
}
}
return false;
}
void Class::SetFunctions(const Array& value) const {
ASSERT(!value.IsNull());
#if defined(DEBUG)
// Verify that all the functions in the array have this class as owner.
Function& func = Function::Handle();
intptr_t len = value.Length();
for (intptr_t i = 0; i < len; i++) {
func ^= value.At(i);
ASSERT(func.Owner() == raw());
}
#endif
StorePointer(&raw_ptr()->functions_, value.raw());
}
void Class::AddFunction(const Function& function) const {
const Array& arr = Array::Handle(functions());
const Array& new_arr = Array::Handle(Array::Grow(arr, arr.Length() + 1));
new_arr.SetAt(arr.Length(), function);
SetFunctions(new_arr);
}
void Class::AddClosureFunction(const Function& function) const {
GrowableObjectArray& closures =
GrowableObjectArray::Handle(raw_ptr()->closure_functions_);
if (closures.IsNull()) {
closures = GrowableObjectArray::New(4);
StorePointer(&raw_ptr()->closure_functions_, closures.raw());
}
ASSERT(function.IsNonImplicitClosureFunction());
closures.Add(function);
}
// Lookup the innermost closure function that contains token at token_pos.
RawFunction* Class::LookupClosureFunction(intptr_t token_pos) const {
if (raw_ptr()->closure_functions_ == GrowableObjectArray::null()) {
return Function::null();
}
const GrowableObjectArray& closures =
GrowableObjectArray::Handle(raw_ptr()->closure_functions_);
Function& closure = Function::Handle();
intptr_t num_closures = closures.Length();
intptr_t best_fit_token_pos = -1;
intptr_t best_fit_index = -1;
for (intptr_t i = 0; i < num_closures; i++) {
closure ^= closures.At(i);
ASSERT(!closure.IsNull());
if ((closure.token_pos() <= token_pos) &&
(token_pos < closure.end_token_pos()) &&
(best_fit_token_pos < closure.token_pos())) {
best_fit_index = i;
best_fit_token_pos = closure.token_pos();
}
}
closure = Function::null();
if (best_fit_index >= 0) {
closure ^= closures.At(best_fit_index);
}
return closure.raw();
}
void Class::set_signature_function(const Function& value) const {
ASSERT(value.IsClosureFunction() || value.IsSignatureFunction());
StorePointer(&raw_ptr()->signature_function_, value.raw());
}
void Class::set_class_state(RawClass::ClassState state) const {
ASSERT((state == RawClass::kAllocated) ||
(state == RawClass::kPreFinalized) ||
(state == RawClass::kFinalized));
set_state_bits(StateBits::update(state, raw_ptr()->state_bits_));
}
void Class::set_state_bits(intptr_t bits) const {
raw_ptr()->state_bits_ = static_cast<uint16_t>(bits);
}
void Class::set_library(const Library& value) const {
StorePointer(&raw_ptr()->library_, value.raw());
}
void Class::set_type_parameters(const TypeArguments& value) const {
StorePointer(&raw_ptr()->type_parameters_, value.raw());
}
intptr_t Class::NumTypeParameters() const {
if (type_parameters() == TypeArguments::null()) {
return 0;
}
const TypeArguments& type_params = TypeArguments::Handle(type_parameters());
return type_params.Length();
}
intptr_t Class::NumTypeArguments() const {
// To work properly, this call requires the super class of this class to be
// resolved, which is checked by the SuperClass() call.
Isolate* isolate = Isolate::Current();
Class& cls = Class::Handle(isolate, raw());
intptr_t num_type_args = 0;
do {
if (cls.IsSignatureClass()) {
const Function& signature_fun =
Function::Handle(isolate, cls.signature_function());
if (!signature_fun.is_static() &&
!signature_fun.HasInstantiatedSignature()) {
cls = signature_fun.Owner();
}
}
num_type_args += cls.NumTypeParameters();
// Super type of Object class is null.
if (cls.super_type() == AbstractType::null() ||
cls.super_type() == isolate->object_store()->object_type()) {
break;
}
cls = cls.SuperClass();
} while (true);
return num_type_args;
}
bool Class::HasTypeArguments() const {
if (!IsSignatureClass() && (is_type_finalized() || is_prefinalized())) {
// More efficient than calling NumTypeArguments().
return type_arguments_field_offset() != kNoTypeArguments;
} else {
// No need to check NumTypeArguments() if class has type parameters.
return (NumTypeParameters() > 0) || (NumTypeArguments() > 0);
}
}
RawClass* Class::SuperClass() const {
if (super_type() == AbstractType::null()) {
return Class::null();
}
const AbstractType& sup_type = AbstractType::Handle(super_type());
return sup_type.type_class();
}
void Class::set_super_type(const AbstractType& value) const {
ASSERT(value.IsNull() ||
value.IsType() ||
value.IsBoundedType() ||
value.IsMixinAppType());
StorePointer(&raw_ptr()->super_type_, value.raw());
}
// Return a TypeParameter if the type_name is a type parameter of this class.
// Return null otherwise.
RawTypeParameter* Class::LookupTypeParameter(const String& type_name,
intptr_t token_pos) const {
ASSERT(!type_name.IsNull());
const TypeArguments& type_params = TypeArguments::Handle(type_parameters());
if (!type_params.IsNull()) {
intptr_t num_type_params = type_params.Length();
TypeParameter& type_param = TypeParameter::Handle();
String& type_param_name = String::Handle();
for (intptr_t i = 0; i < num_type_params; i++) {
type_param ^= type_params.TypeAt(i);
type_param_name = type_param.name();
if (type_param_name.Equals(type_name)) {
return type_param.raw();
}
}
}
return TypeParameter::null();
}
void Class::CalculateFieldOffsets() const {
Array& flds = Array::Handle(fields());
const Class& super = Class::Handle(SuperClass());
intptr_t offset = 0;
intptr_t type_args_field_offset = kNoTypeArguments;
if (super.IsNull()) {
offset = sizeof(RawObject);
} else {
type_args_field_offset = super.type_arguments_field_offset();
offset = super.next_field_offset();
ASSERT(offset > 0);
// We should never call CalculateFieldOffsets for native wrapper
// classes, assert this.
ASSERT(num_native_fields() == 0);
set_num_native_fields(super.num_native_fields());
}
// If the super class is parameterized, use the same type_arguments field.
if (type_args_field_offset == kNoTypeArguments) {
const TypeArguments& type_params = TypeArguments::Handle(type_parameters());
if (!type_params.IsNull()) {
ASSERT(type_params.Length() > 0);
// The instance needs a type_arguments field.
type_args_field_offset = offset;
offset += kWordSize;
}
}
set_type_arguments_field_offset(type_args_field_offset);
ASSERT(offset != 0);
Field& field = Field::Handle();
intptr_t len = flds.Length();
for (intptr_t i = 0; i < len; i++) {
field ^= flds.At(i);
// Offset is computed only for instance fields.
if (!field.is_static()) {
ASSERT(field.Offset() == 0);
field.SetOffset(offset);
offset += kWordSize;
}
}
set_instance_size(RoundedAllocationSize(offset));
set_next_field_offset(offset);
}
void Class::Finalize() const {
ASSERT(!is_finalized());
// Prefinalized classes have a VM internal representation and no Dart fields.
// Their instance size is precomputed and field offsets are known.
if (!is_prefinalized()) {
// Compute offsets of instance fields and instance size.
CalculateFieldOffsets();
}
set_is_finalized();
}
static const char* FormatPatchError(const char* format, const Object& obj) {
const char* msg = obj.ToCString();
intptr_t len = OS::SNPrint(NULL, 0, format, msg) + 1;
char* result = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(result, len, format, msg);
return result;
}
// Apply the members from the patch class to the original class.
const char* Class::ApplyPatch(const Class& patch) const {
ASSERT(!is_finalized());
// Shared handles used during the iteration.
String& member_name = String::Handle();
const PatchClass& patch_class =
PatchClass::Handle(PatchClass::New(*this, patch));
Array& orig_list = Array::Handle(functions());
intptr_t orig_len = orig_list.Length();
Array& patch_list = Array::Handle(patch.functions());
intptr_t patch_len = patch_list.Length();
// TODO(iposva): Verify that only patching existing methods and adding only
// new private methods.
Function& func = Function::Handle();
Function& orig_func = Function::Handle();
const GrowableObjectArray& new_functions = GrowableObjectArray::Handle(
GrowableObjectArray::New(orig_len));
for (intptr_t i = 0; i < orig_len; i++) {
orig_func ^= orig_list.At(i);
member_name ^= orig_func.name();
func = patch.LookupFunction(member_name);
if (func.IsNull()) {
// Non-patched function is preserved, all patched functions are added in
// the loop below.
new_functions.Add(orig_func);
} else if (!func.HasCompatibleParametersWith(orig_func) &&
!(func.IsFactory() && orig_func.IsConstructor() &&
(func.num_fixed_parameters() + 1 ==
orig_func.num_fixed_parameters()))) {
return FormatPatchError("mismatched parameters: %s", member_name);
}
}
for (intptr_t i = 0; i < patch_len; i++) {
func ^= patch_list.At(i);
func.set_owner(patch_class);
new_functions.Add(func);
}
Array& new_list = Array::Handle(Array::MakeArray(new_functions));
SetFunctions(new_list);
// Merge the two list of fields. Raise an error when duplicates are found or
// when a public field is being added.
orig_list = fields();
orig_len = orig_list.Length();
patch_list = patch.fields();
patch_len = patch_list.Length();
Field& field = Field::Handle();
Field& orig_field = Field::Handle();
new_list = Array::New(patch_len + orig_len);
for (intptr_t i = 0; i < patch_len; i++) {
field ^= patch_list.At(i);
field.set_owner(*this);
member_name = field.name();
// TODO(iposva): Verify non-public fields only.
// Verify no duplicate additions.
orig_field ^= LookupField(member_name);
if (!orig_field.IsNull()) {
return FormatPatchError("duplicate field: %s", member_name);
}
new_list.SetAt(i, field);
}
for (intptr_t i = 0; i < orig_len; i++) {
field ^= orig_list.At(i);
new_list.SetAt(patch_len + i, field);
}
SetFields(new_list);
// The functions and fields in the patch class are no longer needed.
patch.SetFunctions(Object::empty_array());
patch.SetFields(Object::empty_array());
return NULL;
}
// Ensure that top level parsing of the class has been done.
RawError* Class::EnsureIsFinalized(Isolate* isolate) const {
// Finalized classes have already been parsed.
if (is_finalized()) {
return Error::null();
}
ASSERT(isolate != NULL);
const Error& error = Error::Handle(isolate, Compiler::CompileClass(*this));
if (!error.IsNull() && (isolate->long_jump_base() != NULL)) {
isolate->long_jump_base()->Jump(1, error);
UNREACHABLE();
}
return error.raw();
}
void Class::SetFields(const Array& value) const {
ASSERT(!value.IsNull());
#if defined(DEBUG)
// Verify that all the fields in the array have this class as owner.
Field& field = Field::Handle();
intptr_t len = value.Length();
for (intptr_t i = 0; i < len; i++) {
field ^= value.At(i);
ASSERT(field.owner() == raw());
}
#endif
// The value of static fields is already initialized to null.
StorePointer(&raw_ptr()->fields_, value.raw());
}
template <class FakeInstance>
RawClass* Class::New(intptr_t index) {
ASSERT(Object::class_class() != Class::null());
Class& result = Class::Handle();
{
RawObject* raw = Object::Allocate(Class::kClassId,
Class::InstanceSize(),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
}
FakeInstance fake;
ASSERT(fake.IsInstance());
result.set_handle_vtable(fake.vtable());
result.set_instance_size(FakeInstance::InstanceSize());
result.set_next_field_offset(FakeInstance::InstanceSize());
result.set_id(index);
result.raw_ptr()->state_bits_ = 0;
result.raw_ptr()->type_arguments_field_offset_in_words_ = kNoTypeArguments;
result.raw_ptr()->num_native_fields_ = 0;
result.raw_ptr()->token_pos_ = Scanner::kDummyTokenIndex;
result.InitEmptyFields();
Isolate::Current()->RegisterClass(result);
return result.raw();
}
RawClass* Class::New(const String& name,
const Script& script,
intptr_t token_pos) {
Class& result = Class::Handle(New<Instance>(kIllegalCid));
result.set_name(name);
result.set_script(script);
result.set_token_pos(token_pos);
return result.raw();
}
RawClass* Class::NewSignatureClass(const String& name,
const Function& signature_function,
const Script& script,
intptr_t token_pos) {
const Class& result = Class::Handle(New(name, script, token_pos));
const Type& super_type = Type::Handle(Type::ObjectType());
ASSERT(!super_type.IsNull());
// Instances of a signature class can only be closures.
result.set_instance_size(Closure::InstanceSize());
result.set_next_field_offset(Closure::InstanceSize());
result.set_super_type(super_type);
result.set_is_synthesized_class();
result.set_type_arguments_field_offset(Closure::type_arguments_offset());
// Implements interface "Function".
const Type& function_type = Type::Handle(Type::Function());
const Array& interfaces = Array::Handle(Array::New(1, Heap::kOld));
interfaces.SetAt(0, function_type);
result.set_interfaces(interfaces);
if (!signature_function.IsNull()) {
result.PatchSignatureFunction(signature_function);
}
return result.raw();
}
void Class::PatchSignatureFunction(const Function& signature_function) const {
ASSERT(!signature_function.IsNull());
const Class& owner_class = Class::Handle(signature_function.Owner());
ASSERT(!owner_class.IsNull());
TypeArguments& type_parameters = TypeArguments::Handle();
// A signature class extends class Instance and is parameterized in the same
// way as the owner class of its non-static signature function.
// It is not type parameterized if its signature function is static.
// In case of a function type alias, the function owner is the alias class
// instead of the enclosing class.
if (!signature_function.is_static() &&
(owner_class.NumTypeParameters() > 0) &&
!signature_function.HasInstantiatedSignature()) {
type_parameters = owner_class.type_parameters();
}
set_signature_function(signature_function);
set_type_parameters(type_parameters);
if (owner_class.raw() == raw()) {
// This signature class is an alias, which cannot be the canonical
// signature class for this signature function.
ASSERT(!IsCanonicalSignatureClass());
} else if (signature_function.signature_class() == Object::null()) {
// Make this signature class the canonical signature class.
signature_function.set_signature_class(*this);
ASSERT(IsCanonicalSignatureClass());
}
set_is_prefinalized();
}
RawClass* Class::NewNativeWrapper(const Library& library,
const String& name,
int field_count) {
Class& cls = Class::Handle(library.LookupClass(name));
if (cls.IsNull()) {
cls = New(name, Script::Handle(), Scanner::kDummyTokenIndex);
cls.SetFields(Object::empty_array());
cls.SetFunctions(Object::empty_array());
// Set super class to Object.
cls.set_super_type(Type::Handle(Type::ObjectType()));
// Compute instance size. First word contains a pointer to a properly
// sized typed array once the first native field has been set.
intptr_t instance_size = sizeof(RawObject) + kWordSize;
cls.set_instance_size(RoundedAllocationSize(instance_size));
cls.set_next_field_offset(instance_size);
cls.set_num_native_fields(field_count);
cls.set_is_finalized();
cls.set_is_type_finalized();
library.AddClass(cls);
return cls.raw();
} else {
return Class::null();
}
}
RawClass* Class::NewStringClass(intptr_t class_id) {
intptr_t instance_size;
if (class_id == kOneByteStringCid) {
instance_size = OneByteString::InstanceSize();
} else if (class_id == kTwoByteStringCid) {
instance_size = TwoByteString::InstanceSize();
} else if (class_id == kExternalOneByteStringCid) {
instance_size = ExternalOneByteString::InstanceSize();
} else {
ASSERT(class_id == kExternalTwoByteStringCid);
instance_size = ExternalTwoByteString::InstanceSize();
}
Class& result = Class::Handle(New<String>(class_id));
result.set_instance_size(instance_size);
result.set_next_field_offset(instance_size);
result.set_is_prefinalized();
return result.raw();
}
RawClass* Class::NewTypedDataClass(intptr_t class_id) {
ASSERT(RawObject::IsTypedDataClassId(class_id));
intptr_t instance_size = TypedData::InstanceSize();
Class& result = Class::Handle(New<TypedData>(class_id));
result.set_instance_size(instance_size);
result.set_next_field_offset(instance_size);
result.set_is_prefinalized();
return result.raw();
}
RawClass* Class::NewTypedDataViewClass(intptr_t class_id) {
ASSERT(RawObject::IsTypedDataViewClassId(class_id));
Class& result = Class::Handle(New<Instance>(class_id));
result.set_instance_size(0);
result.set_next_field_offset(0);
return result.raw();
}
RawClass* Class::NewExternalTypedDataClass(intptr_t class_id) {
ASSERT(RawObject::IsExternalTypedDataClassId(class_id));
intptr_t instance_size = ExternalTypedData::InstanceSize();
Class& result = Class::Handle(New<ExternalTypedData>(class_id));
result.set_instance_size(instance_size);
result.set_next_field_offset(instance_size);
result.set_is_prefinalized();
return result.raw();
}
void Class::set_name(const String& value) const {
ASSERT(value.IsSymbol());
StorePointer(&raw_ptr()->name_, value.raw());
}
void Class::set_script(const Script& value) const {
StorePointer(&raw_ptr()->script_, value.raw());
}
void Class::set_token_pos(intptr_t token_pos) const {
ASSERT(token_pos >= 0);
raw_ptr()->token_pos_ = token_pos;
}
void Class::set_is_implemented() const {
set_state_bits(ImplementedBit::update(true, raw_ptr()->state_bits_));
}
void Class::set_is_abstract() const {
set_state_bits(AbstractBit::update(true, raw_ptr()->state_bits_));
}
void Class::set_is_type_finalized() const {
set_state_bits(TypeFinalizedBit::update(true, raw_ptr()->state_bits_));
}
void Class::set_is_patch() const {
set_state_bits(PatchBit::update(true, raw_ptr()->state_bits_));
}
void Class::set_is_synthesized_class() const {
set_state_bits(SynthesizedClassBit::update(true, raw_ptr()->state_bits_));
}
void Class::set_is_const() const {
set_state_bits(ConstBit::update(true, raw_ptr()->state_bits_));
}
void Class::set_is_finalized() const {
ASSERT(!is_finalized());
set_state_bits(StateBits::update(RawClass::kFinalized,
raw_ptr()->state_bits_));
}
void Class::set_is_prefinalized() const {
ASSERT(!is_finalized());
set_state_bits(StateBits::update(RawClass::kPreFinalized,
raw_ptr()->state_bits_));
}
void Class::set_is_marked_for_parsing() const {
set_state_bits(MarkedForParsingBit::update(true, raw_ptr()->state_bits_));
}
void Class::reset_is_marked_for_parsing() const {
set_state_bits(MarkedForParsingBit::update(false, raw_ptr()->state_bits_));
}
void Class::set_interfaces(const Array& value) const {
// Verification and resolving of interfaces occurs in finalizer.
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->interfaces_, value.raw());
}
void Class::set_mixin(const Type& value) const {
// Resolution and application of mixin type occurs in finalizer.
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->mixin_, value.raw());
}
void Class::set_patch_class(const Class& cls) const {
ASSERT(patch_class() == Class::null());
StorePointer(&raw_ptr()->patch_class_, cls.raw());
}
void Class::AddDirectSubclass(const Class& subclass) const {
ASSERT(!subclass.IsNull());
ASSERT(subclass.SuperClass() == raw());
// Do not keep track of the direct subclasses of class Object.
ASSERT(!IsObjectClass());
GrowableObjectArray& direct_subclasses =
GrowableObjectArray::Handle(raw_ptr()->direct_subclasses_);
if (direct_subclasses.IsNull()) {
direct_subclasses = GrowableObjectArray::New(4, Heap::kOld);
StorePointer(&raw_ptr()->direct_subclasses_, direct_subclasses.raw());
}
#if defined(DEBUG)
// Verify that the same class is not added twice.
for (intptr_t i = 0; i < direct_subclasses.Length(); i++) {
ASSERT(direct_subclasses.At(i) != subclass.raw());
}
#endif
direct_subclasses.Add(subclass);
}
RawArray* Class::constants() const {
return raw_ptr()->constants_;
}
void Class::set_constants(const Array& value) const {
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->constants_, value.raw());
}
RawArray* Class::canonical_types() const {
return raw_ptr()->canonical_types_;
}
void Class::set_canonical_types(const Array& value) const {
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->canonical_types_, value.raw());
}
void Class::set_allocation_stub(const Code& value) const {
ASSERT(!value.IsNull());
ASSERT(raw_ptr()->allocation_stub_ == Code::null());
StorePointer(&raw_ptr()->allocation_stub_, value.raw());
}
bool Class::IsFunctionClass() const {
return raw() == Type::Handle(Type::Function()).type_class();
}
bool Class::IsListClass() const {
return raw() == Isolate::Current()->object_store()->list_class();
}
bool Class::IsCanonicalSignatureClass() const {
const Function& function = Function::Handle(signature_function());
return (!function.IsNull() && (function.signature_class() == raw()));
}
// If test_kind == kIsSubtypeOf, checks if type S is a subtype of type T.
// If test_kind == kIsMoreSpecificThan, checks if S is more specific than T.
// Type S is specified by this class parameterized with 'type_arguments', and
// type T by class 'other' parameterized with 'other_type_arguments'.
// This class and class 'other' do not need to be finalized, however, they must
// be resolved as well as their interfaces.
bool Class::TypeTest(
TypeTestKind test_kind,
const AbstractTypeArguments& type_arguments,
const Class& other,
const AbstractTypeArguments& other_type_arguments,
Error* malformed_error) const {
ASSERT(!IsVoidClass());
// Check for DynamicType.
// Each occurrence of DynamicType in type T is interpreted as the dynamic
// type, a supertype of all types.
if (other.IsDynamicClass()) {
return true;
}
// In the case of a subtype test, each occurrence of DynamicType in type S is
// interpreted as the bottom type, a subtype of all types.
// However, DynamicType is not more specific than any type.
if (IsDynamicClass()) {
return test_kind == kIsSubtypeOf;
}
// Check for NullType, which is only a subtype of ObjectType, of DynamicType,
// or of itself, and which is more specific than any type.
if (IsNullClass()) {
// We already checked for other.IsDynamicClass() above.
return (test_kind == kIsMoreSpecificThan) ||
other.IsObjectClass() || other.IsNullClass();
}
// Check for ObjectType. Any type that is not NullType or DynamicType (already
// checked above), is more specific than ObjectType.
if (other.IsObjectClass()) {
return true;
}
// Check for reflexivity.
if (raw() == other.raw()) {
const intptr_t len = NumTypeArguments();
if (len == 0) {
return true;
}
// Since we do not truncate the type argument vector of a subclass (see
// below), we only check a prefix of the proper length.
// Check for covariance.
if (other_type_arguments.IsNull() || other_type_arguments.IsRaw(len)) {
return true;
}
if (type_arguments.IsNull() || type_arguments.IsRaw(len)) {
// Other type can't be more specific than this one because for that
// it would have to have all dynamic type arguments which is checked
// above.
return test_kind == kIsSubtypeOf;
}
return type_arguments.TypeTest(test_kind,
other_type_arguments,
len,
malformed_error);
}
const bool other_is_function_class = other.IsFunctionClass();
if (other.IsSignatureClass() || other_is_function_class) {
const Function& other_fun = Function::Handle(other.signature_function());
if (IsSignatureClass()) {
if (other_is_function_class) {
return true;
}
// Check for two function types.
const Function& fun = Function::Handle(signature_function());
return fun.TypeTest(test_kind,
type_arguments,
other_fun,
other_type_arguments,
malformed_error);
}
// Check if type S has a call() method of function type T.
Function& function =
Function::Handle(LookupDynamicFunction(Symbols::Call()));
if (function.IsNull()) {
// Walk up the super_class chain.
Class& cls = Class::Handle(SuperClass());
while (!cls.IsNull() && function.IsNull()) {
function = cls.LookupDynamicFunction(Symbols::Call());
cls = cls.SuperClass();
}
}
if (!function.IsNull()) {
if (other_is_function_class ||
function.TypeTest(test_kind,
type_arguments,
other_fun,
other_type_arguments,
malformed_error)) {
return true;
}
}
}
// Check for 'direct super type' specified in the implements clause
// and check for transitivity at the same time.
Array& interfaces = Array::Handle(this->interfaces());
AbstractType& interface = AbstractType::Handle();
Class& interface_class = Class::Handle();
AbstractTypeArguments& interface_args = AbstractTypeArguments::Handle();
Error& args_malformed_error = Error::Handle();
for (intptr_t i = 0; i < interfaces.Length(); i++) {
interface ^= interfaces.At(i);
interface_class = interface.type_class();
interface_args = interface.arguments();
if (!interface_args.IsNull() && !interface_args.IsInstantiated()) {
// This type class implements an interface that is parameterized with
// generic type(s), e.g. it implements List<T>.
// The uninstantiated type T must be instantiated using the type
// parameters of this type before performing the type test.
// The type arguments of this type that are referred to by the type
// parameters of the interface are at the end of the type vector,
// after the type arguments of the super type of this type.
// The index of the type parameters is adjusted upon finalization.
ASSERT(interface.IsFinalized());
args_malformed_error = Error::null();
interface_args = interface_args.InstantiateFrom(type_arguments,
&args_malformed_error);
if (!args_malformed_error.IsNull()) {
// Return the first malformed error to the caller if it requests it.
if ((malformed_error != NULL) && malformed_error->IsNull()) {
*malformed_error = args_malformed_error.raw();
}
continue; // Another interface may work better.
}
}
if (interface_class.TypeTest(test_kind,
interface_args,
other,
other_type_arguments,
malformed_error)) {
return true;
}
}
const Class& super_class = Class::Handle(SuperClass());
if (super_class.IsNull()) {
return false;
}
// Instead of truncating the type argument vector to the length of the super
// type argument vector, we make sure that the code works with a vector that
// is longer than necessary.
return super_class.TypeTest(test_kind,
type_arguments,
other,
other_type_arguments,
malformed_error);
}
bool Class::IsTopLevel() const {
return Name() == Symbols::TopLevel().raw();
}
RawFunction* Class::LookupDynamicFunction(const String& name) const {
return LookupFunction(name, kInstance);
}
RawFunction* Class::LookupDynamicFunctionAllowPrivate(
const String& name) const {
return LookupFunctionAllowPrivate(name, kInstance);
}
RawFunction* Class::LookupStaticFunction(const String& name) const {
return LookupFunction(name, kStatic);
}
RawFunction* Class::LookupStaticFunctionAllowPrivate(const String& name) const {
return LookupFunctionAllowPrivate(name, kStatic);
}
RawFunction* Class::LookupConstructor(const String& name) const {
return LookupFunction(name, kConstructor);
}
RawFunction* Class::LookupConstructorAllowPrivate(const String& name) const {
return LookupFunctionAllowPrivate(name, kConstructor);
}
RawFunction* Class::LookupFactory(const String& name) const {
return LookupFunction(name, kFactory);
}
RawFunction* Class::LookupFunction(const String& name) const {
return LookupFunction(name, kAny);
}
RawFunction* Class::LookupFunctionAllowPrivate(const String& name) const {
return LookupFunctionAllowPrivate(name, kAny);
}
// Returns true if 'prefix' and 'accessor_name' match 'name'.
static bool MatchesAccessorName(const String& name,
const char* prefix,
intptr_t prefix_length,
const String& accessor_name) {
intptr_t name_len = name.Length();
intptr_t accessor_name_len = accessor_name.Length();
if (name_len != (accessor_name_len + prefix_length)) {
return false;
}
for (intptr_t i = 0; i < prefix_length; i++) {
if (name.CharAt(i) != prefix[i]) {
return false;
}
}
for (intptr_t i = 0, j = prefix_length; i < accessor_name_len; i++, j++) {
if (name.CharAt(j) != accessor_name.CharAt(i)) {
return false;
}
}
return true;
}
RawFunction* Class::CheckFunctionType(const Function& func, intptr_t type) {
if (type == kInstance) {
if (func.IsDynamicFunction()) {
return func.raw();
}
} else if (type == kStatic) {
if (func.IsStaticFunction()) {
return func.raw();
}
} else if (type == kConstructor) {
if (func.IsConstructor()) {
ASSERT(!func.is_static());
return func.raw();
}
} else if (type == kFactory) {
if (func.IsFactory()) {
ASSERT(func.is_static());
return func.raw();
}
} else if (type == kAny) {
return func.raw();
}
return Function::null();
}
RawFunction* Class::LookupFunction(const String& name, intptr_t type) const {
Isolate* isolate = Isolate::Current();
if (EnsureIsFinalized(isolate) != Error::null()) {
return Function::null();
}
Array& funcs = Array::Handle(isolate, functions());
if (funcs.IsNull()) {
// This can occur, e.g., for Null classes.
return Function::null();
}
Function& function = Function::Handle(isolate);
const intptr_t len = funcs.Length();
if (name.IsSymbol()) {
// Quick Symbol compare.
NoGCScope no_gc;
for (intptr_t i = 0; i < len; i++) {
function ^= funcs.At(i);
if (function.name() == name.raw()) {
return CheckFunctionType(function, type);
}
}
} else {
String& function_name = String::Handle(isolate);
for (intptr_t i = 0; i < len; i++) {
function ^= funcs.At(i);
function_name ^= function.name();
if (function_name.Equals(name)) {
return CheckFunctionType(function, type);
}
}
}
// No function found.
return Function::null();
}
RawFunction* Class::LookupFunctionAllowPrivate(const String& name,
intptr_t type) const {
Isolate* isolate = Isolate::Current();
if (EnsureIsFinalized(isolate) != Error::null()) {
return Function::null();
}
Array& funcs = Array::Handle(isolate, functions());
if (funcs.IsNull()) {
// This can occur, e.g., for Null classes.
return Function::null();
}
Function& function = Function::Handle(isolate);
String& function_name = String::Handle(isolate);
intptr_t len = funcs.Length();
for (intptr_t i = 0; i < len; i++) {
function ^= funcs.At(i);
function_name ^= function.name();
if (String::EqualsIgnoringPrivateKey(function_name, name)) {
return CheckFunctionType(function, type);
}
}
// No function found.
return Function::null();
}
RawFunction* Class::LookupGetterFunction(const String& name) const {
return LookupAccessorFunction(kGetterPrefix, kGetterPrefixLength, name);
}
RawFunction* Class::LookupSetterFunction(const String& name) const {
return LookupAccessorFunction(kSetterPrefix, kSetterPrefixLength, name);
}
RawFunction* Class::LookupAccessorFunction(const char* prefix,
intptr_t prefix_length,
const String& name) const {
Isolate* isolate = Isolate::Current();
if (EnsureIsFinalized(isolate) != Error::null()) {
return Function::null();
}
Array& funcs = Array::Handle(isolate, functions());
Function& function = Function::Handle(isolate, Function::null());
String& function_name = String::Handle(isolate, String::null());
intptr_t len = funcs.Length();
for (intptr_t i = 0; i < len; i++) {
function ^= funcs.At(i);
function_name ^= function.name();
if (MatchesAccessorName(function_name, prefix, prefix_length, name)) {
return function.raw();
}
}
// No function found.
return Function::null();
}
RawFunction* Class::LookupFunctionAtToken(intptr_t token_pos) const {
// TODO(hausner): we can shortcut the negative case if we knew the
// beginning and end token position of the class.
Isolate* isolate = Isolate::Current();
if (EnsureIsFinalized(isolate) != Error::null()) {
return Function::null();
}
Function& func = Function::Handle(isolate);
func = LookupClosureFunction(token_pos);
if (!func.IsNull()) {
return func.raw();
}
Array& funcs = Array::Handle(isolate, functions());
intptr_t len = funcs.Length();
for (intptr_t i = 0; i < len; i++) {
func ^= funcs.At(i);
if ((func.token_pos() <= token_pos) &&
(token_pos <= func.end_token_pos())) {
return func.raw();
}
}
// No function found.
return Function::null();
}
RawField* Class::LookupInstanceField(const String& name) const {
return LookupField(name, kInstance);
}
RawField* Class::LookupStaticField(const String& name) const {
return LookupField(name, kStatic);
}
RawField* Class::LookupField(const String& name) const {
return LookupField(name, kAny);
}
RawField* Class::LookupField(const String& name, intptr_t type) const {
Isolate* isolate = Isolate::Current();
if (EnsureIsFinalized(isolate) != Error::null()) {
return Field::null();
}
const Array& flds = Array::Handle(isolate, fields());
Field& field = Field::Handle(isolate, Field::null());
String& field_name = String::Handle(isolate, String::null());
intptr_t len = flds.Length();
for (intptr_t i = 0; i < len; i++) {
field ^= flds.At(i);
field_name ^= field.name();
if (String::EqualsIgnoringPrivateKey(field_name, name)) {
if (type == kInstance) {
if (!field.is_static()) {
return field.raw();
}
} else if (type == kStatic) {
if (field.is_static()) {
return field.raw();
}
} else if (type == kAny) {
return field.raw();
}
return Field::null();
}
}
// No field found.
return Field::null();
}
RawLibraryPrefix* Class::LookupLibraryPrefix(const String& name) const {
Isolate* isolate = Isolate::Current();
const Library& lib = Library::Handle(isolate, library());
const Object& obj = Object::Handle(isolate, lib.LookupLocalObject(name));
if (!obj.IsNull() && obj.IsLibraryPrefix()) {
return LibraryPrefix::Cast(obj).raw();
}
return LibraryPrefix::null();
}
const char* Class::ToCString() const {
const char* format = "%s Class: %s";
const Library& lib = Library::Handle(library());
const char* library_name = lib.IsNull() ? "" : lib.ToCString();
const char* class_name = String::Handle(Name()).ToCString();
intptr_t len = OS::SNPrint(NULL, 0, format, library_name, class_name) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, library_name, class_name);
return chars;
}
void Class::InsertCanonicalConstant(intptr_t index,
const Instance& constant) const {
// The constant needs to be added to the list. Grow the list if it is full.
Array& canonical_list = Array::Handle(constants());
const intptr_t list_len = canonical_list.Length();
if (index >= list_len) {
const intptr_t new_length = (list_len == 0) ? 4 : list_len + 4;
const Array& new_canonical_list =
Array::Handle(Array::Grow(canonical_list, new_length, Heap::kOld));
set_constants(new_canonical_list);
new_canonical_list.SetAt(index, constant);
} else {
canonical_list.SetAt(index, constant);
}
}
RawUnresolvedClass* UnresolvedClass::New(const LibraryPrefix& library_prefix,
const String& ident,
intptr_t token_pos) {
const UnresolvedClass& type = UnresolvedClass::Handle(UnresolvedClass::New());
type.set_library_prefix(library_prefix);
type.set_ident(ident);
type.set_token_pos(token_pos);
return type.raw();
}
RawUnresolvedClass* UnresolvedClass::New() {
ASSERT(Object::unresolved_class_class() != Class::null());
RawObject* raw = Object::Allocate(UnresolvedClass::kClassId,
UnresolvedClass::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawUnresolvedClass*>(raw);
}
void UnresolvedClass::set_token_pos(intptr_t token_pos) const {
ASSERT(token_pos >= 0);
raw_ptr()->token_pos_ = token_pos;
}
void UnresolvedClass::set_ident(const String& ident) const {
StorePointer(&raw_ptr()->ident_, ident.raw());
}
void UnresolvedClass::set_library_prefix(
const LibraryPrefix& library_prefix) const {
StorePointer(&raw_ptr()->library_prefix_, library_prefix.raw());
}
RawString* UnresolvedClass::Name() const {
if (library_prefix() != LibraryPrefix::null()) {
const LibraryPrefix& lib_prefix = LibraryPrefix::Handle(library_prefix());
String& name = String::Handle();
name = lib_prefix.name(); // Qualifier.
name = String::Concat(name, Symbols::Dot());
const String& str = String::Handle(ident());
name = String::Concat(name, str);
return name.raw();
} else {
return ident();
}
}
const char* UnresolvedClass::ToCString() const {
const char* format = "unresolved class '%s'";
const char* cname = String::Handle(Name()).ToCString();
intptr_t len = OS::SNPrint(NULL, 0, format, cname) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, cname);
return chars;
}
intptr_t AbstractTypeArguments::Length() const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return -1;
}
RawAbstractType* AbstractTypeArguments::TypeAt(intptr_t index) const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return NULL;
}
void AbstractTypeArguments::SetTypeAt(intptr_t index,
const AbstractType& value) const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
}
bool AbstractTypeArguments::IsResolved() const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractTypeArguments::IsInstantiated() const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractTypeArguments::IsUninstantiatedIdentity() const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractTypeArguments::CanShareInstantiatorTypeArguments(
const Class& instantiator_class) const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractTypeArguments::IsBounded() const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return false;
}
static intptr_t FinalizeHash(uword hash) {
hash += hash << 3;
hash ^= hash >> 11;
hash += hash << 15;
return hash;
}
intptr_t AbstractTypeArguments::Hash() const {
if (IsNull()) return 0;
uword result = 0;
intptr_t num_types = Length();
AbstractType& type = AbstractType::Handle();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
result += type.Hash();
result += result << 10;
result ^= result >> 6;
}
return FinalizeHash(result);
}
RawString* AbstractTypeArguments::SubvectorName(
intptr_t from_index,
intptr_t len,
NameVisibility name_visibility) const {
ASSERT(from_index + len <= Length());
String& name = String::Handle();
const intptr_t num_strings = 2*len + 1; // "<""T"", ""T"">".
const Array& strings = Array::Handle(Array::New(num_strings));
intptr_t s = 0;
strings.SetAt(s++, Symbols::LAngleBracket());
AbstractType& type = AbstractType::Handle();
for (intptr_t i = 0; i < len; i++) {
type = TypeAt(from_index + i);
name = type.BuildName(name_visibility);
strings.SetAt(s++, name);
if (i < len - 1) {
strings.SetAt(s++, Symbols::CommaSpace());
}
}
strings.SetAt(s++, Symbols::RAngleBracket());
ASSERT(s == num_strings);
name = String::ConcatAll(strings);
return Symbols::New(name);
}
bool AbstractTypeArguments::Equals(const AbstractTypeArguments& other) const {
ASSERT(!IsNull()); // Use AbstractTypeArguments::AreEqual().
if (this->raw() == other.raw()) {
return true;
}
if (other.IsNull()) {
return false;
}
intptr_t num_types = Length();
if (num_types != other.Length()) {
return false;
}
AbstractType& type = AbstractType::Handle();
AbstractType& other_type = AbstractType::Handle();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
other_type = other.TypeAt(i);
if (!type.Equals(other_type)) {
return false;
}
}
return true;
}
bool AbstractTypeArguments::AreEqual(
const AbstractTypeArguments& arguments,
const AbstractTypeArguments& other_arguments) {
if (arguments.raw() == other_arguments.raw()) {
return true;
}
if (arguments.IsNull()) {
return other_arguments.IsDynamicTypes(false, other_arguments.Length());
}
if (other_arguments.IsNull()) {
return arguments.IsDynamicTypes(false, arguments.Length());
}
return arguments.Equals(other_arguments);
}
RawAbstractTypeArguments* AbstractTypeArguments::InstantiateFrom(
const AbstractTypeArguments& instantiator_type_arguments,
Error* malformed_error) const {
// AbstractTypeArguments is an abstract class.
UNREACHABLE();
return NULL;
}
bool AbstractTypeArguments::IsDynamicTypes(bool raw_instantiated,
intptr_t len) const {
ASSERT(Length() >= len);
AbstractType& type = AbstractType::Handle();
Class& type_class = Class::Handle();
for (intptr_t i = 0; i < len; i++) {
type = TypeAt(i);
ASSERT(!type.IsNull());
if (!type.HasResolvedTypeClass()) {
if (raw_instantiated && type.IsTypeParameter()) {
// An uninstantiated type parameter is equivalent to dynamic (even in
// the presence of a malformed bound in checked mode).
continue;
}
ASSERT((!raw_instantiated && type.IsTypeParameter()) ||
type.IsBoundedType() ||
type.IsMalformed());
return false;
}
type_class = type.type_class();
if (!type_class.IsDynamicClass()) {
return false;
}
}
return true;
}
static RawError* FormatError(const Error& prev_error,
const Script& script,
intptr_t token_pos,
const char* format, ...) {
va_list args;
va_start(args, format);
if (prev_error.IsNull()) {
return Parser::FormatError(script, token_pos, "Error", format, args);
} else {
return Parser::FormatErrorWithAppend(prev_error, script, token_pos,
"Error", format, args);
}
}
bool AbstractTypeArguments::TypeTest(TypeTestKind test_kind,
const AbstractTypeArguments& other,
intptr_t len,
Error* malformed_error) const {
ASSERT(Length() >= len);
ASSERT(!other.IsNull());
ASSERT(other.Length() >= len);
AbstractType& type = AbstractType::Handle();
AbstractType& other_type = AbstractType::Handle();
for (intptr_t i = 0; i < len; i++) {
type = TypeAt(i);
ASSERT(!type.IsNull());
other_type = other.TypeAt(i);
ASSERT(!other_type.IsNull());
if (!type.TypeTest(test_kind, other_type, malformed_error)) {
return false;
}
}
return true;
}
const char* AbstractTypeArguments::ToCString() const {
// AbstractTypeArguments is an abstract class, valid only for representing
// null.
if (IsNull()) {
return "NULL AbstractTypeArguments";
}
UNREACHABLE();
return "AbstractTypeArguments";
}
intptr_t TypeArguments::Length() const {
ASSERT(!IsNull());
return Smi::Value(raw_ptr()->length_);
}
RawAbstractType* TypeArguments::TypeAt(intptr_t index) const {
return *TypeAddr(index);
}
void TypeArguments::SetTypeAt(intptr_t index, const AbstractType& value) const {
ASSERT(!IsCanonical());
StorePointer(TypeAddr(index), value.raw());
}
bool TypeArguments::IsResolved() const {
AbstractType& type = AbstractType::Handle();
intptr_t num_types = Length();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
if (!type.IsResolved()) {
return false;
}
}
return true;
}
bool TypeArguments::IsInstantiated() const {
AbstractType& type = AbstractType::Handle();
intptr_t num_types = Length();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
ASSERT(!type.IsNull());
if (!type.IsInstantiated()) {
return false;
}
}
return true;
}
bool TypeArguments::IsUninstantiatedIdentity() const {
ASSERT(!IsInstantiated());
AbstractType& type = AbstractType::Handle();
const intptr_t num_types = Length();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
if (!type.IsTypeParameter()) {
return false;
}
const TypeParameter& type_param = TypeParameter::Cast(type);
ASSERT(type_param.IsFinalized());
if ((type_param.index() != i)) {
return false;
}
// If this type parameter specifies an upper bound, then the type argument
// vector does not really represent the identity vector. It cannot be
// substituted by the instantiator's type argument vector without checking
// the upper bound.
const AbstractType& bound = AbstractType::Handle(type_param.bound());
ASSERT(bound.IsResolved());
if (!bound.IsObjectType() && !bound.IsDynamicType()) {
return false;
}
}
return true;
// Note that it is not necessary to verify at runtime that the instantiator
// type vector is long enough, since this uninstantiated vector contains as
// many different type parameters as it is long.
}
bool TypeArguments::CanShareInstantiatorTypeArguments(
const Class& instantiator_class) const {
ASSERT(!IsInstantiated());
const intptr_t num_instantiator_type_args =
instantiator_class.NumTypeArguments();
const intptr_t num_instantiator_type_params =
instantiator_class.NumTypeParameters();
const intptr_t num_super_instantiator_type_args =
num_instantiator_type_args - num_instantiator_type_params;
const intptr_t num_type_args = Length();
// As a first requirement in order to share the instantiator type argument
// vector, this type argument vector must refer to the type parameters of the
// instantiator class in declaration order. It does not need to contain all
// type parameters.
if (num_type_args < num_super_instantiator_type_args) {
return false;
}
AbstractType& type_arg = AbstractType::Handle();
for (intptr_t i = num_super_instantiator_type_args; i < num_type_args; i++) {
type_arg = TypeAt(i);
if (!type_arg.IsTypeParameter()) {
return false;
}
const TypeParameter& type_param = TypeParameter::Cast(type_arg);
ASSERT(type_param.IsFinalized());
if ((type_param.index() != i)) {
return false;
}
}
// As a second requirement, the type arguments corresponding to the super type
// must be identical.
if (num_super_instantiator_type_args == 0) {
return true;
}
AbstractType& super_type = AbstractType::Handle(
instantiator_class.super_type());
const AbstractTypeArguments& super_type_args = AbstractTypeArguments::Handle(
super_type.arguments());
if (super_type_args.IsNull()) {
return false;
}
AbstractType& super_type_arg = AbstractType::Handle();
for (intptr_t i = 0; i < num_super_instantiator_type_args; i++) {
type_arg = TypeAt(i);
super_type_arg = super_type_args.TypeAt(i);
if (!type_arg.Equals(super_type_arg)) {
return false;
}
}
return true;
}
bool TypeArguments::IsBounded() const {
AbstractType& type = AbstractType::Handle();
intptr_t num_types = Length();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
if (type.IsBoundedType()) {
return true;
}
if (type.IsTypeParameter()) {
const AbstractType& bound = AbstractType::Handle(
TypeParameter::Cast(type).bound());
if (!bound.IsObjectType() && !bound.IsDynamicType()) {
return true;
}
continue;
}
const AbstractTypeArguments& type_args = AbstractTypeArguments::Handle(
Type::Cast(type).arguments());
if (!type_args.IsNull() && type_args.IsBounded()) {
return true;
}
}
return false;
}
RawAbstractTypeArguments* TypeArguments::InstantiateFrom(
const AbstractTypeArguments& instantiator_type_arguments,
Error* malformed_error) const {
ASSERT(!IsInstantiated());
if (!instantiator_type_arguments.IsNull() &&
IsUninstantiatedIdentity() &&
(instantiator_type_arguments.Length() == Length())) {
return instantiator_type_arguments.raw();
}
const intptr_t num_types = Length();
TypeArguments& instantiated_array =
TypeArguments::Handle(TypeArguments::New(num_types, Heap::kNew));
AbstractType& type = AbstractType::Handle();
for (intptr_t i = 0; i < num_types; i++) {
type = TypeAt(i);
if (!type.IsInstantiated()) {
type = type.InstantiateFrom(instantiator_type_arguments, malformed_error);
}
instantiated_array.SetTypeAt(i, type);
}
return instantiated_array.raw();
}
RawTypeArguments* TypeArguments::New(intptr_t len, Heap::Space space) {
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in TypeArguments::New: invalid len %"Pd"\n", len);
}
TypeArguments& result = TypeArguments::Handle();
{
RawObject* raw = Object::Allocate(TypeArguments::kClassId,
TypeArguments::InstanceSize(len),
space);
NoGCScope no_gc;
result ^= raw;
// Length must be set before we start storing into the array.
result.SetLength(len);
}
return result.raw();
}
RawAbstractType** TypeArguments::TypeAddr(intptr_t index) const {
// TODO(iposva): Determine if we should throw an exception here.
ASSERT((index >= 0) && (index < Length()));
return &raw_ptr()->types_[index];
}
void TypeArguments::SetLength(intptr_t value) const {
ASSERT(!IsCanonical());
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
raw_ptr()->length_ = Smi::New(value);
}
static void GrowCanonicalTypeArguments(Isolate* isolate, const Array& table) {
// Last element of the array is the number of used elements.
intptr_t table_size = table.Length() - 1;
intptr_t new_table_size = table_size * 2;
Array& new_table = Array::Handle(isolate, Array::New(new_table_size + 1));
// Copy all elements from the original table to the newly allocated
// array.
TypeArguments& element = TypeArguments::Handle(isolate);
Object& new_element = Object::Handle(isolate);
for (intptr_t i = 0; i < table_size; i++) {
element ^= table.At(i);
if (!element.IsNull()) {
intptr_t hash = element.Hash();
ASSERT(Utils::IsPowerOfTwo(new_table_size));
intptr_t index = hash & (new_table_size - 1);
new_element = new_table.At(index);
while (!new_element.IsNull()) {
index = (index + 1) & (new_table_size - 1); // Move to next element.
new_element = new_table.At(index);
}
new_table.SetAt(index, element);
}
}
// Copy used count.
new_element = table.At(table_size);
new_table.SetAt(new_table_size, new_element);
// Remember the new table now.
isolate->object_store()->set_canonical_type_arguments(new_table);
}
static void InsertIntoCanonicalTypeArguments(Isolate* isolate,
const Array& table,
const TypeArguments& arguments,
intptr_t index) {
arguments.SetCanonical(); // Mark object as being canonical.
table.SetAt(index, arguments); // Remember the new element.
// Update used count.
// Last element of the array is the number of used elements.
intptr_t table_size = table.Length() - 1;
intptr_t used_elements = Smi::Value(Smi::RawCast(table.At(table_size))) + 1;
const Smi& used = Smi::Handle(isolate, Smi::New(used_elements));
table.SetAt(table_size, used);
// Rehash if table is 75% full.
if (used_elements > ((table_size / 4) * 3)) {
GrowCanonicalTypeArguments(isolate, table);
}
}
static intptr_t FindIndexInCanonicalTypeArguments(
Isolate* isolate,
const Array& table,
const TypeArguments& arguments,
intptr_t hash) {
// Last element of the array is the number of used elements.
intptr_t table_size = table.Length() - 1;
ASSERT(Utils::IsPowerOfTwo(table_size));
intptr_t index = hash & (table_size - 1);
TypeArguments& current = TypeArguments::Handle(isolate);
current ^= table.At(index);
while (!current.IsNull() && !current.Equals(arguments)) {
index = (index + 1) & (table_size - 1); // Move to next element.
current ^= table.At(index);
}
return index; // Index of element if found or slot into which to add it.
}
RawAbstractTypeArguments* TypeArguments::Canonicalize() const {
if (IsNull() || IsCanonical()) {
ASSERT(IsOld());
return this->raw();
}
Isolate* isolate = Isolate::Current();
ObjectStore* object_store = isolate->object_store();
const Array& table = Array::Handle(isolate,
object_store->canonical_type_arguments());
ASSERT(table.Length() > 0);
intptr_t index = FindIndexInCanonicalTypeArguments(isolate,
table,
*this,
Hash());
TypeArguments& result = TypeArguments::Handle(isolate);
result ^= table.At(index);
if (result.IsNull()) {
// Make sure we have an old space object and add it to the table.
if (this->IsNew()) {
result ^= Object::Clone(*this, Heap::kOld);
} else {
result ^= this->raw();
}
ASSERT(result.IsOld());
InsertIntoCanonicalTypeArguments(isolate, table, result, index);
}
ASSERT(result.Equals(*this));
ASSERT(!result.IsNull());
ASSERT(result.IsTypeArguments());
return result.raw();
}
const char* TypeArguments::ToCString() const {
if (IsNull()) {
return "NULL TypeArguments";
}
const char* format = "%s [%s]";
const char* prev_cstr = "TypeArguments:";
for (int i = 0; i < Length(); i++) {
const AbstractType& type_at = AbstractType::Handle(TypeAt(i));
const char* type_cstr = type_at.IsNull() ? "null" : type_at.ToCString();
intptr_t len = OS::SNPrint(NULL, 0, format, prev_cstr, type_cstr) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, prev_cstr, type_cstr);
prev_cstr = chars;
}
return prev_cstr;
}
intptr_t InstantiatedTypeArguments::Length() const {
return AbstractTypeArguments::Handle(
uninstantiated_type_arguments()).Length();
}
RawAbstractType* InstantiatedTypeArguments::TypeAt(intptr_t index) const {
AbstractType& type = AbstractType::Handle(AbstractTypeArguments::Handle(
uninstantiated_type_arguments()).TypeAt(index));
if (!type.IsInstantiated()) {
const AbstractTypeArguments& instantiator_type_args =
AbstractTypeArguments::Handle(instantiator_type_arguments());
Error& malformed_error = Error::Handle();
type = type.InstantiateFrom(instantiator_type_args, &malformed_error);
// InstantiatedTypeArguments cannot include unchecked bounds.
// In the presence of unchecked bounds, no InstantiatedTypeArguments are
// allocated, but the type arguments are instantiated individually and their
// bounds are checked.
ASSERT(malformed_error.IsNull());
}
return type.raw();
}
void InstantiatedTypeArguments::SetTypeAt(intptr_t index,
const AbstractType& value) const {
// We only replace individual argument types during resolution at compile
// time, when no type parameters are instantiated yet.
UNREACHABLE();
}
void InstantiatedTypeArguments::set_uninstantiated_type_arguments(
const AbstractTypeArguments& value) const {
StorePointer(&raw_ptr()->uninstantiated_type_arguments_, value.raw());
}
void InstantiatedTypeArguments::set_instantiator_type_arguments(
const AbstractTypeArguments& value) const {
StorePointer(&raw_ptr()->instantiator_type_arguments_, value.raw());
}
RawInstantiatedTypeArguments* InstantiatedTypeArguments::New() {
ASSERT(Object::instantiated_type_arguments_class() != Class::null());
RawObject* raw = Object::Allocate(InstantiatedTypeArguments::kClassId,
InstantiatedTypeArguments::InstanceSize(),
Heap::kNew);
return reinterpret_cast<RawInstantiatedTypeArguments*>(raw);
}
RawInstantiatedTypeArguments* InstantiatedTypeArguments::New(
const AbstractTypeArguments& uninstantiated_type_arguments,
const AbstractTypeArguments& instantiator_type_arguments) {
const InstantiatedTypeArguments& result =
InstantiatedTypeArguments::Handle(InstantiatedTypeArguments::New());
result.set_uninstantiated_type_arguments(uninstantiated_type_arguments);
result.set_instantiator_type_arguments(instantiator_type_arguments);
return result.raw();
}
const char* InstantiatedTypeArguments::ToCString() const {
if (IsNull()) {
return "NULL InstantiatedTypeArguments";
}
const char* format = "InstantiatedTypeArguments: [%s] instantiator: [%s]";
const char* arg_cstr =
AbstractTypeArguments::Handle(
uninstantiated_type_arguments()).ToCString();
const char* instantiator_cstr =
AbstractTypeArguments::Handle(instantiator_type_arguments()).ToCString();
intptr_t len =
OS::SNPrint(NULL, 0, format, arg_cstr, instantiator_cstr) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, arg_cstr, instantiator_cstr);
return chars;
}
const char* PatchClass::ToCString() const {
const char* kFormat = "PatchClass for %s";
const Class& cls = Class::Handle(patched_class());
const char* cls_name = cls.ToCString();
intptr_t len = OS::SNPrint(NULL, 0, kFormat, cls_name) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, cls_name);
return chars;
}
RawPatchClass* PatchClass::New(const Class& patched_class,
const Class& source_class) {
const PatchClass& result = PatchClass::Handle(PatchClass::New());
result.set_patched_class(patched_class);
result.set_source_class(source_class);
return result.raw();
}
RawPatchClass* PatchClass::New() {
ASSERT(Object::patch_class_class() != Class::null());
RawObject* raw = Object::Allocate(PatchClass::kClassId,
PatchClass::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawPatchClass*>(raw);
}
RawScript* PatchClass::Script() const {
const Class& source_class = Class::Handle(this->source_class());
return source_class.script();
}
void PatchClass::set_patched_class(const Class& value) const {
StorePointer(&raw_ptr()->patched_class_, value.raw());
}
void PatchClass::set_source_class(const Class& value) const {
StorePointer(&raw_ptr()->source_class_, value.raw());
}
bool Function::HasBreakpoint() const {
return Isolate::Current()->debugger()->HasBreakpoint(*this);
}
void Function::SetCode(const Code& value) const {
StorePointer(&raw_ptr()->code_, value.raw());
ASSERT(Function::Handle(value.function()).IsNull() ||
(value.function() == this->raw()));
value.set_function(*this);
}
void Function::SwitchToUnoptimizedCode() const {
ASSERT(HasOptimizedCode());
const Code& current_code = Code::Handle(CurrentCode());
// Optimized code object might have been actually fully produced by the
// intrinsifier in this case nothing has to be done. In fact an attempt to
// patch such code will cause crash.
// TODO(vegorov): if intrisifier can fully intrisify the function then we
// should not later try to optimize it.
if (PcDescriptors::Handle(current_code.pc_descriptors()).Length() == 0) {
return;
}
if (FLAG_trace_disabling_optimized_code) {
OS::Print("Disabling optimized code: '%s' entry: %#"Px"\n",
ToFullyQualifiedCString(),
current_code.EntryPoint());
}
// Patch entry of the optimized code.
CodePatcher::PatchEntry(current_code);
// Use previously compiled unoptimized code.
SetCode(Code::Handle(unoptimized_code()));
CodePatcher::RestoreEntry(Code::Handle(unoptimized_code()));
}
void Function::set_unoptimized_code(const Code& value) const {
StorePointer(&raw_ptr()->unoptimized_code_, value.raw());
}
RawContextScope* Function::context_scope() const {
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return ClosureData::Cast(obj).context_scope();
}
return ContextScope::null();
}
void Function::set_context_scope(const ContextScope& value) const {
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
ClosureData::Cast(obj).set_context_scope(value);
return;
}
UNREACHABLE();
}
RawInstance* Function::implicit_static_closure() const {
if (IsImplicitStaticClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return ClosureData::Cast(obj).implicit_static_closure();
}
return Instance::null();
}
void Function::set_implicit_static_closure(const Instance& closure) const {
if (IsImplicitStaticClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
ClosureData::Cast(obj).set_implicit_static_closure(closure);
return;
}
UNREACHABLE();
}
RawCode* Function::closure_allocation_stub() const {
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return ClosureData::Cast(obj).closure_allocation_stub();
}
return Code::null();
}
void Function::set_closure_allocation_stub(const Code& value) const {
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
ClosureData::Cast(obj).set_closure_allocation_stub(value);
return;
}
UNREACHABLE();
}
RawFunction* Function::extracted_method_closure() const {
ASSERT(kind() == RawFunction::kMethodExtractor);
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(obj.IsFunction());
return Function::Cast(obj).raw();
}
void Function::set_extracted_method_closure(const Function& value) const {
ASSERT(kind() == RawFunction::kMethodExtractor);
ASSERT(raw_ptr()->data_ == Object::null());
set_data(value);
}
RawFunction* Function::parent_function() const {
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return ClosureData::Cast(obj).parent_function();
}
return Function::null();
}
void Function::set_parent_function(const Function& value) const {
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
ClosureData::Cast(obj).set_parent_function(value);
return;
}
UNREACHABLE();
}
RawFunction* Function::implicit_closure_function() const {
if (IsClosureFunction() || IsSignatureFunction()) {
return Function::null();
}
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(obj.IsNull() || obj.IsFunction());
return (obj.IsNull()) ? Function::null() : Function::Cast(obj).raw();
}
void Function::set_implicit_closure_function(const Function& value) const {
ASSERT(!IsClosureFunction() && !IsSignatureFunction());
set_data(value);
}
RawClass* Function::signature_class() const {
if (IsSignatureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(obj.IsNull() || obj.IsClass());
return (obj.IsNull()) ? Class::null() : Class::Cast(obj).raw();
}
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return ClosureData::Cast(obj).signature_class();
}
return Class::null();
}
void Function::set_signature_class(const Class& value) const {
if (IsSignatureFunction()) {
set_data(value);
return;
}
if (IsClosureFunction()) {
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
ClosureData::Cast(obj).set_signature_class(value);
return;
}
UNREACHABLE();
}
bool Function::IsRedirectingFactory() const {
if (!IsFactory() || (raw_ptr()->data_ == Object::null())) {
return false;
}
ASSERT(!IsClosureFunction()); // A factory cannot also be a closure.
return true;
}
RawType* Function::RedirectionType() const {
ASSERT(IsRedirectingFactory());
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return RedirectionData::Cast(obj).type();
}
void Function::SetRedirectionType(const Type& type) const {
ASSERT(IsFactory());
Object& obj = Object::Handle(raw_ptr()->data_);
if (obj.IsNull()) {
obj = RedirectionData::New();
set_data(obj);
}
RedirectionData::Cast(obj).set_type(type);
}
RawString* Function::RedirectionIdentifier() const {
ASSERT(IsRedirectingFactory());
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return RedirectionData::Cast(obj).identifier();
}
void Function::SetRedirectionIdentifier(const String& identifier) const {
ASSERT(IsFactory());
Object& obj = Object::Handle(raw_ptr()->data_);
if (obj.IsNull()) {
obj = RedirectionData::New();
set_data(obj);
}
RedirectionData::Cast(obj).set_identifier(identifier);
}
RawFunction* Function::RedirectionTarget() const {
ASSERT(IsRedirectingFactory());
const Object& obj = Object::Handle(raw_ptr()->data_);
ASSERT(!obj.IsNull());
return RedirectionData::Cast(obj).target();
}
void Function::SetRedirectionTarget(const Function& target) const {
ASSERT(IsFactory());
Object& obj = Object::Handle(raw_ptr()->data_);
if (obj.IsNull()) {
obj = RedirectionData::New();
set_data(obj);
}
RedirectionData::Cast(obj).set_target(target);
}
void Function::set_data(const Object& value) const {
StorePointer(&raw_ptr()->data_, value.raw());
}
bool Function::IsInFactoryScope() const {
if (!IsLocalFunction()) {
return IsFactory();
}
Function& outer_function = Function::Handle(parent_function());
while (outer_function.IsLocalFunction()) {
outer_function = outer_function.parent_function();
}
return outer_function.IsFactory();
}
void Function::set_name(const String& value) const {
ASSERT(value.IsSymbol());
StorePointer(&raw_ptr()->name_, value.raw());
}
void Function::set_owner(const Object& value) const {
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->owner_, value.raw());
}
void Function::set_result_type(const AbstractType& value) const {
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->result_type_, value.raw());
}
RawAbstractType* Function::ParameterTypeAt(intptr_t index) const {
const Array& parameter_types = Array::Handle(raw_ptr()->parameter_types_);
AbstractType& parameter_type = AbstractType::Handle();
parameter_type ^= parameter_types.At(index);
return parameter_type.raw();
}
void Function::SetParameterTypeAt(
intptr_t index, const AbstractType& value) const {
ASSERT(!value.IsNull());
const Array& parameter_types = Array::Handle(raw_ptr()->parameter_types_);
parameter_types.SetAt(index, value);
}
void Function::set_parameter_types(const Array& value) const {
StorePointer(&raw_ptr()->parameter_types_, value.raw());
}
RawString* Function::ParameterNameAt(intptr_t index) const {
const Array& parameter_names = Array::Handle(raw_ptr()->parameter_names_);
String& parameter_name = String::Handle();
parameter_name ^= parameter_names.At(index);
return parameter_name.raw();
}
void Function::SetParameterNameAt(intptr_t index, const String& value) const {
ASSERT(!value.IsNull() && value.IsSymbol());
const Array& parameter_names = Array::Handle(raw_ptr()->parameter_names_);
parameter_names.SetAt(index, value);
}
void Function::set_parameter_names(const Array& value) const {
StorePointer(&raw_ptr()->parameter_names_, value.raw());
}
void Function::set_kind(RawFunction::Kind value) const {
set_kind_tag(KindBits::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_intrinsic(bool value) const {
set_kind_tag(IntrinsicBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_static(bool value) const {
set_kind_tag(StaticBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_const(bool value) const {
set_kind_tag(ConstBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_external(bool value) const {
set_kind_tag(ExternalBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_token_pos(intptr_t value) const {
ASSERT(value >= 0);
raw_ptr()->token_pos_ = value;
}
void Function::set_kind_tag(intptr_t value) const {
raw_ptr()->kind_tag_ = static_cast<uint16_t>(value);
}
void Function::set_num_fixed_parameters(intptr_t value) const {
ASSERT(value >= 0);
ASSERT(Utils::IsInt(16, value));
raw_ptr()->num_fixed_parameters_ = static_cast<int16_t>(value);
}
void Function::set_num_optional_parameters(intptr_t value) const {
// A positive value indicates positional params, a negative one named params.
ASSERT(Utils::IsInt(16, value));
raw_ptr()->num_optional_parameters_ = static_cast<int16_t>(value);
}
void Function::SetNumOptionalParameters(intptr_t num_optional_parameters,
bool are_optional_positional) const {
ASSERT(num_optional_parameters >= 0);
set_num_optional_parameters(are_optional_positional ?
num_optional_parameters :
-num_optional_parameters);
}
bool Function::is_optimizable() const {
if (OptimizableBit::decode(raw_ptr()->kind_tag_) &&
(script() != Script::null()) &&
!is_native() &&
((end_token_pos() - token_pos()) < FLAG_huge_method_cutoff_in_tokens)) {
// Additional check needed for implicit getters.
if (HasCode() &&
(Code::Handle(unoptimized_code()).Size() >=
FLAG_huge_method_cutoff_in_code_size)) {
return false;
} else {
return true;
}
}
return false;
}
void Function::set_is_optimizable(bool value) const {
set_kind_tag(OptimizableBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_has_finally(bool value) const {
set_kind_tag(HasFinallyBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_native(bool value) const {
set_kind_tag(NativeBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_abstract(bool value) const {
set_kind_tag(AbstractBit::update(value, raw_ptr()->kind_tag_));
}
void Function::set_is_inlinable(bool value) const {
set_kind_tag(InlinableBit::update(value, raw_ptr()->kind_tag_));
}
bool Function::IsInlineable() const {
// '==' call is handled specially.
return InlinableBit::decode(raw_ptr()->kind_tag_) &&
HasCode() &&
name() != Symbols::EqualOperator().raw();
}
void Function::set_is_visible(bool value) const {
set_kind_tag(VisibleBit::update(value, raw_ptr()->kind_tag_));
}
intptr_t Function::NumParameters() const {
return num_fixed_parameters() + NumOptionalParameters();
}
intptr_t Function::NumImplicitParameters() const {
if (kind() == RawFunction::kConstructor) {
if (is_static()) {
ASSERT(IsFactory());
return 1; // Type arguments.
} else {
ASSERT(IsConstructor());
return 2; // Instance, phase.
}
}
if ((kind() == RawFunction::kClosureFunction) ||
(kind() == RawFunction::kSignatureFunction)) {
return 1; // Closure object.
}
if (!is_static()) {
// Closure functions defined inside instance (i.e. non-static) functions are
// marked as non-static, but they do not have a receiver.
// Closures are handled above.
ASSERT((kind() != RawFunction::kClosureFunction) &&
(kind() != RawFunction::kSignatureFunction));
return 1; // Receiver.
}
return 0; // No implicit parameters.
}
bool Function::AreValidArgumentCounts(int num_arguments,
int num_named_arguments,
String* error_message) const {
if (num_named_arguments > NumOptionalNamedParameters()) {
if (error_message != NULL) {
const intptr_t kMessageBufferSize = 64;
char message_buffer[kMessageBufferSize];
OS::SNPrint(message_buffer,
kMessageBufferSize,
"%d named passed, at most %"Pd" expected",
num_named_arguments,
NumOptionalNamedParameters());
*error_message = String::New(message_buffer);
}
return false; // Too many named arguments.
}
const int num_pos_args = num_arguments - num_named_arguments;
const int num_opt_pos_params = NumOptionalPositionalParameters();
const int num_pos_params = num_fixed_parameters() + num_opt_pos_params;
if (num_pos_args > num_pos_params) {
if (error_message != NULL) {
const intptr_t kMessageBufferSize = 64;
char message_buffer[kMessageBufferSize];
// Hide implicit parameters to the user.
const intptr_t num_hidden_params = NumImplicitParameters();
OS::SNPrint(message_buffer,
kMessageBufferSize,
"%"Pd"%s passed, %s%"Pd" expected",
num_pos_args - num_hidden_params,
num_opt_pos_params > 0 ? " positional" : "",
num_opt_pos_params > 0 ? "at most " : "",
num_pos_params - num_hidden_params);
*error_message = String::New(message_buffer);
}
return false; // Too many fixed and/or positional arguments.
}
if (num_pos_args < num_fixed_parameters()) {
if (error_message != NULL) {
const intptr_t kMessageBufferSize = 64;
char message_buffer[kMessageBufferSize];
// Hide implicit parameters to the user.
const intptr_t num_hidden_params = NumImplicitParameters();
OS::SNPrint(message_buffer,
kMessageBufferSize,
"%"Pd"%s passed, %s%"Pd" expected",
num_pos_args - num_hidden_params,
num_opt_pos_params > 0 ? " positional" : "",
num_opt_pos_params > 0 ? "at least " : "",
num_fixed_parameters() - num_hidden_params);
*error_message = String::New(message_buffer);
}
return false; // Too few fixed and/or positional arguments.
}
return true;
}
bool Function::AreValidArguments(int num_arguments,
const Array& argument_names,
String* error_message) const {
const int num_named_arguments =
argument_names.IsNull() ? 0 : argument_names.Length();
if (!AreValidArgumentCounts(num_arguments,
num_named_arguments,
error_message)) {
return false;
}
// Verify that all argument names are valid parameter names.
Isolate* isolate = Isolate::Current();
String& argument_name = String::Handle(isolate);
String& parameter_name = String::Handle(isolate);
for (int i = 0; i < num_named_arguments; i++) {
argument_name ^= argument_names.At(i);
ASSERT(argument_name.IsSymbol());
bool found = false;
const int num_positional_args = num_arguments - num_named_arguments;
const int num_parameters = NumParameters();
for (int j = num_positional_args; !found && (j < num_parameters); j++) {
parameter_name = ParameterNameAt(j);
ASSERT(argument_name.IsSymbol());
if (argument_name.Equals(parameter_name)) {
found = true;
}
}
if (!found) {
if (error_message != NULL) {
const intptr_t kMessageBufferSize = 64;
char message_buffer[kMessageBufferSize];
OS::SNPrint(message_buffer,
kMessageBufferSize,
"no optional formal parameter named '%s'",
argument_name.ToCString());
*error_message = String::New(message_buffer);
}
return false;
}
}
return true;
}
// Helper allocating a C string buffer in the zone, printing the fully qualified
// name of a function in it, and replacing ':' by '_' to make sure the
// constructed name is a valid C++ identifier for debugging purpose.
// Set 'chars' to allocated buffer and return number of written characters.
static intptr_t ConstructFunctionFullyQualifiedCString(const Function& function,
char** chars,
intptr_t reserve_len) {
const char* name = String::Handle(function.name()).ToCString();
const char* function_format = (reserve_len == 0) ? "%s" : "%s_";
reserve_len += OS::SNPrint(NULL, 0, function_format, name);
const Function& parent = Function::Handle(function.parent_function());
intptr_t written = 0;
if (parent.IsNull()) {
const Class& function_class = Class::Handle(function.Owner());
ASSERT(!function_class.IsNull());
const char* class_name = String::Handle(function_class.Name()).ToCString();
ASSERT(class_name != NULL);
const Library& library = Library::Handle(function_class.library());
ASSERT(!library.IsNull());
const char* library_name = String::Handle(library.url()).ToCString();
ASSERT(library_name != NULL);
const char* lib_class_format =
(library_name[0] == '\0') ? "%s%s_" : "%s_%s_";
reserve_len +=
OS::SNPrint(NULL, 0, lib_class_format, library_name, class_name);
ASSERT(chars != NULL);
*chars = Isolate::Current()->current_zone()->Alloc<char>(reserve_len + 1);
written = OS::SNPrint(
*chars, reserve_len + 1, lib_class_format, library_name, class_name);
} else {
written = ConstructFunctionFullyQualifiedCString(parent,
chars,
reserve_len);
}
ASSERT(*chars != NULL);
char* next = *chars + written;
written += OS::SNPrint(next, reserve_len + 1, function_format, name);
// Replace ":" with "_".
while (true) {
next = strchr(next, ':');
if (next == NULL) break;
*next = '_';
}
return written;
}
const char* Function::ToFullyQualifiedCString() const {
char* chars = NULL;
ConstructFunctionFullyQualifiedCString(*this, &chars, 0);
return chars;
}
bool Function::HasCompatibleParametersWith(const Function& other) const {
const intptr_t num_fixed_params = num_fixed_parameters();
const intptr_t num_opt_pos_params = NumOptionalPositionalParameters();
const intptr_t num_opt_named_params = NumOptionalNamedParameters();
const intptr_t other_num_fixed_params = other.num_fixed_parameters();
const intptr_t other_num_opt_pos_params =
other.NumOptionalPositionalParameters();
const intptr_t other_num_opt_named_params =
other.NumOptionalNamedParameters();
// A generative constructor may be compared to a redirecting factory and be
// compatible although it has an additional phase parameter.
const intptr_t num_ignored_params =
(other.IsRedirectingFactory() && IsConstructor()) ? 1 : 0;
// The default values of optional parameters can differ.
// This function requires the same arguments or less and accepts the same
// arguments or more.
if (((num_fixed_params - num_ignored_params) > other_num_fixed_params) ||
((num_fixed_params - num_ignored_params) + num_opt_pos_params <
other_num_fixed_params + other_num_opt_pos_params) ||
(num_opt_named_params < other_num_opt_named_params)) {
return false;
}
if (other_num_opt_named_params == 0) {
return true;
}
// Check that for each optional named parameter of the other function there
// exists an optional named parameter of this function with an identical
// name.
// Note that SetParameterNameAt() guarantees that names are symbols, so we
// can compare their raw pointers.
const int num_params = num_fixed_params + num_opt_named_params;
const int other_num_params =
other_num_fixed_params + other_num_opt_named_params;
bool found_param_name;
String& other_param_name = String::Handle();
for (intptr_t i = other_num_fixed_params; i < other_num_params; i++) {
other_param_name = other.ParameterNameAt(i);
found_param_name = false;
for (intptr_t j = num_fixed_params; j < num_params; j++) {
if (ParameterNameAt(j) == other_param_name.raw()) {
found_param_name = true;
break;
}
}
if (!found_param_name) {
return false;
}
}
return true;
}
// If test_kind == kIsSubtypeOf, checks if the type of the specified parameter
// of this function is a subtype or a supertype of the type of the specified
// parameter of the other function.
// If test_kind == kIsMoreSpecificThan, checks if the type of the specified
// parameter of this function is more specific than the type of the specified
// parameter of the other function.
// Note that we do not apply contravariance of parameter types, but covariance
// of both parameter types and result type.
bool Function::TestParameterType(
TypeTestKind test_kind,
intptr_t parameter_position,
intptr_t other_parameter_position,
const AbstractTypeArguments& type_arguments,
const Function& other,
const AbstractTypeArguments& other_type_arguments,
Error* malformed_error) const {
AbstractType& other_param_type =
AbstractType::Handle(other.ParameterTypeAt(other_parameter_position));
if (!other_param_type.IsInstantiated()) {
other_param_type = other_param_type.InstantiateFrom(other_type_arguments,
malformed_error);
ASSERT((malformed_error == NULL) || malformed_error->IsNull());
}
if (other_param_type.IsDynamicType()) {
return true;
}
AbstractType& param_type =
AbstractType::Handle(ParameterTypeAt(parameter_position));
if (!param_type.IsInstantiated()) {
param_type = param_type.InstantiateFrom(type_arguments, malformed_error);
ASSERT((malformed_error == NULL) || malformed_error->IsNull());
}
if (param_type.IsDynamicType()) {
return test_kind == kIsSubtypeOf;
}
if (test_kind == kIsSubtypeOf) {
if (!param_type.IsSubtypeOf(other_param_type, malformed_error) &&
!other_param_type.IsSubtypeOf(param_type, malformed_error)) {
return false;
}
} else {
ASSERT(test_kind == kIsMoreSpecificThan);
if (!param_type.IsMoreSpecificThan(other_param_type, malformed_error)) {
return false;
}
}
return true;
}
bool Function::TypeTest(TypeTestKind test_kind,
const AbstractTypeArguments& type_arguments,
const Function& other,
const AbstractTypeArguments& other_type_arguments,
Error* malformed_error) const {
const intptr_t num_fixed_params = num_fixed_parameters();
const intptr_t num_opt_pos_params = NumOptionalPositionalParameters();
const intptr_t num_opt_named_params = NumOptionalNamedParameters();
const intptr_t other_num_fixed_params = other.num_fixed_parameters();
const intptr_t other_num_opt_pos_params =
other.NumOptionalPositionalParameters();
const intptr_t other_num_opt_named_params =
other.NumOptionalNamedParameters();
// This function requires the same arguments or less and accepts the same
// arguments or more.
if ((num_fixed_params > other_num_fixed_params) ||
(num_fixed_params + num_opt_pos_params <
other_num_fixed_params + other_num_opt_pos_params) ||
(num_opt_named_params < other_num_opt_named_params)) {
return false;
}
// Check the result type.
AbstractType& other_res_type = AbstractType::Handle(other.result_type());
if (!other_res_type.IsInstantiated()) {
other_res_type = other_res_type.InstantiateFrom(other_type_arguments,
malformed_error);
ASSERT((malformed_error == NULL) || malformed_error->IsNull());
}
if (!other_res_type.IsDynamicType() && !other_res_type.IsVoidType()) {
AbstractType& res_type = AbstractType::Handle(result_type());
if (!res_type.IsInstantiated()) {
res_type = res_type.InstantiateFrom(type_arguments, malformed_error);
ASSERT((malformed_error == NULL) || malformed_error->IsNull());
}
if (res_type.IsVoidType()) {
return false;
}
if (test_kind == kIsSubtypeOf) {
if (!res_type.IsSubtypeOf(other_res_type, malformed_error) &&
!other_res_type.IsSubtypeOf(res_type, malformed_error)) {
return false;
}
} else {
ASSERT(test_kind == kIsMoreSpecificThan);
if (!res_type.IsMoreSpecificThan(other_res_type, malformed_error)) {
return false;
}
}
}
// Check the types of fixed and optional positional parameters.
for (intptr_t i = 0;
i < other_num_fixed_params + other_num_opt_pos_params; i++) {
if (!TestParameterType(test_kind,
i, i, type_arguments, other, other_type_arguments,
malformed_error)) {
return false;
}
}
// Check the names and types of optional named parameters.
if (other_num_opt_named_params == 0) {
return true;
}
// Check that for each optional named parameter of type T of the other
// function type, there exists an optional named parameter of this function
// type with an identical name and with a type S that is a either a subtype
// or supertype of T (if test_kind == kIsSubtypeOf) or that is more specific
// than T (if test_kind == kIsMoreSpecificThan).
// Note that SetParameterNameAt() guarantees that names are symbols, so we
// can compare their raw pointers.
const int num_params = num_fixed_params + num_opt_named_params;
const int other_num_params =
other_num_fixed_params + other_num_opt_named_params;
bool found_param_name;
String& other_param_name = String::Handle();
for (intptr_t i = other_num_fixed_params; i < other_num_params; i++) {
other_param_name = other.ParameterNameAt(i);
ASSERT(other_param_name.IsSymbol());
found_param_name = false;
for (intptr_t j = num_fixed_params; j < num_params; j++) {
ASSERT(String::Handle(ParameterNameAt(j)).IsSymbol());
if (ParameterNameAt(j) == other_param_name.raw()) {
found_param_name = true;
if (!TestParameterType(test_kind,
j, i,
type_arguments, other, other_type_arguments,
malformed_error)) {
return false;
}
break;
}
}
if (!found_param_name) {
return false;
}
}
return true;
}
// The compiler generates an implicit constructor if a class definition
// does not contain an explicit constructor or factory. The implicit
// constructor has the same token position as the owner class.
bool Function::IsImplicitConstructor() const {
return IsConstructor() &&
(token_pos() == Class::Handle(Owner()).token_pos());
}
bool Function::IsImplicitClosureFunction() const {
if (!IsClosureFunction()) {
return false;
}
const Function& parent = Function::Handle(parent_function());
return (parent.implicit_closure_function() == raw());
}
RawFunction* Function::New() {
ASSERT(Object::function_class() != Class::null());
RawObject* raw = Object::Allocate(Function::kClassId,
Function::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawFunction*>(raw);
}
RawFunction* Function::New(const String& name,
RawFunction::Kind kind,
bool is_static,
bool is_const,
bool is_abstract,
bool is_external,
const Object& owner,
intptr_t token_pos) {
ASSERT(!owner.IsNull());
const Function& result = Function::Handle(Function::New());
result.set_parameter_types(Object::empty_array());
result.set_parameter_names(Object::empty_array());
result.set_name(name);
result.set_kind(kind);
result.set_is_static(is_static);
result.set_is_const(is_const);
result.set_is_abstract(is_abstract);
result.set_is_external(is_external);
result.set_is_visible(true); // Will be computed later.
result.set_is_intrinsic(false);
result.set_owner(owner);
result.set_token_pos(token_pos);
result.set_end_token_pos(token_pos);
result.set_num_fixed_parameters(0);
result.set_num_optional_parameters(0);
result.set_usage_counter(0);
result.set_deoptimization_counter(0);
result.set_optimized_instruction_count(0);
result.set_optimized_call_site_count(0);
result.set_is_optimizable(true);
result.set_has_finally(false);
result.set_is_native(false);
result.set_is_inlinable(true);
if (kind == RawFunction::kClosureFunction) {
const ClosureData& data = ClosureData::Handle(ClosureData::New());
result.set_data(data);
}
return result.raw();
}
RawFunction* Function::Clone(const Class& new_owner) const {
ASSERT(!IsConstructor());
Function& clone = Function::Handle();
clone ^= Object::Clone(*this, Heap::kOld);
const Class& owner = Class::Handle(this->Owner());
const PatchClass& clone_owner =
PatchClass::Handle(PatchClass::New(new_owner, owner));
clone.set_owner(clone_owner);
clone.StorePointer(&clone.raw_ptr()->code_, Code::null());
clone.StorePointer(&clone.raw_ptr()->unoptimized_code_, Code::null());
clone.set_usage_counter(0);
clone.set_deoptimization_counter(0);
clone.set_optimized_instruction_count(0);
clone.set_optimized_call_site_count(0);
return clone.raw();
}
RawFunction* Function::NewClosureFunction(const String& name,
const Function& parent,
intptr_t token_pos) {
ASSERT(!parent.IsNull());
// Use the owner defining the parent function and not the class containing it.
const Object& parent_owner = Object::Handle(parent.raw_ptr()->owner_);
ASSERT(!parent_owner.IsNull());
const Function& result = Function::Handle(
Function::New(name,
RawFunction::kClosureFunction,
/* is_static = */ parent.is_static(),
/* is_const = */ false,
/* is_abstract = */ false,
/* is_external = */ false,
parent_owner,
token_pos));
result.set_parent_function(parent);
return result.raw();
}
RawFunction* Function::ImplicitClosureFunction() const {
// Return the existing implicit closure function if any.
if (implicit_closure_function() != Function::null()) {
return implicit_closure_function();
}
ASSERT(!IsSignatureFunction() && !IsClosureFunction());
// Create closure function.
const String& closure_name = String::Handle(name());
const Function& closure_function = Function::Handle(
NewClosureFunction(closure_name, *this, token_pos()));
// Set closure function's context scope.
ContextScope& context_scope = ContextScope::Handle();
if (is_static()) {
context_scope = ContextScope::New(0);
} else {
context_scope = LocalScope::CreateImplicitClosureScope(*this);
}
closure_function.set_context_scope(context_scope);
// Set closure function's result type to this result type.
closure_function.set_result_type(AbstractType::Handle(result_type()));
// Set closure function's formal parameters to this formal parameters,
// removing the receiver if this is an instance method and adding the closure
// object as first parameter.
const int kClosure = 1;
const int has_receiver = is_static() ? 0 : 1;
const int num_fixed_params = kClosure - has_receiver + num_fixed_parameters();
const int num_opt_params = NumOptionalParameters();
const bool has_opt_pos_params = HasOptionalPositionalParameters();
const int num_params = num_fixed_params + num_opt_params;
closure_function.set_num_fixed_parameters(num_fixed_params);
closure_function.SetNumOptionalParameters(num_opt_params, has_opt_pos_params);
closure_function.set_parameter_types(Array::Handle(Array::New(num_params,
Heap::kOld)));
closure_function.set_parameter_names(Array::Handle(Array::New(num_params,
Heap::kOld)));
AbstractType& param_type = AbstractType::Handle();
String& param_name = String::Handle();
// Add implicit closure object parameter.
param_type = Type::DynamicType();
closure_function.SetParameterTypeAt(0, param_type);
closure_function.SetParameterNameAt(0, Symbols::ClosureParameter());
for (int i = kClosure; i < num_params; i++) {
param_type = ParameterTypeAt(has_receiver - kClosure + i);
closure_function.SetParameterTypeAt(i, param_type);
param_name = ParameterNameAt(has_receiver - kClosure + i);
closure_function.SetParameterNameAt(i, param_name);
}
// Lookup or create a new signature class for the closure function in the
// library of the owner class.
const Class& owner_class = Class::Handle(Owner());
ASSERT(!owner_class.IsNull() && (Owner() == closure_function.Owner()));
const Library& library = Library::Handle(owner_class.library());
ASSERT(!library.IsNull());
const String& signature = String::Handle(closure_function.Signature());
Class& signature_class = Class::ZoneHandle(
library.LookupLocalClass(signature));
if (signature_class.IsNull()) {
const Script& script = Script::Handle(this->script());
signature_class = Class::NewSignatureClass(signature,
closure_function,
script,
closure_function.token_pos());
library.AddClass(signature_class);
} else {
closure_function.set_signature_class(signature_class);
}
const Type& signature_type = Type::Handle(signature_class.SignatureType());
if (!signature_type.IsFinalized()) {
ClassFinalizer::FinalizeType(
signature_class, signature_type, ClassFinalizer::kCanonicalize);
}
ASSERT(closure_function.signature_class() == signature_class.raw());
set_implicit_closure_function(closure_function);
ASSERT(closure_function.IsImplicitClosureFunction());
return closure_function.raw();
}
RawString* Function::BuildSignature(
bool instantiate,
NameVisibility name_visibility,
const AbstractTypeArguments& instantiator) const {
const GrowableObjectArray& pieces =
GrowableObjectArray::Handle(GrowableObjectArray::New());
String& name = String::Handle();
if (!instantiate && !is_static() && (name_visibility == kInternalName)) {
// Prefix the signature with its signature class and type parameters, if any
// (e.g. "Map<K, V>(K) => bool"). In case of a function type alias, the
// signature class name is the alias name.
// The signature of static functions cannot be type parameterized.
const Class& function_class = Class::Handle(Owner());
ASSERT(!function_class.IsNull());
const TypeArguments& type_parameters = TypeArguments::Handle(
function_class.type_parameters());
if (!type_parameters.IsNull()) {
const String& function_class_name = String::Handle(function_class.Name());
pieces.Add(function_class_name);
intptr_t num_type_parameters = type_parameters.Length();
pieces.Add(Symbols::LAngleBracket());
TypeParameter& type_parameter = TypeParameter::Handle();
AbstractType& bound = AbstractType::Handle();
for (intptr_t i = 0; i < num_type_parameters; i++) {
type_parameter ^= type_parameters.TypeAt(i);
name = type_parameter.name();
pieces.Add(name);
bound = type_parameter.bound();
if (!bound.IsNull() && !bound.IsObjectType()) {
pieces.Add(Symbols::SpaceExtendsSpace());
name = bound.BuildName(name_visibility);
pieces.Add(name);
}
if (i < num_type_parameters - 1) {
pieces.Add(Symbols::CommaSpace());
}
}
pieces.Add(Symbols::RAngleBracket());
}
}
AbstractType& param_type = AbstractType::Handle();
const intptr_t num_params = NumParameters();
const intptr_t num_fixed_params = num_fixed_parameters();
const intptr_t num_opt_pos_params = NumOptionalPositionalParameters();
const intptr_t num_opt_named_params = NumOptionalNamedParameters();
const intptr_t num_opt_params = num_opt_pos_params + num_opt_named_params;
ASSERT((num_fixed_params + num_opt_params) == num_params);
pieces.Add(Symbols::LParen());
intptr_t i = 0;
if (name_visibility == kUserVisibleName) {
// Hide implicit parameters.
i = NumImplicitParameters();
}
while (i < num_fixed_params) {
param_type = ParameterTypeAt(i);
ASSERT(!param_type.IsNull());
if (instantiate && !param_type.IsInstantiated()) {
param_type = param_type.InstantiateFrom(instantiator, NULL);
}
name = param_type.BuildName(name_visibility);
pieces.Add(name);
if (i != (num_params - 1)) {
pieces.Add(Symbols::CommaSpace());
}
i++;
}
if (num_opt_params > 0) {
if (num_opt_pos_params > 0) {
pieces.Add(Symbols::LBracket());
} else {
pieces.Add(Symbols::LBrace());
}
for (intptr_t i = num_fixed_params; i < num_params; i++) {
// The parameter name of an optional positional parameter does not need
// to be part of the signature, since it is not used.
if (num_opt_named_params > 0) {
name = ParameterNameAt(i);
pieces.Add(name);
pieces.Add(Symbols::ColonSpace());
}
param_type = ParameterTypeAt(i);
if (instantiate && !param_type.IsInstantiated()) {
param_type = param_type.InstantiateFrom(instantiator, NULL);
}
ASSERT(!param_type.IsNull());
name = param_type.BuildName(name_visibility);
pieces.Add(name);
if (i != (num_params - 1)) {
pieces.Add(Symbols::CommaSpace());
}
}
if (num_opt_pos_params > 0) {
pieces.Add(Symbols::RBracket());
} else {
pieces.Add(Symbols::RBrace());
}
}
pieces.Add(Symbols::RParenArrow());
AbstractType& res_type = AbstractType::Handle(result_type());
if (instantiate && !res_type.IsInstantiated()) {
res_type = res_type.InstantiateFrom(instantiator, NULL);
}
name = res_type.BuildName(name_visibility);
pieces.Add(name);
const Array& strings = Array::Handle(Array::MakeArray(pieces));
return Symbols::New(String::Handle(String::ConcatAll(strings)));
}
bool Function::HasInstantiatedSignature() const {
AbstractType& type = AbstractType::Handle(result_type());
if (!type.IsInstantiated()) {
return false;
}
const intptr_t num_parameters = NumParameters();
for (intptr_t i = 0; i < num_parameters; i++) {
type = ParameterTypeAt(i);
if (!type.IsInstantiated()) {
return false;
}
}
return true;
}
RawClass* Function::Owner() const {
const Object& obj = Object::Handle(raw_ptr()->owner_);
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
ASSERT(obj.IsPatchClass());
return PatchClass::Cast(obj).patched_class();
}
RawClass* Function::origin() const {
const Object& obj = Object::Handle(raw_ptr()->owner_);
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
ASSERT(obj.IsPatchClass());
return PatchClass::Cast(obj).source_class();
}
RawScript* Function::script() const {
const Object& obj = Object::Handle(raw_ptr()->owner_);
if (obj.IsClass()) {
return Class::Cast(obj).script();
}
ASSERT(obj.IsPatchClass());
return PatchClass::Cast(obj).Script();
}
bool Function::HasOptimizedCode() const {
return HasCode() && Code::Handle(raw_ptr()->code_).is_optimized();
}
RawString* Function::UserVisibleName() const {
const String& str = String::Handle(name());
return IdentifierPrettyName(str);
}
RawString* Function::QualifiedUserVisibleName() const {
String& tmp = String::Handle();
const Class& cls = Class::Handle(Owner());
if (IsClosureFunction()) {
if (IsLocalFunction()) {
const Function& parent = Function::Handle(parent_function());
tmp = parent.QualifiedUserVisibleName();
} else {
return UserVisibleName();
}
} else {
if (cls.IsTopLevel()) {
return UserVisibleName();
} else {
tmp = cls.UserVisibleName();
}
}
tmp = String::Concat(tmp, Symbols::Dot());
const String& suffix = String::Handle(UserVisibleName());
return String::Concat(tmp, suffix);
}
// Construct fingerprint from token stream. The token stream contains also
// arguments.
int32_t Function::SourceFingerprint() const {
uint32_t result = String::Handle(Signature()).Hash();
TokenStream::Iterator tokens_iterator(TokenStream::Handle(
Script::Handle(script()).tokens()), token_pos());
Object& obj = Object::Handle();
String& literal = String::Handle();
while (tokens_iterator.CurrentPosition() < end_token_pos()) {
uint32_t val = 0;
obj = tokens_iterator.CurrentToken();
if (obj.IsSmi()) {
val = Smi::Cast(obj).Value();
} else {
literal = tokens_iterator.MakeLiteralToken(obj);
val = literal.Hash();
}
result = 31 * result + val;
tokens_iterator.Advance();
}
result = result & ((static_cast<uint32_t>(1) << 31) - 1);
ASSERT(result <= static_cast<uint32_t>(kMaxInt32));
return result;
}
bool Function::CheckSourceFingerprint(int32_t fp) const {
if (SourceFingerprint() != fp) {
const bool recalculatingFingerprints = false;
if (recalculatingFingerprints) {
// This output can be copied into a file, then used with sed
// to replace the old values.
// sed -i .bak -f /tmp/newkeys runtime/vm/intrinsifier.h
OS::Print("s/%d/%d/\n", fp, SourceFingerprint());
} else {
OS::Print("FP mismatch while recognizing method %s:"
" expecting %d found %d\n",
ToFullyQualifiedCString(),
fp,
SourceFingerprint());
return false;
}
}
return true;
}
const char* Function::ToCString() const {
const char* static_str = is_static() ? " static" : "";
const char* abstract_str = is_abstract() ? " abstract" : "";
const char* kind_str = NULL;
const char* const_str = is_const() ? " const" : "";
switch (kind()) {
case RawFunction::kRegularFunction:
case RawFunction::kClosureFunction:
case RawFunction::kGetterFunction:
case RawFunction::kSetterFunction:
kind_str = "";
break;
case RawFunction::kSignatureFunction:
kind_str = " signature";
break;
case RawFunction::kConstructor:
kind_str = is_static() ? " factory" : " constructor";
break;
case RawFunction::kImplicitGetter:
kind_str = " getter";
break;
case RawFunction::kImplicitSetter:
kind_str = " setter";
break;
case RawFunction::kConstImplicitGetter:
kind_str = " const-getter";
break;
case RawFunction::kMethodExtractor:
kind_str = " method-extractor";
break;
default:
UNREACHABLE();
}
const char* kFormat = "Function '%s':%s%s%s%s.";
const char* function_name = String::Handle(name()).ToCString();
intptr_t len = OS::SNPrint(NULL, 0, kFormat, function_name,
static_str, abstract_str, kind_str, const_str) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, function_name,
static_str, abstract_str, kind_str, const_str);
return chars;
}
void ClosureData::set_context_scope(const ContextScope& value) const {
StorePointer(&raw_ptr()->context_scope_, value.raw());
}
void ClosureData::set_implicit_static_closure(const Instance& closure) const {
ASSERT(!closure.IsNull());
ASSERT(raw_ptr()->closure_ == Instance::null());
StorePointer(&raw_ptr()->closure_, closure.raw());
}
void ClosureData::set_closure_allocation_stub(const Code& value) const {
ASSERT(!value.IsNull());
ASSERT(raw_ptr()->closure_allocation_stub_ == Code::null());
StorePointer(&raw_ptr()->closure_allocation_stub_, value.raw());
}
void ClosureData::set_parent_function(const Function& value) const {
StorePointer(&raw_ptr()->parent_function_, value.raw());
}
void ClosureData::set_signature_class(const Class& value) const {
StorePointer(&raw_ptr()->signature_class_, value.raw());
}
RawClosureData* ClosureData::New() {
ASSERT(Object::closure_data_class() != Class::null());
RawObject* raw = Object::Allocate(ClosureData::kClassId,
ClosureData::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawClosureData*>(raw);
}
const char* ClosureData::ToCString() const {
return "ClosureData class";
}
void RedirectionData::set_type(const Type& value) const {
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->type_, value.raw());
}
void RedirectionData::set_identifier(const String& value) const {
StorePointer(&raw_ptr()->identifier_, value.raw());
}
void RedirectionData::set_target(const Function& value) const {
StorePointer(&raw_ptr()->target_, value.raw());
}
RawRedirectionData* RedirectionData::New() {
ASSERT(Object::redirection_data_class() != Class::null());
RawObject* raw = Object::Allocate(RedirectionData::kClassId,
RedirectionData::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawRedirectionData*>(raw);
}
const char* RedirectionData::ToCString() const {
return "RedirectionData class";
}
RawString* Field::GetterName(const String& field_name) {
return String::Concat(Symbols::GetterPrefix(), field_name);
}
RawString* Field::GetterSymbol(const String& field_name) {
const String& str = String::Handle(Field::GetterName(field_name));
return Symbols::New(str);
}
RawString* Field::SetterName(const String& field_name) {
return String::Concat(Symbols::SetterPrefix(), field_name);
}
RawString* Field::SetterSymbol(const String& field_name) {
const String& str = String::Handle(Field::SetterName(field_name));
return Symbols::New(str);
}
RawString* Field::NameFromGetter(const String& getter_name) {
return String::SubString(getter_name, strlen(kGetterPrefix));
}
RawString* Field::NameFromSetter(const String& setter_name) {
return String::SubString(setter_name, strlen(kSetterPrefix));
}
bool Field::IsGetterName(const String& function_name) {
return function_name.StartsWith(Symbols::GetterPrefix());
}
bool Field::IsSetterName(const String& function_name) {
return function_name.StartsWith(Symbols::SetterPrefix());
}
void Field::set_name(const String& value) const {
ASSERT(value.IsSymbol());
StorePointer(&raw_ptr()->name_, value.raw());
}
RawClass* Field::owner() const {
const Object& obj = Object::Handle(raw_ptr()->owner_);
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
ASSERT(obj.IsPatchClass());
return PatchClass::Cast(obj).patched_class();
}
RawClass* Field::origin() const {
const Object& obj = Object::Handle(raw_ptr()->owner_);
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
ASSERT(obj.IsPatchClass());
return PatchClass::Cast(obj).source_class();
}
RawInstance* Field::value() const {
ASSERT(is_static()); // Valid only for static dart fields.
return raw_ptr()->value_;
}
void Field::set_value(const Instance& value) const {
ASSERT(is_static()); // Valid only for static dart fields.
StorePointer(&raw_ptr()->value_, value.raw());
}
void Field::set_type(const AbstractType& value) const {
ASSERT(!value.IsNull());
StorePointer(&raw_ptr()->type_, value.raw());
}
RawField* Field::New() {
ASSERT(Object::field_class() != Class::null());
RawObject* raw = Object::Allocate(Field::kClassId,
Field::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawField*>(raw);
}
RawField* Field::New(const String& name,
bool is_static,
bool is_final,
bool is_const,
const Class& owner,
intptr_t token_pos) {
ASSERT(!owner.IsNull());
const Field& result = Field::Handle(Field::New());
result.set_name(name);
result.set_is_static(is_static);
if (is_static) {
result.set_value(Object::null_instance());
} else {
result.SetOffset(0);
}
result.set_is_final(is_final);
result.set_is_const(is_const);
result.set_owner(owner);
result.set_token_pos(token_pos);
result.set_has_initializer(false);
result.set_guarded_cid(kIllegalCid);
result.set_is_nullable(false);
result.set_dependent_code(Object::null_array());
return result.raw();
}
RawField* Field::Clone(const Class& new_owner) const {
Field& clone = Field::Handle();
clone ^= Object::Clone(*this, Heap::kOld);
const Class& owner = Class::Handle(this->owner());
const PatchClass& clone_owner =
PatchClass::Handle(PatchClass::New(new_owner, owner));
clone.set_owner(clone_owner);
clone.set_dependent_code(Object::null_array());
if (!clone.is_static()) {
clone.SetOffset(0);
}
return clone.raw();
}
RawString* Field::UserVisibleName() const {
const String& str = String::Handle(name());
return IdentifierPrettyName(str);
}
const char* Field::ToCString() const {
if (IsNull()) {
return "Field::null";
}
const char* kF0 = is_static() ? " static" : "";
const char* kF1 = is_final() ? " final" : "";
const char* kF2 = is_const() ? " const" : "";
const char* kFormat = "Field <%s.%s>:%s%s%s";
const char* field_name = String::Handle(name()).ToCString();
const Class& cls = Class::Handle(owner());
const char* cls_name = String::Handle(cls.Name()).ToCString();
intptr_t len =
OS::SNPrint(NULL, 0, kFormat, cls_name, field_name, kF0, kF1, kF2) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, cls_name, field_name, kF0, kF1, kF2);
return chars;
}
RawArray* Field::dependent_code() const {
return raw_ptr()->dependent_code_;
}
void Field::set_dependent_code(const Array& array) const {
raw_ptr()->dependent_code_ = array.raw();
}
void Field::RegisterDependentCode(const Code& code) const {
const Array& dependent = Array::Handle(dependent_code());
if (!dependent.IsNull()) {
// Try to find and reuse cleared WeakProperty to avoid allocating new one.
WeakProperty& weak_property = WeakProperty::Handle();
for (intptr_t i = 0; i < dependent.Length(); i++) {
weak_property ^= dependent.At(i);
if (weak_property.key() == Code::null()) {
// Empty property found. Reuse it.
weak_property.set_key(code);
return;
}
}
}
const WeakProperty& weak_property = WeakProperty::Handle(
WeakProperty::New(Heap::kOld));
weak_property.set_key(code);
intptr_t length = dependent.IsNull() ? 0 : dependent.Length();
const Array& new_dependent = Array::Handle(
Array::Grow(dependent, length + 1, Heap::kOld));
new_dependent.SetAt(length, weak_property);
set_dependent_code(new_dependent);
}
static bool IsDependentCode(const Array& dependent_code, const Code& code) {
if (!code.is_optimized()) {
return false;
}
WeakProperty& weak_property = WeakProperty::Handle();
for (intptr_t i = 0; i < dependent_code.Length(); i++) {
weak_property ^= dependent_code.At(i);
if (code.raw() == weak_property.key()) {
return true;
}
}
return false;
}
void Field::DeoptimizeDependentCode() const {
const Array& code_objects = Array::Handle(dependent_code());
if (code_objects.IsNull()) {
return;
}
set_dependent_code(Object::null_array());
// Deoptimize all dependent code on the stack.
Code& code = Code::Handle();
{
DartFrameIterator iterator;
StackFrame* frame = iterator.NextFrame();
while (frame != NULL) {
code = frame->LookupDartCode();
if (IsDependentCode(code_objects, code)) {
DeoptimizeAt(code, frame->pc());
}
frame = iterator.NextFrame();
}
}
// Switch functions that use dependent code to unoptimized code.
WeakProperty& weak_property = WeakProperty::Handle();
Function& function = Function::Handle();
for (intptr_t i = 0; i < code_objects.Length(); i++) {
weak_property ^= code_objects.At(i);
code ^= weak_property.key();
if (code.IsNull()) {
// Code was garbage collected already.
continue;
}
function ^= code.function();
// If function uses dependent code switch it to unoptimized.
if (function.CurrentCode() == code.raw()) {
ASSERT(function.HasOptimizedCode());
function.SwitchToUnoptimizedCode();
}
}
}
void Field::UpdateCid(intptr_t cid) const {
if (guarded_cid() == kIllegalCid) {
// Field is assigned first time.
set_guarded_cid(cid);
set_is_nullable(cid == kNullCid);
return;
}
if ((cid == guarded_cid()) || ((cid == kNullCid) && is_nullable())) {
// Class id of the assigned value matches expected class id and nullability.
return;
}
if ((cid == kNullCid) && !is_nullable()) {
// Assigning null value to a non-nullable field makes it nullable.
set_is_nullable(true);
} else if ((cid != kNullCid) && (guarded_cid() == kNullCid)) {
// Assigning non-null value to a field that previously contained only null
// turns it into a nullable field with the given class id.
ASSERT(is_nullable());
set_guarded_cid(cid);
} else {
// Give up on tracking class id of values contained in this field.
ASSERT(guarded_cid() != cid);
set_guarded_cid(kDynamicCid);
set_is_nullable(true);
}
// Expected class id or nullability of the field changed.
DeoptimizeDependentCode();
}
void LiteralToken::set_literal(const String& literal) const {
StorePointer(&raw_ptr()->literal_, literal.raw());
}
void LiteralToken::set_value(const Object& value) const {
StorePointer(&raw_ptr()->value_, value.raw());
}
RawLiteralToken* LiteralToken::New() {
ASSERT(Object::literal_token_class() != Class::null());
RawObject* raw = Object::Allocate(LiteralToken::kClassId,
LiteralToken::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawLiteralToken*>(raw);
}
RawLiteralToken* LiteralToken::New(Token::Kind kind, const String& literal) {
const LiteralToken& result = LiteralToken::Handle(LiteralToken::New());
result.set_kind(kind);
result.set_literal(literal);
if (kind == Token::kINTEGER) {
const Integer& value = Integer::Handle(Integer::NewCanonical(literal));
ASSERT(value.IsSmi() || value.IsOld());
result.set_value(value);
} else if (kind == Token::kDOUBLE) {
const Double& value = Double::Handle(Double::NewCanonical(literal));
result.set_value(value);
} else {
ASSERT(Token::NeedsLiteralToken(kind));
result.set_value(literal);
}
return result.raw();
}
const char* LiteralToken::ToCString() const {
const String& token = String::Handle(literal());
return token.ToCString();
}
RawArray* TokenStream::TokenObjects() const {
return raw_ptr()->token_objects_;
}
void TokenStream::SetTokenObjects(const Array& value) const {
StorePointer(&raw_ptr()->token_objects_, value.raw());
}
RawExternalTypedData* TokenStream::GetStream() const {
return raw_ptr()->stream_;
}
void TokenStream::SetStream(const ExternalTypedData& value) const {
StorePointer(&raw_ptr()->stream_, value.raw());
}
void TokenStream::DataFinalizer(Dart_WeakPersistentHandle handle, void *peer) {
ASSERT(peer != NULL);
::free(peer);
DeleteWeakPersistentHandle(handle);
}
RawString* TokenStream::PrivateKey() const {
return raw_ptr()->private_key_;
}
void TokenStream::SetPrivateKey(const String& value) const {
StorePointer(&raw_ptr()->private_key_, value.raw());
}
RawString* TokenStream::GenerateSource() const {
Iterator iterator(*this, 0);
const ExternalTypedData& data = ExternalTypedData::Handle(GetStream());
const GrowableObjectArray& literals =
GrowableObjectArray::Handle(GrowableObjectArray::New(data.Length()));
const String& private_key = String::Handle(PrivateKey());
intptr_t private_len = private_key.Length();
Token::Kind curr = iterator.CurrentTokenKind();
Token::Kind prev = Token::kILLEGAL;
// Handles used in the loop.
Object& obj = Object::Handle();
String& literal = String::Handle();
// Current indentation level.
int indent = 0;
while (curr != Token::kEOS) {
// Remember current values for this token.
obj = iterator.CurrentToken();
literal = iterator.MakeLiteralToken(obj);
// Advance to be able to use next token kind.
iterator.Advance();
Token::Kind next = iterator.CurrentTokenKind();
// Handle the current token.
if (curr == Token::kSTRING) {
bool escape_characters = false;
for (intptr_t i = 0; i < literal.Length(); i++) {
if (IsSpecialCharacter(literal.CharAt(i))) {
escape_characters = true;
}
}
if ((prev != Token::kINTERPOL_VAR) && (prev != Token::kINTERPOL_END)) {
literals.Add(Symbols::DoubleQuotes());
}
if (escape_characters) {
literal = String::EscapeSpecialCharacters(literal);
literals.Add(literal);
} else {
literals.Add(literal);
}
if ((next != Token::kINTERPOL_VAR) && (next != Token::kINTERPOL_START)) {
literals.Add(Symbols::DoubleQuotes());
}
} else if (curr == Token::kINTERPOL_VAR) {
literals.Add(Symbols::Dollar());
if (literal.CharAt(0) == Scanner::kPrivateIdentifierStart) {
literal = String::SubString(literal, 0, literal.Length() - private_len);
}
literals.Add(literal);
} else if (curr == Token::kIDENT) {
if (literal.CharAt(0) == Scanner::kPrivateIdentifierStart) {
literal = String::SubString(literal, 0, literal.Length() - private_len);
}
literals.Add(literal);
} else {
literals.Add(literal);
}
// Determine the separation text based on this current token.
const String* separator = NULL;
switch (curr) {
case Token::kLBRACE:
indent++;
separator = &Symbols::NewLine();
break;
case Token::kRBRACE:
if (indent == 0) {
separator = &Symbols::TwoNewlines();
} else {
separator = &Symbols::NewLine();
}
break;
case Token::kSEMICOLON:
separator = &Symbols::NewLine();
break;
case Token::kPERIOD:
case Token::kLPAREN:
case Token::kLBRACK:
case Token::kTIGHTADD:
case Token::kINTERPOL_VAR:
case Token::kINTERPOL_START:
case Token::kINTERPOL_END:
break;
default:
separator = &Symbols::Blank();
break;
}
// Determine whether the separation text needs to be updated based on the
// next token.
switch (next) {
case Token::kRBRACE:
indent--;
break;
case Token::kSEMICOLON:
case Token::kPERIOD:
case Token::kCOMMA:
case Token::kLPAREN:
case Token::kRPAREN:
case Token::kLBRACK:
case Token::kRBRACK:
case Token::kINTERPOL_VAR:
case Token::kINTERPOL_START:
case Token::kINTERPOL_END:
separator = NULL;
break;
case Token::kELSE:
separator = &Symbols::Blank();
default:
// Do nothing.
break;
}
// Update the few cases where both tokens need to be taken into account.
if (((curr == Token::kIF) || (curr == Token::kFOR)) &&
(next == Token::kLPAREN)) {
separator = &Symbols::Blank();
} else if ((curr == Token::kASSIGN) && (next == Token::kLPAREN)) {
separator = &Symbols::Blank();
} else if ((curr == Token::kLBRACE) && (next == Token::kRBRACE)) {
separator = NULL;
}
if (separator != NULL) {
literals.Add(*separator);
if (separator == &Symbols::NewLine()) {
for (int i = 0; i < indent; i++) {
literals.Add(Symbols::TwoSpaces());
}
}
}
// Setup for next iteration.
prev = curr;
curr = next;
}
const Array& source = Array::Handle(Array::MakeArray(literals));
return String::ConcatAll(source);
}
intptr_t TokenStream::ComputeSourcePosition(intptr_t tok_pos) const {
Iterator iterator(*this, 0);
intptr_t src_pos = 0;
Token::Kind kind = iterator.CurrentTokenKind();
while (iterator.CurrentPosition() < tok_pos && kind != Token::kEOS) {
iterator.Advance();
kind = iterator.CurrentTokenKind();
src_pos += 1;
}
return src_pos;
}
intptr_t TokenStream::ComputeTokenPosition(intptr_t src_pos) const {
Iterator iterator(*this, 0);
intptr_t index = 0;
Token::Kind kind = iterator.CurrentTokenKind();
while (index < src_pos && kind != Token::kEOS) {
iterator.Advance();
kind = iterator.CurrentTokenKind();
index += 1;
}
return iterator.CurrentPosition();
}
RawTokenStream* TokenStream::New() {
ASSERT(Object::token_stream_class() != Class::null());
RawObject* raw = Object::Allocate(TokenStream::kClassId,
TokenStream::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawTokenStream*>(raw);
}
RawTokenStream* TokenStream::New(intptr_t len) {
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in TokenStream::New: invalid len %"Pd"\n", len);
}
uint8_t* data = reinterpret_cast<uint8_t*>(::malloc(len));
ASSERT(data != NULL);
const ExternalTypedData& stream = ExternalTypedData::Handle(
ExternalTypedData::New(kExternalTypedDataUint8ArrayCid,
data, len, Heap::kOld));
stream.AddFinalizer(data, DataFinalizer);
const TokenStream& result = TokenStream::Handle(TokenStream::New());
result.SetStream(stream);
return result.raw();
}
// Helper class for creation of compressed token stream data.
class CompressedTokenStreamData : public ValueObject {
public:
static const intptr_t kInitialSize = 16 * KB;
CompressedTokenStreamData() :
buffer_(NULL),
stream_(&buffer_, Reallocate, kInitialSize),
token_objects_(GrowableObjectArray::Handle(
GrowableObjectArray::New(kInitialTokenCount, Heap::kOld))),
token_obj_(Object::Handle()),
literal_token_(LiteralToken::Handle()),
literal_str_(String::Handle()) {
const String& empty_literal = String::Handle();
token_objects_.Add(empty_literal);
}
~CompressedTokenStreamData() {
}
// Add an IDENT token into the stream and the token objects array.
void AddIdentToken(String* ident) {
if (ident != NULL) {
// If the IDENT token is already in the tokens object array use the
// same index instead of duplicating it.
intptr_t index = FindIdentIndex(ident);
if (index == -1) {
WriteIndex(token_objects_.Length());
ASSERT(ident != NULL);
token_objects_.Add(*ident);
} else {
WriteIndex(index);
}
} else {
WriteIndex(0);
}
}
// Add a LITERAL token into the stream and the token objects array.
void AddLiteralToken(Token::Kind kind, String* literal) {
if (literal != NULL) {
// If the literal token is already in the tokens object array use the
// same index instead of duplicating it.
intptr_t index = FindLiteralIndex(kind, literal);
if (index == -1) {
WriteIndex(token_objects_.Length());
ASSERT(literal != NULL);
literal_token_ = LiteralToken::New(kind, *literal);
token_objects_.Add(literal_token_);
} else {
WriteIndex(index);
}
} else {
WriteIndex(0);
}
}
// Add a simple token into the stream.
void AddSimpleToken(intptr_t kind) {
stream_.WriteUnsigned(kind);
}
// Return the compressed token stream.
uint8_t* GetStream() const { return buffer_; }
// Return the compressed token stream length.
intptr_t Length() const { return stream_.bytes_written(); }
// Return the token objects array.
const GrowableObjectArray& TokenObjects() const {
return token_objects_;
}
private:
intptr_t FindIdentIndex(String* ident) {
ASSERT(ident != NULL);
intptr_t hash_value = ident->Hash() % kTableSize;
GrowableArray<intptr_t>& value = ident_table_[hash_value];
for (intptr_t i = 0; i < value.length(); i++) {
intptr_t index = value[i];
token_obj_ = token_objects_.At(index);
if (token_obj_.IsString()) {
const String& ident_str = String::Cast(token_obj_);
if (ident->Equals(ident_str)) {
return index;
}
}
}
value.Add(token_objects_.Length());
return -1;
}
intptr_t FindLiteralIndex(Token::Kind kind, String* literal) {
ASSERT(literal != NULL);
intptr_t hash_value = literal->Hash() % kTableSize;
GrowableArray<intptr_t>& value = literal_table_[hash_value];
for (intptr_t i = 0; i < value.length(); i++) {
intptr_t index = value[i];
token_obj_ = token_objects_.At(index);
if (token_obj_.IsLiteralToken()) {
const LiteralToken& token = LiteralToken::Cast(token_obj_);
literal_str_ = token.literal();
if (kind == token.kind() && literal->Equals(literal_str_)) {
return index;
}
}
}
value.Add(token_objects_.Length());
return -1;
}
void WriteIndex(intptr_t value) {
stream_.WriteUnsigned(value + Token::kNumTokens);
}
static uint8_t* Reallocate(uint8_t* ptr,
intptr_t old_size,
intptr_t new_size) {
void* new_ptr = ::realloc(reinterpret_cast<void*>(ptr), new_size);
return reinterpret_cast<uint8_t*>(new_ptr);
}
static const int kInitialTokenCount = 32;
static const intptr_t kTableSize = 128;
uint8_t* buffer_;
WriteStream stream_;
GrowableArray<intptr_t> ident_table_[kTableSize];
GrowableArray<intptr_t> literal_table_[kTableSize];
const GrowableObjectArray& token_objects_;
Object& token_obj_;
LiteralToken& literal_token_;
String& literal_str_;
DISALLOW_COPY_AND_ASSIGN(CompressedTokenStreamData);
};
RawTokenStream* TokenStream::New(const Scanner::GrowableTokenStream& tokens,
const String& private_key) {
// Copy the relevant data out of the scanner into a compressed stream of
// tokens.
CompressedTokenStreamData data;
intptr_t len = tokens.length();
for (intptr_t i = 0; i < len; i++) {
Scanner::TokenDescriptor token = tokens[i];
if (token.kind == Token::kIDENT) { // Identifier token.
if (FLAG_compiler_stats) {
CompilerStats::num_ident_tokens_total += 1;
}
data.AddIdentToken(token.literal);
} else if (Token::NeedsLiteralToken(token.kind)) { // Literal token.
if (FLAG_compiler_stats) {
CompilerStats::num_literal_tokens_total += 1;
}
data.AddLiteralToken(token.kind, token.literal);
} else { // Keyword, pseudo keyword etc.
ASSERT(token.kind < Token::kNumTokens);
data.AddSimpleToken(token.kind);
}
}
if (FLAG_compiler_stats) {
CompilerStats::num_tokens_total += len;
}
data.AddSimpleToken(Token::kEOS); // End of stream.
// Create and setup the token stream object.
const ExternalTypedData& stream = ExternalTypedData::Handle(
ExternalTypedData::New(kExternalTypedDataUint8ArrayCid,
data.GetStream(), data.Length(), Heap::kOld));
stream.AddFinalizer(data.GetStream(), DataFinalizer);
const TokenStream& result = TokenStream::Handle(New());
result.SetPrivateKey(private_key);
{
NoGCScope no_gc;
result.SetStream(stream);
const Array& tokens = Array::Handle(Array::MakeArray(data.TokenObjects()));
result.SetTokenObjects(tokens);
}
return result.raw();
}
const char* TokenStream::ToCString() const {
return "TokenStream";
}
TokenStream::Iterator::Iterator(const TokenStream& tokens, intptr_t token_pos)
: tokens_(TokenStream::Handle(tokens.raw())),
data_(ExternalTypedData::Handle(tokens.GetStream())),
stream_(reinterpret_cast<uint8_t*>(data_.DataAddr(0)), data_.Length()),
token_objects_(Array::Handle(tokens.TokenObjects())),
obj_(Object::Handle()),
cur_token_pos_(token_pos),
cur_token_kind_(Token::kILLEGAL),
cur_token_obj_index_(-1) {
SetCurrentPosition(token_pos);
}
void TokenStream::Iterator::SetStream(const TokenStream& tokens,
intptr_t token_pos) {
tokens_ = tokens.raw();
data_ = tokens.GetStream();
stream_.SetStream(reinterpret_cast<uint8_t*>(data_.DataAddr(0)),
data_.Length());
token_objects_ = tokens.TokenObjects();
obj_ = Object::null();
cur_token_pos_ = token_pos;
cur_token_kind_ = Token::kILLEGAL;
cur_token_obj_index_ = -1;
SetCurrentPosition(token_pos);
}
bool TokenStream::Iterator::IsValid() const {
return !tokens_.IsNull();
}
Token::Kind TokenStream::Iterator::LookaheadTokenKind(intptr_t num_tokens) {
intptr_t saved_position = stream_.Position();
Token::Kind kind = Token::kILLEGAL;
intptr_t value = -1;
intptr_t count = 0;
while (count < num_tokens && value != Token::kEOS) {
value = ReadToken();
count += 1;
}
if (value < Token::kNumTokens) {
kind = static_cast<Token::Kind>(value);
} else {
value = value - Token::kNumTokens;
obj_ = token_objects_.At(value);
if (obj_.IsLiteralToken()) {
const LiteralToken& literal_token = LiteralToken::Cast(obj_);
kind = literal_token.kind();
} else {
ASSERT(obj_.IsString()); // Must be an identifier.
kind = Token::kIDENT;
}
}
stream_.SetPosition(saved_position);
return kind;
}
intptr_t TokenStream::Iterator::CurrentPosition() const {
return cur_token_pos_;
}
void TokenStream::Iterator::SetCurrentPosition(intptr_t value) {
stream_.SetPosition(value);
Advance();
}
void TokenStream::Iterator::Advance() {
cur_token_pos_ = stream_.Position();
intptr_t value = ReadToken();
if (value < Token::kNumTokens) {
cur_token_kind_ = static_cast<Token::Kind>(value);
cur_token_obj_index_ = -1;
return;
}
cur_token_obj_index_ = value - Token::kNumTokens;
obj_ = token_objects_.At(cur_token_obj_index_);
if (obj_.IsLiteralToken()) {
const LiteralToken& literal_token = LiteralToken::Cast(obj_);
cur_token_kind_ = literal_token.kind();
return;
}
ASSERT(obj_.IsString()); // Must be an identifier.
cur_token_kind_ = Token::kIDENT;
}
RawObject* TokenStream::Iterator::CurrentToken() const {
if (cur_token_obj_index_ != -1) {
return token_objects_.At(cur_token_obj_index_);
} else {
return Smi::New(cur_token_kind_);
}
}
RawString* TokenStream::Iterator::CurrentLiteral() const {
obj_ = CurrentToken();
return MakeLiteralToken(obj_);
}
RawString* TokenStream::Iterator::MakeLiteralToken(const Object& obj) const {
if (obj.IsString()) {
return reinterpret_cast<RawString*>(obj.raw());
} else if (obj.IsSmi()) {
Token::Kind kind = static_cast<Token::Kind>(
Smi::Value(reinterpret_cast<RawSmi*>(obj.raw())));
ASSERT(kind < Token::kNumTokens);
if (Token::IsPseudoKeyword(kind) || Token::IsKeyword(kind)) {
Isolate* isolate = Isolate::Current();
ObjectStore* object_store = isolate->object_store();
const Array& symbols = Array::Handle(isolate,
object_store->keyword_symbols());
ASSERT(!symbols.IsNull());
ASSERT(symbols.At(kind - Token::kFirstKeyword) != Object::null());
return String::RawCast(symbols.At(kind - Token::kFirstKeyword));
}
return Symbols::New(Token::Str(kind));
} else {
ASSERT(obj.IsLiteralToken()); // Must be a literal token.
const LiteralToken& literal_token = LiteralToken::Cast(obj);
return literal_token.literal();
}
}
bool Script::HasSource() const {
return raw_ptr()->source_ != String::null();
}
RawString* Script::Source() const {
String& source = String::Handle(raw_ptr()->source_);
if (source.IsNull()) {
return GenerateSource();
}
return raw_ptr()->source_;
}
RawString* Script::GenerateSource() const {
const TokenStream& token_stream = TokenStream::Handle(tokens());
return token_stream.GenerateSource();
}
void Script::set_url(const String& value) const {
StorePointer(&raw_ptr()->url_, value.raw());
}
void Script::set_source(const String& value) const {
StorePointer(&raw_ptr()->source_, value.raw());
}
void Script::set_kind(RawScript::Kind value) const {
raw_ptr()->kind_ = value;
}
void Script::set_tokens(const TokenStream& value) const {
StorePointer(&raw_ptr()->tokens_, value.raw());
}
void Script::Tokenize(const String& private_key) const {
const TokenStream& tkns = TokenStream::Handle(tokens());
if (!tkns.IsNull()) {
// Already tokenized.
return;
}
// Get the source, scan and allocate the token stream.
TimerScope timer(FLAG_compiler_stats, &CompilerStats::scanner_timer);
const String& src = String::Handle(Source());
Scanner scanner(src, private_key);
set_tokens(TokenStream::Handle(TokenStream::New(scanner.GetStream(),
private_key)));
if (FLAG_compiler_stats) {
CompilerStats::src_length += src.Length();
}
}
void Script::SetLocationOffset(intptr_t line_offset,
intptr_t col_offset) const {
ASSERT(line_offset >= 0);
ASSERT(col_offset >= 0);
raw_ptr()->line_offset_ = line_offset;
raw_ptr()->col_offset_ = col_offset;
}
void Script::GetTokenLocation(intptr_t token_pos,
intptr_t* line,
intptr_t* column) const {
const String& src = String::Handle(Source());
const TokenStream& tkns = TokenStream::Handle(tokens());
intptr_t src_pos = tkns.ComputeSourcePosition(token_pos);
Scanner scanner(src, Symbols::Empty());
scanner.ScanTo(src_pos);
intptr_t relative_line = scanner.CurrentPosition().line;
*line = relative_line + line_offset();
*column = scanner.CurrentPosition().column;
// On the first line of the script we must add the column offset.
if (relative_line == 1) {
*column += col_offset();
}
}
void Script::TokenRangeAtLine(intptr_t line_number,
intptr_t* first_token_index,
intptr_t* last_token_index) const {
const String& src = String::Handle(Source());
const TokenStream& tkns = TokenStream::Handle(tokens());
line_number -= line_offset();
if (line_number < 1) line_number = 1;
Scanner scanner(src, Symbols::Empty());
scanner.TokenRangeAtLine(line_number, first_token_index, last_token_index);
if (*first_token_index >= 0) {
*first_token_index = tkns.ComputeTokenPosition(*first_token_index);
}
if (*last_token_index >= 0) {
*last_token_index = tkns.ComputeTokenPosition(*last_token_index);
}
}
RawString* Script::GetLine(intptr_t line_number) const {
const String& src = String::Handle(Source());
intptr_t relative_line_number = line_number - line_offset();
intptr_t current_line = 1;
intptr_t line_start_idx = -1;
intptr_t last_char_idx = -1;
for (intptr_t ix = 0;
(ix < src.Length()) && (current_line <= relative_line_number);
ix++) {
if ((current_line == relative_line_number) && (line_start_idx < 0)) {
line_start_idx = ix;
}
if (src.CharAt(ix) == '\n') {
current_line++;
} else if (src.CharAt(ix) == '\r') {
if ((ix + 1 != src.Length()) && (src.CharAt(ix + 1) != '\n')) {
current_line++;
}
} else {
last_char_idx = ix;
}
}
// Guarantee that returned string is never NULL.
if (line_start_idx >= 0) {
return String::SubString(src,
line_start_idx,
last_char_idx - line_start_idx + 1);
} else {
return Symbols::Empty().raw();
}
}
RawString* Script::GetSnippet(intptr_t from_line,
intptr_t from_column,
intptr_t to_line,
intptr_t to_column) const {
const String& src = String::Handle(Source());
intptr_t length = src.Length();
intptr_t line = 1 + line_offset();
intptr_t column = 1;
intptr_t lookahead = 0;
intptr_t snippet_start = -1;
intptr_t snippet_end = -1;
if (from_line - line_offset() == 1) {
column += col_offset();
}
char c = src.CharAt(lookahead);
while (lookahead != length) {
if (snippet_start == -1) {
if ((line == from_line) && (column == from_column)) {
snippet_start = lookahead;
}
} else if ((line == to_line) && (column == to_column)) {
snippet_end = lookahead;
break;
}
if (c == '\n') {
line++;
column = 0;
}
column++;
lookahead++;
if (lookahead != length) {
// Replace '\r' with '\n' and a sequence of '\r' '\n' with a single '\n'.
if (src.CharAt(lookahead) == '\r') {
c = '\n';
if (lookahead + 1 != length && src.CharAt(lookahead) == '\n') {
lookahead++;
}
} else {
c = src.CharAt(lookahead);
}
}
}
String& snippet = String::Handle();
if ((snippet_start != -1) && (snippet_end != -1)) {
snippet =
String::SubString(src, snippet_start, snippet_end - snippet_start);
}
return snippet.raw();
}
RawScript* Script::New() {
ASSERT(Object::script_class() != Class::null());
RawObject* raw = Object::Allocate(Script::kClassId,
Script::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawScript*>(raw);
}
RawScript* Script::New(const String& url,
const String& source,
RawScript::Kind kind) {
const Script& result = Script::Handle(Script::New());
result.set_url(String::Handle(Symbols::New(url)));
result.set_source(source);
result.set_kind(kind);
result.SetLocationOffset(0, 0);
return result.raw();
}
const char* Script::ToCString() const {
return "Script";
}
DictionaryIterator::DictionaryIterator(const Library& library)
: array_(Array::Handle(library.dictionary())),
// Last element in array is a Smi.
size_(Array::Handle(library.dictionary()).Length() - 1),
next_ix_(0) {
MoveToNextObject();
}
RawObject* DictionaryIterator::GetNext() {
ASSERT(HasNext());
int ix = next_ix_++;
MoveToNextObject();
ASSERT(array_.At(ix) != Object::null());
return array_.At(ix);
}
void DictionaryIterator::MoveToNextObject() {
Object& obj = Object::Handle(array_.At(next_ix_));
while (obj.IsNull() && HasNext()) {
next_ix_++;
obj = array_.At(next_ix_);
}
}
ClassDictionaryIterator::ClassDictionaryIterator(const Library& library)
: DictionaryIterator(library) {
MoveToNextClass();
}
RawClass* ClassDictionaryIterator::GetNextClass() {
ASSERT(HasNext());
int ix = next_ix_++;
Object& obj = Object::Handle(array_.At(ix));
MoveToNextClass();
return Class::Cast(obj).raw();
}
void ClassDictionaryIterator::MoveToNextClass() {
Object& obj = Object::Handle(array_.At(next_ix_));
while (!obj.IsClass() && HasNext()) {
next_ix_++;
obj = array_.At(next_ix_);
}
}
LibraryPrefixIterator::LibraryPrefixIterator(const Library& library)
: DictionaryIterator(library) {
Advance();
}
RawLibraryPrefix* LibraryPrefixIterator::GetNext() {
ASSERT(HasNext());
int ix = next_ix_++;
Object& obj = Object::Handle(array_.At(ix));
Advance();
return LibraryPrefix::Cast(obj).raw();
}
void LibraryPrefixIterator::Advance() {
Object& obj = Object::Handle(array_.At(next_ix_));
while (!obj.IsLibraryPrefix() && HasNext()) {
next_ix_++;
obj = array_.At(next_ix_);
}
}
void Library::SetName(const String& name) const {
// Only set name once.
ASSERT(!Loaded());
ASSERT(name.IsSymbol());
StorePointer(&raw_ptr()->name_, name.raw());
}
void Library::SetLoadInProgress() const {
// Should not be already loaded.
ASSERT(raw_ptr()->load_state_ == RawLibrary::kAllocated);
raw_ptr()->load_state_ = RawLibrary::kLoadInProgress;
}
void Library::SetLoaded() const {
// Should not be already loaded or just allocated.
ASSERT(LoadInProgress());
raw_ptr()->load_state_ = RawLibrary::kLoaded;
}
void Library::SetLoadError() const {
// Should not be already loaded or just allocated.
ASSERT(LoadInProgress());
raw_ptr()->load_state_ = RawLibrary::kLoadError;
}
static RawString* MakeClassMetaName(const Class& cls) {
String& cname = String::Handle(cls.Name());
return String::Concat(Symbols::At(), cname);
}
static RawString* MakeFieldMetaName(const Field& field) {
const String& cname =
String::Handle(MakeClassMetaName(Class::Handle(field.origin())));
String& fname = String::Handle(field.name());
fname = String::Concat(Symbols::At(), fname);
return String::Concat(cname, fname);
}
static RawString* MakeFunctionMetaName(const Function& func) {
const String& cname =
String::Handle(MakeClassMetaName(Class::Handle(func.origin())));
String& fname = String::Handle(func.name());
fname = String::Concat(Symbols::At(), fname);
return String::Concat(cname, fname);
}
void Library::AddMetadata(const Class& cls,
const String& name,
intptr_t token_pos) const {
const String& metaname = String::Handle(Symbols::New(name));
Field& field = Field::Handle(Field::New(metaname,
true, // is_static
false, // is_final
false, // is_const
cls,
token_pos));
field.set_type(Type::Handle(Type::DynamicType()));
field.set_value(Array::empty_array());
GrowableObjectArray& metadata =
GrowableObjectArray::Handle(this->metadata());
metadata.Add(field, Heap::kOld);
}
void Library::AddClassMetadata(const Class& cls, intptr_t token_pos) const {
AddMetadata(cls, String::Handle(MakeClassMetaName(cls)), token_pos);
}
void Library::AddFieldMetadata(const Field& field,
intptr_t token_pos) const {
AddMetadata(Class::Handle(field.origin()),
String::Handle(MakeFieldMetaName(field)),
token_pos);
}
void Library::AddFunctionMetadata(const Function& func,
intptr_t token_pos) const {
AddMetadata(Class::Handle(func.origin()),
String::Handle(MakeFunctionMetaName(func)),
token_pos);
}
RawString* Library::MakeMetadataName(const Object& obj) const {
if (obj.IsClass()) {
return MakeClassMetaName(Class::Cast(obj));
} else if (obj.IsField()) {
return MakeFieldMetaName(Field::Cast(obj));
} else if (obj.IsFunction()) {
return MakeFunctionMetaName(Function::Cast(obj));
}
UNIMPLEMENTED();
return String::null();
}
RawField* Library::GetMetadataField(const String& metaname) const {
const GrowableObjectArray& metadata =
GrowableObjectArray::Handle(this->metadata());
Field& entry = Field::Handle();
String& entryname = String::Handle();
intptr_t num_entries = metadata.Length();
for (intptr_t i = 0; i < num_entries; i++) {
entry ^= metadata.At(i);
entryname = entry.name();
if (entryname.Equals(metaname)) {
return entry.raw();
}
}
return Field::null();
}
RawObject* Library::GetMetadata(const Object& obj) const {
if (!obj.IsClass() && !obj.IsField() && !obj.IsFunction()) {
return Object::null();
}
const String& metaname = String::Handle(MakeMetadataName(obj));
Field& field = Field::Handle(GetMetadataField(metaname));
if (field.IsNull()) {
// There is no metadata for this object.
return Object::empty_array().raw();;
}
Object& metadata = Object::Handle();
metadata = field.value();
if (field.value() == Object::empty_array().raw()) {
metadata = Parser::ParseMetadata(Class::Handle(field.owner()),
field.token_pos());
if (metadata.IsArray()) {
ASSERT(Array::Cast(metadata).raw() != Object::empty_array().raw());
field.set_value(Array::Cast(metadata));
}
}
return metadata.raw();
}
void Library::GrowDictionary(const Array& dict, intptr_t dict_size) const {
// TODO(iposva): Avoid exponential growth.
intptr_t new_dict_size = dict_size * 2;
const Array& new_dict =
Array::Handle(Array::New(new_dict_size + 1, Heap::kOld));
// Rehash all elements from the original dictionary
// to the newly allocated array.
Object& entry = Class::Handle();
String& entry_name = String::Handle();
Object& new_entry = Object::Handle();
for (intptr_t i = 0; i < dict_size; i++) {
entry = dict.At(i);
if (!entry.IsNull()) {
entry_name = entry.DictionaryName();
ASSERT(!entry_name.IsNull());
intptr_t hash = entry_name.Hash();
intptr_t index = hash % new_dict_size;
new_entry = new_dict.At(index);
while (!new_entry.IsNull()) {
index = (index + 1) % new_dict_size; // Move to next element.
new_entry = new_dict.At(index);
}
new_dict.SetAt(index, entry);
}
}
// Copy used count.
new_entry = dict.At(dict_size);
new_dict.SetAt(new_dict_size, new_entry);
// Remember the new dictionary now.
StorePointer(&raw_ptr()->dictionary_, new_dict.raw());
}
void Library::AddObject(const Object& obj, const String& name) const {
ASSERT(obj.IsClass() ||
obj.IsFunction() ||
obj.IsField() ||
obj.IsLibraryPrefix());
ASSERT(name.Equals(String::Handle(obj.DictionaryName())));
ASSERT(LookupLocalObject(name) == Object::null());
const Array& dict = Array::Handle(dictionary());
intptr_t dict_size = dict.Length() - 1;
intptr_t index = name.Hash() % dict_size;
Object& entry = Object::Handle();
entry = dict.At(index);
// An empty spot will be found because we keep the hash set at most 75% full.
while (!entry.IsNull()) {
index = (index + 1) % dict_size;
entry = dict.At(index);
}
// Insert the object at the empty slot.
dict.SetAt(index, obj);
// One more element added.
intptr_t used_elements = Smi::Value(Smi::RawCast(dict.At(dict_size))) + 1;
const Smi& used = Smi::Handle(Smi::New(used_elements));
dict.SetAt(dict_size, used); // Update used count.
// Rehash if symbol_table is 75% full.
if (used_elements > ((dict_size / 4) * 3)) {
GrowDictionary(dict, dict_size);
}
// Invalidate the cache of loaded scripts.
if (loaded_scripts() != Array::null()) {
StorePointer(&raw_ptr()->loaded_scripts_, Array::null());
}
}
// Lookup a name in the library's export namespace.
RawObject* Library::LookupExport(const String& name) const {
if (HasExports()) {
const Array& exports = Array::Handle(this->exports());
Namespace& ns = Namespace::Handle();
Object& obj = Object::Handle();
for (int i = 0; i < exports.Length(); i++) {
ns ^= exports.At(i);
obj = ns.Lookup(name);
if (!obj.IsNull()) {
return obj.raw();
}
}
}
return Object::null();
}
RawObject* Library::LookupEntry(const String& name, intptr_t *index) const {
Isolate* isolate = Isolate::Current();
const Array& dict = Array::Handle(isolate, dictionary());
intptr_t dict_size = dict.Length() - 1;
*index = name.Hash() % dict_size;
Object& entry = Object::Handle(isolate);
String& entry_name = String::Handle(isolate);
entry = dict.At(*index);
// Search the entry in the hash set.
while (!entry.IsNull()) {
entry_name = entry.DictionaryName();
ASSERT(!entry_name.IsNull());
if (entry_name.Equals(name)) {
return entry.raw();
}
*index = (*index + 1) % dict_size;
entry = dict.At(*index);
}
return Object::null();
}
void Library::ReplaceObject(const Object& obj, const String& name) const {
ASSERT(obj.IsClass() || obj.IsFunction() || obj.IsField());
ASSERT(LookupLocalObject(name) != Object::null());
intptr_t index;
LookupEntry(name, &index);
// The value is guaranteed to be found.
const Array& dict = Array::Handle(dictionary());
dict.SetAt(index, obj);
}
void Library::AddClass(const Class& cls) const {
AddObject(cls, String::Handle(cls.Name()));
// Link class to this library.
cls.set_library(*this);
}
RawArray* Library::LoadedScripts() const {
// We compute the list of loaded scripts lazily. The result is
// cached in loaded_scripts_.
if (loaded_scripts() == Array::null()) {
// Iterate over the library dictionary and collect all scripts.
const GrowableObjectArray& scripts =
GrowableObjectArray::Handle(GrowableObjectArray::New(8));
Object& entry = Object::Handle();
Class& cls = Class::Handle();
Script& owner_script = Script::Handle();
DictionaryIterator it(*this);
Script& script_obj = Script::Handle();
while (it.HasNext()) {
entry = it.GetNext();
if (entry.IsClass()) {
owner_script = Class::Cast(entry).script();
} else if (entry.IsFunction()) {
owner_script = Function::Cast(entry).script();
} else if (entry.IsField()) {
cls = Field::Cast(entry).owner();
owner_script = cls.script();
} else {
continue;
}
if (owner_script.IsNull()) {
continue;
}
bool is_unique = true;
for (int i = 0; i < scripts.Length(); i++) {
script_obj ^= scripts.At(i);
if (script_obj.raw() == owner_script.raw()) {
// We already have a reference to this script.
is_unique = false;
break;
}
}
if (is_unique) {
// Add script to the list of scripts.
scripts.Add(owner_script);
}
}
// Create the array of scripts and cache it in loaded_scripts_.
const Array& scripts_array = Array::Handle(Array::MakeArray(scripts));
StorePointer(&raw_ptr()->loaded_scripts_, scripts_array.raw());
}
return loaded_scripts();
}
// TODO(hausner): we might want to add a script dictionary to the
// library class to make this lookup faster.
RawScript* Library::LookupScript(const String& url) const {
const Array& scripts = Array::Handle(LoadedScripts());
Script& script = Script::Handle();
String& script_url = String::Handle();
intptr_t num_scripts = scripts.Length();
for (int i = 0; i < num_scripts; i++) {
script ^= scripts.At(i);
script_url = script.url();
if (script_url.Equals(url)) {
return script.raw();
}
}
return Script::null();
}
RawFunction* Library::LookupFunctionInScript(const Script& script,
intptr_t token_pos) const {
Class& cls = Class::Handle();
Function& func = Function::Handle();
ClassDictionaryIterator it(*this);
while (it.HasNext()) {
cls = it.GetNextClass();
if (script.raw() == cls.script()) {
func = cls.LookupFunctionAtToken(token_pos);
if (!func.IsNull()) {
return func.raw();
}
}
}
// Look in anonymous classes for toplevel functions.
Array& anon_classes = Array::Handle(this->raw_ptr()->anonymous_classes_);
intptr_t num_anonymous = raw_ptr()->num_anonymous_;
for (int i = 0; i < num_anonymous; i++) {
cls ^= anon_classes.At(i);
ASSERT(!cls.IsNull());
if (script.raw() == cls.script()) {
func = cls.LookupFunctionAtToken(token_pos);
if (!func.IsNull()) {
return func.raw();
}
}
}
return Function::null();
}
RawObject* Library::LookupLocalObject(const String& name) const {
intptr_t index;
return LookupEntry(name, &index);
}
static bool ShouldBePrivate(const String& name) {
return
(name.Length() >= 1 &&
name.CharAt(0) == '_') ||
(name.Length() >= 5 &&
(name.CharAt(4) == '_' &&
(name.CharAt(0) == 'g' || name.CharAt(0) == 's') &&
name.CharAt(1) == 'e' &&
name.CharAt(2) == 't' &&
name.CharAt(3) == ':'));
}
RawField* Library::LookupFieldAllowPrivate(const String& name) const {
// First check if name is found in the local scope of the library.
Object& obj = Object::Handle(LookupLocalField(name));
if (!obj.IsNull()) {
return Field::Cast(obj).raw();
}
// Do not look up private names in imported libraries.
if (ShouldBePrivate(name)) {
return Field::null();
}
// Now check if name is found in any imported libs.
const Array& imports = Array::Handle(this->imports());
Namespace& import = Namespace::Handle();
for (intptr_t j = 0; j < this->num_imports(); j++) {
import ^= imports.At(j);
obj = import.Lookup(name);
if (!obj.IsNull() && obj.IsField()) {
return Field::Cast(obj).raw();
}
}
return Field::null();
}
RawField* Library::LookupLocalField(const String& name) const {
Isolate* isolate = Isolate::Current();
Field& field = Field::Handle(isolate, Field::null());
Object& obj = Object::Handle(isolate, Object::null());
obj = LookupLocalObject(name);
if (obj.IsNull() && ShouldBePrivate(name)) {
String& private_name = String::Handle(isolate, PrivateName(name));
obj = LookupLocalObject(private_name);
}
if (!obj.IsNull()) {
if (obj.IsField()) {
field ^= obj.raw();
return field.raw();
}
}
// No field found.
return Field::null();
}
RawFunction* Library::LookupFunctionAllowPrivate(const String& name) const {
// First check if name is found in the local scope of the library.
Function& function = Function::Handle(LookupLocalFunction(name));
if (!function.IsNull()) {
return function.raw();
}
// Do not look up private names in imported libraries.
if (ShouldBePrivate(name)) {
return Function::null();
}
// Now check if name is found in any imported libs.
const Array& imports = Array::Handle(this->imports());
Namespace& import = Namespace::Handle();
Object& obj = Object::Handle();
for (intptr_t j = 0; j < this->num_imports(); j++) {
import ^= imports.At(j);
obj = import.Lookup(name);
if (!obj.IsNull() && obj.IsFunction()) {
function ^= obj.raw();
return function.raw();
}
}
return Function::null();
}
RawFunction* Library::LookupLocalFunction(const String& name) const {
Isolate* isolate = Isolate::Current();
Object& obj = Object::Handle(isolate, Object::null());
obj = LookupLocalObject(name);
if (obj.IsNull() && ShouldBePrivate(name)) {
String& private_name = String::Handle(isolate, PrivateName(name));
obj = LookupLocalObject(private_name);
}
if (obj.IsFunction()) {
return Function::Cast(obj).raw();
}
// No function found.
return Function::null();
}
RawObject* Library::LookupObject(const String& name) const {
// First check if name is found in the local scope of the library.
Object& obj = Object::Handle(LookupLocalObject(name));
if (!obj.IsNull()) {
return obj.raw();
}
// Now check if name is found in any imported libs.
const Array& imports = Array::Handle(this->imports());
Namespace& import = Namespace::Handle();
for (intptr_t j = 0; j < this->num_imports(); j++) {
import ^= imports.At(j);
obj = import.Lookup(name);
if (!obj.IsNull()) {
return obj.raw();
}
}
return Object::null();
}
RawClass* Library::LookupClass(const String& name) const {
Object& obj = Object::Handle(LookupObject(name));
if (!obj.IsNull() && obj.IsClass()) {
return Class::Cast(obj).raw();
}
return Class::null();
}
RawClass* Library::LookupLocalClass(const String& name) const {
Object& obj = Object::Handle(LookupLocalObject(name));
if (!obj.IsNull() && obj.IsClass()) {
return Class::Cast(obj).raw();
}
return Class::null();
}
RawClass* Library::LookupClassAllowPrivate(const String& name) const {
// See if the class is available in this library or in the top level
// scope of any imported library.
Isolate* isolate = Isolate::Current();
const Class& cls = Class::Handle(isolate, LookupClass(name));
if (!cls.IsNull()) {
return cls.raw();
}
// Now try to lookup the class using its private name, but only in
// this library (not in imported libraries).
if (ShouldBePrivate(name)) {
String& private_name = String::Handle(isolate, PrivateName(name));
const Object& obj = Object::Handle(LookupLocalObject(private_name));
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
}
return Class::null();
}
RawLibraryPrefix* Library::LookupLocalLibraryPrefix(const String& name) const {
const Object& obj = Object::Handle(LookupLocalObject(name));
if (obj.IsLibraryPrefix()) {
return LibraryPrefix::Cast(obj).raw();
}
return LibraryPrefix::null();
}
void Library::AddAnonymousClass(const Class& cls) const {
intptr_t num_anonymous = this->raw_ptr()->num_anonymous_;
Array& anon_array = Array::Handle(this->raw_ptr()->anonymous_classes_);
if (num_anonymous == anon_array.Length()) {
intptr_t new_len = (num_anonymous == 0) ? 4 : num_anonymous * 2;
anon_array = Array::Grow(anon_array, new_len);
StorePointer(&raw_ptr()->anonymous_classes_, anon_array.raw());
}
anon_array.SetAt(num_anonymous, cls);
num_anonymous++;
raw_ptr()->num_anonymous_ = num_anonymous;
}
RawLibrary* Library::ImportLibraryAt(intptr_t index) const {
Namespace& import = Namespace::Handle(ImportAt(index));
if (import.IsNull()) {
return Library::null();
}
return import.library();
}
RawNamespace* Library::ImportAt(intptr_t index) const {
if ((index < 0) || index >= num_imports()) {
return Namespace::null();
}
const Array& import_list = Array::Handle(imports());
return Namespace::RawCast(import_list.At(index));
}
bool Library::ImportsCorelib() const {
Isolate* isolate = Isolate::Current();
Library& imported = Library::Handle(isolate);
intptr_t count = num_imports();
for (int i = 0; i < count; i++) {
imported = ImportLibraryAt(i);
if (imported.IsCoreLibrary()) {
return true;
}
}
LibraryPrefix& prefix = LibraryPrefix::Handle(isolate);
LibraryPrefixIterator it(*this);
while (it.HasNext()) {
prefix = it.GetNext();
count = prefix.num_imports();
for (int i = 0; i < count; i++) {
imported = prefix.GetLibrary(i);
if (imported.IsCoreLibrary()) {
return true;
}
}
}
return false;
}
void Library::AddImport(const Namespace& ns) const {
Array& imports = Array::Handle(this->imports());
intptr_t capacity = imports.Length();
if (num_imports() == capacity) {
capacity = capacity + kImportsCapacityIncrement;
imports = Array::Grow(imports, capacity);
StorePointer(&raw_ptr()->imports_, imports.raw());
}
intptr_t index = num_imports();
imports.SetAt(index, ns);
set_num_imports(index + 1);
}
// Convenience function to determine whether the export list is
// non-empty.
bool Library::HasExports() const {
return exports() != Object::empty_array().raw();
}
// We add one namespace at a time to the exports array and don't
// pre-allocate any unused capacity. The assumption is that
// re-exports are quite rare.
void Library::AddExport(const Namespace& ns) const {
Array &exports = Array::Handle(this->exports());
intptr_t num_exports = exports.Length();
exports = Array::Grow(exports, num_exports + 1);
StorePointer(&raw_ptr()->exports_, exports.raw());
exports.SetAt(num_exports, ns);
}
void Library::InitClassDictionary() const {
// The last element of the dictionary specifies the number of in use slots.
// TODO(iposva): Find reasonable initial size.
const int kInitialElementCount = 16;
const Array& dictionary =
Array::Handle(Array::New(kInitialElementCount + 1, Heap::kOld));
dictionary.SetAt(kInitialElementCount, Smi::Handle(Smi::New(0)));
StorePointer(&raw_ptr()->dictionary_, dictionary.raw());
}
void Library::InitImportList() const {
const Array& imports =
Array::Handle(Array::New(kInitialImportsCapacity, Heap::kOld));
StorePointer(&raw_ptr()->imports_, imports.raw());
raw_ptr()->num_imports_ = 0;
}
RawLibrary* Library::New() {
ASSERT(Object::library_class() != Class::null());
RawObject* raw = Object::Allocate(Library::kClassId,
Library::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawLibrary*>(raw);
}
RawLibrary* Library::NewLibraryHelper(const String& url,
bool import_core_lib) {
const Library& result = Library::Handle(Library::New());
result.StorePointer(&result.raw_ptr()->name_, url.raw());
result.StorePointer(&result.raw_ptr()->url_, url.raw());
result.raw_ptr()->private_key_ = Scanner::AllocatePrivateKey(result);
result.raw_ptr()->dictionary_ = Object::empty_array().raw();
result.StorePointer(&result.raw_ptr()->metadata_,
GrowableObjectArray::New(4, Heap::kOld));
result.raw_ptr()->anonymous_classes_ = Object::empty_array().raw();
result.raw_ptr()->num_anonymous_ = 0;
result.raw_ptr()->imports_ = Object::empty_array().raw();
result.raw_ptr()->exports_ = Object::empty_array().raw();
result.raw_ptr()->loaded_scripts_ = Array::null();
result.set_native_entry_resolver(NULL);
result.raw_ptr()->corelib_imported_ = true;
result.set_debuggable(false);
result.raw_ptr()->load_state_ = RawLibrary::kAllocated;
result.raw_ptr()->index_ = -1;
result.InitClassDictionary();
result.InitImportList();
if (import_core_lib) {
const Library& core_lib = Library::Handle(Library::CoreLibrary());
ASSERT(!core_lib.IsNull());
const Namespace& ns = Namespace::Handle(
Namespace::New(core_lib, Object::null_array(), Object::null_array()));
result.AddImport(ns);
}
return result.raw();
}
RawLibrary* Library::New(const String& url) {
return NewLibraryHelper(url, false);
}
void Library::InitCoreLibrary(Isolate* isolate) {
const String& core_lib_url = Symbols::DartCore();
const Library& core_lib =
Library::Handle(Library::NewLibraryHelper(core_lib_url, false));
core_lib.Register();
isolate->object_store()->set_bootstrap_library(ObjectStore::kCore, core_lib);
isolate->object_store()->set_root_library(Library::Handle());
// Hook up predefined classes without setting their library pointers. These
// classes are coming from the VM isolate, and are shared between multiple
// isolates so setting their library pointers would be wrong.
const Class& cls = Class::Handle(Object::dynamic_class());
core_lib.AddObject(cls, String::Handle(cls.Name()));
}
void Library::InitNativeWrappersLibrary(Isolate* isolate) {
static const int kNumNativeWrappersClasses = 4;
ASSERT(kNumNativeWrappersClasses > 0 && kNumNativeWrappersClasses < 10);
const String& native_flds_lib_url = Symbols::DartNativeWrappers();
const Library& native_flds_lib = Library::Handle(
Library::NewLibraryHelper(native_flds_lib_url, false));
native_flds_lib.Register();
isolate->object_store()->set_native_wrappers_library(native_flds_lib);
static const char* const kNativeWrappersClass = "NativeFieldWrapperClass";
static const int kNameLength = 25;
ASSERT(kNameLength == (strlen(kNativeWrappersClass) + 1 + 1));
char name_buffer[kNameLength];
String& cls_name = String::Handle();
for (int fld_cnt = 1; fld_cnt <= kNumNativeWrappersClasses; fld_cnt++) {
OS::SNPrint(name_buffer,
kNameLength,
"%s%d",
kNativeWrappersClass,
fld_cnt);
cls_name = Symbols::New(name_buffer);
Class::NewNativeWrapper(native_flds_lib, cls_name, fld_cnt);
}
}
RawLibrary* Library::LookupLibrary(const String &url) {
Isolate* isolate = Isolate::Current();
Library& lib = Library::Handle(isolate, Library::null());
String& lib_url = String::Handle(isolate, String::null());
GrowableObjectArray& libs = GrowableObjectArray::Handle(
isolate, isolate->object_store()->libraries());
for (int i = 0; i < libs.Length(); i++) {
lib ^= libs.At(i);
lib_url ^= lib.url();
if (lib_url.Equals(url)) {
return lib.raw();
}
}
return Library::null();
}
RawError* Library::Patch(const Script& script) const {
ASSERT(script.kind() == RawScript::kPatchTag);
return Compiler::Compile(*this, script);
}
bool Library::IsKeyUsed(intptr_t key) {
intptr_t lib_key;
const GrowableObjectArray& libs = GrowableObjectArray::Handle(
Isolate::Current()->object_store()->libraries());
Library& lib = Library::Handle();
String& lib_url = String::Handle();
for (int i = 0; i < libs.Length(); i++) {
lib ^= libs.At(i);
lib_url ^= lib.url();
lib_key = lib_url.Hash();
if (lib_key == key) {
return true;
}
}
return false;
}
bool Library::IsPrivate(const String& name) {
if (ShouldBePrivate(name)) return true;
// Factory names: List._fromLiteral.
for (intptr_t i = 1; i < name.Length() - 1; i++) {
if (name.CharAt(i) == '.') {
if (name.CharAt(i + 1) == '_') {
return true;
}
}
}
return false;
}
// Cannot handle qualified names properly as it only appends private key to
// the end (e.g. _Alfa.foo -> _Alfa.foo@...).
RawString* Library::PrivateName(const String& name) const {
ASSERT(IsPrivate(name));
// ASSERT(strchr(name, '@') == NULL);
String& str = String::Handle();
str = name.raw();
str = String::Concat(str, String::Handle(this->private_key()));
str = Symbols::New(str);
return str.raw();
}
RawLibrary* Library::GetLibrary(intptr_t index) {
Isolate* isolate = Isolate::Current();
const GrowableObjectArray& libs =
GrowableObjectArray::Handle(isolate->object_store()->libraries());
ASSERT(!libs.IsNull());
if ((0 <= index) && (index < libs.Length())) {
Library& lib = Library::Handle();
lib ^= libs.At(index);
return lib.raw();
}
return Library::null();
}
void Library::Register() const {
ASSERT(Library::LookupLibrary(String::Handle(url())) == Library::null());
ObjectStore* object_store = Isolate::Current()->object_store();
GrowableObjectArray& libs =
GrowableObjectArray::Handle(object_store->libraries());
ASSERT(!libs.IsNull());
set_index(libs.Length());
libs.Add(*this);
}
RawLibrary* Library::AsyncLibrary() {
return Isolate::Current()->object_store()->async_library();
}
RawLibrary* Library::CoreLibrary() {
return Isolate::Current()->object_store()->core_library();
}
RawLibrary* Library::CollectionLibrary() {
return Isolate::Current()->object_store()->collection_library();
}
RawLibrary* Library::CollectionDevLibrary() {
return Isolate::Current()->object_store()->collection_dev_library();
}
RawLibrary* Library::IsolateLibrary() {
return Isolate::Current()->object_store()->isolate_library();
}
RawLibrary* Library::JsonLibrary() {
return Isolate::Current()->object_store()->json_library();
}
RawLibrary* Library::MathLibrary() {
return Isolate::Current()->object_store()->math_library();
}
RawLibrary* Library::MirrorsLibrary() {
return Isolate::Current()->object_store()->mirrors_library();
}
RawLibrary* Library::NativeWrappersLibrary() {
return Isolate::Current()->object_store()->native_wrappers_library();
}
RawLibrary* Library::TypedDataLibrary() {
return Isolate::Current()->object_store()->typed_data_library();
}
RawLibrary* Library::UtfLibrary() {
return Isolate::Current()->object_store()->utf_library();
}
const char* Library::ToCString() const {
const char* kFormat = "Library:'%s'";
const String& name = String::Handle(url());
intptr_t len = OS::SNPrint(NULL, 0, kFormat, name.ToCString()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, name.ToCString());
return chars;
}
RawLibrary* LibraryPrefix::GetLibrary(int index) const {
if ((index >= 0) || (index < num_imports())) {
const Array& imports = Array::Handle(this->imports());
Namespace& import = Namespace::Handle();
import ^= imports.At(index);
return import.library();
}
return Library::null();
}
bool LibraryPrefix::ContainsLibrary(const Library& library) const {
intptr_t num_current_imports = num_imports();
if (num_current_imports > 0) {
Library& lib = Library::Handle();
const String& url = String::Handle(library.url());
String& lib_url = String::Handle();
for (intptr_t i = 0; i < num_current_imports; i++) {
lib = GetLibrary(i);
ASSERT(!lib.IsNull());
lib_url = lib.url();
if (url.Equals(lib_url)) {
return true;
}
}
}
return false;
}
void LibraryPrefix::AddImport(const Namespace& import) const {
intptr_t num_current_imports = num_imports();
// The library needs to be added to the list.
Array& imports = Array::Handle(this->imports());
const intptr_t length = (imports.IsNull()) ? 0 : imports.Length();
// Grow the list if it is full.
if (num_current_imports >= length) {
const intptr_t new_length = length + kIncrementSize;
imports = Array::Grow(imports, new_length, Heap::kOld);
set_imports(imports);
}
imports.SetAt(num_current_imports, import);
set_num_imports(num_current_imports + 1);
}
RawClass* LibraryPrefix::LookupLocalClass(const String& class_name) const {
Array& imports = Array::Handle(this->imports());
Object& obj = Object::Handle();
Namespace& import = Namespace::Handle();
for (intptr_t i = 0; i < num_imports(); i++) {
import ^= imports.At(i);
obj = import.Lookup(class_name);
if (!obj.IsNull() && obj.IsClass()) {
// TODO(hausner):
return Class::Cast(obj).raw();
}
}
return Class::null();
}
RawLibraryPrefix* LibraryPrefix::New() {
ASSERT(Object::library_prefix_class() != Class::null());
RawObject* raw = Object::Allocate(LibraryPrefix::kClassId,
LibraryPrefix::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawLibraryPrefix*>(raw);
}
RawLibraryPrefix* LibraryPrefix::New(const String& name,
const Namespace& import) {
const LibraryPrefix& result = LibraryPrefix::Handle(LibraryPrefix::New());
result.set_name(name);
result.set_num_imports(0);
result.set_imports(Array::Handle(Array::New(kInitialSize)));
result.AddImport(import);
return result.raw();
}
void LibraryPrefix::set_name(const String& value) const {
ASSERT(value.IsSymbol());
StorePointer(&raw_ptr()->name_, value.raw());
}
void LibraryPrefix::set_imports(const Array& value) const {
StorePointer(&raw_ptr()->imports_, value.raw());
}
void LibraryPrefix::set_num_imports(intptr_t value) const {
raw_ptr()->num_imports_ = value;
}
const char* LibraryPrefix::ToCString() const {
const char* kFormat = "LibraryPrefix:'%s'";
const String& prefix = String::Handle(name());
intptr_t len = OS::SNPrint(NULL, 0, kFormat, prefix.ToCString()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, prefix.ToCString());
return chars;
}
const char* Namespace::ToCString() const {
const char* kFormat = "Namespace for library '%s'";
const Library& lib = Library::Handle(library());
intptr_t len = OS::SNPrint(NULL, 0, kFormat, lib.ToCString()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, lib.ToCString());
return chars;
}
bool Namespace::HidesName(const String& name) const {
// Check whether the name is in the list of explicitly hidden names.
if (hide_names() != Array::null()) {
const Array& names = Array::Handle(hide_names());
String& hidden = String::Handle();
intptr_t num_names = names.Length();
for (intptr_t i = 0; i < num_names; i++) {
hidden ^= names.At(i);
if (name.Equals(hidden)) {
return true;
}
}
}
// The name is not explicitly hidden. Now check whether it is in the
// list of explicitly visible names, if there is one.
if (show_names() != Array::null()) {
const Array& names = Array::Handle(show_names());
String& shown = String::Handle();
intptr_t num_names = names.Length();
for (intptr_t i = 0; i < num_names; i++) {
shown ^= names.At(i);
if (name.Equals(shown)) {
return false;
}
}
// There is a list of visible names. The name we're looking for is not
// contained in the list, so it is hidden.
return true;
}
// The name is not filtered out.
return false;
}
RawObject* Namespace::Lookup(const String& name) const {
Isolate* isolate = Isolate::Current();
const Library& lib = Library::Handle(isolate, library());
intptr_t ignore = 0;
// Lookup the name in the library's symbols.
Object& obj = Object::Handle(isolate, lib.LookupEntry(name, &ignore));
if (obj.IsNull()) {
// Lookup in the re-exported symbols.
obj = lib.LookupExport(name);
}
if (obj.IsNull() || HidesName(name)) {
return Object::null();
}
return obj.raw();
}
RawNamespace* Namespace::New() {
ASSERT(Object::namespace_class() != Class::null());
RawObject* raw = Object::Allocate(Namespace::kClassId,
Namespace::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawNamespace*>(raw);
}
RawNamespace* Namespace::New(const Library& library,
const Array& show_names,
const Array& hide_names) {
ASSERT(show_names.IsNull() || (show_names.Length() > 0));
ASSERT(hide_names.IsNull() || (hide_names.Length() > 0));
const Namespace& result = Namespace::Handle(Namespace::New());
result.StorePointer(&result.raw_ptr()->library_, library.raw());
result.StorePointer(&result.raw_ptr()->show_names_, show_names.raw());
result.StorePointer(&result.raw_ptr()->hide_names_, hide_names.raw());
return result.raw();
}
RawError* Library::CompileAll() {
Error& error = Error::Handle();
const GrowableObjectArray& libs = GrowableObjectArray::Handle(
Isolate::Current()->object_store()->libraries());
Library& lib = Library::Handle();
Class& cls = Class::Handle();
for (int i = 0; i < libs.Length(); i++) {
lib ^= libs.At(i);
ClassDictionaryIterator it(lib);
while (it.HasNext()) {
cls = it.GetNextClass();
error = cls.EnsureIsFinalized(Isolate::Current());
if (!error.IsNull()) {
return error.raw();
}
error = Compiler::CompileAllFunctions(cls);
if (!error.IsNull()) {
return error.raw();
}
}
Array& anon_classes = Array::Handle(lib.raw_ptr()->anonymous_classes_);
for (int i = 0; i < lib.raw_ptr()->num_anonymous_; i++) {
cls ^= anon_classes.At(i);
error = Compiler::CompileAllFunctions(cls);
if (!error.IsNull()) {
return error.raw();
}
}
}
return error.raw();
}
struct FpDiff {
FpDiff(int32_t old_, int32_t new_): old_fp(old_), new_fp(new_) {}
int32_t old_fp;
int32_t new_fp;
};
void Library::CheckFunctionFingerprints() {
GrowableArray<FpDiff> collected_fp_diffs;
Library& lib = Library::Handle();
Class& cls = Class::Handle();
Function& func = Function::Handle();
String& str = String::Handle();
bool has_errors = false;
#define CHECK_FINGERPRINTS(class_name, function_name, dest, fp) \
func = Function::null(); \
if (strcmp(#class_name, "::") == 0) { \
str = Symbols::New(#function_name); \
func = lib.LookupFunctionAllowPrivate(str); \
} else { \
str = String::New(#class_name); \
cls = lib.LookupClassAllowPrivate(str); \
if (!cls.IsNull()) { \
if (#function_name[0] == '.') { \
str = String::New(#class_name#function_name); \
} else { \
str = String::New(#function_name); \
} \
func = cls.LookupFunctionAllowPrivate(str); \
} \
} \
if (!func.IsNull() && (func.SourceFingerprint() != fp)) { \
has_errors = true; \
OS::Print("Wrong fingerprint for '%s': expecting %d found %d\n", \
func.ToFullyQualifiedCString(), fp, func.SourceFingerprint()); \
collected_fp_diffs.Add(FpDiff(fp, func.SourceFingerprint())); \
} \
lib = Library::CoreLibrary();
CORE_LIB_INTRINSIC_LIST(CHECK_FINGERPRINTS);
CORE_INTEGER_LIB_INTRINSIC_LIST(CHECK_FINGERPRINTS);
RECOGNIZED_LIST(CHECK_FINGERPRINTS);
lib = Library::MathLibrary();
MATH_LIB_INTRINSIC_LIST(CHECK_FINGERPRINTS);
lib = Library::TypedDataLibrary();
TYPED_DATA_LIB_INTRINSIC_LIST(CHECK_FINGERPRINTS);
#undef CHECK_FINGERPRINTS
#define CHECK_FACTORY_FINGERPRINTS(factory_symbol, cid, fp) \
cls = Isolate::Current()->class_table()->At(cid); \
func = cls.LookupFunctionAllowPrivate(Symbols::factory_symbol()); \
ASSERT(!func.IsNull()); \
if (func.SourceFingerprint() != fp) { \
has_errors = true; \
OS::Print("Wrong fingerprint for '%s': expecting %d found %d\n", \
func.ToFullyQualifiedCString(), fp, func.SourceFingerprint()); \
collected_fp_diffs.Add(FpDiff(fp, func.SourceFingerprint())); \
} \
RECOGNIZED_LIST_FACTORY_LIST(CHECK_FACTORY_FINGERPRINTS);
#undef CHECK_FACTORY_FINGERPRINTS
if (has_errors) {
for (intptr_t i = 0; i < collected_fp_diffs.length(); i++) {
OS::Print("s/%d/%d/\n",
collected_fp_diffs[i].old_fp, collected_fp_diffs[i].new_fp);
}
OS::Print("\n");
FATAL("Fingerprint mismatch.");
}
}
RawInstructions* Instructions::New(intptr_t size) {
ASSERT(Object::instructions_class() != Class::null());
if (size < 0 || size > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in Instructions::New: invalid size %"Pd"\n", size);
}
Instructions& result = Instructions::Handle();
{
uword aligned_size = Instructions::InstanceSize(size);
RawObject* raw = Object::Allocate(Instructions::kClassId,
aligned_size,
Heap::kCode);
NoGCScope no_gc;
result ^= raw;
result.set_size(size);
}
return result.raw();
}
const char* Instructions::ToCString() const {
return "Instructions";
}
intptr_t PcDescriptors::Length() const {
return Smi::Value(raw_ptr()->length_);
}
void PcDescriptors::SetLength(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
raw_ptr()->length_ = Smi::New(value);
}
uword PcDescriptors::PC(intptr_t index) const {
return static_cast<uword>(*(EntryAddr(index, kPcEntry)));
}
void PcDescriptors::SetPC(intptr_t index, uword value) const {
*(EntryAddr(index, kPcEntry)) = static_cast<intptr_t>(value);
}
PcDescriptors::Kind PcDescriptors::DescriptorKind(intptr_t index) const {
return static_cast<PcDescriptors::Kind>(*(EntryAddr(index, kKindEntry)));
}
void PcDescriptors::SetKind(intptr_t index, PcDescriptors::Kind value) const {
*(EntryAddr(index, kKindEntry)) = value;
}
intptr_t PcDescriptors::DeoptId(intptr_t index) const {
return *(EntryAddr(index, kDeoptIdEntry));
}
void PcDescriptors::SetDeoptId(intptr_t index, intptr_t value) const {
*(EntryAddr(index, kDeoptIdEntry)) = value;
}
intptr_t PcDescriptors::TokenPos(intptr_t index) const {
return *(EntryAddr(index, kTokenPosEntry));
}
void PcDescriptors::SetTokenPos(intptr_t index, intptr_t value) const {
*(EntryAddr(index, kTokenPosEntry)) = value;
}
intptr_t PcDescriptors::TryIndex(intptr_t index) const {
return *(EntryAddr(index, kTryIndexEntry));
}
void PcDescriptors::SetTryIndex(intptr_t index, intptr_t value) const {
*(EntryAddr(index, kTryIndexEntry)) = value;
}
RawPcDescriptors* PcDescriptors::New(intptr_t num_descriptors) {
ASSERT(Object::pc_descriptors_class() != Class::null());
if (num_descriptors < 0 || num_descriptors > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in PcDescriptors::New: "
"invalid num_descriptors %"Pd"\n", num_descriptors);
}
PcDescriptors& result = PcDescriptors::Handle();
{
uword size = PcDescriptors::InstanceSize(num_descriptors);
RawObject* raw = Object::Allocate(PcDescriptors::kClassId,
size,
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.SetLength(num_descriptors);
}
return result.raw();
}
const char* PcDescriptors::KindAsStr(intptr_t index) const {
switch (DescriptorKind(index)) {
case PcDescriptors::kDeopt: return "deopt ";
case PcDescriptors::kEntryPatch: return "entry-patch ";
case PcDescriptors::kPatchCode: return "patch ";
case PcDescriptors::kLazyDeoptJump: return "lazy-deopt ";
case PcDescriptors::kIcCall: return "ic-call ";
case PcDescriptors::kFuncCall: return "fn-call ";
case PcDescriptors::kClosureCall: return "closure-call ";
case PcDescriptors::kReturn: return "return ";
case PcDescriptors::kRuntimeCall: return "runtime-call ";
case PcDescriptors::kOther: return "other ";
}
UNREACHABLE();
return "";
}
void PcDescriptors::PrintHeaderString() {
// 4 bits per hex digit + 2 for "0x".
const int addr_width = (kBitsPerWord / 4) + 2;
// "*" in a printf format specifier tells it to read the field width from
// the printf argument list.
OS::Print("%-*s\tkind \tdeopt-id\ttok-ix\ttry-ix\n",
addr_width, "pc");
}
const char* PcDescriptors::ToCString() const {
if (Length() == 0) {
return "No pc descriptors\n";
}
// 4 bits per hex digit.
const int addr_width = kBitsPerWord / 4;
// "*" in a printf format specifier tells it to read the field width from
// the printf argument list.
const char* kFormat =
"%#-*"Px"\t%s\t%"Pd"\t\t%"Pd"\t%"Pd"\n";
// First compute the buffer size required.
intptr_t len = 1; // Trailing '\0'.
for (intptr_t i = 0; i < Length(); i++) {
len += OS::SNPrint(NULL, 0, kFormat, addr_width,
PC(i),
KindAsStr(i),
DeoptId(i),
TokenPos(i),
TryIndex(i));
}
// Allocate the buffer.
char* buffer = Isolate::Current()->current_zone()->Alloc<char>(len);
// Layout the fields in the buffer.
intptr_t index = 0;
for (intptr_t i = 0; i < Length(); i++) {
index += OS::SNPrint((buffer + index), (len - index), kFormat, addr_width,
PC(i),
KindAsStr(i),
DeoptId(i),
TokenPos(i),
TryIndex(i));
}
return buffer;
}
// Verify assumptions (in debug mode only).
// - No two deopt descriptors have the same deoptimization id.
// - No two ic-call descriptors have the same deoptimization id (type feedback).
// A function without unique ids is marked as non-optimizable (e.g., because of
// finally blocks).
void PcDescriptors::Verify(const Function& function) const {
#if defined(DEBUG)
// TODO(srdjan): Implement a more efficient way to check, currently drop
// the check for too large number of descriptors.
if (Length() > 3000) {
if (FLAG_trace_compiler) {
OS::Print("Not checking pc decriptors, length %"Pd"\n", Length());
}
return;
}
// Only check ids for unoptimized code that is optimizable.
if (!function.is_optimizable()) return;
for (intptr_t i = 0; i < Length(); i++) {
PcDescriptors::Kind kind = DescriptorKind(i);
// 'deopt_id' is set for kDeopt and kIcCall and must be unique for one kind.
intptr_t deopt_id = Isolate::kNoDeoptId;
if ((DescriptorKind(i) != PcDescriptors::kDeopt) ||
(DescriptorKind(i) != PcDescriptors::kIcCall)) {
continue;
}
deopt_id = DeoptId(i);
if (Isolate::IsDeoptAfter(deopt_id)) {
// TODO(vegorov): some instructions contain multiple calls and have
// multiple "after" targets recorded. Right now it is benign but might
// lead to issues in the future. Fix that and enable verification.
continue;
}
for (intptr_t k = i + 1; k < Length(); k++) {
if (kind == DescriptorKind(k)) {
if (deopt_id != Isolate::kNoDeoptId) {
ASSERT(DeoptId(k) != deopt_id);
}
}
}
}
#endif // DEBUG
}
uword PcDescriptors::GetPcForKind(Kind kind) const {
for (intptr_t i = 0; i < Length(); i++) {
if (DescriptorKind(i) == kind) {
return PC(i);
}
}
return 0;
}
void Stackmap::SetCode(const dart::Code& code) const {
StorePointer(&raw_ptr()->code_, code.raw());
}
bool Stackmap::GetBit(intptr_t bit_index) const {
ASSERT(InRange(bit_index));
int byte_index = bit_index >> kBitsPerByteLog2;
int bit_remainder = bit_index & (kBitsPerByte - 1);
uint8_t byte_mask = 1U << bit_remainder;
uint8_t byte = raw_ptr()->data_[byte_index];
return (byte & byte_mask);
}
void Stackmap::SetBit(intptr_t bit_index, bool value) const {
ASSERT(InRange(bit_index));
int byte_index = bit_index >> kBitsPerByteLog2;
int bit_remainder = bit_index & (kBitsPerByte - 1);
uint8_t byte_mask = 1U << bit_remainder;
uint8_t* byte_addr = &(raw_ptr()->data_[byte_index]);
if (value) {
*byte_addr |= byte_mask;
} else {
*byte_addr &= ~byte_mask;
}
}
RawStackmap* Stackmap::New(intptr_t pc_offset,
BitmapBuilder* bmap,
intptr_t register_bit_count) {
ASSERT(Object::stackmap_class() != Class::null());
ASSERT(bmap != NULL);
Stackmap& result = Stackmap::Handle();
// Guard against integer overflow of the instance size computation.
intptr_t length = bmap->Length();
intptr_t payload_size =
Utils::RoundUp(length, kBitsPerByte) / kBitsPerByte;
if ((payload_size < 0) ||
(payload_size >
(kSmiMax - static_cast<intptr_t>(sizeof(RawStackmap))))) {
// This should be caught before we reach here.
FATAL1("Fatal error in Stackmap::New: invalid length %"Pd"\n",
length);
}
{
// Stackmap data objects are associated with a code object, allocate them
// in old generation.
RawObject* raw = Object::Allocate(Stackmap::kClassId,
Stackmap::InstanceSize(length),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.SetLength(length);
}
// When constructing a stackmap we store the pc offset in the stackmap's
// PC. StackmapTableBuilder::FinalizeStackmaps will replace it with the pc
// address.
ASSERT(pc_offset >= 0);
result.SetPC(pc_offset);
for (intptr_t i = 0; i < length; ++i) {
result.SetBit(i, bmap->Get(i));
}
result.SetRegisterBitCount(register_bit_count);
return result.raw();
}
const char* Stackmap::ToCString() const {
if (IsNull()) {
return "{null}";
} else {
const char* kFormat = "%#"Px": ";
intptr_t fixed_length = OS::SNPrint(NULL, 0, kFormat, PC()) + 1;
Isolate* isolate = Isolate::Current();
// Guard against integer overflow in the computation of alloc_size.
//
// TODO(kmillikin): We could just truncate the string if someone
// tries to print a 2 billion plus entry stackmap.
if (Length() > (kIntptrMax - fixed_length)) {
FATAL1("Length() is unexpectedly large (%"Pd")", Length());
}
intptr_t alloc_size = fixed_length + Length();
char* chars = isolate->current_zone()->Alloc<char>(alloc_size);
intptr_t index = OS::SNPrint(chars, alloc_size, kFormat, PC());
for (intptr_t i = 0; i < Length(); i++) {
chars[index++] = IsObject(i) ? '1' : '0';
}
chars[index] = '\0';
return chars;
}
}
RawString* LocalVarDescriptors::GetName(intptr_t var_index) const {
ASSERT(var_index < Length());
const Array& names = Array::Handle(raw_ptr()->names_);
ASSERT(Length() == names.Length());
String& name = String::Handle();
name ^= names.At(var_index);
return name.raw();
}
void LocalVarDescriptors::SetVar(intptr_t var_index,
const String& name,
RawLocalVarDescriptors::VarInfo* info) const {
ASSERT(var_index < Length());
const Array& names = Array::Handle(raw_ptr()->names_);
ASSERT(Length() == names.Length());
names.SetAt(var_index, name);
raw_ptr()->data_[var_index] = *info;
}
void LocalVarDescriptors::GetInfo(intptr_t var_index,
RawLocalVarDescriptors::VarInfo* info) const {
ASSERT(var_index < Length());
*info = raw_ptr()->data_[var_index];
}
const char* LocalVarDescriptors::ToCString() const {
intptr_t len = 1; // Trailing '\0'.
const char* kFormat =
"%2"Pd" kind=%d scope=0x%04x begin=%"Pd" end=%"Pd" name=%s\n";
for (intptr_t i = 0; i < Length(); i++) {
String& var_name = String::Handle(GetName(i));
RawLocalVarDescriptors::VarInfo info;
GetInfo(i, &info);
len += OS::SNPrint(NULL, 0, kFormat,
i,
info.kind,
info.scope_id,
info.begin_pos,
info.end_pos,
var_name.ToCString());
}
char* buffer = Isolate::Current()->current_zone()->Alloc<char>(len);
intptr_t num_chars = 0;
for (intptr_t i = 0; i < Length(); i++) {
String& var_name = String::Handle(GetName(i));
RawLocalVarDescriptors::VarInfo info;
GetInfo(i, &info);
num_chars += OS::SNPrint((buffer + num_chars),
(len - num_chars),
kFormat,
i,
info.kind,
info.scope_id,
info.begin_pos,
info.end_pos,
var_name.ToCString());
}
return buffer;
}
RawLocalVarDescriptors* LocalVarDescriptors::New(intptr_t num_variables) {
ASSERT(Object::var_descriptors_class() != Class::null());
if (num_variables < 0 || num_variables > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in LocalVarDescriptors::New: "
"invalid num_variables %"Pd"\n", num_variables);
}
LocalVarDescriptors& result = LocalVarDescriptors::Handle();
{
uword size = LocalVarDescriptors::InstanceSize(num_variables);
RawObject* raw = Object::Allocate(LocalVarDescriptors::kClassId,
size,
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.raw_ptr()->length_ = num_variables;
}
const Array& names = Array::Handle(Array::New(num_variables, Heap::kOld));
result.raw_ptr()->names_ = names.raw();
return result.raw();
}
intptr_t LocalVarDescriptors::Length() const {
return raw_ptr()->length_;
}
intptr_t ExceptionHandlers::Length() const {
return raw_ptr()->length_;
}
void ExceptionHandlers::SetHandlerInfo(intptr_t try_index,
intptr_t outer_try_index,
intptr_t handler_pc) const {
ASSERT((try_index >= 0) && (try_index < Length()));
RawExceptionHandlers::HandlerInfo* info = &raw_ptr()->data_[try_index];
info->outer_try_index = outer_try_index;
info->handler_pc = handler_pc;
}
void ExceptionHandlers::GetHandlerInfo(
intptr_t try_index,
RawExceptionHandlers::HandlerInfo* info) const {
ASSERT((try_index >= 0) && (try_index < Length()));
ASSERT(info != NULL);
RawExceptionHandlers::HandlerInfo* data = &raw_ptr()->data_[try_index];
info->outer_try_index = data->outer_try_index;
info->handler_pc = data->handler_pc;
}
intptr_t ExceptionHandlers::HandlerPC(intptr_t try_index) const {
ASSERT((try_index >= 0) && (try_index < Length()));
return raw_ptr()->data_[try_index].handler_pc;
}
intptr_t ExceptionHandlers::OuterTryIndex(intptr_t try_index) const {
ASSERT((try_index >= 0) && (try_index < Length()));
return raw_ptr()->data_[try_index].outer_try_index;
}
void ExceptionHandlers::SetHandledTypes(intptr_t try_index,
const Array& handled_types) const {
ASSERT((try_index >= 0) && (try_index < Length()));
const Array& handled_types_data =
Array::Handle(raw_ptr()->handled_types_data_);
handled_types_data.SetAt(try_index, handled_types);
}
RawArray* ExceptionHandlers::GetHandledTypes(intptr_t try_index) const {
ASSERT((try_index >= 0) && (try_index < Length()));
Array& array = Array::Handle(raw_ptr()->handled_types_data_);
array ^= array.At(try_index);
return array.raw();
}
void ExceptionHandlers::set_handled_types_data(const Array& value) const {
StorePointer(&raw_ptr()->handled_types_data_, value.raw());
}
RawExceptionHandlers* ExceptionHandlers::New(intptr_t num_handlers) {
ASSERT(Object::exception_handlers_class() != Class::null());
if (num_handlers < 0 || num_handlers >= kMaxHandlers) {
FATAL1("Fatal error in ExceptionHandlers::New(): "
"invalid num_handlers %"Pd"\n",
num_handlers);
}
ExceptionHandlers& result = ExceptionHandlers::Handle();
{
uword size = ExceptionHandlers::InstanceSize(num_handlers);
RawObject* raw = Object::Allocate(ExceptionHandlers::kClassId,
size,
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.raw_ptr()->length_ = num_handlers;
}
const Array& handled_types_data = Array::Handle(Array::New(num_handlers));
result.set_handled_types_data(handled_types_data);
return result.raw();
}
const char* ExceptionHandlers::ToCString() const {
if (Length() == 0) {
return "No exception handlers\n";
}
Array& handled_types = Array::Handle();
Type& type = Type::Handle();
RawExceptionHandlers::HandlerInfo info;
// First compute the buffer size required.
const char* kFormat = "%"Pd" => %#"Px" (%"Pd" types) (outer %"Pd")\n";
const char* kFormat2 = " %d. %s\n";
intptr_t len = 1; // Trailing '\0'.
for (intptr_t i = 0; i < Length(); i++) {
GetHandlerInfo(i, &info);
handled_types = GetHandledTypes(i);
ASSERT(!handled_types.IsNull());
intptr_t num_types = handled_types.Length();
len += OS::SNPrint(NULL, 0, kFormat,
i,
info.handler_pc,
num_types,
info.outer_try_index);
for (int k = 0; k < num_types; k++) {
type ^= handled_types.At(k);
ASSERT(!type.IsNull());
len += OS::SNPrint(NULL, 0, kFormat2, k, type.ToCString());
}
}
// Allocate the buffer.
char* buffer = Isolate::Current()->current_zone()->Alloc<char>(len);
// Layout the fields in the buffer.
intptr_t num_chars = 0;
for (intptr_t i = 0; i < Length(); i++) {
GetHandlerInfo(i, &info);
handled_types = GetHandledTypes(i);
intptr_t num_types = handled_types.Length();
num_chars += OS::SNPrint((buffer + num_chars),
(len - num_chars),
kFormat,
i,
info.handler_pc,
num_types,
info.outer_try_index);
for (int k = 0; k < num_types; k++) {
type ^= handled_types.At(k);
num_chars += OS::SNPrint((buffer + num_chars),
(len - num_chars),
kFormat2, k, type.ToCString());
}
}
return buffer;
}
intptr_t DeoptInfo::Length() const {
return Smi::Value(raw_ptr()->length_);
}
intptr_t DeoptInfo::FromIndex(intptr_t index) const {
return *(EntryAddr(index, kFromIndex));
}
intptr_t DeoptInfo::Instruction(intptr_t index) const {
return *(EntryAddr(index, kInstruction));
}
intptr_t DeoptInfo::FrameSize() const {
intptr_t pos = 0;
while (Instruction(pos) == DeoptInstr::kMaterializeObject) {
pos++;
}
return TranslationLength() - pos;
}
intptr_t DeoptInfo::TranslationLength() const {
intptr_t length = Length();
if (Instruction(length - 1) != DeoptInstr::kSuffix) return length;
// If the last command is a suffix, add in the length of the suffix and
// do not count the suffix command as a translation command.
intptr_t ignored = 0;
intptr_t suffix_length =
DeoptInstr::DecodeSuffix(FromIndex(length - 1), &ignored);
return length + suffix_length - 1;
}
void DeoptInfo::ToInstructions(const Array& table,
GrowableArray<DeoptInstr*>* instructions) const {
ASSERT(instructions->is_empty());
Smi& offset = Smi::Handle();
DeoptInfo& info = DeoptInfo::Handle(raw());
Smi& reason = Smi::Handle();
intptr_t index = 0;
intptr_t length = TranslationLength();
while (index < length) {
intptr_t instruction = info.Instruction(index);
intptr_t from_index = info.FromIndex(index);
if (instruction == DeoptInstr::kSuffix) {
// Suffix instructions cause us to 'jump' to another translation,
// changing info, length and index.
intptr_t info_number = 0;
intptr_t suffix_length =
DeoptInstr::DecodeSuffix(from_index, &info_number);
DeoptTable::GetEntry(table, info_number, &offset, &info, &reason);
length = info.TranslationLength();
index = length - suffix_length;
} else {
instructions->Add(DeoptInstr::Create(instruction, from_index));
++index;
}
}
}
const char* DeoptInfo::ToCString() const {
if (Length() == 0) {
return "No DeoptInfo";
}
// Convert to DeoptInstr.
GrowableArray<DeoptInstr*> deopt_instrs(Length());
for (intptr_t i = 0; i < Length(); i++) {
deopt_instrs.Add(DeoptInstr::Create(Instruction(i), FromIndex(i)));
}
// Compute the buffer size required.
intptr_t len = 1; // Trailing '\0'.
for (intptr_t i = 0; i < Length(); i++) {
len += OS::SNPrint(NULL, 0, "[%s]", deopt_instrs[i]->ToCString());
}
// Allocate the buffer.
char* buffer = Isolate::Current()->current_zone()->Alloc<char>(len);
// Layout the fields in the buffer.
intptr_t index = 0;
for (intptr_t i = 0; i < Length(); i++) {
index += OS::SNPrint((buffer + index),
(len - index),
"[%s]",
deopt_instrs[i]->ToCString());
}
return buffer;
}
RawDeoptInfo* DeoptInfo::New(intptr_t num_commands) {
ASSERT(Object::deopt_info_class() != Class::null());
DeoptInfo& result = DeoptInfo::Handle();
{
uword size = DeoptInfo::InstanceSize(num_commands);
RawObject* raw = Object::Allocate(DeoptInfo::kClassId,
size,
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.SetLength(num_commands);
}
return result.raw();
}
void DeoptInfo::SetLength(intptr_t value) const {
// This is only safe because we create a new Smi, which does not cause
// heap allocation.
raw_ptr()->length_ = Smi::New(value);
}
void DeoptInfo::SetAt(intptr_t index,
intptr_t instr_kind,
intptr_t from_index) const {
*(EntryAddr(index, kInstruction)) = instr_kind;
*(EntryAddr(index, kFromIndex)) = from_index;
}
Code::Comments& Code::Comments::New(intptr_t count) {
Comments* comments;
if (count < 0 || count > (kIntptrMax / kNumberOfEntries)) {
// This should be caught before we reach here.
FATAL1("Fatal error in Code::Comments::New: invalid count %"Pd"\n", count);
}
if (count == 0) {
comments = new Comments(Object::empty_array());
} else {
const Array& data = Array::Handle(Array::New(count * kNumberOfEntries));
comments = new Comments(data);
}
return *comments;
}
intptr_t Code::Comments::Length() const {
if (comments_.IsNull()) {
return 0;
}
return comments_.Length() / kNumberOfEntries;
}
intptr_t Code::Comments::PCOffsetAt(intptr_t idx) const {
return Smi::Value(Smi::RawCast(
comments_.At(idx * kNumberOfEntries + kPCOffsetEntry)));
}
void Code::Comments::SetPCOffsetAt(intptr_t idx, intptr_t pc) {
comments_.SetAt(idx * kNumberOfEntries + kPCOffsetEntry,
Smi::Handle(Smi::New(pc)));
}
RawString* Code::Comments::CommentAt(intptr_t idx) const {
return String::RawCast(comments_.At(idx * kNumberOfEntries + kCommentEntry));
}
void Code::Comments::SetCommentAt(intptr_t idx, const String& comment) {
comments_.SetAt(idx * kNumberOfEntries + kCommentEntry, comment);
}
Code::Comments::Comments(const Array& comments)
: comments_(comments) {
}
void Code::set_stackmaps(const Array& maps) const {
StorePointer(&raw_ptr()->stackmaps_, maps.raw());
}
void Code::set_deopt_info_array(const Array& array) const {
StorePointer(&raw_ptr()->deopt_info_array_, array.raw());
}
void Code::set_object_table(const Array& array) const {
StorePointer(&raw_ptr()->object_table_, array.raw());
}
void Code::set_static_calls_target_table(const Array& value) const {
StorePointer(&raw_ptr()->static_calls_target_table_, value.raw());
#if defined(DEBUG)
// Check that the table is sorted by pc offsets.
// FlowGraphCompiler::AddStaticCallTarget adds pc-offsets to the table while
// emitting assembly. This guarantees that every succeeding pc-offset is
// larger than the previously added one.
for (intptr_t i = kSCallTableEntryLength;
i < value.Length();
i += kSCallTableEntryLength) {
ASSERT(value.At(i - kSCallTableEntryLength) < value.At(i));
}
#endif // DEBUG
}
RawDeoptInfo* Code::GetDeoptInfoAtPc(uword pc, intptr_t* deopt_reason) const {
ASSERT(is_optimized());
const Instructions& instrs = Instructions::Handle(instructions());
uword code_entry = instrs.EntryPoint();
const Array& table = Array::Handle(deopt_info_array());
ASSERT(!table.IsNull());
// Linear search for the PC offset matching the target PC.
intptr_t length = DeoptTable::GetLength(table);
Smi& offset = Smi::Handle();
Smi& reason = Smi::Handle();
DeoptInfo& info = DeoptInfo::Handle();
for (intptr_t i = 0; i < length; ++i) {
DeoptTable::GetEntry(table, i, &offset, &info, &reason);
if (pc == (code_entry + offset.Value())) {
ASSERT(!info.IsNull());
*deopt_reason = reason.Value();
return info.raw();
}
}
*deopt_reason = kDeoptUnknown;
return DeoptInfo::null();
}
intptr_t Code::BinarySearchInSCallTable(uword pc) const {
NoGCScope no_gc;
const Array& table = Array::Handle(raw_ptr()->static_calls_target_table_);
RawObject* key = reinterpret_cast<RawObject*>(Smi::New(pc - EntryPoint()));
intptr_t imin = 0;
intptr_t imax = table.Length() / kSCallTableEntryLength;
while (imax >= imin) {
const intptr_t imid = ((imax - imin) / 2) + imin;
const intptr_t real_index = imid * kSCallTableEntryLength;
RawObject* key_in_table = table.At(real_index);
if (key_in_table < key) {
imin = imid + 1;
} else if (key_in_table > key) {
imax = imid - 1;
} else {
return real_index;
}
}
return -1;
}
RawFunction* Code::GetStaticCallTargetFunctionAt(uword pc) const {
const intptr_t i = BinarySearchInSCallTable(pc);
if (i < 0) {
return Function::null();
}
const Array& array =
Array::Handle(raw_ptr()->static_calls_target_table_);
Function& function = Function::Handle();
function ^= array.At(i + kSCallTableFunctionEntry);
return function.raw();
}
void Code::SetStaticCallTargetCodeAt(uword pc, const Code& code) const {
const intptr_t i = BinarySearchInSCallTable(pc);
ASSERT(i >= 0);
const Array& array =
Array::Handle(raw_ptr()->static_calls_target_table_);
ASSERT(code.IsNull() ||
(code.function() == array.At(i + kSCallTableFunctionEntry)));
array.SetAt(i + kSCallTableCodeEntry, code);
}
const Code::Comments& Code::comments() const {
Comments* comments = new Code::Comments(Array::Handle(raw_ptr()->comments_));
return *comments;
}
void Code::set_comments(const Code::Comments& comments) const {
StorePointer(&raw_ptr()->comments_, comments.comments_.raw());
}
RawCode* Code::New(intptr_t pointer_offsets_length) {
if (pointer_offsets_length < 0 || pointer_offsets_length > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in Code::New: invalid pointer_offsets_length %"Pd"\n",
pointer_offsets_length);
}
ASSERT(Object::code_class() != Class::null());
Code& result = Code::Handle();
{
uword size = Code::InstanceSize(pointer_offsets_length);
RawObject* raw = Object::Allocate(Code::kClassId, size, Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.set_pointer_offsets_length(pointer_offsets_length);
result.set_is_optimized(false);
result.set_is_alive(true);
result.set_comments(Comments::New(0));
}
return result.raw();
}
RawCode* Code::FinalizeCode(const char* name,
Assembler* assembler,
bool optimized) {
ASSERT(assembler != NULL);
// Allocate the Instructions object.
Instructions& instrs =
Instructions::ZoneHandle(Instructions::New(assembler->CodeSize()));
// Copy the instructions into the instruction area and apply all fixups.
// Embedded pointers are still in handles at this point.
MemoryRegion region(reinterpret_cast<void*>(instrs.EntryPoint()),
instrs.size());
assembler->FinalizeInstructions(region);
CPU::FlushICache(instrs.EntryPoint(), instrs.size());
CodeObservers::NotifyAll(name,
instrs.EntryPoint(),
assembler->prologue_offset(),
instrs.size(),
optimized);
const ZoneGrowableArray<int>& pointer_offsets =
assembler->GetPointerOffsets();
// Allocate the code object.
Code& code = Code::ZoneHandle(Code::New(pointer_offsets.length()));
{
NoGCScope no_gc;
// Set pointer offsets list in Code object and resolve all handles in
// the instruction stream to raw objects.
ASSERT(code.pointer_offsets_length() == pointer_offsets.length());
for (int i = 0; i < pointer_offsets.length(); i++) {
int offset_in_instrs = pointer_offsets[i];
code.SetPointerOffsetAt(i, offset_in_instrs);
const Object* object = region.Load<const Object*>(offset_in_instrs);
region.Store<RawObject*>(offset_in_instrs, object->raw());
}
// Hook up Code and Instructions objects.
instrs.set_code(code.raw());
code.set_instructions(instrs.raw());
// Set object pool in Instructions object.
const GrowableObjectArray& object_pool = assembler->object_pool();
if (object_pool.IsNull()) {
instrs.set_object_pool(Object::empty_array().raw());
} else {
// TODO(regis): Once MakeArray takes a Heap::Space argument, call it here
// with Heap::kOld and change the ARM and MIPS assemblers to work with a
// GrowableObjectArray in new space.
instrs.set_object_pool(Array::MakeArray(object_pool));
}
}
return code.raw();
}
RawCode* Code::FinalizeCode(const Function& function,
Assembler* assembler,
bool optimized) {
// Calling ToFullyQualifiedCString is very expensive, try to avoid it.
if (CodeObservers::AreActive()) {
return FinalizeCode(function.ToFullyQualifiedCString(),
assembler,
optimized);
} else {
return FinalizeCode("", assembler);
}
}
// Check if object matches find condition.
bool Code::FindRawCodeVisitor::FindObject(RawObject* obj) {
return RawInstructions::ContainsPC(obj, pc_);
}
RawCode* Code::LookupCode(uword pc) {
Isolate* isolate = Isolate::Current();
NoGCScope no_gc;
FindRawCodeVisitor visitor(pc);
RawInstructions* instr;
instr = isolate->heap()->FindObjectInCodeSpace(&visitor);
if (instr != Instructions::null()) {
return instr->ptr()->code_;
}
return Code::null();
}
intptr_t Code::GetTokenIndexOfPC(uword pc) const {
intptr_t token_pos = -1;
const PcDescriptors& descriptors = PcDescriptors::Handle(pc_descriptors());
for (intptr_t i = 0; i < descriptors.Length(); i++) {
if (descriptors.PC(i) == pc) {
token_pos = descriptors.TokenPos(i);
break;
}
}
return token_pos;
}
uword Code::GetPcForDeoptId(intptr_t deopt_id, PcDescriptors::Kind kind) const {
const PcDescriptors& descriptors = PcDescriptors::Handle(pc_descriptors());
for (intptr_t i = 0; i < descriptors.Length(); i++) {
if ((descriptors.DeoptId(i) == deopt_id) &&
(descriptors.DescriptorKind(i) == kind)) {
uword pc = descriptors.PC(i);
ASSERT(ContainsInstructionAt(pc));
return pc;
}
}
return 0;
}
const char* Code::ToCString() const {
const char* kFormat = "Code entry:%p";
intptr_t len = OS::SNPrint(NULL, 0, kFormat, EntryPoint()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, EntryPoint());
return chars;
}
uword Code::GetPatchCodePc() const {
const PcDescriptors& descriptors = PcDescriptors::Handle(pc_descriptors());
return descriptors.GetPcForKind(PcDescriptors::kPatchCode);
}
uword Code::GetLazyDeoptPc() const {
const PcDescriptors& descriptors = PcDescriptors::Handle(pc_descriptors());
return descriptors.GetPcForKind(PcDescriptors::kLazyDeoptJump);
}
bool Code::ObjectExistsInArea(intptr_t start_offset,
intptr_t end_offset) const {
for (intptr_t i = 0; i < this->pointer_offsets_length(); i++) {
const intptr_t offset = this->GetPointerOffsetAt(i);
if ((start_offset <= offset) && (offset < end_offset)) {
return false;
}
}
return true;
}
intptr_t Code::ExtractIcDataArraysAtCalls(
GrowableArray<intptr_t>* node_ids,
const GrowableObjectArray& ic_data_objs) const {
ASSERT(node_ids != NULL);
ASSERT(!ic_data_objs.IsNull());
const PcDescriptors& descriptors =
PcDescriptors::Handle(this->pc_descriptors());
ICData& ic_data_obj = ICData::Handle();
intptr_t max_id = -1;
for (intptr_t i = 0; i < descriptors.Length(); i++) {
if (descriptors.DescriptorKind(i) == PcDescriptors::kIcCall) {
intptr_t deopt_id = descriptors.DeoptId(i);
if (deopt_id > max_id) {
max_id = deopt_id;
}
node_ids->Add(deopt_id);
CodePatcher::GetInstanceCallAt(descriptors.PC(i), *this,
&ic_data_obj, NULL);
ic_data_objs.Add(ic_data_obj);
}
}
return max_id;
}
RawArray* Code::ExtractTypeFeedbackArray() const {
ASSERT(!IsNull() && !is_optimized());
GrowableArray<intptr_t> deopt_ids;
const GrowableObjectArray& ic_data_objs =
GrowableObjectArray::Handle(GrowableObjectArray::New());
const intptr_t max_id =
ExtractIcDataArraysAtCalls(&deopt_ids, ic_data_objs);
const Array& result = Array::Handle(Array::New(max_id + 1));
for (intptr_t i = 0; i < deopt_ids.length(); i++) {
intptr_t result_index = deopt_ids[i];
ASSERT(result.At(result_index) == Object::null());
result.SetAt(result_index, Object::Handle(ic_data_objs.At(i)));
}
return result.raw();
}
void Code::ExtractUncalledStaticCallDeoptIds(
GrowableArray<intptr_t>* deopt_ids) const {
ASSERT(!IsNull() && !is_optimized());
ASSERT(deopt_ids != NULL);
deopt_ids->Clear();
const PcDescriptors& descriptors =
PcDescriptors::Handle(this->pc_descriptors());
for (intptr_t i = 0; i < descriptors.Length(); i++) {
if (descriptors.DescriptorKind(i) == PcDescriptors::kFuncCall) {
// Static call.
const uword target_addr =
CodePatcher::GetStaticCallTargetAt(descriptors.PC(i), *this);
if (target_addr == StubCode::CallStaticFunctionEntryPoint()) {
deopt_ids->Add(descriptors.DeoptId(i));
}
}
}
}
RawStackmap* Code::GetStackmap(uword pc, Array* maps, Stackmap* map) const {
// This code is used during iterating frames during a GC and hence it
// should not in turn start a GC.
NoGCScope no_gc;
if (stackmaps() == Array::null()) {
// No stack maps are present in the code object which means this
// frame relies on tagged pointers.
return Stackmap::null();
}
// A stack map is present in the code object, use the stack map to visit
// frame slots which are marked as having objects.
*maps = stackmaps();
*map = Stackmap::null();
for (intptr_t i = 0; i < maps->Length(); i++) {
*map ^= maps->At(i);
ASSERT(!map->IsNull());
if (map->PC() == pc) {
return map->raw(); // We found a stack map for this frame.
}
}
// If the code has stackmaps, it must have them for all safepoints.
UNREACHABLE();
return Stackmap::null();
}
RawContext* Context::New(intptr_t num_variables, Heap::Space space) {
ASSERT(num_variables >= 0);
ASSERT(Object::context_class() != Class::null());
if (num_variables < 0 || num_variables > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in Context::New: invalid num_variables %"Pd"\n",
num_variables);
}
Context& result = Context::Handle();
{
RawObject* raw = Object::Allocate(Context::kClassId,
Context::InstanceSize(num_variables),
space);
NoGCScope no_gc;
result ^= raw;
result.set_num_variables(num_variables);
}
result.set_isolate(Isolate::Current());
return result.raw();
}
const char* Context::ToCString() const {
return "Context";
}
RawContextScope* ContextScope::New(intptr_t num_variables) {
ASSERT(Object::context_scope_class() != Class::null());
if (num_variables < 0 || num_variables > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in ContextScope::New: invalid num_variables %"Pd"\n",
num_variables);
}
intptr_t size = ContextScope::InstanceSize(num_variables);
ContextScope& result = ContextScope::Handle();
{
RawObject* raw = Object::Allocate(ContextScope::kClassId,
size,
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
result.set_num_variables(num_variables);
}
return result.raw();
}
intptr_t ContextScope::TokenIndexAt(intptr_t scope_index) const {
return Smi::Value(VariableDescAddr(scope_index)->token_pos);
}
void ContextScope::SetTokenIndexAt(intptr_t scope_index,
intptr_t token_pos) const {
VariableDescAddr(scope_index)->token_pos = Smi::New(token_pos);
}
RawString* ContextScope::NameAt(intptr_t scope_index) const {
return VariableDescAddr(scope_index)->name;
}
void ContextScope::SetNameAt(intptr_t scope_index, const String& name) const {
StorePointer(&(VariableDescAddr(scope_index)->name), name.raw());
}
bool ContextScope::IsFinalAt(intptr_t scope_index) const {
return Bool::Handle(VariableDescAddr(scope_index)->is_final).value();
}
void ContextScope::SetIsFinalAt(intptr_t scope_index, bool is_final) const {
VariableDescAddr(scope_index)->is_final = Bool::Get(is_final);
}
bool ContextScope::IsConstAt(intptr_t scope_index) const {
return Bool::Handle(VariableDescAddr(scope_index)->is_const).value();
}
void ContextScope::SetIsConstAt(intptr_t scope_index, bool is_const) const {
VariableDescAddr(scope_index)->is_const = Bool::Get(is_const);
}
RawAbstractType* ContextScope::TypeAt(intptr_t scope_index) const {
ASSERT(!IsConstAt(scope_index));
return VariableDescAddr(scope_index)->type;
}
void ContextScope::SetTypeAt(
intptr_t scope_index, const AbstractType& type) const {
StorePointer(&(VariableDescAddr(scope_index)->type), type.raw());
}
RawInstance* ContextScope::ConstValueAt(intptr_t scope_index) const {
ASSERT(IsConstAt(scope_index));
return VariableDescAddr(scope_index)->value;
}
void ContextScope::SetConstValueAt(
intptr_t scope_index, const Instance& value) const {
ASSERT(IsConstAt(scope_index));
StorePointer(&(VariableDescAddr(scope_index)->value), value.raw());
}
intptr_t ContextScope::ContextIndexAt(intptr_t scope_index) const {
return Smi::Value(VariableDescAddr(scope_index)->context_index);
}
void ContextScope::SetContextIndexAt(intptr_t scope_index,
intptr_t context_index) const {
VariableDescAddr(scope_index)->context_index = Smi::New(context_index);
}
intptr_t ContextScope::ContextLevelAt(intptr_t scope_index) const {
return Smi::Value(VariableDescAddr(scope_index)->context_level);
}
void ContextScope::SetContextLevelAt(intptr_t scope_index,
intptr_t context_level) const {
VariableDescAddr(scope_index)->context_level = Smi::New(context_level);
}
const char* ContextScope::ToCString() const {
return "ContextScope";
}
const char* ICData::ToCString() const {
const char* kFormat = "ICData target:'%s' num-checks: %"Pd"";
const String& name = String::Handle(target_name());
const intptr_t num = NumberOfChecks();
intptr_t len = OS::SNPrint(NULL, 0, kFormat, name.ToCString(), num) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, name.ToCString(), num);
return chars;
}
void ICData::set_function(const Function& value) const {
StorePointer(&raw_ptr()->function_, value.raw());
}
void ICData::set_target_name(const String& value) const {
StorePointer(&raw_ptr()->target_name_, value.raw());
}
void ICData::set_deopt_id(intptr_t value) const {
raw_ptr()->deopt_id_ = value;
}
void ICData::set_num_args_tested(intptr_t value) const {
raw_ptr()->num_args_tested_ = value;
}
void ICData::set_ic_data(const Array& value) const {
StorePointer(&raw_ptr()->ic_data_, value.raw());
}
void ICData::set_deopt_reason(intptr_t deopt_reason) const {
raw_ptr()->deopt_reason_ = deopt_reason;
}
void ICData::set_is_closure_call(bool value) const {
raw_ptr()->is_closure_call_ = value ? 1 : 0;
}
intptr_t ICData::TestEntryLengthFor(intptr_t num_args) {
return num_args + 1 /* target function*/ + 1 /* frequency */;
}
intptr_t ICData::TestEntryLength() const {
return TestEntryLengthFor(num_args_tested());
}
intptr_t ICData::NumberOfChecks() const {
// Do not count the sentinel;
return (Array::Handle(ic_data()).Length() / TestEntryLength()) - 1;
}
void ICData::WriteSentinel(const Array& data) const {
for (intptr_t i = 1; i <= TestEntryLength(); i++) {
data.SetAt(data.Length() - i, smi_illegal_cid());
}
}
#if defined(DEBUG)
// Used in asserts to verify that a check is not added twice.
bool ICData::HasCheck(const GrowableArray<intptr_t>& cids) const {
const intptr_t len = NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
GrowableArray<intptr_t> class_ids;
Function& target = Function::Handle();
GetCheckAt(i, &class_ids, &target);
bool matches = true;
for (intptr_t k = 0; k < class_ids.length(); k++) {
if (class_ids[k] != cids[k]) {
matches = false;
break;
}
}
if (matches) {
return true;
}
}
return false;
}
#endif // DEBUG
void ICData::AddCheck(const GrowableArray<intptr_t>& class_ids,
const Function& target) const {
DEBUG_ASSERT(!HasCheck(class_ids));
ASSERT(num_args_tested() > 1); // Otherwise use 'AddReceiverCheck'.
ASSERT(class_ids.length() == num_args_tested());
const intptr_t old_num = NumberOfChecks();
Array& data = Array::Handle(ic_data());
const intptr_t new_len = data.Length() + TestEntryLength();
data = Array::Grow(data, new_len, Heap::kOld);
set_ic_data(data);
WriteSentinel(data);
intptr_t data_pos = old_num * TestEntryLength();
Smi& value = Smi::Handle();
for (intptr_t i = 0; i < class_ids.length(); i++) {
// kIllegalCid is used as terminating value, do not add it.
ASSERT(class_ids[i] != kIllegalCid);
value = Smi::New(class_ids[i]);
data.SetAt(data_pos++, value);
}
ASSERT(!target.IsNull());
data.SetAt(data_pos++, target);
value = Smi::New(1);
data.SetAt(data_pos, value);
}
void ICData::AddReceiverCheck(intptr_t receiver_class_id,
const Function& target,
intptr_t count) const {
#if defined(DEBUG)
GrowableArray<intptr_t> class_ids(1);
class_ids.Add(receiver_class_id);
ASSERT(!HasCheck(class_ids));
#endif // DEBUG
ASSERT(num_args_tested() == 1); // Otherwise use 'AddCheck'.
ASSERT(receiver_class_id != kIllegalCid);
const intptr_t old_num = NumberOfChecks();
Array& data = Array::Handle(ic_data());
const intptr_t new_len = data.Length() + TestEntryLength();
data = Array::Grow(data, new_len, Heap::kOld);
set_ic_data(data);
WriteSentinel(data);
intptr_t data_pos = old_num * TestEntryLength();
if ((receiver_class_id == kSmiCid) && (data_pos > 0)) {
ASSERT(GetReceiverClassIdAt(0) != kSmiCid);
// Move class occupying position 0 to the data_pos.
for (intptr_t i = 0; i < TestEntryLength(); i++) {
data.SetAt(data_pos + i, Object::Handle(data.At(i)));
}
// Insert kSmiCid in position 0.
data_pos = 0;
}
data.SetAt(data_pos, Smi::Handle(Smi::New(receiver_class_id)));
data.SetAt(data_pos + 1, target);
data.SetAt(data_pos + 2, Smi::Handle(Smi::New(count)));
}
void ICData::GetCheckAt(intptr_t index,
GrowableArray<intptr_t>* class_ids,
Function* target) const {
ASSERT(index < NumberOfChecks());
ASSERT(class_ids != NULL);
ASSERT(target != NULL);
class_ids->Clear();
const Array& data = Array::Handle(ic_data());
intptr_t data_pos = index * TestEntryLength();
for (intptr_t i = 0; i < num_args_tested(); i++) {
class_ids->Add(Smi::Value(Smi::RawCast(data.At(data_pos++))));
}
(*target) ^= data.At(data_pos++);
}
void ICData::GetOneClassCheckAt(intptr_t index,
intptr_t* class_id,
Function* target) const {
ASSERT(class_id != NULL);
ASSERT(target != NULL);
ASSERT(num_args_tested() == 1);
const Array& data = Array::Handle(ic_data());
intptr_t data_pos = index * TestEntryLength();
*class_id = Smi::Value(Smi::RawCast(data.At(data_pos)));
*target ^= data.At(data_pos + 1);
}
intptr_t ICData::GetClassIdAt(intptr_t index, intptr_t arg_nr) const {
GrowableArray<intptr_t> class_ids;
Function& target = Function::Handle();
GetCheckAt(index, &class_ids, &target);
return class_ids[arg_nr];
}
intptr_t ICData::GetReceiverClassIdAt(intptr_t index) const {
ASSERT(index < NumberOfChecks());
const Array& data = Array::Handle(ic_data());
const intptr_t data_pos = index * TestEntryLength();
return Smi::Value(Smi::RawCast(data.At(data_pos)));
}
RawFunction* ICData::GetTargetAt(intptr_t index) const {
const Array& data = Array::Handle(ic_data());
const intptr_t data_pos = index * TestEntryLength() + num_args_tested();
ASSERT(Object::Handle(data.At(data_pos)).IsFunction());
return reinterpret_cast<RawFunction*>(data.At(data_pos));
}
void ICData::IncrementCountAt(intptr_t index, intptr_t value) const {
ASSERT(0 <= value);
ASSERT(value <= Smi::kMaxValue);
SetCountAt(index, Utils::Minimum(GetCountAt(index) + value, Smi::kMaxValue));
}
void ICData::SetCountAt(intptr_t index, intptr_t value) const {
ASSERT(0 <= value);
ASSERT(value <= Smi::kMaxValue);
const Array& data = Array::Handle(ic_data());
const intptr_t data_pos = index * TestEntryLength() +
CountIndexFor(num_args_tested());
data.SetAt(data_pos, Smi::Handle(Smi::New(value)));
}
intptr_t ICData::GetCountAt(intptr_t index) const {
const Array& data = Array::Handle(ic_data());
const intptr_t data_pos = index * TestEntryLength() +
CountIndexFor(num_args_tested());
return Smi::Value(Smi::RawCast(data.At(data_pos)));
}
intptr_t ICData::AggregateCount() const {
const intptr_t len = NumberOfChecks();
intptr_t count = 0;
for (intptr_t i = 0; i < len; i++) {
count += GetCountAt(i);
}
return count;
}
RawFunction* ICData::GetTargetForReceiverClassId(intptr_t class_id) const {
const intptr_t len = NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
if (GetReceiverClassIdAt(i) == class_id) {
return GetTargetAt(i);
}
}
return Function::null();
}
RawICData* ICData::AsUnaryClassChecksForArgNr(intptr_t arg_nr) const {
ASSERT(!IsNull());
ASSERT(num_args_tested() > arg_nr);
if ((arg_nr == 0) && (num_args_tested() == 1)) {
// Frequent case.
return raw();
}
const intptr_t kNumArgsTested = 1;
ICData& result = ICData::Handle(ICData::New(
Function::Handle(function()),
String::Handle(target_name()),
deopt_id(),
kNumArgsTested));
const intptr_t len = NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
const intptr_t class_id = GetClassIdAt(i, arg_nr);
const intptr_t count = GetCountAt(i);
intptr_t duplicate_class_id = -1;
const intptr_t result_len = result.NumberOfChecks();
for (intptr_t k = 0; k < result_len; k++) {
if (class_id == result.GetReceiverClassIdAt(k)) {
duplicate_class_id = k;
break;
}
}
if (duplicate_class_id >= 0) {
// This check is valid only when checking the receiver.
ASSERT((arg_nr != 0) ||
(result.GetTargetAt(duplicate_class_id) == GetTargetAt(i)));
result.IncrementCountAt(duplicate_class_id, count);
} else {
// This will make sure that Smi is first if it exists.
result.AddReceiverCheck(class_id,
Function::Handle(GetTargetAt(i)),
count);
}
}
// Copy deoptimization reason.
result.set_deopt_reason(this->deopt_reason());
return result.raw();
}
bool ICData::AllTargetsHaveSameOwner(intptr_t owner_cid) const {
if (NumberOfChecks() == 0) return false;
Class& cls = Class::Handle();
const intptr_t len = NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
cls = Function::Handle(GetTargetAt(i)).Owner();
if (cls.id() != owner_cid) {
return false;
}
}
return true;
}
bool ICData::AllReceiversAreNumbers() const {
if (NumberOfChecks() == 0) return false;
Class& cls = Class::Handle();
const intptr_t len = NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
cls = Function::Handle(GetTargetAt(i)).Owner();
const intptr_t cid = cls.id();
if ((cid != kSmiCid) &&
(cid != kMintCid) &&
(cid != kBigintCid) &&
(cid != kDoubleCid)) {
return false;
}
}
return true;
}
bool ICData::HasReceiverClassId(intptr_t class_id) const {
ASSERT(num_args_tested() > 0);
const intptr_t len = NumberOfChecks();
for (intptr_t i = 0; i < len; i++) {
const intptr_t test_class_id = GetReceiverClassIdAt(i);
if (test_class_id == class_id) {
return true;
}
}
return false;
}
// Returns true if all targets are the same.
// TODO(srdjan): if targets are native use their C_function to compare.
bool ICData::HasOneTarget() const {
ASSERT(NumberOfChecks() > 0);
const Function& first_target = Function::Handle(GetTargetAt(0));
const intptr_t len = NumberOfChecks();
for (intptr_t i = 1; i < len; i++) {
if (GetTargetAt(i) != first_target.raw()) {
return false;
}
}
return true;
}
RawICData* ICData::New(const Function& function,
const String& target_name,
intptr_t deopt_id,
intptr_t num_args_tested) {
ASSERT(Object::icdata_class() != Class::null());
ASSERT(num_args_tested > 0);
ICData& result = ICData::Handle();
{
// IC data objects are long living objects, allocate them in old generation.
RawObject* raw = Object::Allocate(ICData::kClassId,
ICData::InstanceSize(),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
}
result.set_function(function);
result.set_target_name(target_name);
result.set_deopt_id(deopt_id);
result.set_num_args_tested(num_args_tested);
result.set_deopt_reason(kDeoptUnknown);
result.set_is_closure_call(false);
// Number of array elements in one test entry.
intptr_t len = result.TestEntryLength();
// IC data array must be null terminated (sentinel entry).
const Array& ic_data = Array::Handle(Array::New(len, Heap::kOld));
result.set_ic_data(ic_data);
result.WriteSentinel(ic_data);
return result.raw();
}
RawArray* MegamorphicCache::buckets() const {
return raw_ptr()->buckets_;
}
void MegamorphicCache::set_buckets(const Array& buckets) const {
StorePointer(&raw_ptr()->buckets_, buckets.raw());
}
// Class IDs in the table are smi-tagged, so we use a smi-tagged mask
// and target class ID to avoid untagging (on each iteration of the
// test loop) in generated code.
intptr_t MegamorphicCache::mask() const {
return Smi::Value(raw_ptr()->mask_);
}
void MegamorphicCache::set_mask(intptr_t mask) const {
raw_ptr()->mask_ = Smi::New(mask);
}
intptr_t MegamorphicCache::filled_entry_count() const {
return raw_ptr()->filled_entry_count_;
}
void MegamorphicCache::set_filled_entry_count(intptr_t count) const {
raw_ptr()->filled_entry_count_ = count;
}
RawMegamorphicCache* MegamorphicCache::New() {
MegamorphicCache& result = MegamorphicCache::Handle();
{ RawObject* raw = Object::Allocate(MegamorphicCache::kClassId,
MegamorphicCache::InstanceSize(),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
}
const intptr_t capacity = kInitialCapacity;
const Array& buckets = Array::Handle(Array::New(kEntryLength * capacity));
const Function& handler = Function::Handle(
Isolate::Current()->megamorphic_cache_table()->miss_handler());
for (intptr_t i = 0; i < capacity; ++i) {
SetEntry(buckets, i, smi_illegal_cid(), handler);
}
result.set_buckets(buckets);
result.set_mask(capacity - 1);
result.set_filled_entry_count(0);
return result.raw();
}
void MegamorphicCache::EnsureCapacity() const {
intptr_t old_capacity = mask() + 1;
double load_limit = kLoadFactor * static_cast<double>(old_capacity);
if (static_cast<double>(filled_entry_count() + 1) > load_limit) {
const Array& old_buckets = Array::Handle(buckets());
intptr_t new_capacity = old_capacity * 2;
const Array& new_buckets =
Array::Handle(Array::New(kEntryLength * new_capacity));
Function& target = Function::Handle(
Isolate::Current()->megamorphic_cache_table()->miss_handler());
for (intptr_t i = 0; i < new_capacity; ++i) {
SetEntry(new_buckets, i, smi_illegal_cid(), target);
}
set_buckets(new_buckets);
set_mask(new_capacity - 1);
set_filled_entry_count(0);
// Rehash the valid entries.
Smi& class_id = Smi::Handle();
for (intptr_t i = 0; i < old_capacity; ++i) {
class_id ^= GetClassId(old_buckets, i);
if (class_id.Value() != kIllegalCid) {
target ^= GetTargetFunction(old_buckets, i);
Insert(class_id, target);
}
}
}
}
void MegamorphicCache::Insert(const Smi& class_id,
const Function& target) const {
ASSERT(static_cast<double>(filled_entry_count() + 1) <=
(kLoadFactor * static_cast<double>(mask() + 1)));
const Array& backing_array = Array::Handle(buckets());
intptr_t id_mask = mask();
intptr_t index = class_id.Value() & id_mask;
intptr_t i = index;
do {
if (Smi::Value(Smi::RawCast(GetClassId(backing_array, i))) == kIllegalCid) {
SetEntry(backing_array, i, class_id, target);
set_filled_entry_count(filled_entry_count() + 1);
return;
}
i = (i + 1) & id_mask;
} while (i != index);
UNREACHABLE();
}
const char* MegamorphicCache::ToCString() const {
return "";
}
RawSubtypeTestCache* SubtypeTestCache::New() {
ASSERT(Object::subtypetestcache_class() != Class::null());
SubtypeTestCache& result = SubtypeTestCache::Handle();
{
// SubtypeTestCache objects are long living objects, allocate them in the
// old generation.
RawObject* raw = Object::Allocate(SubtypeTestCache::kClassId,
SubtypeTestCache::InstanceSize(),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
}
const Array& cache = Array::Handle(Array::New(kTestEntryLength));
result.set_cache(cache);
return result.raw();
}
void SubtypeTestCache::set_cache(const Array& value) const {
StorePointer(&raw_ptr()->cache_, value.raw());
}
intptr_t SubtypeTestCache::NumberOfChecks() const {
// Do not count the sentinel;
return (Array::Handle(cache()).Length() / kTestEntryLength) - 1;
}
void SubtypeTestCache::AddCheck(
intptr_t instance_class_id,
const AbstractTypeArguments& instance_type_arguments,
const AbstractTypeArguments& instantiator_type_arguments,
const Bool& test_result) const {
intptr_t old_num = NumberOfChecks();
Array& data = Array::Handle(cache());
intptr_t new_len = data.Length() + kTestEntryLength;
data = Array::Grow(data, new_len);
set_cache(data);
intptr_t data_pos = old_num * kTestEntryLength;
data.SetAt(data_pos + kInstanceClassId,
Smi::Handle(Smi::New(instance_class_id)));
data.SetAt(data_pos + kInstanceTypeArguments, instance_type_arguments);
data.SetAt(data_pos + kInstantiatorTypeArguments,
instantiator_type_arguments);
data.SetAt(data_pos + kTestResult, test_result);
}
void SubtypeTestCache::GetCheck(
intptr_t ix,
intptr_t* instance_class_id,
AbstractTypeArguments* instance_type_arguments,
AbstractTypeArguments* instantiator_type_arguments,
Bool* test_result) const {
Array& data = Array::Handle(cache());
intptr_t data_pos = ix * kTestEntryLength;
*instance_class_id =
Smi::Value(Smi::RawCast(data.At(data_pos + kInstanceClassId)));
*instance_type_arguments ^= data.At(data_pos + kInstanceTypeArguments);
*instantiator_type_arguments ^=
data.At(data_pos + kInstantiatorTypeArguments);
*test_result ^= data.At(data_pos + kTestResult);
}
const char* SubtypeTestCache::ToCString() const {
return "SubtypeTestCache";
}
const char* Error::ToErrorCString() const {
UNREACHABLE();
return "Internal Error";
}
const char* Error::ToCString() const {
// Error is an abstract class. We should never reach here.
UNREACHABLE();
return "Error";
}
RawApiError* ApiError::New() {
ASSERT(Object::api_error_class() != Class::null());
RawObject* raw = Object::Allocate(ApiError::kClassId,
ApiError::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawApiError*>(raw);
}
RawApiError* ApiError::New(const String& message, Heap::Space space) {
ASSERT(Object::api_error_class() != Class::null());
ApiError& result = ApiError::Handle();
{
RawObject* raw = Object::Allocate(ApiError::kClassId,
ApiError::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_message(message);
return result.raw();
}
void ApiError::set_message(const String& message) const {
StorePointer(&raw_ptr()->message_, message.raw());
}
const char* ApiError::ToErrorCString() const {
const String& msg_str = String::Handle(message());
return msg_str.ToCString();
}
const char* ApiError::ToCString() const {
return "ApiError";
}
RawLanguageError* LanguageError::New() {
ASSERT(Object::language_error_class() != Class::null());
RawObject* raw = Object::Allocate(LanguageError::kClassId,
LanguageError::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawLanguageError*>(raw);
}
RawLanguageError* LanguageError::New(const String& message, Heap::Space space) {
ASSERT(Object::language_error_class() != Class::null());
LanguageError& result = LanguageError::Handle();
{
RawObject* raw = Object::Allocate(LanguageError::kClassId,
LanguageError::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_message(message);
return result.raw();
}
void LanguageError::set_message(const String& message) const {
StorePointer(&raw_ptr()->message_, message.raw());
}
const char* LanguageError::ToErrorCString() const {
const String& msg_str = String::Handle(message());
return msg_str.ToCString();
}
const char* LanguageError::ToCString() const {
return "LanguageError";
}
RawUnhandledException* UnhandledException::New(const Instance& exception,
const Instance& stacktrace,
Heap::Space space) {
ASSERT(Object::unhandled_exception_class() != Class::null());
UnhandledException& result = UnhandledException::Handle();
{
RawObject* raw = Object::Allocate(UnhandledException::kClassId,
UnhandledException::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_exception(exception);
result.set_stacktrace(stacktrace);
return result.raw();
}
void UnhandledException::set_exception(const Instance& exception) const {
StorePointer(&raw_ptr()->exception_, exception.raw());
}
void UnhandledException::set_stacktrace(const Instance& stacktrace) const {
StorePointer(&raw_ptr()->stacktrace_, stacktrace.raw());
}
const char* UnhandledException::ToErrorCString() const {
Isolate* isolate = Isolate::Current();
if (exception() == isolate->object_store()->out_of_memory()) {
return "Unhandled exception:\nOut of memory";
}
if (exception() == isolate->object_store()->stack_overflow()) {
return "Unhandled exception:\nStack overflow";
}
HANDLESCOPE(isolate);
Object& strtmp = Object::Handle();
const Instance& exc = Instance::Handle(exception());
strtmp = DartLibraryCalls::ToString(exc);
const char* exc_str =
"<Received error while converting exception to string>";
if (!strtmp.IsError()) {
exc_str = strtmp.ToCString();
}
const Instance& stack = Instance::Handle(stacktrace());
strtmp = DartLibraryCalls::ToString(stack);
const char* stack_str =
"<Received error while converting stack trace to string>";
if (!strtmp.IsError()) {
stack_str = strtmp.ToCString();
}
const char* format = "Unhandled exception:\n%s\n%s";
int len = (strlen(exc_str) + strlen(stack_str) + strlen(format)
- 4 // Two '%s'
+ 1); // '\0'
char* chars = isolate->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, exc_str, stack_str);
return chars;
}
const char* UnhandledException::ToCString() const {
return "UnhandledException";
}
RawUnwindError* UnwindError::New(const String& message, Heap::Space space) {
ASSERT(Object::unwind_error_class() != Class::null());
UnwindError& result = UnwindError::Handle();
{
RawObject* raw = Object::Allocate(UnwindError::kClassId,
UnwindError::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_message(message);
return result.raw();
}
void UnwindError::set_message(const String& message) const {
StorePointer(&raw_ptr()->message_, message.raw());
}
const char* UnwindError::ToErrorCString() const {
const String& msg_str = String::Handle(message());
return msg_str.ToCString();
}
const char* UnwindError::ToCString() const {
return "UnwindError";
}
bool Instance::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
return true; // "===".
}
if (other.IsNull() || (this->clazz() != other.clazz())) {
return false;
}
{
NoGCScope no_gc;
// Raw bits compare.
const intptr_t instance_size = Class::Handle(this->clazz()).instance_size();
ASSERT(instance_size != 0);
uword this_addr = reinterpret_cast<uword>(this->raw_ptr());
uword other_addr = reinterpret_cast<uword>(other.raw_ptr());
for (intptr_t offset = sizeof(RawObject);
offset < instance_size;
offset += kWordSize) {
if ((*reinterpret_cast<RawObject**>(this_addr + offset)) !=
(*reinterpret_cast<RawObject**>(other_addr + offset))) {
return false;
}
}
}
return true;
}
RawInstance* Instance::CheckAndCanonicalize(const char** error_str) const {
ASSERT(!IsNull());
if (this->IsCanonical()) {
return this->raw();
}
Instance& result = Instance::Handle();
const Class& cls = Class::Handle(this->clazz());
// TODO(srdjan): Check that predefined classes do not have fields that need
// to be checked/canonicalized as well.
if ((cls.id() >= kNumPredefinedCids) || cls.IsArray()) {
// Iterate over all fields, canonicalize numbers and strings, expect all
// other instances to be canonical otherwise report error (return
// Instance::null()).
Object& obj = Object::Handle();
const intptr_t end_field_offset = cls.instance_size() - kWordSize;
for (intptr_t field_offset = 0;
field_offset <= end_field_offset;
field_offset += kWordSize) {
obj = *this->FieldAddrAtOffset(field_offset);
if (obj.IsInstance() && !obj.IsSmi() && !obj.IsCanonical()) {
if (obj.IsNumber() || obj.IsString()) {
obj = Instance::Cast(obj).CheckAndCanonicalize(NULL);
ASSERT(!obj.IsNull());
this->SetFieldAtOffset(field_offset, obj);
} else {
ASSERT(error_str != NULL);
const char* kFormat = "field: %s\n";
const intptr_t len =
OS::SNPrint(NULL, 0, kFormat, obj.ToCString()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, obj.ToCString());
*error_str = chars;
return Instance::null();
}
}
}
}
Array& constants = Array::Handle(cls.constants());
const intptr_t constants_len = constants.Length();
// Linear search to see whether this value is already present in the
// list of canonicalized constants.
intptr_t index = 0;
while (index < constants_len) {
result ^= constants.At(index);
if (result.IsNull()) {
break;
}
if (this->Equals(result)) {
return result.raw();
}
index++;
}
// The value needs to be added to the list. Grow the list if
// it is full.
result ^= this->raw();
if (result.IsNew()) {
// Create a canonical object in old space.
result ^= Object::Clone(result, Heap::kOld);
}
ASSERT(result.IsOld());
cls.InsertCanonicalConstant(index, result);
result.SetCanonical();
return result.raw();
}
RawType* Instance::GetType() const {
if (IsNull()) {
return Type::NullType();
}
const Class& cls = Class::Handle(clazz());
AbstractTypeArguments& type_arguments = AbstractTypeArguments::Handle();
if (cls.HasTypeArguments()) {
type_arguments = GetTypeArguments();
}
const Type& type = Type::Handle(
Type::New(cls, type_arguments, Scanner::kDummyTokenIndex));
type.SetIsFinalized();
return type.raw();
}
RawAbstractTypeArguments* Instance::GetTypeArguments() const {
const Class& cls = Class::Handle(clazz());
intptr_t field_offset = cls.type_arguments_field_offset();
ASSERT(field_offset != Class::kNoTypeArguments);
AbstractTypeArguments& type_arguments = AbstractTypeArguments::Handle();
type_arguments ^= *FieldAddrAtOffset(field_offset);
return type_arguments.raw();
}
void Instance::SetTypeArguments(const AbstractTypeArguments& value) const {
const Class& cls = Class::Handle(clazz());
intptr_t field_offset = cls.type_arguments_field_offset();
ASSERT(field_offset != Class::kNoTypeArguments);
SetFieldAtOffset(field_offset, value);
}
bool Instance::IsInstanceOf(const AbstractType& other,
const AbstractTypeArguments& other_instantiator,
Error* malformed_error) const {
ASSERT(other.IsFinalized());
ASSERT(!other.IsDynamicType());
ASSERT(!other.IsMalformed());
if (other.IsVoidType()) {
return false;
}
const Class& cls = Class::Handle(clazz());
AbstractTypeArguments& type_arguments = AbstractTypeArguments::Handle();
const intptr_t num_type_arguments = cls.NumTypeArguments();
if (num_type_arguments > 0) {
type_arguments = GetTypeArguments();
if (!type_arguments.IsNull() && !type_arguments.IsCanonical()) {
type_arguments = type_arguments.Canonicalize();
SetTypeArguments(type_arguments);
}
// The number of type arguments in the instance must be greater or equal to
// the number of type arguments expected by the instance class.
// A discrepancy is allowed for closures, which borrow the type argument
// vector of their instantiator, which may be of a subclass of the class
// defining the closure. Truncating the vector to the correct length on
// instantiation is unnecessary. The vector may therefore be longer.
// Also, an optimization reuses the type argument vector of the instantiator
// of generic instances when its layout is compatible.
ASSERT(type_arguments.IsNull() ||
(type_arguments.Length() >= num_type_arguments));
}
Class& other_class = Class::Handle();
AbstractTypeArguments& other_type_arguments = AbstractTypeArguments::Handle();
// Note that we may encounter a bound error in checked mode.
if (!other.IsInstantiated()) {
const AbstractType& instantiated_other = AbstractType::Handle(
other.InstantiateFrom(other_instantiator, malformed_error));
if ((malformed_error != NULL) && !malformed_error->IsNull()) {
ASSERT(FLAG_enable_type_checks);
return false;
}
other_class = instantiated_other.type_class();
other_type_arguments = instantiated_other.arguments();
} else {
other_class = other.type_class();
other_type_arguments = other.arguments();
}
return cls.IsSubtypeOf(type_arguments, other_class, other_type_arguments,
malformed_error);
}
void Instance::SetNativeField(int index, intptr_t value) const {
ASSERT(IsValidNativeIndex(index));
Object& native_fields = Object::Handle(*NativeFieldsAddr());
if (native_fields.IsNull()) {
// Allocate backing storage for the native fields.
const Class& cls = Class::Handle(clazz());
int num_native_fields = cls.num_native_fields();
native_fields = TypedData::New(kIntPtrCid, num_native_fields);
StorePointer(NativeFieldsAddr(), native_fields.raw());
}
intptr_t byte_offset = index * sizeof(intptr_t);
TypedData::Cast(native_fields).SetIntPtr(byte_offset, value);
}
bool Instance::IsClosure() const {
const Class& cls = Class::Handle(clazz());
return cls.IsSignatureClass();
}
bool Instance::IsCallable(Function* function, Context* context) const {
Class& cls = Class::Handle(clazz());
if (cls.IsSignatureClass()) {
if (function != NULL) {
*function = Closure::function(*this);
}
if (context != NULL) {
*context = Closure::context(*this);
}
return true;
}
// Try to resolve a "call" method.
Function& call_function = Function::Handle();
do {
call_function = cls.LookupDynamicFunction(Symbols::Call());
if (!call_function.IsNull()) {
if (function != NULL) {
*function = call_function.raw();
}
if (context != NULL) {
*context = Isolate::Current()->object_store()->empty_context();
}
return true;
}
cls = cls.SuperClass();
} while (!cls.IsNull());
return false;
}
RawInstance* Instance::New(const Class& cls, Heap::Space space) {
Isolate* isolate = Isolate::Current();
if (cls.EnsureIsFinalized(isolate) != Error::null()) {
return Instance::null();
}
intptr_t instance_size = cls.instance_size();
ASSERT(instance_size > 0);
RawObject* raw = Object::Allocate(cls.id(), instance_size, space);
return reinterpret_cast<RawInstance*>(raw);
}
bool Instance::IsValidFieldOffset(int offset) const {
const Class& cls = Class::Handle(clazz());
return (offset >= 0 && offset <= (cls.instance_size() - kWordSize));
}
const char* Instance::ToCString() const {
if (IsNull()) {
return "null";
} else if (raw() == Object::sentinel().raw()) {
return "sentinel";
} else if (raw() == Object::transition_sentinel().raw()) {
return "transition_sentinel";
} else if (raw() == Object::unknown_constant().raw()) {
return "unknown_constant";
} else if (raw() == Object::non_constant().raw()) {
return "non_constant";
} else if (Isolate::Current()->no_gc_scope_depth() > 0) {
// Can occur when running disassembler.
return "Instance";
} else {
if (IsClosure()) {
return Closure::ToCString(*this);
}
const char* kFormat = "Instance of '%s'";
const Class& cls = Class::Handle(clazz());
AbstractTypeArguments& type_arguments = AbstractTypeArguments::Handle();
const intptr_t num_type_arguments = cls.NumTypeArguments();
if (num_type_arguments > 0) {
type_arguments = GetTypeArguments();
}
const Type& type =
Type::Handle(Type::New(cls, type_arguments, Scanner::kDummyTokenIndex));
const String& type_name = String::Handle(type.Name());
// Calculate the size of the string.
intptr_t len = OS::SNPrint(NULL, 0, kFormat, type_name.ToCString()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, type_name.ToCString());
return chars;
}
}
bool AbstractType::IsResolved() const {
// AbstractType is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractType::HasResolvedTypeClass() const {
// AbstractType is an abstract class.
UNREACHABLE();
return false;
}
RawClass* AbstractType::type_class() const {
// AbstractType is an abstract class.
UNREACHABLE();
return Class::null();
}
RawUnresolvedClass* AbstractType::unresolved_class() const {
// AbstractType is an abstract class.
UNREACHABLE();
return UnresolvedClass::null();
}
RawAbstractTypeArguments* AbstractType::arguments() const {
// AbstractType is an abstract class.
UNREACHABLE();
return NULL;
}
intptr_t AbstractType::token_pos() const {
// AbstractType is an abstract class.
UNREACHABLE();
return -1;
}
bool AbstractType::IsInstantiated() const {
// AbstractType is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractType::IsFinalized() const {
// AbstractType is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractType::IsBeingFinalized() const {
// AbstractType is an abstract class.
UNREACHABLE();
return false;
}
bool AbstractType::IsMalformed() const {
// AbstractType is an abstract class.
UNREACHABLE();
return false;
}
RawError* AbstractType::malformed_error() const {
// AbstractType is an abstract class.
UNREACHABLE();
return Error::null();
}
void AbstractType::set_malformed_error(const Error& value) const {
// AbstractType is an abstract class.
UNREACHABLE();
}
bool AbstractType::Equals(const Instance& other) const {
// AbstractType is an abstract class.
ASSERT(raw() == AbstractType::null());
return other.IsNull();
}
RawAbstractType* AbstractType::InstantiateFrom(
const AbstractTypeArguments& instantiator_type_arguments,
Error* malformed_error) const {
// AbstractType is an abstract class.
UNREACHABLE();
return NULL;
}
RawAbstractType* AbstractType::Canonicalize() const {
// AbstractType is an abstract class.
UNREACHABLE();
return NULL;
}
RawString* AbstractType::BuildName(NameVisibility name_visibility) const {
if (IsBoundedType()) {
// TODO(regis): Should the bound be visible in the name for debug purposes
// if name_visibility is kInternalName?
const AbstractType& type = AbstractType::Handle(
BoundedType::Cast(*this).type());
return type.BuildName(name_visibility);
}
if (IsTypeParameter()) {
return TypeParameter::Cast(*this).name();
}
// If the type is still being finalized, we may be reporting an error about
// a malformed type, so proceed with caution.
const AbstractTypeArguments& args =
AbstractTypeArguments::Handle(arguments());
const intptr_t num_args = args.IsNull() ? 0 : args.Length();
String& class_name = String::Handle();
intptr_t first_type_param_index;
intptr_t num_type_params; // Number of type parameters to print.
if (HasResolvedTypeClass()) {
const Class& cls = Class::Handle(type_class());
num_type_params = cls.NumTypeParameters(); // Do not print the full vector.
if (name_visibility == kInternalName) {
class_name = cls.Name();
} else {
ASSERT(name_visibility == kUserVisibleName);
// Map internal types to their corresponding public interfaces.
class_name = cls.UserVisibleName();
}
if (num_type_params > num_args) {
first_type_param_index = 0;
if (!IsFinalized() || IsBeingFinalized() || IsMalformed()) {
// Most probably a malformed type. Do not fill up with "dynamic",
// but use actual vector.
num_type_params = num_args;
} else {
ASSERT(num_args == 0); // Type is raw.
// No need to fill up with "dynamic".
num_type_params = 0;
}
} else {
// The actual type argument vector can be longer than necessary, because
// of type optimizations.
if (IsFinalized() && cls.is_type_finalized()) {
first_type_param_index = cls.NumTypeArguments() - num_type_params;
} else {
first_type_param_index = num_args - num_type_params;
}
}
if (cls.IsSignatureClass()) {
// We may be reporting an error about a malformed function type. In that
// case, avoid instantiating the signature, since it may lead to cycles.
if (!IsFinalized() || IsBeingFinalized() || IsMalformed()) {
return class_name.raw();
}
// In order to avoid cycles, print the name of a typedef (non-canonical
// signature class) as a regular, possibly parameterized, class.
if (cls.IsCanonicalSignatureClass()) {
const Function& signature_function = Function::Handle(
cls.signature_function());
// Signature classes have no super type, however, they take as many
// type arguments as the owner class of their signature function (if it
// is non static and generic, see Class::NumTypeArguments()). Therefore,
// first_type_param_index may be greater than 0 here.
return signature_function.InstantiatedSignatureFrom(args,
name_visibility);
}
}
} else {
const UnresolvedClass& cls = UnresolvedClass::Handle(unresolved_class());
class_name = cls.Name();
num_type_params = num_args;
first_type_param_index = 0;
}
String& type_name = String::Handle();
if (num_type_params == 0) {
type_name = class_name.raw();
} else {
const String& args_name = String::Handle(
args.SubvectorName(first_type_param_index,
num_type_params,
name_visibility));
type_name = String::Concat(class_name, args_name);
}
// The name is only used for type checking and debugging purposes.
// Unless profiling data shows otherwise, it is not worth caching the name in
// the type.
return Symbols::New(type_name);
}
RawString* AbstractType::ClassName() const {
if (HasResolvedTypeClass()) {
return Class::Handle(type_class()).Name();
} else {
return UnresolvedClass::Handle(unresolved_class()).Name();
}
}
bool AbstractType::IsBoolType() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::BoolType()).type_class());
}
bool AbstractType::IsIntType() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::IntType()).type_class());
}
bool AbstractType::IsDoubleType() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::Double()).type_class());
}
bool AbstractType::IsFloat32x4Type() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::Float32x4()).type_class());
}
bool AbstractType::IsUint32x4Type() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::Uint32x4()).type_class());
}
bool AbstractType::IsNumberType() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::Number()).type_class());
}
bool AbstractType::IsStringType() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::StringType()).type_class());
}
bool AbstractType::IsFunctionType() const {
return HasResolvedTypeClass() &&
(type_class() == Type::Handle(Type::Function()).type_class());
}
bool AbstractType::TypeTest(TypeTestKind test_kind,
const AbstractType& other,
Error* malformed_error) const {
ASSERT(IsResolved());
ASSERT(other.IsResolved());
// In case the type checked in a type test is malformed, the code generator
// may compile a throw instead of a run time call performing the type check.
// However, in checked mode, a function type may include malformed result type
// and/or malformed parameter types, which will then be encountered here at
// run time.
if (IsMalformed()) {
ASSERT(FLAG_enable_type_checks);
if ((malformed_error != NULL) && malformed_error->IsNull()) {
*malformed_error = this->malformed_error();
}
return false;
}
if (other.IsMalformed()) {
// Note that 'other' may represent an unresolved bound that is checked at
// compile time, even in production mode, in which case the resulting
// BoundedType is ignored at run time if in production mode.
// Therefore, we cannot assert that we are in checked mode here.
if ((malformed_error != NULL) && malformed_error->IsNull()) {
*malformed_error = other.malformed_error();
}
return false;
}
if (IsBoundedType() || other.IsBoundedType()) {
if (Equals(other)) {
return true;
}
return false; // TODO(regis): We should return "maybe after instantiation".
}
// Type parameters cannot be handled by Class::TypeTest().
// When comparing two uninstantiated function types, one returning type
// parameter K, the other returning type parameter V, we cannot assume that K
// is a subtype of V, or vice versa. We only return true if K equals V, as
// defined by TypeParameter::Equals.
// The same rule applies when checking the upper bound of a still
// uninstantiated type at compile time. Returning false will defer the test
// to run time.
// There are however some cases can be decided at compile time.
// For example, with class A<K, V extends K>, new A<T, T> called from within
// a class B<T> will never require a run time bound check, even if T is
// uninstantiated at compile time.
if (IsTypeParameter()) {
const TypeParameter& type_param = TypeParameter::Cast(*this);
if (other.IsTypeParameter()) {
const TypeParameter& other_type_param = TypeParameter::Cast(other);
if (type_param.Equals(other_type_param)) {
return true;
}
}
const AbstractType& bound = AbstractType::Handle(type_param.bound());
if (bound.IsMoreSpecificThan(other, malformed_error)) {
return true;
}
return false; // TODO(regis): We should return "maybe after instantiation".
}
if (other.IsTypeParameter()) {
return false; // TODO(regis): We should return "maybe after instantiation".
}
const Class& cls = Class::Handle(type_class());
return cls.TypeTest(test_kind,
AbstractTypeArguments::Handle(arguments()),
Class::Handle(other.type_class()),
AbstractTypeArguments::Handle(other.arguments()),
malformed_error);
}
intptr_t AbstractType::Hash() const {
// AbstractType is an abstract class.
UNREACHABLE();
return 0;
}
const char* AbstractType::ToCString() const {
// AbstractType is an abstract class.
UNREACHABLE();
return "AbstractType";
}
RawType* Type::NullType() {
return Isolate::Current()->object_store()->null_type();
}
RawType* Type::DynamicType() {
return Isolate::Current()->object_store()->dynamic_type();
}
RawType* Type::VoidType() {
return Isolate::Current()->object_store()->void_type();
}
RawType* Type::ObjectType() {
return Isolate::Current()->object_store()->object_type();
}
RawType* Type::BoolType() {
return Isolate::Current()->object_store()->bool_type();
}
RawType* Type::IntType() {
return Isolate::Current()->object_store()->int_type();
}
RawType* Type::SmiType() {
return Isolate::Current()->object_store()->smi_type();
}
RawType* Type::MintType() {
return Isolate::Current()->object_store()->mint_type();
}
RawType* Type::Double() {
return Isolate::Current()->object_store()->double_type();
}
RawType* Type::Float32x4() {
return Isolate::Current()->object_store()->float32x4_type();
}
RawType* Type::Uint32x4() {
return Isolate::Current()->object_store()->uint32x4_type();
}
RawType* Type::Number() {
return Isolate::Current()->object_store()->number_type();
}
RawType* Type::StringType() {
return Isolate::Current()->object_store()->string_type();
}
RawType* Type::ArrayType() {
return Isolate::Current()->object_store()->array_type();
}
RawType* Type::Function() {
return Isolate::Current()->object_store()->function_type();
}
RawType* Type::NewNonParameterizedType(const Class& type_class) {
ASSERT(!type_class.HasTypeArguments());
const TypeArguments& no_type_arguments = TypeArguments::Handle();
Type& type = Type::Handle();
type ^= Type::New(Object::Handle(type_class.raw()),
no_type_arguments,
Scanner::kDummyTokenIndex);
type.SetIsFinalized();
type ^= type.Canonicalize();
return type.raw();
}
void Type::SetIsFinalized() const {
ASSERT(!IsFinalized());
if (IsInstantiated()) {
set_type_state(RawType::kFinalizedInstantiated);
} else {
set_type_state(RawType::kFinalizedUninstantiated);
}
}
void Type::set_is_being_finalized() const {
ASSERT(!IsFinalized() && !IsBeingFinalized());
set_type_state(RawType::kBeingFinalized);
}
bool Type::IsMalformed() const {
return raw_ptr()->malformed_error_ != Error::null();
}
void Type::set_malformed_error(const Error& value) const {
StorePointer(&raw_ptr()->malformed_error_, value.raw());
}
RawError* Type::malformed_error() const {
ASSERT(IsMalformed());
return raw_ptr()->malformed_error_;
}
bool Type::IsResolved() const {
if (IsFinalized()) {
return true;
}
if (!HasResolvedTypeClass()) {
return false;
}
const AbstractTypeArguments& args =
AbstractTypeArguments::Handle(arguments());
return args.IsNull() || args.IsResolved();
}
bool Type::HasResolvedTypeClass() const {
const Object& type_class = Object::Handle(raw_ptr()->type_class_);
return !type_class.IsNull() && type_class.IsClass();
}
RawClass* Type::type_class() const {
ASSERT(HasResolvedTypeClass());
#ifdef DEBUG
Class& type_class = Class::Handle();
type_class ^= raw_ptr()->type_class_;
return type_class.raw();
#else
return reinterpret_cast<RawClass*>(raw_ptr()->type_class_);
#endif
}
RawUnresolvedClass* Type::unresolved_class() const {
ASSERT(!HasResolvedTypeClass());
#ifdef DEBUG
UnresolvedClass& unresolved_class = UnresolvedClass::Handle();
unresolved_class ^= raw_ptr()->type_class_;
ASSERT(!unresolved_class.IsNull());
return unresolved_class.raw();
#else
ASSERT(!Object::Handle(raw_ptr()->type_class_).IsNull());
ASSERT(Object::Handle(raw_ptr()->type_class_).IsUnresolvedClass());
return reinterpret_cast<RawUnresolvedClass*>(raw_ptr()->type_class_);
#endif
}
RawString* Type::TypeClassName() const {
if (HasResolvedTypeClass()) {
const Class& cls = Class::Handle(type_class());
return cls.Name();
} else {
const UnresolvedClass& cls = UnresolvedClass::Handle(unresolved_class());
return cls.Name();
}
}
RawAbstractTypeArguments* Type::arguments() const {
return raw_ptr()->arguments_;
}
bool Type::IsInstantiated() const {
if (raw_ptr()->type_state_ == RawType::kFinalizedInstantiated) {
return true;
}
if (raw_ptr()->type_state_ == RawType::kFinalizedUninstantiated) {
return false;
}
const AbstractTypeArguments& args =
AbstractTypeArguments::Handle(arguments());
return args.IsNull() || args.IsInstantiated();
}
RawAbstractType* Type::InstantiateFrom(
const AbstractTypeArguments& instantiator_type_arguments,
Error* malformed_error) const {
ASSERT(IsResolved());
ASSERT(!IsInstantiated());
// Return the uninstantiated type unchanged if malformed. No copy needed.
if (IsMalformed()) {
return raw();
}
AbstractTypeArguments& type_arguments =
AbstractTypeArguments::Handle(arguments());
type_arguments = type_arguments.InstantiateFrom(instantiator_type_arguments,
malformed_error);
// Note that the type class has to be resolved at this time, but not
// necessarily finalized yet. We may be checking bounds at compile time.
const Class& cls = Class::Handle(type_class());
// This uninstantiated type is not modified, as it can be instantiated
// with different instantiators.
Type& instantiated_type = Type::Handle(
Type::New(cls, type_arguments, token_pos()));
ASSERT(type_arguments.IsNull() ||
(type_arguments.Length() == cls.NumTypeArguments()));
instantiated_type.SetIsFinalized();
return instantiated_type.raw();
}
bool Type::Equals(const Instance& other) const {
if (raw() == other.raw()) {
return true;
}
if (!other.IsType()) {
return false;
}
const Type& other_type = Type::Cast(other);
ASSERT(IsResolved() && other_type.IsResolved());
if (IsMalformed() || other_type.IsMalformed()) {
return false;
}
if (type_class() != other_type.type_class()) {
return false;
}
if (!IsFinalized() || !other_type.IsFinalized()) {
return false;
}
return AbstractTypeArguments::AreEqual(
AbstractTypeArguments::Handle(arguments()),
AbstractTypeArguments::Handle(other_type.arguments()));
}
RawAbstractType* Type::Canonicalize() const {
ASSERT(IsFinalized());
if (IsCanonical() || IsMalformed()) {
ASSERT(IsMalformed() || AbstractTypeArguments::Handle(arguments()).IsOld());
return this->raw();
}
const Class& cls = Class::Handle(type_class());
Array& canonical_types = Array::Handle(cls.canonical_types());
if (canonical_types.IsNull()) {
// Types defined in the VM isolate are canonicalized via the object store.
return this->raw();
}
const intptr_t canonical_types_len = canonical_types.Length();
// Linear search to see whether this type is already present in the
// list of canonicalized types.
// TODO(asiva): Try to re-factor this lookup code to make sharing
// easy between the 4 versions of this loop.
Type& type = Type::Handle();
intptr_t index = 0;
while (index < canonical_types_len) {
type ^= canonical_types.At(index);
if (type.IsNull()) {
break;
}
if (!type.IsFinalized()) {
ASSERT((index == 0) && cls.IsSignatureClass());
index++;
continue;
}
if (this->Equals(type)) {
return type.raw();
}
index++;
}
// Canonicalize the type arguments.
AbstractTypeArguments& type_args = AbstractTypeArguments::Handle(arguments());
type_args = type_args.Canonicalize();
set_arguments(type_args);
// The type needs to be added to the list. Grow the list if it is full.
if (index == canonical_types_len) {
const intptr_t kLengthIncrement = 2; // Raw and parameterized.
const intptr_t new_length = canonical_types.Length() + kLengthIncrement;
const Array& new_canonical_types =
Array::Handle(Array::Grow(canonical_types, new_length, Heap::kOld));
cls.set_canonical_types(new_canonical_types);
new_canonical_types.SetAt(index, *this);
} else {
canonical_types.SetAt(index, *this);
}
ASSERT(IsOld());
SetCanonical();
return this->raw();
}
intptr_t Type::Hash() const {
ASSERT(IsFinalized());
uword result = 1;
if (IsMalformed()) return result;
result += Class::Handle(type_class()).id();
result += AbstractTypeArguments::Handle(arguments()).Hash();
return FinalizeHash(result);
}
void Type::set_type_class(const Object& value) const {
ASSERT(!value.IsNull() && (value.IsClass() || value.IsUnresolvedClass()));
StorePointer(&raw_ptr()->type_class_, value.raw());
}
void Type::set_arguments(const AbstractTypeArguments& value) const {
StorePointer(&raw_ptr()->arguments_, value.raw());
}
RawType* Type::New(Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->type_class() != Class::null());
RawObject* raw = Object::Allocate(Type::kClassId,
Type::InstanceSize(),
space);
return reinterpret_cast<RawType*>(raw);
}
RawType* Type::New(const Object& clazz,
const AbstractTypeArguments& arguments,
intptr_t token_pos,
Heap::Space space) {
const Type& result = Type::Handle(Type::New(space));
result.set_type_class(clazz);
result.set_arguments(arguments);
result.set_token_pos(token_pos);
result.raw_ptr()->type_state_ = RawType::kAllocated;
return result.raw();
}
void Type::set_token_pos(intptr_t token_pos) const {
ASSERT(token_pos >= 0);
raw_ptr()->token_pos_ = token_pos;
}
void Type::set_type_state(int8_t state) const {
ASSERT((state == RawType::kAllocated) ||
(state == RawType::kBeingFinalized) ||
(state == RawType::kFinalizedInstantiated) ||
(state == RawType::kFinalizedUninstantiated));
raw_ptr()->type_state_ = state;
}
const char* Type::ToCString() const {
if (IsResolved()) {
const AbstractTypeArguments& type_arguments =
AbstractTypeArguments::Handle(arguments());
const char* class_name;
if (HasResolvedTypeClass()) {
class_name = String::Handle(
Class::Handle(type_class()).Name()).ToCString();
} else {
class_name = UnresolvedClass::Handle(unresolved_class()).ToCString();
}
if (type_arguments.IsNull()) {
const char* format = "Type: class '%s'";
intptr_t len = OS::SNPrint(NULL, 0, format, class_name) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, class_name);
return chars;
} else {
const char* format = "Type: class '%s', args:[%s]";
const char* args_cstr =
AbstractTypeArguments::Handle(arguments()).ToCString();
intptr_t len = OS::SNPrint(NULL, 0, format, class_name, args_cstr) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, class_name, args_cstr);
return chars;
}
} else {
return "Unresolved Type";
}
}
void TypeParameter::set_is_finalized() const {
ASSERT(!IsFinalized());
set_type_state(RawTypeParameter::kFinalizedUninstantiated);
}
bool TypeParameter::Equals(const Instance& other) const {
if (raw() == other.raw()) {
return true;
}
if (!other.IsTypeParameter()) {
return false;
}
const TypeParameter& other_type_param = TypeParameter::Cast(other);
ASSERT(other_type_param.IsFinalized());
if (parameterized_class() != other_type_param.parameterized_class()) {
return false;
}
if (IsFinalized() != other_type_param.IsFinalized()) {
return false;
}
if (index() != other_type_param.index()) {
return false;
}
return true;
}
void TypeParameter::set_parameterized_class(const Class& value) const {
// Set value may be null.
StorePointer(&raw_ptr()->parameterized_class_, value.raw());
}
void TypeParameter::set_index(intptr_t value) const {
ASSERT(value >= 0);
raw_ptr()->index_ = value;
}
void TypeParameter::set_name(const String& value) const {
ASSERT(value.IsSymbol());
StorePointer(&raw_ptr()->name_, value.raw());
}
void TypeParameter::set_bound(const AbstractType& value) const {
StorePointer(&raw_ptr()->bound_, value.raw());
}
RawAbstractType* TypeParameter::InstantiateFrom(
const AbstractTypeArguments& instantiator_type_arguments,
Error* malformed_error) const {
ASSERT(IsFinalized());
if (instantiator_type_arguments.IsNull()) {
return Type::DynamicType();
}
// Bound checks may appear in the instantiator type arguments, as is the case
// with a pair of type parameters of the same class referring to each other
// via their bounds.
AbstractType& type_arg = AbstractType::Handle(
instantiator_type_arguments.TypeAt(index()));
if (type_arg.IsBoundedType()) {
const BoundedType& bounded_type = BoundedType::Cast(type_arg);
ASSERT(!bounded_type.IsInstantiated());
ASSERT(AbstractType::Handle(bounded_type.bound()).IsInstantiated());
type_arg = bounded_type.InstantiateFrom(AbstractTypeArguments::Handle(),
malformed_error);
}
return type_arg.raw();
}
bool TypeParameter::CheckBound(const AbstractType& bounded_type,
const AbstractType& upper_bound,
Error* malformed_error) const {
ASSERT((malformed_error == NULL) || malformed_error->IsNull());
ASSERT(bounded_type.IsFinalized());
ASSERT(upper_bound.IsFinalized());
ASSERT(!bounded_type.IsMalformed());
if (bounded_type.IsSubtypeOf(upper_bound, malformed_error)) {
return true;
}
if ((malformed_error != NULL) && malformed_error->IsNull()) {
// Report the bound error.
const String& bounded_type_name = String::Handle(
bounded_type.UserVisibleName());
const String& upper_bound_name = String::Handle(
upper_bound.UserVisibleName());
const AbstractType& declared_bound = AbstractType::Handle(bound());
const String& declared_bound_name = String::Handle(
declared_bound.UserVisibleName());
const String& type_param_name = String::Handle(UserVisibleName());
const Class& cls = Class::Handle(parameterized_class());
const String& class_name = String::Handle(cls.Name());
const Script& script = Script::Handle(cls.script());
// Since the bound may have been canonicalized, its token index is
// meaningless, therefore use the token index of this type parameter.
*malformed_error = FormatError(
*malformed_error,
script,
token_pos(),
"type parameter '%s' of class '%s' must extend bound '%s', "
"but type argument '%s' is not a subtype of '%s'\n",
type_param_name.ToCString(),
class_name.ToCString(),
declared_bound_name.ToCString(),
bounded_type_name.ToCString(),
upper_bound_name.ToCString());
}
return false;
}
intptr_t TypeParameter::Hash() const {
ASSERT(IsFinalized());
uword result = 0;
result += Class::Handle(parameterized_class()).id();
// Do not include the hash of the bound, which could lead to cycles.
result <<= index();
return FinalizeHash(result);
}
RawTypeParameter* TypeParameter::New() {
ASSERT(Isolate::Current()->object_store()->type_parameter_class() !=
Class::null());
RawObject* raw = Object::Allocate(TypeParameter::kClassId,
TypeParameter::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawTypeParameter*>(raw);
}
RawTypeParameter* TypeParameter::New(const Class& parameterized_class,
intptr_t index,
const String& name,
const AbstractType& bound,
intptr_t token_pos) {
const TypeParameter& result = TypeParameter::Handle(TypeParameter::New());
result.set_parameterized_class(parameterized_class);
result.set_index(index);
result.set_name(name);
result.set_bound(bound);
result.set_token_pos(token_pos);
result.raw_ptr()->type_state_ = RawTypeParameter::kAllocated;
return result.raw();
}
void TypeParameter::set_token_pos(intptr_t token_pos) const {
ASSERT(token_pos >= 0);
raw_ptr()->token_pos_ = token_pos;
}
void TypeParameter::set_type_state(int8_t state) const {
ASSERT((state == RawTypeParameter::kAllocated) ||
(state == RawTypeParameter::kBeingFinalized) ||
(state == RawTypeParameter::kFinalizedUninstantiated));
raw_ptr()->type_state_ = state;
}
const char* TypeParameter::ToCString() const {
const char* format = "TypeParameter: name %s; index: %d; class: %s";
const char* name_cstr = String::Handle(Name()).ToCString();
const Class& cls = Class::Handle(parameterized_class());
const char* cls_cstr =
cls.IsNull() ? " null" : String::Handle(cls.Name()).ToCString();
intptr_t len = OS::SNPrint(NULL, 0, format, name_cstr, index(), cls_cstr) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, name_cstr, index(), cls_cstr);
return chars;
}
bool BoundedType::IsMalformed() const {
return FLAG_enable_type_checks && AbstractType::Handle(bound()).IsMalformed();
}
RawError* BoundedType::malformed_error() const {
ASSERT(FLAG_enable_type_checks);
return AbstractType::Handle(bound()).malformed_error();
}
bool BoundedType::Equals(const Instance& other) const {
// BoundedType are not canonicalized, because their bound may get finalized
// after the BoundedType is created and initialized.
if (raw() == other.raw()) {
return true;
}
if (!other.IsBoundedType()) {
return false;
}
const BoundedType& other_bounded = BoundedType::Cast(other);
if (type_parameter() != other_bounded.type_parameter()) {
// Not a structural compare.
// Note that a deep comparison of bounds could lead to cycles.
return false;
}
const AbstractType& this_type = AbstractType::Handle(type());
const AbstractType& other_type = AbstractType::Handle(other_bounded.type());
if (!this_type.Equals(other_type)) {
return false;
}
const AbstractType& this_bound = AbstractType::Handle(bound());
const AbstractType& other_bound = AbstractType::Handle(other_bounded.bound());
return this_bound.IsFinalized() &&
other_bound.IsFinalized() &&
this_bound.Equals(other_bound);
}
void BoundedType::set_type(const AbstractType& value) const {
ASSERT(value.IsFinalized());
ASSERT(!value.IsMalformed());
StorePointer(&raw_ptr()->type_, value.raw());
}
void BoundedType::set_bound(const AbstractType& value) const {
// The bound may still be unfinalized because of legal cycles.
// It must be finalized before it is checked at run time, though.
StorePointer(&raw_ptr()->bound_, value.raw());
}
void BoundedType::set_type_parameter(const TypeParameter& value) const {
// A null type parameter is set when marking a type malformed because of a
// bound error at compile time.
ASSERT(value.IsNull() || value.IsFinalized());
StorePointer(&raw_ptr()->type_parameter_, value.raw());
}
void BoundedType::set_is_being_checked(bool value) const {
raw_ptr()->is_being_checked_ = value;
}
RawAbstractType* BoundedType::InstantiateFrom(
const AbstractTypeArguments& instantiator_type_arguments,
Error* malformed_error) const {
ASSERT(IsFinalized());
AbstractType& bounded_type = AbstractType::Handle(type());
if (!bounded_type.IsInstantiated()) {
bounded_type = bounded_type.InstantiateFrom(instantiator_type_arguments,
malformed_error);
}
if (FLAG_enable_type_checks &&
malformed_error->IsNull() &&
!is_being_checked()) {
// Avoid endless recursion while checking and instantiating bound.
set_is_being_checked(true);
AbstractType& upper_bound = AbstractType::Handle(bound());
ASSERT(!upper_bound.IsObjectType() && !upper_bound.IsDynamicType());
const TypeParameter& type_param = TypeParameter::Handle(type_parameter());
if (!upper_bound.IsInstantiated()) {
upper_bound = upper_bound.InstantiateFrom(instantiator_type_arguments,
malformed_error);
}
if (malformed_error->IsNull()) {
type_param.CheckBound(bounded_type, upper_bound, malformed_error);
}
set_is_being_checked(false);
}
return bounded_type.raw();
}
intptr_t BoundedType::Hash() const {
uword result = 0;
result += AbstractType::Handle(type()).Hash();
// Do not include the hash of the bound, which could lead to cycles.
TypeParameter& type_param = TypeParameter::Handle(type_parameter());
if (!type_param.IsNull()) {
result += type_param.Hash();
}
return FinalizeHash(result);
}
RawBoundedType* BoundedType::New() {
ASSERT(Isolate::Current()->object_store()->bounded_type_class() !=
Class::null());
RawObject* raw = Object::Allocate(BoundedType::kClassId,
BoundedType::InstanceSize(),
Heap::kOld);
return reinterpret_cast<RawBoundedType*>(raw);
}
RawBoundedType* BoundedType::New(const AbstractType& type,
const AbstractType& bound,
const TypeParameter& type_parameter) {
const BoundedType& result = BoundedType::Handle(BoundedType::New());
result.set_type(type);
result.set_bound(bound);
result.set_type_parameter(type_parameter);
result.set_is_being_checked(false);
return result.raw();
}
const char* BoundedType::ToCString() const {
const char* format = "BoundedType: type %s; bound: %s; class: %s";
const char* type_cstr = String::Handle(AbstractType::Handle(
type()).Name()).ToCString();
const char* bound_cstr = String::Handle(AbstractType::Handle(
bound()).Name()).ToCString();
const Class& cls = Class::Handle(TypeParameter::Handle(
type_parameter()).parameterized_class());
const char* cls_cstr =
cls.IsNull() ? " null" : String::Handle(cls.Name()).ToCString();
intptr_t len = OS::SNPrint(
NULL, 0, format, type_cstr, bound_cstr, cls_cstr) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, type_cstr, bound_cstr, cls_cstr);
return chars;
}
RawString* MixinAppType::Name() const {
return String::New("MixinApplication");
}
const char* MixinAppType::ToCString() const {
return "MixinAppType";
}
void MixinAppType::set_super_type(const AbstractType& value) const {
StorePointer(&raw_ptr()->super_type_, value.raw());
}
void MixinAppType::set_mixin_types(const Array& value) const {
StorePointer(&raw_ptr()->mixin_types_, value.raw());
}
RawMixinAppType* MixinAppType::New() {
ASSERT(Isolate::Current()->object_store()->mixin_app_type_class() !=
Class::null());
// MixinAppType objects do not survive finalization, so allocate
// on new heap.
RawObject* raw = Object::Allocate(MixinAppType::kClassId,
MixinAppType::InstanceSize(),
Heap::kNew);
return reinterpret_cast<RawMixinAppType*>(raw);
}
RawMixinAppType* MixinAppType::New(const AbstractType& super_type,
const Array& mixin_types) {
const MixinAppType& result = MixinAppType::Handle(MixinAppType::New());
result.set_super_type(super_type);
result.set_mixin_types(mixin_types);
return result.raw();
}
const char* Number::ToCString() const {
// Number is an interface. No instances of Number should exist.
UNREACHABLE();
return "Number";
}
const char* Integer::ToCString() const {
// Integer is an interface. No instances of Integer should exist.
UNREACHABLE();
return "Integer";
}
// Throw FiftyThreeBitOverflow exception.
static void ThrowFiftyThreeBitOverflow(const Integer& i) {
const Array& exc_args = Array::Handle(Array::New(1));
exc_args.SetAt(0, i);
Exceptions::ThrowByType(Exceptions::kFiftyThreeBitOverflowError, exc_args);
}
RawInteger* Integer::New(const String& str, Heap::Space space) {
// We are not supposed to have integers represented as two byte strings.
ASSERT(str.IsOneByteString());
int64_t value;
if (!OS::StringToInt64(str.ToCString(), &value)) {
const Bigint& big = Bigint::Handle(Bigint::New(str, space));
ASSERT(!BigintOperations::FitsIntoSmi(big));
ASSERT(!BigintOperations::FitsIntoInt64(big));
if (FLAG_throw_on_javascript_int_overflow) {
ThrowFiftyThreeBitOverflow(big);
}
return big.raw();
}
return Integer::New(value, space);
}
// This is called from LiteralToken::New() in the parser, so we can't
// raise an exception for 53-bit overflow here. Instead we do it in
// Parser::CurrentIntegerLiteral(), which is the point in the parser where
// integer literals escape, so we can call Parser::ErrorMsg().
RawInteger* Integer::NewCanonical(const String& str) {
// We are not supposed to have integers represented as two byte strings.
ASSERT(str.IsOneByteString());
int64_t value;
if (!OS::StringToInt64(str.ToCString(), &value)) {
const Bigint& big = Bigint::Handle(Bigint::NewCanonical(str));
ASSERT(!BigintOperations::FitsIntoSmi(big));
ASSERT(!BigintOperations::FitsIntoInt64(big));
return big.raw();
}
if ((value <= Smi::kMaxValue) && (value >= Smi::kMinValue)) {
return Smi::New(value);
}
return Mint::NewCanonical(value);
}
RawInteger* Integer::New(int64_t value, Heap::Space space) {
if ((value <= Smi::kMaxValue) && (value >= Smi::kMinValue)) {
return Smi::New(value);
}
if (FLAG_throw_on_javascript_int_overflow && !Utils::IsInt(53, value)) {
const Integer &i = Integer::Handle(Mint::New(value));
ThrowFiftyThreeBitOverflow(i);
}
return Mint::New(value, space);
}
RawInteger* Integer::NewFromUint64(uint64_t value, Heap::Space space) {
if (value > static_cast<uint64_t>(Mint::kMaxValue)) {
if (FLAG_throw_on_javascript_int_overflow) {
const Integer &i =
Integer::Handle(BigintOperations::NewFromUint64(value));
ThrowFiftyThreeBitOverflow(i);
}
return BigintOperations::NewFromUint64(value);
} else {
return Integer::New(value);
}
}
double Integer::AsDoubleValue() const {
UNIMPLEMENTED();
return 0.0;
}
int64_t Integer::AsInt64Value() const {
UNIMPLEMENTED();
return 0;
}
int Integer::CompareWith(const Integer& other) const {
UNIMPLEMENTED();
return 0;
}
// Returns true if the signed Integer requires more than 53 bits.
bool Integer::CheckFiftyThreeBitOverflow() const {
// Always overflow if the value doesn't fit into an int64_t.
int64_t value = 1ULL << 63;
if (IsSmi()) {
value = AsInt64Value();
} else if (IsMint()) {
Mint& mint = Mint::Handle();
mint ^= raw();
value = mint.value();
} else {
ASSERT(IsBigint());
Bigint& big_value = Bigint::Handle();
big_value ^= raw();
if (BigintOperations::FitsIntoInt64(big_value)) {
value = BigintOperations::ToInt64(big_value);
}
}
return !Utils::IsInt(53, value);
}
RawInteger* Integer::AsValidInteger() const {
if (FLAG_throw_on_javascript_int_overflow &&
CheckFiftyThreeBitOverflow()) {
ThrowFiftyThreeBitOverflow(*this);
}
if (IsSmi()) return raw();
if (IsMint()) {
Mint& mint = Mint::Handle();
mint ^= raw();
if (Smi::IsValid64(mint.value())) {
return Smi::New(mint.value());
} else {
return raw();
}
}
ASSERT(IsBigint());
Bigint& big_value = Bigint::Handle();
big_value ^= raw();
if (BigintOperations::FitsIntoSmi(big_value)) {
return BigintOperations::ToSmi(big_value);
} else if (BigintOperations::FitsIntoInt64(big_value)) {
return Mint::New(BigintOperations::ToInt64(big_value));
} else {
return big_value.raw();
}
}
RawInteger* Integer::ArithmeticOp(Token::Kind operation,
const Integer& other) const {
// In 32-bit mode, the result of any operation between two Smis will fit in a
// 32-bit signed result, except the product of two Smis, which will be 64-bit.
// In 64-bit mode, the result of any operation between two Smis will fit in a
// 64-bit signed result, except the product of two Smis (unless the Smis are
// 32-bit or less).
if (IsSmi() && other.IsSmi()) {
const intptr_t left_value = Smi::Value(Smi::RawCast(raw()));
const intptr_t right_value = Smi::Value(Smi::RawCast(other.raw()));
switch (operation) {
case Token::kADD:
return Integer::New(left_value + right_value);
case Token::kSUB:
return Integer::New(left_value - right_value);
case Token::kMUL: {
if (Smi::kBits < 32) {
// In 32-bit mode, the product of two Smis fits in a 64-bit result.
return Integer::New(static_cast<int64_t>(left_value) *
static_cast<int64_t>(right_value));
} else {
// In 64-bit mode, the product of two 32-bit signed integers fits in a
// 64-bit result.
ASSERT(sizeof(intptr_t) == sizeof(int64_t));
if (Utils::IsInt(32, left_value) && Utils::IsInt(32, right_value)) {
return Integer::New(left_value * right_value);
}
}
// Perform a Bigint multiplication below.
break;
}
case Token::kTRUNCDIV:
return Integer::New(left_value / right_value);
case Token::kMOD: {
const intptr_t remainder = left_value % right_value;
if (remainder < 0) {
if (right_value < 0) {
return Integer::New(remainder - right_value);
} else {
return Integer::New(remainder + right_value);
}
}
return Integer::New(remainder);
}
default:
UNIMPLEMENTED();
}
}
// In 32-bit mode, the result of any operation between two 63-bit signed
// integers (or 32-bit for multiplication) will fit in a 64-bit signed result.
// In 64-bit mode, 63-bit signed integers are Smis, already processed above.
if ((Smi::kBits < 32) && !IsBigint() && !other.IsBigint()) {
const int64_t left_value = AsInt64Value();
if (Utils::IsInt(63, left_value)) {
const int64_t right_value = other.AsInt64Value();
if (Utils::IsInt(63, right_value)) {
switch (operation) {
case Token::kADD:
return Integer::New(left_value + right_value);
case Token::kSUB:
return Integer::New(left_value - right_value);
case Token::kMUL: {
if (Utils::IsInt(32, left_value) && Utils::IsInt(32, right_value)) {
return Integer::New(left_value * right_value);
}
// Perform a Bigint multiplication below.
break;
}
case Token::kTRUNCDIV:
return Integer::New(left_value / right_value);
case Token::kMOD: {
const int64_t remainder = left_value % right_value;
if (remainder < 0) {
if (right_value < 0) {
return Integer::New(remainder - right_value);
} else {
return Integer::New(remainder + right_value);
}
}
return Integer::New(remainder);
}
default:
UNIMPLEMENTED();
}
}
}
}
const Bigint& left_big = Bigint::Handle(AsBigint());
const Bigint& right_big = Bigint::Handle(other.AsBigint());
const Bigint& result =
Bigint::Handle(left_big.BigArithmeticOp(operation, right_big));
return Integer::Handle(result.AsValidInteger()).raw();
}
static bool Are64bitOperands(const Integer& op1, const Integer& op2) {
return !op1.IsBigint() && !op2.IsBigint();
}
RawInteger* Integer::BitOp(Token::Kind kind, const Integer& other) const {
if (IsSmi() && other.IsSmi()) {
intptr_t op1_value = Smi::Value(Smi::RawCast(raw()));
intptr_t op2_value = Smi::Value(Smi::RawCast(other.raw()));
intptr_t result = 0;
switch (kind) {
case Token::kBIT_AND:
result = op1_value & op2_value;
break;
case Token::kBIT_OR:
result = op1_value | op2_value;
break;
case Token::kBIT_XOR:
result = op1_value ^ op2_value;
break;
default:
UNIMPLEMENTED();
}
ASSERT(Smi::IsValid(result));
return Smi::New(result);
} else if (Are64bitOperands(*this, other)) {
int64_t a = AsInt64Value();
int64_t b = other.AsInt64Value();
switch (kind) {
case Token::kBIT_AND:
return Integer::New(a & b);
case Token::kBIT_OR:
return Integer::New(a | b);
case Token::kBIT_XOR:
return Integer::New(a ^ b);
default:
UNIMPLEMENTED();
}
} else {
Bigint& op1 = Bigint::Handle(AsBigint());
Bigint& op2 = Bigint::Handle(other.AsBigint());
switch (kind) {
case Token::kBIT_AND:
return BigintOperations::BitAnd(op1, op2);
case Token::kBIT_OR:
return BigintOperations::BitOr(op1, op2);
case Token::kBIT_XOR:
return BigintOperations::BitXor(op1, op2);
default:
UNIMPLEMENTED();
}
}
return Integer::null();
}
// TODO(srdjan): Clarify handling of negative right operand in a shift op.
RawInteger* Smi::ShiftOp(Token::Kind kind, const Smi& other) const {
intptr_t result = 0;
const intptr_t left_value = Value();
const intptr_t right_value = other.Value();
ASSERT(right_value >= 0);
switch (kind) {
case Token::kSHL: {
if ((left_value == 0) || (right_value == 0)) {
return raw();
}
{ // Check for overflow.
int cnt = Utils::HighestBit(left_value);
if ((cnt + right_value) >= Smi::kBits) {
if ((cnt + right_value) >= Mint::kBits) {
return BigintOperations::ShiftLeft(
Bigint::Handle(BigintOperations::NewFromSmi(*this)),
right_value);
} else {
int64_t left_64 = left_value;
return Integer::New(left_64 << right_value);
}
}
}
result = left_value << right_value;
break;
}
case Token::kSHR: {
const intptr_t shift_amount =
(right_value >= kBitsPerWord) ? (kBitsPerWord - 1) : right_value;
result = left_value >> shift_amount;
break;
}
default:
UNIMPLEMENTED();
}
ASSERT(Smi::IsValid(result));
return Smi::New(result);
}
bool Smi::Equals(const Instance& other) const {
if (other.IsNull() || !other.IsSmi()) {
return false;
}
return (this->Value() == Smi::Cast(other).Value());
}
double Smi::AsDoubleValue() const {
return static_cast<double>(this->Value());
}
int64_t Smi::AsInt64Value() const {
return this->Value();
}
static bool FitsIntoSmi(const Integer& integer) {
if (integer.IsSmi()) {
return true;
}
if (integer.IsMint()) {
int64_t mint_value = integer.AsInt64Value();
return Smi::IsValid64(mint_value);
}
if (integer.IsBigint()) {
return BigintOperations::FitsIntoSmi(Bigint::Cast(integer));
}
UNREACHABLE();
return false;
}
int Smi::CompareWith(const Integer& other) const {
if (other.IsSmi()) {
const Smi& other_smi = Smi::Cast(other);
if (this->Value() < other_smi.Value()) {
return -1;
} else if (this->Value() > other_smi.Value()) {
return 1;
} else {
return 0;
}
}
ASSERT(!FitsIntoSmi(other));
if (other.IsMint() || other.IsBigint()) {
if (this->IsNegative() == other.IsNegative()) {
return this->IsNegative() ? 1 : -1;
}
return this->IsNegative() ? -1 : 1;
}
UNREACHABLE();
return 0;
}
const char* Smi::ToCString() const {
const char* kFormat = "%ld";
// Calculate the size of the string.
intptr_t len = OS::SNPrint(NULL, 0, kFormat, Value()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, Value());
return chars;
}
RawClass* Smi::Class() {
return Isolate::Current()->object_store()->smi_class();
}
void Mint::set_value(int64_t value) const {
raw_ptr()->value_ = value;
}
RawMint* Mint::New(int64_t val, Heap::Space space) {
// Do not allocate a Mint if Smi would do.
ASSERT(!Smi::IsValid64(val));
ASSERT(Isolate::Current()->object_store()->mint_class() != Class::null());
Mint& result = Mint::Handle();
{
RawObject* raw = Object::Allocate(Mint::kClassId,
Mint::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_value(val);
return result.raw();
}
RawMint* Mint::NewCanonical(int64_t value) {
// Do not allocate a Mint if Smi would do.
ASSERT(!Smi::IsValid64(value));
const Class& cls =
Class::Handle(Isolate::Current()->object_store()->mint_class());
const Array& constants = Array::Handle(cls.constants());
const intptr_t constants_len = constants.Length();
// Linear search to see whether this value is already present in the
// list of canonicalized constants.
Mint& canonical_value = Mint::Handle();
intptr_t index = 0;
while (index < constants_len) {
canonical_value ^= constants.At(index);
if (canonical_value.IsNull()) {
break;
}
if (canonical_value.value() == value) {
return canonical_value.raw();
}
index++;
}
// The value needs to be added to the constants list. Grow the list if
// it is full.
canonical_value = Mint::New(value, Heap::kOld);
cls.InsertCanonicalConstant(index, canonical_value);
canonical_value.SetCanonical();
return canonical_value.raw();
}
bool Mint::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
// Both handles point to the same raw instance.
return true;
}
if (!other.IsMint() || other.IsNull()) {
return false;
}
return value() == Mint::Cast(other).value();
}
double Mint::AsDoubleValue() const {
return static_cast<double>(this->value());
}
int64_t Mint::AsInt64Value() const {
return this->value();
}
int Mint::CompareWith(const Integer& other) const {
ASSERT(!FitsIntoSmi(*this));
if (other.IsMint() || other.IsSmi()) {
int64_t a = AsInt64Value();
int64_t b = other.AsInt64Value();
if (a < b) {
return -1;
} else if (a > b) {
return 1;
} else {
return 0;
}
}
if (other.IsBigint()) {
ASSERT(!BigintOperations::FitsIntoInt64(Bigint::Cast(other)));
if (this->IsNegative() == other.IsNegative()) {
return this->IsNegative() ? 1 : -1;
}
return this->IsNegative() ? -1 : 1;
}
UNREACHABLE();
return 0;
}
const char* Mint::ToCString() const {
const char* kFormat = "%lld";
// Calculate the size of the string.
intptr_t len = OS::SNPrint(NULL, 0, kFormat, value()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, value());
return chars;
}
void Double::set_value(double value) const {
raw_ptr()->value_ = value;
}
bool Double::EqualsToDouble(double value) const {
intptr_t value_offset = Double::value_offset();
void* this_addr = reinterpret_cast<void*>(
reinterpret_cast<uword>(this->raw_ptr()) + value_offset);
void* other_addr = reinterpret_cast<void*>(&value);
return (memcmp(this_addr, other_addr, sizeof(value)) == 0);
}
bool Double::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
return true; // "===".
}
if (other.IsNull() || !other.IsDouble()) {
return false;
}
return EqualsToDouble(Double::Cast(other).value());
}
RawDouble* Double::New(double d, Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->double_class() != Class::null());
Double& result = Double::Handle();
{
RawObject* raw = Object::Allocate(Double::kClassId,
Double::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_value(d);
return result.raw();
}
RawDouble* Double::New(const String& str, Heap::Space space) {
double double_value;
if (!CStringToDouble(str.ToCString(), str.Length(), &double_value)) {
return Double::Handle().raw();
}
return New(double_value, space);
}
RawDouble* Double::NewCanonical(double value) {
const Class& cls =
Class::Handle(Isolate::Current()->object_store()->double_class());
const Array& constants = Array::Handle(cls.constants());
const intptr_t constants_len = constants.Length();
// Linear search to see whether this value is already present in the
// list of canonicalized constants.
Double& canonical_value = Double::Handle();
intptr_t index = 0;
while (index < constants_len) {
canonical_value ^= constants.At(index);
if (canonical_value.IsNull()) {
break;
}
if (canonical_value.EqualsToDouble(value)) {
return canonical_value.raw();
}
index++;
}
// The value needs to be added to the constants list. Grow the list if
// it is full.
canonical_value = Double::New(value, Heap::kOld);
cls.InsertCanonicalConstant(index, canonical_value);
canonical_value.SetCanonical();
return canonical_value.raw();
}
RawDouble* Double::NewCanonical(const String& str) {
double double_value;
if (!CStringToDouble(str.ToCString(), str.Length(), &double_value)) {
return Double::Handle().raw();
}
return NewCanonical(double_value);
}
const char* Double::ToCString() const {
if (isnan(value())) {
return "NaN";
}
if (isinf(value())) {
return value() < 0 ? "-Infinity" : "Infinity";
}
const int kBufferSize = 128;
char* buffer = Isolate::Current()->current_zone()->Alloc<char>(kBufferSize);
buffer[kBufferSize - 1] = '\0';
DoubleToCString(value(), buffer, kBufferSize);
return buffer;
}
RawBigint* Integer::AsBigint() const {
ASSERT(!IsNull());
if (IsSmi()) {
Smi& smi = Smi::Handle();
smi ^= raw();
return BigintOperations::NewFromSmi(smi);
} else if (IsMint()) {
Mint& mint = Mint::Handle();
mint ^= raw();
return BigintOperations::NewFromInt64(mint.value());
} else {
ASSERT(IsBigint());
Bigint& big = Bigint::Handle();
big ^= raw();
ASSERT(!BigintOperations::FitsIntoSmi(big));
return big.raw();
}
}
RawBigint* Bigint::BigArithmeticOp(Token::Kind operation,
const Bigint& other) const {
switch (operation) {
case Token::kADD:
return BigintOperations::Add(*this, other);
case Token::kSUB:
return BigintOperations::Subtract(*this, other);
case Token::kMUL:
return BigintOperations::Multiply(*this, other);
case Token::kTRUNCDIV:
return BigintOperations::Divide(*this, other);
case Token::kMOD:
return BigintOperations::Modulo(*this, other);
default:
UNIMPLEMENTED();
return Bigint::null();
}
}
bool Bigint::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
// Both handles point to the same raw instance.
return true;
}
if (!other.IsBigint() || other.IsNull()) {
return false;
}
const Bigint& other_bgi = Bigint::Cast(other);
if (this->IsNegative() != other_bgi.IsNegative()) {
return false;
}
intptr_t len = this->Length();
if (len != other_bgi.Length()) {
return false;
}
for (intptr_t i = 0; i < len; i++) {
if (this->GetChunkAt(i) != other_bgi.GetChunkAt(i)) {
return false;
}
}
return true;
}
RawBigint* Bigint::New(const String& str, Heap::Space space) {
const Bigint& result = Bigint::Handle(
BigintOperations::NewFromCString(str.ToCString(), space));
ASSERT(!BigintOperations::FitsIntoInt64(result));
return result.raw();
}
RawBigint* Bigint::NewCanonical(const String& str) {
const Bigint& value = Bigint::Handle(
BigintOperations::NewFromCString(str.ToCString(), Heap::kOld));
ASSERT(!BigintOperations::FitsIntoInt64(value));
const Class& cls =
Class::Handle(Isolate::Current()->object_store()->bigint_class());
const Array& constants = Array::Handle(cls.constants());
const intptr_t constants_len = constants.Length();
// Linear search to see whether this value is already present in the
// list of canonicalized constants.
Bigint& canonical_value = Bigint::Handle();
intptr_t index = 0;
while (index < constants_len) {
canonical_value ^= constants.At(index);
if (canonical_value.IsNull()) {
break;
}
if (canonical_value.Equals(value)) {
return canonical_value.raw();
}
index++;
}
// The value needs to be added to the constants list. Grow the list if
// it is full.
cls.InsertCanonicalConstant(index, value);
value.SetCanonical();
return value.raw();
}
double Bigint::AsDoubleValue() const {
return Double::Handle(BigintOperations::ToDouble(*this)).value();
}
int64_t Bigint::AsInt64Value() const {
if (!BigintOperations::FitsIntoInt64(*this)) {
UNREACHABLE();
}
return BigintOperations::ToInt64(*this);
}
// For positive values: Smi < Mint < Bigint.
int Bigint::CompareWith(const Integer& other) const {
ASSERT(!FitsIntoSmi(*this));
ASSERT(!BigintOperations::FitsIntoInt64(*this));
if (other.IsBigint()) {
return BigintOperations::Compare(*this, Bigint::Cast(other));
}
if (this->IsNegative() == other.IsNegative()) {
return this->IsNegative() ? -1 : 1;
}
return this->IsNegative() ? -1 : 1;
}
RawBigint* Bigint::Allocate(intptr_t length, Heap::Space space) {
if (length < 0 || length > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in Bigint::Allocate: invalid length %"Pd"\n", length);
}
ASSERT(Isolate::Current()->object_store()->bigint_class() != Class::null());
Bigint& result = Bigint::Handle();
{
RawObject* raw = Object::Allocate(Bigint::kClassId,
Bigint::InstanceSize(length),
space);
NoGCScope no_gc;
result ^= raw;
result.raw_ptr()->allocated_length_ = length; // Chunk length allocated.
result.raw_ptr()->signed_length_ = length; // Chunk length in use.
}
return result.raw();
}
static uword BigintAllocator(intptr_t size) {
Zone* zone = Isolate::Current()->current_zone();
return zone->AllocUnsafe(size);
}
const char* Bigint::ToCString() const {
return BigintOperations::ToDecimalCString(*this, &BigintAllocator);
}
// Synchronize with implementation in compiler (intrinsifier).
class StringHasher : ValueObject {
public:
StringHasher() : hash_(0) {}
void Add(int32_t ch) {
hash_ += ch;
hash_ += hash_ << 10;
hash_ ^= hash_ >> 6;
}
// Return a non-zero hash of at most 'bits' bits.
intptr_t Finalize(int bits) {
ASSERT(1 <= bits && bits <= (kBitsPerWord - 1));
hash_ += hash_ << 3;
hash_ ^= hash_ >> 11;
hash_ += hash_ << 15;
hash_ = hash_ & ((static_cast<intptr_t>(1) << bits) - 1);
ASSERT(hash_ <= static_cast<uint32_t>(kMaxInt32));
return hash_ == 0 ? 1 : hash_;
}
private:
uint32_t hash_;
};
intptr_t String::Hash(const String& str, intptr_t begin_index, intptr_t len) {
ASSERT(begin_index >= 0);
ASSERT(len >= 0);
ASSERT((begin_index + len) <= str.Length());
StringHasher hasher;
if (str.IsOneByteString()) {
for (intptr_t i = 0; i < len; i++) {
hasher.Add(*OneByteString::CharAddr(str, i + begin_index));
}
} else {
CodePointIterator it(str, begin_index, len);
while (it.Next()) {
hasher.Add(it.Current());
}
}
return hasher.Finalize(String::kHashBits);
}
template<typename T>
static intptr_t HashImpl(const T* characters, intptr_t len) {
ASSERT(len >= 0);
StringHasher hasher;
for (intptr_t i = 0; i < len; i++) {
hasher.Add(characters[i]);
}
return hasher.Finalize(String::kHashBits);
}
intptr_t String::Hash(const uint8_t* characters, intptr_t len) {
return HashImpl(characters, len);
}
intptr_t String::Hash(const uint16_t* characters, intptr_t len) {
StringHasher hasher;
intptr_t i = 0;
while (i < len) {
hasher.Add(Utf16::Next(characters, &i, len));
}
return hasher.Finalize(String::kHashBits);
}
intptr_t String::Hash(const int32_t* characters, intptr_t len) {
return HashImpl(characters, len);
}
int32_t String::CharAt(intptr_t index) const {
intptr_t class_id = raw()->GetClassId();
ASSERT(RawObject::IsStringClassId(class_id));
NoGCScope no_gc;
if (class_id == kOneByteStringCid) {
return *OneByteString::CharAddr(*this, index);
}
if (class_id == kTwoByteStringCid) {
return *TwoByteString::CharAddr(*this, index);
}
if (class_id == kExternalOneByteStringCid) {
return *ExternalOneByteString::CharAddr(*this, index);
}
ASSERT(class_id == kExternalTwoByteStringCid);
return *ExternalTwoByteString::CharAddr(*this, index);
}
intptr_t String::CharSize() const {
intptr_t class_id = raw()->GetClassId();
if (class_id == kOneByteStringCid || class_id == kExternalOneByteStringCid) {
return kOneByteChar;
}
ASSERT(class_id == kTwoByteStringCid ||
class_id == kExternalTwoByteStringCid);
return kTwoByteChar;
}
void* String::GetPeer() const {
intptr_t class_id = raw()->GetClassId();
if (class_id == kExternalOneByteStringCid) {
return ExternalOneByteString::GetPeer(*this);
}
ASSERT(class_id == kExternalTwoByteStringCid);
return ExternalTwoByteString::GetPeer(*this);
}
bool String::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
// Both handles point to the same raw instance.
return true;
}
if (!other.IsString() || other.IsNull()) {
return false;
}
const String& other_string = String::Cast(other);
if (this->HasHash() && other_string.HasHash() &&
(this->Hash() != other_string.Hash())) {
return false; // Both sides have a hash code and it does not match.
}
return Equals(other_string, 0, other_string.Length());
}
bool String::Equals(const char* cstr) const {
ASSERT(cstr != NULL);
CodePointIterator it(*this);
intptr_t len = strlen(cstr);
while (it.Next()) {
if (*cstr == '\0') {
// Lengths don't match.
return false;
}
int32_t ch;
intptr_t consumed = Utf8::Decode(reinterpret_cast<const uint8_t*>(cstr),
len,
&ch);
if (consumed == 0 || it.Current() != ch) {
return false;
}
cstr += consumed;
len -= consumed;
}
return *cstr == '\0';
}
bool String::Equals(const uint8_t* latin1_array, intptr_t len) const {
if (len != this->Length()) {
// Lengths don't match.
return false;
}
for (intptr_t i = 0; i < len; i++) {
if (this->CharAt(i) != latin1_array[i]) {
return false;
}
}
return true;
}
bool String::Equals(const uint16_t* utf16_array, intptr_t len) const {
if (len != this->Length()) {
// Lengths don't match.
return false;
}
for (intptr_t i = 0; i < len; i++) {
if (this->CharAt(i) != utf16_array[i]) {
return false;
}
}
return true;
}
bool String::Equals(const int32_t* utf32_array, intptr_t len) const {
CodePointIterator it(*this);
intptr_t i = 0;
bool has_more = it.Next();
while (has_more && (i < len)) {
if ((it.Current() != static_cast<int32_t>(utf32_array[i]))) {
return false;
}
// Advance both streams forward.
++i;
has_more = it.Next();
}
// Strings are only true iff we reached the end in both streams.
return (i == len) && !has_more;
}
intptr_t String::CompareTo(const String& other) const {
const intptr_t this_len = this->Length();
const intptr_t other_len = other.IsNull() ? 0 : other.Length();
const intptr_t len = (this_len < other_len) ? this_len : other_len;
for (intptr_t i = 0; i < len; i++) {
int32_t this_code_point = this->CharAt(i);
int32_t other_code_point = other.CharAt(i);
if (this_code_point < other_code_point) {
return -1;
}
if (this_code_point > other_code_point) {
return 1;
}
}
if (this_len < other_len) return -1;
if (this_len > other_len) return 1;
return 0;
}
bool String::StartsWith(const String& other) const {
if (other.IsNull() || (other.Length() > this->Length())) {
return false;
}
intptr_t slen = other.Length();
for (int i = 0; i < slen; i++) {
if (this->CharAt(i) != other.CharAt(i)) {
return false;
}
}
return true;
}
RawInstance* String::CheckAndCanonicalize(const char** error_str) const {
if (IsCanonical()) {
return this->raw();
}
return Symbols::New(*this);
}
RawString* String::New(const char* cstr, Heap::Space space) {
ASSERT(cstr != NULL);
intptr_t array_len = strlen(cstr);
const uint8_t* utf8_array = reinterpret_cast<const uint8_t*>(cstr);
return String::FromUTF8(utf8_array, array_len, space);
}
RawString* String::FromUTF8(const uint8_t* utf8_array,
intptr_t array_len,
Heap::Space space) {
Utf8::Type type;
intptr_t len = Utf8::CodeUnitCount(utf8_array, array_len, &type);
if (type == Utf8::kLatin1) {
const String& strobj = String::Handle(OneByteString::New(len, space));
if (len > 0) {
NoGCScope no_gc;
Utf8::DecodeToLatin1(utf8_array, array_len,
OneByteString::CharAddr(strobj, 0), len);
}
return strobj.raw();
}
ASSERT((type == Utf8::kBMP) || (type == Utf8::kSupplementary));
const String& strobj = String::Handle(TwoByteString::New(len, space));
NoGCScope no_gc;
Utf8::DecodeToUTF16(utf8_array, array_len,
TwoByteString::CharAddr(strobj, 0), len);
return strobj.raw();
}
RawString* String::FromLatin1(const uint8_t* latin1_array,
intptr_t array_len,
Heap::Space space) {
return OneByteString::New(latin1_array, array_len, space);
}
RawString* String::FromUTF16(const uint16_t* utf16_array,
intptr_t array_len,
Heap::Space space) {
bool is_one_byte_string = true;
for (intptr_t i = 0; i < array_len; ++i) {
if (!Utf::IsLatin1(utf16_array[i])) {
is_one_byte_string = false;
break;
}
}
if (is_one_byte_string) {
return OneByteString::New(utf16_array, array_len, space);
}
return TwoByteString::New(utf16_array, array_len, space);
}
RawString* String::FromUTF32(const int32_t* utf32_array,
intptr_t array_len,
Heap::Space space) {
bool is_one_byte_string = true;
intptr_t utf16_len = array_len;
for (intptr_t i = 0; i < array_len; ++i) {
if (!Utf::IsLatin1(utf32_array[i])) {
is_one_byte_string = false;
if (Utf::IsSupplementary(utf32_array[i])) {
utf16_len += 1;
}
}
}
if (is_one_byte_string) {
return OneByteString::New(utf32_array, array_len, space);
}
return TwoByteString::New(utf16_len, utf32_array, array_len, space);
}
RawString* String::New(const String& str, Heap::Space space) {
// Currently this just creates a copy of the string in the correct space.
// Once we have external string support, this will also create a heap copy of
// the string if necessary. Some optimizations are possible, such as not
// copying internal strings into the same space.
intptr_t len = str.Length();
String& result = String::Handle();
intptr_t char_size = str.CharSize();
if (char_size == kOneByteChar) {
result = OneByteString::New(len, space);
} else {
ASSERT(char_size == kTwoByteChar);
result = TwoByteString::New(len, space);
}
String::Copy(result, 0, str, 0, len);
return result.raw();
}
RawString* String::NewExternal(const uint8_t* characters,
intptr_t len,
void* peer,
Dart_PeerFinalizer callback,
Heap::Space space) {
return ExternalOneByteString::New(characters, len, peer, callback, space);
}
RawString* String::NewExternal(const uint16_t* characters,
intptr_t len,
void* peer,
Dart_PeerFinalizer callback,
Heap::Space space) {
return ExternalTwoByteString::New(characters, len, peer, callback, space);
}
void String::Copy(const String& dst, intptr_t dst_offset,
const uint8_t* characters,
intptr_t len) {
ASSERT(dst_offset >= 0);
ASSERT(len >= 0);
ASSERT(len <= (dst.Length() - dst_offset));
if (dst.IsOneByteString()) {
NoGCScope no_gc;
if (len > 0) {
memmove(OneByteString::CharAddr(dst, dst_offset),
characters,
len);
}
} else if (dst.IsTwoByteString()) {
for (intptr_t i = 0; i < len; ++i) {
*TwoByteString::CharAddr(dst, i + dst_offset) = characters[i];
}
}
}
void String::Copy(const String& dst, intptr_t dst_offset,
const uint16_t* utf16_array,
intptr_t array_len) {
ASSERT(dst_offset >= 0);
ASSERT(array_len >= 0);
ASSERT(array_len <= (dst.Length() - dst_offset));
if (dst.IsOneByteString()) {
NoGCScope no_gc;
for (intptr_t i = 0; i < array_len; ++i) {
ASSERT(Utf::IsLatin1(utf16_array[i]));
*OneByteString::CharAddr(dst, i + dst_offset) = utf16_array[i];
}
} else {
ASSERT(dst.IsTwoByteString());
NoGCScope no_gc;
if (array_len > 0) {
memmove(TwoByteString::CharAddr(dst, dst_offset),
utf16_array,
array_len * 2);
}
}
}
void String::Copy(const String& dst, intptr_t dst_offset,
const String& src, intptr_t src_offset,
intptr_t len) {
ASSERT(dst_offset >= 0);
ASSERT(src_offset >= 0);
ASSERT(len >= 0);
ASSERT(len <= (dst.Length() - dst_offset));
ASSERT(len <= (src.Length() - src_offset));
if (len > 0) {
intptr_t char_size = src.CharSize();
if (char_size == kOneByteChar) {
if (src.IsOneByteString()) {
NoGCScope no_gc;
String::Copy(dst,
dst_offset,
OneByteString::CharAddr(src, src_offset),
len);
} else {
ASSERT(src.IsExternalOneByteString());
NoGCScope no_gc;
String::Copy(dst,
dst_offset,
ExternalOneByteString::CharAddr(src, src_offset),
len);
}
} else {
ASSERT(char_size == kTwoByteChar);
if (src.IsTwoByteString()) {
NoGCScope no_gc;
String::Copy(dst,
dst_offset,
TwoByteString::CharAddr(src, src_offset),
len);
} else {
ASSERT(src.IsExternalTwoByteString());
NoGCScope no_gc;
String::Copy(dst,
dst_offset,
ExternalTwoByteString::CharAddr(src, src_offset),
len);
}
}
}
}
RawString* String::EscapeSpecialCharacters(const String& str) {
if (str.IsOneByteString()) {
return OneByteString::EscapeSpecialCharacters(str);
}
ASSERT(str.IsTwoByteString());
return TwoByteString::EscapeSpecialCharacters(str);
}
RawString* String::NewFormatted(const char* format, ...) {
va_list args;
va_start(args, format);
RawString* result = NewFormattedV(format, args);
NoGCScope no_gc;
va_end(args);
return result;
}
RawString* String::NewFormattedV(const char* format, va_list args) {
va_list args_copy;
va_copy(args_copy, args);
intptr_t len = OS::VSNPrint(NULL, 0, format, args_copy);
va_end(args_copy);
Zone* zone = Isolate::Current()->current_zone();
char* buffer = zone->Alloc<char>(len + 1);
OS::VSNPrint(buffer, (len + 1), format, args);
return String::New(buffer);
}
RawString* String::Concat(const String& str1,
const String& str2,
Heap::Space space) {
ASSERT(!str1.IsNull() && !str2.IsNull());
intptr_t char_size = Utils::Maximum(str1.CharSize(), str2.CharSize());
if (char_size == kTwoByteChar) {
return TwoByteString::Concat(str1, str2, space);
}
return OneByteString::Concat(str1, str2, space);
}
RawString* String::ConcatAll(const Array& strings,
Heap::Space space) {
ASSERT(!strings.IsNull());
intptr_t result_len = 0;
intptr_t strings_len = strings.Length();
String& str = String::Handle();
intptr_t char_size = kOneByteChar;
for (intptr_t i = 0; i < strings_len; i++) {
str ^= strings.At(i);
intptr_t str_len = str.Length();
if ((kMaxElements - result_len) < str_len) {
Isolate* isolate = Isolate::Current();
const Instance& exception =
Instance::Handle(isolate->object_store()->out_of_memory());
Exceptions::Throw(exception);
UNREACHABLE();
}
result_len += str_len;
char_size = Utils::Maximum(char_size, str.CharSize());
}
if (char_size == kOneByteChar) {
return OneByteString::ConcatAll(strings, result_len, space);
}
ASSERT(char_size == kTwoByteChar);
return TwoByteString::ConcatAll(strings, result_len, space);
}
RawString* String::SubString(const String& str,
intptr_t begin_index,
Heap::Space space) {
ASSERT(!str.IsNull());
if (begin_index >= str.Length()) {
return String::null();
}
return String::SubString(str, begin_index, (str.Length() - begin_index));
}
RawString* String::SubString(const String& str,
intptr_t begin_index,
intptr_t length,
Heap::Space space) {
ASSERT(!str.IsNull());
ASSERT(begin_index >= 0);
ASSERT(length >= 0);
if (begin_index <= str.Length() && length == 0) {
return Symbols::Empty().raw();
}
if (begin_index > str.Length()) {
return String::null();
}
String& result = String::Handle();
bool is_one_byte_string = true;
intptr_t char_size = str.CharSize();
if (char_size == kTwoByteChar) {
for (intptr_t i = begin_index; i < begin_index + length; ++i) {
if (!Utf::IsLatin1(str.CharAt(i))) {
is_one_byte_string = false;
break;
}
}
}
if (is_one_byte_string) {
result = OneByteString::New(length, space);
} else {
result = TwoByteString::New(length, space);
}
String::Copy(result, 0, str, begin_index, length);
return result.raw();
}
const char* String::ToCString() const {
if (IsOneByteString()) {
// Quick conversion if OneByteString contains only ASCII characters.
intptr_t len = Length();
if (len == 0) {
return "";
}
Zone* zone = Isolate::Current()->current_zone();
uint8_t* result = zone->Alloc<uint8_t>(len + 1);
NoGCScope no_gc;
const uint8_t* original_str = OneByteString::CharAddr(*this, 0);
for (intptr_t i = 0; i < len; i++) {
if (original_str[i] <= Utf8::kMaxOneByteChar) {
result[i] = original_str[i];
} else {
len = -1;
break;
}
}
if (len > 0) {
result[len] = 0;
return reinterpret_cast<const char*>(result);
}
}
const intptr_t len = Utf8::Length(*this);
Zone* zone = Isolate::Current()->current_zone();
uint8_t* result = zone->Alloc<uint8_t>(len + 1);
ToUTF8(result, len);
result[len] = 0;
return reinterpret_cast<const char*>(result);
}
void String::ToUTF8(uint8_t* utf8_array, intptr_t array_len) const {
ASSERT(array_len >= Utf8::Length(*this));
Utf8::Encode(*this, reinterpret_cast<char*>(utf8_array), array_len);
}
static FinalizablePersistentHandle* AddFinalizer(
const Object& referent,
void* peer,
Dart_WeakPersistentHandleFinalizer callback) {
ASSERT((callback != NULL && peer != NULL) ||
(callback == NULL && peer == NULL));
ApiState* state = Isolate::Current()->api_state();
ASSERT(state != NULL);
FinalizablePersistentHandle* weak_ref =
state->weak_persistent_handles().AllocateHandle();
weak_ref->set_raw(referent);
weak_ref->set_peer(peer);
weak_ref->set_callback(callback);
return weak_ref;
}
RawString* String::MakeExternal(void* array,
intptr_t length,
void* peer,
Dart_PeerFinalizer cback) const {
NoGCScope no_gc;
ASSERT(array != NULL);
intptr_t str_length = this->Length();
ASSERT(length >= (str_length * this->CharSize()));
intptr_t class_id = raw()->GetClassId();
intptr_t used_size = 0;
intptr_t original_size = 0;
uword tags = raw_ptr()->tags_;
ASSERT(!InVMHeap());
if (class_id == kOneByteStringCid) {
used_size = ExternalOneByteString::InstanceSize();
original_size = OneByteString::InstanceSize(str_length);
ASSERT(original_size >= used_size);
// Copy the data into the external array.
if (str_length > 0) {
memmove(array, OneByteString::CharAddr(*this, 0), str_length);
}
// Update the class information of the object.
const intptr_t class_id = kExternalOneByteStringCid;
tags = RawObject::SizeTag::update(used_size, tags);
tags = RawObject::ClassIdTag::update(class_id, tags);
raw_ptr()->tags_ = tags;
const String& result = String::Handle(this->raw());
ExternalStringData<uint8_t>* ext_data = new ExternalStringData<uint8_t>(
reinterpret_cast<const uint8_t*>(array), peer, cback);
result.SetLength(str_length);
result.SetHash(0);
ExternalOneByteString::SetExternalData(result, ext_data);
AddFinalizer(result, ext_data, ExternalOneByteString::Finalize);
} else {
ASSERT(class_id == kTwoByteStringCid);
used_size = ExternalTwoByteString::InstanceSize();
original_size = TwoByteString::InstanceSize(str_length);
ASSERT(original_size >= used_size);
// Copy the data into the external array.
if (str_length > 0) {
memmove(array,
TwoByteString::CharAddr(*this, 0),
(str_length * kTwoByteChar));
}
// Update the class information of the object.
const intptr_t class_id = kExternalTwoByteStringCid;
tags = RawObject::SizeTag::update(used_size, tags);
tags = RawObject::ClassIdTag::update(class_id, tags);
raw_ptr()->tags_ = tags;
const String& result = String::Handle(this->raw());
ExternalStringData<uint16_t>* ext_data = new ExternalStringData<uint16_t>(
reinterpret_cast<const uint16_t*>(array), peer, cback);
result.SetLength(str_length);
result.SetHash(0);
ExternalTwoByteString::SetExternalData(result, ext_data);
AddFinalizer(result, ext_data, ExternalTwoByteString::Finalize);
}
// If there is any left over space fill it with either an Array object or
// just a plain object (depending on the amount of left over space) so
// that it can be traversed over successfully during garbage collection.
Object::MakeUnusedSpaceTraversable(*this, original_size, used_size);
return this->raw();
}
RawString* String::Transform(int32_t (*mapping)(int32_t ch),
const String& str,
Heap::Space space) {
ASSERT(!str.IsNull());
bool has_mapping = false;
int32_t dst_max = 0;
CodePointIterator it(str);
while (it.Next()) {
int32_t src = it.Current();
int32_t dst = mapping(src);
if (src != dst) {
has_mapping = true;
}
dst_max = Utils::Maximum(dst_max, dst);
}
if (!has_mapping) {
return str.raw();
}
if (Utf::IsLatin1(dst_max)) {
return OneByteString::Transform(mapping, str, space);
}
ASSERT(Utf::IsBmp(dst_max) || Utf::IsSupplementary(dst_max));
return TwoByteString::Transform(mapping, str, space);
}
RawString* String::ToUpperCase(const String& str, Heap::Space space) {
// TODO(cshapiro): create a fast-path for OneByteString instances.
return Transform(CaseMapping::ToUpper, str, space);
}
RawString* String::ToLowerCase(const String& str, Heap::Space space) {
// TODO(cshapiro): create a fast-path for OneByteString instances.
return Transform(CaseMapping::ToLower, str, space);
}
// Check to see if 'str1' matches 'str2' as is or
// once the private key separator is stripped from str2.
//
// Things are made more complicated by the fact that constructors are
// added *after* the private suffix, so "foo@123.named" should match
// "foo.named".
//
// Also, the private suffix can occur more than once in the name, as in:
//
// _ReceivePortImpl@6be832b._internal@6be832b
//
template<typename T1, typename T2>
static bool EqualsIgnoringPrivateKey(const String& str1,
const String& str2) {
intptr_t len = str1.Length();
intptr_t str2_len = str2.Length();
if (len == str2_len) {
for (intptr_t i = 0; i < len; i++) {
if (T1::CharAt(str1, i) != T2::CharAt(str2, i)) {
return false;
}
}
return true;
}
if (len < str2_len) {
return false; // No way they can match.
}
intptr_t pos = 0;
intptr_t str2_pos = 0;
while (pos < len) {
int32_t ch = T1::CharAt(str1, pos);
pos++;
if (ch == Scanner::kPrivateKeySeparator) {
// Consume a private key separator.
while ((pos < len) && (T1::CharAt(str1, pos) != '.')) {
pos++;
}
// Resume matching characters.
continue;
}
if ((str2_pos == str2_len) || (ch != T2::CharAt(str2, str2_pos))) {
return false;
}
str2_pos++;
}
// We have reached the end of mangled_name string.
ASSERT(pos == len);
return (str2_pos == str2_len);
}
#define EQUALS_IGNORING_PRIVATE_KEY(class_id, type, str1, str2) \
switch (class_id) { \
case kOneByteStringCid : \
return dart::EqualsIgnoringPrivateKey<type, OneByteString>(str1, str2); \
case kTwoByteStringCid : \
return dart::EqualsIgnoringPrivateKey<type, TwoByteString>(str1, str2); \
case kExternalOneByteStringCid : \
return dart::EqualsIgnoringPrivateKey<type, ExternalOneByteString>(str1, \
str2);\
case kExternalTwoByteStringCid : \
return dart::EqualsIgnoringPrivateKey<type, ExternalTwoByteString>(str1, \
str2);\
} \
UNREACHABLE(); \
bool String::EqualsIgnoringPrivateKey(const String& str1,
const String& str2) {
if (str1.raw() == str2.raw()) {
return true; // Both handles point to the same raw instance.
}
NoGCScope no_gc;
intptr_t str1_class_id = str1.raw()->GetClassId();
intptr_t str2_class_id = str2.raw()->GetClassId();
switch (str1_class_id) {
case kOneByteStringCid :
EQUALS_IGNORING_PRIVATE_KEY(str2_class_id, OneByteString, str1, str2);
break;
case kTwoByteStringCid :
EQUALS_IGNORING_PRIVATE_KEY(str2_class_id, TwoByteString, str1, str2);
break;
case kExternalOneByteStringCid :
EQUALS_IGNORING_PRIVATE_KEY(str2_class_id,
ExternalOneByteString, str1, str2);
break;
case kExternalTwoByteStringCid :
EQUALS_IGNORING_PRIVATE_KEY(str2_class_id,
ExternalTwoByteString, str1, str2);
break;
}
UNREACHABLE();
return false;
}
bool String::CodePointIterator::Next() {
ASSERT(index_ >= -1);
intptr_t length = Utf16::Length(ch_);
if (index_ < (end_ - length)) {
index_ += length;
ch_ = str_.CharAt(index_);
if (Utf16::IsLeadSurrogate(ch_) && (index_ < (end_ - 1))) {
int32_t ch2 = str_.CharAt(index_ + 1);
if (Utf16::IsTrailSurrogate(ch2)) {
ch_ = Utf16::Decode(ch_, ch2);
}
}
return true;
}
index_ = end_;
return false;
}
RawOneByteString* OneByteString::EscapeSpecialCharacters(const String& str) {
intptr_t len = str.Length();
if (len > 0) {
intptr_t num_escapes = 0;
intptr_t index = 0;
for (intptr_t i = 0; i < len; i++) {
if (IsSpecialCharacter(*CharAddr(str, i))) {
num_escapes += 1;
}
}
const String& dststr = String::Handle(
OneByteString::New(len + num_escapes, Heap::kNew));
for (intptr_t i = 0; i < len; i++) {
if (IsSpecialCharacter(*CharAddr(str, i))) {
*(CharAddr(dststr, index)) = '\\';
*(CharAddr(dststr, index + 1)) = SpecialCharacter(*CharAddr(str, i));
index += 2;
} else {
*(CharAddr(dststr, index)) = *CharAddr(str, i);
index += 1;
}
}
return OneByteString::raw(dststr);
}
return OneByteString::null();
}
RawOneByteString* OneByteString::New(intptr_t len,
Heap::Space space) {
ASSERT(Isolate::Current() == Dart::vm_isolate() ||
Isolate::Current()->object_store()->one_byte_string_class() !=
Class::null());
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in OneByteString::New: invalid len %"Pd"\n", len);
}
{
RawObject* raw = Object::Allocate(OneByteString::kClassId,
OneByteString::InstanceSize(len),
space);
NoGCScope no_gc;
RawOneByteString* result = reinterpret_cast<RawOneByteString*>(raw);
result->ptr()->length_ = Smi::New(len);
result->ptr()->hash_ = 0;
return result;
}
}
RawOneByteString* OneByteString::New(const uint8_t* characters,
intptr_t len,
Heap::Space space) {
const String& result = String::Handle(OneByteString::New(len, space));
if (len > 0) {
NoGCScope no_gc;
memmove(CharAddr(result, 0), characters, len);
}
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::New(const uint16_t* characters,
intptr_t len,
Heap::Space space) {
const String& result =String::Handle(OneByteString::New(len, space));
for (intptr_t i = 0; i < len; ++i) {
ASSERT(Utf::IsLatin1(characters[i]));
*CharAddr(result, i) = characters[i];
}
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::New(const int32_t* characters,
intptr_t len,
Heap::Space space) {
const String& result = String::Handle(OneByteString::New(len, space));
for (intptr_t i = 0; i < len; ++i) {
ASSERT(Utf::IsLatin1(characters[i]));
*CharAddr(result, i) = characters[i];
}
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::New(const String& str,
Heap::Space space) {
intptr_t len = str.Length();
const String& result = String::Handle(OneByteString::New(len, space));
String::Copy(result, 0, str, 0, len);
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::New(const String& other_one_byte_string,
intptr_t other_start_index,
intptr_t other_len,
Heap::Space space) {
const String& result = String::Handle(OneByteString::New(other_len, space));
ASSERT(other_one_byte_string.IsOneByteString());
if (other_len > 0) {
NoGCScope no_gc;
memmove(OneByteString::CharAddr(result, 0),
OneByteString::CharAddr(other_one_byte_string, other_start_index),
other_len);
}
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::Concat(const String& str1,
const String& str2,
Heap::Space space) {
intptr_t len1 = str1.Length();
intptr_t len2 = str2.Length();
intptr_t len = len1 + len2;
const String& result = String::Handle(OneByteString::New(len, space));
String::Copy(result, 0, str1, 0, len1);
String::Copy(result, len1, str2, 0, len2);
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::ConcatAll(const Array& strings,
intptr_t len,
Heap::Space space) {
const String& result = String::Handle(OneByteString::New(len, space));
String& str = String::Handle();
intptr_t strings_len = strings.Length();
intptr_t pos = 0;
for (intptr_t i = 0; i < strings_len; i++) {
str ^= strings.At(i);
intptr_t str_len = str.Length();
String::Copy(result, pos, str, 0, str_len);
ASSERT((kMaxElements - pos) >= str_len);
pos += str_len;
}
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::Transform(int32_t (*mapping)(int32_t ch),
const String& str,
Heap::Space space) {
ASSERT(!str.IsNull());
intptr_t len = str.Length();
const String& result = String::Handle(OneByteString::New(len, space));
for (intptr_t i = 0; i < len; ++i) {
int32_t ch = mapping(str.CharAt(i));
ASSERT(Utf::IsLatin1(ch));
*CharAddr(result, i) = ch;
}
return OneByteString::raw(result);
}
RawOneByteString* OneByteString::SubStringUnchecked(const String& str,
intptr_t begin_index,
intptr_t length,
Heap::Space space) {
ASSERT(!str.IsNull() && str.IsOneByteString());
ASSERT(begin_index >= 0);
ASSERT(length >= 0);
if (begin_index <= str.Length() && length == 0) {
return OneByteString::raw(Symbols::Empty());
}
ASSERT(begin_index < str.Length());
RawOneByteString* result = OneByteString::New(length, space);
NoGCScope no_gc;
if (length > 0) {
uint8_t* dest = &result->ptr()->data_[0];
uint8_t* src = &raw_ptr(str)->data_[begin_index];
memmove(dest, src, length);
}
return result;
}
RawTwoByteString* TwoByteString::EscapeSpecialCharacters(const String& str) {
intptr_t len = str.Length();
if (len > 0) {
intptr_t num_escapes = 0;
intptr_t index = 0;
for (intptr_t i = 0; i < len; i++) {
if (IsSpecialCharacter(*CharAddr(str, i))) {
num_escapes += 1;
}
}
const String& dststr = String::Handle(
TwoByteString::New(len + num_escapes, Heap::kNew));
for (intptr_t i = 0; i < len; i++) {
if (IsSpecialCharacter(*CharAddr(str, i))) {
*(CharAddr(dststr, index)) = '\\';
*(CharAddr(dststr, index + 1)) = SpecialCharacter(*CharAddr(str, i));
index += 2;
} else {
*(CharAddr(dststr, index)) = *CharAddr(str, i);
index += 1;
}
}
return TwoByteString::raw(dststr);
}
return TwoByteString::null();
}
RawTwoByteString* TwoByteString::New(intptr_t len,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->two_byte_string_class());
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in TwoByteString::New: invalid len %"Pd"\n", len);
}
String& result = String::Handle();
{
RawObject* raw = Object::Allocate(TwoByteString::kClassId,
TwoByteString::InstanceSize(len),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(len);
result.SetHash(0);
}
return TwoByteString::raw(result);
}
RawTwoByteString* TwoByteString::New(const uint16_t* utf16_array,
intptr_t array_len,
Heap::Space space) {
ASSERT(array_len > 0);
const String& result = String::Handle(TwoByteString::New(array_len, space));
{
NoGCScope no_gc;
memmove(CharAddr(result, 0), utf16_array, (array_len * 2));
}
return TwoByteString::raw(result);
}
RawTwoByteString* TwoByteString::New(intptr_t utf16_len,
const int32_t* utf32_array,
intptr_t array_len,
Heap::Space space) {
ASSERT((array_len > 0) && (utf16_len >= array_len));
const String& result = String::Handle(TwoByteString::New(utf16_len, space));
{
NoGCScope no_gc;
intptr_t j = 0;
for (intptr_t i = 0; i < array_len; ++i) {
if (Utf::IsSupplementary(utf32_array[i])) {
ASSERT(j < (utf16_len - 1));
Utf16::Encode(utf32_array[i], CharAddr(result, j));
j += 2;
} else {
ASSERT(j < utf16_len);
*CharAddr(result, j) = utf32_array[i];
j += 1;
}
}
}
return TwoByteString::raw(result);
}
RawTwoByteString* TwoByteString::New(const String& str,
Heap::Space space) {
intptr_t len = str.Length();
const String& result = String::Handle(TwoByteString::New(len, space));
String::Copy(result, 0, str, 0, len);
return TwoByteString::raw(result);
}
RawTwoByteString* TwoByteString::Concat(const String& str1,
const String& str2,
Heap::Space space) {
intptr_t len1 = str1.Length();
intptr_t len2 = str2.Length();
intptr_t len = len1 + len2;
const String& result = String::Handle(TwoByteString::New(len, space));
String::Copy(result, 0, str1, 0, len1);
String::Copy(result, len1, str2, 0, len2);
return TwoByteString::raw(result);
}
RawTwoByteString* TwoByteString::ConcatAll(const Array& strings,
intptr_t len,
Heap::Space space) {
const String& result = String::Handle(TwoByteString::New(len, space));
String& str = String::Handle();
intptr_t strings_len = strings.Length();
intptr_t pos = 0;
for (intptr_t i = 0; i < strings_len; i++) {
str ^= strings.At(i);
intptr_t str_len = str.Length();
String::Copy(result, pos, str, 0, str_len);
ASSERT((kMaxElements - pos) >= str_len);
pos += str_len;
}
return TwoByteString::raw(result);
}
RawTwoByteString* TwoByteString::Transform(int32_t (*mapping)(int32_t ch),
const String& str,
Heap::Space space) {
ASSERT(!str.IsNull());
intptr_t len = str.Length();
const String& result = String::Handle(TwoByteString::New(len, space));
String::CodePointIterator it(str);
intptr_t i = 0;
while (it.Next()) {
int32_t src = it.Current();
int32_t dst = mapping(src);
ASSERT(dst >= 0 && dst <= 0x10FFFF);
intptr_t len = Utf16::Length(dst);
if (len == 1) {
*CharAddr(result, i) = dst;
} else {
ASSERT(len == 2);
Utf16::Encode(dst, CharAddr(result, i));
}
i += len;
}
return TwoByteString::raw(result);
}
RawExternalOneByteString* ExternalOneByteString::New(
const uint8_t* data,
intptr_t len,
void* peer,
Dart_PeerFinalizer callback,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->
external_one_byte_string_class() != Class::null());
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in ExternalOneByteString::New: invalid len %"Pd"\n",
len);
}
String& result = String::Handle();
ExternalStringData<uint8_t>* external_data =
new ExternalStringData<uint8_t>(data, peer, callback);
{
RawObject* raw = Object::Allocate(ExternalOneByteString::kClassId,
ExternalOneByteString::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(len);
result.SetHash(0);
SetExternalData(result, external_data);
}
AddFinalizer(result, external_data, ExternalOneByteString::Finalize);
return ExternalOneByteString::raw(result);
}
void ExternalOneByteString::Finalize(Dart_WeakPersistentHandle handle,
void* peer) {
delete reinterpret_cast<ExternalStringData<uint8_t>*>(peer);
DeleteWeakPersistentHandle(handle);
}
RawExternalTwoByteString* ExternalTwoByteString::New(
const uint16_t* data,
intptr_t len,
void* peer,
Dart_PeerFinalizer callback,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->external_two_byte_string_class() !=
Class::null());
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in ExternalTwoByteString::New: invalid len %"Pd"\n",
len);
}
String& result = String::Handle();
ExternalStringData<uint16_t>* external_data =
new ExternalStringData<uint16_t>(data, peer, callback);
{
RawObject* raw = Object::Allocate(ExternalTwoByteString::kClassId,
ExternalTwoByteString::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(len);
result.SetHash(0);
SetExternalData(result, external_data);
}
AddFinalizer(result, external_data, ExternalTwoByteString::Finalize);
return ExternalTwoByteString::raw(result);
}
void ExternalTwoByteString::Finalize(Dart_WeakPersistentHandle handle,
void* peer) {
delete reinterpret_cast<ExternalStringData<uint16_t>*>(peer);
DeleteWeakPersistentHandle(handle);
}
RawBool* Bool::New(bool value) {
ASSERT(Isolate::Current()->object_store()->bool_class() != Class::null());
Bool& result = Bool::Handle();
{
// Since the two boolean instances are singletons we allocate them straight
// in the old generation.
RawObject* raw = Object::Allocate(Bool::kClassId,
Bool::InstanceSize(),
Heap::kOld);
NoGCScope no_gc;
result ^= raw;
}
result.set_value(value);
result.SetCanonical();
return result.raw();
}
const char* Bool::ToCString() const {
return value() ? "true" : "false";
}
bool Array::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
// Both handles point to the same raw instance.
return true;
}
if (!other.IsArray() || other.IsNull()) {
return false;
}
// Must have the same type arguments.
if (!AbstractTypeArguments::AreEqual(
AbstractTypeArguments::Handle(GetTypeArguments()),
AbstractTypeArguments::Handle(other.GetTypeArguments()))) {
return false;
}
const Array& other_arr = Array::Cast(other);
intptr_t len = this->Length();
if (len != other_arr.Length()) {
return false;
}
for (intptr_t i = 0; i < len; i++) {
if (this->At(i) != other_arr.At(i)) {
return false;
}
}
return true;
}
RawArray* Array::New(intptr_t len, Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->array_class() != Class::null());
return New(kClassId, len, space);
}
RawArray* Array::New(intptr_t class_id, intptr_t len, Heap::Space space) {
if (len < 0 || len > Array::kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in Array::New: invalid len %"Pd"\n", len);
}
Array& result = Array::Handle();
{
RawObject* raw = Object::Allocate(class_id,
Array::InstanceSize(len),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(len);
}
return result.raw();
}
void Array::MakeImmutable() const {
NoGCScope no_gc;
uword tags = raw_ptr()->tags_;
tags = RawObject::ClassIdTag::update(kImmutableArrayCid, tags);
raw_ptr()->tags_ = tags;
}
const char* Array::ToCString() const {
if (IsNull()) {
return IsImmutable() ? "ImmutableArray NULL" : "Array NULL";
}
const char* format = !IsImmutable() ? "Array len:%"Pd"" :
"Immutable Array len:%"Pd"";
intptr_t len = OS::SNPrint(NULL, 0, format, Length()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, Length());
return chars;
}
RawArray* Array::Grow(const Array& source, int new_length, Heap::Space space) {
const Array& result = Array::Handle(Array::New(new_length, space));
intptr_t len = 0;
if (!source.IsNull()) {
len = source.Length();
result.SetTypeArguments(
AbstractTypeArguments::Handle(source.GetTypeArguments()));
}
ASSERT(new_length >= len); // Cannot copy 'source' into new array.
ASSERT(new_length != len); // Unnecessary copying of array.
Object& obj = Object::Handle();
for (int i = 0; i < len; i++) {
obj = source.At(i);
result.SetAt(i, obj);
}
return result.raw();
}
RawArray* Array::MakeArray(const GrowableObjectArray& growable_array) {
ASSERT(!growable_array.IsNull());
intptr_t used_len = growable_array.Length();
if (used_len == 0) {
return Object::empty_array().raw();
}
intptr_t capacity_len = growable_array.Capacity();
Isolate* isolate = Isolate::Current();
const Array& array = Array::Handle(isolate, growable_array.data());
intptr_t capacity_size = Array::InstanceSize(capacity_len);
intptr_t used_size = Array::InstanceSize(used_len);
NoGCScope no_gc;
// Update the size in the header field and length of the array object.
uword tags = array.raw_ptr()->tags_;
ASSERT(kArrayCid == RawObject::ClassIdTag::decode(tags));
tags = RawObject::SizeTag::update(used_size, tags);
array.raw_ptr()->tags_ = tags;
array.SetLength(used_len);
// Null the GrowableObjectArray, we are removing it's backing array.
growable_array.SetLength(0);
growable_array.SetData(Object::empty_array());
// If there is any left over space fill it with either an Array object or
// just a plain object (depending on the amount of left over space) so
// that it can be traversed over successfully during garbage collection.
Object::MakeUnusedSpaceTraversable(array, capacity_size, used_size);
return array.raw();
}
RawImmutableArray* ImmutableArray::New(intptr_t len,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->immutable_array_class() !=
Class::null());
return reinterpret_cast<RawImmutableArray*>(Array::New(kClassId, len, space));
}
void GrowableObjectArray::Add(const Object& value, Heap::Space space) const {
ASSERT(!IsNull());
if (Length() == Capacity()) {
// TODO(Issue 2500): Need a better growth strategy.
intptr_t new_capacity = (Capacity() == 0) ? 4 : Capacity() * 2;
if (new_capacity <= Capacity()) {
// Use the preallocated out of memory exception to avoid calling
// into dart code or allocating any code.
Isolate* isolate = Isolate::Current();
const Instance& exception =
Instance::Handle(isolate->object_store()->out_of_memory());
Exceptions::Throw(exception);
UNREACHABLE();
}
Grow(new_capacity, space);
}
ASSERT(Length() < Capacity());
intptr_t index = Length();
SetLength(index + 1);
SetAt(index, value);
}
void GrowableObjectArray::Grow(intptr_t new_capacity, Heap::Space space) const {
ASSERT(new_capacity > Capacity());
const Array& contents = Array::Handle(data());
const Array& new_contents =
Array::Handle(Array::Grow(contents, new_capacity, space));
StorePointer(&(raw_ptr()->data_), new_contents.raw());
}
RawObject* GrowableObjectArray::RemoveLast() const {
ASSERT(!IsNull());
ASSERT(Length() > 0);
intptr_t index = Length() - 1;
const Array& contents = Array::Handle(data());
const Object& obj = Object::Handle(contents.At(index));
contents.SetAt(index, Object::null_object());
SetLength(index);
return obj.raw();
}
bool GrowableObjectArray::Equals(const Instance& other) const {
// If both handles point to the same raw instance they are equal.
if (this->raw() == other.raw()) {
return true;
}
// Other instance must be non null and a GrowableObjectArray.
if (!other.IsGrowableObjectArray() || other.IsNull()) {
return false;
}
const GrowableObjectArray& other_arr = GrowableObjectArray::Cast(other);
// The capacity and length of both objects must be equal.
if (Capacity() != other_arr.Capacity() || Length() != other_arr.Length()) {
return false;
}
// Both must have the same type arguments.
if (!AbstractTypeArguments::AreEqual(
AbstractTypeArguments::Handle(GetTypeArguments()),
AbstractTypeArguments::Handle(other.GetTypeArguments()))) {
return false;
}
// The data part in both arrays must be identical.
const Array& contents = Array::Handle(data());
const Array& other_contents = Array::Handle(other_arr.data());
for (intptr_t i = 0; i < Length(); i++) {
if (contents.At(i) != other_contents.At(i)) {
return false;
}
}
return true;
}
RawGrowableObjectArray* GrowableObjectArray::New(intptr_t capacity,
Heap::Space space) {
const Array& data = Array::Handle(Array::New(capacity, space));
return New(data, space);
}
RawGrowableObjectArray* GrowableObjectArray::New(const Array& array,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->growable_object_array_class()
!= Class::null());
GrowableObjectArray& result = GrowableObjectArray::Handle();
{
RawObject* raw = Object::Allocate(GrowableObjectArray::kClassId,
GrowableObjectArray::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(0);
result.SetData(array);
}
return result.raw();
}
const char* GrowableObjectArray::ToCString() const {
if (IsNull()) {
return "GrowableObjectArray NULL";
}
const char* format = "GrowableObjectArray len:%"Pd"";
intptr_t len = OS::SNPrint(NULL, 0, format, Length()) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, Length());
return chars;
}
RawFloat32x4* Float32x4::New(float v0, float v1, float v2, float v3,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->float32x4_class() !=
Class::null());
Float32x4& result = Float32x4::Handle();
{
RawObject* raw = Object::Allocate(Float32x4::kClassId,
Float32x4::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_x(v0);
result.set_y(v1);
result.set_z(v2);
result.set_w(v3);
return result.raw();
}
RawFloat32x4* Float32x4::New(simd128_value_t value, Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->float32x4_class() !=
Class::null());
Float32x4& result = Float32x4::Handle();
{
RawObject* raw = Object::Allocate(Float32x4::kClassId,
Float32x4::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_value(value);
return result.raw();
}
simd128_value_t Float32x4::value() const {
return simd128_value_t().readFrom(&raw_ptr()->value_[0]);
}
void Float32x4::set_value(simd128_value_t value) const {
value.writeTo(&raw_ptr()->value_[0]);
}
void Float32x4::set_x(float value) const {
raw_ptr()->value_[0] = value;
}
void Float32x4::set_y(float value) const {
raw_ptr()->value_[1] = value;
}
void Float32x4::set_z(float value) const {
raw_ptr()->value_[2] = value;
}
void Float32x4::set_w(float value) const {
raw_ptr()->value_[3] = value;
}
float Float32x4::x() const {
return raw_ptr()->value_[0];
}
float Float32x4::y() const {
return raw_ptr()->value_[1];
}
float Float32x4::z() const {
return raw_ptr()->value_[2];
}
float Float32x4::w() const {
return raw_ptr()->value_[3];
}
const char* Float32x4::ToCString() const {
const char* kFormat = "[%f, %f, %f, %f]";
float _x = x();
float _y = y();
float _z = z();
float _w = w();
// Calculate the size of the string.
intptr_t len = OS::SNPrint(NULL, 0, kFormat, _x, _y, _z, _w) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, _x, _y, _z, _w);
return chars;
}
RawUint32x4* Uint32x4::New(uint32_t v0, uint32_t v1, uint32_t v2, uint32_t v3,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->uint32x4_class() !=
Class::null());
Uint32x4& result = Uint32x4::Handle();
{
RawObject* raw = Object::Allocate(Uint32x4::kClassId,
Uint32x4::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_x(v0);
result.set_y(v1);
result.set_z(v2);
result.set_w(v3);
return result.raw();
}
RawUint32x4* Uint32x4::New(simd128_value_t value, Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->float32x4_class() !=
Class::null());
Uint32x4& result = Uint32x4::Handle();
{
RawObject* raw = Object::Allocate(Uint32x4::kClassId,
Uint32x4::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_value(value);
return result.raw();
}
void Uint32x4::set_x(uint32_t value) const {
raw_ptr()->value_[0] = value;
}
void Uint32x4::set_y(uint32_t value) const {
raw_ptr()->value_[1] = value;
}
void Uint32x4::set_z(uint32_t value) const {
raw_ptr()->value_[2] = value;
}
void Uint32x4::set_w(uint32_t value) const {
raw_ptr()->value_[3] = value;
}
uint32_t Uint32x4::x() const {
return raw_ptr()->value_[0];
}
uint32_t Uint32x4::y() const {
return raw_ptr()->value_[1];
}
uint32_t Uint32x4::z() const {
return raw_ptr()->value_[2];
}
uint32_t Uint32x4::w() const {
return raw_ptr()->value_[3];
}
simd128_value_t Uint32x4::value() const {
return simd128_value_t().readFrom(&raw_ptr()->value_[0]);
}
void Uint32x4::set_value(simd128_value_t value) const {
value.writeTo(&raw_ptr()->value_[0]);
}
const char* Uint32x4::ToCString() const {
const char* kFormat = "[%08x, %08x, %08x, %08x]";
uint32_t _x = x();
uint32_t _y = y();
uint32_t _z = z();
uint32_t _w = w();
// Calculate the size of the string.
intptr_t len = OS::SNPrint(NULL, 0, kFormat, _x, _y, _z, _w) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, _x, _y, _z, _w);
return chars;
}
const intptr_t TypedData::element_size[] = {
1, // kTypedDataInt8ArrayCid.
1, // kTypedDataUint8ArrayCid.
1, // kTypedDataUint8ClampedArrayCid.
2, // kTypedDataInt16ArrayCid.
2, // kTypedDataUint16ArrayCid.
4, // kTypedDataInt32ArrayCid.
4, // kTypedDataUint32ArrayCid.
8, // kTypedDataInt64ArrayCid.
8, // kTypedDataUint64ArrayCid.
4, // kTypedDataFloat32ArrayCid.
8, // kTypedDataFloat64ArrayCid.
16, // kTypedDataFloat32x4ArrayCid.
};
RawTypedData* TypedData::New(intptr_t class_id,
intptr_t len,
Heap::Space space) {
// TODO(asiva): Add a check for maximum elements.
TypedData& result = TypedData::Handle();
{
// The len field has already been checked by the caller, we only assert
// here that it is within a valid range.
ASSERT((len >= 0) &&
(len < (kSmiMax / TypedData::ElementSizeInBytes(class_id))));
intptr_t lengthInBytes = len * ElementSizeInBytes(class_id);
RawObject* raw = Object::Allocate(class_id,
TypedData::InstanceSize(lengthInBytes),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(len);
if (len > 0) {
memset(result.DataAddr(0), 0, lengthInBytes);
}
}
return result.raw();
}
const char* TypedData::ToCString() const {
return "TypedData";
}
FinalizablePersistentHandle* ExternalTypedData::AddFinalizer(
void* peer, Dart_WeakPersistentHandleFinalizer callback) const {
SetPeer(peer);
return dart::AddFinalizer(*this, peer, callback);
}
RawExternalTypedData* ExternalTypedData::New(intptr_t class_id,
uint8_t* data,
intptr_t len,
Heap::Space space) {
ExternalTypedData& result = ExternalTypedData::Handle();
{
RawObject* raw = Object::Allocate(class_id,
ExternalTypedData::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
result.SetLength(len);
result.SetData(data);
}
return result.raw();
}
const char* ExternalTypedData::ToCString() const {
return "ExternalTypedData";
}
const char* Closure::ToCString(const Instance& closure) {
const Function& fun = Function::Handle(Closure::function(closure));
const bool is_implicit_closure = fun.IsImplicitClosureFunction();
const char* fun_sig = String::Handle(fun.Signature()).ToCString();
const char* from = is_implicit_closure ? " from " : "";
const char* fun_desc = is_implicit_closure ? fun.ToCString() : "";
const char* format = "Closure: %s%s%s";
intptr_t len = OS::SNPrint(NULL, 0, format, fun_sig, from, fun_desc) + 1;
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len);
OS::SNPrint(chars, len, format, fun_sig, from, fun_desc);
return chars;
}
RawInstance* Closure::New(const Function& function,
const Context& context,
Heap::Space space) {
Isolate* isolate = Isolate::Current();
ASSERT(context.isolate() == isolate);
const Class& cls = Class::Handle(function.signature_class());
ASSERT(cls.instance_size() == Closure::InstanceSize());
Instance& result = Instance::Handle();
{
RawObject* raw = Object::Allocate(cls.id(), Closure::InstanceSize(), space);
NoGCScope no_gc;
result ^= raw;
}
Closure::set_function(result, function);
Closure::set_context(result, context);
return result.raw();
}
const char* DartFunction::ToCString() const {
return "Function type class";
}
intptr_t Stacktrace::Length() const {
const Array& code_array = Array::Handle(raw_ptr()->code_array_);
return code_array.Length();
}
RawFunction* Stacktrace::FunctionAtFrame(intptr_t frame_index) const {
const Array& function_array = Array::Handle(raw_ptr()->function_array_);
return reinterpret_cast<RawFunction*>(function_array.At(frame_index));
}
void Stacktrace::SetFunctionAtFrame(intptr_t frame_index,
const Function& func) const {
const Array& function_array = Array::Handle(raw_ptr()->function_array_);
function_array.SetAt(frame_index, func);
}
RawCode* Stacktrace::CodeAtFrame(intptr_t frame_index) const {
const Array& code_array = Array::Handle(raw_ptr()->code_array_);
return reinterpret_cast<RawCode*>(code_array.At(frame_index));
}
void Stacktrace::SetCodeAtFrame(intptr_t frame_index,
const Code& code) const {
const Array& code_array = Array::Handle(raw_ptr()->code_array_);
code_array.SetAt(frame_index, code);
}
RawSmi* Stacktrace::PcOffsetAtFrame(intptr_t frame_index) const {
const Array& pc_offset_array = Array::Handle(raw_ptr()->pc_offset_array_);
return reinterpret_cast<RawSmi*>(pc_offset_array.At(frame_index));
}
void Stacktrace::SetPcOffsetAtFrame(intptr_t frame_index,
const Smi& pc_offset) const {
const Array& pc_offset_array = Array::Handle(raw_ptr()->pc_offset_array_);
pc_offset_array.SetAt(frame_index, pc_offset);
}
void Stacktrace::set_function_array(const Array& function_array) const {
StorePointer(&raw_ptr()->function_array_, function_array.raw());
}
void Stacktrace::set_code_array(const Array& code_array) const {
StorePointer(&raw_ptr()->code_array_, code_array.raw());
}
void Stacktrace::set_pc_offset_array(const Array& pc_offset_array) const {
StorePointer(&raw_ptr()->pc_offset_array_, pc_offset_array.raw());
}
void Stacktrace::set_catch_func_array(const Array& function_array) const {
StorePointer(&raw_ptr()->catch_func_array_, function_array.raw());
}
void Stacktrace::set_catch_code_array(const Array& code_array) const {
StorePointer(&raw_ptr()->catch_code_array_, code_array.raw());
}
void Stacktrace::set_catch_pc_offset_array(const Array& pc_offset_array) const {
StorePointer(&raw_ptr()->catch_pc_offset_array_, pc_offset_array.raw());
}
RawStacktrace* Stacktrace::New(const Array& func_array,
const Array& code_array,
const Array& pc_offset_array,
Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->stacktrace_class() !=
Class::null());
Stacktrace& result = Stacktrace::Handle();
{
RawObject* raw = Object::Allocate(Stacktrace::kClassId,
Stacktrace::InstanceSize(),
space);
NoGCScope no_gc;
result ^= raw;
}
result.set_function_array(func_array);
result.set_code_array(code_array);
result.set_pc_offset_array(pc_offset_array);
result.SetCatchStacktrace(Object::empty_array(),
Object::empty_array(),
Object::empty_array());
return result.raw();
}
void Stacktrace::Append(const Array& func_list,
const Array& code_list,
const Array& pc_offset_list) const {
intptr_t old_length = Length();
intptr_t new_length = old_length + pc_offset_list.Length();
ASSERT(pc_offset_list.Length() == func_list.Length());
ASSERT(pc_offset_list.Length() == code_list.Length());
// Grow the arrays for function, code and pc_offset triplet to accommodate
// the new stack frames.
Array& function_array = Array::Handle(raw_ptr()->function_array_);
Array& code_array = Array::Handle(raw_ptr()->code_array_);
Array& pc_offset_array = Array::Handle(raw_ptr()->pc_offset_array_);
function_array = Array::Grow(function_array, new_length);
code_array = Array::Grow(code_array, new_length);
pc_offset_array = Array::Grow(pc_offset_array, new_length);
set_function_array(function_array);
set_code_array(code_array);
set_pc_offset_array(pc_offset_array);
// Now append the new function and code list to the existing arrays.
intptr_t j = 0;
Object& obj = Object::Handle();
for (intptr_t i = old_length; i < new_length; i++, j++) {
obj = func_list.At(j);
function_array.SetAt(i, obj);
obj = code_list.At(j);
code_array.SetAt(i, obj);
obj = pc_offset_list.At(j);
pc_offset_array.SetAt(i, obj);
}
}
void Stacktrace::SetCatchStacktrace(const Array& func_array,
const Array& code_array,
const Array& pc_offset_array) const {
StorePointer(&raw_ptr()->catch_func_array_, func_array.raw());
StorePointer(&raw_ptr()->catch_code_array_, code_array.raw());
StorePointer(&raw_ptr()->catch_pc_offset_array_, pc_offset_array.raw());
}
RawString* Stacktrace::FullStacktrace() const {
const Array& func_array = Array::Handle(raw_ptr()->catch_func_array_);
if (!func_array.IsNull() && (func_array.Length() > 0)) {
const Array& code_array = Array::Handle(raw_ptr()->catch_code_array_);
const Array& pc_offset_array =
Array::Handle(raw_ptr()->catch_pc_offset_array_);
const Stacktrace& catch_trace = Stacktrace::Handle(
Stacktrace::New(func_array, code_array, pc_offset_array));
intptr_t idx = Length();
const String& trace =
String::Handle(String::New(catch_trace.ToCStringInternal(idx)));
const String& throw_trace =
String::Handle(String::New(ToCStringInternal(0)));
return String::Concat(throw_trace, trace);
}
return String::New(ToCStringInternal(0));
}
const char* Stacktrace::ToCString() const {
const String& trace = String::Handle(FullStacktrace());
return trace.ToCString();
}
const char* Stacktrace::ToCStringInternal(intptr_t frame_index) const {
Isolate* isolate = Isolate::Current();
Function& function = Function::Handle();
Code& code = Code::Handle();
Script& script = Script::Handle();
String& function_name = String::Handle();
String& url = String::Handle();
// Iterate through the stack frames and create C string description
// for each frame.
intptr_t total_len = 0;
const char* kFormat = "#%-6d %s (%s:%d:%d)\n";
GrowableArray<char*> frame_strings;
char* chars;
for (intptr_t i = 0; i < Length(); i++) {
function = FunctionAtFrame(i);
if (function.IsNull()) {
// Check if null function object indicates a stack trace overflow.
if ((i < (Length() - 1)) &&
(FunctionAtFrame(i + 1) != Function::null())) {
const char* kTruncated = "...\n...\n";
intptr_t truncated_len = strlen(kTruncated) + 1;
chars = isolate->current_zone()->Alloc<char>(truncated_len);
OS::SNPrint(chars, truncated_len, "%s", kTruncated);
frame_strings.Add(chars);
}
continue;
}
code = CodeAtFrame(i);
uword pc = code.EntryPoint() + Smi::Value(PcOffsetAtFrame(i));
intptr_t token_pos = code.GetTokenIndexOfPC(pc);
script = function.script();
function_name = function.QualifiedUserVisibleName();
url = script.url();
intptr_t line = -1;
intptr_t column = -1;
if (token_pos >= 0) {
script.GetTokenLocation(token_pos, &line, &column);
}
intptr_t len = OS::SNPrint(NULL, 0, kFormat,
(frame_index + i),
function_name.ToCString(),
url.ToCString(),
line, column);
total_len += len;
chars = isolate->current_zone()->Alloc<char>(len + 1);
OS::SNPrint(chars, (len + 1), kFormat,
(frame_index + i),
function_name.ToCString(),
url.ToCString(),
line, column);
frame_strings.Add(chars);
}
// Now concatenate the frame descriptions into a single C string.
chars = isolate->current_zone()->Alloc<char>(total_len + 1);
intptr_t index = 0;
for (intptr_t i = 0; i < frame_strings.length(); i++) {
index += OS::SNPrint((chars + index),
(total_len + 1 - index),
"%s",
frame_strings[i]);
}
chars[total_len] = '\0';
return chars;
}
void JSRegExp::set_pattern(const String& pattern) const {
StorePointer(&raw_ptr()->pattern_, pattern.raw());
}
void JSRegExp::set_num_bracket_expressions(intptr_t value) const {
raw_ptr()->num_bracket_expressions_ = Smi::New(value);
}
RawJSRegExp* JSRegExp::New(intptr_t len, Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->jsregexp_class() !=
Class::null());
if (len < 0 || len > kMaxElements) {
// This should be caught before we reach here.
FATAL1("Fatal error in JSRegexp::New: invalid len %"Pd"\n", len);
}
JSRegExp& result = JSRegExp::Handle();
{
RawObject* raw = Object::Allocate(JSRegExp::kClassId,
JSRegExp::InstanceSize(len),
space);
NoGCScope no_gc;
result ^= raw;
result.set_type(kUnitialized);
result.set_flags(0);
result.SetLength(len);
}
return result.raw();
}
void* JSRegExp::GetDataStartAddress() const {
intptr_t addr = reinterpret_cast<intptr_t>(raw_ptr());
return reinterpret_cast<void*>(addr + sizeof(RawJSRegExp));
}
RawJSRegExp* JSRegExp::FromDataStartAddress(void* data) {
JSRegExp& regexp = JSRegExp::Handle();
intptr_t addr = reinterpret_cast<intptr_t>(data) - sizeof(RawJSRegExp);
regexp ^= RawObject::FromAddr(addr);
return regexp.raw();
}
const char* JSRegExp::Flags() const {
switch (raw_ptr()->flags_) {
case kGlobal | kIgnoreCase | kMultiLine :
case kIgnoreCase | kMultiLine :
return "im";
case kGlobal | kIgnoreCase :
case kIgnoreCase:
return "i";
case kGlobal | kMultiLine :
case kMultiLine:
return "m";
default:
break;
}
return "";
}
bool JSRegExp::Equals(const Instance& other) const {
if (this->raw() == other.raw()) {
return true; // "===".
}
if (other.IsNull() || !other.IsJSRegExp()) {
return false;
}
const JSRegExp& other_js = JSRegExp::Cast(other);
// Match the pattern.
const String& str1 = String::Handle(pattern());
const String& str2 = String::Handle(other_js.pattern());
if (!str1.Equals(str2)) {
return false;
}
// Match the flags.
if ((is_global() != other_js.is_global()) ||
(is_ignore_case() != other_js.is_ignore_case()) ||
(is_multi_line() != other_js.is_multi_line())) {
return false;
}
return true;
}
const char* JSRegExp::ToCString() const {
const String& str = String::Handle(pattern());
const char* format = "JSRegExp: pattern=%s flags=%s";
intptr_t len = OS::SNPrint(NULL, 0, format, str.ToCString(), Flags());
char* chars = Isolate::Current()->current_zone()->Alloc<char>(len + 1);
OS::SNPrint(chars, (len + 1), format, str.ToCString(), Flags());
return chars;
}
RawWeakProperty* WeakProperty::New(Heap::Space space) {
ASSERT(Isolate::Current()->object_store()->weak_property_class()
!= Class::null());
RawObject* raw = Object::Allocate(WeakProperty::kClassId,
WeakProperty::InstanceSize(),
space);
return reinterpret_cast<RawWeakProperty*>(raw);
}
const char* WeakProperty::ToCString() const {
return "_WeakProperty";
}
} // namespace dart