v8/src/runtime.cc
fschneider@chromium.org 8066271fd2 Optimize calls to object literal properties that are initialized with a function literal.
This allows fast calls and inlining of functions like:

var o = {f: function() { return "foo"; }}
o.f();


Object literals that contain function literals are initially created a dictionary mode
object and only transformed to fast properties once all properties are computed and
added. This allows us to create constant function properties for functions declared
inside the object literal. Function literals inside object literals are marked for
pretenuring so that they work as contant function properties.

Object literals without functions should just function as before.

Review URL: http://codereview.chromium.org/6240012

git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@7283 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
2011-03-21 12:25:31 +00:00

12235 lines
417 KiB
C++

// Copyright 2010 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include <stdlib.h>
#include "v8.h"
#include "accessors.h"
#include "api.h"
#include "arguments.h"
#include "codegen.h"
#include "compilation-cache.h"
#include "compiler.h"
#include "cpu.h"
#include "dateparser-inl.h"
#include "debug.h"
#include "deoptimizer.h"
#include "execution.h"
#include "global-handles.h"
#include "jsregexp.h"
#include "liveedit.h"
#include "liveobjectlist-inl.h"
#include "parser.h"
#include "platform.h"
#include "runtime.h"
#include "runtime-profiler.h"
#include "scopeinfo.h"
#include "smart-pointer.h"
#include "stub-cache.h"
#include "v8threads.h"
#include "string-search.h"
namespace v8 {
namespace internal {
#define RUNTIME_ASSERT(value) \
if (!(value)) return isolate->ThrowIllegalOperation();
// Cast the given object to a value of the specified type and store
// it in a variable with the given name. If the object is not of the
// expected type call IllegalOperation and return.
#define CONVERT_CHECKED(Type, name, obj) \
RUNTIME_ASSERT(obj->Is##Type()); \
Type* name = Type::cast(obj);
#define CONVERT_ARG_CHECKED(Type, name, index) \
RUNTIME_ASSERT(args[index]->Is##Type()); \
Handle<Type> name = args.at<Type>(index);
// Cast the given object to a boolean and store it in a variable with
// the given name. If the object is not a boolean call IllegalOperation
// and return.
#define CONVERT_BOOLEAN_CHECKED(name, obj) \
RUNTIME_ASSERT(obj->IsBoolean()); \
bool name = (obj)->IsTrue();
// Cast the given object to a Smi and store its value in an int variable
// with the given name. If the object is not a Smi call IllegalOperation
// and return.
#define CONVERT_SMI_CHECKED(name, obj) \
RUNTIME_ASSERT(obj->IsSmi()); \
int name = Smi::cast(obj)->value();
// Cast the given object to a double and store it in a variable with
// the given name. If the object is not a number (as opposed to
// the number not-a-number) call IllegalOperation and return.
#define CONVERT_DOUBLE_CHECKED(name, obj) \
RUNTIME_ASSERT(obj->IsNumber()); \
double name = (obj)->Number();
// Call the specified converter on the object *comand store the result in
// a variable of the specified type with the given name. If the
// object is not a Number call IllegalOperation and return.
#define CONVERT_NUMBER_CHECKED(type, name, Type, obj) \
RUNTIME_ASSERT(obj->IsNumber()); \
type name = NumberTo##Type(obj);
MUST_USE_RESULT static MaybeObject* DeepCopyBoilerplate(Isolate* isolate,
JSObject* boilerplate) {
StackLimitCheck check(isolate);
if (check.HasOverflowed()) return isolate->StackOverflow();
Heap* heap = isolate->heap();
Object* result;
{ MaybeObject* maybe_result = heap->CopyJSObject(boilerplate);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
JSObject* copy = JSObject::cast(result);
// Deep copy local properties.
if (copy->HasFastProperties()) {
FixedArray* properties = copy->properties();
for (int i = 0; i < properties->length(); i++) {
Object* value = properties->get(i);
if (value->IsJSObject()) {
JSObject* js_object = JSObject::cast(value);
{ MaybeObject* maybe_result = DeepCopyBoilerplate(isolate, js_object);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
properties->set(i, result);
}
}
int nof = copy->map()->inobject_properties();
for (int i = 0; i < nof; i++) {
Object* value = copy->InObjectPropertyAt(i);
if (value->IsJSObject()) {
JSObject* js_object = JSObject::cast(value);
{ MaybeObject* maybe_result = DeepCopyBoilerplate(isolate, js_object);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
copy->InObjectPropertyAtPut(i, result);
}
}
} else {
{ MaybeObject* maybe_result =
heap->AllocateFixedArray(copy->NumberOfLocalProperties(NONE));
if (!maybe_result->ToObject(&result)) return maybe_result;
}
FixedArray* names = FixedArray::cast(result);
copy->GetLocalPropertyNames(names, 0);
for (int i = 0; i < names->length(); i++) {
ASSERT(names->get(i)->IsString());
String* key_string = String::cast(names->get(i));
PropertyAttributes attributes =
copy->GetLocalPropertyAttribute(key_string);
// Only deep copy fields from the object literal expression.
// In particular, don't try to copy the length attribute of
// an array.
if (attributes != NONE) continue;
Object* value =
copy->GetProperty(key_string, &attributes)->ToObjectUnchecked();
if (value->IsJSObject()) {
JSObject* js_object = JSObject::cast(value);
{ MaybeObject* maybe_result = DeepCopyBoilerplate(isolate, js_object);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
{ MaybeObject* maybe_result =
// Creating object copy for literals. No strict mode needed.
copy->SetProperty(key_string, result, NONE, kNonStrictMode);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
}
}
}
// Deep copy local elements.
// Pixel elements cannot be created using an object literal.
ASSERT(!copy->HasExternalArrayElements());
switch (copy->GetElementsKind()) {
case JSObject::FAST_ELEMENTS: {
FixedArray* elements = FixedArray::cast(copy->elements());
if (elements->map() == heap->fixed_cow_array_map()) {
isolate->counters()->cow_arrays_created_runtime()->Increment();
#ifdef DEBUG
for (int i = 0; i < elements->length(); i++) {
ASSERT(!elements->get(i)->IsJSObject());
}
#endif
} else {
for (int i = 0; i < elements->length(); i++) {
Object* value = elements->get(i);
if (value->IsJSObject()) {
JSObject* js_object = JSObject::cast(value);
{ MaybeObject* maybe_result = DeepCopyBoilerplate(isolate,
js_object);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
elements->set(i, result);
}
}
}
break;
}
case JSObject::DICTIONARY_ELEMENTS: {
NumberDictionary* element_dictionary = copy->element_dictionary();
int capacity = element_dictionary->Capacity();
for (int i = 0; i < capacity; i++) {
Object* k = element_dictionary->KeyAt(i);
if (element_dictionary->IsKey(k)) {
Object* value = element_dictionary->ValueAt(i);
if (value->IsJSObject()) {
JSObject* js_object = JSObject::cast(value);
{ MaybeObject* maybe_result = DeepCopyBoilerplate(isolate,
js_object);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
element_dictionary->ValueAtPut(i, result);
}
}
}
break;
}
default:
UNREACHABLE();
break;
}
return copy;
}
static MaybeObject* Runtime_CloneLiteralBoilerplate(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(JSObject, boilerplate, args[0]);
return DeepCopyBoilerplate(isolate, boilerplate);
}
static MaybeObject* Runtime_CloneShallowLiteralBoilerplate(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(JSObject, boilerplate, args[0]);
return isolate->heap()->CopyJSObject(boilerplate);
}
static Handle<Map> ComputeObjectLiteralMap(
Handle<Context> context,
Handle<FixedArray> constant_properties,
bool* is_result_from_cache) {
Isolate* isolate = context->GetIsolate();
int properties_length = constant_properties->length();
int number_of_properties = properties_length / 2;
if (FLAG_canonicalize_object_literal_maps) {
// Check that there are only symbols and array indices among keys.
int number_of_symbol_keys = 0;
for (int p = 0; p != properties_length; p += 2) {
Object* key = constant_properties->get(p);
uint32_t element_index = 0;
if (key->IsSymbol()) {
number_of_symbol_keys++;
} else if (key->ToArrayIndex(&element_index)) {
// An index key does not require space in the property backing store.
number_of_properties--;
} else {
// Bail out as a non-symbol non-index key makes caching impossible.
// ASSERT to make sure that the if condition after the loop is false.
ASSERT(number_of_symbol_keys != number_of_properties);
break;
}
}
// If we only have symbols and array indices among keys then we can
// use the map cache in the global context.
const int kMaxKeys = 10;
if ((number_of_symbol_keys == number_of_properties) &&
(number_of_symbol_keys < kMaxKeys)) {
// Create the fixed array with the key.
Handle<FixedArray> keys =
isolate->factory()->NewFixedArray(number_of_symbol_keys);
if (number_of_symbol_keys > 0) {
int index = 0;
for (int p = 0; p < properties_length; p += 2) {
Object* key = constant_properties->get(p);
if (key->IsSymbol()) {
keys->set(index++, key);
}
}
ASSERT(index == number_of_symbol_keys);
}
*is_result_from_cache = true;
return isolate->factory()->ObjectLiteralMapFromCache(context, keys);
}
}
*is_result_from_cache = false;
return isolate->factory()->CopyMap(
Handle<Map>(context->object_function()->initial_map()),
number_of_properties);
}
static Handle<Object> CreateLiteralBoilerplate(
Isolate* isolate,
Handle<FixedArray> literals,
Handle<FixedArray> constant_properties);
static Handle<Object> CreateObjectLiteralBoilerplate(
Isolate* isolate,
Handle<FixedArray> literals,
Handle<FixedArray> constant_properties,
bool should_have_fast_elements,
bool has_function_literal) {
// Get the global context from the literals array. This is the
// context in which the function was created and we use the object
// function from this context to create the object literal. We do
// not use the object function from the current global context
// because this might be the object function from another context
// which we should not have access to.
Handle<Context> context =
Handle<Context>(JSFunction::GlobalContextFromLiterals(*literals));
// In case we have function literals, we want the object to be in
// slow properties mode for now. We don't go in the map cache because
// maps with constant functions can't be shared if the functions are
// not the same (which is the common case).
bool is_result_from_cache = false;
Handle<Map> map = has_function_literal
? Handle<Map>(context->object_function()->initial_map())
: ComputeObjectLiteralMap(context,
constant_properties,
&is_result_from_cache);
Handle<JSObject> boilerplate = isolate->factory()->NewJSObjectFromMap(map);
// Normalize the elements of the boilerplate to save space if needed.
if (!should_have_fast_elements) NormalizeElements(boilerplate);
// Add the constant properties to the boilerplate.
int length = constant_properties->length();
bool should_transform =
!is_result_from_cache && boilerplate->HasFastProperties();
if (should_transform || has_function_literal) {
// Normalize the properties of object to avoid n^2 behavior
// when extending the object multiple properties. Indicate the number of
// properties to be added.
NormalizeProperties(boilerplate, KEEP_INOBJECT_PROPERTIES, length / 2);
}
for (int index = 0; index < length; index +=2) {
Handle<Object> key(constant_properties->get(index+0), isolate);
Handle<Object> value(constant_properties->get(index+1), isolate);
if (value->IsFixedArray()) {
// The value contains the constant_properties of a
// simple object or array literal.
Handle<FixedArray> array = Handle<FixedArray>::cast(value);
value = CreateLiteralBoilerplate(isolate, literals, array);
if (value.is_null()) return value;
}
Handle<Object> result;
uint32_t element_index = 0;
if (key->IsSymbol()) {
if (Handle<String>::cast(key)->AsArrayIndex(&element_index)) {
// Array index as string (uint32).
result = SetOwnElement(boilerplate,
element_index,
value,
kNonStrictMode);
} else {
Handle<String> name(String::cast(*key));
ASSERT(!name->AsArrayIndex(&element_index));
result = SetLocalPropertyIgnoreAttributes(boilerplate, name,
value, NONE);
}
} else if (key->ToArrayIndex(&element_index)) {
// Array index (uint32).
result = SetOwnElement(boilerplate,
element_index,
value,
kNonStrictMode);
} else {
// Non-uint32 number.
ASSERT(key->IsNumber());
double num = key->Number();
char arr[100];
Vector<char> buffer(arr, ARRAY_SIZE(arr));
const char* str = DoubleToCString(num, buffer);
Handle<String> name =
isolate->factory()->NewStringFromAscii(CStrVector(str));
result = SetLocalPropertyIgnoreAttributes(boilerplate, name,
value, NONE);
}
// If setting the property on the boilerplate throws an
// exception, the exception is converted to an empty handle in
// the handle based operations. In that case, we need to
// convert back to an exception.
if (result.is_null()) return result;
}
// Transform to fast properties if necessary. For object literals with
// containing function literals we defer this operation until after all
// computed properties have been assigned so that we can generate
// constant function properties.
if (should_transform && !has_function_literal) {
TransformToFastProperties(boilerplate,
boilerplate->map()->unused_property_fields());
}
return boilerplate;
}
static Handle<Object> CreateArrayLiteralBoilerplate(
Isolate* isolate,
Handle<FixedArray> literals,
Handle<FixedArray> elements) {
// Create the JSArray.
Handle<JSFunction> constructor(
JSFunction::GlobalContextFromLiterals(*literals)->array_function());
Handle<Object> object = isolate->factory()->NewJSObject(constructor);
const bool is_cow =
(elements->map() == isolate->heap()->fixed_cow_array_map());
Handle<FixedArray> copied_elements =
is_cow ? elements : isolate->factory()->CopyFixedArray(elements);
Handle<FixedArray> content = Handle<FixedArray>::cast(copied_elements);
if (is_cow) {
#ifdef DEBUG
// Copy-on-write arrays must be shallow (and simple).
for (int i = 0; i < content->length(); i++) {
ASSERT(!content->get(i)->IsFixedArray());
}
#endif
} else {
for (int i = 0; i < content->length(); i++) {
if (content->get(i)->IsFixedArray()) {
// The value contains the constant_properties of a
// simple object or array literal.
Handle<FixedArray> fa(FixedArray::cast(content->get(i)));
Handle<Object> result =
CreateLiteralBoilerplate(isolate, literals, fa);
if (result.is_null()) return result;
content->set(i, *result);
}
}
}
// Set the elements.
Handle<JSArray>::cast(object)->SetContent(*content);
return object;
}
static Handle<Object> CreateLiteralBoilerplate(
Isolate* isolate,
Handle<FixedArray> literals,
Handle<FixedArray> array) {
Handle<FixedArray> elements = CompileTimeValue::GetElements(array);
const bool kHasNoFunctionLiteral = false;
switch (CompileTimeValue::GetType(array)) {
case CompileTimeValue::OBJECT_LITERAL_FAST_ELEMENTS:
return CreateObjectLiteralBoilerplate(isolate,
literals,
elements,
true,
kHasNoFunctionLiteral);
case CompileTimeValue::OBJECT_LITERAL_SLOW_ELEMENTS:
return CreateObjectLiteralBoilerplate(isolate,
literals,
elements,
false,
kHasNoFunctionLiteral);
case CompileTimeValue::ARRAY_LITERAL:
return CreateArrayLiteralBoilerplate(isolate, literals, elements);
default:
UNREACHABLE();
return Handle<Object>::null();
}
}
static MaybeObject* Runtime_CreateArrayLiteralBoilerplate(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
// Takes a FixedArray of elements containing the literal elements of
// the array literal and produces JSArray with those elements.
// Additionally takes the literals array of the surrounding function
// which contains the context from which to get the Array function
// to use for creating the array literal.
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(FixedArray, literals, 0);
CONVERT_SMI_CHECKED(literals_index, args[1]);
CONVERT_ARG_CHECKED(FixedArray, elements, 2);
Handle<Object> object =
CreateArrayLiteralBoilerplate(isolate, literals, elements);
if (object.is_null()) return Failure::Exception();
// Update the functions literal and return the boilerplate.
literals->set(literals_index, *object);
return *object;
}
static MaybeObject* Runtime_CreateObjectLiteral(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 4);
CONVERT_ARG_CHECKED(FixedArray, literals, 0);
CONVERT_SMI_CHECKED(literals_index, args[1]);
CONVERT_ARG_CHECKED(FixedArray, constant_properties, 2);
CONVERT_SMI_CHECKED(flags, args[3]);
bool should_have_fast_elements = (flags & ObjectLiteral::kFastElements) != 0;
bool has_function_literal = (flags & ObjectLiteral::kHasFunction) != 0;
// Check if boilerplate exists. If not, create it first.
Handle<Object> boilerplate(literals->get(literals_index), isolate);
if (*boilerplate == isolate->heap()->undefined_value()) {
boilerplate = CreateObjectLiteralBoilerplate(isolate,
literals,
constant_properties,
should_have_fast_elements,
has_function_literal);
if (boilerplate.is_null()) return Failure::Exception();
// Update the functions literal and return the boilerplate.
literals->set(literals_index, *boilerplate);
}
return DeepCopyBoilerplate(isolate, JSObject::cast(*boilerplate));
}
static MaybeObject* Runtime_CreateObjectLiteralShallow(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 4);
CONVERT_ARG_CHECKED(FixedArray, literals, 0);
CONVERT_SMI_CHECKED(literals_index, args[1]);
CONVERT_ARG_CHECKED(FixedArray, constant_properties, 2);
CONVERT_SMI_CHECKED(flags, args[3]);
bool should_have_fast_elements = (flags & ObjectLiteral::kFastElements) != 0;
bool has_function_literal = (flags & ObjectLiteral::kHasFunction) != 0;
// Check if boilerplate exists. If not, create it first.
Handle<Object> boilerplate(literals->get(literals_index), isolate);
if (*boilerplate == isolate->heap()->undefined_value()) {
boilerplate = CreateObjectLiteralBoilerplate(isolate,
literals,
constant_properties,
should_have_fast_elements,
has_function_literal);
if (boilerplate.is_null()) return Failure::Exception();
// Update the functions literal and return the boilerplate.
literals->set(literals_index, *boilerplate);
}
return isolate->heap()->CopyJSObject(JSObject::cast(*boilerplate));
}
static MaybeObject* Runtime_CreateArrayLiteral(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(FixedArray, literals, 0);
CONVERT_SMI_CHECKED(literals_index, args[1]);
CONVERT_ARG_CHECKED(FixedArray, elements, 2);
// Check if boilerplate exists. If not, create it first.
Handle<Object> boilerplate(literals->get(literals_index), isolate);
if (*boilerplate == isolate->heap()->undefined_value()) {
boilerplate = CreateArrayLiteralBoilerplate(isolate, literals, elements);
if (boilerplate.is_null()) return Failure::Exception();
// Update the functions literal and return the boilerplate.
literals->set(literals_index, *boilerplate);
}
return DeepCopyBoilerplate(isolate, JSObject::cast(*boilerplate));
}
static MaybeObject* Runtime_CreateArrayLiteralShallow(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(FixedArray, literals, 0);
CONVERT_SMI_CHECKED(literals_index, args[1]);
CONVERT_ARG_CHECKED(FixedArray, elements, 2);
// Check if boilerplate exists. If not, create it first.
Handle<Object> boilerplate(literals->get(literals_index), isolate);
if (*boilerplate == isolate->heap()->undefined_value()) {
boilerplate = CreateArrayLiteralBoilerplate(isolate, literals, elements);
if (boilerplate.is_null()) return Failure::Exception();
// Update the functions literal and return the boilerplate.
literals->set(literals_index, *boilerplate);
}
if (JSObject::cast(*boilerplate)->elements()->map() ==
isolate->heap()->fixed_cow_array_map()) {
COUNTERS->cow_arrays_created_runtime()->Increment();
}
return isolate->heap()->CopyJSObject(JSObject::cast(*boilerplate));
}
static MaybeObject* Runtime_CreateCatchExtensionObject(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, key, args[0]);
Object* value = args[1];
// Create a catch context extension object.
JSFunction* constructor =
isolate->context()->global_context()->
context_extension_function();
Object* object;
{ MaybeObject* maybe_object = isolate->heap()->AllocateJSObject(constructor);
if (!maybe_object->ToObject(&object)) return maybe_object;
}
// Assign the exception value to the catch variable and make sure
// that the catch variable is DontDelete.
{ MaybeObject* maybe_value =
// Passing non-strict per ECMA-262 5th Ed. 12.14. Catch, bullet #4.
JSObject::cast(object)->SetProperty(
key, value, DONT_DELETE, kNonStrictMode);
if (!maybe_value->ToObject(&value)) return maybe_value;
}
return object;
}
static MaybeObject* Runtime_ClassOf(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
Object* obj = args[0];
if (!obj->IsJSObject()) return isolate->heap()->null_value();
return JSObject::cast(obj)->class_name();
}
static MaybeObject* Runtime_IsInPrototypeChain(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
// See ECMA-262, section 15.3.5.3, page 88 (steps 5 - 8).
Object* O = args[0];
Object* V = args[1];
while (true) {
Object* prototype = V->GetPrototype();
if (prototype->IsNull()) return isolate->heap()->false_value();
if (O == prototype) return isolate->heap()->true_value();
V = prototype;
}
}
// Inserts an object as the hidden prototype of another object.
static MaybeObject* Runtime_SetHiddenPrototype(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSObject, jsobject, args[0]);
CONVERT_CHECKED(JSObject, proto, args[1]);
// Sanity checks. The old prototype (that we are replacing) could
// theoretically be null, but if it is not null then check that we
// didn't already install a hidden prototype here.
RUNTIME_ASSERT(!jsobject->GetPrototype()->IsHeapObject() ||
!HeapObject::cast(jsobject->GetPrototype())->map()->is_hidden_prototype());
RUNTIME_ASSERT(!proto->map()->is_hidden_prototype());
// Allocate up front before we start altering state in case we get a GC.
Object* map_or_failure;
{ MaybeObject* maybe_map_or_failure = proto->map()->CopyDropTransitions();
if (!maybe_map_or_failure->ToObject(&map_or_failure)) {
return maybe_map_or_failure;
}
}
Map* new_proto_map = Map::cast(map_or_failure);
{ MaybeObject* maybe_map_or_failure = jsobject->map()->CopyDropTransitions();
if (!maybe_map_or_failure->ToObject(&map_or_failure)) {
return maybe_map_or_failure;
}
}
Map* new_map = Map::cast(map_or_failure);
// Set proto's prototype to be the old prototype of the object.
new_proto_map->set_prototype(jsobject->GetPrototype());
proto->set_map(new_proto_map);
new_proto_map->set_is_hidden_prototype();
// Set the object's prototype to proto.
new_map->set_prototype(proto);
jsobject->set_map(new_map);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_IsConstructCall(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 0);
JavaScriptFrameIterator it;
return isolate->heap()->ToBoolean(it.frame()->IsConstructor());
}
// Recursively traverses hidden prototypes if property is not found
static void GetOwnPropertyImplementation(JSObject* obj,
String* name,
LookupResult* result) {
obj->LocalLookupRealNamedProperty(name, result);
if (!result->IsProperty()) {
Object* proto = obj->GetPrototype();
if (proto->IsJSObject() &&
JSObject::cast(proto)->map()->is_hidden_prototype())
GetOwnPropertyImplementation(JSObject::cast(proto),
name, result);
}
}
static bool CheckAccessException(LookupResult* result,
v8::AccessType access_type) {
if (result->type() == CALLBACKS) {
Object* callback = result->GetCallbackObject();
if (callback->IsAccessorInfo()) {
AccessorInfo* info = AccessorInfo::cast(callback);
bool can_access =
(access_type == v8::ACCESS_HAS &&
(info->all_can_read() || info->all_can_write())) ||
(access_type == v8::ACCESS_GET && info->all_can_read()) ||
(access_type == v8::ACCESS_SET && info->all_can_write());
return can_access;
}
}
return false;
}
static bool CheckAccess(JSObject* obj,
String* name,
LookupResult* result,
v8::AccessType access_type) {
ASSERT(result->IsProperty());
JSObject* holder = result->holder();
JSObject* current = obj;
Isolate* isolate = obj->GetIsolate();
while (true) {
if (current->IsAccessCheckNeeded() &&
!isolate->MayNamedAccess(current, name, access_type)) {
// Access check callback denied the access, but some properties
// can have a special permissions which override callbacks descision
// (currently see v8::AccessControl).
break;
}
if (current == holder) {
return true;
}
current = JSObject::cast(current->GetPrototype());
}
// API callbacks can have per callback access exceptions.
switch (result->type()) {
case CALLBACKS: {
if (CheckAccessException(result, access_type)) {
return true;
}
break;
}
case INTERCEPTOR: {
// If the object has an interceptor, try real named properties.
// Overwrite the result to fetch the correct property later.
holder->LookupRealNamedProperty(name, result);
if (result->IsProperty()) {
if (CheckAccessException(result, access_type)) {
return true;
}
}
break;
}
default:
break;
}
isolate->ReportFailedAccessCheck(current, access_type);
return false;
}
// TODO(1095): we should traverse hidden prototype hierachy as well.
static bool CheckElementAccess(JSObject* obj,
uint32_t index,
v8::AccessType access_type) {
if (obj->IsAccessCheckNeeded() &&
!obj->GetIsolate()->MayIndexedAccess(obj, index, access_type)) {
return false;
}
return true;
}
// Enumerator used as indices into the array returned from GetOwnProperty
enum PropertyDescriptorIndices {
IS_ACCESSOR_INDEX,
VALUE_INDEX,
GETTER_INDEX,
SETTER_INDEX,
WRITABLE_INDEX,
ENUMERABLE_INDEX,
CONFIGURABLE_INDEX,
DESCRIPTOR_SIZE
};
// Returns an array with the property description:
// if args[1] is not a property on args[0]
// returns undefined
// if args[1] is a data property on args[0]
// [false, value, Writeable, Enumerable, Configurable]
// if args[1] is an accessor on args[0]
// [true, GetFunction, SetFunction, Enumerable, Configurable]
static MaybeObject* Runtime_GetOwnProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
Heap* heap = isolate->heap();
HandleScope scope(isolate);
Handle<FixedArray> elms = isolate->factory()->NewFixedArray(DESCRIPTOR_SIZE);
Handle<JSArray> desc = isolate->factory()->NewJSArrayWithElements(elms);
LookupResult result;
CONVERT_ARG_CHECKED(JSObject, obj, 0);
CONVERT_ARG_CHECKED(String, name, 1);
// This could be an element.
uint32_t index;
if (name->AsArrayIndex(&index)) {
switch (obj->HasLocalElement(index)) {
case JSObject::UNDEFINED_ELEMENT:
return heap->undefined_value();
case JSObject::STRING_CHARACTER_ELEMENT: {
// Special handling of string objects according to ECMAScript 5
// 15.5.5.2. Note that this might be a string object with elements
// other than the actual string value. This is covered by the
// subsequent cases.
Handle<JSValue> js_value = Handle<JSValue>::cast(obj);
Handle<String> str(String::cast(js_value->value()));
Handle<String> substr = SubString(str, index, index + 1, NOT_TENURED);
elms->set(IS_ACCESSOR_INDEX, heap->false_value());
elms->set(VALUE_INDEX, *substr);
elms->set(WRITABLE_INDEX, heap->false_value());
elms->set(ENUMERABLE_INDEX, heap->false_value());
elms->set(CONFIGURABLE_INDEX, heap->false_value());
return *desc;
}
case JSObject::INTERCEPTED_ELEMENT:
case JSObject::FAST_ELEMENT: {
elms->set(IS_ACCESSOR_INDEX, heap->false_value());
Handle<Object> value = GetElement(obj, index);
RETURN_IF_EMPTY_HANDLE(isolate, value);
elms->set(VALUE_INDEX, *value);
elms->set(WRITABLE_INDEX, heap->true_value());
elms->set(ENUMERABLE_INDEX, heap->true_value());
elms->set(CONFIGURABLE_INDEX, heap->true_value());
return *desc;
}
case JSObject::DICTIONARY_ELEMENT: {
Handle<JSObject> holder = obj;
if (obj->IsJSGlobalProxy()) {
Object* proto = obj->GetPrototype();
if (proto->IsNull()) return heap->undefined_value();
ASSERT(proto->IsJSGlobalObject());
holder = Handle<JSObject>(JSObject::cast(proto));
}
NumberDictionary* dictionary = holder->element_dictionary();
int entry = dictionary->FindEntry(index);
ASSERT(entry != NumberDictionary::kNotFound);
PropertyDetails details = dictionary->DetailsAt(entry);
switch (details.type()) {
case CALLBACKS: {
// This is an accessor property with getter and/or setter.
FixedArray* callbacks =
FixedArray::cast(dictionary->ValueAt(entry));
elms->set(IS_ACCESSOR_INDEX, heap->true_value());
if (CheckElementAccess(*obj, index, v8::ACCESS_GET)) {
elms->set(GETTER_INDEX, callbacks->get(0));
}
if (CheckElementAccess(*obj, index, v8::ACCESS_SET)) {
elms->set(SETTER_INDEX, callbacks->get(1));
}
break;
}
case NORMAL: {
// This is a data property.
elms->set(IS_ACCESSOR_INDEX, heap->false_value());
Handle<Object> value = GetElement(obj, index);
ASSERT(!value.is_null());
elms->set(VALUE_INDEX, *value);
elms->set(WRITABLE_INDEX, heap->ToBoolean(!details.IsReadOnly()));
break;
}
default:
UNREACHABLE();
break;
}
elms->set(ENUMERABLE_INDEX, heap->ToBoolean(!details.IsDontEnum()));
elms->set(CONFIGURABLE_INDEX, heap->ToBoolean(!details.IsDontDelete()));
return *desc;
}
}
}
// Use recursive implementation to also traverse hidden prototypes
GetOwnPropertyImplementation(*obj, *name, &result);
if (!result.IsProperty()) {
return heap->undefined_value();
}
if (!CheckAccess(*obj, *name, &result, v8::ACCESS_HAS)) {
return heap->false_value();
}
elms->set(ENUMERABLE_INDEX, heap->ToBoolean(!result.IsDontEnum()));
elms->set(CONFIGURABLE_INDEX, heap->ToBoolean(!result.IsDontDelete()));
bool is_js_accessor = (result.type() == CALLBACKS) &&
(result.GetCallbackObject()->IsFixedArray());
if (is_js_accessor) {
// __defineGetter__/__defineSetter__ callback.
elms->set(IS_ACCESSOR_INDEX, heap->true_value());
FixedArray* structure = FixedArray::cast(result.GetCallbackObject());
if (CheckAccess(*obj, *name, &result, v8::ACCESS_GET)) {
elms->set(GETTER_INDEX, structure->get(0));
}
if (CheckAccess(*obj, *name, &result, v8::ACCESS_SET)) {
elms->set(SETTER_INDEX, structure->get(1));
}
} else {
elms->set(IS_ACCESSOR_INDEX, heap->false_value());
elms->set(WRITABLE_INDEX, heap->ToBoolean(!result.IsReadOnly()));
PropertyAttributes attrs;
Object* value;
// GetProperty will check access and report any violations.
{ MaybeObject* maybe_value = obj->GetProperty(*obj, &result, *name, &attrs);
if (!maybe_value->ToObject(&value)) return maybe_value;
}
elms->set(VALUE_INDEX, value);
}
return *desc;
}
static MaybeObject* Runtime_PreventExtensions(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSObject, obj, args[0]);
return obj->PreventExtensions();
}
static MaybeObject* Runtime_IsExtensible(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSObject, obj, args[0]);
if (obj->IsJSGlobalProxy()) {
Object* proto = obj->GetPrototype();
if (proto->IsNull()) return isolate->heap()->false_value();
ASSERT(proto->IsJSGlobalObject());
obj = JSObject::cast(proto);
}
return obj->map()->is_extensible() ? isolate->heap()->true_value()
: isolate->heap()->false_value();
}
static MaybeObject* Runtime_RegExpCompile(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(JSRegExp, re, 0);
CONVERT_ARG_CHECKED(String, pattern, 1);
CONVERT_ARG_CHECKED(String, flags, 2);
Handle<Object> result = RegExpImpl::Compile(re, pattern, flags);
if (result.is_null()) return Failure::Exception();
return *result;
}
static MaybeObject* Runtime_CreateApiFunction(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(FunctionTemplateInfo, data, 0);
return *isolate->factory()->CreateApiFunction(data);
}
static MaybeObject* Runtime_IsTemplate(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
Object* arg = args[0];
bool result = arg->IsObjectTemplateInfo() || arg->IsFunctionTemplateInfo();
return isolate->heap()->ToBoolean(result);
}
static MaybeObject* Runtime_GetTemplateField(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(HeapObject, templ, args[0]);
CONVERT_CHECKED(Smi, field, args[1]);
int index = field->value();
int offset = index * kPointerSize + HeapObject::kHeaderSize;
InstanceType type = templ->map()->instance_type();
RUNTIME_ASSERT(type == FUNCTION_TEMPLATE_INFO_TYPE ||
type == OBJECT_TEMPLATE_INFO_TYPE);
RUNTIME_ASSERT(offset > 0);
if (type == FUNCTION_TEMPLATE_INFO_TYPE) {
RUNTIME_ASSERT(offset < FunctionTemplateInfo::kSize);
} else {
RUNTIME_ASSERT(offset < ObjectTemplateInfo::kSize);
}
return *HeapObject::RawField(templ, offset);
}
static MaybeObject* Runtime_DisableAccessChecks(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(HeapObject, object, args[0]);
Map* old_map = object->map();
bool needs_access_checks = old_map->is_access_check_needed();
if (needs_access_checks) {
// Copy map so it won't interfere constructor's initial map.
Object* new_map;
{ MaybeObject* maybe_new_map = old_map->CopyDropTransitions();
if (!maybe_new_map->ToObject(&new_map)) return maybe_new_map;
}
Map::cast(new_map)->set_is_access_check_needed(false);
object->set_map(Map::cast(new_map));
}
return needs_access_checks ? isolate->heap()->true_value()
: isolate->heap()->false_value();
}
static MaybeObject* Runtime_EnableAccessChecks(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(HeapObject, object, args[0]);
Map* old_map = object->map();
if (!old_map->is_access_check_needed()) {
// Copy map so it won't interfere constructor's initial map.
Object* new_map;
{ MaybeObject* maybe_new_map = old_map->CopyDropTransitions();
if (!maybe_new_map->ToObject(&new_map)) return maybe_new_map;
}
Map::cast(new_map)->set_is_access_check_needed(true);
object->set_map(Map::cast(new_map));
}
return isolate->heap()->undefined_value();
}
static Failure* ThrowRedeclarationError(Isolate* isolate,
const char* type,
Handle<String> name) {
HandleScope scope(isolate);
Handle<Object> type_handle =
isolate->factory()->NewStringFromAscii(CStrVector(type));
Handle<Object> args[2] = { type_handle, name };
Handle<Object> error =
isolate->factory()->NewTypeError("redeclaration", HandleVector(args, 2));
return isolate->Throw(*error);
}
static MaybeObject* Runtime_DeclareGlobals(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 4);
HandleScope scope(isolate);
Handle<GlobalObject> global = Handle<GlobalObject>(
isolate->context()->global());
Handle<Context> context = args.at<Context>(0);
CONVERT_ARG_CHECKED(FixedArray, pairs, 1);
bool is_eval = Smi::cast(args[2])->value() == 1;
StrictModeFlag strict_mode =
static_cast<StrictModeFlag>(Smi::cast(args[3])->value());
ASSERT(strict_mode == kStrictMode || strict_mode == kNonStrictMode);
// Compute the property attributes. According to ECMA-262, section
// 13, page 71, the property must be read-only and
// non-deletable. However, neither SpiderMonkey nor KJS creates the
// property as read-only, so we don't either.
PropertyAttributes base = is_eval ? NONE : DONT_DELETE;
// Traverse the name/value pairs and set the properties.
int length = pairs->length();
for (int i = 0; i < length; i += 2) {
HandleScope scope(isolate);
Handle<String> name(String::cast(pairs->get(i)));
Handle<Object> value(pairs->get(i + 1), isolate);
// We have to declare a global const property. To capture we only
// assign to it when evaluating the assignment for "const x =
// <expr>" the initial value is the hole.
bool is_const_property = value->IsTheHole();
if (value->IsUndefined() || is_const_property) {
// Lookup the property in the global object, and don't set the
// value of the variable if the property is already there.
LookupResult lookup;
global->Lookup(*name, &lookup);
if (lookup.IsProperty()) {
// Determine if the property is local by comparing the holder
// against the global object. The information will be used to
// avoid throwing re-declaration errors when declaring
// variables or constants that exist in the prototype chain.
bool is_local = (*global == lookup.holder());
// Get the property attributes and determine if the property is
// read-only.
PropertyAttributes attributes = global->GetPropertyAttribute(*name);
bool is_read_only = (attributes & READ_ONLY) != 0;
if (lookup.type() == INTERCEPTOR) {
// If the interceptor says the property is there, we
// just return undefined without overwriting the property.
// Otherwise, we continue to setting the property.
if (attributes != ABSENT) {
// Check if the existing property conflicts with regards to const.
if (is_local && (is_read_only || is_const_property)) {
const char* type = (is_read_only) ? "const" : "var";
return ThrowRedeclarationError(isolate, type, name);
};
// The property already exists without conflicting: Go to
// the next declaration.
continue;
}
// Fall-through and introduce the absent property by using
// SetProperty.
} else {
// For const properties, we treat a callback with this name
// even in the prototype as a conflicting declaration.
if (is_const_property && (lookup.type() == CALLBACKS)) {
return ThrowRedeclarationError(isolate, "const", name);
}
// Otherwise, we check for locally conflicting declarations.
if (is_local && (is_read_only || is_const_property)) {
const char* type = (is_read_only) ? "const" : "var";
return ThrowRedeclarationError(isolate, type, name);
}
// The property already exists without conflicting: Go to
// the next declaration.
continue;
}
}
} else {
// Copy the function and update its context. Use it as value.
Handle<SharedFunctionInfo> shared =
Handle<SharedFunctionInfo>::cast(value);
Handle<JSFunction> function =
isolate->factory()->NewFunctionFromSharedFunctionInfo(shared,
context,
TENURED);
value = function;
}
LookupResult lookup;
global->LocalLookup(*name, &lookup);
PropertyAttributes attributes = is_const_property
? static_cast<PropertyAttributes>(base | READ_ONLY)
: base;
// There's a local property that we need to overwrite because
// we're either declaring a function or there's an interceptor
// that claims the property is absent.
//
// Check for conflicting re-declarations. We cannot have
// conflicting types in case of intercepted properties because
// they are absent.
if (lookup.IsProperty() &&
(lookup.type() != INTERCEPTOR) &&
(lookup.IsReadOnly() || is_const_property)) {
const char* type = (lookup.IsReadOnly()) ? "const" : "var";
return ThrowRedeclarationError(isolate, type, name);
}
// Safari does not allow the invocation of callback setters for
// function declarations. To mimic this behavior, we do not allow
// the invocation of setters for function values. This makes a
// difference for global functions with the same names as event
// handlers such as "function onload() {}". Firefox does call the
// onload setter in those case and Safari does not. We follow
// Safari for compatibility.
if (value->IsJSFunction()) {
// Do not change DONT_DELETE to false from true.
if (lookup.IsProperty() && (lookup.type() != INTERCEPTOR)) {
attributes = static_cast<PropertyAttributes>(
attributes | (lookup.GetAttributes() & DONT_DELETE));
}
RETURN_IF_EMPTY_HANDLE(isolate,
SetLocalPropertyIgnoreAttributes(global,
name,
value,
attributes));
} else {
RETURN_IF_EMPTY_HANDLE(isolate,
SetProperty(global,
name,
value,
attributes,
strict_mode));
}
}
ASSERT(!isolate->has_pending_exception());
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_DeclareContextSlot(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 4);
CONVERT_ARG_CHECKED(Context, context, 0);
Handle<String> name(String::cast(args[1]));
PropertyAttributes mode =
static_cast<PropertyAttributes>(Smi::cast(args[2])->value());
RUNTIME_ASSERT(mode == READ_ONLY || mode == NONE);
Handle<Object> initial_value(args[3], isolate);
// Declarations are always done in the function context.
context = Handle<Context>(context->fcontext());
int index;
PropertyAttributes attributes;
ContextLookupFlags flags = DONT_FOLLOW_CHAINS;
Handle<Object> holder =
context->Lookup(name, flags, &index, &attributes);
if (attributes != ABSENT) {
// The name was declared before; check for conflicting
// re-declarations: This is similar to the code in parser.cc in
// the AstBuildingParser::Declare function.
if (((attributes & READ_ONLY) != 0) || (mode == READ_ONLY)) {
// Functions are not read-only.
ASSERT(mode != READ_ONLY || initial_value->IsTheHole());
const char* type = ((attributes & READ_ONLY) != 0) ? "const" : "var";
return ThrowRedeclarationError(isolate, type, name);
}
// Initialize it if necessary.
if (*initial_value != NULL) {
if (index >= 0) {
// The variable or constant context slot should always be in
// the function context or the arguments object.
if (holder->IsContext()) {
ASSERT(holder.is_identical_to(context));
if (((attributes & READ_ONLY) == 0) ||
context->get(index)->IsTheHole()) {
context->set(index, *initial_value);
}
} else {
// The holder is an arguments object.
Handle<JSObject> arguments(Handle<JSObject>::cast(holder));
Handle<Object> result = SetElement(arguments, index, initial_value,
kNonStrictMode);
if (result.is_null()) return Failure::Exception();
}
} else {
// Slow case: The property is not in the FixedArray part of the context.
Handle<JSObject> context_ext = Handle<JSObject>::cast(holder);
RETURN_IF_EMPTY_HANDLE(
isolate,
SetProperty(context_ext, name, initial_value,
mode, kNonStrictMode));
}
}
} else {
// The property is not in the function context. It needs to be
// "declared" in the function context's extension context, or in the
// global context.
Handle<JSObject> context_ext;
if (context->has_extension()) {
// The function context's extension context exists - use it.
context_ext = Handle<JSObject>(context->extension());
} else {
// The function context's extension context does not exists - allocate
// it.
context_ext = isolate->factory()->NewJSObject(
isolate->context_extension_function());
// And store it in the extension slot.
context->set_extension(*context_ext);
}
ASSERT(*context_ext != NULL);
// Declare the property by setting it to the initial value if provided,
// or undefined, and use the correct mode (e.g. READ_ONLY attribute for
// constant declarations).
ASSERT(!context_ext->HasLocalProperty(*name));
Handle<Object> value(isolate->heap()->undefined_value(), isolate);
if (*initial_value != NULL) value = initial_value;
// Declaring a const context slot is a conflicting declaration if
// there is a callback with that name in a prototype. It is
// allowed to introduce const variables in
// JSContextExtensionObjects. They are treated specially in
// SetProperty and no setters are invoked for those since they are
// not real JSObjects.
if (initial_value->IsTheHole() &&
!context_ext->IsJSContextExtensionObject()) {
LookupResult lookup;
context_ext->Lookup(*name, &lookup);
if (lookup.IsProperty() && (lookup.type() == CALLBACKS)) {
return ThrowRedeclarationError(isolate, "const", name);
}
}
RETURN_IF_EMPTY_HANDLE(isolate,
SetProperty(context_ext, name, value, mode,
kNonStrictMode));
}
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_InitializeVarGlobal(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation nha;
// args[0] == name
// args[1] == strict_mode
// args[2] == value (optional)
// Determine if we need to assign to the variable if it already
// exists (based on the number of arguments).
RUNTIME_ASSERT(args.length() == 2 || args.length() == 3);
bool assign = args.length() == 3;
CONVERT_ARG_CHECKED(String, name, 0);
GlobalObject* global = isolate->context()->global();
RUNTIME_ASSERT(args[1]->IsSmi());
StrictModeFlag strict_mode =
static_cast<StrictModeFlag>(Smi::cast(args[1])->value());
ASSERT(strict_mode == kStrictMode || strict_mode == kNonStrictMode);
// According to ECMA-262, section 12.2, page 62, the property must
// not be deletable.
PropertyAttributes attributes = DONT_DELETE;
// Lookup the property locally in the global object. If it isn't
// there, there is a property with this name in the prototype chain.
// We follow Safari and Firefox behavior and only set the property
// locally if there is an explicit initialization value that we have
// to assign to the property.
// Note that objects can have hidden prototypes, so we need to traverse
// the whole chain of hidden prototypes to do a 'local' lookup.
JSObject* real_holder = global;
LookupResult lookup;
while (true) {
real_holder->LocalLookup(*name, &lookup);
if (lookup.IsProperty()) {
// Determine if this is a redeclaration of something read-only.
if (lookup.IsReadOnly()) {
// If we found readonly property on one of hidden prototypes,
// just shadow it.
if (real_holder != isolate->context()->global()) break;
return ThrowRedeclarationError(isolate, "const", name);
}
// Determine if this is a redeclaration of an intercepted read-only
// property and figure out if the property exists at all.
bool found = true;
PropertyType type = lookup.type();
if (type == INTERCEPTOR) {
HandleScope handle_scope(isolate);
Handle<JSObject> holder(real_holder);
PropertyAttributes intercepted = holder->GetPropertyAttribute(*name);
real_holder = *holder;
if (intercepted == ABSENT) {
// The interceptor claims the property isn't there. We need to
// make sure to introduce it.
found = false;
} else if ((intercepted & READ_ONLY) != 0) {
// The property is present, but read-only. Since we're trying to
// overwrite it with a variable declaration we must throw a
// re-declaration error. However if we found readonly property
// on one of hidden prototypes, just shadow it.
if (real_holder != isolate->context()->global()) break;
return ThrowRedeclarationError(isolate, "const", name);
}
}
if (found && !assign) {
// The global property is there and we're not assigning any value
// to it. Just return.
return isolate->heap()->undefined_value();
}
// Assign the value (or undefined) to the property.
Object* value = (assign) ? args[2] : isolate->heap()->undefined_value();
return real_holder->SetProperty(
&lookup, *name, value, attributes, strict_mode);
}
Object* proto = real_holder->GetPrototype();
if (!proto->IsJSObject())
break;
if (!JSObject::cast(proto)->map()->is_hidden_prototype())
break;
real_holder = JSObject::cast(proto);
}
global = isolate->context()->global();
if (assign) {
return global->SetProperty(*name, args[2], attributes, strict_mode);
}
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_InitializeConstGlobal(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
// All constants are declared with an initial value. The name
// of the constant is the first argument and the initial value
// is the second.
RUNTIME_ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(String, name, 0);
Handle<Object> value = args.at<Object>(1);
// Get the current global object from top.
GlobalObject* global = isolate->context()->global();
// According to ECMA-262, section 12.2, page 62, the property must
// not be deletable. Since it's a const, it must be READ_ONLY too.
PropertyAttributes attributes =
static_cast<PropertyAttributes>(DONT_DELETE | READ_ONLY);
// Lookup the property locally in the global object. If it isn't
// there, we add the property and take special precautions to always
// add it as a local property even in case of callbacks in the
// prototype chain (this rules out using SetProperty).
// We use SetLocalPropertyIgnoreAttributes instead
LookupResult lookup;
global->LocalLookup(*name, &lookup);
if (!lookup.IsProperty()) {
return global->SetLocalPropertyIgnoreAttributes(*name,
*value,
attributes);
}
// Determine if this is a redeclaration of something not
// read-only. In case the result is hidden behind an interceptor we
// need to ask it for the property attributes.
if (!lookup.IsReadOnly()) {
if (lookup.type() != INTERCEPTOR) {
return ThrowRedeclarationError(isolate, "var", name);
}
PropertyAttributes intercepted = global->GetPropertyAttribute(*name);
// Throw re-declaration error if the intercepted property is present
// but not read-only.
if (intercepted != ABSENT && (intercepted & READ_ONLY) == 0) {
return ThrowRedeclarationError(isolate, "var", name);
}
// Restore global object from context (in case of GC) and continue
// with setting the value because the property is either absent or
// read-only. We also have to do redo the lookup.
HandleScope handle_scope(isolate);
Handle<GlobalObject> global(isolate->context()->global());
// BUG 1213575: Handle the case where we have to set a read-only
// property through an interceptor and only do it if it's
// uninitialized, e.g. the hole. Nirk...
// Passing non-strict mode because the property is writable.
RETURN_IF_EMPTY_HANDLE(isolate,
SetProperty(global,
name,
value,
attributes,
kNonStrictMode));
return *value;
}
// Set the value, but only we're assigning the initial value to a
// constant. For now, we determine this by checking if the
// current value is the hole.
// Strict mode handling not needed (const disallowed in strict mode).
PropertyType type = lookup.type();
if (type == FIELD) {
FixedArray* properties = global->properties();
int index = lookup.GetFieldIndex();
if (properties->get(index)->IsTheHole()) {
properties->set(index, *value);
}
} else if (type == NORMAL) {
if (global->GetNormalizedProperty(&lookup)->IsTheHole()) {
global->SetNormalizedProperty(&lookup, *value);
}
} else {
// Ignore re-initialization of constants that have already been
// assigned a function value.
ASSERT(lookup.IsReadOnly() && type == CONSTANT_FUNCTION);
}
// Use the set value as the result of the operation.
return *value;
}
static MaybeObject* Runtime_InitializeConstContextSlot(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
Handle<Object> value(args[0], isolate);
ASSERT(!value->IsTheHole());
CONVERT_ARG_CHECKED(Context, context, 1);
Handle<String> name(String::cast(args[2]));
// Initializations are always done in the function context.
context = Handle<Context>(context->fcontext());
int index;
PropertyAttributes attributes;
ContextLookupFlags flags = FOLLOW_CHAINS;
Handle<Object> holder =
context->Lookup(name, flags, &index, &attributes);
// In most situations, the property introduced by the const
// declaration should be present in the context extension object.
// However, because declaration and initialization are separate, the
// property might have been deleted (if it was introduced by eval)
// before we reach the initialization point.
//
// Example:
//
// function f() { eval("delete x; const x;"); }
//
// In that case, the initialization behaves like a normal assignment
// to property 'x'.
if (index >= 0) {
// Property was found in a context.
if (holder->IsContext()) {
// The holder cannot be the function context. If it is, there
// should have been a const redeclaration error when declaring
// the const property.
ASSERT(!holder.is_identical_to(context));
if ((attributes & READ_ONLY) == 0) {
Handle<Context>::cast(holder)->set(index, *value);
}
} else {
// The holder is an arguments object.
ASSERT((attributes & READ_ONLY) == 0);
Handle<JSObject> arguments(Handle<JSObject>::cast(holder));
RETURN_IF_EMPTY_HANDLE(
isolate,
SetElement(arguments, index, value, kNonStrictMode));
}
return *value;
}
// The property could not be found, we introduce it in the global
// context.
if (attributes == ABSENT) {
Handle<JSObject> global = Handle<JSObject>(
isolate->context()->global());
// Strict mode not needed (const disallowed in strict mode).
RETURN_IF_EMPTY_HANDLE(
isolate,
SetProperty(global, name, value, NONE, kNonStrictMode));
return *value;
}
// The property was present in a context extension object.
Handle<JSObject> context_ext = Handle<JSObject>::cast(holder);
if (*context_ext == context->extension()) {
// This is the property that was introduced by the const
// declaration. Set it if it hasn't been set before. NOTE: We
// cannot use GetProperty() to get the current value as it
// 'unholes' the value.
LookupResult lookup;
context_ext->LocalLookupRealNamedProperty(*name, &lookup);
ASSERT(lookup.IsProperty()); // the property was declared
ASSERT(lookup.IsReadOnly()); // and it was declared as read-only
PropertyType type = lookup.type();
if (type == FIELD) {
FixedArray* properties = context_ext->properties();
int index = lookup.GetFieldIndex();
if (properties->get(index)->IsTheHole()) {
properties->set(index, *value);
}
} else if (type == NORMAL) {
if (context_ext->GetNormalizedProperty(&lookup)->IsTheHole()) {
context_ext->SetNormalizedProperty(&lookup, *value);
}
} else {
// We should not reach here. Any real, named property should be
// either a field or a dictionary slot.
UNREACHABLE();
}
} else {
// The property was found in a different context extension object.
// Set it if it is not a read-only property.
if ((attributes & READ_ONLY) == 0) {
// Strict mode not needed (const disallowed in strict mode).
RETURN_IF_EMPTY_HANDLE(
isolate,
SetProperty(context_ext, name, value, attributes, kNonStrictMode));
}
}
return *value;
}
static MaybeObject* Runtime_OptimizeObjectForAddingMultipleProperties(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSObject, object, 0);
CONVERT_SMI_CHECKED(properties, args[1]);
if (object->HasFastProperties()) {
NormalizeProperties(object, KEEP_INOBJECT_PROPERTIES, properties);
}
return *object;
}
static MaybeObject* Runtime_RegExpExec(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 4);
CONVERT_ARG_CHECKED(JSRegExp, regexp, 0);
CONVERT_ARG_CHECKED(String, subject, 1);
// Due to the way the JS calls are constructed this must be less than the
// length of a string, i.e. it is always a Smi. We check anyway for security.
CONVERT_SMI_CHECKED(index, args[2]);
CONVERT_ARG_CHECKED(JSArray, last_match_info, 3);
RUNTIME_ASSERT(last_match_info->HasFastElements());
RUNTIME_ASSERT(index >= 0);
RUNTIME_ASSERT(index <= subject->length());
isolate->counters()->regexp_entry_runtime()->Increment();
Handle<Object> result = RegExpImpl::Exec(regexp,
subject,
index,
last_match_info);
if (result.is_null()) return Failure::Exception();
return *result;
}
static MaybeObject* Runtime_RegExpConstructResult(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 3);
CONVERT_SMI_CHECKED(elements_count, args[0]);
if (elements_count > JSArray::kMaxFastElementsLength) {
return isolate->ThrowIllegalOperation();
}
Object* new_object;
{ MaybeObject* maybe_new_object =
isolate->heap()->AllocateFixedArrayWithHoles(elements_count);
if (!maybe_new_object->ToObject(&new_object)) return maybe_new_object;
}
FixedArray* elements = FixedArray::cast(new_object);
{ MaybeObject* maybe_new_object = isolate->heap()->AllocateRaw(
JSRegExpResult::kSize, NEW_SPACE, OLD_POINTER_SPACE);
if (!maybe_new_object->ToObject(&new_object)) return maybe_new_object;
}
{
AssertNoAllocation no_gc;
HandleScope scope(isolate);
reinterpret_cast<HeapObject*>(new_object)->
set_map(isolate->global_context()->regexp_result_map());
}
JSArray* array = JSArray::cast(new_object);
array->set_properties(isolate->heap()->empty_fixed_array());
array->set_elements(elements);
array->set_length(Smi::FromInt(elements_count));
// Write in-object properties after the length of the array.
array->InObjectPropertyAtPut(JSRegExpResult::kIndexIndex, args[1]);
array->InObjectPropertyAtPut(JSRegExpResult::kInputIndex, args[2]);
return array;
}
static MaybeObject* Runtime_RegExpInitializeObject(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
AssertNoAllocation no_alloc;
ASSERT(args.length() == 5);
CONVERT_CHECKED(JSRegExp, regexp, args[0]);
CONVERT_CHECKED(String, source, args[1]);
Object* global = args[2];
if (!global->IsTrue()) global = isolate->heap()->false_value();
Object* ignoreCase = args[3];
if (!ignoreCase->IsTrue()) ignoreCase = isolate->heap()->false_value();
Object* multiline = args[4];
if (!multiline->IsTrue()) multiline = isolate->heap()->false_value();
Map* map = regexp->map();
Object* constructor = map->constructor();
if (constructor->IsJSFunction() &&
JSFunction::cast(constructor)->initial_map() == map) {
// If we still have the original map, set in-object properties directly.
regexp->InObjectPropertyAtPut(JSRegExp::kSourceFieldIndex, source);
// TODO(lrn): Consider skipping write barrier on booleans as well.
// Both true and false should be in oldspace at all times.
regexp->InObjectPropertyAtPut(JSRegExp::kGlobalFieldIndex, global);
regexp->InObjectPropertyAtPut(JSRegExp::kIgnoreCaseFieldIndex, ignoreCase);
regexp->InObjectPropertyAtPut(JSRegExp::kMultilineFieldIndex, multiline);
regexp->InObjectPropertyAtPut(JSRegExp::kLastIndexFieldIndex,
Smi::FromInt(0),
SKIP_WRITE_BARRIER);
return regexp;
}
// Map has changed, so use generic, but slower, method.
PropertyAttributes final =
static_cast<PropertyAttributes>(READ_ONLY | DONT_ENUM | DONT_DELETE);
PropertyAttributes writable =
static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE);
Heap* heap = isolate->heap();
MaybeObject* result;
result = regexp->SetLocalPropertyIgnoreAttributes(heap->source_symbol(),
source,
final);
ASSERT(!result->IsFailure());
result = regexp->SetLocalPropertyIgnoreAttributes(heap->global_symbol(),
global,
final);
ASSERT(!result->IsFailure());
result =
regexp->SetLocalPropertyIgnoreAttributes(heap->ignore_case_symbol(),
ignoreCase,
final);
ASSERT(!result->IsFailure());
result = regexp->SetLocalPropertyIgnoreAttributes(heap->multiline_symbol(),
multiline,
final);
ASSERT(!result->IsFailure());
result =
regexp->SetLocalPropertyIgnoreAttributes(heap->last_index_symbol(),
Smi::FromInt(0),
writable);
ASSERT(!result->IsFailure());
USE(result);
return regexp;
}
static MaybeObject* Runtime_FinishArrayPrototypeSetup(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSArray, prototype, 0);
// This is necessary to enable fast checks for absence of elements
// on Array.prototype and below.
prototype->set_elements(isolate->heap()->empty_fixed_array());
return Smi::FromInt(0);
}
static Handle<JSFunction> InstallBuiltin(Isolate* isolate,
Handle<JSObject> holder,
const char* name,
Builtins::Name builtin_name) {
Handle<String> key = isolate->factory()->LookupAsciiSymbol(name);
Handle<Code> code(isolate->builtins()->builtin(builtin_name));
Handle<JSFunction> optimized =
isolate->factory()->NewFunction(key,
JS_OBJECT_TYPE,
JSObject::kHeaderSize,
code,
false);
optimized->shared()->DontAdaptArguments();
SetProperty(holder, key, optimized, NONE, kStrictMode);
return optimized;
}
static MaybeObject* Runtime_SpecialArrayFunctions(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSObject, holder, 0);
InstallBuiltin(isolate, holder, "pop", Builtins::ArrayPop);
InstallBuiltin(isolate, holder, "push", Builtins::ArrayPush);
InstallBuiltin(isolate, holder, "shift", Builtins::ArrayShift);
InstallBuiltin(isolate, holder, "unshift", Builtins::ArrayUnshift);
InstallBuiltin(isolate, holder, "slice", Builtins::ArraySlice);
InstallBuiltin(isolate, holder, "splice", Builtins::ArraySplice);
InstallBuiltin(isolate, holder, "concat", Builtins::ArrayConcat);
return *holder;
}
static MaybeObject* Runtime_GetGlobalReceiver(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
// Returns a real global receiver, not one of builtins object.
Context* global_context =
isolate->context()->global()->global_context();
return global_context->global()->global_receiver();
}
static MaybeObject* Runtime_MaterializeRegExpLiteral(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 4);
CONVERT_ARG_CHECKED(FixedArray, literals, 0);
int index = Smi::cast(args[1])->value();
Handle<String> pattern = args.at<String>(2);
Handle<String> flags = args.at<String>(3);
// Get the RegExp function from the context in the literals array.
// This is the RegExp function from the context in which the
// function was created. We do not use the RegExp function from the
// current global context because this might be the RegExp function
// from another context which we should not have access to.
Handle<JSFunction> constructor =
Handle<JSFunction>(
JSFunction::GlobalContextFromLiterals(*literals)->regexp_function());
// Compute the regular expression literal.
bool has_pending_exception;
Handle<Object> regexp =
RegExpImpl::CreateRegExpLiteral(constructor, pattern, flags,
&has_pending_exception);
if (has_pending_exception) {
ASSERT(isolate->has_pending_exception());
return Failure::Exception();
}
literals->set(index, *regexp);
return *regexp;
}
static MaybeObject* Runtime_FunctionGetName(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, f, args[0]);
return f->shared()->name();
}
static MaybeObject* Runtime_FunctionSetName(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSFunction, f, args[0]);
CONVERT_CHECKED(String, name, args[1]);
f->shared()->set_name(name);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_FunctionRemovePrototype(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, f, args[0]);
Object* obj = f->RemovePrototype();
if (obj->IsFailure()) return obj;
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_FunctionGetScript(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, fun, args[0]);
Handle<Object> script = Handle<Object>(fun->shared()->script(), isolate);
if (!script->IsScript()) return isolate->heap()->undefined_value();
return *GetScriptWrapper(Handle<Script>::cast(script));
}
static MaybeObject* Runtime_FunctionGetSourceCode(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, f, args[0]);
return f->shared()->GetSourceCode();
}
static MaybeObject* Runtime_FunctionGetScriptSourcePosition(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, fun, args[0]);
int pos = fun->shared()->start_position();
return Smi::FromInt(pos);
}
static MaybeObject* Runtime_FunctionGetPositionForOffset(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(Code, code, args[0]);
CONVERT_NUMBER_CHECKED(int, offset, Int32, args[1]);
RUNTIME_ASSERT(0 <= offset && offset < code->Size());
Address pc = code->address() + offset;
return Smi::FromInt(code->SourcePosition(pc));
}
static MaybeObject* Runtime_FunctionSetInstanceClassName(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSFunction, fun, args[0]);
CONVERT_CHECKED(String, name, args[1]);
fun->SetInstanceClassName(name);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_FunctionSetLength(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSFunction, fun, args[0]);
CONVERT_CHECKED(Smi, length, args[1]);
fun->shared()->set_length(length->value());
return length;
}
static MaybeObject* Runtime_FunctionSetPrototype(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSFunction, fun, args[0]);
ASSERT(fun->should_have_prototype());
Object* obj;
{ MaybeObject* maybe_obj =
Accessors::FunctionSetPrototype(fun, args[1], NULL);
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
return args[0]; // return TOS
}
static MaybeObject* Runtime_FunctionIsAPIFunction(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, f, args[0]);
return f->shared()->IsApiFunction() ? isolate->heap()->true_value()
: isolate->heap()->false_value();
}
static MaybeObject* Runtime_FunctionIsBuiltin(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, f, args[0]);
return f->IsBuiltin() ? isolate->heap()->true_value() :
isolate->heap()->false_value();
}
static MaybeObject* Runtime_SetCode(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSFunction, target, 0);
Handle<Object> code = args.at<Object>(1);
Handle<Context> context(target->context());
if (!code->IsNull()) {
RUNTIME_ASSERT(code->IsJSFunction());
Handle<JSFunction> fun = Handle<JSFunction>::cast(code);
Handle<SharedFunctionInfo> shared(fun->shared());
if (!EnsureCompiled(shared, KEEP_EXCEPTION)) {
return Failure::Exception();
}
// Since we don't store the source for this we should never
// optimize this.
shared->code()->set_optimizable(false);
// Set the code, scope info, formal parameter count,
// and the length of the target function.
target->shared()->set_code(shared->code());
target->ReplaceCode(shared->code());
target->shared()->set_scope_info(shared->scope_info());
target->shared()->set_length(shared->length());
target->shared()->set_formal_parameter_count(
shared->formal_parameter_count());
// Set the source code of the target function to undefined.
// SetCode is only used for built-in constructors like String,
// Array, and Object, and some web code
// doesn't like seeing source code for constructors.
target->shared()->set_script(isolate->heap()->undefined_value());
target->shared()->code()->set_optimizable(false);
// Clear the optimization hints related to the compiled code as these are no
// longer valid when the code is overwritten.
target->shared()->ClearThisPropertyAssignmentsInfo();
context = Handle<Context>(fun->context());
// Make sure we get a fresh copy of the literal vector to avoid
// cross context contamination.
int number_of_literals = fun->NumberOfLiterals();
Handle<FixedArray> literals =
isolate->factory()->NewFixedArray(number_of_literals, TENURED);
if (number_of_literals > 0) {
// Insert the object, regexp and array functions in the literals
// array prefix. These are the functions that will be used when
// creating object, regexp and array literals.
literals->set(JSFunction::kLiteralGlobalContextIndex,
context->global_context());
}
// It's okay to skip the write barrier here because the literals
// are guaranteed to be in old space.
target->set_literals(*literals, SKIP_WRITE_BARRIER);
target->set_next_function_link(isolate->heap()->undefined_value());
}
target->set_context(*context);
return *target;
}
static MaybeObject* Runtime_SetExpectedNumberOfProperties(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSFunction, function, 0);
CONVERT_SMI_CHECKED(num, args[1]);
RUNTIME_ASSERT(num >= 0);
SetExpectedNofProperties(function, num);
return isolate->heap()->undefined_value();
}
MUST_USE_RESULT static MaybeObject* CharFromCode(Isolate* isolate,
Object* char_code) {
uint32_t code;
if (char_code->ToArrayIndex(&code)) {
if (code <= 0xffff) {
return isolate->heap()->LookupSingleCharacterStringFromCode(code);
}
}
return isolate->heap()->empty_string();
}
static MaybeObject* Runtime_StringCharCodeAt(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, subject, args[0]);
Object* index = args[1];
RUNTIME_ASSERT(index->IsNumber());
uint32_t i = 0;
if (index->IsSmi()) {
int value = Smi::cast(index)->value();
if (value < 0) return isolate->heap()->nan_value();
i = value;
} else {
ASSERT(index->IsHeapNumber());
double value = HeapNumber::cast(index)->value();
i = static_cast<uint32_t>(DoubleToInteger(value));
}
// Flatten the string. If someone wants to get a char at an index
// in a cons string, it is likely that more indices will be
// accessed.
Object* flat;
{ MaybeObject* maybe_flat = subject->TryFlatten();
if (!maybe_flat->ToObject(&flat)) return maybe_flat;
}
subject = String::cast(flat);
if (i >= static_cast<uint32_t>(subject->length())) {
return isolate->heap()->nan_value();
}
return Smi::FromInt(subject->Get(i));
}
static MaybeObject* Runtime_CharFromCode(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
return CharFromCode(isolate, args[0]);
}
class FixedArrayBuilder {
public:
explicit FixedArrayBuilder(Isolate* isolate, int initial_capacity)
: array_(isolate->factory()->NewFixedArrayWithHoles(initial_capacity)),
length_(0) {
// Require a non-zero initial size. Ensures that doubling the size to
// extend the array will work.
ASSERT(initial_capacity > 0);
}
explicit FixedArrayBuilder(Handle<FixedArray> backing_store)
: array_(backing_store),
length_(0) {
// Require a non-zero initial size. Ensures that doubling the size to
// extend the array will work.
ASSERT(backing_store->length() > 0);
}
bool HasCapacity(int elements) {
int length = array_->length();
int required_length = length_ + elements;
return (length >= required_length);
}
void EnsureCapacity(int elements) {
int length = array_->length();
int required_length = length_ + elements;
if (length < required_length) {
int new_length = length;
do {
new_length *= 2;
} while (new_length < required_length);
Handle<FixedArray> extended_array =
array_->GetIsolate()->factory()->NewFixedArrayWithHoles(new_length);
array_->CopyTo(0, *extended_array, 0, length_);
array_ = extended_array;
}
}
void Add(Object* value) {
ASSERT(length_ < capacity());
array_->set(length_, value);
length_++;
}
void Add(Smi* value) {
ASSERT(length_ < capacity());
array_->set(length_, value);
length_++;
}
Handle<FixedArray> array() {
return array_;
}
int length() {
return length_;
}
int capacity() {
return array_->length();
}
Handle<JSArray> ToJSArray() {
Handle<JSArray> result_array = FACTORY->NewJSArrayWithElements(array_);
result_array->set_length(Smi::FromInt(length_));
return result_array;
}
Handle<JSArray> ToJSArray(Handle<JSArray> target_array) {
target_array->set_elements(*array_);
target_array->set_length(Smi::FromInt(length_));
return target_array;
}
private:
Handle<FixedArray> array_;
int length_;
};
// Forward declarations.
const int kStringBuilderConcatHelperLengthBits = 11;
const int kStringBuilderConcatHelperPositionBits = 19;
template <typename schar>
static inline void StringBuilderConcatHelper(String*,
schar*,
FixedArray*,
int);
typedef BitField<int, 0, kStringBuilderConcatHelperLengthBits>
StringBuilderSubstringLength;
typedef BitField<int,
kStringBuilderConcatHelperLengthBits,
kStringBuilderConcatHelperPositionBits>
StringBuilderSubstringPosition;
class ReplacementStringBuilder {
public:
ReplacementStringBuilder(Heap* heap,
Handle<String> subject,
int estimated_part_count)
: heap_(heap),
array_builder_(heap->isolate(), estimated_part_count),
subject_(subject),
character_count_(0),
is_ascii_(subject->IsAsciiRepresentation()) {
// Require a non-zero initial size. Ensures that doubling the size to
// extend the array will work.
ASSERT(estimated_part_count > 0);
}
static inline void AddSubjectSlice(FixedArrayBuilder* builder,
int from,
int to) {
ASSERT(from >= 0);
int length = to - from;
ASSERT(length > 0);
if (StringBuilderSubstringLength::is_valid(length) &&
StringBuilderSubstringPosition::is_valid(from)) {
int encoded_slice = StringBuilderSubstringLength::encode(length) |
StringBuilderSubstringPosition::encode(from);
builder->Add(Smi::FromInt(encoded_slice));
} else {
// Otherwise encode as two smis.
builder->Add(Smi::FromInt(-length));
builder->Add(Smi::FromInt(from));
}
}
void EnsureCapacity(int elements) {
array_builder_.EnsureCapacity(elements);
}
void AddSubjectSlice(int from, int to) {
AddSubjectSlice(&array_builder_, from, to);
IncrementCharacterCount(to - from);
}
void AddString(Handle<String> string) {
int length = string->length();
ASSERT(length > 0);
AddElement(*string);
if (!string->IsAsciiRepresentation()) {
is_ascii_ = false;
}
IncrementCharacterCount(length);
}
Handle<String> ToString() {
if (array_builder_.length() == 0) {
return heap_->isolate()->factory()->empty_string();
}
Handle<String> joined_string;
if (is_ascii_) {
joined_string = NewRawAsciiString(character_count_);
AssertNoAllocation no_alloc;
SeqAsciiString* seq = SeqAsciiString::cast(*joined_string);
char* char_buffer = seq->GetChars();
StringBuilderConcatHelper(*subject_,
char_buffer,
*array_builder_.array(),
array_builder_.length());
} else {
// Non-ASCII.
joined_string = NewRawTwoByteString(character_count_);
AssertNoAllocation no_alloc;
SeqTwoByteString* seq = SeqTwoByteString::cast(*joined_string);
uc16* char_buffer = seq->GetChars();
StringBuilderConcatHelper(*subject_,
char_buffer,
*array_builder_.array(),
array_builder_.length());
}
return joined_string;
}
void IncrementCharacterCount(int by) {
if (character_count_ > String::kMaxLength - by) {
V8::FatalProcessOutOfMemory("String.replace result too large.");
}
character_count_ += by;
}
Handle<JSArray> GetParts() {
return array_builder_.ToJSArray();
}
private:
Handle<String> NewRawAsciiString(int size) {
CALL_HEAP_FUNCTION(heap_->isolate(),
heap_->AllocateRawAsciiString(size), String);
}
Handle<String> NewRawTwoByteString(int size) {
CALL_HEAP_FUNCTION(heap_->isolate(),
heap_->AllocateRawTwoByteString(size), String);
}
void AddElement(Object* element) {
ASSERT(element->IsSmi() || element->IsString());
ASSERT(array_builder_.capacity() > array_builder_.length());
array_builder_.Add(element);
}
Heap* heap_;
FixedArrayBuilder array_builder_;
Handle<String> subject_;
int character_count_;
bool is_ascii_;
};
class CompiledReplacement {
public:
CompiledReplacement()
: parts_(1), replacement_substrings_(0) {}
void Compile(Handle<String> replacement,
int capture_count,
int subject_length);
void Apply(ReplacementStringBuilder* builder,
int match_from,
int match_to,
Handle<JSArray> last_match_info);
// Number of distinct parts of the replacement pattern.
int parts() {
return parts_.length();
}
private:
enum PartType {
SUBJECT_PREFIX = 1,
SUBJECT_SUFFIX,
SUBJECT_CAPTURE,
REPLACEMENT_SUBSTRING,
REPLACEMENT_STRING,
NUMBER_OF_PART_TYPES
};
struct ReplacementPart {
static inline ReplacementPart SubjectMatch() {
return ReplacementPart(SUBJECT_CAPTURE, 0);
}
static inline ReplacementPart SubjectCapture(int capture_index) {
return ReplacementPart(SUBJECT_CAPTURE, capture_index);
}
static inline ReplacementPart SubjectPrefix() {
return ReplacementPart(SUBJECT_PREFIX, 0);
}
static inline ReplacementPart SubjectSuffix(int subject_length) {
return ReplacementPart(SUBJECT_SUFFIX, subject_length);
}
static inline ReplacementPart ReplacementString() {
return ReplacementPart(REPLACEMENT_STRING, 0);
}
static inline ReplacementPart ReplacementSubString(int from, int to) {
ASSERT(from >= 0);
ASSERT(to > from);
return ReplacementPart(-from, to);
}
// If tag <= 0 then it is the negation of a start index of a substring of
// the replacement pattern, otherwise it's a value from PartType.
ReplacementPart(int tag, int data)
: tag(tag), data(data) {
// Must be non-positive or a PartType value.
ASSERT(tag < NUMBER_OF_PART_TYPES);
}
// Either a value of PartType or a non-positive number that is
// the negation of an index into the replacement string.
int tag;
// The data value's interpretation depends on the value of tag:
// tag == SUBJECT_PREFIX ||
// tag == SUBJECT_SUFFIX: data is unused.
// tag == SUBJECT_CAPTURE: data is the number of the capture.
// tag == REPLACEMENT_SUBSTRING ||
// tag == REPLACEMENT_STRING: data is index into array of substrings
// of the replacement string.
// tag <= 0: Temporary representation of the substring of the replacement
// string ranging over -tag .. data.
// Is replaced by REPLACEMENT_{SUB,}STRING when we create the
// substring objects.
int data;
};
template<typename Char>
static void ParseReplacementPattern(ZoneList<ReplacementPart>* parts,
Vector<Char> characters,
int capture_count,
int subject_length) {
int length = characters.length();
int last = 0;
for (int i = 0; i < length; i++) {
Char c = characters[i];
if (c == '$') {
int next_index = i + 1;
if (next_index == length) { // No next character!
break;
}
Char c2 = characters[next_index];
switch (c2) {
case '$':
if (i > last) {
// There is a substring before. Include the first "$".
parts->Add(ReplacementPart::ReplacementSubString(last, next_index));
last = next_index + 1; // Continue after the second "$".
} else {
// Let the next substring start with the second "$".
last = next_index;
}
i = next_index;
break;
case '`':
if (i > last) {
parts->Add(ReplacementPart::ReplacementSubString(last, i));
}
parts->Add(ReplacementPart::SubjectPrefix());
i = next_index;
last = i + 1;
break;
case '\'':
if (i > last) {
parts->Add(ReplacementPart::ReplacementSubString(last, i));
}
parts->Add(ReplacementPart::SubjectSuffix(subject_length));
i = next_index;
last = i + 1;
break;
case '&':
if (i > last) {
parts->Add(ReplacementPart::ReplacementSubString(last, i));
}
parts->Add(ReplacementPart::SubjectMatch());
i = next_index;
last = i + 1;
break;
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9': {
int capture_ref = c2 - '0';
if (capture_ref > capture_count) {
i = next_index;
continue;
}
int second_digit_index = next_index + 1;
if (second_digit_index < length) {
// Peek ahead to see if we have two digits.
Char c3 = characters[second_digit_index];
if ('0' <= c3 && c3 <= '9') { // Double digits.
int double_digit_ref = capture_ref * 10 + c3 - '0';
if (double_digit_ref <= capture_count) {
next_index = second_digit_index;
capture_ref = double_digit_ref;
}
}
}
if (capture_ref > 0) {
if (i > last) {
parts->Add(ReplacementPart::ReplacementSubString(last, i));
}
ASSERT(capture_ref <= capture_count);
parts->Add(ReplacementPart::SubjectCapture(capture_ref));
last = next_index + 1;
}
i = next_index;
break;
}
default:
i = next_index;
break;
}
}
}
if (length > last) {
if (last == 0) {
parts->Add(ReplacementPart::ReplacementString());
} else {
parts->Add(ReplacementPart::ReplacementSubString(last, length));
}
}
}
ZoneList<ReplacementPart> parts_;
ZoneList<Handle<String> > replacement_substrings_;
};
void CompiledReplacement::Compile(Handle<String> replacement,
int capture_count,
int subject_length) {
ASSERT(replacement->IsFlat());
if (replacement->IsAsciiRepresentation()) {
AssertNoAllocation no_alloc;
ParseReplacementPattern(&parts_,
replacement->ToAsciiVector(),
capture_count,
subject_length);
} else {
ASSERT(replacement->IsTwoByteRepresentation());
AssertNoAllocation no_alloc;
ParseReplacementPattern(&parts_,
replacement->ToUC16Vector(),
capture_count,
subject_length);
}
Isolate* isolate = replacement->GetIsolate();
// Find substrings of replacement string and create them as String objects.
int substring_index = 0;
for (int i = 0, n = parts_.length(); i < n; i++) {
int tag = parts_[i].tag;
if (tag <= 0) { // A replacement string slice.
int from = -tag;
int to = parts_[i].data;
replacement_substrings_.Add(
isolate->factory()->NewSubString(replacement, from, to));
parts_[i].tag = REPLACEMENT_SUBSTRING;
parts_[i].data = substring_index;
substring_index++;
} else if (tag == REPLACEMENT_STRING) {
replacement_substrings_.Add(replacement);
parts_[i].data = substring_index;
substring_index++;
}
}
}
void CompiledReplacement::Apply(ReplacementStringBuilder* builder,
int match_from,
int match_to,
Handle<JSArray> last_match_info) {
for (int i = 0, n = parts_.length(); i < n; i++) {
ReplacementPart part = parts_[i];
switch (part.tag) {
case SUBJECT_PREFIX:
if (match_from > 0) builder->AddSubjectSlice(0, match_from);
break;
case SUBJECT_SUFFIX: {
int subject_length = part.data;
if (match_to < subject_length) {
builder->AddSubjectSlice(match_to, subject_length);
}
break;
}
case SUBJECT_CAPTURE: {
int capture = part.data;
FixedArray* match_info = FixedArray::cast(last_match_info->elements());
int from = RegExpImpl::GetCapture(match_info, capture * 2);
int to = RegExpImpl::GetCapture(match_info, capture * 2 + 1);
if (from >= 0 && to > from) {
builder->AddSubjectSlice(from, to);
}
break;
}
case REPLACEMENT_SUBSTRING:
case REPLACEMENT_STRING:
builder->AddString(replacement_substrings_[part.data]);
break;
default:
UNREACHABLE();
}
}
}
MUST_USE_RESULT static MaybeObject* StringReplaceRegExpWithString(
Isolate* isolate,
String* subject,
JSRegExp* regexp,
String* replacement,
JSArray* last_match_info) {
ASSERT(subject->IsFlat());
ASSERT(replacement->IsFlat());
HandleScope handles(isolate);
int length = subject->length();
Handle<String> subject_handle(subject);
Handle<JSRegExp> regexp_handle(regexp);
Handle<String> replacement_handle(replacement);
Handle<JSArray> last_match_info_handle(last_match_info);
Handle<Object> match = RegExpImpl::Exec(regexp_handle,
subject_handle,
0,
last_match_info_handle);
if (match.is_null()) {
return Failure::Exception();
}
if (match->IsNull()) {
return *subject_handle;
}
int capture_count = regexp_handle->CaptureCount();
// CompiledReplacement uses zone allocation.
CompilationZoneScope zone(DELETE_ON_EXIT);
CompiledReplacement compiled_replacement;
compiled_replacement.Compile(replacement_handle,
capture_count,
length);
bool is_global = regexp_handle->GetFlags().is_global();
// Guessing the number of parts that the final result string is built
// from. Global regexps can match any number of times, so we guess
// conservatively.
int expected_parts =
(compiled_replacement.parts() + 1) * (is_global ? 4 : 1) + 1;
ReplacementStringBuilder builder(isolate->heap(),
subject_handle,
expected_parts);
// Index of end of last match.
int prev = 0;
// Number of parts added by compiled replacement plus preceeding
// string and possibly suffix after last match. It is possible for
// all components to use two elements when encoded as two smis.
const int parts_added_per_loop = 2 * (compiled_replacement.parts() + 2);
bool matched = true;
do {
ASSERT(last_match_info_handle->HasFastElements());
// Increase the capacity of the builder before entering local handle-scope,
// so its internal buffer can safely allocate a new handle if it grows.
builder.EnsureCapacity(parts_added_per_loop);
HandleScope loop_scope(isolate);
int start, end;
{
AssertNoAllocation match_info_array_is_not_in_a_handle;
FixedArray* match_info_array =
FixedArray::cast(last_match_info_handle->elements());
ASSERT_EQ(capture_count * 2 + 2,
RegExpImpl::GetLastCaptureCount(match_info_array));
start = RegExpImpl::GetCapture(match_info_array, 0);
end = RegExpImpl::GetCapture(match_info_array, 1);
}
if (prev < start) {
builder.AddSubjectSlice(prev, start);
}
compiled_replacement.Apply(&builder,
start,
end,
last_match_info_handle);
prev = end;
// Only continue checking for global regexps.
if (!is_global) break;
// Continue from where the match ended, unless it was an empty match.
int next = end;
if (start == end) {
next = end + 1;
if (next > length) break;
}
match = RegExpImpl::Exec(regexp_handle,
subject_handle,
next,
last_match_info_handle);
if (match.is_null()) {
return Failure::Exception();
}
matched = !match->IsNull();
} while (matched);
if (prev < length) {
builder.AddSubjectSlice(prev, length);
}
return *(builder.ToString());
}
template <typename ResultSeqString>
MUST_USE_RESULT static MaybeObject* StringReplaceRegExpWithEmptyString(
Isolate* isolate,
String* subject,
JSRegExp* regexp,
JSArray* last_match_info) {
ASSERT(subject->IsFlat());
HandleScope handles(isolate);
Handle<String> subject_handle(subject);
Handle<JSRegExp> regexp_handle(regexp);
Handle<JSArray> last_match_info_handle(last_match_info);
Handle<Object> match = RegExpImpl::Exec(regexp_handle,
subject_handle,
0,
last_match_info_handle);
if (match.is_null()) return Failure::Exception();
if (match->IsNull()) return *subject_handle;
ASSERT(last_match_info_handle->HasFastElements());
int start, end;
{
AssertNoAllocation match_info_array_is_not_in_a_handle;
FixedArray* match_info_array =
FixedArray::cast(last_match_info_handle->elements());
start = RegExpImpl::GetCapture(match_info_array, 0);
end = RegExpImpl::GetCapture(match_info_array, 1);
}
int length = subject->length();
int new_length = length - (end - start);
if (new_length == 0) {
return isolate->heap()->empty_string();
}
Handle<ResultSeqString> answer;
if (ResultSeqString::kHasAsciiEncoding) {
answer = Handle<ResultSeqString>::cast(
isolate->factory()->NewRawAsciiString(new_length));
} else {
answer = Handle<ResultSeqString>::cast(
isolate->factory()->NewRawTwoByteString(new_length));
}
// If the regexp isn't global, only match once.
if (!regexp_handle->GetFlags().is_global()) {
if (start > 0) {
String::WriteToFlat(*subject_handle,
answer->GetChars(),
0,
start);
}
if (end < length) {
String::WriteToFlat(*subject_handle,
answer->GetChars() + start,
end,
length);
}
return *answer;
}
int prev = 0; // Index of end of last match.
int next = 0; // Start of next search (prev unless last match was empty).
int position = 0;
do {
if (prev < start) {
// Add substring subject[prev;start] to answer string.
String::WriteToFlat(*subject_handle,
answer->GetChars() + position,
prev,
start);
position += start - prev;
}
prev = end;
next = end;
// Continue from where the match ended, unless it was an empty match.
if (start == end) {
next++;
if (next > length) break;
}
match = RegExpImpl::Exec(regexp_handle,
subject_handle,
next,
last_match_info_handle);
if (match.is_null()) return Failure::Exception();
if (match->IsNull()) break;
ASSERT(last_match_info_handle->HasFastElements());
HandleScope loop_scope(isolate);
{
AssertNoAllocation match_info_array_is_not_in_a_handle;
FixedArray* match_info_array =
FixedArray::cast(last_match_info_handle->elements());
start = RegExpImpl::GetCapture(match_info_array, 0);
end = RegExpImpl::GetCapture(match_info_array, 1);
}
} while (true);
if (prev < length) {
// Add substring subject[prev;length] to answer string.
String::WriteToFlat(*subject_handle,
answer->GetChars() + position,
prev,
length);
position += length - prev;
}
if (position == 0) {
return isolate->heap()->empty_string();
}
// Shorten string and fill
int string_size = ResultSeqString::SizeFor(position);
int allocated_string_size = ResultSeqString::SizeFor(new_length);
int delta = allocated_string_size - string_size;
answer->set_length(position);
if (delta == 0) return *answer;
Address end_of_string = answer->address() + string_size;
isolate->heap()->CreateFillerObjectAt(end_of_string, delta);
return *answer;
}
static MaybeObject* Runtime_StringReplaceRegExpWithString(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 4);
CONVERT_CHECKED(String, subject, args[0]);
if (!subject->IsFlat()) {
Object* flat_subject;
{ MaybeObject* maybe_flat_subject = subject->TryFlatten();
if (!maybe_flat_subject->ToObject(&flat_subject)) {
return maybe_flat_subject;
}
}
subject = String::cast(flat_subject);
}
CONVERT_CHECKED(String, replacement, args[2]);
if (!replacement->IsFlat()) {
Object* flat_replacement;
{ MaybeObject* maybe_flat_replacement = replacement->TryFlatten();
if (!maybe_flat_replacement->ToObject(&flat_replacement)) {
return maybe_flat_replacement;
}
}
replacement = String::cast(flat_replacement);
}
CONVERT_CHECKED(JSRegExp, regexp, args[1]);
CONVERT_CHECKED(JSArray, last_match_info, args[3]);
ASSERT(last_match_info->HasFastElements());
if (replacement->length() == 0) {
if (subject->HasOnlyAsciiChars()) {
return StringReplaceRegExpWithEmptyString<SeqAsciiString>(
isolate, subject, regexp, last_match_info);
} else {
return StringReplaceRegExpWithEmptyString<SeqTwoByteString>(
isolate, subject, regexp, last_match_info);
}
}
return StringReplaceRegExpWithString(isolate,
subject,
regexp,
replacement,
last_match_info);
}
// Perform string match of pattern on subject, starting at start index.
// Caller must ensure that 0 <= start_index <= sub->length(),
// and should check that pat->length() + start_index <= sub->length().
int Runtime::StringMatch(Isolate* isolate,
Handle<String> sub,
Handle<String> pat,
int start_index) {
ASSERT(0 <= start_index);
ASSERT(start_index <= sub->length());
int pattern_length = pat->length();
if (pattern_length == 0) return start_index;
int subject_length = sub->length();
if (start_index + pattern_length > subject_length) return -1;
if (!sub->IsFlat()) FlattenString(sub);
if (!pat->IsFlat()) FlattenString(pat);
AssertNoAllocation no_heap_allocation; // ensure vectors stay valid
// Extract flattened substrings of cons strings before determining asciiness.
String* seq_sub = *sub;
if (seq_sub->IsConsString()) seq_sub = ConsString::cast(seq_sub)->first();
String* seq_pat = *pat;
if (seq_pat->IsConsString()) seq_pat = ConsString::cast(seq_pat)->first();
// dispatch on type of strings
if (seq_pat->IsAsciiRepresentation()) {
Vector<const char> pat_vector = seq_pat->ToAsciiVector();
if (seq_sub->IsAsciiRepresentation()) {
return SearchString(isolate,
seq_sub->ToAsciiVector(),
pat_vector,
start_index);
}
return SearchString(isolate,
seq_sub->ToUC16Vector(),
pat_vector,
start_index);
}
Vector<const uc16> pat_vector = seq_pat->ToUC16Vector();
if (seq_sub->IsAsciiRepresentation()) {
return SearchString(isolate,
seq_sub->ToAsciiVector(),
pat_vector,
start_index);
}
return SearchString(isolate,
seq_sub->ToUC16Vector(),
pat_vector,
start_index);
}
static MaybeObject* Runtime_StringIndexOf(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate); // create a new handle scope
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(String, sub, 0);
CONVERT_ARG_CHECKED(String, pat, 1);
Object* index = args[2];
uint32_t start_index;
if (!index->ToArrayIndex(&start_index)) return Smi::FromInt(-1);
RUNTIME_ASSERT(start_index <= static_cast<uint32_t>(sub->length()));
int position =
Runtime::StringMatch(isolate, sub, pat, start_index);
return Smi::FromInt(position);
}
template <typename schar, typename pchar>
static int StringMatchBackwards(Vector<const schar> subject,
Vector<const pchar> pattern,
int idx) {
int pattern_length = pattern.length();
ASSERT(pattern_length >= 1);
ASSERT(idx + pattern_length <= subject.length());
if (sizeof(schar) == 1 && sizeof(pchar) > 1) {
for (int i = 0; i < pattern_length; i++) {
uc16 c = pattern[i];
if (c > String::kMaxAsciiCharCode) {
return -1;
}
}
}
pchar pattern_first_char = pattern[0];
for (int i = idx; i >= 0; i--) {
if (subject[i] != pattern_first_char) continue;
int j = 1;
while (j < pattern_length) {
if (pattern[j] != subject[i+j]) {
break;
}
j++;
}
if (j == pattern_length) {
return i;
}
}
return -1;
}
static MaybeObject* Runtime_StringLastIndexOf(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate); // create a new handle scope
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(String, sub, 0);
CONVERT_ARG_CHECKED(String, pat, 1);
Object* index = args[2];
uint32_t start_index;
if (!index->ToArrayIndex(&start_index)) return Smi::FromInt(-1);
uint32_t pat_length = pat->length();
uint32_t sub_length = sub->length();
if (start_index + pat_length > sub_length) {
start_index = sub_length - pat_length;
}
if (pat_length == 0) {
return Smi::FromInt(start_index);
}
if (!sub->IsFlat()) FlattenString(sub);
if (!pat->IsFlat()) FlattenString(pat);
AssertNoAllocation no_heap_allocation; // ensure vectors stay valid
int position = -1;
if (pat->IsAsciiRepresentation()) {
Vector<const char> pat_vector = pat->ToAsciiVector();
if (sub->IsAsciiRepresentation()) {
position = StringMatchBackwards(sub->ToAsciiVector(),
pat_vector,
start_index);
} else {
position = StringMatchBackwards(sub->ToUC16Vector(),
pat_vector,
start_index);
}
} else {
Vector<const uc16> pat_vector = pat->ToUC16Vector();
if (sub->IsAsciiRepresentation()) {
position = StringMatchBackwards(sub->ToAsciiVector(),
pat_vector,
start_index);
} else {
position = StringMatchBackwards(sub->ToUC16Vector(),
pat_vector,
start_index);
}
}
return Smi::FromInt(position);
}
static MaybeObject* Runtime_StringLocaleCompare(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, str1, args[0]);
CONVERT_CHECKED(String, str2, args[1]);
if (str1 == str2) return Smi::FromInt(0); // Equal.
int str1_length = str1->length();
int str2_length = str2->length();
// Decide trivial cases without flattening.
if (str1_length == 0) {
if (str2_length == 0) return Smi::FromInt(0); // Equal.
return Smi::FromInt(-str2_length);
} else {
if (str2_length == 0) return Smi::FromInt(str1_length);
}
int end = str1_length < str2_length ? str1_length : str2_length;
// No need to flatten if we are going to find the answer on the first
// character. At this point we know there is at least one character
// in each string, due to the trivial case handling above.
int d = str1->Get(0) - str2->Get(0);
if (d != 0) return Smi::FromInt(d);
str1->TryFlatten();
str2->TryFlatten();
StringInputBuffer& buf1 =
*isolate->runtime_state()->string_locale_compare_buf1();
StringInputBuffer& buf2 =
*isolate->runtime_state()->string_locale_compare_buf2();
buf1.Reset(str1);
buf2.Reset(str2);
for (int i = 0; i < end; i++) {
uint16_t char1 = buf1.GetNext();
uint16_t char2 = buf2.GetNext();
if (char1 != char2) return Smi::FromInt(char1 - char2);
}
return Smi::FromInt(str1_length - str2_length);
}
static MaybeObject* Runtime_SubString(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_CHECKED(String, value, args[0]);
Object* from = args[1];
Object* to = args[2];
int start, end;
// We have a fast integer-only case here to avoid a conversion to double in
// the common case where from and to are Smis.
if (from->IsSmi() && to->IsSmi()) {
start = Smi::cast(from)->value();
end = Smi::cast(to)->value();
} else {
CONVERT_DOUBLE_CHECKED(from_number, from);
CONVERT_DOUBLE_CHECKED(to_number, to);
start = FastD2I(from_number);
end = FastD2I(to_number);
}
RUNTIME_ASSERT(end >= start);
RUNTIME_ASSERT(start >= 0);
RUNTIME_ASSERT(end <= value->length());
isolate->counters()->sub_string_runtime()->Increment();
return value->SubString(start, end);
}
static MaybeObject* Runtime_StringMatch(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT_EQ(3, args.length());
CONVERT_ARG_CHECKED(String, subject, 0);
CONVERT_ARG_CHECKED(JSRegExp, regexp, 1);
CONVERT_ARG_CHECKED(JSArray, regexp_info, 2);
HandleScope handles;
Handle<Object> match = RegExpImpl::Exec(regexp, subject, 0, regexp_info);
if (match.is_null()) {
return Failure::Exception();
}
if (match->IsNull()) {
return isolate->heap()->null_value();
}
int length = subject->length();
CompilationZoneScope zone_space(DELETE_ON_EXIT);
ZoneList<int> offsets(8);
do {
int start;
int end;
{
AssertNoAllocation no_alloc;
FixedArray* elements = FixedArray::cast(regexp_info->elements());
start = Smi::cast(elements->get(RegExpImpl::kFirstCapture))->value();
end = Smi::cast(elements->get(RegExpImpl::kFirstCapture + 1))->value();
}
offsets.Add(start);
offsets.Add(end);
int index = start < end ? end : end + 1;
if (index > length) break;
match = RegExpImpl::Exec(regexp, subject, index, regexp_info);
if (match.is_null()) {
return Failure::Exception();
}
} while (!match->IsNull());
int matches = offsets.length() / 2;
Handle<FixedArray> elements = isolate->factory()->NewFixedArray(matches);
for (int i = 0; i < matches ; i++) {
int from = offsets.at(i * 2);
int to = offsets.at(i * 2 + 1);
Handle<String> match = isolate->factory()->NewSubString(subject, from, to);
elements->set(i, *match);
}
Handle<JSArray> result = isolate->factory()->NewJSArrayWithElements(elements);
result->set_length(Smi::FromInt(matches));
return *result;
}
// Two smis before and after the match, for very long strings.
const int kMaxBuilderEntriesPerRegExpMatch = 5;
static void SetLastMatchInfoNoCaptures(Handle<String> subject,
Handle<JSArray> last_match_info,
int match_start,
int match_end) {
// Fill last_match_info with a single capture.
last_match_info->EnsureSize(2 + RegExpImpl::kLastMatchOverhead);
AssertNoAllocation no_gc;
FixedArray* elements = FixedArray::cast(last_match_info->elements());
RegExpImpl::SetLastCaptureCount(elements, 2);
RegExpImpl::SetLastInput(elements, *subject);
RegExpImpl::SetLastSubject(elements, *subject);
RegExpImpl::SetCapture(elements, 0, match_start);
RegExpImpl::SetCapture(elements, 1, match_end);
}
template <typename SubjectChar, typename PatternChar>
static bool SearchStringMultiple(Isolate* isolate,
Vector<const SubjectChar> subject,
Vector<const PatternChar> pattern,
String* pattern_string,
FixedArrayBuilder* builder,
int* match_pos) {
int pos = *match_pos;
int subject_length = subject.length();
int pattern_length = pattern.length();
int max_search_start = subject_length - pattern_length;
StringSearch<PatternChar, SubjectChar> search(isolate, pattern);
while (pos <= max_search_start) {
if (!builder->HasCapacity(kMaxBuilderEntriesPerRegExpMatch)) {
*match_pos = pos;
return false;
}
// Position of end of previous match.
int match_end = pos + pattern_length;
int new_pos = search.Search(subject, match_end);
if (new_pos >= 0) {
// A match.
if (new_pos > match_end) {
ReplacementStringBuilder::AddSubjectSlice(builder,
match_end,
new_pos);
}
pos = new_pos;
builder->Add(pattern_string);
} else {
break;
}
}
if (pos < max_search_start) {
ReplacementStringBuilder::AddSubjectSlice(builder,
pos + pattern_length,
subject_length);
}
*match_pos = pos;
return true;
}
static bool SearchStringMultiple(Isolate* isolate,
Handle<String> subject,
Handle<String> pattern,
Handle<JSArray> last_match_info,
FixedArrayBuilder* builder) {
ASSERT(subject->IsFlat());
ASSERT(pattern->IsFlat());
// Treating as if a previous match was before first character.
int match_pos = -pattern->length();
for (;;) { // Break when search complete.
builder->EnsureCapacity(kMaxBuilderEntriesPerRegExpMatch);
AssertNoAllocation no_gc;
if (subject->IsAsciiRepresentation()) {
Vector<const char> subject_vector = subject->ToAsciiVector();
if (pattern->IsAsciiRepresentation()) {
if (SearchStringMultiple(isolate,
subject_vector,
pattern->ToAsciiVector(),
*pattern,
builder,
&match_pos)) break;
} else {
if (SearchStringMultiple(isolate,
subject_vector,
pattern->ToUC16Vector(),
*pattern,
builder,
&match_pos)) break;
}
} else {
Vector<const uc16> subject_vector = subject->ToUC16Vector();
if (pattern->IsAsciiRepresentation()) {
if (SearchStringMultiple(isolate,
subject_vector,
pattern->ToAsciiVector(),
*pattern,
builder,
&match_pos)) break;
} else {
if (SearchStringMultiple(isolate,
subject_vector,
pattern->ToUC16Vector(),
*pattern,
builder,
&match_pos)) break;
}
}
}
if (match_pos >= 0) {
SetLastMatchInfoNoCaptures(subject,
last_match_info,
match_pos,
match_pos + pattern->length());
return true;
}
return false; // No matches at all.
}
static RegExpImpl::IrregexpResult SearchRegExpNoCaptureMultiple(
Isolate* isolate,
Handle<String> subject,
Handle<JSRegExp> regexp,
Handle<JSArray> last_match_array,
FixedArrayBuilder* builder) {
ASSERT(subject->IsFlat());
int match_start = -1;
int match_end = 0;
int pos = 0;
int required_registers = RegExpImpl::IrregexpPrepare(regexp, subject);
if (required_registers < 0) return RegExpImpl::RE_EXCEPTION;
OffsetsVector registers(required_registers);
Vector<int32_t> register_vector(registers.vector(), registers.length());
int subject_length = subject->length();
for (;;) { // Break on failure, return on exception.
RegExpImpl::IrregexpResult result =
RegExpImpl::IrregexpExecOnce(regexp,
subject,
pos,
register_vector);
if (result == RegExpImpl::RE_SUCCESS) {
match_start = register_vector[0];
builder->EnsureCapacity(kMaxBuilderEntriesPerRegExpMatch);
if (match_end < match_start) {
ReplacementStringBuilder::AddSubjectSlice(builder,
match_end,
match_start);
}
match_end = register_vector[1];
HandleScope loop_scope(isolate);
builder->Add(*isolate->factory()->NewSubString(subject,
match_start,
match_end));
if (match_start != match_end) {
pos = match_end;
} else {
pos = match_end + 1;
if (pos > subject_length) break;
}
} else if (result == RegExpImpl::RE_FAILURE) {
break;
} else {
ASSERT_EQ(result, RegExpImpl::RE_EXCEPTION);
return result;
}
}
if (match_start >= 0) {
if (match_end < subject_length) {
ReplacementStringBuilder::AddSubjectSlice(builder,
match_end,
subject_length);
}
SetLastMatchInfoNoCaptures(subject,
last_match_array,
match_start,
match_end);
return RegExpImpl::RE_SUCCESS;
} else {
return RegExpImpl::RE_FAILURE; // No matches at all.
}
}
static RegExpImpl::IrregexpResult SearchRegExpMultiple(
Isolate* isolate,
Handle<String> subject,
Handle<JSRegExp> regexp,
Handle<JSArray> last_match_array,
FixedArrayBuilder* builder) {
ASSERT(subject->IsFlat());
int required_registers = RegExpImpl::IrregexpPrepare(regexp, subject);
if (required_registers < 0) return RegExpImpl::RE_EXCEPTION;
OffsetsVector registers(required_registers);
Vector<int32_t> register_vector(registers.vector(), registers.length());
RegExpImpl::IrregexpResult result =
RegExpImpl::IrregexpExecOnce(regexp,
subject,
0,
register_vector);
int capture_count = regexp->CaptureCount();
int subject_length = subject->length();
// Position to search from.
int pos = 0;
// End of previous match. Differs from pos if match was empty.
int match_end = 0;
if (result == RegExpImpl::RE_SUCCESS) {
// Need to keep a copy of the previous match for creating last_match_info
// at the end, so we have two vectors that we swap between.
OffsetsVector registers2(required_registers);
Vector<int> prev_register_vector(registers2.vector(), registers2.length());
do {
int match_start = register_vector[0];
builder->EnsureCapacity(kMaxBuilderEntriesPerRegExpMatch);
if (match_end < match_start) {
ReplacementStringBuilder::AddSubjectSlice(builder,
match_end,
match_start);
}
match_end = register_vector[1];
{
// Avoid accumulating new handles inside loop.
HandleScope temp_scope(isolate);
// Arguments array to replace function is match, captures, index and
// subject, i.e., 3 + capture count in total.
Handle<FixedArray> elements =
isolate->factory()->NewFixedArray(3 + capture_count);
Handle<String> match = isolate->factory()->NewSubString(subject,
match_start,
match_end);
elements->set(0, *match);
for (int i = 1; i <= capture_count; i++) {
int start = register_vector[i * 2];
if (start >= 0) {
int end = register_vector[i * 2 + 1];
ASSERT(start <= end);
Handle<String> substring = isolate->factory()->NewSubString(subject,
start,
end);
elements->set(i, *substring);
} else {
ASSERT(register_vector[i * 2 + 1] < 0);
elements->set(i, isolate->heap()->undefined_value());
}
}
elements->set(capture_count + 1, Smi::FromInt(match_start));
elements->set(capture_count + 2, *subject);
builder->Add(*isolate->factory()->NewJSArrayWithElements(elements));
}
// Swap register vectors, so the last successful match is in
// prev_register_vector.
Vector<int32_t> tmp = prev_register_vector;
prev_register_vector = register_vector;
register_vector = tmp;
if (match_end > match_start) {
pos = match_end;
} else {
pos = match_end + 1;
if (pos > subject_length) {
break;
}
}
result = RegExpImpl::IrregexpExecOnce(regexp,
subject,
pos,
register_vector);
} while (result == RegExpImpl::RE_SUCCESS);
if (result != RegExpImpl::RE_EXCEPTION) {
// Finished matching, with at least one match.
if (match_end < subject_length) {
ReplacementStringBuilder::AddSubjectSlice(builder,
match_end,
subject_length);
}
int last_match_capture_count = (capture_count + 1) * 2;
int last_match_array_size =
last_match_capture_count + RegExpImpl::kLastMatchOverhead;
last_match_array->EnsureSize(last_match_array_size);
AssertNoAllocation no_gc;
FixedArray* elements = FixedArray::cast(last_match_array->elements());
RegExpImpl::SetLastCaptureCount(elements, last_match_capture_count);
RegExpImpl::SetLastSubject(elements, *subject);
RegExpImpl::SetLastInput(elements, *subject);
for (int i = 0; i < last_match_capture_count; i++) {
RegExpImpl::SetCapture(elements, i, prev_register_vector[i]);
}
return RegExpImpl::RE_SUCCESS;
}
}
// No matches at all, return failure or exception result directly.
return result;
}
static MaybeObject* Runtime_RegExpExecMultiple(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 4);
HandleScope handles(isolate);
CONVERT_ARG_CHECKED(String, subject, 1);
if (!subject->IsFlat()) { FlattenString(subject); }
CONVERT_ARG_CHECKED(JSRegExp, regexp, 0);
CONVERT_ARG_CHECKED(JSArray, last_match_info, 2);
CONVERT_ARG_CHECKED(JSArray, result_array, 3);
ASSERT(last_match_info->HasFastElements());
ASSERT(regexp->GetFlags().is_global());
Handle<FixedArray> result_elements;
if (result_array->HasFastElements()) {
result_elements =
Handle<FixedArray>(FixedArray::cast(result_array->elements()));
} else {
result_elements = isolate->factory()->NewFixedArrayWithHoles(16);
}
FixedArrayBuilder builder(result_elements);
if (regexp->TypeTag() == JSRegExp::ATOM) {
Handle<String> pattern(
String::cast(regexp->DataAt(JSRegExp::kAtomPatternIndex)));
ASSERT(pattern->IsFlat());
if (SearchStringMultiple(isolate, subject, pattern,
last_match_info, &builder)) {
return *builder.ToJSArray(result_array);
}
return isolate->heap()->null_value();
}
ASSERT_EQ(regexp->TypeTag(), JSRegExp::IRREGEXP);
RegExpImpl::IrregexpResult result;
if (regexp->CaptureCount() == 0) {
result = SearchRegExpNoCaptureMultiple(isolate,
subject,
regexp,
last_match_info,
&builder);
} else {
result = SearchRegExpMultiple(isolate,
subject,
regexp,
last_match_info,
&builder);
}
if (result == RegExpImpl::RE_SUCCESS) return *builder.ToJSArray(result_array);
if (result == RegExpImpl::RE_FAILURE) return isolate->heap()->null_value();
ASSERT_EQ(result, RegExpImpl::RE_EXCEPTION);
return Failure::Exception();
}
static MaybeObject* Runtime_NumberToRadixString(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
// Fast case where the result is a one character string.
if (args[0]->IsSmi() && args[1]->IsSmi()) {
int value = Smi::cast(args[0])->value();
int radix = Smi::cast(args[1])->value();
if (value >= 0 && value < radix) {
RUNTIME_ASSERT(radix <= 36);
// Character array used for conversion.
static const char kCharTable[] = "0123456789abcdefghijklmnopqrstuvwxyz";
return isolate->heap()->
LookupSingleCharacterStringFromCode(kCharTable[value]);
}
}
// Slow case.
CONVERT_DOUBLE_CHECKED(value, args[0]);
if (isnan(value)) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("NaN"));
}
if (isinf(value)) {
if (value < 0) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("-Infinity"));
}
return isolate->heap()->AllocateStringFromAscii(CStrVector("Infinity"));
}
CONVERT_DOUBLE_CHECKED(radix_number, args[1]);
int radix = FastD2I(radix_number);
RUNTIME_ASSERT(2 <= radix && radix <= 36);
char* str = DoubleToRadixCString(value, radix);
MaybeObject* result =
isolate->heap()->AllocateStringFromAscii(CStrVector(str));
DeleteArray(str);
return result;
}
static MaybeObject* Runtime_NumberToFixed(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(value, args[0]);
if (isnan(value)) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("NaN"));
}
if (isinf(value)) {
if (value < 0) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("-Infinity"));
}
return isolate->heap()->AllocateStringFromAscii(CStrVector("Infinity"));
}
CONVERT_DOUBLE_CHECKED(f_number, args[1]);
int f = FastD2I(f_number);
RUNTIME_ASSERT(f >= 0);
char* str = DoubleToFixedCString(value, f);
MaybeObject* res =
isolate->heap()->AllocateStringFromAscii(CStrVector(str));
DeleteArray(str);
return res;
}
static MaybeObject* Runtime_NumberToExponential(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(value, args[0]);
if (isnan(value)) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("NaN"));
}
if (isinf(value)) {
if (value < 0) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("-Infinity"));
}
return isolate->heap()->AllocateStringFromAscii(CStrVector("Infinity"));
}
CONVERT_DOUBLE_CHECKED(f_number, args[1]);
int f = FastD2I(f_number);
RUNTIME_ASSERT(f >= -1 && f <= 20);
char* str = DoubleToExponentialCString(value, f);
MaybeObject* res =
isolate->heap()->AllocateStringFromAscii(CStrVector(str));
DeleteArray(str);
return res;
}
static MaybeObject* Runtime_NumberToPrecision(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(value, args[0]);
if (isnan(value)) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("NaN"));
}
if (isinf(value)) {
if (value < 0) {
return isolate->heap()->AllocateStringFromAscii(CStrVector("-Infinity"));
}
return isolate->heap()->AllocateStringFromAscii(CStrVector("Infinity"));
}
CONVERT_DOUBLE_CHECKED(f_number, args[1]);
int f = FastD2I(f_number);
RUNTIME_ASSERT(f >= 1 && f <= 21);
char* str = DoubleToPrecisionCString(value, f);
MaybeObject* res =
isolate->heap()->AllocateStringFromAscii(CStrVector(str));
DeleteArray(str);
return res;
}
// Returns a single character string where first character equals
// string->Get(index).
static Handle<Object> GetCharAt(Handle<String> string, uint32_t index) {
if (index < static_cast<uint32_t>(string->length())) {
string->TryFlatten();
return LookupSingleCharacterStringFromCode(
string->Get(index));
}
return Execution::CharAt(string, index);
}
MaybeObject* Runtime::GetElementOrCharAt(Isolate* isolate,
Handle<Object> object,
uint32_t index) {
// Handle [] indexing on Strings
if (object->IsString()) {
Handle<Object> result = GetCharAt(Handle<String>::cast(object), index);
if (!result->IsUndefined()) return *result;
}
// Handle [] indexing on String objects
if (object->IsStringObjectWithCharacterAt(index)) {
Handle<JSValue> js_value = Handle<JSValue>::cast(object);
Handle<Object> result =
GetCharAt(Handle<String>(String::cast(js_value->value())), index);
if (!result->IsUndefined()) return *result;
}
if (object->IsString() || object->IsNumber() || object->IsBoolean()) {
Handle<Object> prototype = GetPrototype(object);
return prototype->GetElement(index);
}
return GetElement(object, index);
}
MaybeObject* Runtime::GetElement(Handle<Object> object, uint32_t index) {
return object->GetElement(index);
}
MaybeObject* Runtime::GetObjectProperty(Isolate* isolate,
Handle<Object> object,
Handle<Object> key) {
HandleScope scope(isolate);
if (object->IsUndefined() || object->IsNull()) {
Handle<Object> args[2] = { key, object };
Handle<Object> error =
isolate->factory()->NewTypeError("non_object_property_load",
HandleVector(args, 2));
return isolate->Throw(*error);
}
// Check if the given key is an array index.
uint32_t index;
if (key->ToArrayIndex(&index)) {
return GetElementOrCharAt(isolate, object, index);
}
// Convert the key to a string - possibly by calling back into JavaScript.
Handle<String> name;
if (key->IsString()) {
name = Handle<String>::cast(key);
} else {
bool has_pending_exception = false;
Handle<Object> converted =
Execution::ToString(key, &has_pending_exception);
if (has_pending_exception) return Failure::Exception();
name = Handle<String>::cast(converted);
}
// Check if the name is trivially convertible to an index and get
// the element if so.
if (name->AsArrayIndex(&index)) {
return GetElementOrCharAt(isolate, object, index);
} else {
PropertyAttributes attr;
return object->GetProperty(*name, &attr);
}
}
static MaybeObject* Runtime_GetProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
Handle<Object> object = args.at<Object>(0);
Handle<Object> key = args.at<Object>(1);
return Runtime::GetObjectProperty(isolate, object, key);
}
// KeyedStringGetProperty is called from KeyedLoadIC::GenerateGeneric.
static MaybeObject* Runtime_KeyedGetProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
// Fast cases for getting named properties of the receiver JSObject
// itself.
//
// The global proxy objects has to be excluded since LocalLookup on
// the global proxy object can return a valid result even though the
// global proxy object never has properties. This is the case
// because the global proxy object forwards everything to its hidden
// prototype including local lookups.
//
// Additionally, we need to make sure that we do not cache results
// for objects that require access checks.
if (args[0]->IsJSObject() &&
!args[0]->IsJSGlobalProxy() &&
!args[0]->IsAccessCheckNeeded() &&
args[1]->IsString()) {
JSObject* receiver = JSObject::cast(args[0]);
String* key = String::cast(args[1]);
if (receiver->HasFastProperties()) {
// Attempt to use lookup cache.
Map* receiver_map = receiver->map();
KeyedLookupCache* keyed_lookup_cache = isolate->keyed_lookup_cache();
int offset = keyed_lookup_cache->Lookup(receiver_map, key);
if (offset != -1) {
Object* value = receiver->FastPropertyAt(offset);
return value->IsTheHole() ? isolate->heap()->undefined_value() : value;
}
// Lookup cache miss. Perform lookup and update the cache if appropriate.
LookupResult result;
receiver->LocalLookup(key, &result);
if (result.IsProperty() && result.type() == FIELD) {
int offset = result.GetFieldIndex();
keyed_lookup_cache->Update(receiver_map, key, offset);
return receiver->FastPropertyAt(offset);
}
} else {
// Attempt dictionary lookup.
StringDictionary* dictionary = receiver->property_dictionary();
int entry = dictionary->FindEntry(key);
if ((entry != StringDictionary::kNotFound) &&
(dictionary->DetailsAt(entry).type() == NORMAL)) {
Object* value = dictionary->ValueAt(entry);
if (!receiver->IsGlobalObject()) return value;
value = JSGlobalPropertyCell::cast(value)->value();
if (!value->IsTheHole()) return value;
// If value is the hole do the general lookup.
}
}
} else if (args[0]->IsString() && args[1]->IsSmi()) {
// Fast case for string indexing using [] with a smi index.
HandleScope scope(isolate);
Handle<String> str = args.at<String>(0);
int index = Smi::cast(args[1])->value();
if (index >= 0 && index < str->length()) {
Handle<Object> result = GetCharAt(str, index);
return *result;
}
}
// Fall back to GetObjectProperty.
return Runtime::GetObjectProperty(isolate,
args.at<Object>(0),
args.at<Object>(1));
}
// Implements part of 8.12.9 DefineOwnProperty.
// There are 3 cases that lead here:
// Step 4b - define a new accessor property.
// Steps 9c & 12 - replace an existing data property with an accessor property.
// Step 12 - update an existing accessor property with an accessor or generic
// descriptor.
static MaybeObject* Runtime_DefineOrRedefineAccessorProperty(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 5);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
CONVERT_CHECKED(String, name, args[1]);
CONVERT_CHECKED(Smi, flag_setter, args[2]);
Object* fun = args[3];
RUNTIME_ASSERT(fun->IsJSFunction() || fun->IsUndefined());
CONVERT_CHECKED(Smi, flag_attr, args[4]);
int unchecked = flag_attr->value();
RUNTIME_ASSERT((unchecked & ~(READ_ONLY | DONT_ENUM | DONT_DELETE)) == 0);
RUNTIME_ASSERT(!obj->IsNull());
LookupResult result;
obj->LocalLookupRealNamedProperty(name, &result);
PropertyAttributes attr = static_cast<PropertyAttributes>(unchecked);
// If an existing property is either FIELD, NORMAL or CONSTANT_FUNCTION
// delete it to avoid running into trouble in DefineAccessor, which
// handles this incorrectly if the property is readonly (does nothing)
if (result.IsProperty() &&
(result.type() == FIELD || result.type() == NORMAL
|| result.type() == CONSTANT_FUNCTION)) {
Object* ok;
{ MaybeObject* maybe_ok =
obj->DeleteProperty(name, JSObject::NORMAL_DELETION);
if (!maybe_ok->ToObject(&ok)) return maybe_ok;
}
}
return obj->DefineAccessor(name, flag_setter->value() == 0, fun, attr);
}
// Implements part of 8.12.9 DefineOwnProperty.
// There are 3 cases that lead here:
// Step 4a - define a new data property.
// Steps 9b & 12 - replace an existing accessor property with a data property.
// Step 12 - update an existing data property with a data or generic
// descriptor.
static MaybeObject* Runtime_DefineOrRedefineDataProperty(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 4);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSObject, js_object, 0);
CONVERT_ARG_CHECKED(String, name, 1);
Handle<Object> obj_value = args.at<Object>(2);
CONVERT_CHECKED(Smi, flag, args[3]);
int unchecked = flag->value();
RUNTIME_ASSERT((unchecked & ~(READ_ONLY | DONT_ENUM | DONT_DELETE)) == 0);
PropertyAttributes attr = static_cast<PropertyAttributes>(unchecked);
// Check if this is an element.
uint32_t index;
bool is_element = name->AsArrayIndex(&index);
// Special case for elements if any of the flags are true.
// If elements are in fast case we always implicitly assume that:
// DONT_DELETE: false, DONT_ENUM: false, READ_ONLY: false.
if (((unchecked & (DONT_DELETE | DONT_ENUM | READ_ONLY)) != 0) &&
is_element) {
// Normalize the elements to enable attributes on the property.
if (js_object->IsJSGlobalProxy()) {
// We do not need to do access checks here since these has already
// been performed by the call to GetOwnProperty.
Handle<Object> proto(js_object->GetPrototype());
// If proxy is detached, ignore the assignment. Alternatively,
// we could throw an exception.
if (proto->IsNull()) return *obj_value;
js_object = Handle<JSObject>::cast(proto);
}
NormalizeElements(js_object);
Handle<NumberDictionary> dictionary(js_object->element_dictionary());
// Make sure that we never go back to fast case.
dictionary->set_requires_slow_elements();
PropertyDetails details = PropertyDetails(attr, NORMAL);
NumberDictionarySet(dictionary, index, obj_value, details);
return *obj_value;
}
LookupResult result;
js_object->LookupRealNamedProperty(*name, &result);
// To be compatible with safari we do not change the value on API objects
// in defineProperty. Firefox disagrees here, and actually changes the value.
if (result.IsProperty() &&
(result.type() == CALLBACKS) &&
result.GetCallbackObject()->IsAccessorInfo()) {
return isolate->heap()->undefined_value();
}
// Take special care when attributes are different and there is already
// a property. For simplicity we normalize the property which enables us
// to not worry about changing the instance_descriptor and creating a new
// map. The current version of SetObjectProperty does not handle attributes
// correctly in the case where a property is a field and is reset with
// new attributes.
if (result.IsProperty() &&
(attr != result.GetAttributes() || result.type() == CALLBACKS)) {
// New attributes - normalize to avoid writing to instance descriptor
if (js_object->IsJSGlobalProxy()) {
// Since the result is a property, the prototype will exist so
// we don't have to check for null.
js_object = Handle<JSObject>(JSObject::cast(js_object->GetPrototype()));
}
NormalizeProperties(js_object, CLEAR_INOBJECT_PROPERTIES, 0);
// Use IgnoreAttributes version since a readonly property may be
// overridden and SetProperty does not allow this.
return js_object->SetLocalPropertyIgnoreAttributes(*name,
*obj_value,
attr);
}
return Runtime::ForceSetObjectProperty(isolate,
js_object,
name,
obj_value,
attr);
}
MaybeObject* Runtime::SetObjectProperty(Isolate* isolate,
Handle<Object> object,
Handle<Object> key,
Handle<Object> value,
PropertyAttributes attr,
StrictModeFlag strict_mode) {
HandleScope scope(isolate);
if (object->IsUndefined() || object->IsNull()) {
Handle<Object> args[2] = { key, object };
Handle<Object> error =
isolate->factory()->NewTypeError("non_object_property_store",
HandleVector(args, 2));
return isolate->Throw(*error);
}
// If the object isn't a JavaScript object, we ignore the store.
if (!object->IsJSObject()) return *value;
Handle<JSObject> js_object = Handle<JSObject>::cast(object);
// Check if the given key is an array index.
uint32_t index;
if (key->ToArrayIndex(&index)) {
// In Firefox/SpiderMonkey, Safari and Opera you can access the characters
// of a string using [] notation. We need to support this too in
// JavaScript.
// In the case of a String object we just need to redirect the assignment to
// the underlying string if the index is in range. Since the underlying
// string does nothing with the assignment then we can ignore such
// assignments.
if (js_object->IsStringObjectWithCharacterAt(index)) {
return *value;
}
Handle<Object> result = SetElement(js_object, index, value, strict_mode);
if (result.is_null()) return Failure::Exception();
return *value;
}
if (key->IsString()) {
Handle<Object> result;
if (Handle<String>::cast(key)->AsArrayIndex(&index)) {
result = SetElement(js_object, index, value, strict_mode);
} else {
Handle<String> key_string = Handle<String>::cast(key);
key_string->TryFlatten();
result = SetProperty(js_object, key_string, value, attr, strict_mode);
}
if (result.is_null()) return Failure::Exception();
return *value;
}
// Call-back into JavaScript to convert the key to a string.
bool has_pending_exception = false;
Handle<Object> converted = Execution::ToString(key, &has_pending_exception);
if (has_pending_exception) return Failure::Exception();
Handle<String> name = Handle<String>::cast(converted);
if (name->AsArrayIndex(&index)) {
return js_object->SetElement(index, *value, strict_mode);
} else {
return js_object->SetProperty(*name, *value, attr, strict_mode);
}
}
MaybeObject* Runtime::ForceSetObjectProperty(Isolate* isolate,
Handle<JSObject> js_object,
Handle<Object> key,
Handle<Object> value,
PropertyAttributes attr) {
HandleScope scope(isolate);
// Check if the given key is an array index.
uint32_t index;
if (key->ToArrayIndex(&index)) {
// In Firefox/SpiderMonkey, Safari and Opera you can access the characters
// of a string using [] notation. We need to support this too in
// JavaScript.
// In the case of a String object we just need to redirect the assignment to
// the underlying string if the index is in range. Since the underlying
// string does nothing with the assignment then we can ignore such
// assignments.
if (js_object->IsStringObjectWithCharacterAt(index)) {
return *value;
}
return js_object->SetElement(index, *value, kNonStrictMode);
}
if (key->IsString()) {
if (Handle<String>::cast(key)->AsArrayIndex(&index)) {
return js_object->SetElement(index, *value, kNonStrictMode);
} else {
Handle<String> key_string = Handle<String>::cast(key);
key_string->TryFlatten();
return js_object->SetLocalPropertyIgnoreAttributes(*key_string,
*value,
attr);
}
}
// Call-back into JavaScript to convert the key to a string.
bool has_pending_exception = false;
Handle<Object> converted = Execution::ToString(key, &has_pending_exception);
if (has_pending_exception) return Failure::Exception();
Handle<String> name = Handle<String>::cast(converted);
if (name->AsArrayIndex(&index)) {
return js_object->SetElement(index, *value, kNonStrictMode);
} else {
return js_object->SetLocalPropertyIgnoreAttributes(*name, *value, attr);
}
}
MaybeObject* Runtime::ForceDeleteObjectProperty(Isolate* isolate,
Handle<JSObject> js_object,
Handle<Object> key) {
HandleScope scope(isolate);
// Check if the given key is an array index.
uint32_t index;
if (key->ToArrayIndex(&index)) {
// In Firefox/SpiderMonkey, Safari and Opera you can access the
// characters of a string using [] notation. In the case of a
// String object we just need to redirect the deletion to the
// underlying string if the index is in range. Since the
// underlying string does nothing with the deletion, we can ignore
// such deletions.
if (js_object->IsStringObjectWithCharacterAt(index)) {
return isolate->heap()->true_value();
}
return js_object->DeleteElement(index, JSObject::FORCE_DELETION);
}
Handle<String> key_string;
if (key->IsString()) {
key_string = Handle<String>::cast(key);
} else {
// Call-back into JavaScript to convert the key to a string.
bool has_pending_exception = false;
Handle<Object> converted = Execution::ToString(key, &has_pending_exception);
if (has_pending_exception) return Failure::Exception();
key_string = Handle<String>::cast(converted);
}
key_string->TryFlatten();
return js_object->DeleteProperty(*key_string, JSObject::FORCE_DELETION);
}
static MaybeObject* Runtime_SetProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
RUNTIME_ASSERT(args.length() == 4 || args.length() == 5);
Handle<Object> object = args.at<Object>(0);
Handle<Object> key = args.at<Object>(1);
Handle<Object> value = args.at<Object>(2);
CONVERT_SMI_CHECKED(unchecked_attributes, args[3]);
RUNTIME_ASSERT(
(unchecked_attributes & ~(READ_ONLY | DONT_ENUM | DONT_DELETE)) == 0);
// Compute attributes.
PropertyAttributes attributes =
static_cast<PropertyAttributes>(unchecked_attributes);
StrictModeFlag strict_mode = kNonStrictMode;
if (args.length() == 5) {
CONVERT_SMI_CHECKED(strict_unchecked, args[4]);
RUNTIME_ASSERT(strict_unchecked == kStrictMode ||
strict_unchecked == kNonStrictMode);
strict_mode = static_cast<StrictModeFlag>(strict_unchecked);
}
return Runtime::SetObjectProperty(isolate,
object,
key,
value,
attributes,
strict_mode);
}
// Set a local property, even if it is READ_ONLY. If the property does not
// exist, it will be added with attributes NONE.
static MaybeObject* Runtime_IgnoreAttributesAndSetProperty(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
RUNTIME_ASSERT(args.length() == 3 || args.length() == 4);
CONVERT_CHECKED(JSObject, object, args[0]);
CONVERT_CHECKED(String, name, args[1]);
// Compute attributes.
PropertyAttributes attributes = NONE;
if (args.length() == 4) {
CONVERT_CHECKED(Smi, value_obj, args[3]);
int unchecked_value = value_obj->value();
// Only attribute bits should be set.
RUNTIME_ASSERT(
(unchecked_value & ~(READ_ONLY | DONT_ENUM | DONT_DELETE)) == 0);
attributes = static_cast<PropertyAttributes>(unchecked_value);
}
return object->
SetLocalPropertyIgnoreAttributes(name, args[2], attributes);
}
static MaybeObject* Runtime_DeleteProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_CHECKED(JSObject, object, args[0]);
CONVERT_CHECKED(String, key, args[1]);
CONVERT_SMI_CHECKED(strict, args[2]);
return object->DeleteProperty(key, (strict == kStrictMode)
? JSObject::STRICT_DELETION
: JSObject::NORMAL_DELETION);
}
static Object* HasLocalPropertyImplementation(Isolate* isolate,
Handle<JSObject> object,
Handle<String> key) {
if (object->HasLocalProperty(*key)) return isolate->heap()->true_value();
// Handle hidden prototypes. If there's a hidden prototype above this thing
// then we have to check it for properties, because they are supposed to
// look like they are on this object.
Handle<Object> proto(object->GetPrototype());
if (proto->IsJSObject() &&
Handle<JSObject>::cast(proto)->map()->is_hidden_prototype()) {
return HasLocalPropertyImplementation(isolate,
Handle<JSObject>::cast(proto),
key);
}
return isolate->heap()->false_value();
}
static MaybeObject* Runtime_HasLocalProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, key, args[1]);
Object* obj = args[0];
// Only JS objects can have properties.
if (obj->IsJSObject()) {
JSObject* object = JSObject::cast(obj);
// Fast case - no interceptors.
if (object->HasRealNamedProperty(key)) return isolate->heap()->true_value();
// Slow case. Either it's not there or we have an interceptor. We should
// have handles for this kind of deal.
HandleScope scope(isolate);
return HasLocalPropertyImplementation(isolate,
Handle<JSObject>(object),
Handle<String>(key));
} else if (obj->IsString()) {
// Well, there is one exception: Handle [] on strings.
uint32_t index;
if (key->AsArrayIndex(&index)) {
String* string = String::cast(obj);
if (index < static_cast<uint32_t>(string->length()))
return isolate->heap()->true_value();
}
}
return isolate->heap()->false_value();
}
static MaybeObject* Runtime_HasProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation na;
ASSERT(args.length() == 2);
// Only JS objects can have properties.
if (args[0]->IsJSObject()) {
JSObject* object = JSObject::cast(args[0]);
CONVERT_CHECKED(String, key, args[1]);
if (object->HasProperty(key)) return isolate->heap()->true_value();
}
return isolate->heap()->false_value();
}
static MaybeObject* Runtime_HasElement(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation na;
ASSERT(args.length() == 2);
// Only JS objects can have elements.
if (args[0]->IsJSObject()) {
JSObject* object = JSObject::cast(args[0]);
CONVERT_CHECKED(Smi, index_obj, args[1]);
uint32_t index = index_obj->value();
if (object->HasElement(index)) return isolate->heap()->true_value();
}
return isolate->heap()->false_value();
}
static MaybeObject* Runtime_IsPropertyEnumerable(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSObject, object, args[0]);
CONVERT_CHECKED(String, key, args[1]);
uint32_t index;
if (key->AsArrayIndex(&index)) {
return isolate->heap()->ToBoolean(object->HasElement(index));
}
PropertyAttributes att = object->GetLocalPropertyAttribute(key);
return isolate->heap()->ToBoolean(att != ABSENT && (att & DONT_ENUM) == 0);
}
static MaybeObject* Runtime_GetPropertyNames(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSObject, object, 0);
return *GetKeysFor(object);
}
// Returns either a FixedArray as Runtime_GetPropertyNames,
// or, if the given object has an enum cache that contains
// all enumerable properties of the object and its prototypes
// have none, the map of the object. This is used to speed up
// the check for deletions during a for-in.
static MaybeObject* Runtime_GetPropertyNamesFast(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSObject, raw_object, args[0]);
if (raw_object->IsSimpleEnum()) return raw_object->map();
HandleScope scope(isolate);
Handle<JSObject> object(raw_object);
Handle<FixedArray> content = GetKeysInFixedArrayFor(object,
INCLUDE_PROTOS);
// Test again, since cache may have been built by preceding call.
if (object->IsSimpleEnum()) return object->map();
return *content;
}
// Find the length of the prototype chain that is to to handled as one. If a
// prototype object is hidden it is to be viewed as part of the the object it
// is prototype for.
static int LocalPrototypeChainLength(JSObject* obj) {
int count = 1;
Object* proto = obj->GetPrototype();
while (proto->IsJSObject() &&
JSObject::cast(proto)->map()->is_hidden_prototype()) {
count++;
proto = JSObject::cast(proto)->GetPrototype();
}
return count;
}
// Return the names of the local named properties.
// args[0]: object
static MaybeObject* Runtime_GetLocalPropertyNames(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
if (!args[0]->IsJSObject()) {
return isolate->heap()->undefined_value();
}
CONVERT_ARG_CHECKED(JSObject, obj, 0);
// Skip the global proxy as it has no properties and always delegates to the
// real global object.
if (obj->IsJSGlobalProxy()) {
// Only collect names if access is permitted.
if (obj->IsAccessCheckNeeded() &&
!isolate->MayNamedAccess(*obj,
isolate->heap()->undefined_value(),
v8::ACCESS_KEYS)) {
isolate->ReportFailedAccessCheck(*obj, v8::ACCESS_KEYS);
return *isolate->factory()->NewJSArray(0);
}
obj = Handle<JSObject>(JSObject::cast(obj->GetPrototype()));
}
// Find the number of objects making up this.
int length = LocalPrototypeChainLength(*obj);
// Find the number of local properties for each of the objects.
ScopedVector<int> local_property_count(length);
int total_property_count = 0;
Handle<JSObject> jsproto = obj;
for (int i = 0; i < length; i++) {
// Only collect names if access is permitted.
if (jsproto->IsAccessCheckNeeded() &&
!isolate->MayNamedAccess(*jsproto,
isolate->heap()->undefined_value(),
v8::ACCESS_KEYS)) {
isolate->ReportFailedAccessCheck(*jsproto, v8::ACCESS_KEYS);
return *isolate->factory()->NewJSArray(0);
}
int n;
n = jsproto->NumberOfLocalProperties(static_cast<PropertyAttributes>(NONE));
local_property_count[i] = n;
total_property_count += n;
if (i < length - 1) {
jsproto = Handle<JSObject>(JSObject::cast(jsproto->GetPrototype()));
}
}
// Allocate an array with storage for all the property names.
Handle<FixedArray> names =
isolate->factory()->NewFixedArray(total_property_count);
// Get the property names.
jsproto = obj;
int proto_with_hidden_properties = 0;
for (int i = 0; i < length; i++) {
jsproto->GetLocalPropertyNames(*names,
i == 0 ? 0 : local_property_count[i - 1]);
if (!GetHiddenProperties(jsproto, false)->IsUndefined()) {
proto_with_hidden_properties++;
}
if (i < length - 1) {
jsproto = Handle<JSObject>(JSObject::cast(jsproto->GetPrototype()));
}
}
// Filter out name of hidden propeties object.
if (proto_with_hidden_properties > 0) {
Handle<FixedArray> old_names = names;
names = isolate->factory()->NewFixedArray(
names->length() - proto_with_hidden_properties);
int dest_pos = 0;
for (int i = 0; i < total_property_count; i++) {
Object* name = old_names->get(i);
if (name == isolate->heap()->hidden_symbol()) {
continue;
}
names->set(dest_pos++, name);
}
}
return *isolate->factory()->NewJSArrayWithElements(names);
}
// Return the names of the local indexed properties.
// args[0]: object
static MaybeObject* Runtime_GetLocalElementNames(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
if (!args[0]->IsJSObject()) {
return isolate->heap()->undefined_value();
}
CONVERT_ARG_CHECKED(JSObject, obj, 0);
int n = obj->NumberOfLocalElements(static_cast<PropertyAttributes>(NONE));
Handle<FixedArray> names = isolate->factory()->NewFixedArray(n);
obj->GetLocalElementKeys(*names, static_cast<PropertyAttributes>(NONE));
return *isolate->factory()->NewJSArrayWithElements(names);
}
// Return information on whether an object has a named or indexed interceptor.
// args[0]: object
static MaybeObject* Runtime_GetInterceptorInfo(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
if (!args[0]->IsJSObject()) {
return Smi::FromInt(0);
}
CONVERT_ARG_CHECKED(JSObject, obj, 0);
int result = 0;
if (obj->HasNamedInterceptor()) result |= 2;
if (obj->HasIndexedInterceptor()) result |= 1;
return Smi::FromInt(result);
}
// Return property names from named interceptor.
// args[0]: object
static MaybeObject* Runtime_GetNamedInterceptorPropertyNames(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
if (obj->HasNamedInterceptor()) {
v8::Handle<v8::Array> result = GetKeysForNamedInterceptor(obj, obj);
if (!result.IsEmpty()) return *v8::Utils::OpenHandle(*result);
}
return isolate->heap()->undefined_value();
}
// Return element names from indexed interceptor.
// args[0]: object
static MaybeObject* Runtime_GetIndexedInterceptorElementNames(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
if (obj->HasIndexedInterceptor()) {
v8::Handle<v8::Array> result = GetKeysForIndexedInterceptor(obj, obj);
if (!result.IsEmpty()) return *v8::Utils::OpenHandle(*result);
}
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_LocalKeys(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT_EQ(args.length(), 1);
CONVERT_CHECKED(JSObject, raw_object, args[0]);
HandleScope scope(isolate);
Handle<JSObject> object(raw_object);
if (object->IsJSGlobalProxy()) {
// Do access checks before going to the global object.
if (object->IsAccessCheckNeeded() &&
!isolate->MayNamedAccess(*object, isolate->heap()->undefined_value(),
v8::ACCESS_KEYS)) {
isolate->ReportFailedAccessCheck(*object, v8::ACCESS_KEYS);
return *isolate->factory()->NewJSArray(0);
}
Handle<Object> proto(object->GetPrototype());
// If proxy is detached we simply return an empty array.
if (proto->IsNull()) return *isolate->factory()->NewJSArray(0);
object = Handle<JSObject>::cast(proto);
}
Handle<FixedArray> contents = GetKeysInFixedArrayFor(object,
LOCAL_ONLY);
// Some fast paths through GetKeysInFixedArrayFor reuse a cached
// property array and since the result is mutable we have to create
// a fresh clone on each invocation.
int length = contents->length();
Handle<FixedArray> copy = isolate->factory()->NewFixedArray(length);
for (int i = 0; i < length; i++) {
Object* entry = contents->get(i);
if (entry->IsString()) {
copy->set(i, entry);
} else {
ASSERT(entry->IsNumber());
HandleScope scope(isolate);
Handle<Object> entry_handle(entry, isolate);
Handle<Object> entry_str =
isolate->factory()->NumberToString(entry_handle);
copy->set(i, *entry_str);
}
}
return *isolate->factory()->NewJSArrayWithElements(copy);
}
static MaybeObject* Runtime_GetArgumentsProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
// Compute the frame holding the arguments.
JavaScriptFrameIterator it;
it.AdvanceToArgumentsFrame();
JavaScriptFrame* frame = it.frame();
// Get the actual number of provided arguments.
const uint32_t n = frame->ComputeParametersCount();
// Try to convert the key to an index. If successful and within
// index return the the argument from the frame.
uint32_t index;
if (args[0]->ToArrayIndex(&index) && index < n) {
return frame->GetParameter(index);
}
// Convert the key to a string.
HandleScope scope(isolate);
bool exception = false;
Handle<Object> converted =
Execution::ToString(args.at<Object>(0), &exception);
if (exception) return Failure::Exception();
Handle<String> key = Handle<String>::cast(converted);
// Try to convert the string key into an array index.
if (key->AsArrayIndex(&index)) {
if (index < n) {
return frame->GetParameter(index);
} else {
return isolate->initial_object_prototype()->GetElement(index);
}
}
// Handle special arguments properties.
if (key->Equals(isolate->heap()->length_symbol())) return Smi::FromInt(n);
if (key->Equals(isolate->heap()->callee_symbol())) {
Object* function = frame->function();
if (function->IsJSFunction() &&
JSFunction::cast(function)->shared()->strict_mode()) {
return isolate->Throw(*isolate->factory()->NewTypeError(
"strict_arguments_callee", HandleVector<Object>(NULL, 0)));
}
return function;
}
// Lookup in the initial Object.prototype object.
return isolate->initial_object_prototype()->GetProperty(*key);
}
static MaybeObject* Runtime_ToFastProperties(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<Object> object = args.at<Object>(0);
if (object->IsJSObject()) {
Handle<JSObject> js_object = Handle<JSObject>::cast(object);
if (!js_object->HasFastProperties() && !js_object->IsGlobalObject()) {
MaybeObject* ok = js_object->TransformToFastProperties(0);
if (ok->IsRetryAfterGC()) return ok;
}
}
return *object;
}
static MaybeObject* Runtime_ToSlowProperties(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<Object> object = args.at<Object>(0);
if (object->IsJSObject() && !object->IsJSGlobalProxy()) {
Handle<JSObject> js_object = Handle<JSObject>::cast(object);
NormalizeProperties(js_object, CLEAR_INOBJECT_PROPERTIES, 0);
}
return *object;
}
static MaybeObject* Runtime_ToBool(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
return args[0]->ToBoolean();
}
// Returns the type string of a value; see ECMA-262, 11.4.3 (p 47).
// Possible optimizations: put the type string into the oddballs.
static MaybeObject* Runtime_Typeof(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
Object* obj = args[0];
if (obj->IsNumber()) return isolate->heap()->number_symbol();
HeapObject* heap_obj = HeapObject::cast(obj);
// typeof an undetectable object is 'undefined'
if (heap_obj->map()->is_undetectable()) {
return isolate->heap()->undefined_symbol();
}
InstanceType instance_type = heap_obj->map()->instance_type();
if (instance_type < FIRST_NONSTRING_TYPE) {
return isolate->heap()->string_symbol();
}
switch (instance_type) {
case ODDBALL_TYPE:
if (heap_obj->IsTrue() || heap_obj->IsFalse()) {
return isolate->heap()->boolean_symbol();
}
if (heap_obj->IsNull()) {
return isolate->heap()->object_symbol();
}
ASSERT(heap_obj->IsUndefined());
return isolate->heap()->undefined_symbol();
case JS_FUNCTION_TYPE: case JS_REGEXP_TYPE:
return isolate->heap()->function_symbol();
default:
// For any kind of object not handled above, the spec rule for
// host objects gives that it is okay to return "object"
return isolate->heap()->object_symbol();
}
}
static bool AreDigits(const char*s, int from, int to) {
for (int i = from; i < to; i++) {
if (s[i] < '0' || s[i] > '9') return false;
}
return true;
}
static int ParseDecimalInteger(const char*s, int from, int to) {
ASSERT(to - from < 10); // Overflow is not possible.
ASSERT(from < to);
int d = s[from] - '0';
for (int i = from + 1; i < to; i++) {
d = 10 * d + (s[i] - '0');
}
return d;
}
static MaybeObject* Runtime_StringToNumber(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(String, subject, args[0]);
subject->TryFlatten();
// Fast case: short integer or some sorts of junk values.
int len = subject->length();
if (subject->IsSeqAsciiString()) {
if (len == 0) return Smi::FromInt(0);
char const* data = SeqAsciiString::cast(subject)->GetChars();
bool minus = (data[0] == '-');
int start_pos = (minus ? 1 : 0);
if (start_pos == len) {
return isolate->heap()->nan_value();
} else if (data[start_pos] > '9') {
// Fast check for a junk value. A valid string may start from a
// whitespace, a sign ('+' or '-'), the decimal point, a decimal digit or
// the 'I' character ('Infinity'). All of that have codes not greater than
// '9' except 'I'.
if (data[start_pos] != 'I') {
return isolate->heap()->nan_value();
}
} else if (len - start_pos < 10 && AreDigits(data, start_pos, len)) {
// The maximal/minimal smi has 10 digits. If the string has less digits we
// know it will fit into the smi-data type.
int d = ParseDecimalInteger(data, start_pos, len);
if (minus) {
if (d == 0) return isolate->heap()->minus_zero_value();
d = -d;
} else if (!subject->HasHashCode() &&
len <= String::kMaxArrayIndexSize &&
(len == 1 || data[0] != '0')) {
// String hash is not calculated yet but all the data are present.
// Update the hash field to speed up sequential convertions.
uint32_t hash = StringHasher::MakeArrayIndexHash(d, len);
#ifdef DEBUG
subject->Hash(); // Force hash calculation.
ASSERT_EQ(static_cast<int>(subject->hash_field()),
static_cast<int>(hash));
#endif
subject->set_hash_field(hash);
}
return Smi::FromInt(d);
}
}
// Slower case.
return isolate->heap()->NumberFromDouble(StringToDouble(subject, ALLOW_HEX));
}
static MaybeObject* Runtime_StringFromCharCodeArray(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSArray, codes, args[0]);
int length = Smi::cast(codes->length())->value();
// Check if the string can be ASCII.
int i;
for (i = 0; i < length; i++) {
Object* element;
{ MaybeObject* maybe_element = codes->GetElement(i);
// We probably can't get an exception here, but just in order to enforce
// the checking of inputs in the runtime calls we check here.
if (!maybe_element->ToObject(&element)) return maybe_element;
}
CONVERT_NUMBER_CHECKED(int, chr, Int32, element);
if ((chr & 0xffff) > String::kMaxAsciiCharCode)
break;
}
MaybeObject* maybe_object = NULL;
if (i == length) { // The string is ASCII.
maybe_object = isolate->heap()->AllocateRawAsciiString(length);
} else { // The string is not ASCII.
maybe_object = isolate->heap()->AllocateRawTwoByteString(length);
}
Object* object = NULL;
if (!maybe_object->ToObject(&object)) return maybe_object;
String* result = String::cast(object);
for (int i = 0; i < length; i++) {
Object* element;
{ MaybeObject* maybe_element = codes->GetElement(i);
if (!maybe_element->ToObject(&element)) return maybe_element;
}
CONVERT_NUMBER_CHECKED(int, chr, Int32, element);
result->Set(i, chr & 0xffff);
}
return result;
}
// kNotEscaped is generated by the following:
//
// #!/bin/perl
// for (my $i = 0; $i < 256; $i++) {
// print "\n" if $i % 16 == 0;
// my $c = chr($i);
// my $escaped = 1;
// $escaped = 0 if $c =~ m#[A-Za-z0-9@*_+./-]#;
// print $escaped ? "0, " : "1, ";
// }
static bool IsNotEscaped(uint16_t character) {
// Only for 8 bit characters, the rest are always escaped (in a different way)
ASSERT(character < 256);
static const char kNotEscaped[256] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 0, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 1,
0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
};
return kNotEscaped[character] != 0;
}
static MaybeObject* Runtime_URIEscape(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
const char hex_chars[] = "0123456789ABCDEF";
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(String, source, args[0]);
source->TryFlatten();
int escaped_length = 0;
int length = source->length();
{
Access<StringInputBuffer> buffer(
isolate->runtime_state()->string_input_buffer());
buffer->Reset(source);
while (buffer->has_more()) {
uint16_t character = buffer->GetNext();
if (character >= 256) {
escaped_length += 6;
} else if (IsNotEscaped(character)) {
escaped_length++;
} else {
escaped_length += 3;
}
// We don't allow strings that are longer than a maximal length.
ASSERT(String::kMaxLength < 0x7fffffff - 6); // Cannot overflow.
if (escaped_length > String::kMaxLength) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
}
}
// No length change implies no change. Return original string if no change.
if (escaped_length == length) {
return source;
}
Object* o;
{ MaybeObject* maybe_o =
isolate->heap()->AllocateRawAsciiString(escaped_length);
if (!maybe_o->ToObject(&o)) return maybe_o;
}
String* destination = String::cast(o);
int dest_position = 0;
Access<StringInputBuffer> buffer(
isolate->runtime_state()->string_input_buffer());
buffer->Rewind();
while (buffer->has_more()) {
uint16_t chr = buffer->GetNext();
if (chr >= 256) {
destination->Set(dest_position, '%');
destination->Set(dest_position+1, 'u');
destination->Set(dest_position+2, hex_chars[chr >> 12]);
destination->Set(dest_position+3, hex_chars[(chr >> 8) & 0xf]);
destination->Set(dest_position+4, hex_chars[(chr >> 4) & 0xf]);
destination->Set(dest_position+5, hex_chars[chr & 0xf]);
dest_position += 6;
} else if (IsNotEscaped(chr)) {
destination->Set(dest_position, chr);
dest_position++;
} else {
destination->Set(dest_position, '%');
destination->Set(dest_position+1, hex_chars[chr >> 4]);
destination->Set(dest_position+2, hex_chars[chr & 0xf]);
dest_position += 3;
}
}
return destination;
}
static inline int TwoDigitHex(uint16_t character1, uint16_t character2) {
static const signed char kHexValue['g'] = {
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, -1, -1, -1, -1, -1, -1,
-1, 10, 11, 12, 13, 14, 15, -1, -1, -1, -1, -1, -1, -1, -1, -1,
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1,
-1, 10, 11, 12, 13, 14, 15 };
if (character1 > 'f') return -1;
int hi = kHexValue[character1];
if (hi == -1) return -1;
if (character2 > 'f') return -1;
int lo = kHexValue[character2];
if (lo == -1) return -1;
return (hi << 4) + lo;
}
static inline int Unescape(String* source,
int i,
int length,
int* step) {
uint16_t character = source->Get(i);
int32_t hi = 0;
int32_t lo = 0;
if (character == '%' &&
i <= length - 6 &&
source->Get(i + 1) == 'u' &&
(hi = TwoDigitHex(source->Get(i + 2),
source->Get(i + 3))) != -1 &&
(lo = TwoDigitHex(source->Get(i + 4),
source->Get(i + 5))) != -1) {
*step = 6;
return (hi << 8) + lo;
} else if (character == '%' &&
i <= length - 3 &&
(lo = TwoDigitHex(source->Get(i + 1),
source->Get(i + 2))) != -1) {
*step = 3;
return lo;
} else {
*step = 1;
return character;
}
}
static MaybeObject* Runtime_URIUnescape(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(String, source, args[0]);
source->TryFlatten();
bool ascii = true;
int length = source->length();
int unescaped_length = 0;
for (int i = 0; i < length; unescaped_length++) {
int step;
if (Unescape(source, i, length, &step) > String::kMaxAsciiCharCode) {
ascii = false;
}
i += step;
}
// No length change implies no change. Return original string if no change.
if (unescaped_length == length)
return source;
Object* o;
{ MaybeObject* maybe_o =
ascii ?
isolate->heap()->AllocateRawAsciiString(unescaped_length) :
isolate->heap()->AllocateRawTwoByteString(unescaped_length);
if (!maybe_o->ToObject(&o)) return maybe_o;
}
String* destination = String::cast(o);
int dest_position = 0;
for (int i = 0; i < length; dest_position++) {
int step;
destination->Set(dest_position, Unescape(source, i, length, &step));
i += step;
}
return destination;
}
static const unsigned int kQuoteTableLength = 128u;
static const int kJsonQuotesCharactersPerEntry = 8;
static const char* const JsonQuotes =
"\\u0000 \\u0001 \\u0002 \\u0003 "
"\\u0004 \\u0005 \\u0006 \\u0007 "
"\\b \\t \\n \\u000b "
"\\f \\r \\u000e \\u000f "
"\\u0010 \\u0011 \\u0012 \\u0013 "
"\\u0014 \\u0015 \\u0016 \\u0017 "
"\\u0018 \\u0019 \\u001a \\u001b "
"\\u001c \\u001d \\u001e \\u001f "
" ! \\\" # "
"$ % & ' "
"( ) * + "
", - . / "
"0 1 2 3 "
"4 5 6 7 "
"8 9 : ; "
"< = > ? "
"@ A B C "
"D E F G "
"H I J K "
"L M N O "
"P Q R S "
"T U V W "
"X Y Z [ "
"\\\\ ] ^ _ "
"` a b c "
"d e f g "
"h i j k "
"l m n o "
"p q r s "
"t u v w "
"x y z { "
"| } ~ \177 ";
// For a string that is less than 32k characters it should always be
// possible to allocate it in new space.
static const int kMaxGuaranteedNewSpaceString = 32 * 1024;
// Doing JSON quoting cannot make the string more than this many times larger.
static const int kJsonQuoteWorstCaseBlowup = 6;
// Covers the entire ASCII range (all other characters are unchanged by JSON
// quoting).
static const byte JsonQuoteLengths[kQuoteTableLength] = {
6, 6, 6, 6, 6, 6, 6, 6,
2, 2, 2, 6, 2, 2, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6,
1, 1, 2, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 2, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1,
};
template <typename StringType>
MaybeObject* AllocateRawString(Isolate* isolate, int length);
template <>
MaybeObject* AllocateRawString<SeqTwoByteString>(Isolate* isolate, int length) {
return isolate->heap()->AllocateRawTwoByteString(length);
}
template <>
MaybeObject* AllocateRawString<SeqAsciiString>(Isolate* isolate, int length) {
return isolate->heap()->AllocateRawAsciiString(length);
}
template <typename Char, typename StringType, bool comma>
static MaybeObject* SlowQuoteJsonString(Isolate* isolate,
Vector<const Char> characters) {
int length = characters.length();
const Char* read_cursor = characters.start();
const Char* end = read_cursor + length;
const int kSpaceForQuotes = 2 + (comma ? 1 :0);
int quoted_length = kSpaceForQuotes;
while (read_cursor < end) {
Char c = *(read_cursor++);
if (sizeof(Char) > 1u && static_cast<unsigned>(c) >= kQuoteTableLength) {
quoted_length++;
} else {
quoted_length += JsonQuoteLengths[static_cast<unsigned>(c)];
}
}
MaybeObject* new_alloc = AllocateRawString<StringType>(isolate,
quoted_length);
Object* new_object;
if (!new_alloc->ToObject(&new_object)) {
return new_alloc;
}
StringType* new_string = StringType::cast(new_object);
Char* write_cursor = reinterpret_cast<Char*>(
new_string->address() + SeqAsciiString::kHeaderSize);
if (comma) *(write_cursor++) = ',';
*(write_cursor++) = '"';
read_cursor = characters.start();
while (read_cursor < end) {
Char c = *(read_cursor++);
if (sizeof(Char) > 1u && static_cast<unsigned>(c) >= kQuoteTableLength) {
*(write_cursor++) = c;
} else {
int len = JsonQuoteLengths[static_cast<unsigned>(c)];
const char* replacement = JsonQuotes +
static_cast<unsigned>(c) * kJsonQuotesCharactersPerEntry;
for (int i = 0; i < len; i++) {
*write_cursor++ = *replacement++;
}
}
}
*(write_cursor++) = '"';
return new_string;
}
template <typename Char, typename StringType, bool comma>
static MaybeObject* QuoteJsonString(Isolate* isolate,
Vector<const Char> characters) {
int length = characters.length();
isolate->counters()->quote_json_char_count()->Increment(length);
const int kSpaceForQuotes = 2 + (comma ? 1 :0);
int worst_case_length = length * kJsonQuoteWorstCaseBlowup + kSpaceForQuotes;
if (worst_case_length > kMaxGuaranteedNewSpaceString) {
return SlowQuoteJsonString<Char, StringType, comma>(isolate, characters);
}
MaybeObject* new_alloc = AllocateRawString<StringType>(isolate,
worst_case_length);
Object* new_object;
if (!new_alloc->ToObject(&new_object)) {
return new_alloc;
}
if (!isolate->heap()->new_space()->Contains(new_object)) {
// Even if our string is small enough to fit in new space we still have to
// handle it being allocated in old space as may happen in the third
// attempt. See CALL_AND_RETRY in heap-inl.h and similar code in
// CEntryStub::GenerateCore.
return SlowQuoteJsonString<Char, StringType, comma>(isolate, characters);
}
StringType* new_string = StringType::cast(new_object);
ASSERT(isolate->heap()->new_space()->Contains(new_string));
STATIC_ASSERT(SeqTwoByteString::kHeaderSize == SeqAsciiString::kHeaderSize);
Char* write_cursor = reinterpret_cast<Char*>(
new_string->address() + SeqAsciiString::kHeaderSize);
if (comma) *(write_cursor++) = ',';
*(write_cursor++) = '"';
const Char* read_cursor = characters.start();
const Char* end = read_cursor + length;
while (read_cursor < end) {
Char c = *(read_cursor++);
if (sizeof(Char) > 1u && static_cast<unsigned>(c) >= kQuoteTableLength) {
*(write_cursor++) = c;
} else {
int len = JsonQuoteLengths[static_cast<unsigned>(c)];
const char* replacement = JsonQuotes +
static_cast<unsigned>(c) * kJsonQuotesCharactersPerEntry;
write_cursor[0] = replacement[0];
if (len > 1) {
write_cursor[1] = replacement[1];
if (len > 2) {
ASSERT(len == 6);
write_cursor[2] = replacement[2];
write_cursor[3] = replacement[3];
write_cursor[4] = replacement[4];
write_cursor[5] = replacement[5];
}
}
write_cursor += len;
}
}
*(write_cursor++) = '"';
int final_length = static_cast<int>(
write_cursor - reinterpret_cast<Char*>(
new_string->address() + SeqAsciiString::kHeaderSize));
isolate->heap()->new_space()->ShrinkStringAtAllocationBoundary<StringType>(
new_string, final_length);
return new_string;
}
static MaybeObject* Runtime_QuoteJSONString(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
CONVERT_CHECKED(String, str, args[0]);
if (!str->IsFlat()) {
MaybeObject* try_flatten = str->TryFlatten();
Object* flat;
if (!try_flatten->ToObject(&flat)) {
return try_flatten;
}
str = String::cast(flat);
ASSERT(str->IsFlat());
}
if (str->IsTwoByteRepresentation()) {
return QuoteJsonString<uc16, SeqTwoByteString, false>(isolate,
str->ToUC16Vector());
} else {
return QuoteJsonString<char, SeqAsciiString, false>(isolate,
str->ToAsciiVector());
}
}
static MaybeObject* Runtime_QuoteJSONStringComma(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
CONVERT_CHECKED(String, str, args[0]);
if (!str->IsFlat()) {
MaybeObject* try_flatten = str->TryFlatten();
Object* flat;
if (!try_flatten->ToObject(&flat)) {
return try_flatten;
}
str = String::cast(flat);
ASSERT(str->IsFlat());
}
if (str->IsTwoByteRepresentation()) {
return QuoteJsonString<uc16, SeqTwoByteString, true>(isolate,
str->ToUC16Vector());
} else {
return QuoteJsonString<char, SeqAsciiString, true>(isolate,
str->ToAsciiVector());
}
}
static MaybeObject* Runtime_StringParseInt(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
CONVERT_CHECKED(String, s, args[0]);
CONVERT_SMI_CHECKED(radix, args[1]);
s->TryFlatten();
RUNTIME_ASSERT(radix == 0 || (2 <= radix && radix <= 36));
double value = StringToInt(s, radix);
return isolate->heap()->NumberFromDouble(value);
}
static MaybeObject* Runtime_StringParseFloat(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
CONVERT_CHECKED(String, str, args[0]);
// ECMA-262 section 15.1.2.3, empty string is NaN
double value = StringToDouble(str, ALLOW_TRAILING_JUNK, OS::nan_value());
// Create a number object from the value.
return isolate->heap()->NumberFromDouble(value);
}
template <class Converter>
MUST_USE_RESULT static MaybeObject* ConvertCaseHelper(
Isolate* isolate,
String* s,
int length,
int input_string_length,
unibrow::Mapping<Converter, 128>* mapping) {
// We try this twice, once with the assumption that the result is no longer
// than the input and, if that assumption breaks, again with the exact
// length. This may not be pretty, but it is nicer than what was here before
// and I hereby claim my vaffel-is.
//
// Allocate the resulting string.
//
// NOTE: This assumes that the upper/lower case of an ascii
// character is also ascii. This is currently the case, but it
// might break in the future if we implement more context and locale
// dependent upper/lower conversions.
Object* o;
{ MaybeObject* maybe_o = s->IsAsciiRepresentation()
? isolate->heap()->AllocateRawAsciiString(length)
: isolate->heap()->AllocateRawTwoByteString(length);
if (!maybe_o->ToObject(&o)) return maybe_o;
}
String* result = String::cast(o);
bool has_changed_character = false;
// Convert all characters to upper case, assuming that they will fit
// in the buffer
Access<StringInputBuffer> buffer(
isolate->runtime_state()->string_input_buffer());
buffer->Reset(s);
unibrow::uchar chars[Converter::kMaxWidth];
// We can assume that the string is not empty
uc32 current = buffer->GetNext();
for (int i = 0; i < length;) {
bool has_next = buffer->has_more();
uc32 next = has_next ? buffer->GetNext() : 0;
int char_length = mapping->get(current, next, chars);
if (char_length == 0) {
// The case conversion of this character is the character itself.
result->Set(i, current);
i++;
} else if (char_length == 1) {
// Common case: converting the letter resulted in one character.
ASSERT(static_cast<uc32>(chars[0]) != current);
result->Set(i, chars[0]);
has_changed_character = true;
i++;
} else if (length == input_string_length) {
// We've assumed that the result would be as long as the
// input but here is a character that converts to several
// characters. No matter, we calculate the exact length
// of the result and try the whole thing again.
//
// Note that this leaves room for optimization. We could just
// memcpy what we already have to the result string. Also,
// the result string is the last object allocated we could
// "realloc" it and probably, in the vast majority of cases,
// extend the existing string to be able to hold the full
// result.
int next_length = 0;
if (has_next) {
next_length = mapping->get(next, 0, chars);
if (next_length == 0) next_length = 1;
}
int current_length = i + char_length + next_length;
while (buffer->has_more()) {
current = buffer->GetNext();
// NOTE: we use 0 as the next character here because, while
// the next character may affect what a character converts to,
// it does not in any case affect the length of what it convert
// to.
int char_length = mapping->get(current, 0, chars);
if (char_length == 0) char_length = 1;
current_length += char_length;
if (current_length > Smi::kMaxValue) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
}
// Try again with the real length.
return Smi::FromInt(current_length);
} else {
for (int j = 0; j < char_length; j++) {
result->Set(i, chars[j]);
i++;
}
has_changed_character = true;
}
current = next;
}
if (has_changed_character) {
return result;
} else {
// If we didn't actually change anything in doing the conversion
// we simple return the result and let the converted string
// become garbage; there is no reason to keep two identical strings
// alive.
return s;
}
}
namespace {
static const uintptr_t kOneInEveryByte = kUintptrAllBitsSet / 0xFF;
// Given a word and two range boundaries returns a word with high bit
// set in every byte iff the corresponding input byte was strictly in
// the range (m, n). All the other bits in the result are cleared.
// This function is only useful when it can be inlined and the
// boundaries are statically known.
// Requires: all bytes in the input word and the boundaries must be
// ascii (less than 0x7F).
static inline uintptr_t AsciiRangeMask(uintptr_t w, char m, char n) {
// Every byte in an ascii string is less than or equal to 0x7F.
ASSERT((w & (kOneInEveryByte * 0x7F)) == w);
// Use strict inequalities since in edge cases the function could be
// further simplified.
ASSERT(0 < m && m < n && n < 0x7F);
// Has high bit set in every w byte less than n.
uintptr_t tmp1 = kOneInEveryByte * (0x7F + n) - w;
// Has high bit set in every w byte greater than m.
uintptr_t tmp2 = w + kOneInEveryByte * (0x7F - m);
return (tmp1 & tmp2 & (kOneInEveryByte * 0x80));
}
enum AsciiCaseConversion {
ASCII_TO_LOWER,
ASCII_TO_UPPER
};
template <AsciiCaseConversion dir>
struct FastAsciiConverter {
static bool Convert(char* dst, char* src, int length) {
#ifdef DEBUG
char* saved_dst = dst;
char* saved_src = src;
#endif
// We rely on the distance between upper and lower case letters
// being a known power of 2.
ASSERT('a' - 'A' == (1 << 5));
// Boundaries for the range of input characters than require conversion.
const char lo = (dir == ASCII_TO_LOWER) ? 'A' - 1 : 'a' - 1;
const char hi = (dir == ASCII_TO_LOWER) ? 'Z' + 1 : 'z' + 1;
bool changed = false;
char* const limit = src + length;
#ifdef V8_HOST_CAN_READ_UNALIGNED
// Process the prefix of the input that requires no conversion one
// (machine) word at a time.
while (src <= limit - sizeof(uintptr_t)) {
uintptr_t w = *reinterpret_cast<uintptr_t*>(src);
if (AsciiRangeMask(w, lo, hi) != 0) {
changed = true;
break;
}
*reinterpret_cast<uintptr_t*>(dst) = w;
src += sizeof(uintptr_t);
dst += sizeof(uintptr_t);
}
// Process the remainder of the input performing conversion when
// required one word at a time.
while (src <= limit - sizeof(uintptr_t)) {
uintptr_t w = *reinterpret_cast<uintptr_t*>(src);
uintptr_t m = AsciiRangeMask(w, lo, hi);
// The mask has high (7th) bit set in every byte that needs
// conversion and we know that the distance between cases is
// 1 << 5.
*reinterpret_cast<uintptr_t*>(dst) = w ^ (m >> 2);
src += sizeof(uintptr_t);
dst += sizeof(uintptr_t);
}
#endif
// Process the last few bytes of the input (or the whole input if
// unaligned access is not supported).
while (src < limit) {
char c = *src;
if (lo < c && c < hi) {
c ^= (1 << 5);
changed = true;
}
*dst = c;
++src;
++dst;
}
#ifdef DEBUG
CheckConvert(saved_dst, saved_src, length, changed);
#endif
return changed;
}
#ifdef DEBUG
static void CheckConvert(char* dst, char* src, int length, bool changed) {
bool expected_changed = false;
for (int i = 0; i < length; i++) {
if (dst[i] == src[i]) continue;
expected_changed = true;
if (dir == ASCII_TO_LOWER) {
ASSERT('A' <= src[i] && src[i] <= 'Z');
ASSERT(dst[i] == src[i] + ('a' - 'A'));
} else {
ASSERT(dir == ASCII_TO_UPPER);
ASSERT('a' <= src[i] && src[i] <= 'z');
ASSERT(dst[i] == src[i] - ('a' - 'A'));
}
}
ASSERT(expected_changed == changed);
}
#endif
};
struct ToLowerTraits {
typedef unibrow::ToLowercase UnibrowConverter;
typedef FastAsciiConverter<ASCII_TO_LOWER> AsciiConverter;
};
struct ToUpperTraits {
typedef unibrow::ToUppercase UnibrowConverter;
typedef FastAsciiConverter<ASCII_TO_UPPER> AsciiConverter;
};
} // namespace
template <typename ConvertTraits>
MUST_USE_RESULT static MaybeObject* ConvertCase(
Arguments args,
Isolate* isolate,
unibrow::Mapping<typename ConvertTraits::UnibrowConverter, 128>* mapping) {
NoHandleAllocation ha;
CONVERT_CHECKED(String, s, args[0]);
s = s->TryFlattenGetString();
const int length = s->length();
// Assume that the string is not empty; we need this assumption later
if (length == 0) return s;
// Simpler handling of ascii strings.
//
// NOTE: This assumes that the upper/lower case of an ascii
// character is also ascii. This is currently the case, but it
// might break in the future if we implement more context and locale
// dependent upper/lower conversions.
if (s->IsSeqAsciiString()) {
Object* o;
{ MaybeObject* maybe_o = isolate->heap()->AllocateRawAsciiString(length);
if (!maybe_o->ToObject(&o)) return maybe_o;
}
SeqAsciiString* result = SeqAsciiString::cast(o);
bool has_changed_character = ConvertTraits::AsciiConverter::Convert(
result->GetChars(), SeqAsciiString::cast(s)->GetChars(), length);
return has_changed_character ? result : s;
}
Object* answer;
{ MaybeObject* maybe_answer =
ConvertCaseHelper(isolate, s, length, length, mapping);
if (!maybe_answer->ToObject(&answer)) return maybe_answer;
}
if (answer->IsSmi()) {
// Retry with correct length.
{ MaybeObject* maybe_answer =
ConvertCaseHelper(isolate,
s, Smi::cast(answer)->value(), length, mapping);
if (!maybe_answer->ToObject(&answer)) return maybe_answer;
}
}
return answer;
}
static MaybeObject* Runtime_StringToLowerCase(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
return ConvertCase<ToLowerTraits>(
args, isolate, isolate->runtime_state()->to_lower_mapping());
}
static MaybeObject* Runtime_StringToUpperCase(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
return ConvertCase<ToUpperTraits>(
args, isolate, isolate->runtime_state()->to_upper_mapping());
}
static inline bool IsTrimWhiteSpace(unibrow::uchar c) {
return unibrow::WhiteSpace::Is(c) || c == 0x200b;
}
static MaybeObject* Runtime_StringTrim(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_CHECKED(String, s, args[0]);
CONVERT_BOOLEAN_CHECKED(trimLeft, args[1]);
CONVERT_BOOLEAN_CHECKED(trimRight, args[2]);
s->TryFlatten();
int length = s->length();
int left = 0;
if (trimLeft) {
while (left < length && IsTrimWhiteSpace(s->Get(left))) {
left++;
}
}
int right = length;
if (trimRight) {
while (right > left && IsTrimWhiteSpace(s->Get(right - 1))) {
right--;
}
}
return s->SubString(left, right);
}
template <typename SubjectChar, typename PatternChar>
void FindStringIndices(Isolate* isolate,
Vector<const SubjectChar> subject,
Vector<const PatternChar> pattern,
ZoneList<int>* indices,
unsigned int limit) {
ASSERT(limit > 0);
// Collect indices of pattern in subject, and the end-of-string index.
// Stop after finding at most limit values.
StringSearch<PatternChar, SubjectChar> search(isolate, pattern);
int pattern_length = pattern.length();
int index = 0;
while (limit > 0) {
index = search.Search(subject, index);
if (index < 0) return;
indices->Add(index);
index += pattern_length;
limit--;
}
}
static MaybeObject* Runtime_StringSplit(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 3);
HandleScope handle_scope(isolate);
CONVERT_ARG_CHECKED(String, subject, 0);
CONVERT_ARG_CHECKED(String, pattern, 1);
CONVERT_NUMBER_CHECKED(uint32_t, limit, Uint32, args[2]);
int subject_length = subject->length();
int pattern_length = pattern->length();
RUNTIME_ASSERT(pattern_length > 0);
// The limit can be very large (0xffffffffu), but since the pattern
// isn't empty, we can never create more parts than ~half the length
// of the subject.
if (!subject->IsFlat()) FlattenString(subject);
static const int kMaxInitialListCapacity = 16;
ZoneScope scope(DELETE_ON_EXIT);
// Find (up to limit) indices of separator and end-of-string in subject
int initial_capacity = Min<uint32_t>(kMaxInitialListCapacity, limit);
ZoneList<int> indices(initial_capacity);
if (!pattern->IsFlat()) FlattenString(pattern);
// No allocation block.
{
AssertNoAllocation nogc;
if (subject->IsAsciiRepresentation()) {
Vector<const char> subject_vector = subject->ToAsciiVector();
if (pattern->IsAsciiRepresentation()) {
FindStringIndices(isolate,
subject_vector,
pattern->ToAsciiVector(),
&indices,
limit);
} else {
FindStringIndices(isolate,
subject_vector,
pattern->ToUC16Vector(),
&indices,
limit);
}
} else {
Vector<const uc16> subject_vector = subject->ToUC16Vector();
if (pattern->IsAsciiRepresentation()) {
FindStringIndices(isolate,
subject_vector,
pattern->ToAsciiVector(),
&indices,
limit);
} else {
FindStringIndices(isolate,
subject_vector,
pattern->ToUC16Vector(),
&indices,
limit);
}
}
}
if (static_cast<uint32_t>(indices.length()) < limit) {
indices.Add(subject_length);
}
// The list indices now contains the end of each part to create.
// Create JSArray of substrings separated by separator.
int part_count = indices.length();
Handle<JSArray> result = isolate->factory()->NewJSArray(part_count);
result->set_length(Smi::FromInt(part_count));
ASSERT(result->HasFastElements());
if (part_count == 1 && indices.at(0) == subject_length) {
FixedArray::cast(result->elements())->set(0, *subject);
return *result;
}
Handle<FixedArray> elements(FixedArray::cast(result->elements()));
int part_start = 0;
for (int i = 0; i < part_count; i++) {
HandleScope local_loop_handle;
int part_end = indices.at(i);
Handle<String> substring =
isolate->factory()->NewSubString(subject, part_start, part_end);
elements->set(i, *substring);
part_start = part_end + pattern_length;
}
return *result;
}
// Copies ascii characters to the given fixed array looking up
// one-char strings in the cache. Gives up on the first char that is
// not in the cache and fills the remainder with smi zeros. Returns
// the length of the successfully copied prefix.
static int CopyCachedAsciiCharsToArray(Heap* heap,
const char* chars,
FixedArray* elements,
int length) {
AssertNoAllocation nogc;
FixedArray* ascii_cache = heap->single_character_string_cache();
Object* undefined = heap->undefined_value();
int i;
for (i = 0; i < length; ++i) {
Object* value = ascii_cache->get(chars[i]);
if (value == undefined) break;
ASSERT(!heap->InNewSpace(value));
elements->set(i, value, SKIP_WRITE_BARRIER);
}
if (i < length) {
ASSERT(Smi::FromInt(0) == 0);
memset(elements->data_start() + i, 0, kPointerSize * (length - i));
}
#ifdef DEBUG
for (int j = 0; j < length; ++j) {
Object* element = elements->get(j);
ASSERT(element == Smi::FromInt(0) ||
(element->IsString() && String::cast(element)->LooksValid()));
}
#endif
return i;
}
// Converts a String to JSArray.
// For example, "foo" => ["f", "o", "o"].
static MaybeObject* Runtime_StringToArray(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(String, s, 0);
CONVERT_NUMBER_CHECKED(uint32_t, limit, Uint32, args[1]);
s->TryFlatten();
const int length = static_cast<int>(Min<uint32_t>(s->length(), limit));
Handle<FixedArray> elements;
if (s->IsFlat() && s->IsAsciiRepresentation()) {
Object* obj;
{ MaybeObject* maybe_obj =
isolate->heap()->AllocateUninitializedFixedArray(length);
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
elements = Handle<FixedArray>(FixedArray::cast(obj), isolate);
Vector<const char> chars = s->ToAsciiVector();
// Note, this will initialize all elements (not only the prefix)
// to prevent GC from seeing partially initialized array.
int num_copied_from_cache = CopyCachedAsciiCharsToArray(isolate->heap(),
chars.start(),
*elements,
length);
for (int i = num_copied_from_cache; i < length; ++i) {
Handle<Object> str = LookupSingleCharacterStringFromCode(chars[i]);
elements->set(i, *str);
}
} else {
elements = isolate->factory()->NewFixedArray(length);
for (int i = 0; i < length; ++i) {
Handle<Object> str = LookupSingleCharacterStringFromCode(s->Get(i));
elements->set(i, *str);
}
}
#ifdef DEBUG
for (int i = 0; i < length; ++i) {
ASSERT(String::cast(elements->get(i))->length() == 1);
}
#endif
return *isolate->factory()->NewJSArrayWithElements(elements);
}
static MaybeObject* Runtime_NewStringWrapper(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(String, value, args[0]);
return value->ToObject();
}
bool Runtime::IsUpperCaseChar(RuntimeState* runtime_state, uint16_t ch) {
unibrow::uchar chars[unibrow::ToUppercase::kMaxWidth];
int char_length = runtime_state->to_upper_mapping()->get(ch, 0, chars);
return char_length == 0;
}
static MaybeObject* Runtime_NumberToString(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
Object* number = args[0];
RUNTIME_ASSERT(number->IsNumber());
return isolate->heap()->NumberToString(number);
}
static MaybeObject* Runtime_NumberToStringSkipCache(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
Object* number = args[0];
RUNTIME_ASSERT(number->IsNumber());
return isolate->heap()->NumberToString(number, false);
}
static MaybeObject* Runtime_NumberToInteger(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_DOUBLE_CHECKED(number, args[0]);
// We do not include 0 so that we don't have to treat +0 / -0 cases.
if (number > 0 && number <= Smi::kMaxValue) {
return Smi::FromInt(static_cast<int>(number));
}
return isolate->heap()->NumberFromDouble(DoubleToInteger(number));
}
static MaybeObject* Runtime_NumberToIntegerMapMinusZero(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_DOUBLE_CHECKED(number, args[0]);
// We do not include 0 so that we don't have to treat +0 / -0 cases.
if (number > 0 && number <= Smi::kMaxValue) {
return Smi::FromInt(static_cast<int>(number));
}
double double_value = DoubleToInteger(number);
// Map both -0 and +0 to +0.
if (double_value == 0) double_value = 0;
return isolate->heap()->NumberFromDouble(double_value);
}
static MaybeObject* Runtime_NumberToJSUint32(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_NUMBER_CHECKED(int32_t, number, Uint32, args[0]);
return isolate->heap()->NumberFromUint32(number);
}
static MaybeObject* Runtime_NumberToJSInt32(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_DOUBLE_CHECKED(number, args[0]);
// We do not include 0 so that we don't have to treat +0 / -0 cases.
if (number > 0 && number <= Smi::kMaxValue) {
return Smi::FromInt(static_cast<int>(number));
}
return isolate->heap()->NumberFromInt32(DoubleToInt32(number));
}
// Converts a Number to a Smi, if possible. Returns NaN if the number is not
// a small integer.
static MaybeObject* Runtime_NumberToSmi(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
Object* obj = args[0];
if (obj->IsSmi()) {
return obj;
}
if (obj->IsHeapNumber()) {
double value = HeapNumber::cast(obj)->value();
int int_value = FastD2I(value);
if (value == FastI2D(int_value) && Smi::IsValid(int_value)) {
return Smi::FromInt(int_value);
}
}
return isolate->heap()->nan_value();
}
static MaybeObject* Runtime_AllocateHeapNumber(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 0);
return isolate->heap()->AllocateHeapNumber(0);
}
static MaybeObject* Runtime_NumberAdd(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
return isolate->heap()->NumberFromDouble(x + y);
}
static MaybeObject* Runtime_NumberSub(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
return isolate->heap()->NumberFromDouble(x - y);
}
static MaybeObject* Runtime_NumberMul(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
return isolate->heap()->NumberFromDouble(x * y);
}
static MaybeObject* Runtime_NumberUnaryMinus(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->heap()->NumberFromDouble(-x);
}
static MaybeObject* Runtime_NumberAlloc(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 0);
return isolate->heap()->NumberFromDouble(9876543210.0);
}
static MaybeObject* Runtime_NumberDiv(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
return isolate->heap()->NumberFromDouble(x / y);
}
static MaybeObject* Runtime_NumberMod(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
x = modulo(x, y);
// NumberFromDouble may return a Smi instead of a Number object
return isolate->heap()->NumberFromDouble(x);
}
static MaybeObject* Runtime_StringAdd(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, str1, args[0]);
CONVERT_CHECKED(String, str2, args[1]);
isolate->counters()->string_add_runtime()->Increment();
return isolate->heap()->AllocateConsString(str1, str2);
}
template <typename sinkchar>
static inline void StringBuilderConcatHelper(String* special,
sinkchar* sink,
FixedArray* fixed_array,
int array_length) {
int position = 0;
for (int i = 0; i < array_length; i++) {
Object* element = fixed_array->get(i);
if (element->IsSmi()) {
// Smi encoding of position and length.
int encoded_slice = Smi::cast(element)->value();
int pos;
int len;
if (encoded_slice > 0) {
// Position and length encoded in one smi.
pos = StringBuilderSubstringPosition::decode(encoded_slice);
len = StringBuilderSubstringLength::decode(encoded_slice);
} else {
// Position and length encoded in two smis.
Object* obj = fixed_array->get(++i);
ASSERT(obj->IsSmi());
pos = Smi::cast(obj)->value();
len = -encoded_slice;
}
String::WriteToFlat(special,
sink + position,
pos,
pos + len);
position += len;
} else {
String* string = String::cast(element);
int element_length = string->length();
String::WriteToFlat(string, sink + position, 0, element_length);
position += element_length;
}
}
}
static MaybeObject* Runtime_StringBuilderConcat(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_CHECKED(JSArray, array, args[0]);
if (!args[1]->IsSmi()) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
int array_length = Smi::cast(args[1])->value();
CONVERT_CHECKED(String, special, args[2]);
// This assumption is used by the slice encoding in one or two smis.
ASSERT(Smi::kMaxValue >= String::kMaxLength);
int special_length = special->length();
if (!array->HasFastElements()) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
FixedArray* fixed_array = FixedArray::cast(array->elements());
if (fixed_array->length() < array_length) {
array_length = fixed_array->length();
}
if (array_length == 0) {
return isolate->heap()->empty_string();
} else if (array_length == 1) {
Object* first = fixed_array->get(0);
if (first->IsString()) return first;
}
bool ascii = special->HasOnlyAsciiChars();
int position = 0;
for (int i = 0; i < array_length; i++) {
int increment = 0;
Object* elt = fixed_array->get(i);
if (elt->IsSmi()) {
// Smi encoding of position and length.
int smi_value = Smi::cast(elt)->value();
int pos;
int len;
if (smi_value > 0) {
// Position and length encoded in one smi.
pos = StringBuilderSubstringPosition::decode(smi_value);
len = StringBuilderSubstringLength::decode(smi_value);
} else {
// Position and length encoded in two smis.
len = -smi_value;
// Get the position and check that it is a positive smi.
i++;
if (i >= array_length) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
Object* next_smi = fixed_array->get(i);
if (!next_smi->IsSmi()) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
pos = Smi::cast(next_smi)->value();
if (pos < 0) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
}
ASSERT(pos >= 0);
ASSERT(len >= 0);
if (pos > special_length || len > special_length - pos) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
increment = len;
} else if (elt->IsString()) {
String* element = String::cast(elt);
int element_length = element->length();
increment = element_length;
if (ascii && !element->HasOnlyAsciiChars()) {
ascii = false;
}
} else {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
if (increment > String::kMaxLength - position) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
position += increment;
}
int length = position;
Object* object;
if (ascii) {
{ MaybeObject* maybe_object =
isolate->heap()->AllocateRawAsciiString(length);
if (!maybe_object->ToObject(&object)) return maybe_object;
}
SeqAsciiString* answer = SeqAsciiString::cast(object);
StringBuilderConcatHelper(special,
answer->GetChars(),
fixed_array,
array_length);
return answer;
} else {
{ MaybeObject* maybe_object =
isolate->heap()->AllocateRawTwoByteString(length);
if (!maybe_object->ToObject(&object)) return maybe_object;
}
SeqTwoByteString* answer = SeqTwoByteString::cast(object);
StringBuilderConcatHelper(special,
answer->GetChars(),
fixed_array,
array_length);
return answer;
}
}
static MaybeObject* Runtime_StringBuilderJoin(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_CHECKED(JSArray, array, args[0]);
if (!args[1]->IsSmi()) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
int array_length = Smi::cast(args[1])->value();
CONVERT_CHECKED(String, separator, args[2]);
if (!array->HasFastElements()) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
FixedArray* fixed_array = FixedArray::cast(array->elements());
if (fixed_array->length() < array_length) {
array_length = fixed_array->length();
}
if (array_length == 0) {
return isolate->heap()->empty_string();
} else if (array_length == 1) {
Object* first = fixed_array->get(0);
if (first->IsString()) return first;
}
int separator_length = separator->length();
int max_nof_separators =
(String::kMaxLength + separator_length - 1) / separator_length;
if (max_nof_separators < (array_length - 1)) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
int length = (array_length - 1) * separator_length;
for (int i = 0; i < array_length; i++) {
Object* element_obj = fixed_array->get(i);
if (!element_obj->IsString()) {
// TODO(1161): handle this case.
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
String* element = String::cast(element_obj);
int increment = element->length();
if (increment > String::kMaxLength - length) {
isolate->context()->mark_out_of_memory();
return Failure::OutOfMemoryException();
}
length += increment;
}
Object* object;
{ MaybeObject* maybe_object =
isolate->heap()->AllocateRawTwoByteString(length);
if (!maybe_object->ToObject(&object)) return maybe_object;
}
SeqTwoByteString* answer = SeqTwoByteString::cast(object);
uc16* sink = answer->GetChars();
#ifdef DEBUG
uc16* end = sink + length;
#endif
String* first = String::cast(fixed_array->get(0));
int first_length = first->length();
String::WriteToFlat(first, sink, 0, first_length);
sink += first_length;
for (int i = 1; i < array_length; i++) {
ASSERT(sink + separator_length <= end);
String::WriteToFlat(separator, sink, 0, separator_length);
sink += separator_length;
String* element = String::cast(fixed_array->get(i));
int element_length = element->length();
ASSERT(sink + element_length <= end);
String::WriteToFlat(element, sink, 0, element_length);
sink += element_length;
}
ASSERT(sink == end);
ASSERT(!answer->HasOnlyAsciiChars()); // Use %_FastAsciiArrayJoin instead.
return answer;
}
static MaybeObject* Runtime_NumberOr(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_NUMBER_CHECKED(int32_t, x, Int32, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, y, Int32, args[1]);
return isolate->heap()->NumberFromInt32(x | y);
}
static MaybeObject* Runtime_NumberAnd(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_NUMBER_CHECKED(int32_t, x, Int32, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, y, Int32, args[1]);
return isolate->heap()->NumberFromInt32(x & y);
}
static MaybeObject* Runtime_NumberXor(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_NUMBER_CHECKED(int32_t, x, Int32, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, y, Int32, args[1]);
return isolate->heap()->NumberFromInt32(x ^ y);
}
static MaybeObject* Runtime_NumberNot(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_NUMBER_CHECKED(int32_t, x, Int32, args[0]);
return isolate->heap()->NumberFromInt32(~x);
}
static MaybeObject* Runtime_NumberShl(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_NUMBER_CHECKED(int32_t, x, Int32, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, y, Int32, args[1]);
return isolate->heap()->NumberFromInt32(x << (y & 0x1f));
}
static MaybeObject* Runtime_NumberShr(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_NUMBER_CHECKED(uint32_t, x, Uint32, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, y, Int32, args[1]);
return isolate->heap()->NumberFromUint32(x >> (y & 0x1f));
}
static MaybeObject* Runtime_NumberSar(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_NUMBER_CHECKED(int32_t, x, Int32, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, y, Int32, args[1]);
return isolate->heap()->NumberFromInt32(ArithmeticShiftRight(x, y & 0x1f));
}
static MaybeObject* Runtime_NumberEquals(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
if (isnan(x)) return Smi::FromInt(NOT_EQUAL);
if (isnan(y)) return Smi::FromInt(NOT_EQUAL);
if (x == y) return Smi::FromInt(EQUAL);
Object* result;
if ((fpclassify(x) == FP_ZERO) && (fpclassify(y) == FP_ZERO)) {
result = Smi::FromInt(EQUAL);
} else {
result = Smi::FromInt(NOT_EQUAL);
}
return result;
}
static MaybeObject* Runtime_StringEquals(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, x, args[0]);
CONVERT_CHECKED(String, y, args[1]);
bool not_equal = !x->Equals(y);
// This is slightly convoluted because the value that signifies
// equality is 0 and inequality is 1 so we have to negate the result
// from String::Equals.
ASSERT(not_equal == 0 || not_equal == 1);
STATIC_CHECK(EQUAL == 0);
STATIC_CHECK(NOT_EQUAL == 1);
return Smi::FromInt(not_equal);
}
static MaybeObject* Runtime_NumberCompare(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
if (isnan(x) || isnan(y)) return args[2];
if (x == y) return Smi::FromInt(EQUAL);
if (isless(x, y)) return Smi::FromInt(LESS);
return Smi::FromInt(GREATER);
}
// Compare two Smis as if they were converted to strings and then
// compared lexicographically.
static MaybeObject* Runtime_SmiLexicographicCompare(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
// Extract the integer values from the Smis.
CONVERT_CHECKED(Smi, x, args[0]);
CONVERT_CHECKED(Smi, y, args[1]);
int x_value = x->value();
int y_value = y->value();
// If the integers are equal so are the string representations.
if (x_value == y_value) return Smi::FromInt(EQUAL);
// If one of the integers are zero the normal integer order is the
// same as the lexicographic order of the string representations.
if (x_value == 0 || y_value == 0) return Smi::FromInt(x_value - y_value);
// If only one of the integers is negative the negative number is
// smallest because the char code of '-' is less than the char code
// of any digit. Otherwise, we make both values positive.
if (x_value < 0 || y_value < 0) {
if (y_value >= 0) return Smi::FromInt(LESS);
if (x_value >= 0) return Smi::FromInt(GREATER);
x_value = -x_value;
y_value = -y_value;
}
// Arrays for the individual characters of the two Smis. Smis are
// 31 bit integers and 10 decimal digits are therefore enough.
// TODO(isolates): maybe we should simply allocate 20 bytes on the stack.
int* x_elms = isolate->runtime_state()->smi_lexicographic_compare_x_elms();
int* y_elms = isolate->runtime_state()->smi_lexicographic_compare_y_elms();
// Convert the integers to arrays of their decimal digits.
int x_index = 0;
int y_index = 0;
while (x_value > 0) {
x_elms[x_index++] = x_value % 10;
x_value /= 10;
}
while (y_value > 0) {
y_elms[y_index++] = y_value % 10;
y_value /= 10;
}
// Loop through the arrays of decimal digits finding the first place
// where they differ.
while (--x_index >= 0 && --y_index >= 0) {
int diff = x_elms[x_index] - y_elms[y_index];
if (diff != 0) return Smi::FromInt(diff);
}
// If one array is a suffix of the other array, the longest array is
// the representation of the largest of the Smis in the
// lexicographic ordering.
return Smi::FromInt(x_index - y_index);
}
static Object* StringInputBufferCompare(RuntimeState* state,
String* x,
String* y) {
StringInputBuffer& bufx = *state->string_input_buffer_compare_bufx();
StringInputBuffer& bufy = *state->string_input_buffer_compare_bufy();
bufx.Reset(x);
bufy.Reset(y);
while (bufx.has_more() && bufy.has_more()) {
int d = bufx.GetNext() - bufy.GetNext();
if (d < 0) return Smi::FromInt(LESS);
else if (d > 0) return Smi::FromInt(GREATER);
}
// x is (non-trivial) prefix of y:
if (bufy.has_more()) return Smi::FromInt(LESS);
// y is prefix of x:
return Smi::FromInt(bufx.has_more() ? GREATER : EQUAL);
}
static Object* FlatStringCompare(String* x, String* y) {
ASSERT(x->IsFlat());
ASSERT(y->IsFlat());
Object* equal_prefix_result = Smi::FromInt(EQUAL);
int prefix_length = x->length();
if (y->length() < prefix_length) {
prefix_length = y->length();
equal_prefix_result = Smi::FromInt(GREATER);
} else if (y->length() > prefix_length) {
equal_prefix_result = Smi::FromInt(LESS);
}
int r;
if (x->IsAsciiRepresentation()) {
Vector<const char> x_chars = x->ToAsciiVector();
if (y->IsAsciiRepresentation()) {
Vector<const char> y_chars = y->ToAsciiVector();
r = CompareChars(x_chars.start(), y_chars.start(), prefix_length);
} else {
Vector<const uc16> y_chars = y->ToUC16Vector();
r = CompareChars(x_chars.start(), y_chars.start(), prefix_length);
}
} else {
Vector<const uc16> x_chars = x->ToUC16Vector();
if (y->IsAsciiRepresentation()) {
Vector<const char> y_chars = y->ToAsciiVector();
r = CompareChars(x_chars.start(), y_chars.start(), prefix_length);
} else {
Vector<const uc16> y_chars = y->ToUC16Vector();
r = CompareChars(x_chars.start(), y_chars.start(), prefix_length);
}
}
Object* result;
if (r == 0) {
result = equal_prefix_result;
} else {
result = (r < 0) ? Smi::FromInt(LESS) : Smi::FromInt(GREATER);
}
ASSERT(result ==
StringInputBufferCompare(Isolate::Current()->runtime_state(), x, y));
return result;
}
static MaybeObject* Runtime_StringCompare(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, x, args[0]);
CONVERT_CHECKED(String, y, args[1]);
isolate->counters()->string_compare_runtime()->Increment();
// A few fast case tests before we flatten.
if (x == y) return Smi::FromInt(EQUAL);
if (y->length() == 0) {
if (x->length() == 0) return Smi::FromInt(EQUAL);
return Smi::FromInt(GREATER);
} else if (x->length() == 0) {
return Smi::FromInt(LESS);
}
int d = x->Get(0) - y->Get(0);
if (d < 0) return Smi::FromInt(LESS);
else if (d > 0) return Smi::FromInt(GREATER);
Object* obj;
{ MaybeObject* maybe_obj = isolate->heap()->PrepareForCompare(x);
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
{ MaybeObject* maybe_obj = isolate->heap()->PrepareForCompare(y);
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
return (x->IsFlat() && y->IsFlat()) ? FlatStringCompare(x, y)
: StringInputBufferCompare(isolate->runtime_state(), x, y);
}
static MaybeObject* Runtime_Math_acos(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_acos()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::ACOS, x);
}
static MaybeObject* Runtime_Math_asin(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_asin()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::ASIN, x);
}
static MaybeObject* Runtime_Math_atan(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_atan()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::ATAN, x);
}
static const double kPiDividedBy4 = 0.78539816339744830962;
static MaybeObject* Runtime_Math_atan2(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
isolate->counters()->math_atan2()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
double result;
if (isinf(x) && isinf(y)) {
// Make sure that the result in case of two infinite arguments
// is a multiple of Pi / 4. The sign of the result is determined
// by the first argument (x) and the sign of the second argument
// determines the multiplier: one or three.
int multiplier = (x < 0) ? -1 : 1;
if (y < 0) multiplier *= 3;
result = multiplier * kPiDividedBy4;
} else {
result = atan2(x, y);
}
return isolate->heap()->AllocateHeapNumber(result);
}
static MaybeObject* Runtime_Math_ceil(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_ceil()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->heap()->NumberFromDouble(ceiling(x));
}
static MaybeObject* Runtime_Math_cos(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_cos()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::COS, x);
}
static MaybeObject* Runtime_Math_exp(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_exp()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::EXP, x);
}
static MaybeObject* Runtime_Math_floor(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_floor()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->heap()->NumberFromDouble(floor(x));
}
static MaybeObject* Runtime_Math_log(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_log()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::LOG, x);
}
static MaybeObject* Runtime_Math_pow(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
isolate->counters()->math_pow()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
// If the second argument is a smi, it is much faster to call the
// custom powi() function than the generic pow().
if (args[1]->IsSmi()) {
int y = Smi::cast(args[1])->value();
return isolate->heap()->NumberFromDouble(power_double_int(x, y));
}
CONVERT_DOUBLE_CHECKED(y, args[1]);
return isolate->heap()->AllocateHeapNumber(power_double_double(x, y));
}
// Fast version of Math.pow if we know that y is not an integer and
// y is not -0.5 or 0.5. Used as slowcase from codegen.
static MaybeObject* Runtime_Math_pow_cfunction(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(x, args[0]);
CONVERT_DOUBLE_CHECKED(y, args[1]);
if (y == 0) {
return Smi::FromInt(1);
} else if (isnan(y) || ((x == 1 || x == -1) && isinf(y))) {
return isolate->heap()->nan_value();
} else {
return isolate->heap()->AllocateHeapNumber(pow(x, y));
}
}
static MaybeObject* Runtime_RoundNumber(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_round()->Increment();
if (!args[0]->IsHeapNumber()) {
// Must be smi. Return the argument unchanged for all the other types
// to make fuzz-natives test happy.
return args[0];
}
HeapNumber* number = reinterpret_cast<HeapNumber*>(args[0]);
double value = number->value();
int exponent = number->get_exponent();
int sign = number->get_sign();
// We compare with kSmiValueSize - 3 because (2^30 - 0.1) has exponent 29 and
// should be rounded to 2^30, which is not smi.
if (!sign && exponent <= kSmiValueSize - 3) {
return Smi::FromInt(static_cast<int>(value + 0.5));
}
// If the magnitude is big enough, there's no place for fraction part. If we
// try to add 0.5 to this number, 1.0 will be added instead.
if (exponent >= 52) {
return number;
}
if (sign && value >= -0.5) return isolate->heap()->minus_zero_value();
// Do not call NumberFromDouble() to avoid extra checks.
return isolate->heap()->AllocateHeapNumber(floor(value + 0.5));
}
static MaybeObject* Runtime_Math_sin(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_sin()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::SIN, x);
}
static MaybeObject* Runtime_Math_sqrt(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_sqrt()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->heap()->AllocateHeapNumber(sqrt(x));
}
static MaybeObject* Runtime_Math_tan(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
isolate->counters()->math_tan()->Increment();
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->transcendental_cache()->Get(TranscendentalCache::TAN, x);
}
static int MakeDay(int year, int month, int day) {
static const int day_from_month[] = {0, 31, 59, 90, 120, 151,
181, 212, 243, 273, 304, 334};
static const int day_from_month_leap[] = {0, 31, 60, 91, 121, 152,
182, 213, 244, 274, 305, 335};
year += month / 12;
month %= 12;
if (month < 0) {
year--;
month += 12;
}
ASSERT(month >= 0);
ASSERT(month < 12);
// year_delta is an arbitrary number such that:
// a) year_delta = -1 (mod 400)
// b) year + year_delta > 0 for years in the range defined by
// ECMA 262 - 15.9.1.1, i.e. upto 100,000,000 days on either side of
// Jan 1 1970. This is required so that we don't run into integer
// division of negative numbers.
// c) there shouldn't be an overflow for 32-bit integers in the following
// operations.
static const int year_delta = 399999;
static const int base_day = 365 * (1970 + year_delta) +
(1970 + year_delta) / 4 -
(1970 + year_delta) / 100 +
(1970 + year_delta) / 400;
int year1 = year + year_delta;
int day_from_year = 365 * year1 +
year1 / 4 -
year1 / 100 +
year1 / 400 -
base_day;
if (year % 4 || (year % 100 == 0 && year % 400 != 0)) {
return day_from_year + day_from_month[month] + day - 1;
}
return day_from_year + day_from_month_leap[month] + day - 1;
}
static MaybeObject* Runtime_DateMakeDay(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
CONVERT_SMI_CHECKED(year, args[0]);
CONVERT_SMI_CHECKED(month, args[1]);
CONVERT_SMI_CHECKED(date, args[2]);
return Smi::FromInt(MakeDay(year, month, date));
}
static const int kDays4Years[] = {0, 365, 2 * 365, 3 * 365 + 1};
static const int kDaysIn4Years = 4 * 365 + 1;
static const int kDaysIn100Years = 25 * kDaysIn4Years - 1;
static const int kDaysIn400Years = 4 * kDaysIn100Years + 1;
static const int kDays1970to2000 = 30 * 365 + 7;
static const int kDaysOffset = 1000 * kDaysIn400Years + 5 * kDaysIn400Years -
kDays1970to2000;
static const int kYearsOffset = 400000;
static const char kDayInYear[] = {
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21,
22, 23, 24, 25, 26, 27, 28, 29, 30, 31};
static const char kMonthInYear[] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1,
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2,
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3,
4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
4, 4, 4, 4, 4, 4,
5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5,
5, 5, 5, 5, 5,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6,
7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7,
7, 7, 7, 7, 7, 7,
8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8,
8, 8, 8, 8, 8,
9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9,
9, 9, 9, 9, 9, 9,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1,
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2,
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3,
4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
4, 4, 4, 4, 4, 4,
5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5,
5, 5, 5, 5, 5,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6,
7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7,
7, 7, 7, 7, 7, 7,
8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8,
8, 8, 8, 8, 8,
9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9,
9, 9, 9, 9, 9, 9,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1,
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2,
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3,
4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
4, 4, 4, 4, 4, 4,
5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5,
5, 5, 5, 5, 5,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6,
7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7,
7, 7, 7, 7, 7, 7,
8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8,
8, 8, 8, 8, 8,
9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9,
9, 9, 9, 9, 9, 9,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1,
2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2,
3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3,
4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
4, 4, 4, 4, 4, 4,
5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5, 5,
5, 5, 5, 5, 5,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6,
7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7,
7, 7, 7, 7, 7, 7,
8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8,
8, 8, 8, 8, 8,
9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9,
9, 9, 9, 9, 9, 9,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10, 10,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11,
11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11};
// This function works for dates from 1970 to 2099.
static inline void DateYMDFromTimeAfter1970(int date,
int& year, int& month, int& day) {
#ifdef DEBUG
int save_date = date; // Need this for ASSERT in the end.
#endif
year = 1970 + (4 * date + 2) / kDaysIn4Years;
date %= kDaysIn4Years;
month = kMonthInYear[date];
day = kDayInYear[date];
ASSERT(MakeDay(year, month, day) == save_date);
}
static inline void DateYMDFromTimeSlow(int date,
int& year, int& month, int& day) {
#ifdef DEBUG
int save_date = date; // Need this for ASSERT in the end.
#endif
date += kDaysOffset;
year = 400 * (date / kDaysIn400Years) - kYearsOffset;
date %= kDaysIn400Years;
ASSERT(MakeDay(year, 0, 1) + date == save_date);
date--;
int yd1 = date / kDaysIn100Years;
date %= kDaysIn100Years;
year += 100 * yd1;
date++;
int yd2 = date / kDaysIn4Years;
date %= kDaysIn4Years;
year += 4 * yd2;
date--;
int yd3 = date / 365;
date %= 365;
year += yd3;
bool is_leap = (!yd1 || yd2) && !yd3;
ASSERT(date >= -1);
ASSERT(is_leap || (date >= 0));
ASSERT((date < 365) || (is_leap && (date < 366)));
ASSERT(is_leap == ((year % 4 == 0) && (year % 100 || (year % 400 == 0))));
ASSERT(is_leap || ((MakeDay(year, 0, 1) + date) == save_date));
ASSERT(!is_leap || ((MakeDay(year, 0, 1) + date + 1) == save_date));
if (is_leap) {
day = kDayInYear[2*365 + 1 + date];
month = kMonthInYear[2*365 + 1 + date];
} else {
day = kDayInYear[date];
month = kMonthInYear[date];
}
ASSERT(MakeDay(year, month, day) == save_date);
}
static inline void DateYMDFromTime(int date,
int& year, int& month, int& day) {
if (date >= 0 && date < 32 * kDaysIn4Years) {
DateYMDFromTimeAfter1970(date, year, month, day);
} else {
DateYMDFromTimeSlow(date, year, month, day);
}
}
static MaybeObject* Runtime_DateYMDFromTime(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_DOUBLE_CHECKED(t, args[0]);
CONVERT_CHECKED(JSArray, res_array, args[1]);
int year, month, day;
DateYMDFromTime(static_cast<int>(floor(t / 86400000)), year, month, day);
RUNTIME_ASSERT(res_array->elements()->map() ==
isolate->heap()->fixed_array_map());
FixedArray* elms = FixedArray::cast(res_array->elements());
RUNTIME_ASSERT(elms->length() == 3);
elms->set(0, Smi::FromInt(year));
elms->set(1, Smi::FromInt(month));
elms->set(2, Smi::FromInt(day));
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_NewArgumentsFast(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 3);
JSFunction* callee = JSFunction::cast(args[0]);
Object** parameters = reinterpret_cast<Object**>(args[1]);
const int length = Smi::cast(args[2])->value();
Object* result;
{ MaybeObject* maybe_result =
isolate->heap()->AllocateArgumentsObject(callee, length);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
// Allocate the elements if needed.
if (length > 0) {
// Allocate the fixed array.
Object* obj;
{ MaybeObject* maybe_obj = isolate->heap()->AllocateRawFixedArray(length);
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
AssertNoAllocation no_gc;
FixedArray* array = reinterpret_cast<FixedArray*>(obj);
array->set_map(isolate->heap()->fixed_array_map());
array->set_length(length);
WriteBarrierMode mode = array->GetWriteBarrierMode(no_gc);
for (int i = 0; i < length; i++) {
array->set(i, *--parameters, mode);
}
JSObject::cast(result)->set_elements(FixedArray::cast(obj));
}
return result;
}
static MaybeObject* Runtime_NewClosure(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(Context, context, 0);
CONVERT_ARG_CHECKED(SharedFunctionInfo, shared, 1);
CONVERT_BOOLEAN_CHECKED(pretenure, args[2]);
// Allocate global closures in old space and allocate local closures
// in new space. Additionally pretenure closures that are assigned
// directly to properties.
pretenure = pretenure || (context->global_context() == *context);
PretenureFlag pretenure_flag = pretenure ? TENURED : NOT_TENURED;
Handle<JSFunction> result =
isolate->factory()->NewFunctionFromSharedFunctionInfo(shared,
context,
pretenure_flag);
return *result;
}
static MaybeObject* Runtime_NewObjectFromBound(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
// First argument is a function to use as a constructor.
CONVERT_ARG_CHECKED(JSFunction, function, 0);
// Second argument is either null or an array of bound arguments.
FixedArray* bound_args = NULL;
int bound_argc = 0;
if (!args[1]->IsNull()) {
CONVERT_ARG_CHECKED(JSArray, params, 1);
RUNTIME_ASSERT(params->HasFastElements());
bound_args = FixedArray::cast(params->elements());
bound_argc = Smi::cast(params->length())->value();
}
// Find frame containing arguments passed to the caller.
JavaScriptFrameIterator it;
JavaScriptFrame* frame = it.frame();
ASSERT(!frame->is_optimized());
it.AdvanceToArgumentsFrame();
frame = it.frame();
int argc = frame->ComputeParametersCount();
// Prepend bound arguments to caller's arguments.
int total_argc = bound_argc + argc;
SmartPointer<Object**> param_data(NewArray<Object**>(total_argc));
for (int i = 0; i < bound_argc; i++) {
Handle<Object> val = Handle<Object>(bound_args->get(i));
param_data[i] = val.location();
}
for (int i = 0; i < argc; i++) {
Handle<Object> val = Handle<Object>(frame->GetParameter(i));
param_data[bound_argc + i] = val.location();
}
bool exception = false;
Handle<Object> result =
Execution::New(function, total_argc, *param_data, &exception);
if (exception) {
return Failure::Exception();
}
ASSERT(!result.is_null());
return *result;
}
static void TrySettingInlineConstructStub(Isolate* isolate,
Handle<JSFunction> function) {
Handle<Object> prototype = isolate->factory()->null_value();
if (function->has_instance_prototype()) {
prototype = Handle<Object>(function->instance_prototype(), isolate);
}
if (function->shared()->CanGenerateInlineConstructor(*prototype)) {
ConstructStubCompiler compiler;
MaybeObject* code = compiler.CompileConstructStub(*function);
if (!code->IsFailure()) {
function->shared()->set_construct_stub(
Code::cast(code->ToObjectUnchecked()));
}
}
}
static MaybeObject* Runtime_NewObject(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<Object> constructor = args.at<Object>(0);
// If the constructor isn't a proper function we throw a type error.
if (!constructor->IsJSFunction()) {
Vector< Handle<Object> > arguments = HandleVector(&constructor, 1);
Handle<Object> type_error =
isolate->factory()->NewTypeError("not_constructor", arguments);
return isolate->Throw(*type_error);
}
Handle<JSFunction> function = Handle<JSFunction>::cast(constructor);
// If function should not have prototype, construction is not allowed. In this
// case generated code bailouts here, since function has no initial_map.
if (!function->should_have_prototype()) {
Vector< Handle<Object> > arguments = HandleVector(&constructor, 1);
Handle<Object> type_error =
isolate->factory()->NewTypeError("not_constructor", arguments);
return isolate->Throw(*type_error);
}
#ifdef ENABLE_DEBUGGER_SUPPORT
Debug* debug = isolate->debug();
// Handle stepping into constructors if step into is active.
if (debug->StepInActive()) {
debug->HandleStepIn(function, Handle<Object>::null(), 0, true);
}
#endif
if (function->has_initial_map()) {
if (function->initial_map()->instance_type() == JS_FUNCTION_TYPE) {
// The 'Function' function ignores the receiver object when
// called using 'new' and creates a new JSFunction object that
// is returned. The receiver object is only used for error
// reporting if an error occurs when constructing the new
// JSFunction. FACTORY->NewJSObject() should not be used to
// allocate JSFunctions since it does not properly initialize
// the shared part of the function. Since the receiver is
// ignored anyway, we use the global object as the receiver
// instead of a new JSFunction object. This way, errors are
// reported the same way whether or not 'Function' is called
// using 'new'.
return isolate->context()->global();
}
}
// The function should be compiled for the optimization hints to be
// available. We cannot use EnsureCompiled because that forces a
// compilation through the shared function info which makes it
// impossible for us to optimize.
Handle<SharedFunctionInfo> shared(function->shared(), isolate);
if (!function->is_compiled()) CompileLazy(function, CLEAR_EXCEPTION);
if (!function->has_initial_map() &&
shared->IsInobjectSlackTrackingInProgress()) {
// The tracking is already in progress for another function. We can only
// track one initial_map at a time, so we force the completion before the
// function is called as a constructor for the first time.
shared->CompleteInobjectSlackTracking();
}
bool first_allocation = !shared->live_objects_may_exist();
Handle<JSObject> result = isolate->factory()->NewJSObject(function);
RETURN_IF_EMPTY_HANDLE(isolate, result);
// Delay setting the stub if inobject slack tracking is in progress.
if (first_allocation && !shared->IsInobjectSlackTrackingInProgress()) {
TrySettingInlineConstructStub(isolate, function);
}
isolate->counters()->constructed_objects()->Increment();
isolate->counters()->constructed_objects_runtime()->Increment();
return *result;
}
static MaybeObject* Runtime_FinalizeInstanceSize(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSFunction, function, 0);
function->shared()->CompleteInobjectSlackTracking();
TrySettingInlineConstructStub(isolate, function);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_LazyCompile(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<JSFunction> function = args.at<JSFunction>(0);
#ifdef DEBUG
if (FLAG_trace_lazy && !function->shared()->is_compiled()) {
PrintF("[lazy: ");
function->PrintName();
PrintF("]\n");
}
#endif
// Compile the target function. Here we compile using CompileLazyInLoop in
// order to get the optimized version. This helps code like delta-blue
// that calls performance-critical routines through constructors. A
// constructor call doesn't use a CallIC, it uses a LoadIC followed by a
// direct call. Since the in-loop tracking takes place through CallICs
// this means that things called through constructors are never known to
// be in loops. We compile them as if they are in loops here just in case.
ASSERT(!function->is_compiled());
if (!CompileLazyInLoop(function, KEEP_EXCEPTION)) {
return Failure::Exception();
}
// All done. Return the compiled code.
ASSERT(function->is_compiled());
return function->code();
}
static MaybeObject* Runtime_LazyRecompile(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<JSFunction> function = args.at<JSFunction>(0);
// If the function is not optimizable or debugger is active continue using the
// code from the full compiler.
if (!function->shared()->code()->optimizable() ||
isolate->debug()->has_break_points()) {
if (FLAG_trace_opt) {
PrintF("[failed to optimize ");
function->PrintName();
PrintF(": is code optimizable: %s, is debugger enabled: %s]\n",
function->shared()->code()->optimizable() ? "T" : "F",
isolate->debug()->has_break_points() ? "T" : "F");
}
function->ReplaceCode(function->shared()->code());
return function->code();
}
if (CompileOptimized(function, AstNode::kNoNumber, CLEAR_EXCEPTION)) {
return function->code();
}
if (FLAG_trace_opt) {
PrintF("[failed to optimize ");
function->PrintName();
PrintF(": optimized compilation failed]\n");
}
function->ReplaceCode(function->shared()->code());
return function->code();
}
static MaybeObject* Runtime_NotifyDeoptimized(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
RUNTIME_ASSERT(args[0]->IsSmi());
Deoptimizer::BailoutType type =
static_cast<Deoptimizer::BailoutType>(Smi::cast(args[0])->value());
Deoptimizer* deoptimizer = Deoptimizer::Grab(isolate);
ASSERT(isolate->heap()->IsAllocationAllowed());
int frames = deoptimizer->output_count();
JavaScriptFrameIterator it;
JavaScriptFrame* frame = NULL;
for (int i = 0; i < frames; i++) {
if (i != 0) it.Advance();
frame = it.frame();
deoptimizer->InsertHeapNumberValues(frames - i - 1, frame);
}
delete deoptimizer;
RUNTIME_ASSERT(frame->function()->IsJSFunction());
Handle<JSFunction> function(JSFunction::cast(frame->function()), isolate);
Handle<Object> arguments;
for (int i = frame->ComputeExpressionsCount() - 1; i >= 0; --i) {
if (frame->GetExpression(i) == isolate->heap()->arguments_marker()) {
if (arguments.is_null()) {
// FunctionGetArguments can't throw an exception, so cast away the
// doubt with an assert.
arguments = Handle<Object>(
Accessors::FunctionGetArguments(*function,
NULL)->ToObjectUnchecked());
ASSERT(*arguments != isolate->heap()->null_value());
ASSERT(*arguments != isolate->heap()->undefined_value());
}
frame->SetExpression(i, *arguments);
}
}
isolate->compilation_cache()->MarkForLazyOptimizing(function);
if (type == Deoptimizer::EAGER) {
RUNTIME_ASSERT(function->IsOptimized());
} else {
RUNTIME_ASSERT(!function->IsOptimized());
}
// Avoid doing too much work when running with --always-opt and keep
// the optimized code around.
if (FLAG_always_opt || type == Deoptimizer::LAZY) {
return isolate->heap()->undefined_value();
}
// Count the number of optimized activations of the function.
int activations = 0;
while (!it.done()) {
JavaScriptFrame* frame = it.frame();
if (frame->is_optimized() && frame->function() == *function) {
activations++;
}
it.Advance();
}
// TODO(kasperl): For now, we cannot support removing the optimized
// code when we have recursive invocations of the same function.
if (activations == 0) {
if (FLAG_trace_deopt) {
PrintF("[removing optimized code for: ");
function->PrintName();
PrintF("]\n");
}
function->ReplaceCode(function->shared()->code());
}
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_NotifyOSR(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
Deoptimizer* deoptimizer = Deoptimizer::Grab(isolate);
delete deoptimizer;
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_DeoptimizeFunction(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSFunction, function, 0);
if (!function->IsOptimized()) return isolate->heap()->undefined_value();
Deoptimizer::DeoptimizeFunction(*function);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_CompileForOnStackReplacement(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSFunction, function, 0);
// We're not prepared to handle a function with arguments object.
ASSERT(!function->shared()->scope_info()->HasArgumentsShadow());
// We have hit a back edge in an unoptimized frame for a function that was
// selected for on-stack replacement. Find the unoptimized code object.
Handle<Code> unoptimized(function->shared()->code(), isolate);
// Keep track of whether we've succeeded in optimizing.
bool succeeded = unoptimized->optimizable();
if (succeeded) {
// If we are trying to do OSR when there are already optimized
// activations of the function, it means (a) the function is directly or
// indirectly recursive and (b) an optimized invocation has been
// deoptimized so that we are currently in an unoptimized activation.
// Check for optimized activations of this function.
JavaScriptFrameIterator it;
while (succeeded && !it.done()) {
JavaScriptFrame* frame = it.frame();
succeeded = !frame->is_optimized() || frame->function() != *function;
it.Advance();
}
}
int ast_id = AstNode::kNoNumber;
if (succeeded) {
// The top JS function is this one, the PC is somewhere in the
// unoptimized code.
JavaScriptFrameIterator it;
JavaScriptFrame* frame = it.frame();
ASSERT(frame->function() == *function);
ASSERT(frame->LookupCode(isolate) == *unoptimized);
ASSERT(unoptimized->contains(frame->pc()));
// Use linear search of the unoptimized code's stack check table to find
// the AST id matching the PC.
Address start = unoptimized->instruction_start();
unsigned target_pc_offset = static_cast<unsigned>(frame->pc() - start);
Address table_cursor = start + unoptimized->stack_check_table_offset();
uint32_t table_length = Memory::uint32_at(table_cursor);
table_cursor += kIntSize;
for (unsigned i = 0; i < table_length; ++i) {
// Table entries are (AST id, pc offset) pairs.
uint32_t pc_offset = Memory::uint32_at(table_cursor + kIntSize);
if (pc_offset == target_pc_offset) {
ast_id = static_cast<int>(Memory::uint32_at(table_cursor));
break;
}
table_cursor += 2 * kIntSize;
}
ASSERT(ast_id != AstNode::kNoNumber);
if (FLAG_trace_osr) {
PrintF("[replacing on-stack at AST id %d in ", ast_id);
function->PrintName();
PrintF("]\n");
}
// Try to compile the optimized code. A true return value from
// CompileOptimized means that compilation succeeded, not necessarily
// that optimization succeeded.
if (CompileOptimized(function, ast_id, CLEAR_EXCEPTION) &&
function->IsOptimized()) {
DeoptimizationInputData* data = DeoptimizationInputData::cast(
function->code()->deoptimization_data());
if (data->OsrPcOffset()->value() >= 0) {
if (FLAG_trace_osr) {
PrintF("[on-stack replacement offset %d in optimized code]\n",
data->OsrPcOffset()->value());
}
ASSERT(data->OsrAstId()->value() == ast_id);
} else {
// We may never generate the desired OSR entry if we emit an
// early deoptimize.
succeeded = false;
}
} else {
succeeded = false;
}
}
// Revert to the original stack checks in the original unoptimized code.
if (FLAG_trace_osr) {
PrintF("[restoring original stack checks in ");
function->PrintName();
PrintF("]\n");
}
StackCheckStub check_stub;
Handle<Code> check_code = check_stub.GetCode();
Handle<Code> replacement_code(
isolate->builtins()->builtin(Builtins::OnStackReplacement));
Deoptimizer::RevertStackCheckCode(*unoptimized,
*check_code,
*replacement_code);
// Allow OSR only at nesting level zero again.
unoptimized->set_allow_osr_at_loop_nesting_level(0);
// If the optimization attempt succeeded, return the AST id tagged as a
// smi. This tells the builtin that we need to translate the unoptimized
// frame to an optimized one.
if (succeeded) {
ASSERT(function->code()->kind() == Code::OPTIMIZED_FUNCTION);
return Smi::FromInt(ast_id);
} else {
if (function->IsMarkedForLazyRecompilation()) {
function->ReplaceCode(function->shared()->code());
}
return Smi::FromInt(-1);
}
}
static MaybeObject* Runtime_GetFunctionDelegate(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
RUNTIME_ASSERT(!args[0]->IsJSFunction());
return *Execution::GetFunctionDelegate(args.at<Object>(0));
}
static MaybeObject* Runtime_GetConstructorDelegate(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
RUNTIME_ASSERT(!args[0]->IsJSFunction());
return *Execution::GetConstructorDelegate(args.at<Object>(0));
}
static MaybeObject* Runtime_NewContext(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, function, args[0]);
int length = function->shared()->scope_info()->NumberOfContextSlots();
Object* result;
{ MaybeObject* maybe_result =
isolate->heap()->AllocateFunctionContext(length, function);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
isolate->set_context(Context::cast(result));
return result; // non-failure
}
MUST_USE_RESULT static MaybeObject* PushContextHelper(Isolate* isolate,
Object* object,
bool is_catch_context) {
// Convert the object to a proper JavaScript object.
Object* js_object = object;
if (!js_object->IsJSObject()) {
MaybeObject* maybe_js_object = js_object->ToObject();
if (!maybe_js_object->ToObject(&js_object)) {
if (!Failure::cast(maybe_js_object)->IsInternalError()) {
return maybe_js_object;
}
HandleScope scope(isolate);
Handle<Object> handle(object, isolate);
Handle<Object> result =
isolate->factory()->NewTypeError("with_expression",
HandleVector(&handle, 1));
return isolate->Throw(*result);
}
}
Object* result;
{ MaybeObject* maybe_result = isolate->heap()->AllocateWithContext(
isolate->context(), JSObject::cast(js_object), is_catch_context);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
Context* context = Context::cast(result);
isolate->set_context(context);
return result;
}
static MaybeObject* Runtime_PushContext(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
return PushContextHelper(isolate, args[0], false);
}
static MaybeObject* Runtime_PushCatchContext(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
return PushContextHelper(isolate, args[0], true);
}
static MaybeObject* Runtime_DeleteContextSlot(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(Context, context, 0);
CONVERT_ARG_CHECKED(String, name, 1);
int index;
PropertyAttributes attributes;
ContextLookupFlags flags = FOLLOW_CHAINS;
Handle<Object> holder = context->Lookup(name, flags, &index, &attributes);
// If the slot was not found the result is true.
if (holder.is_null()) {
return isolate->heap()->true_value();
}
// If the slot was found in a context, it should be DONT_DELETE.
if (holder->IsContext()) {
return isolate->heap()->false_value();
}
// The slot was found in a JSObject, either a context extension object,
// the global object, or an arguments object. Try to delete it
// (respecting DONT_DELETE). For consistency with V8's usual behavior,
// which allows deleting all parameters in functions that mention
// 'arguments', we do this even for the case of slots found on an
// arguments object. The slot was found on an arguments object if the
// index is non-negative.
Handle<JSObject> object = Handle<JSObject>::cast(holder);
if (index >= 0) {
return object->DeleteElement(index, JSObject::NORMAL_DELETION);
} else {
return object->DeleteProperty(*name, JSObject::NORMAL_DELETION);
}
}
// A mechanism to return a pair of Object pointers in registers (if possible).
// How this is achieved is calling convention-dependent.
// All currently supported x86 compiles uses calling conventions that are cdecl
// variants where a 64-bit value is returned in two 32-bit registers
// (edx:eax on ia32, r1:r0 on ARM).
// In AMD-64 calling convention a struct of two pointers is returned in rdx:rax.
// In Win64 calling convention, a struct of two pointers is returned in memory,
// allocated by the caller, and passed as a pointer in a hidden first parameter.
#ifdef V8_HOST_ARCH_64_BIT
struct ObjectPair {
MaybeObject* x;
MaybeObject* y;
};
static inline ObjectPair MakePair(MaybeObject* x, MaybeObject* y) {
ObjectPair result = {x, y};
// Pointers x and y returned in rax and rdx, in AMD-x64-abi.
// In Win64 they are assigned to a hidden first argument.
return result;
}
#else
typedef uint64_t ObjectPair;
static inline ObjectPair MakePair(MaybeObject* x, MaybeObject* y) {
return reinterpret_cast<uint32_t>(x) |
(reinterpret_cast<ObjectPair>(y) << 32);
}
#endif
static inline MaybeObject* Unhole(Heap* heap,
MaybeObject* x,
PropertyAttributes attributes) {
ASSERT(!x->IsTheHole() || (attributes & READ_ONLY) != 0);
USE(attributes);
return x->IsTheHole() ? heap->undefined_value() : x;
}
static JSObject* ComputeReceiverForNonGlobal(Isolate* isolate,
JSObject* holder) {
ASSERT(!holder->IsGlobalObject());
Context* top = isolate->context();
// Get the context extension function.
JSFunction* context_extension_function =
top->global_context()->context_extension_function();
// If the holder isn't a context extension object, we just return it
// as the receiver. This allows arguments objects to be used as
// receivers, but only if they are put in the context scope chain
// explicitly via a with-statement.
Object* constructor = holder->map()->constructor();
if (constructor != context_extension_function) return holder;
// Fall back to using the global object as the receiver if the
// property turns out to be a local variable allocated in a context
// extension object - introduced via eval.
return top->global()->global_receiver();
}
static ObjectPair LoadContextSlotHelper(Arguments args,
Isolate* isolate,
bool throw_error) {
HandleScope scope(isolate);
ASSERT_EQ(2, args.length());
if (!args[0]->IsContext() || !args[1]->IsString()) {
return MakePair(isolate->ThrowIllegalOperation(), NULL);
}
Handle<Context> context = args.at<Context>(0);
Handle<String> name = args.at<String>(1);
int index;
PropertyAttributes attributes;
ContextLookupFlags flags = FOLLOW_CHAINS;
Handle<Object> holder = context->Lookup(name, flags, &index, &attributes);
// If the index is non-negative, the slot has been found in a local
// variable or a parameter. Read it from the context object or the
// arguments object.
if (index >= 0) {
// If the "property" we were looking for is a local variable or an
// argument in a context, the receiver is the global object; see
// ECMA-262, 3rd., 10.1.6 and 10.2.3.
JSObject* receiver =
isolate->context()->global()->global_receiver();
MaybeObject* value = (holder->IsContext())
? Context::cast(*holder)->get(index)
: JSObject::cast(*holder)->GetElement(index);
return MakePair(Unhole(isolate->heap(), value, attributes), receiver);
}
// If the holder is found, we read the property from it.
if (!holder.is_null() && holder->IsJSObject()) {
ASSERT(Handle<JSObject>::cast(holder)->HasProperty(*name));
JSObject* object = JSObject::cast(*holder);
JSObject* receiver;
if (object->IsGlobalObject()) {
receiver = GlobalObject::cast(object)->global_receiver();
} else if (context->is_exception_holder(*holder)) {
receiver = isolate->context()->global()->global_receiver();
} else {
receiver = ComputeReceiverForNonGlobal(isolate, object);
}
// No need to unhole the value here. This is taken care of by the
// GetProperty function.
MaybeObject* value = object->GetProperty(*name);
return MakePair(value, receiver);
}
if (throw_error) {
// The property doesn't exist - throw exception.
Handle<Object> reference_error =
isolate->factory()->NewReferenceError("not_defined",
HandleVector(&name, 1));
return MakePair(isolate->Throw(*reference_error), NULL);
} else {
// The property doesn't exist - return undefined
return MakePair(isolate->heap()->undefined_value(),
isolate->heap()->undefined_value());
}
}
static ObjectPair Runtime_LoadContextSlot(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
return LoadContextSlotHelper(args, isolate, true);
}
static ObjectPair Runtime_LoadContextSlotNoReferenceError(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
return LoadContextSlotHelper(args, isolate, false);
}
static MaybeObject* Runtime_StoreContextSlot(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 4);
Handle<Object> value(args[0], isolate);
CONVERT_ARG_CHECKED(Context, context, 1);
CONVERT_ARG_CHECKED(String, name, 2);
CONVERT_SMI_CHECKED(strict_unchecked, args[3]);
RUNTIME_ASSERT(strict_unchecked == kStrictMode ||
strict_unchecked == kNonStrictMode);
StrictModeFlag strict_mode = static_cast<StrictModeFlag>(strict_unchecked);
int index;
PropertyAttributes attributes;
ContextLookupFlags flags = FOLLOW_CHAINS;
Handle<Object> holder = context->Lookup(name, flags, &index, &attributes);
if (index >= 0) {
if (holder->IsContext()) {
// Ignore if read_only variable.
if ((attributes & READ_ONLY) == 0) {
// Context is a fixed array and set cannot fail.
Context::cast(*holder)->set(index, *value);
} else if (strict_mode == kStrictMode) {
// Setting read only property in strict mode.
Handle<Object> error =
isolate->factory()->NewTypeError("strict_cannot_assign",
HandleVector(&name, 1));
return isolate->Throw(*error);
}
} else {
ASSERT((attributes & READ_ONLY) == 0);
Handle<Object> result =
SetElement(Handle<JSObject>::cast(holder), index, value, strict_mode);
if (result.is_null()) {
ASSERT(isolate->has_pending_exception());
return Failure::Exception();
}
}
return *value;
}
// Slow case: The property is not in a FixedArray context.
// It is either in an JSObject extension context or it was not found.
Handle<JSObject> context_ext;
if (!holder.is_null()) {
// The property exists in the extension context.
context_ext = Handle<JSObject>::cast(holder);
} else {
// The property was not found. It needs to be stored in the global context.
ASSERT(attributes == ABSENT);
attributes = NONE;
context_ext = Handle<JSObject>(isolate->context()->global());
}
// Set the property, but ignore if read_only variable on the context
// extension object itself.
if ((attributes & READ_ONLY) == 0 ||
(context_ext->GetLocalPropertyAttribute(*name) == ABSENT)) {
RETURN_IF_EMPTY_HANDLE(
isolate,
SetProperty(context_ext, name, value, NONE, strict_mode));
} else if (strict_mode == kStrictMode && (attributes & READ_ONLY) != 0) {
// Setting read only property in strict mode.
Handle<Object> error =
isolate->factory()->NewTypeError(
"strict_cannot_assign", HandleVector(&name, 1));
return isolate->Throw(*error);
}
return *value;
}
static MaybeObject* Runtime_Throw(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
return isolate->Throw(args[0]);
}
static MaybeObject* Runtime_ReThrow(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
return isolate->ReThrow(args[0]);
}
static MaybeObject* Runtime_PromoteScheduledException(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT_EQ(0, args.length());
return isolate->PromoteScheduledException();
}
static MaybeObject* Runtime_ThrowReferenceError(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<Object> name(args[0], isolate);
Handle<Object> reference_error =
isolate->factory()->NewReferenceError("not_defined",
HandleVector(&name, 1));
return isolate->Throw(*reference_error);
}
static MaybeObject* Runtime_StackGuard(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
// First check if this is a real stack overflow.
if (isolate->stack_guard()->IsStackOverflow()) {
NoHandleAllocation na;
return isolate->StackOverflow();
}
return Execution::HandleStackGuardInterrupt();
}
// NOTE: These PrintXXX functions are defined for all builds (not just
// DEBUG builds) because we may want to be able to trace function
// calls in all modes.
static void PrintString(String* str) {
// not uncommon to have empty strings
if (str->length() > 0) {
SmartPointer<char> s =
str->ToCString(DISALLOW_NULLS, ROBUST_STRING_TRAVERSAL);
PrintF("%s", *s);
}
}
static void PrintObject(Object* obj) {
if (obj->IsSmi()) {
PrintF("%d", Smi::cast(obj)->value());
} else if (obj->IsString() || obj->IsSymbol()) {
PrintString(String::cast(obj));
} else if (obj->IsNumber()) {
PrintF("%g", obj->Number());
} else if (obj->IsFailure()) {
PrintF("<failure>");
} else if (obj->IsUndefined()) {
PrintF("<undefined>");
} else if (obj->IsNull()) {
PrintF("<null>");
} else if (obj->IsTrue()) {
PrintF("<true>");
} else if (obj->IsFalse()) {
PrintF("<false>");
} else {
PrintF("%p", reinterpret_cast<void*>(obj));
}
}
static int StackSize() {
int n = 0;
for (JavaScriptFrameIterator it; !it.done(); it.Advance()) n++;
return n;
}
static void PrintTransition(Object* result) {
// indentation
{ const int nmax = 80;
int n = StackSize();
if (n <= nmax)
PrintF("%4d:%*s", n, n, "");
else
PrintF("%4d:%*s", n, nmax, "...");
}
if (result == NULL) {
// constructor calls
JavaScriptFrameIterator it;
JavaScriptFrame* frame = it.frame();
if (frame->IsConstructor()) PrintF("new ");
// function name
Object* fun = frame->function();
if (fun->IsJSFunction()) {
PrintObject(JSFunction::cast(fun)->shared()->name());
} else {
PrintObject(fun);
}
// function arguments
// (we are intentionally only printing the actually
// supplied parameters, not all parameters required)
PrintF("(this=");
PrintObject(frame->receiver());
const int length = frame->ComputeParametersCount();
for (int i = 0; i < length; i++) {
PrintF(", ");
PrintObject(frame->GetParameter(i));
}
PrintF(") {\n");
} else {
// function result
PrintF("} -> ");
PrintObject(result);
PrintF("\n");
}
}
static MaybeObject* Runtime_TraceEnter(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
NoHandleAllocation ha;
PrintTransition(NULL);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_TraceExit(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
PrintTransition(args[0]);
return args[0]; // return TOS
}
static MaybeObject* Runtime_DebugPrint(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
#ifdef DEBUG
if (args[0]->IsString()) {
// If we have a string, assume it's a code "marker"
// and print some interesting cpu debugging info.
JavaScriptFrameIterator it;
JavaScriptFrame* frame = it.frame();
PrintF("fp = %p, sp = %p, caller_sp = %p: ",
frame->fp(), frame->sp(), frame->caller_sp());
} else {
PrintF("DebugPrint: ");
}
args[0]->Print();
if (args[0]->IsHeapObject()) {
PrintF("\n");
HeapObject::cast(args[0])->map()->Print();
}
#else
// ShortPrint is available in release mode. Print is not.
args[0]->ShortPrint();
#endif
PrintF("\n");
Flush();
return args[0]; // return TOS
}
static MaybeObject* Runtime_DebugTrace(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
NoHandleAllocation ha;
isolate->PrintStack();
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_DateCurrentTime(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 0);
// According to ECMA-262, section 15.9.1, page 117, the precision of
// the number in a Date object representing a particular instant in
// time is milliseconds. Therefore, we floor the result of getting
// the OS time.
double millis = floor(OS::TimeCurrentMillis());
return isolate->heap()->NumberFromDouble(millis);
}
static MaybeObject* Runtime_DateParseString(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(String, str, 0);
FlattenString(str);
CONVERT_ARG_CHECKED(JSArray, output, 1);
RUNTIME_ASSERT(output->HasFastElements());
AssertNoAllocation no_allocation;
FixedArray* output_array = FixedArray::cast(output->elements());
RUNTIME_ASSERT(output_array->length() >= DateParser::OUTPUT_SIZE);
bool result;
if (str->IsAsciiRepresentation()) {
result = DateParser::Parse(str->ToAsciiVector(), output_array);
} else {
ASSERT(str->IsTwoByteRepresentation());
result = DateParser::Parse(str->ToUC16Vector(), output_array);
}
if (result) {
return *output;
} else {
return isolate->heap()->null_value();
}
}
static MaybeObject* Runtime_DateLocalTimezone(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_DOUBLE_CHECKED(x, args[0]);
const char* zone = OS::LocalTimezone(x);
return isolate->heap()->AllocateStringFromUtf8(CStrVector(zone));
}
static MaybeObject* Runtime_DateLocalTimeOffset(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 0);
return isolate->heap()->NumberFromDouble(OS::LocalTimeOffset());
}
static MaybeObject* Runtime_DateDaylightSavingsOffset(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_DOUBLE_CHECKED(x, args[0]);
return isolate->heap()->NumberFromDouble(OS::DaylightSavingsOffset(x));
}
static MaybeObject* Runtime_GlobalReceiver(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
Object* global = args[0];
if (!global->IsJSGlobalObject()) return isolate->heap()->null_value();
return JSGlobalObject::cast(global)->global_receiver();
}
static MaybeObject* Runtime_ParseJson(RUNTIME_CALLING_CONVENTION) {
HandleScope scope(isolate);
ASSERT_EQ(1, args.length());
CONVERT_ARG_CHECKED(String, source, 0);
Handle<Object> result = JsonParser::Parse(source);
if (result.is_null()) {
// Syntax error or stack overflow in scanner.
ASSERT(isolate->has_pending_exception());
return Failure::Exception();
}
return *result;
}
static MaybeObject* Runtime_CompileString(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT_EQ(1, args.length());
CONVERT_ARG_CHECKED(String, source, 0);
// Compile source string in the global context.
Handle<Context> context(isolate->context()->global_context());
Handle<SharedFunctionInfo> shared = Compiler::CompileEval(source,
context,
true,
kNonStrictMode);
if (shared.is_null()) return Failure::Exception();
Handle<JSFunction> fun =
isolate->factory()->NewFunctionFromSharedFunctionInfo(shared,
context,
NOT_TENURED);
return *fun;
}
static ObjectPair CompileGlobalEval(Isolate* isolate,
Handle<String> source,
Handle<Object> receiver,
StrictModeFlag strict_mode) {
// Deal with a normal eval call with a string argument. Compile it
// and return the compiled function bound in the local context.
Handle<SharedFunctionInfo> shared = Compiler::CompileEval(
source,
Handle<Context>(isolate->context()),
isolate->context()->IsGlobalContext(),
strict_mode);
if (shared.is_null()) return MakePair(Failure::Exception(), NULL);
Handle<JSFunction> compiled =
isolate->factory()->NewFunctionFromSharedFunctionInfo(
shared, Handle<Context>(isolate->context()), NOT_TENURED);
return MakePair(*compiled, *receiver);
}
static ObjectPair Runtime_ResolvePossiblyDirectEval(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 4);
HandleScope scope(isolate);
Handle<Object> callee = args.at<Object>(0);
Handle<Object> receiver; // Will be overwritten.
// Compute the calling context.
Handle<Context> context = Handle<Context>(isolate->context(), isolate);
#ifdef DEBUG
// Make sure Isolate::context() agrees with the old code that traversed
// the stack frames to compute the context.
StackFrameLocator locator;
JavaScriptFrame* frame = locator.FindJavaScriptFrame(0);
ASSERT(Context::cast(frame->context()) == *context);
#endif
// Find where the 'eval' symbol is bound. It is unaliased only if
// it is bound in the global context.
int index = -1;
PropertyAttributes attributes = ABSENT;
while (true) {
receiver = context->Lookup(isolate->factory()->eval_symbol(),
FOLLOW_PROTOTYPE_CHAIN,
&index, &attributes);
// Stop search when eval is found or when the global context is
// reached.
if (attributes != ABSENT || context->IsGlobalContext()) break;
if (context->is_function_context()) {
context = Handle<Context>(Context::cast(context->closure()->context()),
isolate);
} else {
context = Handle<Context>(context->previous(), isolate);
}
}
// If eval could not be resolved, it has been deleted and we need to
// throw a reference error.
if (attributes == ABSENT) {
Handle<Object> name = isolate->factory()->eval_symbol();
Handle<Object> reference_error =
isolate->factory()->NewReferenceError("not_defined",
HandleVector(&name, 1));
return MakePair(isolate->Throw(*reference_error), NULL);
}
if (!context->IsGlobalContext()) {
// 'eval' is not bound in the global context. Just call the function
// with the given arguments. This is not necessarily the global eval.
if (receiver->IsContext()) {
context = Handle<Context>::cast(receiver);
receiver = Handle<Object>(context->get(index), isolate);
} else if (receiver->IsJSContextExtensionObject()) {
receiver = Handle<JSObject>(
isolate->context()->global()->global_receiver(), isolate);
}
return MakePair(*callee, *receiver);
}
// 'eval' is bound in the global context, but it may have been overwritten.
// Compare it to the builtin 'GlobalEval' function to make sure.
if (*callee != isolate->global_context()->global_eval_fun() ||
!args[1]->IsString()) {
return MakePair(*callee,
isolate->context()->global()->global_receiver());
}
ASSERT(args[3]->IsSmi());
return CompileGlobalEval(isolate,
args.at<String>(1),
args.at<Object>(2),
static_cast<StrictModeFlag>(
Smi::cast(args[3])->value()));
}
static ObjectPair Runtime_ResolvePossiblyDirectEvalNoLookup(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 4);
HandleScope scope(isolate);
Handle<Object> callee = args.at<Object>(0);
// 'eval' is bound in the global context, but it may have been overwritten.
// Compare it to the builtin 'GlobalEval' function to make sure.
if (*callee != isolate->global_context()->global_eval_fun() ||
!args[1]->IsString()) {
return MakePair(*callee,
isolate->context()->global()->global_receiver());
}
ASSERT(args[3]->IsSmi());
return CompileGlobalEval(isolate,
args.at<String>(1),
args.at<Object>(2),
static_cast<StrictModeFlag>(
Smi::cast(args[3])->value()));
}
static MaybeObject* Runtime_SetNewFunctionAttributes(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
// This utility adjusts the property attributes for newly created Function
// object ("new Function(...)") by changing the map.
// All it does is changing the prototype property to enumerable
// as specified in ECMA262, 15.3.5.2.
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSFunction, func, 0);
Handle<Map> map = func->shared()->strict_mode()
? isolate->strict_mode_function_instance_map()
: isolate->function_instance_map();
ASSERT(func->map()->instance_type() == map->instance_type());
ASSERT(func->map()->instance_size() == map->instance_size());
func->set_map(*map);
return *func;
}
static MaybeObject* Runtime_AllocateInNewSpace(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
// Allocate a block of memory in NewSpace (filled with a filler).
// Use as fallback for allocation in generated code when NewSpace
// is full.
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(Smi, size_smi, 0);
int size = size_smi->value();
RUNTIME_ASSERT(IsAligned(size, kPointerSize));
RUNTIME_ASSERT(size > 0);
Heap* heap = isolate->heap();
const int kMinFreeNewSpaceAfterGC = heap->InitialSemiSpaceSize() * 3/4;
RUNTIME_ASSERT(size <= kMinFreeNewSpaceAfterGC);
Object* allocation;
{ MaybeObject* maybe_allocation = heap->new_space()->AllocateRaw(size);
if (maybe_allocation->ToObject(&allocation)) {
heap->CreateFillerObjectAt(HeapObject::cast(allocation)->address(), size);
}
return maybe_allocation;
}
}
// Push an object unto an array of objects if it is not already in the
// array. Returns true if the element was pushed on the stack and
// false otherwise.
static MaybeObject* Runtime_PushIfAbsent(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSArray, array, args[0]);
CONVERT_CHECKED(JSObject, element, args[1]);
RUNTIME_ASSERT(array->HasFastElements());
int length = Smi::cast(array->length())->value();
FixedArray* elements = FixedArray::cast(array->elements());
for (int i = 0; i < length; i++) {
if (elements->get(i) == element) return isolate->heap()->false_value();
}
Object* obj;
// Strict not needed. Used for cycle detection in Array join implementation.
{ MaybeObject* maybe_obj = array->SetFastElement(length, element,
kNonStrictMode);
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
return isolate->heap()->true_value();
}
/**
* A simple visitor visits every element of Array's.
* The backend storage can be a fixed array for fast elements case,
* or a dictionary for sparse array. Since Dictionary is a subtype
* of FixedArray, the class can be used by both fast and slow cases.
* The second parameter of the constructor, fast_elements, specifies
* whether the storage is a FixedArray or Dictionary.
*
* An index limit is used to deal with the situation that a result array
* length overflows 32-bit non-negative integer.
*/
class ArrayConcatVisitor {
public:
ArrayConcatVisitor(Isolate* isolate,
Handle<FixedArray> storage,
bool fast_elements) :
isolate_(isolate),
storage_(Handle<FixedArray>::cast(
isolate->global_handles()->Create(*storage))),
index_offset_(0u),
fast_elements_(fast_elements) { }
~ArrayConcatVisitor() {
clear_storage();
}
void visit(uint32_t i, Handle<Object> elm) {
if (i >= JSObject::kMaxElementCount - index_offset_) return;
uint32_t index = index_offset_ + i;
if (fast_elements_) {
if (index < static_cast<uint32_t>(storage_->length())) {
storage_->set(index, *elm);
return;
}
// Our initial estimate of length was foiled, possibly by
// getters on the arrays increasing the length of later arrays
// during iteration.
// This shouldn't happen in anything but pathological cases.
SetDictionaryMode(index);
// Fall-through to dictionary mode.
}
ASSERT(!fast_elements_);
Handle<NumberDictionary> dict(NumberDictionary::cast(*storage_));
Handle<NumberDictionary> result =
isolate_->factory()->DictionaryAtNumberPut(dict, index, elm);
if (!result.is_identical_to(dict)) {
// Dictionary needed to grow.
clear_storage();
set_storage(*result);
}
}
void increase_index_offset(uint32_t delta) {
if (JSObject::kMaxElementCount - index_offset_ < delta) {
index_offset_ = JSObject::kMaxElementCount;
} else {
index_offset_ += delta;
}
}
Handle<JSArray> ToArray() {
Handle<JSArray> array = isolate_->factory()->NewJSArray(0);
Handle<Object> length =
isolate_->factory()->NewNumber(static_cast<double>(index_offset_));
Handle<Map> map;
if (fast_elements_) {
map = isolate_->factory()->GetFastElementsMap(Handle<Map>(array->map()));
} else {
map = isolate_->factory()->GetSlowElementsMap(Handle<Map>(array->map()));
}
array->set_map(*map);
array->set_length(*length);
array->set_elements(*storage_);
return array;
}
private:
// Convert storage to dictionary mode.
void SetDictionaryMode(uint32_t index) {
ASSERT(fast_elements_);
Handle<FixedArray> current_storage(*storage_);
Handle<NumberDictionary> slow_storage(
isolate_->factory()->NewNumberDictionary(current_storage->length()));
uint32_t current_length = static_cast<uint32_t>(current_storage->length());
for (uint32_t i = 0; i < current_length; i++) {
HandleScope loop_scope;
Handle<Object> element(current_storage->get(i));
if (!element->IsTheHole()) {
Handle<NumberDictionary> new_storage =
isolate_->factory()->DictionaryAtNumberPut(slow_storage, i, element);
if (!new_storage.is_identical_to(slow_storage)) {
slow_storage = loop_scope.CloseAndEscape(new_storage);
}
}
}
clear_storage();
set_storage(*slow_storage);
fast_elements_ = false;
}
inline void clear_storage() {
isolate_->global_handles()->Destroy(
Handle<Object>::cast(storage_).location());
}
inline void set_storage(FixedArray* storage) {
storage_ = Handle<FixedArray>::cast(
isolate_->global_handles()->Create(storage));
}
Isolate* isolate_;
Handle<FixedArray> storage_; // Always a global handle.
// Index after last seen index. Always less than or equal to
// JSObject::kMaxElementCount.
uint32_t index_offset_;
bool fast_elements_;
};
static uint32_t EstimateElementCount(Handle<JSArray> array) {
uint32_t length = static_cast<uint32_t>(array->length()->Number());
int element_count = 0;
switch (array->GetElementsKind()) {
case JSObject::FAST_ELEMENTS: {
// Fast elements can't have lengths that are not representable by
// a 32-bit signed integer.
ASSERT(static_cast<int32_t>(FixedArray::kMaxLength) >= 0);
int fast_length = static_cast<int>(length);
Handle<FixedArray> elements(FixedArray::cast(array->elements()));
for (int i = 0; i < fast_length; i++) {
if (!elements->get(i)->IsTheHole()) element_count++;
}
break;
}
case JSObject::DICTIONARY_ELEMENTS: {
Handle<NumberDictionary> dictionary(
NumberDictionary::cast(array->elements()));
int capacity = dictionary->Capacity();
for (int i = 0; i < capacity; i++) {
Handle<Object> key(dictionary->KeyAt(i));
if (dictionary->IsKey(*key)) {
element_count++;
}
}
break;
}
default:
// External arrays are always dense.
return length;
}
// As an estimate, we assume that the prototype doesn't contain any
// inherited elements.
return element_count;
}
template<class ExternalArrayClass, class ElementType>
static void IterateExternalArrayElements(Isolate* isolate,
Handle<JSObject> receiver,
bool elements_are_ints,
bool elements_are_guaranteed_smis,
ArrayConcatVisitor* visitor) {
Handle<ExternalArrayClass> array(
ExternalArrayClass::cast(receiver->elements()));
uint32_t len = static_cast<uint32_t>(array->length());
ASSERT(visitor != NULL);
if (elements_are_ints) {
if (elements_are_guaranteed_smis) {
for (uint32_t j = 0; j < len; j++) {
HandleScope loop_scope;
Handle<Smi> e(Smi::FromInt(static_cast<int>(array->get(j))));
visitor->visit(j, e);
}
} else {
for (uint32_t j = 0; j < len; j++) {
HandleScope loop_scope;
int64_t val = static_cast<int64_t>(array->get(j));
if (Smi::IsValid(static_cast<intptr_t>(val))) {
Handle<Smi> e(Smi::FromInt(static_cast<int>(val)));
visitor->visit(j, e);
} else {
Handle<Object> e =
isolate->factory()->NewNumber(static_cast<ElementType>(val));
visitor->visit(j, e);
}
}
}
} else {
for (uint32_t j = 0; j < len; j++) {
HandleScope loop_scope(isolate);
Handle<Object> e = isolate->factory()->NewNumber(array->get(j));
visitor->visit(j, e);
}
}
}
// Used for sorting indices in a List<uint32_t>.
static int compareUInt32(const uint32_t* ap, const uint32_t* bp) {
uint32_t a = *ap;
uint32_t b = *bp;
return (a == b) ? 0 : (a < b) ? -1 : 1;
}
static void CollectElementIndices(Handle<JSObject> object,
uint32_t range,
List<uint32_t>* indices) {
JSObject::ElementsKind kind = object->GetElementsKind();
switch (kind) {
case JSObject::FAST_ELEMENTS: {
Handle<FixedArray> elements(FixedArray::cast(object->elements()));
uint32_t length = static_cast<uint32_t>(elements->length());
if (range < length) length = range;
for (uint32_t i = 0; i < length; i++) {
if (!elements->get(i)->IsTheHole()) {
indices->Add(i);
}
}
break;
}
case JSObject::DICTIONARY_ELEMENTS: {
Handle<NumberDictionary> dict(NumberDictionary::cast(object->elements()));
uint32_t capacity = dict->Capacity();
for (uint32_t j = 0; j < capacity; j++) {
HandleScope loop_scope;
Handle<Object> k(dict->KeyAt(j));
if (dict->IsKey(*k)) {
ASSERT(k->IsNumber());
uint32_t index = static_cast<uint32_t>(k->Number());
if (index < range) {
indices->Add(index);
}
}
}
break;
}
default: {
int dense_elements_length;
switch (kind) {
case JSObject::EXTERNAL_PIXEL_ELEMENTS: {
dense_elements_length =
ExternalPixelArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_BYTE_ELEMENTS: {
dense_elements_length =
ExternalByteArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_UNSIGNED_BYTE_ELEMENTS: {
dense_elements_length =
ExternalUnsignedByteArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_SHORT_ELEMENTS: {
dense_elements_length =
ExternalShortArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_UNSIGNED_SHORT_ELEMENTS: {
dense_elements_length =
ExternalUnsignedShortArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_INT_ELEMENTS: {
dense_elements_length =
ExternalIntArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_UNSIGNED_INT_ELEMENTS: {
dense_elements_length =
ExternalUnsignedIntArray::cast(object->elements())->length();
break;
}
case JSObject::EXTERNAL_FLOAT_ELEMENTS: {
dense_elements_length =
ExternalFloatArray::cast(object->elements())->length();
break;
}
default:
UNREACHABLE();
dense_elements_length = 0;
break;
}
uint32_t length = static_cast<uint32_t>(dense_elements_length);
if (range <= length) {
length = range;
// We will add all indices, so we might as well clear it first
// and avoid duplicates.
indices->Clear();
}
for (uint32_t i = 0; i < length; i++) {
indices->Add(i);
}
if (length == range) return; // All indices accounted for already.
break;
}
}
Handle<Object> prototype(object->GetPrototype());
if (prototype->IsJSObject()) {
// The prototype will usually have no inherited element indices,
// but we have to check.
CollectElementIndices(Handle<JSObject>::cast(prototype), range, indices);
}
}
/**
* A helper function that visits elements of a JSArray in numerical
* order.
*
* The visitor argument called for each existing element in the array
* with the element index and the element's value.
* Afterwards it increments the base-index of the visitor by the array
* length.
* Returns false if any access threw an exception, otherwise true.
*/
static bool IterateElements(Isolate* isolate,
Handle<JSArray> receiver,
ArrayConcatVisitor* visitor) {
uint32_t length = static_cast<uint32_t>(receiver->length()->Number());
switch (receiver->GetElementsKind()) {
case JSObject::FAST_ELEMENTS: {
// Run through the elements FixedArray and use HasElement and GetElement
// to check the prototype for missing elements.
Handle<FixedArray> elements(FixedArray::cast(receiver->elements()));
int fast_length = static_cast<int>(length);
ASSERT(fast_length <= elements->length());
for (int j = 0; j < fast_length; j++) {
HandleScope loop_scope(isolate);
Handle<Object> element_value(elements->get(j), isolate);
if (!element_value->IsTheHole()) {
visitor->visit(j, element_value);
} else if (receiver->HasElement(j)) {
// Call GetElement on receiver, not its prototype, or getters won't
// have the correct receiver.
element_value = GetElement(receiver, j);
if (element_value.is_null()) return false;
visitor->visit(j, element_value);
}
}
break;
}
case JSObject::DICTIONARY_ELEMENTS: {
Handle<NumberDictionary> dict(receiver->element_dictionary());
List<uint32_t> indices(dict->Capacity() / 2);
// Collect all indices in the object and the prototypes less
// than length. This might introduce duplicates in the indices list.
CollectElementIndices(receiver, length, &indices);
indices.Sort(&compareUInt32);
int j = 0;
int n = indices.length();
while (j < n) {
HandleScope loop_scope;
uint32_t index = indices[j];
Handle<Object> element = GetElement(receiver, index);
if (element.is_null()) return false;
visitor->visit(index, element);
// Skip to next different index (i.e., omit duplicates).
do {
j++;
} while (j < n && indices[j] == index);
}
break;
}
case JSObject::EXTERNAL_PIXEL_ELEMENTS: {
Handle<ExternalPixelArray> pixels(ExternalPixelArray::cast(
receiver->elements()));
for (uint32_t j = 0; j < length; j++) {
Handle<Smi> e(Smi::FromInt(pixels->get(j)));
visitor->visit(j, e);
}
break;
}
case JSObject::EXTERNAL_BYTE_ELEMENTS: {
IterateExternalArrayElements<ExternalByteArray, int8_t>(
isolate, receiver, true, true, visitor);
break;
}
case JSObject::EXTERNAL_UNSIGNED_BYTE_ELEMENTS: {
IterateExternalArrayElements<ExternalUnsignedByteArray, uint8_t>(
isolate, receiver, true, true, visitor);
break;
}
case JSObject::EXTERNAL_SHORT_ELEMENTS: {
IterateExternalArrayElements<ExternalShortArray, int16_t>(
isolate, receiver, true, true, visitor);
break;
}
case JSObject::EXTERNAL_UNSIGNED_SHORT_ELEMENTS: {
IterateExternalArrayElements<ExternalUnsignedShortArray, uint16_t>(
isolate, receiver, true, true, visitor);
break;
}
case JSObject::EXTERNAL_INT_ELEMENTS: {
IterateExternalArrayElements<ExternalIntArray, int32_t>(
isolate, receiver, true, false, visitor);
break;
}
case JSObject::EXTERNAL_UNSIGNED_INT_ELEMENTS: {
IterateExternalArrayElements<ExternalUnsignedIntArray, uint32_t>(
isolate, receiver, true, false, visitor);
break;
}
case JSObject::EXTERNAL_FLOAT_ELEMENTS: {
IterateExternalArrayElements<ExternalFloatArray, float>(
isolate, receiver, false, false, visitor);
break;
}
default:
UNREACHABLE();
break;
}
visitor->increase_index_offset(length);
return true;
}
/**
* Array::concat implementation.
* See ECMAScript 262, 15.4.4.4.
* TODO(581): Fix non-compliance for very large concatenations and update to
* following the ECMAScript 5 specification.
*/
static MaybeObject* Runtime_ArrayConcat(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
HandleScope handle_scope(isolate);
CONVERT_ARG_CHECKED(JSArray, arguments, 0);
int argument_count = static_cast<int>(arguments->length()->Number());
RUNTIME_ASSERT(arguments->HasFastElements());
Handle<FixedArray> elements(FixedArray::cast(arguments->elements()));
// Pass 1: estimate the length and number of elements of the result.
// The actual length can be larger if any of the arguments have getters
// that mutate other arguments (but will otherwise be precise).
// The number of elements is precise if there are no inherited elements.
uint32_t estimate_result_length = 0;
uint32_t estimate_nof_elements = 0;
{
for (int i = 0; i < argument_count; i++) {
HandleScope loop_scope;
Handle<Object> obj(elements->get(i));
uint32_t length_estimate;
uint32_t element_estimate;
if (obj->IsJSArray()) {
Handle<JSArray> array(Handle<JSArray>::cast(obj));
length_estimate =
static_cast<uint32_t>(array->length()->Number());
element_estimate =
EstimateElementCount(array);
} else {
length_estimate = 1;
element_estimate = 1;
}
// Avoid overflows by capping at kMaxElementCount.
if (JSObject::kMaxElementCount - estimate_result_length <
length_estimate) {
estimate_result_length = JSObject::kMaxElementCount;
} else {
estimate_result_length += length_estimate;
}
if (JSObject::kMaxElementCount - estimate_nof_elements <
element_estimate) {
estimate_nof_elements = JSObject::kMaxElementCount;
} else {
estimate_nof_elements += element_estimate;
}
}
}
// If estimated number of elements is more than half of length, a
// fixed array (fast case) is more time and space-efficient than a
// dictionary.
bool fast_case = (estimate_nof_elements * 2) >= estimate_result_length;
Handle<FixedArray> storage;
if (fast_case) {
// The backing storage array must have non-existing elements to
// preserve holes across concat operations.
storage = isolate->factory()->NewFixedArrayWithHoles(
estimate_result_length);
} else {
// TODO(126): move 25% pre-allocation logic into Dictionary::Allocate
uint32_t at_least_space_for = estimate_nof_elements +
(estimate_nof_elements >> 2);
storage = Handle<FixedArray>::cast(
isolate->factory()->NewNumberDictionary(at_least_space_for));
}
ArrayConcatVisitor visitor(isolate, storage, fast_case);
for (int i = 0; i < argument_count; i++) {
Handle<Object> obj(elements->get(i));
if (obj->IsJSArray()) {
Handle<JSArray> array = Handle<JSArray>::cast(obj);
if (!IterateElements(isolate, array, &visitor)) {
return Failure::Exception();
}
} else {
visitor.visit(0, obj);
visitor.increase_index_offset(1);
}
}
return *visitor.ToArray();
}
// This will not allocate (flatten the string), but it may run
// very slowly for very deeply nested ConsStrings. For debugging use only.
static MaybeObject* Runtime_GlobalPrint(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(String, string, args[0]);
StringInputBuffer buffer(string);
while (buffer.has_more()) {
uint16_t character = buffer.GetNext();
PrintF("%c", character);
}
return string;
}
// Moves all own elements of an object, that are below a limit, to positions
// starting at zero. All undefined values are placed after non-undefined values,
// and are followed by non-existing element. Does not change the length
// property.
// Returns the number of non-undefined elements collected.
static MaybeObject* Runtime_RemoveArrayHoles(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSObject, object, args[0]);
CONVERT_NUMBER_CHECKED(uint32_t, limit, Uint32, args[1]);
return object->PrepareElementsForSort(limit);
}
// Move contents of argument 0 (an array) to argument 1 (an array)
static MaybeObject* Runtime_MoveArrayContents(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(JSArray, from, args[0]);
CONVERT_CHECKED(JSArray, to, args[1]);
HeapObject* new_elements = from->elements();
MaybeObject* maybe_new_map;
if (new_elements->map() == isolate->heap()->fixed_array_map() ||
new_elements->map() == isolate->heap()->fixed_cow_array_map()) {
maybe_new_map = to->map()->GetFastElementsMap();
} else {
maybe_new_map = to->map()->GetSlowElementsMap();
}
Object* new_map;
if (!maybe_new_map->ToObject(&new_map)) return maybe_new_map;
to->set_map(Map::cast(new_map));
to->set_elements(new_elements);
to->set_length(from->length());
Object* obj;
{ MaybeObject* maybe_obj = from->ResetElements();
if (!maybe_obj->ToObject(&obj)) return maybe_obj;
}
from->set_length(Smi::FromInt(0));
return to;
}
// How many elements does this object/array have?
static MaybeObject* Runtime_EstimateNumberOfElements(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSObject, object, args[0]);
HeapObject* elements = object->elements();
if (elements->IsDictionary()) {
return Smi::FromInt(NumberDictionary::cast(elements)->NumberOfElements());
} else if (object->IsJSArray()) {
return JSArray::cast(object)->length();
} else {
return Smi::FromInt(FixedArray::cast(elements)->length());
}
}
static MaybeObject* Runtime_SwapElements(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope handle_scope(isolate);
ASSERT_EQ(3, args.length());
CONVERT_ARG_CHECKED(JSObject, object, 0);
Handle<Object> key1 = args.at<Object>(1);
Handle<Object> key2 = args.at<Object>(2);
uint32_t index1, index2;
if (!key1->ToArrayIndex(&index1)
|| !key2->ToArrayIndex(&index2)) {
return isolate->ThrowIllegalOperation();
}
Handle<JSObject> jsobject = Handle<JSObject>::cast(object);
Handle<Object> tmp1 = GetElement(jsobject, index1);
RETURN_IF_EMPTY_HANDLE(isolate, tmp1);
Handle<Object> tmp2 = GetElement(jsobject, index2);
RETURN_IF_EMPTY_HANDLE(isolate, tmp2);
RETURN_IF_EMPTY_HANDLE(isolate,
SetElement(jsobject, index1, tmp2, kStrictMode));
RETURN_IF_EMPTY_HANDLE(isolate,
SetElement(jsobject, index2, tmp1, kStrictMode));
return isolate->heap()->undefined_value();
}
// Returns an array that tells you where in the [0, length) interval an array
// might have elements. Can either return keys (positive integers) or
// intervals (pair of a negative integer (-start-1) followed by a
// positive (length)) or undefined values.
// Intervals can span over some keys that are not in the object.
static MaybeObject* Runtime_GetArrayKeys(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSObject, array, 0);
CONVERT_NUMBER_CHECKED(uint32_t, length, Uint32, args[1]);
if (array->elements()->IsDictionary()) {
// Create an array and get all the keys into it, then remove all the
// keys that are not integers in the range 0 to length-1.
Handle<FixedArray> keys = GetKeysInFixedArrayFor(array, INCLUDE_PROTOS);
int keys_length = keys->length();
for (int i = 0; i < keys_length; i++) {
Object* key = keys->get(i);
uint32_t index = 0;
if (!key->ToArrayIndex(&index) || index >= length) {
// Zap invalid keys.
keys->set_undefined(i);
}
}
return *isolate->factory()->NewJSArrayWithElements(keys);
} else {
ASSERT(array->HasFastElements());
Handle<FixedArray> single_interval = isolate->factory()->NewFixedArray(2);
// -1 means start of array.
single_interval->set(0, Smi::FromInt(-1));
uint32_t actual_length =
static_cast<uint32_t>(FixedArray::cast(array->elements())->length());
uint32_t min_length = actual_length < length ? actual_length : length;
Handle<Object> length_object =
isolate->factory()->NewNumber(static_cast<double>(min_length));
single_interval->set(1, *length_object);
return *isolate->factory()->NewJSArrayWithElements(single_interval);
}
}
// DefineAccessor takes an optional final argument which is the
// property attributes (eg, DONT_ENUM, DONT_DELETE). IMPORTANT: due
// to the way accessors are implemented, it is set for both the getter
// and setter on the first call to DefineAccessor and ignored on
// subsequent calls.
static MaybeObject* Runtime_DefineAccessor(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
RUNTIME_ASSERT(args.length() == 4 || args.length() == 5);
// Compute attributes.
PropertyAttributes attributes = NONE;
if (args.length() == 5) {
CONVERT_CHECKED(Smi, attrs, args[4]);
int value = attrs->value();
// Only attribute bits should be set.
ASSERT((value & ~(READ_ONLY | DONT_ENUM | DONT_DELETE)) == 0);
attributes = static_cast<PropertyAttributes>(value);
}
CONVERT_CHECKED(JSObject, obj, args[0]);
CONVERT_CHECKED(String, name, args[1]);
CONVERT_CHECKED(Smi, flag, args[2]);
CONVERT_CHECKED(JSFunction, fun, args[3]);
return obj->DefineAccessor(name, flag->value() == 0, fun, attributes);
}
static MaybeObject* Runtime_LookupAccessor(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 3);
CONVERT_CHECKED(JSObject, obj, args[0]);
CONVERT_CHECKED(String, name, args[1]);
CONVERT_CHECKED(Smi, flag, args[2]);
return obj->LookupAccessor(name, flag->value() == 0);
}
#ifdef ENABLE_DEBUGGER_SUPPORT
static MaybeObject* Runtime_DebugBreak(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
return Execution::DebugBreakHelper();
}
// Helper functions for wrapping and unwrapping stack frame ids.
static Smi* WrapFrameId(StackFrame::Id id) {
ASSERT(IsAligned(OffsetFrom(id), static_cast<intptr_t>(4)));
return Smi::FromInt(id >> 2);
}
static StackFrame::Id UnwrapFrameId(Smi* wrapped) {
return static_cast<StackFrame::Id>(wrapped->value() << 2);
}
// Adds a JavaScript function as a debug event listener.
// args[0]: debug event listener function to set or null or undefined for
// clearing the event listener function
// args[1]: object supplied during callback
static MaybeObject* Runtime_SetDebugEventListener(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
RUNTIME_ASSERT(args[0]->IsJSFunction() ||
args[0]->IsUndefined() ||
args[0]->IsNull());
Handle<Object> callback = args.at<Object>(0);
Handle<Object> data = args.at<Object>(1);
isolate->debugger()->SetEventListener(callback, data);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_Break(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
isolate->stack_guard()->DebugBreak();
return isolate->heap()->undefined_value();
}
static MaybeObject* DebugLookupResultValue(Heap* heap,
Object* receiver,
String* name,
LookupResult* result,
bool* caught_exception) {
Object* value;
switch (result->type()) {
case NORMAL:
value = result->holder()->GetNormalizedProperty(result);
if (value->IsTheHole()) {
return heap->undefined_value();
}
return value;
case FIELD:
value =
JSObject::cast(
result->holder())->FastPropertyAt(result->GetFieldIndex());
if (value->IsTheHole()) {
return heap->undefined_value();
}
return value;
case CONSTANT_FUNCTION:
return result->GetConstantFunction();
case CALLBACKS: {
Object* structure = result->GetCallbackObject();
if (structure->IsProxy() || structure->IsAccessorInfo()) {
MaybeObject* maybe_value = receiver->GetPropertyWithCallback(
receiver, structure, name, result->holder());
if (!maybe_value->ToObject(&value)) {
if (maybe_value->IsRetryAfterGC()) return maybe_value;
ASSERT(maybe_value->IsException());
maybe_value = heap->isolate()->pending_exception();
heap->isolate()->clear_pending_exception();
if (caught_exception != NULL) {
*caught_exception = true;
}
return maybe_value;
}
return value;
} else {
return heap->undefined_value();
}
}
case INTERCEPTOR:
case MAP_TRANSITION:
case CONSTANT_TRANSITION:
case NULL_DESCRIPTOR:
return heap->undefined_value();
default:
UNREACHABLE();
}
UNREACHABLE();
return heap->undefined_value();
}
// Get debugger related details for an object property.
// args[0]: object holding property
// args[1]: name of the property
//
// The array returned contains the following information:
// 0: Property value
// 1: Property details
// 2: Property value is exception
// 3: Getter function if defined
// 4: Setter function if defined
// Items 2-4 are only filled if the property has either a getter or a setter
// defined through __defineGetter__ and/or __defineSetter__.
static MaybeObject* Runtime_DebugGetPropertyDetails(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
CONVERT_ARG_CHECKED(String, name, 1);
// Make sure to set the current context to the context before the debugger was
// entered (if the debugger is entered). The reason for switching context here
// is that for some property lookups (accessors and interceptors) callbacks
// into the embedding application can occour, and the embedding application
// could have the assumption that its own global context is the current
// context and not some internal debugger context.
SaveContext save(isolate);
if (isolate->debug()->InDebugger()) {
isolate->set_context(*isolate->debug()->debugger_entry()->GetContext());
}
// Skip the global proxy as it has no properties and always delegates to the
// real global object.
if (obj->IsJSGlobalProxy()) {
obj = Handle<JSObject>(JSObject::cast(obj->GetPrototype()));
}
// Check if the name is trivially convertible to an index and get the element
// if so.
uint32_t index;
if (name->AsArrayIndex(&index)) {
Handle<FixedArray> details = isolate->factory()->NewFixedArray(2);
Object* element_or_char;
{ MaybeObject* maybe_element_or_char =
Runtime::GetElementOrCharAt(isolate, obj, index);
if (!maybe_element_or_char->ToObject(&element_or_char)) {
return maybe_element_or_char;
}
}
details->set(0, element_or_char);
details->set(1, PropertyDetails(NONE, NORMAL).AsSmi());
return *isolate->factory()->NewJSArrayWithElements(details);
}
// Find the number of objects making up this.
int length = LocalPrototypeChainLength(*obj);
// Try local lookup on each of the objects.
Handle<JSObject> jsproto = obj;
for (int i = 0; i < length; i++) {
LookupResult result;
jsproto->LocalLookup(*name, &result);
if (result.IsProperty()) {
// LookupResult is not GC safe as it holds raw object pointers.
// GC can happen later in this code so put the required fields into
// local variables using handles when required for later use.
PropertyType result_type = result.type();
Handle<Object> result_callback_obj;
if (result_type == CALLBACKS) {
result_callback_obj = Handle<Object>(result.GetCallbackObject(),
isolate);
}
Smi* property_details = result.GetPropertyDetails().AsSmi();
// DebugLookupResultValue can cause GC so details from LookupResult needs
// to be copied to handles before this.
bool caught_exception = false;
Object* raw_value;
{ MaybeObject* maybe_raw_value =
DebugLookupResultValue(isolate->heap(), *obj, *name,
&result, &caught_exception);
if (!maybe_raw_value->ToObject(&raw_value)) return maybe_raw_value;
}
Handle<Object> value(raw_value, isolate);
// If the callback object is a fixed array then it contains JavaScript
// getter and/or setter.
bool hasJavaScriptAccessors = result_type == CALLBACKS &&
result_callback_obj->IsFixedArray();
Handle<FixedArray> details =
isolate->factory()->NewFixedArray(hasJavaScriptAccessors ? 5 : 2);
details->set(0, *value);
details->set(1, property_details);
if (hasJavaScriptAccessors) {
details->set(2,
caught_exception ? isolate->heap()->true_value()
: isolate->heap()->false_value());
details->set(3, FixedArray::cast(*result_callback_obj)->get(0));
details->set(4, FixedArray::cast(*result_callback_obj)->get(1));
}
return *isolate->factory()->NewJSArrayWithElements(details);
}
if (i < length - 1) {
jsproto = Handle<JSObject>(JSObject::cast(jsproto->GetPrototype()));
}
}
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_DebugGetProperty(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
CONVERT_ARG_CHECKED(String, name, 1);
LookupResult result;
obj->Lookup(*name, &result);
if (result.IsProperty()) {
return DebugLookupResultValue(isolate->heap(), *obj, *name, &result, NULL);
}
return isolate->heap()->undefined_value();
}
// Return the property type calculated from the property details.
// args[0]: smi with property details.
static MaybeObject* Runtime_DebugPropertyTypeFromDetails(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(Smi, details, args[0]);
PropertyType type = PropertyDetails(details).type();
return Smi::FromInt(static_cast<int>(type));
}
// Return the property attribute calculated from the property details.
// args[0]: smi with property details.
static MaybeObject* Runtime_DebugPropertyAttributesFromDetails(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(Smi, details, args[0]);
PropertyAttributes attributes = PropertyDetails(details).attributes();
return Smi::FromInt(static_cast<int>(attributes));
}
// Return the property insertion index calculated from the property details.
// args[0]: smi with property details.
static MaybeObject* Runtime_DebugPropertyIndexFromDetails(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(Smi, details, args[0]);
int index = PropertyDetails(details).index();
return Smi::FromInt(index);
}
// Return property value from named interceptor.
// args[0]: object
// args[1]: property name
static MaybeObject* Runtime_DebugNamedInterceptorPropertyValue(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
RUNTIME_ASSERT(obj->HasNamedInterceptor());
CONVERT_ARG_CHECKED(String, name, 1);
PropertyAttributes attributes;
return obj->GetPropertyWithInterceptor(*obj, *name, &attributes);
}
// Return element value from indexed interceptor.
// args[0]: object
// args[1]: index
static MaybeObject* Runtime_DebugIndexedInterceptorElementValue(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
CONVERT_ARG_CHECKED(JSObject, obj, 0);
RUNTIME_ASSERT(obj->HasIndexedInterceptor());
CONVERT_NUMBER_CHECKED(uint32_t, index, Uint32, args[1]);
return obj->GetElementWithInterceptor(*obj, index);
}
static MaybeObject* Runtime_CheckExecutionState(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() >= 1);
CONVERT_NUMBER_CHECKED(int, break_id, Int32, args[0]);
// Check that the break id is valid.
if (isolate->debug()->break_id() == 0 ||
break_id != isolate->debug()->break_id()) {
return isolate->Throw(
isolate->heap()->illegal_execution_state_symbol());
}
return isolate->heap()->true_value();
}
static MaybeObject* Runtime_GetFrameCount(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
// Check arguments.
Object* result;
{ MaybeObject* maybe_result = Runtime_CheckExecutionState(args, isolate);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
// Count all frames which are relevant to debugging stack trace.
int n = 0;
StackFrame::Id id = isolate->debug()->break_frame_id();
if (id == StackFrame::NO_ID) {
// If there is no JavaScript stack frame count is 0.
return Smi::FromInt(0);
}
for (JavaScriptFrameIterator it(id); !it.done(); it.Advance()) n++;
return Smi::FromInt(n);
}
static const int kFrameDetailsFrameIdIndex = 0;
static const int kFrameDetailsReceiverIndex = 1;
static const int kFrameDetailsFunctionIndex = 2;
static const int kFrameDetailsArgumentCountIndex = 3;
static const int kFrameDetailsLocalCountIndex = 4;
static const int kFrameDetailsSourcePositionIndex = 5;
static const int kFrameDetailsConstructCallIndex = 6;
static const int kFrameDetailsAtReturnIndex = 7;
static const int kFrameDetailsDebuggerFrameIndex = 8;
static const int kFrameDetailsFirstDynamicIndex = 9;
// Return an array with frame details
// args[0]: number: break id
// args[1]: number: frame index
//
// The array returned contains the following information:
// 0: Frame id
// 1: Receiver
// 2: Function
// 3: Argument count
// 4: Local count
// 5: Source position
// 6: Constructor call
// 7: Is at return
// 8: Debugger frame
// Arguments name, value
// Locals name, value
// Return value if any
static MaybeObject* Runtime_GetFrameDetails(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
// Check arguments.
Object* check;
{ MaybeObject* maybe_check = Runtime_CheckExecutionState(args, isolate);
if (!maybe_check->ToObject(&check)) return maybe_check;
}
CONVERT_NUMBER_CHECKED(int, index, Int32, args[1]);
Heap* heap = isolate->heap();
// Find the relevant frame with the requested index.
StackFrame::Id id = isolate->debug()->break_frame_id();
if (id == StackFrame::NO_ID) {
// If there are no JavaScript stack frames return undefined.
return heap->undefined_value();
}
int count = 0;
JavaScriptFrameIterator it(id);
for (; !it.done(); it.Advance()) {
if (count == index) break;
count++;
}
if (it.done()) return heap->undefined_value();
bool is_optimized_frame =
it.frame()->LookupCode(isolate)->kind() == Code::OPTIMIZED_FUNCTION;
// Traverse the saved contexts chain to find the active context for the
// selected frame.
SaveContext* save = isolate->save_context();
while (save != NULL && !save->below(it.frame())) {
save = save->prev();
}
ASSERT(save != NULL);
// Get the frame id.
Handle<Object> frame_id(WrapFrameId(it.frame()->id()), isolate);
// Find source position.
int position =
it.frame()->LookupCode(isolate)->SourcePosition(it.frame()->pc());
// Check for constructor frame.
bool constructor = it.frame()->IsConstructor();
// Get scope info and read from it for local variable information.
Handle<JSFunction> function(JSFunction::cast(it.frame()->function()));
Handle<SerializedScopeInfo> scope_info(function->shared()->scope_info());
ScopeInfo<> info(*scope_info);
// Get the context.
Handle<Context> context(Context::cast(it.frame()->context()));
// Get the locals names and values into a temporary array.
//
// TODO(1240907): Hide compiler-introduced stack variables
// (e.g. .result)? For users of the debugger, they will probably be
// confusing.
Handle<FixedArray> locals =
isolate->factory()->NewFixedArray(info.NumberOfLocals() * 2);
// Fill in the names of the locals.
for (int i = 0; i < info.NumberOfLocals(); i++) {
locals->set(i * 2, *info.LocalName(i));
}
// Fill in the values of the locals.
for (int i = 0; i < info.NumberOfLocals(); i++) {
if (is_optimized_frame) {
// If we are inspecting an optimized frame use undefined as the
// value for all locals.
//
// TODO(1140): We should be able to get the correct values
// for locals in optimized frames.
locals->set(i * 2 + 1, isolate->heap()->undefined_value());
} else if (i < info.number_of_stack_slots()) {
// Get the value from the stack.
locals->set(i * 2 + 1, it.frame()->GetExpression(i));
} else {
// Traverse the context chain to the function context as all local
// variables stored in the context will be on the function context.
Handle<String> name = info.LocalName(i);
while (!context->is_function_context()) {
context = Handle<Context>(context->previous());
}
ASSERT(context->is_function_context());
locals->set(i * 2 + 1,
context->get(scope_info->ContextSlotIndex(*name, NULL)));
}
}
// Check whether this frame is positioned at return. If not top
// frame or if the frame is optimized it cannot be at a return.
bool at_return = false;
if (!is_optimized_frame && index == 0) {
at_return = isolate->debug()->IsBreakAtReturn(it.frame());
}
// If positioned just before return find the value to be returned and add it
// to the frame information.
Handle<Object> return_value = isolate->factory()->undefined_value();
if (at_return) {
StackFrameIterator it2;
Address internal_frame_sp = NULL;
while (!it2.done()) {
if (it2.frame()->is_internal()) {
internal_frame_sp = it2.frame()->sp();
} else {
if (it2.frame()->is_java_script()) {
if (it2.frame()->id() == it.frame()->id()) {
// The internal frame just before the JavaScript frame contains the
// value to return on top. A debug break at return will create an
// internal frame to store the return value (eax/rax/r0) before
// entering the debug break exit frame.
if (internal_frame_sp != NULL) {
return_value =
Handle<Object>(Memory::Object_at(internal_frame_sp),
isolate);
break;
}
}
}
// Indicate that the previous frame was not an internal frame.
internal_frame_sp = NULL;
}
it2.Advance();
}
}
// Now advance to the arguments adapter frame (if any). It contains all
// the provided parameters whereas the function frame always have the number
// of arguments matching the functions parameters. The rest of the
// information (except for what is collected above) is the same.
it.AdvanceToArgumentsFrame();
// Find the number of arguments to fill. At least fill the number of
// parameters for the function and fill more if more parameters are provided.
int argument_count = info.number_of_parameters();
if (argument_count < it.frame()->ComputeParametersCount()) {
argument_count = it.frame()->ComputeParametersCount();
}
// Calculate the size of the result.
int details_size = kFrameDetailsFirstDynamicIndex +
2 * (argument_count + info.NumberOfLocals()) +
(at_return ? 1 : 0);
Handle<FixedArray> details = isolate->factory()->NewFixedArray(details_size);
// Add the frame id.
details->set(kFrameDetailsFrameIdIndex, *frame_id);
// Add the function (same as in function frame).
details->set(kFrameDetailsFunctionIndex, it.frame()->function());
// Add the arguments count.
details->set(kFrameDetailsArgumentCountIndex, Smi::FromInt(argument_count));
// Add the locals count
details->set(kFrameDetailsLocalCountIndex,
Smi::FromInt(info.NumberOfLocals()));
// Add the source position.
if (position != RelocInfo::kNoPosition) {
details->set(kFrameDetailsSourcePositionIndex, Smi::FromInt(position));
} else {
details->set(kFrameDetailsSourcePositionIndex, heap->undefined_value());
}
// Add the constructor information.
details->set(kFrameDetailsConstructCallIndex, heap->ToBoolean(constructor));
// Add the at return information.
details->set(kFrameDetailsAtReturnIndex, heap->ToBoolean(at_return));
// Add information on whether this frame is invoked in the debugger context.
details->set(kFrameDetailsDebuggerFrameIndex,
heap->ToBoolean(*save->context() ==
*isolate->debug()->debug_context()));
// Fill the dynamic part.
int details_index = kFrameDetailsFirstDynamicIndex;
// Add arguments name and value.
for (int i = 0; i < argument_count; i++) {
// Name of the argument.
if (i < info.number_of_parameters()) {
details->set(details_index++, *info.parameter_name(i));
} else {
details->set(details_index++, heap->undefined_value());
}
// Parameter value. If we are inspecting an optimized frame, use
// undefined as the value.
//
// TODO(3141533): We should be able to get the actual parameter
// value for optimized frames.
if (!is_optimized_frame &&
(i < it.frame()->ComputeParametersCount())) {
details->set(details_index++, it.frame()->GetParameter(i));
} else {
details->set(details_index++, heap->undefined_value());
}
}
// Add locals name and value from the temporary copy from the function frame.
for (int i = 0; i < info.NumberOfLocals() * 2; i++) {
details->set(details_index++, locals->get(i));
}
// Add the value being returned.
if (at_return) {
details->set(details_index++, *return_value);
}
// Add the receiver (same as in function frame).
// THIS MUST BE DONE LAST SINCE WE MIGHT ADVANCE
// THE FRAME ITERATOR TO WRAP THE RECEIVER.
Handle<Object> receiver(it.frame()->receiver(), isolate);
if (!receiver->IsJSObject()) {
// If the receiver is NOT a JSObject we have hit an optimization
// where a value object is not converted into a wrapped JS objects.
// To hide this optimization from the debugger, we wrap the receiver
// by creating correct wrapper object based on the calling frame's
// global context.
it.Advance();
Handle<Context> calling_frames_global_context(
Context::cast(Context::cast(it.frame()->context())->global_context()));
receiver =
isolate->factory()->ToObject(receiver, calling_frames_global_context);
}
details->set(kFrameDetailsReceiverIndex, *receiver);
ASSERT_EQ(details_size, details_index);
return *isolate->factory()->NewJSArrayWithElements(details);
}
// Copy all the context locals into an object used to materialize a scope.
static bool CopyContextLocalsToScopeObject(
Isolate* isolate,
Handle<SerializedScopeInfo> serialized_scope_info,
ScopeInfo<>& scope_info,
Handle<Context> context,
Handle<JSObject> scope_object) {
// Fill all context locals to the context extension.
for (int i = Context::MIN_CONTEXT_SLOTS;
i < scope_info.number_of_context_slots();
i++) {
int context_index = serialized_scope_info->ContextSlotIndex(
*scope_info.context_slot_name(i), NULL);
// Don't include the arguments shadow (.arguments) context variable.
if (*scope_info.context_slot_name(i) !=
isolate->heap()->arguments_shadow_symbol()) {
RETURN_IF_EMPTY_HANDLE_VALUE(
isolate,
SetProperty(scope_object,
scope_info.context_slot_name(i),
Handle<Object>(context->get(context_index), isolate),
NONE,
kNonStrictMode),
false);
}
}
return true;
}
// Create a plain JSObject which materializes the local scope for the specified
// frame.
static Handle<JSObject> MaterializeLocalScope(Isolate* isolate,
JavaScriptFrame* frame) {
Handle<JSFunction> function(JSFunction::cast(frame->function()));
Handle<SharedFunctionInfo> shared(function->shared());
Handle<SerializedScopeInfo> serialized_scope_info(shared->scope_info());
ScopeInfo<> scope_info(*serialized_scope_info);
// Allocate and initialize a JSObject with all the arguments, stack locals
// heap locals and extension properties of the debugged function.
Handle<JSObject> local_scope =
isolate->factory()->NewJSObject(isolate->object_function());
// First fill all parameters.
for (int i = 0; i < scope_info.number_of_parameters(); ++i) {
RETURN_IF_EMPTY_HANDLE_VALUE(
isolate,
SetProperty(local_scope,
scope_info.parameter_name(i),
Handle<Object>(frame->GetParameter(i), isolate),
NONE,
kNonStrictMode),
Handle<JSObject>());
}
// Second fill all stack locals.
for (int i = 0; i < scope_info.number_of_stack_slots(); i++) {
RETURN_IF_EMPTY_HANDLE_VALUE(
isolate,
SetProperty(local_scope,
scope_info.stack_slot_name(i),
Handle<Object>(frame->GetExpression(i), isolate),
NONE,
kNonStrictMode),
Handle<JSObject>());
}
// Third fill all context locals.
Handle<Context> frame_context(Context::cast(frame->context()));
Handle<Context> function_context(frame_context->fcontext());
if (!CopyContextLocalsToScopeObject(isolate,
serialized_scope_info, scope_info,
function_context, local_scope)) {
return Handle<JSObject>();
}
// Finally copy any properties from the function context extension. This will
// be variables introduced by eval.
if (function_context->closure() == *function) {
if (function_context->has_extension() &&
!function_context->IsGlobalContext()) {
Handle<JSObject> ext(JSObject::cast(function_context->extension()));
Handle<FixedArray> keys = GetKeysInFixedArrayFor(ext, INCLUDE_PROTOS);
for (int i = 0; i < keys->length(); i++) {
// Names of variables introduced by eval are strings.
ASSERT(keys->get(i)->IsString());
Handle<String> key(String::cast(keys->get(i)));
RETURN_IF_EMPTY_HANDLE_VALUE(
isolate,
SetProperty(local_scope,
key,
GetProperty(ext, key),
NONE,
kNonStrictMode),
Handle<JSObject>());
}
}
}
return local_scope;
}
// Create a plain JSObject which materializes the closure content for the
// context.
static Handle<JSObject> MaterializeClosure(Isolate* isolate,
Handle<Context> context) {
ASSERT(context->is_function_context());
Handle<SharedFunctionInfo> shared(context->closure()->shared());
Handle<SerializedScopeInfo> serialized_scope_info(shared->scope_info());
ScopeInfo<> scope_info(*serialized_scope_info);
// Allocate and initialize a JSObject with all the content of theis function
// closure.
Handle<JSObject> closure_scope =
isolate->factory()->NewJSObject(isolate->object_function());
// Check whether the arguments shadow object exists.
int arguments_shadow_index =
shared->scope_info()->ContextSlotIndex(
isolate->heap()->arguments_shadow_symbol(), NULL);
if (arguments_shadow_index >= 0) {
// In this case all the arguments are available in the arguments shadow
// object.
Handle<JSObject> arguments_shadow(
JSObject::cast(context->get(arguments_shadow_index)));
for (int i = 0; i < scope_info.number_of_parameters(); ++i) {
// We don't expect exception-throwing getters on the arguments shadow.
Object* element = arguments_shadow->GetElement(i)->ToObjectUnchecked();
RETURN_IF_EMPTY_HANDLE_VALUE(
isolate,
SetProperty(closure_scope,
scope_info.parameter_name(i),
Handle<Object>(element, isolate),
NONE,
kNonStrictMode),
Handle<JSObject>());
}
}
// Fill all context locals to the context extension.
if (!CopyContextLocalsToScopeObject(isolate,
serialized_scope_info, scope_info,
context, closure_scope)) {
return Handle<JSObject>();
}
// Finally copy any properties from the function context extension. This will
// be variables introduced by eval.
if (context->has_extension()) {
Handle<JSObject> ext(JSObject::cast(context->extension()));
Handle<FixedArray> keys = GetKeysInFixedArrayFor(ext, INCLUDE_PROTOS);
for (int i = 0; i < keys->length(); i++) {
// Names of variables introduced by eval are strings.
ASSERT(keys->get(i)->IsString());
Handle<String> key(String::cast(keys->get(i)));
RETURN_IF_EMPTY_HANDLE_VALUE(
isolate,
SetProperty(closure_scope,
key,
GetProperty(ext, key),
NONE,
kNonStrictMode),
Handle<JSObject>());
}
}
return closure_scope;
}
// Iterate over the actual scopes visible from a stack frame. All scopes are
// backed by an actual context except the local scope, which is inserted
// "artifically" in the context chain.
class ScopeIterator {
public:
enum ScopeType {
ScopeTypeGlobal = 0,
ScopeTypeLocal,
ScopeTypeWith,
ScopeTypeClosure,
// Every catch block contains an implicit with block (its parameter is
// a JSContextExtensionObject) that extends current scope with a variable
// holding exception object. Such with blocks are treated as scopes of their
// own type.
ScopeTypeCatch
};
ScopeIterator(Isolate* isolate, JavaScriptFrame* frame)
: isolate_(isolate),
frame_(frame),
function_(JSFunction::cast(frame->function())),
context_(Context::cast(frame->context())),
local_done_(false),
at_local_(false) {
// Check whether the first scope is actually a local scope.
if (context_->IsGlobalContext()) {
// If there is a stack slot for .result then this local scope has been
// created for evaluating top level code and it is not a real local scope.
// Checking for the existence of .result seems fragile, but the scope info
// saved with the code object does not otherwise have that information.
int index = function_->shared()->scope_info()->
StackSlotIndex(isolate_->heap()->result_symbol());
at_local_ = index < 0;
} else if (context_->is_function_context()) {
at_local_ = true;
}
}
// More scopes?
bool Done() { return context_.is_null(); }
// Move to the next scope.
void Next() {
// If at a local scope mark the local scope as passed.
if (at_local_) {
at_local_ = false;
local_done_ = true;
// If the current context is not associated with the local scope the
// current context is the next real scope, so don't move to the next
// context in this case.
if (context_->closure() != *function_) {
return;
}
}
// The global scope is always the last in the chain.
if (context_->IsGlobalContext()) {
context_ = Handle<Context>();
return;
}
// Move to the next context.
if (context_->is_function_context()) {
context_ = Handle<Context>(Context::cast(context_->closure()->context()));
} else {
context_ = Handle<Context>(context_->previous());
}
// If passing the local scope indicate that the current scope is now the
// local scope.
if (!local_done_ &&
(context_->IsGlobalContext() || (context_->is_function_context()))) {
at_local_ = true;
}
}
// Return the type of the current scope.
int Type() {
if (at_local_) {
return ScopeTypeLocal;
}
if (context_->IsGlobalContext()) {
ASSERT(context_->global()->IsGlobalObject());
return ScopeTypeGlobal;
}
if (context_->is_function_context()) {
return ScopeTypeClosure;
}
ASSERT(context_->has_extension());
// Current scope is either an explicit with statement or a with statement
// implicitely generated for a catch block.
// If the extension object here is a JSContextExtensionObject then
// current with statement is one frome a catch block otherwise it's a
// regular with statement.
if (context_->extension()->IsJSContextExtensionObject()) {
return ScopeTypeCatch;
}
return ScopeTypeWith;
}
// Return the JavaScript object with the content of the current scope.
Handle<JSObject> ScopeObject() {
switch (Type()) {
case ScopeIterator::ScopeTypeGlobal:
return Handle<JSObject>(CurrentContext()->global());
break;
case ScopeIterator::ScopeTypeLocal:
// Materialize the content of the local scope into a JSObject.
return MaterializeLocalScope(isolate_, frame_);
break;
case ScopeIterator::ScopeTypeWith:
case ScopeIterator::ScopeTypeCatch:
// Return the with object.
return Handle<JSObject>(CurrentContext()->extension());
break;
case ScopeIterator::ScopeTypeClosure:
// Materialize the content of the closure scope into a JSObject.
return MaterializeClosure(isolate_, CurrentContext());
break;
}
UNREACHABLE();
return Handle<JSObject>();
}
// Return the context for this scope. For the local context there might not
// be an actual context.
Handle<Context> CurrentContext() {
if (at_local_ && context_->closure() != *function_) {
return Handle<Context>();
}
return context_;
}
#ifdef DEBUG
// Debug print of the content of the current scope.
void DebugPrint() {
switch (Type()) {
case ScopeIterator::ScopeTypeGlobal:
PrintF("Global:\n");
CurrentContext()->Print();
break;
case ScopeIterator::ScopeTypeLocal: {
PrintF("Local:\n");
ScopeInfo<> scope_info(function_->shared()->scope_info());
scope_info.Print();
if (!CurrentContext().is_null()) {
CurrentContext()->Print();
if (CurrentContext()->has_extension()) {
Handle<JSObject> extension =
Handle<JSObject>(CurrentContext()->extension());
if (extension->IsJSContextExtensionObject()) {
extension->Print();
}
}
}
break;
}
case ScopeIterator::ScopeTypeWith: {
PrintF("With:\n");
Handle<JSObject> extension =
Handle<JSObject>(CurrentContext()->extension());
extension->Print();
break;
}
case ScopeIterator::ScopeTypeCatch: {
PrintF("Catch:\n");
Handle<JSObject> extension =
Handle<JSObject>(CurrentContext()->extension());
extension->Print();
break;
}
case ScopeIterator::ScopeTypeClosure: {
PrintF("Closure:\n");
CurrentContext()->Print();
if (CurrentContext()->has_extension()) {
Handle<JSObject> extension =
Handle<JSObject>(CurrentContext()->extension());
if (extension->IsJSContextExtensionObject()) {
extension->Print();
}
}
break;
}
default:
UNREACHABLE();
}
PrintF("\n");
}
#endif
private:
Isolate* isolate_;
JavaScriptFrame* frame_;
Handle<JSFunction> function_;
Handle<Context> context_;
bool local_done_;
bool at_local_;
DISALLOW_IMPLICIT_CONSTRUCTORS(ScopeIterator);
};
static MaybeObject* Runtime_GetScopeCount(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
// Check arguments.
Object* check;
{ MaybeObject* maybe_check = Runtime_CheckExecutionState(args, isolate);
if (!maybe_check->ToObject(&check)) return maybe_check;
}
CONVERT_CHECKED(Smi, wrapped_id, args[1]);
// Get the frame where the debugging is performed.
StackFrame::Id id = UnwrapFrameId(wrapped_id);
JavaScriptFrameIterator it(id);
JavaScriptFrame* frame = it.frame();
// Count the visible scopes.
int n = 0;
for (ScopeIterator it(isolate, frame); !it.Done(); it.Next()) {
n++;
}
return Smi::FromInt(n);
}
static const int kScopeDetailsTypeIndex = 0;
static const int kScopeDetailsObjectIndex = 1;
static const int kScopeDetailsSize = 2;
// Return an array with scope details
// args[0]: number: break id
// args[1]: number: frame index
// args[2]: number: scope index
//
// The array returned contains the following information:
// 0: Scope type
// 1: Scope object
static MaybeObject* Runtime_GetScopeDetails(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
// Check arguments.
Object* check;
{ MaybeObject* maybe_check = Runtime_CheckExecutionState(args, isolate);
if (!maybe_check->ToObject(&check)) return maybe_check;
}
CONVERT_CHECKED(Smi, wrapped_id, args[1]);
CONVERT_NUMBER_CHECKED(int, index, Int32, args[2]);
// Get the frame where the debugging is performed.
StackFrame::Id id = UnwrapFrameId(wrapped_id);
JavaScriptFrameIterator frame_it(id);
JavaScriptFrame* frame = frame_it.frame();
// Find the requested scope.
int n = 0;
ScopeIterator it(isolate, frame);
for (; !it.Done() && n < index; it.Next()) {
n++;
}
if (it.Done()) {
return isolate->heap()->undefined_value();
}
// Calculate the size of the result.
int details_size = kScopeDetailsSize;
Handle<FixedArray> details = isolate->factory()->NewFixedArray(details_size);
// Fill in scope details.
details->set(kScopeDetailsTypeIndex, Smi::FromInt(it.Type()));
Handle<JSObject> scope_object = it.ScopeObject();
RETURN_IF_EMPTY_HANDLE(isolate, scope_object);
details->set(kScopeDetailsObjectIndex, *scope_object);
return *isolate->factory()->NewJSArrayWithElements(details);
}
static MaybeObject* Runtime_DebugPrintScopes(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 0);
#ifdef DEBUG
// Print the scopes for the top frame.
StackFrameLocator locator;
JavaScriptFrame* frame = locator.FindJavaScriptFrame(0);
for (ScopeIterator it(isolate, frame); !it.Done(); it.Next()) {
it.DebugPrint();
}
#endif
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_GetThreadCount(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
// Check arguments.
Object* result;
{ MaybeObject* maybe_result = Runtime_CheckExecutionState(args, isolate);
if (!maybe_result->ToObject(&result)) return maybe_result;
}
// Count all archived V8 threads.
int n = 0;
for (ThreadState* thread =
isolate->thread_manager()->FirstThreadStateInUse();
thread != NULL;
thread = thread->Next()) {
n++;
}
// Total number of threads is current thread and archived threads.
return Smi::FromInt(n + 1);
}
static const int kThreadDetailsCurrentThreadIndex = 0;
static const int kThreadDetailsThreadIdIndex = 1;
static const int kThreadDetailsSize = 2;
// Return an array with thread details
// args[0]: number: break id
// args[1]: number: thread index
//
// The array returned contains the following information:
// 0: Is current thread?
// 1: Thread id
static MaybeObject* Runtime_GetThreadDetails(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
// Check arguments.
Object* check;
{ MaybeObject* maybe_check = Runtime_CheckExecutionState(args, isolate);
if (!maybe_check->ToObject(&check)) return maybe_check;
}
CONVERT_NUMBER_CHECKED(int, index, Int32, args[1]);
// Allocate array for result.
Handle<FixedArray> details =
isolate->factory()->NewFixedArray(kThreadDetailsSize);
// Thread index 0 is current thread.
if (index == 0) {
// Fill the details.
details->set(kThreadDetailsCurrentThreadIndex,
isolate->heap()->true_value());
details->set(kThreadDetailsThreadIdIndex,
Smi::FromInt(
isolate->thread_manager()->CurrentId()));
} else {
// Find the thread with the requested index.
int n = 1;
ThreadState* thread =
isolate->thread_manager()->FirstThreadStateInUse();
while (index != n && thread != NULL) {
thread = thread->Next();
n++;
}
if (thread == NULL) {
return isolate->heap()->undefined_value();
}
// Fill the details.
details->set(kThreadDetailsCurrentThreadIndex,
isolate->heap()->false_value());
details->set(kThreadDetailsThreadIdIndex, Smi::FromInt(thread->id()));
}
// Convert to JS array and return.
return *isolate->factory()->NewJSArrayWithElements(details);
}
// Sets the disable break state
// args[0]: disable break state
static MaybeObject* Runtime_SetDisableBreak(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_BOOLEAN_CHECKED(disable_break, args[0]);
isolate->debug()->set_disable_break(disable_break);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_GetBreakLocations(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_ARG_CHECKED(JSFunction, fun, 0);
Handle<SharedFunctionInfo> shared(fun->shared());
// Find the number of break points
Handle<Object> break_locations = Debug::GetSourceBreakLocations(shared);
if (break_locations->IsUndefined()) return isolate->heap()->undefined_value();
// Return array as JS array
return *isolate->factory()->NewJSArrayWithElements(
Handle<FixedArray>::cast(break_locations));
}
// Set a break point in a function
// args[0]: function
// args[1]: number: break source position (within the function source)
// args[2]: number: break point object
static MaybeObject* Runtime_SetFunctionBreakPoint(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(JSFunction, fun, 0);
Handle<SharedFunctionInfo> shared(fun->shared());
CONVERT_NUMBER_CHECKED(int32_t, source_position, Int32, args[1]);
RUNTIME_ASSERT(source_position >= 0);
Handle<Object> break_point_object_arg = args.at<Object>(2);
// Set break point.
isolate->debug()->SetBreakPoint(shared, break_point_object_arg,
&source_position);
return Smi::FromInt(source_position);
}
Object* Runtime::FindSharedFunctionInfoInScript(Isolate* isolate,
Handle<Script> script,
int position) {
// Iterate the heap looking for SharedFunctionInfo generated from the
// script. The inner most SharedFunctionInfo containing the source position
// for the requested break point is found.
// NOTE: This might require several heap iterations. If the SharedFunctionInfo
// which is found is not compiled it is compiled and the heap is iterated
// again as the compilation might create inner functions from the newly
// compiled function and the actual requested break point might be in one of
// these functions.
bool done = false;
// The current candidate for the source position:
int target_start_position = RelocInfo::kNoPosition;
Handle<SharedFunctionInfo> target;
while (!done) {
HeapIterator iterator;
for (HeapObject* obj = iterator.next();
obj != NULL; obj = iterator.next()) {
if (obj->IsSharedFunctionInfo()) {
Handle<SharedFunctionInfo> shared(SharedFunctionInfo::cast(obj));
if (shared->script() == *script) {
// If the SharedFunctionInfo found has the requested script data and
// contains the source position it is a candidate.
int start_position = shared->function_token_position();
if (start_position == RelocInfo::kNoPosition) {
start_position = shared->start_position();
}
if (start_position <= position &&
position <= shared->end_position()) {
// If there is no candidate or this function is within the current
// candidate this is the new candidate.
if (target.is_null()) {
target_start_position = start_position;
target = shared;
} else {
if (target_start_position == start_position &&
shared->end_position() == target->end_position()) {
// If a top-level function contain only one function
// declartion the source for the top-level and the function is
// the same. In that case prefer the non top-level function.
if (!shared->is_toplevel()) {
target_start_position = start_position;
target = shared;
}
} else if (target_start_position <= start_position &&
shared->end_position() <= target->end_position()) {
// This containment check includes equality as a function inside
// a top-level function can share either start or end position
// with the top-level function.
target_start_position = start_position;
target = shared;
}
}
}
}
}
}
if (target.is_null()) {
return isolate->heap()->undefined_value();
}
// If the candidate found is compiled we are done. NOTE: when lazy
// compilation of inner functions is introduced some additional checking
// needs to be done here to compile inner functions.
done = target->is_compiled();
if (!done) {
// If the candidate is not compiled compile it to reveal any inner
// functions which might contain the requested source position.
CompileLazyShared(target, KEEP_EXCEPTION);
}
}
return *target;
}
// Changes the state of a break point in a script and returns source position
// where break point was set. NOTE: Regarding performance see the NOTE for
// GetScriptFromScriptData.
// args[0]: script to set break point in
// args[1]: number: break source position (within the script source)
// args[2]: number: break point object
static MaybeObject* Runtime_SetScriptBreakPoint(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
CONVERT_ARG_CHECKED(JSValue, wrapper, 0);
CONVERT_NUMBER_CHECKED(int32_t, source_position, Int32, args[1]);
RUNTIME_ASSERT(source_position >= 0);
Handle<Object> break_point_object_arg = args.at<Object>(2);
// Get the script from the script wrapper.
RUNTIME_ASSERT(wrapper->value()->IsScript());
Handle<Script> script(Script::cast(wrapper->value()));
Object* result = Runtime::FindSharedFunctionInfoInScript(
isolate, script, source_position);
if (!result->IsUndefined()) {
Handle<SharedFunctionInfo> shared(SharedFunctionInfo::cast(result));
// Find position within function. The script position might be before the
// source position of the first function.
int position;
if (shared->start_position() > source_position) {
position = 0;
} else {
position = source_position - shared->start_position();
}
isolate->debug()->SetBreakPoint(shared, break_point_object_arg, &position);
position += shared->start_position();
return Smi::FromInt(position);
}
return isolate->heap()->undefined_value();
}
// Clear a break point
// args[0]: number: break point object
static MaybeObject* Runtime_ClearBreakPoint(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
Handle<Object> break_point_object_arg = args.at<Object>(0);
// Clear break point.
isolate->debug()->ClearBreakPoint(break_point_object_arg);
return isolate->heap()->undefined_value();
}
// Change the state of break on exceptions.
// args[0]: Enum value indicating whether to affect caught/uncaught exceptions.
// args[1]: Boolean indicating on/off.
static MaybeObject* Runtime_ChangeBreakOnException(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 2);
RUNTIME_ASSERT(args[0]->IsNumber());
CONVERT_BOOLEAN_CHECKED(enable, args[1]);
// If the number doesn't match an enum value, the ChangeBreakOnException
// function will default to affecting caught exceptions.
ExceptionBreakType type =
static_cast<ExceptionBreakType>(NumberToUint32(args[0]));
// Update break point state.
isolate->debug()->ChangeBreakOnException(type, enable);
return isolate->heap()->undefined_value();
}
// Returns the state of break on exceptions
// args[0]: boolean indicating uncaught exceptions
static MaybeObject* Runtime_IsBreakOnException(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
RUNTIME_ASSERT(args[0]->IsNumber());
ExceptionBreakType type =
static_cast<ExceptionBreakType>(NumberToUint32(args[0]));
bool result = isolate->debug()->IsBreakOnException(type);
return Smi::FromInt(result);
}
// Prepare for stepping
// args[0]: break id for checking execution state
// args[1]: step action from the enumeration StepAction
// args[2]: number of times to perform the step, for step out it is the number
// of frames to step down.
static MaybeObject* Runtime_PrepareStep(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 3);
// Check arguments.
Object* check;
{ MaybeObject* maybe_check = Runtime_CheckExecutionState(args, isolate);
if (!maybe_check->ToObject(&check)) return maybe_check;
}
if (!args[1]->IsNumber() || !args[2]->IsNumber()) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
// Get the step action and check validity.
StepAction step_action = static_cast<StepAction>(NumberToInt32(args[1]));
if (step_action != StepIn &&
step_action != StepNext &&
step_action != StepOut &&
step_action != StepInMin &&
step_action != StepMin) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
// Get the number of steps.
int step_count = NumberToInt32(args[2]);
if (step_count < 1) {
return isolate->Throw(isolate->heap()->illegal_argument_symbol());
}
// Clear all current stepping setup.
isolate->debug()->ClearStepping();
// Prepare step.
isolate->debug()->PrepareStep(static_cast<StepAction>(step_action),
step_count);
return isolate->heap()->undefined_value();
}
// Clear all stepping set by PrepareStep.
static MaybeObject* Runtime_ClearStepping(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 0);
isolate->debug()->ClearStepping();
return isolate->heap()->undefined_value();
}
// Creates a copy of the with context chain. The copy of the context chain is
// is linked to the function context supplied.
static Handle<Context> CopyWithContextChain(Handle<Context> context_chain,
Handle<Context> function_context) {
// At the bottom of the chain. Return the function context to link to.
if (context_chain->is_function_context()) {
return function_context;
}
// Recursively copy the with contexts.
Handle<Context> previous(context_chain->previous());
Handle<JSObject> extension(JSObject::cast(context_chain->extension()));
Handle<Context> context = CopyWithContextChain(function_context, previous);
return context->GetIsolate()->factory()->NewWithContext(
context, extension, context_chain->IsCatchContext());
}
// Helper function to find or create the arguments object for
// Runtime_DebugEvaluate.
static Handle<Object> GetArgumentsObject(Isolate* isolate,
JavaScriptFrame* frame,
Handle<JSFunction> function,
Handle<SerializedScopeInfo> scope_info,
const ScopeInfo<>* sinfo,
Handle<Context> function_context) {
// Try to find the value of 'arguments' to pass as parameter. If it is not
// found (that is the debugged function does not reference 'arguments' and
// does not support eval) then create an 'arguments' object.
int index;
if (sinfo->number_of_stack_slots() > 0) {
index = scope_info->StackSlotIndex(isolate->heap()->arguments_symbol());
if (index != -1) {
return Handle<Object>(frame->GetExpression(index), isolate);
}
}
if (sinfo->number_of_context_slots() > Context::MIN_CONTEXT_SLOTS) {
index = scope_info->ContextSlotIndex(isolate->heap()->arguments_symbol(),
NULL);
if (index != -1) {
return Handle<Object>(function_context->get(index), isolate);
}
}
const int length = frame->ComputeParametersCount();
Handle<JSObject> arguments =
isolate->factory()->NewArgumentsObject(function, length);
Handle<FixedArray> array = isolate->factory()->NewFixedArray(length);
AssertNoAllocation no_gc;
WriteBarrierMode mode = array->GetWriteBarrierMode(no_gc);
for (int i = 0; i < length; i++) {
array->set(i, frame->GetParameter(i), mode);
}
arguments->set_elements(*array);
return arguments;
}
static const char kSourceStr[] =
"(function(arguments,__source__){return eval(__source__);})";
// Evaluate a piece of JavaScript in the context of a stack frame for
// debugging. This is accomplished by creating a new context which in its
// extension part has all the parameters and locals of the function on the
// stack frame. A function which calls eval with the code to evaluate is then
// compiled in this context and called in this context. As this context
// replaces the context of the function on the stack frame a new (empty)
// function is created as well to be used as the closure for the context.
// This function and the context acts as replacements for the function on the
// stack frame presenting the same view of the values of parameters and
// local variables as if the piece of JavaScript was evaluated at the point
// where the function on the stack frame is currently stopped.
static MaybeObject* Runtime_DebugEvaluate(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
// Check the execution state and decode arguments frame and source to be
// evaluated.
ASSERT(args.length() == 5);
Object* check_result;
{ MaybeObject* maybe_check_result = Runtime_CheckExecutionState(args,
isolate);
if (!maybe_check_result->ToObject(&check_result)) {
return maybe_check_result;
}
}
CONVERT_CHECKED(Smi, wrapped_id, args[1]);
CONVERT_ARG_CHECKED(String, source, 2);
CONVERT_BOOLEAN_CHECKED(disable_break, args[3]);
Handle<Object> additional_context(args[4]);
// Handle the processing of break.
DisableBreak disable_break_save(disable_break);
// Get the frame where the debugging is performed.
StackFrame::Id id = UnwrapFrameId(wrapped_id);
JavaScriptFrameIterator it(id);
JavaScriptFrame* frame = it.frame();
Handle<JSFunction> function(JSFunction::cast(frame->function()));
Handle<SerializedScopeInfo> scope_info(function->shared()->scope_info());
ScopeInfo<> sinfo(*scope_info);
// Traverse the saved contexts chain to find the active context for the
// selected frame.
SaveContext* save = isolate->save_context();
while (save != NULL && !save->below(frame)) {
save = save->prev();
}
ASSERT(save != NULL);
SaveContext savex(isolate);
isolate->set_context(*(save->context()));
// Create the (empty) function replacing the function on the stack frame for
// the purpose of evaluating in the context created below. It is important
// that this function does not describe any parameters and local variables
// in the context. If it does then this will cause problems with the lookup
// in Context::Lookup, where context slots for parameters and local variables
// are looked at before the extension object.
Handle<JSFunction> go_between =
isolate->factory()->NewFunction(isolate->factory()->empty_string(),
isolate->factory()->undefined_value());
go_between->set_context(function->context());
#ifdef DEBUG
ScopeInfo<> go_between_sinfo(go_between->shared()->scope_info());
ASSERT(go_between_sinfo.number_of_parameters() == 0);
ASSERT(go_between_sinfo.number_of_context_slots() == 0);
#endif
// Materialize the content of the local scope into a JSObject.
Handle<JSObject> local_scope = MaterializeLocalScope(isolate, frame);
RETURN_IF_EMPTY_HANDLE(isolate, local_scope);
// Allocate a new context for the debug evaluation and set the extension
// object build.
Handle<Context> context =
isolate->factory()->NewFunctionContext(Context::MIN_CONTEXT_SLOTS,
go_between);
context->set_extension(*local_scope);
// Copy any with contexts present and chain them in front of this context.
Handle<Context> frame_context(Context::cast(frame->context()));
Handle<Context> function_context(frame_context->fcontext());
context = CopyWithContextChain(frame_context, context);
if (additional_context->IsJSObject()) {
context = isolate->factory()->NewWithContext(context,
Handle<JSObject>::cast(additional_context), false);
}
// Wrap the evaluation statement in a new function compiled in the newly
// created context. The function has one parameter which has to be called
// 'arguments'. This it to have access to what would have been 'arguments' in
// the function being debugged.
// function(arguments,__source__) {return eval(__source__);}
Handle<String> function_source =
isolate->factory()->NewStringFromAscii(
Vector<const char>(kSourceStr, sizeof(kSourceStr) - 1));
// Currently, the eval code will be executed in non-strict mode,
// even in the strict code context.
Handle<SharedFunctionInfo> shared =
Compiler::CompileEval(function_source,
context,
context->IsGlobalContext(),
kNonStrictMode);
if (shared.is_null()) return Failure::Exception();
Handle<JSFunction> compiled_function =
isolate->factory()->NewFunctionFromSharedFunctionInfo(shared, context);
// Invoke the result of the compilation to get the evaluation function.
bool has_pending_exception;
Handle<Object> receiver(frame->receiver(), isolate);
Handle<Object> evaluation_function =
Execution::Call(compiled_function, receiver, 0, NULL,
&has_pending_exception);
if (has_pending_exception) return Failure::Exception();
Handle<Object> arguments = GetArgumentsObject(isolate, frame,
function, scope_info,
&sinfo, function_context);
// Invoke the evaluation function and return the result.
const int argc = 2;
Object** argv[argc] = { arguments.location(),
Handle<Object>::cast(source).location() };
Handle<Object> result =
Execution::Call(Handle<JSFunction>::cast(evaluation_function), receiver,
argc, argv, &has_pending_exception);
if (has_pending_exception) return Failure::Exception();
// Skip the global proxy as it has no properties and always delegates to the
// real global object.
if (result->IsJSGlobalProxy()) {
result = Handle<JSObject>(JSObject::cast(result->GetPrototype()));
}
return *result;
}
static MaybeObject* Runtime_DebugEvaluateGlobal(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
// Check the execution state and decode arguments frame and source to be
// evaluated.
ASSERT(args.length() == 4);
Object* check_result;
{ MaybeObject* maybe_check_result = Runtime_CheckExecutionState(args,
isolate);
if (!maybe_check_result->ToObject(&check_result)) {
return maybe_check_result;
}
}
CONVERT_ARG_CHECKED(String, source, 1);
CONVERT_BOOLEAN_CHECKED(disable_break, args[2]);
Handle<Object> additional_context(args[3]);
// Handle the processing of break.
DisableBreak disable_break_save(disable_break);
// Enter the top context from before the debugger was invoked.
SaveContext save(isolate);
SaveContext* top = &save;
while (top != NULL && *top->context() == *isolate->debug()->debug_context()) {
top = top->prev();
}
if (top != NULL) {
isolate->set_context(*top->context());
}
// Get the global context now set to the top context from before the
// debugger was invoked.
Handle<Context> context = isolate->global_context();
bool is_global = true;
if (additional_context->IsJSObject()) {
// Create a function context first, than put 'with' context on top of it.
Handle<JSFunction> go_between = isolate->factory()->NewFunction(
isolate->factory()->empty_string(),
isolate->factory()->undefined_value());
go_between->set_context(*context);
context =
isolate->factory()->NewFunctionContext(
Context::MIN_CONTEXT_SLOTS, go_between);
context->set_extension(JSObject::cast(*additional_context));
is_global = false;
}
// Compile the source to be evaluated.
// Currently, the eval code will be executed in non-strict mode,
// even in the strict code context.
Handle<SharedFunctionInfo> shared =
Compiler::CompileEval(source, context, is_global, kNonStrictMode);
if (shared.is_null()) return Failure::Exception();
Handle<JSFunction> compiled_function =
Handle<JSFunction>(
isolate->factory()->NewFunctionFromSharedFunctionInfo(shared,
context));
// Invoke the result of the compilation to get the evaluation function.
bool has_pending_exception;
Handle<Object> receiver = isolate->global();
Handle<Object> result =
Execution::Call(compiled_function, receiver, 0, NULL,
&has_pending_exception);
if (has_pending_exception) return Failure::Exception();
return *result;
}
static MaybeObject* Runtime_DebugGetLoadedScripts(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 0);
// Fill the script objects.
Handle<FixedArray> instances = isolate->debug()->GetLoadedScripts();
// Convert the script objects to proper JS objects.
for (int i = 0; i < instances->length(); i++) {
Handle<Script> script = Handle<Script>(Script::cast(instances->get(i)));
// Get the script wrapper in a local handle before calling GetScriptWrapper,
// because using
// instances->set(i, *GetScriptWrapper(script))
// is unsafe as GetScriptWrapper might call GC and the C++ compiler might
// already have deferenced the instances handle.
Handle<JSValue> wrapper = GetScriptWrapper(script);
instances->set(i, *wrapper);
}
// Return result as a JS array.
Handle<JSObject> result =
isolate->factory()->NewJSObject(isolate->array_function());
Handle<JSArray>::cast(result)->SetContent(*instances);
return *result;
}
// Helper function used by Runtime_DebugReferencedBy below.
static int DebugReferencedBy(JSObject* target,
Object* instance_filter, int max_references,
FixedArray* instances, int instances_size,
JSFunction* arguments_function) {
NoHandleAllocation ha;
AssertNoAllocation no_alloc;
// Iterate the heap.
int count = 0;
JSObject* last = NULL;
HeapIterator iterator;
HeapObject* heap_obj = NULL;
while (((heap_obj = iterator.next()) != NULL) &&
(max_references == 0 || count < max_references)) {
// Only look at all JSObjects.
if (heap_obj->IsJSObject()) {
// Skip context extension objects and argument arrays as these are
// checked in the context of functions using them.
JSObject* obj = JSObject::cast(heap_obj);
if (obj->IsJSContextExtensionObject() ||
obj->map()->constructor() == arguments_function) {
continue;
}
// Check if the JS object has a reference to the object looked for.
if (obj->ReferencesObject(target)) {
// Check instance filter if supplied. This is normally used to avoid
// references from mirror objects (see Runtime_IsInPrototypeChain).
if (!instance_filter->IsUndefined()) {
Object* V = obj;
while (true) {
Object* prototype = V->GetPrototype();
if (prototype->IsNull()) {
break;
}
if (instance_filter == prototype) {
obj = NULL; // Don't add this object.
break;
}
V = prototype;
}
}
if (obj != NULL) {
// Valid reference found add to instance array if supplied an update
// count.
if (instances != NULL && count < instances_size) {
instances->set(count, obj);
}
last = obj;
count++;
}
}
}
}
// Check for circular reference only. This can happen when the object is only
// referenced from mirrors and has a circular reference in which case the
// object is not really alive and would have been garbage collected if not
// referenced from the mirror.
if (count == 1 && last == target) {
count = 0;
}
// Return the number of referencing objects found.
return count;
}
// Scan the heap for objects with direct references to an object
// args[0]: the object to find references to
// args[1]: constructor function for instances to exclude (Mirror)
// args[2]: the the maximum number of objects to return
static MaybeObject* Runtime_DebugReferencedBy(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 3);
// First perform a full GC in order to avoid references from dead objects.
isolate->heap()->CollectAllGarbage(false);
// Check parameters.
CONVERT_CHECKED(JSObject, target, args[0]);
Object* instance_filter = args[1];
RUNTIME_ASSERT(instance_filter->IsUndefined() ||
instance_filter->IsJSObject());
CONVERT_NUMBER_CHECKED(int32_t, max_references, Int32, args[2]);
RUNTIME_ASSERT(max_references >= 0);
// Get the constructor function for context extension and arguments array.
JSObject* arguments_boilerplate =
isolate->context()->global_context()->arguments_boilerplate();
JSFunction* arguments_function =
JSFunction::cast(arguments_boilerplate->map()->constructor());
// Get the number of referencing objects.
int count;
count = DebugReferencedBy(target, instance_filter, max_references,
NULL, 0, arguments_function);
// Allocate an array to hold the result.
Object* object;
{ MaybeObject* maybe_object = isolate->heap()->AllocateFixedArray(count);
if (!maybe_object->ToObject(&object)) return maybe_object;
}
FixedArray* instances = FixedArray::cast(object);
// Fill the referencing objects.
count = DebugReferencedBy(target, instance_filter, max_references,
instances, count, arguments_function);
// Return result as JS array.
Object* result;
{ MaybeObject* maybe_result = isolate->heap()->AllocateJSObject(
isolate->context()->global_context()->array_function());
if (!maybe_result->ToObject(&result)) return maybe_result;
}
JSArray::cast(result)->SetContent(instances);
return result;
}
// Helper function used by Runtime_DebugConstructedBy below.
static int DebugConstructedBy(JSFunction* constructor, int max_references,
FixedArray* instances, int instances_size) {
AssertNoAllocation no_alloc;
// Iterate the heap.
int count = 0;
HeapIterator iterator;
HeapObject* heap_obj = NULL;
while (((heap_obj = iterator.next()) != NULL) &&
(max_references == 0 || count < max_references)) {
// Only look at all JSObjects.
if (heap_obj->IsJSObject()) {
JSObject* obj = JSObject::cast(heap_obj);
if (obj->map()->constructor() == constructor) {
// Valid reference found add to instance array if supplied an update
// count.
if (instances != NULL && count < instances_size) {
instances->set(count, obj);
}
count++;
}
}
}
// Return the number of referencing objects found.
return count;
}
// Scan the heap for objects constructed by a specific function.
// args[0]: the constructor to find instances of
// args[1]: the the maximum number of objects to return
static MaybeObject* Runtime_DebugConstructedBy(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
// First perform a full GC in order to avoid dead objects.
isolate->heap()->CollectAllGarbage(false);
// Check parameters.
CONVERT_CHECKED(JSFunction, constructor, args[0]);
CONVERT_NUMBER_CHECKED(int32_t, max_references, Int32, args[1]);
RUNTIME_ASSERT(max_references >= 0);
// Get the number of referencing objects.
int count;
count = DebugConstructedBy(constructor, max_references, NULL, 0);
// Allocate an array to hold the result.
Object* object;
{ MaybeObject* maybe_object = isolate->heap()->AllocateFixedArray(count);
if (!maybe_object->ToObject(&object)) return maybe_object;
}
FixedArray* instances = FixedArray::cast(object);
// Fill the referencing objects.
count = DebugConstructedBy(constructor, max_references, instances, count);
// Return result as JS array.
Object* result;
{ MaybeObject* maybe_result = isolate->heap()->AllocateJSObject(
isolate->context()->global_context()->array_function());
if (!maybe_result->ToObject(&result)) return maybe_result;
}
JSArray::cast(result)->SetContent(instances);
return result;
}
// Find the effective prototype object as returned by __proto__.
// args[0]: the object to find the prototype for.
static MaybeObject* Runtime_DebugGetPrototype(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSObject, obj, args[0]);
// Use the __proto__ accessor.
return Accessors::ObjectPrototype.getter(obj, NULL);
}
static MaybeObject* Runtime_SystemBreak(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
CPU::DebugBreak();
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_DebugDisassembleFunction(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef DEBUG
HandleScope scope(isolate);
ASSERT(args.length() == 1);
// Get the function and make sure it is compiled.
CONVERT_ARG_CHECKED(JSFunction, func, 0);
Handle<SharedFunctionInfo> shared(func->shared());
if (!EnsureCompiled(shared, KEEP_EXCEPTION)) {
return Failure::Exception();
}
func->code()->PrintLn();
#endif // DEBUG
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_DebugDisassembleConstructor(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef DEBUG
HandleScope scope(isolate);
ASSERT(args.length() == 1);
// Get the function and make sure it is compiled.
CONVERT_ARG_CHECKED(JSFunction, func, 0);
Handle<SharedFunctionInfo> shared(func->shared());
if (!EnsureCompiled(shared, KEEP_EXCEPTION)) {
return Failure::Exception();
}
shared->construct_stub()->PrintLn();
#endif // DEBUG
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_FunctionGetInferredName(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 1);
CONVERT_CHECKED(JSFunction, f, args[0]);
return f->shared()->inferred_name();
}
static int FindSharedFunctionInfosForScript(Script* script,
FixedArray* buffer) {
AssertNoAllocation no_allocations;
int counter = 0;
int buffer_size = buffer->length();
HeapIterator iterator;
for (HeapObject* obj = iterator.next(); obj != NULL; obj = iterator.next()) {
ASSERT(obj != NULL);
if (!obj->IsSharedFunctionInfo()) {
continue;
}
SharedFunctionInfo* shared = SharedFunctionInfo::cast(obj);
if (shared->script() != script) {
continue;
}
if (counter < buffer_size) {
buffer->set(counter, shared);
}
counter++;
}
return counter;
}
// For a script finds all SharedFunctionInfo's in the heap that points
// to this script. Returns JSArray of SharedFunctionInfo wrapped
// in OpaqueReferences.
static MaybeObject* Runtime_LiveEditFindSharedFunctionInfosForScript(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
HandleScope scope(isolate);
CONVERT_CHECKED(JSValue, script_value, args[0]);
Handle<Script> script = Handle<Script>(Script::cast(script_value->value()));
const int kBufferSize = 32;
Handle<FixedArray> array;
array = isolate->factory()->NewFixedArray(kBufferSize);
int number = FindSharedFunctionInfosForScript(*script, *array);
if (number > kBufferSize) {
array = isolate->factory()->NewFixedArray(number);
FindSharedFunctionInfosForScript(*script, *array);
}
Handle<JSArray> result = isolate->factory()->NewJSArrayWithElements(array);
result->set_length(Smi::FromInt(number));
LiveEdit::WrapSharedFunctionInfos(result);
return *result;
}
// For a script calculates compilation information about all its functions.
// The script source is explicitly specified by the second argument.
// The source of the actual script is not used, however it is important that
// all generated code keeps references to this particular instance of script.
// Returns a JSArray of compilation infos. The array is ordered so that
// each function with all its descendant is always stored in a continues range
// with the function itself going first. The root function is a script function.
static MaybeObject* Runtime_LiveEditGatherCompileInfo(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_CHECKED(JSValue, script, args[0]);
CONVERT_ARG_CHECKED(String, source, 1);
Handle<Script> script_handle = Handle<Script>(Script::cast(script->value()));
JSArray* result = LiveEdit::GatherCompileInfo(script_handle, source);
if (isolate->has_pending_exception()) {
return Failure::Exception();
}
return result;
}
// Changes the source of the script to a new_source.
// If old_script_name is provided (i.e. is a String), also creates a copy of
// the script with its original source and sends notification to debugger.
static MaybeObject* Runtime_LiveEditReplaceScript(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 3);
HandleScope scope(isolate);
CONVERT_CHECKED(JSValue, original_script_value, args[0]);
CONVERT_ARG_CHECKED(String, new_source, 1);
Handle<Object> old_script_name(args[2], isolate);
CONVERT_CHECKED(Script, original_script_pointer,
original_script_value->value());
Handle<Script> original_script(original_script_pointer);
Object* old_script = LiveEdit::ChangeScriptSource(original_script,
new_source,
old_script_name);
if (old_script->IsScript()) {
Handle<Script> script_handle(Script::cast(old_script));
return *(GetScriptWrapper(script_handle));
} else {
return isolate->heap()->null_value();
}
}
static MaybeObject* Runtime_LiveEditFunctionSourceUpdated(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 1);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSArray, shared_info, 0);
return LiveEdit::FunctionSourceUpdated(shared_info);
}
// Replaces code of SharedFunctionInfo with a new one.
static MaybeObject* Runtime_LiveEditReplaceFunctionCode(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSArray, new_compile_info, 0);
CONVERT_ARG_CHECKED(JSArray, shared_info, 1);
return LiveEdit::ReplaceFunctionCode(new_compile_info, shared_info);
}
// Connects SharedFunctionInfo to another script.
static MaybeObject* Runtime_LiveEditFunctionSetScript(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
Handle<Object> function_object(args[0], isolate);
Handle<Object> script_object(args[1], isolate);
if (function_object->IsJSValue()) {
Handle<JSValue> function_wrapper = Handle<JSValue>::cast(function_object);
if (script_object->IsJSValue()) {
CONVERT_CHECKED(Script, script, JSValue::cast(*script_object)->value());
script_object = Handle<Object>(script, isolate);
}
LiveEdit::SetFunctionScript(function_wrapper, script_object);
} else {
// Just ignore this. We may not have a SharedFunctionInfo for some functions
// and we check it in this function.
}
return isolate->heap()->undefined_value();
}
// In a code of a parent function replaces original function as embedded object
// with a substitution one.
static MaybeObject* Runtime_LiveEditReplaceRefToNestedFunction(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 3);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSValue, parent_wrapper, 0);
CONVERT_ARG_CHECKED(JSValue, orig_wrapper, 1);
CONVERT_ARG_CHECKED(JSValue, subst_wrapper, 2);
LiveEdit::ReplaceRefToNestedFunction(parent_wrapper, orig_wrapper,
subst_wrapper);
return isolate->heap()->undefined_value();
}
// Updates positions of a shared function info (first parameter) according
// to script source change. Text change is described in second parameter as
// array of groups of 3 numbers:
// (change_begin, change_end, change_end_new_position).
// Each group describes a change in text; groups are sorted by change_begin.
static MaybeObject* Runtime_LiveEditPatchFunctionPositions(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSArray, shared_array, 0);
CONVERT_ARG_CHECKED(JSArray, position_change_array, 1);
return LiveEdit::PatchFunctionPositions(shared_array, position_change_array);
}
// For array of SharedFunctionInfo's (each wrapped in JSValue)
// checks that none of them have activations on stacks (of any thread).
// Returns array of the same length with corresponding results of
// LiveEdit::FunctionPatchabilityStatus type.
static MaybeObject* Runtime_LiveEditCheckAndDropActivations(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSArray, shared_array, 0);
CONVERT_BOOLEAN_CHECKED(do_drop, args[1]);
return *LiveEdit::CheckAndDropActivations(shared_array, do_drop);
}
// Compares 2 strings line-by-line, then token-wise and returns diff in form
// of JSArray of triplets (pos1, pos1_end, pos2_end) describing list
// of diff chunks.
static MaybeObject* Runtime_LiveEditCompareStrings(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(String, s1, 0);
CONVERT_ARG_CHECKED(String, s2, 1);
return *LiveEdit::CompareStrings(s1, s2);
}
// A testing entry. Returns statement position which is the closest to
// source_position.
static MaybeObject* Runtime_GetFunctionCodePositionFromSource(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSFunction, function, 0);
CONVERT_NUMBER_CHECKED(int32_t, source_position, Int32, args[1]);
Handle<Code> code(function->code(), isolate);
if (code->kind() != Code::FUNCTION &&
code->kind() != Code::OPTIMIZED_FUNCTION) {
return isolate->heap()->undefined_value();
}
RelocIterator it(*code, RelocInfo::ModeMask(RelocInfo::STATEMENT_POSITION));
int closest_pc = 0;
int distance = kMaxInt;
while (!it.done()) {
int statement_position = static_cast<int>(it.rinfo()->data());
// Check if this break point is closer that what was previously found.
if (source_position <= statement_position &&
statement_position - source_position < distance) {
closest_pc =
static_cast<int>(it.rinfo()->pc() - code->instruction_start());
distance = statement_position - source_position;
// Check whether we can't get any closer.
if (distance == 0) break;
}
it.next();
}
return Smi::FromInt(closest_pc);
}
// Calls specified function with or without entering the debugger.
// This is used in unit tests to run code as if debugger is entered or simply
// to have a stack with C++ frame in the middle.
static MaybeObject* Runtime_ExecuteInDebugContext(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(JSFunction, function, 0);
CONVERT_BOOLEAN_CHECKED(without_debugger, args[1]);
Handle<Object> result;
bool pending_exception;
{
if (without_debugger) {
result = Execution::Call(function, isolate->global(), 0, NULL,
&pending_exception);
} else {
EnterDebugger enter_debugger;
result = Execution::Call(function, isolate->global(), 0, NULL,
&pending_exception);
}
}
if (!pending_exception) {
return *result;
} else {
return Failure::Exception();
}
}
// Sets a v8 flag.
static MaybeObject* Runtime_SetFlags(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(String, arg, args[0]);
SmartPointer<char> flags =
arg->ToCString(DISALLOW_NULLS, ROBUST_STRING_TRAVERSAL);
FlagList::SetFlagsFromString(*flags, StrLength(*flags));
return isolate->heap()->undefined_value();
}
// Performs a GC.
// Presently, it only does a full GC.
static MaybeObject* Runtime_CollectGarbage(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
isolate->heap()->CollectAllGarbage(true);
return isolate->heap()->undefined_value();
}
// Gets the current heap usage.
static MaybeObject* Runtime_GetHeapUsage(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
int usage = static_cast<int>(isolate->heap()->SizeOfObjects());
if (!Smi::IsValid(usage)) {
return *isolate->factory()->NewNumberFromInt(usage);
}
return Smi::FromInt(usage);
}
// Captures a live object list from the present heap.
static MaybeObject* Runtime_HasLOLEnabled(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
return isolate->heap()->true_value();
#else
return isolate->heap()->false_value();
#endif
}
// Captures a live object list from the present heap.
static MaybeObject* Runtime_CaptureLOL(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
return LiveObjectList::Capture();
#else
return isolate->heap()->undefined_value();
#endif
}
// Deletes the specified live object list.
static MaybeObject* Runtime_DeleteLOL(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
CONVERT_SMI_CHECKED(id, args[0]);
bool success = LiveObjectList::Delete(id);
return success ? isolate->heap()->true_value() :
isolate->heap()->false_value();
#else
return isolate->heap()->undefined_value();
#endif
}
// Generates the response to a debugger request for a dump of the objects
// contained in the difference between the captured live object lists
// specified by id1 and id2.
// If id1 is 0 (i.e. not a valid lol), then the whole of lol id2 will be
// dumped.
static MaybeObject* Runtime_DumpLOL(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
HandleScope scope;
CONVERT_SMI_CHECKED(id1, args[0]);
CONVERT_SMI_CHECKED(id2, args[1]);
CONVERT_SMI_CHECKED(start, args[2]);
CONVERT_SMI_CHECKED(count, args[3]);
CONVERT_ARG_CHECKED(JSObject, filter_obj, 4);
EnterDebugger enter_debugger;
return LiveObjectList::Dump(id1, id2, start, count, filter_obj);
#else
return isolate->heap()->undefined_value();
#endif
}
// Gets the specified object as requested by the debugger.
// This is only used for obj ids shown in live object lists.
static MaybeObject* Runtime_GetLOLObj(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
CONVERT_SMI_CHECKED(obj_id, args[0]);
Object* result = LiveObjectList::GetObj(obj_id);
return result;
#else
return isolate->heap()->undefined_value();
#endif
}
// Gets the obj id for the specified address if valid.
// This is only used for obj ids shown in live object lists.
static MaybeObject* Runtime_GetLOLObjId(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
HandleScope scope;
CONVERT_ARG_CHECKED(String, address, 0);
Object* result = LiveObjectList::GetObjId(address);
return result;
#else
return isolate->heap()->undefined_value();
#endif
}
// Gets the retainers that references the specified object alive.
static MaybeObject* Runtime_GetLOLObjRetainers(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
HandleScope scope;
CONVERT_SMI_CHECKED(obj_id, args[0]);
RUNTIME_ASSERT(args[1]->IsUndefined() || args[1]->IsJSObject());
RUNTIME_ASSERT(args[2]->IsUndefined() || args[2]->IsBoolean());
RUNTIME_ASSERT(args[3]->IsUndefined() || args[3]->IsSmi());
RUNTIME_ASSERT(args[4]->IsUndefined() || args[4]->IsSmi());
CONVERT_ARG_CHECKED(JSObject, filter_obj, 5);
Handle<JSObject> instance_filter;
if (args[1]->IsJSObject()) {
instance_filter = args.at<JSObject>(1);
}
bool verbose = false;
if (args[2]->IsBoolean()) {
verbose = args[2]->IsTrue();
}
int start = 0;
if (args[3]->IsSmi()) {
start = Smi::cast(args[3])->value();
}
int limit = Smi::kMaxValue;
if (args[4]->IsSmi()) {
limit = Smi::cast(args[4])->value();
}
return LiveObjectList::GetObjRetainers(obj_id,
instance_filter,
verbose,
start,
limit,
filter_obj);
#else
return isolate->heap()->undefined_value();
#endif
}
// Gets the reference path between 2 objects.
static MaybeObject* Runtime_GetLOLPath(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
HandleScope scope;
CONVERT_SMI_CHECKED(obj_id1, args[0]);
CONVERT_SMI_CHECKED(obj_id2, args[1]);
RUNTIME_ASSERT(args[2]->IsUndefined() || args[2]->IsJSObject());
Handle<JSObject> instance_filter;
if (args[2]->IsJSObject()) {
instance_filter = args.at<JSObject>(2);
}
Object* result =
LiveObjectList::GetPath(obj_id1, obj_id2, instance_filter);
return result;
#else
return isolate->heap()->undefined_value();
#endif
}
// Generates the response to a debugger request for a list of all
// previously captured live object lists.
static MaybeObject* Runtime_InfoLOL(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
CONVERT_SMI_CHECKED(start, args[0]);
CONVERT_SMI_CHECKED(count, args[1]);
return LiveObjectList::Info(start, count);
#else
return isolate->heap()->undefined_value();
#endif
}
// Gets a dump of the specified object as requested by the debugger.
// This is only used for obj ids shown in live object lists.
static MaybeObject* Runtime_PrintLOLObj(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
HandleScope scope;
CONVERT_SMI_CHECKED(obj_id, args[0]);
Object* result = LiveObjectList::PrintObj(obj_id);
return result;
#else
return isolate->heap()->undefined_value();
#endif
}
// Resets and releases all previously captured live object lists.
static MaybeObject* Runtime_ResetLOL(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
LiveObjectList::Reset();
return isolate->heap()->undefined_value();
#else
return isolate->heap()->undefined_value();
#endif
}
// Generates the response to a debugger request for a summary of the types
// of objects in the difference between the captured live object lists
// specified by id1 and id2.
// If id1 is 0 (i.e. not a valid lol), then the whole of lol id2 will be
// summarized.
static MaybeObject* Runtime_SummarizeLOL(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
#ifdef LIVE_OBJECT_LIST
HandleScope scope;
CONVERT_SMI_CHECKED(id1, args[0]);
CONVERT_SMI_CHECKED(id2, args[1]);
CONVERT_ARG_CHECKED(JSObject, filter_obj, 2);
EnterDebugger enter_debugger;
return LiveObjectList::Summarize(id1, id2, filter_obj);
#else
return isolate->heap()->undefined_value();
#endif
}
#endif // ENABLE_DEBUGGER_SUPPORT
#ifdef ENABLE_LOGGING_AND_PROFILING
static MaybeObject* Runtime_ProfilerResume(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(Smi, smi_modules, args[0]);
CONVERT_CHECKED(Smi, smi_tag, args[1]);
v8::V8::ResumeProfilerEx(smi_modules->value(), smi_tag->value());
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_ProfilerPause(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
NoHandleAllocation ha;
ASSERT(args.length() == 2);
CONVERT_CHECKED(Smi, smi_modules, args[0]);
CONVERT_CHECKED(Smi, smi_tag, args[1]);
v8::V8::PauseProfilerEx(smi_modules->value(), smi_tag->value());
return isolate->heap()->undefined_value();
}
#endif // ENABLE_LOGGING_AND_PROFILING
// Finds the script object from the script data. NOTE: This operation uses
// heap traversal to find the function generated for the source position
// for the requested break point. For lazily compiled functions several heap
// traversals might be required rendering this operation as a rather slow
// operation. However for setting break points which is normally done through
// some kind of user interaction the performance is not crucial.
static Handle<Object> Runtime_GetScriptFromScriptName(
Handle<String> script_name) {
// Scan the heap for Script objects to find the script with the requested
// script data.
Handle<Script> script;
HeapIterator iterator;
HeapObject* obj = NULL;
while (script.is_null() && ((obj = iterator.next()) != NULL)) {
// If a script is found check if it has the script data requested.
if (obj->IsScript()) {
if (Script::cast(obj)->name()->IsString()) {
if (String::cast(Script::cast(obj)->name())->Equals(*script_name)) {
script = Handle<Script>(Script::cast(obj));
}
}
}
}
// If no script with the requested script data is found return undefined.
if (script.is_null()) return FACTORY->undefined_value();
// Return the script found.
return GetScriptWrapper(script);
}
// Get the script object from script data. NOTE: Regarding performance
// see the NOTE for GetScriptFromScriptData.
// args[0]: script data for the script to find the source for
static MaybeObject* Runtime_GetScript(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
ASSERT(args.length() == 1);
CONVERT_CHECKED(String, script_name, args[0]);
// Find the requested script.
Handle<Object> result =
Runtime_GetScriptFromScriptName(Handle<String>(script_name));
return *result;
}
// Determines whether the given stack frame should be displayed in
// a stack trace. The caller is the error constructor that asked
// for the stack trace to be collected. The first time a construct
// call to this function is encountered it is skipped. The seen_caller
// in/out parameter is used to remember if the caller has been seen
// yet.
static bool ShowFrameInStackTrace(StackFrame* raw_frame, Object* caller,
bool* seen_caller) {
// Only display JS frames.
if (!raw_frame->is_java_script())
return false;
JavaScriptFrame* frame = JavaScriptFrame::cast(raw_frame);
Object* raw_fun = frame->function();
// Not sure when this can happen but skip it just in case.
if (!raw_fun->IsJSFunction())
return false;
if ((raw_fun == caller) && !(*seen_caller)) {
*seen_caller = true;
return false;
}
// Skip all frames until we've seen the caller. Also, skip the most
// obvious builtin calls. Some builtin calls (such as Number.ADD
// which is invoked using 'call') are very difficult to recognize
// so we're leaving them in for now.
return *seen_caller && !frame->receiver()->IsJSBuiltinsObject();
}
// Collect the raw data for a stack trace. Returns an array of 4
// element segments each containing a receiver, function, code and
// native code offset.
static MaybeObject* Runtime_CollectStackTrace(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT_EQ(args.length(), 2);
Handle<Object> caller = args.at<Object>(0);
CONVERT_NUMBER_CHECKED(int32_t, limit, Int32, args[1]);
HandleScope scope(isolate);
Factory* factory = isolate->factory();
limit = Max(limit, 0); // Ensure that limit is not negative.
int initial_size = Min(limit, 10);
Handle<FixedArray> elements =
factory->NewFixedArrayWithHoles(initial_size * 4);
StackFrameIterator iter;
// If the caller parameter is a function we skip frames until we're
// under it before starting to collect.
bool seen_caller = !caller->IsJSFunction();
int cursor = 0;
int frames_seen = 0;
while (!iter.done() && frames_seen < limit) {
StackFrame* raw_frame = iter.frame();
if (ShowFrameInStackTrace(raw_frame, *caller, &seen_caller)) {
frames_seen++;
JavaScriptFrame* frame = JavaScriptFrame::cast(raw_frame);
List<FrameSummary> frames(3); // Max 2 levels of inlining.
frame->Summarize(&frames);
for (int i = frames.length() - 1; i >= 0; i--) {
if (cursor + 4 > elements->length()) {
int new_capacity = JSObject::NewElementsCapacity(elements->length());
Handle<FixedArray> new_elements =
factory->NewFixedArrayWithHoles(new_capacity);
for (int i = 0; i < cursor; i++) {
new_elements->set(i, elements->get(i));
}
elements = new_elements;
}
ASSERT(cursor + 4 <= elements->length());
Handle<Object> recv = frames[i].receiver();
Handle<JSFunction> fun = frames[i].function();
Handle<Code> code = frames[i].code();
Handle<Smi> offset(Smi::FromInt(frames[i].offset()));
elements->set(cursor++, *recv);
elements->set(cursor++, *fun);
elements->set(cursor++, *code);
elements->set(cursor++, *offset);
}
}
iter.Advance();
}
Handle<JSArray> result = factory->NewJSArrayWithElements(elements);
result->set_length(Smi::FromInt(cursor));
return *result;
}
// Returns V8 version as a string.
static MaybeObject* Runtime_GetV8Version(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT_EQ(args.length(), 0);
NoHandleAllocation ha;
const char* version_string = v8::V8::GetVersion();
return isolate->heap()->AllocateStringFromAscii(CStrVector(version_string),
NOT_TENURED);
}
static MaybeObject* Runtime_Abort(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
OS::PrintError("abort: %s\n", reinterpret_cast<char*>(args[0]) +
Smi::cast(args[1])->value());
isolate->PrintStack();
OS::Abort();
UNREACHABLE();
return NULL;
}
static MaybeObject* Runtime_GetFromCache(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
// This is only called from codegen, so checks might be more lax.
CONVERT_CHECKED(JSFunctionResultCache, cache, args[0]);
Object* key = args[1];
int finger_index = cache->finger_index();
Object* o = cache->get(finger_index);
if (o == key) {
// The fastest case: hit the same place again.
return cache->get(finger_index + 1);
}
for (int i = finger_index - 2;
i >= JSFunctionResultCache::kEntriesIndex;
i -= 2) {
o = cache->get(i);
if (o == key) {
cache->set_finger_index(i);
return cache->get(i + 1);
}
}
int size = cache->size();
ASSERT(size <= cache->length());
for (int i = size - 2; i > finger_index; i -= 2) {
o = cache->get(i);
if (o == key) {
cache->set_finger_index(i);
return cache->get(i + 1);
}
}
// There is no value in the cache. Invoke the function and cache result.
HandleScope scope(isolate);
Handle<JSFunctionResultCache> cache_handle(cache);
Handle<Object> key_handle(key);
Handle<Object> value;
{
Handle<JSFunction> factory(JSFunction::cast(
cache_handle->get(JSFunctionResultCache::kFactoryIndex)));
// TODO(antonm): consider passing a receiver when constructing a cache.
Handle<Object> receiver(isolate->global_context()->global());
// This handle is nor shared, nor used later, so it's safe.
Object** argv[] = { key_handle.location() };
bool pending_exception = false;
value = Execution::Call(factory,
receiver,
1,
argv,
&pending_exception);
if (pending_exception) return Failure::Exception();
}
#ifdef DEBUG
cache_handle->JSFunctionResultCacheVerify();
#endif
// Function invocation may have cleared the cache. Reread all the data.
finger_index = cache_handle->finger_index();
size = cache_handle->size();
// If we have spare room, put new data into it, otherwise evict post finger
// entry which is likely to be the least recently used.
int index = -1;
if (size < cache_handle->length()) {
cache_handle->set_size(size + JSFunctionResultCache::kEntrySize);
index = size;
} else {
index = finger_index + JSFunctionResultCache::kEntrySize;
if (index == cache_handle->length()) {
index = JSFunctionResultCache::kEntriesIndex;
}
}
ASSERT(index % 2 == 0);
ASSERT(index >= JSFunctionResultCache::kEntriesIndex);
ASSERT(index < cache_handle->length());
cache_handle->set(index, *key_handle);
cache_handle->set(index + 1, *value);
cache_handle->set_finger_index(index);
#ifdef DEBUG
cache_handle->JSFunctionResultCacheVerify();
#endif
return *value;
}
static MaybeObject* Runtime_NewMessageObject(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
HandleScope scope(isolate);
CONVERT_ARG_CHECKED(String, type, 0);
CONVERT_ARG_CHECKED(JSArray, arguments, 1);
return *isolate->factory()->NewJSMessageObject(
type,
arguments,
0,
0,
isolate->factory()->undefined_value(),
isolate->factory()->undefined_value(),
isolate->factory()->undefined_value());
}
static MaybeObject* Runtime_MessageGetType(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(JSMessageObject, message, args[0]);
return message->type();
}
static MaybeObject* Runtime_MessageGetArguments(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(JSMessageObject, message, args[0]);
return message->arguments();
}
static MaybeObject* Runtime_MessageGetStartPosition(
RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(JSMessageObject, message, args[0]);
return Smi::FromInt(message->start_position());
}
static MaybeObject* Runtime_MessageGetScript(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
CONVERT_CHECKED(JSMessageObject, message, args[0]);
return message->script();
}
#ifdef DEBUG
// ListNatives is ONLY used by the fuzz-natives.js in debug mode
// Exclude the code in release mode.
static MaybeObject* Runtime_ListNatives(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 0);
HandleScope scope;
#define COUNT_ENTRY(Name, argc, ressize) + 1
int entry_count = 0
RUNTIME_FUNCTION_LIST(COUNT_ENTRY)
INLINE_FUNCTION_LIST(COUNT_ENTRY)
INLINE_RUNTIME_FUNCTION_LIST(COUNT_ENTRY);
#undef COUNT_ENTRY
Factory* factory = isolate->factory();
Handle<FixedArray> elements = factory->NewFixedArray(entry_count);
int index = 0;
bool inline_runtime_functions = false;
#define ADD_ENTRY(Name, argc, ressize) \
{ \
HandleScope inner; \
Handle<String> name; \
/* Inline runtime functions have an underscore in front of the name. */ \
if (inline_runtime_functions) { \
name = factory->NewStringFromAscii( \
Vector<const char>("_" #Name, StrLength("_" #Name))); \
} else { \
name = factory->NewStringFromAscii( \
Vector<const char>(#Name, StrLength(#Name))); \
} \
Handle<FixedArray> pair_elements = factory->NewFixedArray(2); \
pair_elements->set(0, *name); \
pair_elements->set(1, Smi::FromInt(argc)); \
Handle<JSArray> pair = factory->NewJSArrayWithElements(pair_elements); \
elements->set(index++, *pair); \
}
inline_runtime_functions = false;
RUNTIME_FUNCTION_LIST(ADD_ENTRY)
inline_runtime_functions = true;
INLINE_FUNCTION_LIST(ADD_ENTRY)
INLINE_RUNTIME_FUNCTION_LIST(ADD_ENTRY)
#undef ADD_ENTRY
ASSERT_EQ(index, entry_count);
Handle<JSArray> result = factory->NewJSArrayWithElements(elements);
return *result;
}
#endif
static MaybeObject* Runtime_Log(RUNTIME_CALLING_CONVENTION) {
RUNTIME_GET_ISOLATE;
ASSERT(args.length() == 2);
CONVERT_CHECKED(String, format, args[0]);
CONVERT_CHECKED(JSArray, elms, args[1]);
Vector<const char> chars = format->ToAsciiVector();
LOGGER->LogRuntime(chars, elms);
return isolate->heap()->undefined_value();
}
static MaybeObject* Runtime_IS_VAR(RUNTIME_CALLING_CONVENTION) {
UNREACHABLE(); // implemented as macro in the parser
return NULL;
}
// ----------------------------------------------------------------------------
// Implementation of Runtime
#define F(name, number_of_args, result_size) \
{ Runtime::k##name, Runtime::RUNTIME, #name, \
FUNCTION_ADDR(Runtime_##name), number_of_args, result_size },
#define I(name, number_of_args, result_size) \
{ Runtime::kInline##name, Runtime::INLINE, \
"_" #name, NULL, number_of_args, result_size },
static const Runtime::Function kIntrinsicFunctions[] = {
RUNTIME_FUNCTION_LIST(F)
INLINE_FUNCTION_LIST(I)
INLINE_RUNTIME_FUNCTION_LIST(I)
};
MaybeObject* Runtime::InitializeIntrinsicFunctionNames(Heap* heap,
Object* dictionary) {
ASSERT(Isolate::Current()->heap() == heap);
ASSERT(dictionary != NULL);
ASSERT(StringDictionary::cast(dictionary)->NumberOfElements() == 0);
for (int i = 0; i < kNumFunctions; ++i) {
Object* name_symbol;
{ MaybeObject* maybe_name_symbol =
heap->LookupAsciiSymbol(kIntrinsicFunctions[i].name);
if (!maybe_name_symbol->ToObject(&name_symbol)) return maybe_name_symbol;
}
StringDictionary* string_dictionary = StringDictionary::cast(dictionary);
{ MaybeObject* maybe_dictionary = string_dictionary->Add(
String::cast(name_symbol),
Smi::FromInt(i),
PropertyDetails(NONE, NORMAL));
if (!maybe_dictionary->ToObject(&dictionary)) {
// Non-recoverable failure. Calling code must restart heap
// initialization.
return maybe_dictionary;
}
}
}
return dictionary;
}
const Runtime::Function* Runtime::FunctionForSymbol(Handle<String> name) {
Heap* heap = name->GetHeap();
int entry = heap->intrinsic_function_names()->FindEntry(*name);
if (entry != kNotFound) {
Object* smi_index = heap->intrinsic_function_names()->ValueAt(entry);
int function_index = Smi::cast(smi_index)->value();
return &(kIntrinsicFunctions[function_index]);
}
return NULL;
}
const Runtime::Function* Runtime::FunctionForId(Runtime::FunctionId id) {
return &(kIntrinsicFunctions[static_cast<int>(id)]);
}
void Runtime::PerformGC(Object* result) {
Failure* failure = Failure::cast(result);
if (failure->IsRetryAfterGC()) {
// Try to do a garbage collection; ignore it if it fails. The C
// entry stub will throw an out-of-memory exception in that case.
HEAP->CollectGarbage(failure->allocation_space());
} else {
// Handle last resort GC and make sure to allow future allocations
// to grow the heap without causing GCs (if possible).
COUNTERS->gc_last_resort_from_js()->Increment();
HEAP->CollectAllGarbage(false);
}
}
} } // namespace v8::internal