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1 // Copyright 2014 the V8 project authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4 
5 #include "src/bootstrapper.h"
6 
7 #include "src/accessors.h"
8 #include "src/code-stubs.h"
9 #include "src/extensions/externalize-string-extension.h"
10 #include "src/extensions/free-buffer-extension.h"
11 #include "src/extensions/gc-extension.h"
12 #include "src/extensions/statistics-extension.h"
13 #include "src/extensions/trigger-failure-extension.h"
14 #include "src/isolate-inl.h"
15 #include "src/natives.h"
16 #include "src/snapshot.h"
17 #include "third_party/fdlibm/fdlibm.h"
18 
19 namespace v8 {
20 namespace internal {
21 
NativesExternalStringResource(Bootstrapper * bootstrapper,const char * source,size_t length)22 NativesExternalStringResource::NativesExternalStringResource(
23     Bootstrapper* bootstrapper,
24     const char* source,
25     size_t length)
26     : data_(source), length_(length) {
27   if (bootstrapper->delete_these_non_arrays_on_tear_down_ == NULL) {
28     bootstrapper->delete_these_non_arrays_on_tear_down_ = new List<char*>(2);
29   }
30   // The resources are small objects and we only make a fixed number of
31   // them, but let's clean them up on exit for neatness.
32   bootstrapper->delete_these_non_arrays_on_tear_down_->
33       Add(reinterpret_cast<char*>(this));
34 }
35 
36 
Bootstrapper(Isolate * isolate)37 Bootstrapper::Bootstrapper(Isolate* isolate)
38     : isolate_(isolate),
39       nesting_(0),
40       extensions_cache_(Script::TYPE_EXTENSION),
41       delete_these_non_arrays_on_tear_down_(NULL),
42       delete_these_arrays_on_tear_down_(NULL) {
43 }
44 
45 
NativesSourceLookup(int index)46 Handle<String> Bootstrapper::NativesSourceLookup(int index) {
47   DCHECK(0 <= index && index < Natives::GetBuiltinsCount());
48   Heap* heap = isolate_->heap();
49   if (heap->natives_source_cache()->get(index)->IsUndefined()) {
50     // We can use external strings for the natives.
51     Vector<const char> source = Natives::GetRawScriptSource(index);
52     NativesExternalStringResource* resource =
53         new NativesExternalStringResource(this,
54                                           source.start(),
55                                           source.length());
56     // We do not expect this to throw an exception. Change this if it does.
57     Handle<String> source_code = isolate_->factory()
58                                      ->NewExternalStringFromOneByte(resource)
59                                      .ToHandleChecked();
60     heap->natives_source_cache()->set(index, *source_code);
61   }
62   Handle<Object> cached_source(heap->natives_source_cache()->get(index),
63                                isolate_);
64   return Handle<String>::cast(cached_source);
65 }
66 
67 
Initialize(bool create_heap_objects)68 void Bootstrapper::Initialize(bool create_heap_objects) {
69   extensions_cache_.Initialize(isolate_, create_heap_objects);
70 }
71 
72 
GCFunctionName()73 static const char* GCFunctionName() {
74   bool flag_given = FLAG_expose_gc_as != NULL && strlen(FLAG_expose_gc_as) != 0;
75   return flag_given ? FLAG_expose_gc_as : "gc";
76 }
77 
78 
79 v8::Extension* Bootstrapper::free_buffer_extension_ = NULL;
80 v8::Extension* Bootstrapper::gc_extension_ = NULL;
81 v8::Extension* Bootstrapper::externalize_string_extension_ = NULL;
82 v8::Extension* Bootstrapper::statistics_extension_ = NULL;
83 v8::Extension* Bootstrapper::trigger_failure_extension_ = NULL;
84 
85 
InitializeOncePerProcess()86 void Bootstrapper::InitializeOncePerProcess() {
87   free_buffer_extension_ = new FreeBufferExtension;
88   v8::RegisterExtension(free_buffer_extension_);
89   gc_extension_ = new GCExtension(GCFunctionName());
90   v8::RegisterExtension(gc_extension_);
91   externalize_string_extension_ = new ExternalizeStringExtension;
92   v8::RegisterExtension(externalize_string_extension_);
93   statistics_extension_ = new StatisticsExtension;
94   v8::RegisterExtension(statistics_extension_);
95   trigger_failure_extension_ = new TriggerFailureExtension;
96   v8::RegisterExtension(trigger_failure_extension_);
97 }
98 
99 
TearDownExtensions()100 void Bootstrapper::TearDownExtensions() {
101   delete free_buffer_extension_;
102   free_buffer_extension_ = NULL;
103   delete gc_extension_;
104   gc_extension_ = NULL;
105   delete externalize_string_extension_;
106   externalize_string_extension_ = NULL;
107   delete statistics_extension_;
108   statistics_extension_ = NULL;
109   delete trigger_failure_extension_;
110   trigger_failure_extension_ = NULL;
111 }
112 
113 
AllocateAutoDeletedArray(int bytes)114 char* Bootstrapper::AllocateAutoDeletedArray(int bytes) {
115   char* memory = new char[bytes];
116   if (memory != NULL) {
117     if (delete_these_arrays_on_tear_down_ == NULL) {
118       delete_these_arrays_on_tear_down_ = new List<char*>(2);
119     }
120     delete_these_arrays_on_tear_down_->Add(memory);
121   }
122   return memory;
123 }
124 
125 
TearDown()126 void Bootstrapper::TearDown() {
127   if (delete_these_non_arrays_on_tear_down_ != NULL) {
128     int len = delete_these_non_arrays_on_tear_down_->length();
129     DCHECK(len < 28);  // Don't use this mechanism for unbounded allocations.
130     for (int i = 0; i < len; i++) {
131       delete delete_these_non_arrays_on_tear_down_->at(i);
132       delete_these_non_arrays_on_tear_down_->at(i) = NULL;
133     }
134     delete delete_these_non_arrays_on_tear_down_;
135     delete_these_non_arrays_on_tear_down_ = NULL;
136   }
137 
138   if (delete_these_arrays_on_tear_down_ != NULL) {
139     int len = delete_these_arrays_on_tear_down_->length();
140     DCHECK(len < 1000);  // Don't use this mechanism for unbounded allocations.
141     for (int i = 0; i < len; i++) {
142       delete[] delete_these_arrays_on_tear_down_->at(i);
143       delete_these_arrays_on_tear_down_->at(i) = NULL;
144     }
145     delete delete_these_arrays_on_tear_down_;
146     delete_these_arrays_on_tear_down_ = NULL;
147   }
148 
149   extensions_cache_.Initialize(isolate_, false);  // Yes, symmetrical
150 }
151 
152 
153 class Genesis BASE_EMBEDDED {
154  public:
155   Genesis(Isolate* isolate,
156           MaybeHandle<JSGlobalProxy> maybe_global_proxy,
157           v8::Handle<v8::ObjectTemplate> global_proxy_template,
158           v8::ExtensionConfiguration* extensions);
~Genesis()159   ~Genesis() { }
160 
isolate() const161   Isolate* isolate() const { return isolate_; }
factory() const162   Factory* factory() const { return isolate_->factory(); }
heap() const163   Heap* heap() const { return isolate_->heap(); }
164 
result()165   Handle<Context> result() { return result_; }
166 
167  private:
native_context()168   Handle<Context> native_context() { return native_context_; }
169 
170   // Creates some basic objects. Used for creating a context from scratch.
171   void CreateRoots();
172   // Creates the empty function.  Used for creating a context from scratch.
173   Handle<JSFunction> CreateEmptyFunction(Isolate* isolate);
174   // Creates the ThrowTypeError function. ECMA 5th Ed. 13.2.3
175   Handle<JSFunction> GetStrictPoisonFunction();
176   // Poison for sloppy generator function arguments/callee.
177   Handle<JSFunction> GetGeneratorPoisonFunction();
178 
179   void CreateStrictModeFunctionMaps(Handle<JSFunction> empty);
180 
181   // Make the "arguments" and "caller" properties throw a TypeError on access.
182   void PoisonArgumentsAndCaller(Handle<Map> map);
183 
184   // Creates the global objects using the global and the template passed in
185   // through the API.  We call this regardless of whether we are building a
186   // context from scratch or using a deserialized one from the partial snapshot
187   // but in the latter case we don't use the objects it produces directly, as
188   // we have to used the deserialized ones that are linked together with the
189   // rest of the context snapshot.
190   Handle<JSGlobalProxy> CreateNewGlobals(
191       v8::Handle<v8::ObjectTemplate> global_proxy_template,
192       MaybeHandle<JSGlobalProxy> maybe_global_proxy,
193       Handle<GlobalObject>* global_object_out);
194   // Hooks the given global proxy into the context.  If the context was created
195   // by deserialization then this will unhook the global proxy that was
196   // deserialized, leaving the GC to pick it up.
197   void HookUpGlobalProxy(Handle<GlobalObject> global_object,
198                          Handle<JSGlobalProxy> global_proxy);
199   // Similarly, we want to use the global that has been created by the templates
200   // passed through the API.  The global from the snapshot is detached from the
201   // other objects in the snapshot.
202   void HookUpGlobalObject(Handle<GlobalObject> global_object);
203   // New context initialization.  Used for creating a context from scratch.
204   void InitializeGlobal(Handle<GlobalObject> global_object,
205                         Handle<JSFunction> empty_function);
206   void InitializeExperimentalGlobal();
207   // Installs the contents of the native .js files on the global objects.
208   // Used for creating a context from scratch.
209   void InstallNativeFunctions();
210   void InstallExperimentalNativeFunctions();
211   Handle<JSFunction> InstallInternalArray(Handle<JSBuiltinsObject> builtins,
212                                           const char* name,
213                                           ElementsKind elements_kind);
214   bool InstallNatives();
215 
216   void InstallTypedArray(
217       const char* name,
218       ElementsKind elements_kind,
219       Handle<JSFunction>* fun,
220       Handle<Map>* external_map);
221   bool InstallExperimentalNatives();
222   void InstallBuiltinFunctionIds();
223   void InstallJSFunctionResultCaches();
224   void InitializeNormalizedMapCaches();
225 
226   enum ExtensionTraversalState {
227     UNVISITED, VISITED, INSTALLED
228   };
229 
230   class ExtensionStates {
231    public:
232     ExtensionStates();
233     ExtensionTraversalState get_state(RegisteredExtension* extension);
234     void set_state(RegisteredExtension* extension,
235                    ExtensionTraversalState state);
236    private:
237     HashMap map_;
238     DISALLOW_COPY_AND_ASSIGN(ExtensionStates);
239   };
240 
241   // Used both for deserialized and from-scratch contexts to add the extensions
242   // provided.
243   static bool InstallExtensions(Handle<Context> native_context,
244                                 v8::ExtensionConfiguration* extensions);
245   static bool InstallAutoExtensions(Isolate* isolate,
246                                     ExtensionStates* extension_states);
247   static bool InstallRequestedExtensions(Isolate* isolate,
248                                          v8::ExtensionConfiguration* extensions,
249                                          ExtensionStates* extension_states);
250   static bool InstallExtension(Isolate* isolate,
251                                const char* name,
252                                ExtensionStates* extension_states);
253   static bool InstallExtension(Isolate* isolate,
254                                v8::RegisteredExtension* current,
255                                ExtensionStates* extension_states);
256   static bool InstallSpecialObjects(Handle<Context> native_context);
257   bool InstallJSBuiltins(Handle<JSBuiltinsObject> builtins);
258   bool ConfigureApiObject(Handle<JSObject> object,
259                           Handle<ObjectTemplateInfo> object_template);
260   bool ConfigureGlobalObjects(
261       v8::Handle<v8::ObjectTemplate> global_proxy_template);
262 
263   // Migrates all properties from the 'from' object to the 'to'
264   // object and overrides the prototype in 'to' with the one from
265   // 'from'.
266   void TransferObject(Handle<JSObject> from, Handle<JSObject> to);
267   void TransferNamedProperties(Handle<JSObject> from, Handle<JSObject> to);
268   void TransferIndexedProperties(Handle<JSObject> from, Handle<JSObject> to);
269 
270   enum FunctionMode {
271     // With prototype.
272     FUNCTION_WITH_WRITEABLE_PROTOTYPE,
273     FUNCTION_WITH_READONLY_PROTOTYPE,
274     // Without prototype.
275     FUNCTION_WITHOUT_PROTOTYPE,
276     BOUND_FUNCTION
277   };
278 
IsFunctionModeWithPrototype(FunctionMode function_mode)279   static bool IsFunctionModeWithPrototype(FunctionMode function_mode) {
280     return (function_mode == FUNCTION_WITH_WRITEABLE_PROTOTYPE ||
281             function_mode == FUNCTION_WITH_READONLY_PROTOTYPE);
282   }
283 
284   Handle<Map> CreateFunctionMap(FunctionMode function_mode);
285 
286   void SetFunctionInstanceDescriptor(Handle<Map> map,
287                                      FunctionMode function_mode);
288   void MakeFunctionInstancePrototypeWritable();
289 
290   Handle<Map> CreateStrictFunctionMap(
291       FunctionMode function_mode,
292       Handle<JSFunction> empty_function);
293 
294   void SetStrictFunctionInstanceDescriptor(Handle<Map> map,
295                                            FunctionMode function_mode);
296 
297   static bool CompileBuiltin(Isolate* isolate, int index);
298   static bool CompileExperimentalBuiltin(Isolate* isolate, int index);
299   static bool CompileNative(Isolate* isolate,
300                             Vector<const char> name,
301                             Handle<String> source);
302   static bool CompileScriptCached(Isolate* isolate,
303                                   Vector<const char> name,
304                                   Handle<String> source,
305                                   SourceCodeCache* cache,
306                                   v8::Extension* extension,
307                                   Handle<Context> top_context,
308                                   bool use_runtime_context);
309 
310   Isolate* isolate_;
311   Handle<Context> result_;
312   Handle<Context> native_context_;
313 
314   // Function maps. Function maps are created initially with a read only
315   // prototype for the processing of JS builtins. Later the function maps are
316   // replaced in order to make prototype writable. These are the final, writable
317   // prototype, maps.
318   Handle<Map> sloppy_function_map_writable_prototype_;
319   Handle<Map> strict_function_map_writable_prototype_;
320   Handle<JSFunction> strict_poison_function;
321   Handle<JSFunction> generator_poison_function;
322 
323   BootstrapperActive active_;
324   friend class Bootstrapper;
325 };
326 
327 
Iterate(ObjectVisitor * v)328 void Bootstrapper::Iterate(ObjectVisitor* v) {
329   extensions_cache_.Iterate(v);
330   v->Synchronize(VisitorSynchronization::kExtensions);
331 }
332 
333 
CreateEnvironment(MaybeHandle<JSGlobalProxy> maybe_global_proxy,v8::Handle<v8::ObjectTemplate> global_proxy_template,v8::ExtensionConfiguration * extensions)334 Handle<Context> Bootstrapper::CreateEnvironment(
335     MaybeHandle<JSGlobalProxy> maybe_global_proxy,
336     v8::Handle<v8::ObjectTemplate> global_proxy_template,
337     v8::ExtensionConfiguration* extensions) {
338   HandleScope scope(isolate_);
339   Genesis genesis(
340       isolate_, maybe_global_proxy, global_proxy_template, extensions);
341   Handle<Context> env = genesis.result();
342   if (env.is_null() || !InstallExtensions(env, extensions)) {
343     return Handle<Context>();
344   }
345   return scope.CloseAndEscape(env);
346 }
347 
348 
SetObjectPrototype(Handle<JSObject> object,Handle<Object> proto)349 static void SetObjectPrototype(Handle<JSObject> object, Handle<Object> proto) {
350   // object.__proto__ = proto;
351   Handle<Map> old_map = Handle<Map>(object->map());
352   Handle<Map> new_map = Map::Copy(old_map);
353   new_map->set_prototype(*proto);
354   JSObject::MigrateToMap(object, new_map);
355 }
356 
357 
DetachGlobal(Handle<Context> env)358 void Bootstrapper::DetachGlobal(Handle<Context> env) {
359   Factory* factory = env->GetIsolate()->factory();
360   Handle<JSGlobalProxy> global_proxy(JSGlobalProxy::cast(env->global_proxy()));
361   global_proxy->set_native_context(*factory->null_value());
362   SetObjectPrototype(global_proxy, factory->null_value());
363   global_proxy->map()->set_constructor(*factory->null_value());
364 }
365 
366 
InstallFunction(Handle<JSObject> target,const char * name,InstanceType type,int instance_size,MaybeHandle<JSObject> maybe_prototype,Builtins::Name call)367 static Handle<JSFunction> InstallFunction(Handle<JSObject> target,
368                                           const char* name,
369                                           InstanceType type,
370                                           int instance_size,
371                                           MaybeHandle<JSObject> maybe_prototype,
372                                           Builtins::Name call) {
373   Isolate* isolate = target->GetIsolate();
374   Factory* factory = isolate->factory();
375   Handle<String> internalized_name = factory->InternalizeUtf8String(name);
376   Handle<Code> call_code = Handle<Code>(isolate->builtins()->builtin(call));
377   Handle<JSObject> prototype;
378   Handle<JSFunction> function = maybe_prototype.ToHandle(&prototype)
379       ? factory->NewFunction(internalized_name, call_code, prototype,
380                              type, instance_size)
381       : factory->NewFunctionWithoutPrototype(internalized_name, call_code);
382   PropertyAttributes attributes;
383   if (target->IsJSBuiltinsObject()) {
384     attributes =
385         static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE | READ_ONLY);
386   } else {
387     attributes = DONT_ENUM;
388   }
389   JSObject::AddProperty(target, internalized_name, function, attributes);
390   if (target->IsJSGlobalObject()) {
391     function->shared()->set_instance_class_name(*internalized_name);
392   }
393   function->shared()->set_native(true);
394   return function;
395 }
396 
397 
SetFunctionInstanceDescriptor(Handle<Map> map,FunctionMode function_mode)398 void Genesis::SetFunctionInstanceDescriptor(
399     Handle<Map> map, FunctionMode function_mode) {
400   int size = IsFunctionModeWithPrototype(function_mode) ? 5 : 4;
401   Map::EnsureDescriptorSlack(map, size);
402 
403   PropertyAttributes attribs = static_cast<PropertyAttributes>(
404       DONT_ENUM | DONT_DELETE | READ_ONLY);
405 
406   Handle<AccessorInfo> length =
407       Accessors::FunctionLengthInfo(isolate(), attribs);
408   {  // Add length.
409     CallbacksDescriptor d(Handle<Name>(Name::cast(length->name())),
410                           length, attribs);
411     map->AppendDescriptor(&d);
412   }
413   Handle<AccessorInfo> name =
414       Accessors::FunctionNameInfo(isolate(), attribs);
415   {  // Add name.
416     CallbacksDescriptor d(Handle<Name>(Name::cast(name->name())),
417                           name, attribs);
418     map->AppendDescriptor(&d);
419   }
420   Handle<AccessorInfo> args =
421       Accessors::FunctionArgumentsInfo(isolate(), attribs);
422   {  // Add arguments.
423     CallbacksDescriptor d(Handle<Name>(Name::cast(args->name())),
424                           args, attribs);
425     map->AppendDescriptor(&d);
426   }
427   Handle<AccessorInfo> caller =
428       Accessors::FunctionCallerInfo(isolate(), attribs);
429   {  // Add caller.
430     CallbacksDescriptor d(Handle<Name>(Name::cast(caller->name())),
431                           caller, attribs);
432     map->AppendDescriptor(&d);
433   }
434   if (IsFunctionModeWithPrototype(function_mode)) {
435     if (function_mode == FUNCTION_WITH_WRITEABLE_PROTOTYPE) {
436       attribs = static_cast<PropertyAttributes>(attribs & ~READ_ONLY);
437     }
438     Handle<AccessorInfo> prototype =
439         Accessors::FunctionPrototypeInfo(isolate(), attribs);
440     CallbacksDescriptor d(Handle<Name>(Name::cast(prototype->name())),
441                           prototype, attribs);
442     map->AppendDescriptor(&d);
443   }
444 }
445 
446 
CreateFunctionMap(FunctionMode function_mode)447 Handle<Map> Genesis::CreateFunctionMap(FunctionMode function_mode) {
448   Handle<Map> map = factory()->NewMap(JS_FUNCTION_TYPE, JSFunction::kSize);
449   SetFunctionInstanceDescriptor(map, function_mode);
450   map->set_function_with_prototype(IsFunctionModeWithPrototype(function_mode));
451   return map;
452 }
453 
454 
CreateEmptyFunction(Isolate * isolate)455 Handle<JSFunction> Genesis::CreateEmptyFunction(Isolate* isolate) {
456   // Allocate the map for function instances. Maps are allocated first and their
457   // prototypes patched later, once empty function is created.
458 
459   // Functions with this map will not have a 'prototype' property, and
460   // can not be used as constructors.
461   Handle<Map> function_without_prototype_map =
462       CreateFunctionMap(FUNCTION_WITHOUT_PROTOTYPE);
463   native_context()->set_sloppy_function_without_prototype_map(
464       *function_without_prototype_map);
465 
466   // Allocate the function map. This map is temporary, used only for processing
467   // of builtins.
468   // Later the map is replaced with writable prototype map, allocated below.
469   Handle<Map> function_map =
470       CreateFunctionMap(FUNCTION_WITH_READONLY_PROTOTYPE);
471   native_context()->set_sloppy_function_map(*function_map);
472   native_context()->set_sloppy_function_with_readonly_prototype_map(
473       *function_map);
474 
475   // The final map for functions. Writeable prototype.
476   // This map is installed in MakeFunctionInstancePrototypeWritable.
477   sloppy_function_map_writable_prototype_ =
478       CreateFunctionMap(FUNCTION_WITH_WRITEABLE_PROTOTYPE);
479 
480   Factory* factory = isolate->factory();
481 
482   Handle<String> object_name = factory->Object_string();
483 
484   {  // --- O b j e c t ---
485     Handle<JSFunction> object_fun = factory->NewFunction(object_name);
486     int unused = JSObject::kInitialGlobalObjectUnusedPropertiesCount;
487     int instance_size = JSObject::kHeaderSize + kPointerSize * unused;
488     Handle<Map> object_function_map =
489         factory->NewMap(JS_OBJECT_TYPE, instance_size);
490     object_function_map->set_inobject_properties(unused);
491     JSFunction::SetInitialMap(object_fun, object_function_map,
492                               isolate->factory()->null_value());
493     object_function_map->set_unused_property_fields(unused);
494 
495     native_context()->set_object_function(*object_fun);
496 
497     // Allocate a new prototype for the object function.
498     Handle<JSObject> prototype = factory->NewJSObject(
499         isolate->object_function(),
500         TENURED);
501     Handle<Map> map = Map::Copy(handle(prototype->map()));
502     map->set_is_prototype_map(true);
503     prototype->set_map(*map);
504 
505     native_context()->set_initial_object_prototype(*prototype);
506     // For bootstrapping set the array prototype to be the same as the object
507     // prototype, otherwise the missing initial_array_prototype will cause
508     // assertions during startup.
509     native_context()->set_initial_array_prototype(*prototype);
510     Accessors::FunctionSetPrototype(object_fun, prototype);
511   }
512 
513   // Allocate the empty function as the prototype for function ECMAScript
514   // 262 15.3.4.
515   Handle<String> empty_string =
516       factory->InternalizeOneByteString(STATIC_CHAR_VECTOR("Empty"));
517   Handle<Code> code(isolate->builtins()->builtin(Builtins::kEmptyFunction));
518   Handle<JSFunction> empty_function = factory->NewFunctionWithoutPrototype(
519       empty_string, code);
520 
521   // Allocate the function map first and then patch the prototype later
522   Handle<Map> empty_function_map =
523       CreateFunctionMap(FUNCTION_WITHOUT_PROTOTYPE);
524   DCHECK(!empty_function_map->is_dictionary_map());
525   empty_function_map->set_prototype(
526       native_context()->object_function()->prototype());
527   empty_function_map->set_is_prototype_map(true);
528   empty_function->set_map(*empty_function_map);
529 
530   // --- E m p t y ---
531   Handle<String> source = factory->NewStringFromStaticChars("() {}");
532   Handle<Script> script = factory->NewScript(source);
533   script->set_type(Smi::FromInt(Script::TYPE_NATIVE));
534   empty_function->shared()->set_script(*script);
535   empty_function->shared()->set_start_position(0);
536   empty_function->shared()->set_end_position(source->length());
537   empty_function->shared()->DontAdaptArguments();
538 
539   // Set prototypes for the function maps.
540   native_context()->sloppy_function_map()->set_prototype(*empty_function);
541   native_context()->sloppy_function_without_prototype_map()->
542       set_prototype(*empty_function);
543   sloppy_function_map_writable_prototype_->set_prototype(*empty_function);
544   return empty_function;
545 }
546 
547 
SetStrictFunctionInstanceDescriptor(Handle<Map> map,FunctionMode function_mode)548 void Genesis::SetStrictFunctionInstanceDescriptor(
549     Handle<Map> map, FunctionMode function_mode) {
550   int size = IsFunctionModeWithPrototype(function_mode) ? 5 : 4;
551   Map::EnsureDescriptorSlack(map, size);
552 
553   Handle<AccessorPair> arguments(factory()->NewAccessorPair());
554   Handle<AccessorPair> caller(factory()->NewAccessorPair());
555   PropertyAttributes rw_attribs =
556       static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE);
557   PropertyAttributes ro_attribs =
558       static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE | READ_ONLY);
559 
560   // Add length.
561   if (function_mode == BOUND_FUNCTION) {
562     Handle<String> length_string = isolate()->factory()->length_string();
563     FieldDescriptor d(length_string, 0, ro_attribs, Representation::Tagged());
564     map->AppendDescriptor(&d);
565   } else {
566     DCHECK(function_mode == FUNCTION_WITH_WRITEABLE_PROTOTYPE ||
567            function_mode == FUNCTION_WITH_READONLY_PROTOTYPE ||
568            function_mode == FUNCTION_WITHOUT_PROTOTYPE);
569     Handle<AccessorInfo> length =
570         Accessors::FunctionLengthInfo(isolate(), ro_attribs);
571     CallbacksDescriptor d(Handle<Name>(Name::cast(length->name())),
572                           length, ro_attribs);
573     map->AppendDescriptor(&d);
574   }
575   Handle<AccessorInfo> name =
576       Accessors::FunctionNameInfo(isolate(), ro_attribs);
577   {  // Add name.
578     CallbacksDescriptor d(Handle<Name>(Name::cast(name->name())),
579                           name, ro_attribs);
580     map->AppendDescriptor(&d);
581   }
582   {  // Add arguments.
583     CallbacksDescriptor d(factory()->arguments_string(), arguments,
584                           rw_attribs);
585     map->AppendDescriptor(&d);
586   }
587   {  // Add caller.
588     CallbacksDescriptor d(factory()->caller_string(), caller, rw_attribs);
589     map->AppendDescriptor(&d);
590   }
591   if (IsFunctionModeWithPrototype(function_mode)) {
592     // Add prototype.
593     PropertyAttributes attribs =
594         function_mode == FUNCTION_WITH_WRITEABLE_PROTOTYPE ? rw_attribs
595                                                            : ro_attribs;
596     Handle<AccessorInfo> prototype =
597         Accessors::FunctionPrototypeInfo(isolate(), attribs);
598     CallbacksDescriptor d(Handle<Name>(Name::cast(prototype->name())),
599                           prototype, attribs);
600     map->AppendDescriptor(&d);
601   }
602 }
603 
604 
605 // ECMAScript 5th Edition, 13.2.3
GetStrictPoisonFunction()606 Handle<JSFunction> Genesis::GetStrictPoisonFunction() {
607   if (strict_poison_function.is_null()) {
608     Handle<String> name = factory()->InternalizeOneByteString(
609         STATIC_CHAR_VECTOR("ThrowTypeError"));
610     Handle<Code> code(isolate()->builtins()->builtin(
611         Builtins::kStrictModePoisonPill));
612     strict_poison_function = factory()->NewFunctionWithoutPrototype(name, code);
613     strict_poison_function->set_map(native_context()->sloppy_function_map());
614     strict_poison_function->shared()->DontAdaptArguments();
615 
616     JSObject::PreventExtensions(strict_poison_function).Assert();
617   }
618   return strict_poison_function;
619 }
620 
621 
GetGeneratorPoisonFunction()622 Handle<JSFunction> Genesis::GetGeneratorPoisonFunction() {
623   if (generator_poison_function.is_null()) {
624     Handle<String> name = factory()->InternalizeOneByteString(
625         STATIC_CHAR_VECTOR("ThrowTypeError"));
626     Handle<Code> code(isolate()->builtins()->builtin(
627         Builtins::kGeneratorPoisonPill));
628     generator_poison_function = factory()->NewFunctionWithoutPrototype(
629         name, code);
630     generator_poison_function->set_map(native_context()->sloppy_function_map());
631     generator_poison_function->shared()->DontAdaptArguments();
632 
633     JSObject::PreventExtensions(generator_poison_function).Assert();
634   }
635   return generator_poison_function;
636 }
637 
638 
CreateStrictFunctionMap(FunctionMode function_mode,Handle<JSFunction> empty_function)639 Handle<Map> Genesis::CreateStrictFunctionMap(
640     FunctionMode function_mode,
641     Handle<JSFunction> empty_function) {
642   Handle<Map> map = factory()->NewMap(JS_FUNCTION_TYPE, JSFunction::kSize);
643   SetStrictFunctionInstanceDescriptor(map, function_mode);
644   map->set_function_with_prototype(IsFunctionModeWithPrototype(function_mode));
645   map->set_prototype(*empty_function);
646   return map;
647 }
648 
649 
CreateStrictModeFunctionMaps(Handle<JSFunction> empty)650 void Genesis::CreateStrictModeFunctionMaps(Handle<JSFunction> empty) {
651   // Allocate map for the prototype-less strict mode instances.
652   Handle<Map> strict_function_without_prototype_map =
653       CreateStrictFunctionMap(FUNCTION_WITHOUT_PROTOTYPE, empty);
654   native_context()->set_strict_function_without_prototype_map(
655       *strict_function_without_prototype_map);
656 
657   // Allocate map for the strict mode functions. This map is temporary, used
658   // only for processing of builtins.
659   // Later the map is replaced with writable prototype map, allocated below.
660   Handle<Map> strict_function_map =
661       CreateStrictFunctionMap(FUNCTION_WITH_READONLY_PROTOTYPE, empty);
662   native_context()->set_strict_function_map(*strict_function_map);
663 
664   // The final map for the strict mode functions. Writeable prototype.
665   // This map is installed in MakeFunctionInstancePrototypeWritable.
666   strict_function_map_writable_prototype_ =
667       CreateStrictFunctionMap(FUNCTION_WITH_WRITEABLE_PROTOTYPE, empty);
668   // Special map for bound functions.
669   Handle<Map> bound_function_map =
670       CreateStrictFunctionMap(BOUND_FUNCTION, empty);
671   native_context()->set_bound_function_map(*bound_function_map);
672 
673   // Complete the callbacks.
674   PoisonArgumentsAndCaller(strict_function_without_prototype_map);
675   PoisonArgumentsAndCaller(strict_function_map);
676   PoisonArgumentsAndCaller(strict_function_map_writable_prototype_);
677   PoisonArgumentsAndCaller(bound_function_map);
678 }
679 
680 
SetAccessors(Handle<Map> map,Handle<String> name,Handle<JSFunction> func)681 static void SetAccessors(Handle<Map> map,
682                          Handle<String> name,
683                          Handle<JSFunction> func) {
684   DescriptorArray* descs = map->instance_descriptors();
685   int number = descs->SearchWithCache(*name, *map);
686   AccessorPair* accessors = AccessorPair::cast(descs->GetValue(number));
687   accessors->set_getter(*func);
688   accessors->set_setter(*func);
689 }
690 
691 
ReplaceAccessors(Handle<Map> map,Handle<String> name,PropertyAttributes attributes,Handle<AccessorPair> accessor_pair)692 static void ReplaceAccessors(Handle<Map> map,
693                              Handle<String> name,
694                              PropertyAttributes attributes,
695                              Handle<AccessorPair> accessor_pair) {
696   DescriptorArray* descriptors = map->instance_descriptors();
697   int idx = descriptors->SearchWithCache(*name, *map);
698   CallbacksDescriptor descriptor(name, accessor_pair, attributes);
699   descriptors->Replace(idx, &descriptor);
700 }
701 
702 
PoisonArgumentsAndCaller(Handle<Map> map)703 void Genesis::PoisonArgumentsAndCaller(Handle<Map> map) {
704   SetAccessors(map, factory()->arguments_string(), GetStrictPoisonFunction());
705   SetAccessors(map, factory()->caller_string(), GetStrictPoisonFunction());
706 }
707 
708 
AddToWeakNativeContextList(Context * context)709 static void AddToWeakNativeContextList(Context* context) {
710   DCHECK(context->IsNativeContext());
711   Heap* heap = context->GetIsolate()->heap();
712 #ifdef DEBUG
713   { // NOLINT
714     DCHECK(context->get(Context::NEXT_CONTEXT_LINK)->IsUndefined());
715     // Check that context is not in the list yet.
716     for (Object* current = heap->native_contexts_list();
717          !current->IsUndefined();
718          current = Context::cast(current)->get(Context::NEXT_CONTEXT_LINK)) {
719       DCHECK(current != context);
720     }
721   }
722 #endif
723   context->set(Context::NEXT_CONTEXT_LINK, heap->native_contexts_list());
724   heap->set_native_contexts_list(context);
725 }
726 
727 
CreateRoots()728 void Genesis::CreateRoots() {
729   // Allocate the native context FixedArray first and then patch the
730   // closure and extension object later (we need the empty function
731   // and the global object, but in order to create those, we need the
732   // native context).
733   native_context_ = factory()->NewNativeContext();
734   AddToWeakNativeContextList(*native_context());
735   isolate()->set_context(*native_context());
736 
737   // Allocate the message listeners object.
738   {
739     v8::NeanderArray listeners(isolate());
740     native_context()->set_message_listeners(*listeners.value());
741   }
742 }
743 
744 
CreateNewGlobals(v8::Handle<v8::ObjectTemplate> global_proxy_template,MaybeHandle<JSGlobalProxy> maybe_global_proxy,Handle<GlobalObject> * global_object_out)745 Handle<JSGlobalProxy> Genesis::CreateNewGlobals(
746     v8::Handle<v8::ObjectTemplate> global_proxy_template,
747     MaybeHandle<JSGlobalProxy> maybe_global_proxy,
748     Handle<GlobalObject>* global_object_out) {
749   // The argument global_proxy_template aka data is an ObjectTemplateInfo.
750   // It has a constructor pointer that points at global_constructor which is a
751   // FunctionTemplateInfo.
752   // The global_proxy_constructor is used to create or reinitialize the
753   // global_proxy. The global_proxy_constructor also has a prototype_template
754   // pointer that points at js_global_object_template which is an
755   // ObjectTemplateInfo.
756   // That in turn has a constructor pointer that points at
757   // js_global_object_constructor which is a FunctionTemplateInfo.
758   // js_global_object_constructor is used to make js_global_object_function
759   // js_global_object_function is used to make the new global_object.
760   //
761   // --- G l o b a l ---
762   // Step 1: Create a fresh JSGlobalObject.
763   Handle<JSFunction> js_global_object_function;
764   Handle<ObjectTemplateInfo> js_global_object_template;
765   if (!global_proxy_template.IsEmpty()) {
766     // Get prototype template of the global_proxy_template.
767     Handle<ObjectTemplateInfo> data =
768         v8::Utils::OpenHandle(*global_proxy_template);
769     Handle<FunctionTemplateInfo> global_constructor =
770         Handle<FunctionTemplateInfo>(
771             FunctionTemplateInfo::cast(data->constructor()));
772     Handle<Object> proto_template(global_constructor->prototype_template(),
773                                   isolate());
774     if (!proto_template->IsUndefined()) {
775       js_global_object_template =
776           Handle<ObjectTemplateInfo>::cast(proto_template);
777     }
778   }
779 
780   if (js_global_object_template.is_null()) {
781     Handle<String> name = Handle<String>(heap()->empty_string());
782     Handle<Code> code = Handle<Code>(isolate()->builtins()->builtin(
783         Builtins::kIllegal));
784     Handle<JSObject> prototype =
785         factory()->NewFunctionPrototype(isolate()->object_function());
786     js_global_object_function = factory()->NewFunction(
787         name, code, prototype, JS_GLOBAL_OBJECT_TYPE, JSGlobalObject::kSize);
788 #ifdef DEBUG
789     LookupIterator it(prototype, factory()->constructor_string(),
790                       LookupIterator::OWN_SKIP_INTERCEPTOR);
791     Handle<Object> value = JSReceiver::GetProperty(&it).ToHandleChecked();
792     DCHECK(it.IsFound());
793     DCHECK_EQ(*isolate()->object_function(), *value);
794 #endif
795   } else {
796     Handle<FunctionTemplateInfo> js_global_object_constructor(
797         FunctionTemplateInfo::cast(js_global_object_template->constructor()));
798     js_global_object_function =
799         factory()->CreateApiFunction(js_global_object_constructor,
800                                      factory()->the_hole_value(),
801                                      factory()->GlobalObjectType);
802   }
803 
804   js_global_object_function->initial_map()->set_is_hidden_prototype();
805   js_global_object_function->initial_map()->set_dictionary_map(true);
806   Handle<GlobalObject> global_object =
807       factory()->NewGlobalObject(js_global_object_function);
808   if (global_object_out != NULL) {
809     *global_object_out = global_object;
810   }
811 
812   // Step 2: create or re-initialize the global proxy object.
813   Handle<JSFunction> global_proxy_function;
814   if (global_proxy_template.IsEmpty()) {
815     Handle<String> name = Handle<String>(heap()->empty_string());
816     Handle<Code> code = Handle<Code>(isolate()->builtins()->builtin(
817         Builtins::kIllegal));
818     global_proxy_function = factory()->NewFunction(
819         name, code, JS_GLOBAL_PROXY_TYPE, JSGlobalProxy::kSize);
820   } else {
821     Handle<ObjectTemplateInfo> data =
822         v8::Utils::OpenHandle(*global_proxy_template);
823     Handle<FunctionTemplateInfo> global_constructor(
824             FunctionTemplateInfo::cast(data->constructor()));
825     global_proxy_function =
826         factory()->CreateApiFunction(global_constructor,
827                                      factory()->the_hole_value(),
828                                      factory()->GlobalProxyType);
829   }
830 
831   Handle<String> global_name = factory()->global_string();
832   global_proxy_function->shared()->set_instance_class_name(*global_name);
833   global_proxy_function->initial_map()->set_is_access_check_needed(true);
834 
835   // Set global_proxy.__proto__ to js_global after ConfigureGlobalObjects
836   // Return the global proxy.
837 
838   Handle<JSGlobalProxy> global_proxy;
839   if (maybe_global_proxy.ToHandle(&global_proxy)) {
840     factory()->ReinitializeJSGlobalProxy(global_proxy, global_proxy_function);
841   } else {
842     global_proxy = Handle<JSGlobalProxy>::cast(
843         factory()->NewJSObject(global_proxy_function, TENURED));
844     global_proxy->set_hash(heap()->undefined_value());
845   }
846   return global_proxy;
847 }
848 
849 
HookUpGlobalProxy(Handle<GlobalObject> global_object,Handle<JSGlobalProxy> global_proxy)850 void Genesis::HookUpGlobalProxy(Handle<GlobalObject> global_object,
851                                 Handle<JSGlobalProxy> global_proxy) {
852   // Set the native context for the global object.
853   global_object->set_native_context(*native_context());
854   global_object->set_global_context(*native_context());
855   global_object->set_global_proxy(*global_proxy);
856   global_proxy->set_native_context(*native_context());
857   native_context()->set_global_proxy(*global_proxy);
858 }
859 
860 
HookUpGlobalObject(Handle<GlobalObject> global_object)861 void Genesis::HookUpGlobalObject(Handle<GlobalObject> global_object) {
862   Handle<GlobalObject> global_object_from_snapshot(
863       GlobalObject::cast(native_context()->extension()));
864   Handle<JSBuiltinsObject> builtins_global(native_context()->builtins());
865   native_context()->set_extension(*global_object);
866   native_context()->set_global_object(*global_object);
867   native_context()->set_security_token(*global_object);
868   static const PropertyAttributes attributes =
869       static_cast<PropertyAttributes>(READ_ONLY | DONT_DELETE);
870   Runtime::DefineObjectProperty(builtins_global, factory()->global_string(),
871                                 global_object, attributes).Assert();
872   // Set up the reference from the global object to the builtins object.
873   JSGlobalObject::cast(*global_object)->set_builtins(*builtins_global);
874   TransferNamedProperties(global_object_from_snapshot, global_object);
875   TransferIndexedProperties(global_object_from_snapshot, global_object);
876 }
877 
878 
879 // This is only called if we are not using snapshots.  The equivalent
880 // work in the snapshot case is done in HookUpGlobalObject.
InitializeGlobal(Handle<GlobalObject> global_object,Handle<JSFunction> empty_function)881 void Genesis::InitializeGlobal(Handle<GlobalObject> global_object,
882                                Handle<JSFunction> empty_function) {
883   // --- N a t i v e   C o n t e x t ---
884   // Use the empty function as closure (no scope info).
885   native_context()->set_closure(*empty_function);
886   native_context()->set_previous(NULL);
887   // Set extension and global object.
888   native_context()->set_extension(*global_object);
889   native_context()->set_global_object(*global_object);
890   // Security setup: Set the security token of the native context to the global
891   // object. This makes the security check between two different contexts fail
892   // by default even in case of global object reinitialization.
893   native_context()->set_security_token(*global_object);
894 
895   Isolate* isolate = global_object->GetIsolate();
896   Factory* factory = isolate->factory();
897   Heap* heap = isolate->heap();
898 
899   Handle<String> object_name = factory->Object_string();
900   JSObject::AddProperty(
901       global_object, object_name, isolate->object_function(), DONT_ENUM);
902 
903   Handle<JSObject> global(native_context()->global_object());
904 
905   // Install global Function object
906   InstallFunction(global, "Function", JS_FUNCTION_TYPE, JSFunction::kSize,
907                   empty_function, Builtins::kIllegal);
908 
909   {  // --- A r r a y ---
910     Handle<JSFunction> array_function =
911         InstallFunction(global, "Array", JS_ARRAY_TYPE, JSArray::kSize,
912                         isolate->initial_object_prototype(),
913                         Builtins::kArrayCode);
914     array_function->shared()->DontAdaptArguments();
915     array_function->shared()->set_function_data(Smi::FromInt(kArrayCode));
916 
917     // This seems a bit hackish, but we need to make sure Array.length
918     // is 1.
919     array_function->shared()->set_length(1);
920 
921     Handle<Map> initial_map(array_function->initial_map());
922 
923     // This assert protects an optimization in
924     // HGraphBuilder::JSArrayBuilder::EmitMapCode()
925     DCHECK(initial_map->elements_kind() == GetInitialFastElementsKind());
926     Map::EnsureDescriptorSlack(initial_map, 1);
927 
928     PropertyAttributes attribs = static_cast<PropertyAttributes>(
929         DONT_ENUM | DONT_DELETE);
930 
931     Handle<AccessorInfo> array_length =
932         Accessors::ArrayLengthInfo(isolate, attribs);
933     {  // Add length.
934       CallbacksDescriptor d(
935           Handle<Name>(Name::cast(array_length->name())),
936           array_length, attribs);
937       array_function->initial_map()->AppendDescriptor(&d);
938     }
939 
940     // array_function is used internally. JS code creating array object should
941     // search for the 'Array' property on the global object and use that one
942     // as the constructor. 'Array' property on a global object can be
943     // overwritten by JS code.
944     native_context()->set_array_function(*array_function);
945 
946     // Cache the array maps, needed by ArrayConstructorStub
947     CacheInitialJSArrayMaps(native_context(), initial_map);
948     ArrayConstructorStub array_constructor_stub(isolate);
949     Handle<Code> code = array_constructor_stub.GetCode();
950     array_function->shared()->set_construct_stub(*code);
951   }
952 
953   {  // --- N u m b e r ---
954     Handle<JSFunction> number_fun =
955         InstallFunction(global, "Number", JS_VALUE_TYPE, JSValue::kSize,
956                         isolate->initial_object_prototype(),
957                         Builtins::kIllegal);
958     native_context()->set_number_function(*number_fun);
959   }
960 
961   {  // --- B o o l e a n ---
962     Handle<JSFunction> boolean_fun =
963         InstallFunction(global, "Boolean", JS_VALUE_TYPE, JSValue::kSize,
964                         isolate->initial_object_prototype(),
965                         Builtins::kIllegal);
966     native_context()->set_boolean_function(*boolean_fun);
967   }
968 
969   {  // --- S t r i n g ---
970     Handle<JSFunction> string_fun =
971         InstallFunction(global, "String", JS_VALUE_TYPE, JSValue::kSize,
972                         isolate->initial_object_prototype(),
973                         Builtins::kIllegal);
974     string_fun->shared()->set_construct_stub(
975         isolate->builtins()->builtin(Builtins::kStringConstructCode));
976     native_context()->set_string_function(*string_fun);
977 
978     Handle<Map> string_map =
979         Handle<Map>(native_context()->string_function()->initial_map());
980     Map::EnsureDescriptorSlack(string_map, 1);
981 
982     PropertyAttributes attribs = static_cast<PropertyAttributes>(
983         DONT_ENUM | DONT_DELETE | READ_ONLY);
984     Handle<AccessorInfo> string_length(
985         Accessors::StringLengthInfo(isolate, attribs));
986 
987     {  // Add length.
988       CallbacksDescriptor d(factory->length_string(), string_length, attribs);
989       string_map->AppendDescriptor(&d);
990     }
991   }
992 
993   {
994     // --- S y m b o l ---
995     Handle<JSFunction> symbol_fun = InstallFunction(
996         global, "Symbol", JS_VALUE_TYPE, JSValue::kSize,
997         isolate->initial_object_prototype(), Builtins::kIllegal);
998     native_context()->set_symbol_function(*symbol_fun);
999   }
1000 
1001   {  // --- D a t e ---
1002     // Builtin functions for Date.prototype.
1003     Handle<JSFunction> date_fun =
1004         InstallFunction(global, "Date", JS_DATE_TYPE, JSDate::kSize,
1005                         isolate->initial_object_prototype(),
1006                         Builtins::kIllegal);
1007 
1008     native_context()->set_date_function(*date_fun);
1009   }
1010 
1011 
1012   {  // -- R e g E x p
1013     // Builtin functions for RegExp.prototype.
1014     Handle<JSFunction> regexp_fun =
1015         InstallFunction(global, "RegExp", JS_REGEXP_TYPE, JSRegExp::kSize,
1016                         isolate->initial_object_prototype(),
1017                         Builtins::kIllegal);
1018     native_context()->set_regexp_function(*regexp_fun);
1019 
1020     DCHECK(regexp_fun->has_initial_map());
1021     Handle<Map> initial_map(regexp_fun->initial_map());
1022 
1023     DCHECK_EQ(0, initial_map->inobject_properties());
1024 
1025     PropertyAttributes final =
1026         static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE | READ_ONLY);
1027     Map::EnsureDescriptorSlack(initial_map, 5);
1028 
1029     {
1030       // ECMA-262, section 15.10.7.1.
1031       FieldDescriptor field(factory->source_string(),
1032                             JSRegExp::kSourceFieldIndex,
1033                             final,
1034                             Representation::Tagged());
1035       initial_map->AppendDescriptor(&field);
1036     }
1037     {
1038       // ECMA-262, section 15.10.7.2.
1039       FieldDescriptor field(factory->global_string(),
1040                             JSRegExp::kGlobalFieldIndex,
1041                             final,
1042                             Representation::Tagged());
1043       initial_map->AppendDescriptor(&field);
1044     }
1045     {
1046       // ECMA-262, section 15.10.7.3.
1047       FieldDescriptor field(factory->ignore_case_string(),
1048                             JSRegExp::kIgnoreCaseFieldIndex,
1049                             final,
1050                             Representation::Tagged());
1051       initial_map->AppendDescriptor(&field);
1052     }
1053     {
1054       // ECMA-262, section 15.10.7.4.
1055       FieldDescriptor field(factory->multiline_string(),
1056                             JSRegExp::kMultilineFieldIndex,
1057                             final,
1058                             Representation::Tagged());
1059       initial_map->AppendDescriptor(&field);
1060     }
1061     {
1062       // ECMA-262, section 15.10.7.5.
1063       PropertyAttributes writable =
1064           static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE);
1065       FieldDescriptor field(factory->last_index_string(),
1066                             JSRegExp::kLastIndexFieldIndex,
1067                             writable,
1068                             Representation::Tagged());
1069       initial_map->AppendDescriptor(&field);
1070     }
1071 
1072     initial_map->set_inobject_properties(5);
1073     initial_map->set_pre_allocated_property_fields(5);
1074     initial_map->set_unused_property_fields(0);
1075     initial_map->set_instance_size(
1076         initial_map->instance_size() + 5 * kPointerSize);
1077     initial_map->set_visitor_id(StaticVisitorBase::GetVisitorId(*initial_map));
1078 
1079     // RegExp prototype object is itself a RegExp.
1080     Handle<Map> proto_map = Map::Copy(initial_map);
1081     proto_map->set_prototype(native_context()->initial_object_prototype());
1082     Handle<JSObject> proto = factory->NewJSObjectFromMap(proto_map);
1083     proto->InObjectPropertyAtPut(JSRegExp::kSourceFieldIndex,
1084                                  heap->query_colon_string());
1085     proto->InObjectPropertyAtPut(JSRegExp::kGlobalFieldIndex,
1086                                  heap->false_value());
1087     proto->InObjectPropertyAtPut(JSRegExp::kIgnoreCaseFieldIndex,
1088                                  heap->false_value());
1089     proto->InObjectPropertyAtPut(JSRegExp::kMultilineFieldIndex,
1090                                  heap->false_value());
1091     proto->InObjectPropertyAtPut(JSRegExp::kLastIndexFieldIndex,
1092                                  Smi::FromInt(0),
1093                                  SKIP_WRITE_BARRIER);  // It's a Smi.
1094     proto_map->set_is_prototype_map(true);
1095     initial_map->set_prototype(*proto);
1096     factory->SetRegExpIrregexpData(Handle<JSRegExp>::cast(proto),
1097                                    JSRegExp::IRREGEXP, factory->empty_string(),
1098                                    JSRegExp::Flags(0), 0);
1099   }
1100 
1101   {  // -- J S O N
1102     Handle<String> name = factory->InternalizeUtf8String("JSON");
1103     Handle<JSFunction> cons = factory->NewFunction(name);
1104     JSFunction::SetInstancePrototype(cons,
1105         Handle<Object>(native_context()->initial_object_prototype(), isolate));
1106     cons->SetInstanceClassName(*name);
1107     Handle<JSObject> json_object = factory->NewJSObject(cons, TENURED);
1108     DCHECK(json_object->IsJSObject());
1109     JSObject::AddProperty(global, name, json_object, DONT_ENUM);
1110     native_context()->set_json_object(*json_object);
1111   }
1112 
1113   {  // -- A r r a y B u f f e r
1114     Handle<JSFunction> array_buffer_fun =
1115         InstallFunction(
1116             global, "ArrayBuffer", JS_ARRAY_BUFFER_TYPE,
1117             JSArrayBuffer::kSizeWithInternalFields,
1118             isolate->initial_object_prototype(),
1119             Builtins::kIllegal);
1120     native_context()->set_array_buffer_fun(*array_buffer_fun);
1121   }
1122 
1123   {  // -- T y p e d A r r a y s
1124 #define INSTALL_TYPED_ARRAY(Type, type, TYPE, ctype, size)                    \
1125     {                                                                         \
1126       Handle<JSFunction> fun;                                                 \
1127       Handle<Map> external_map;                                               \
1128       InstallTypedArray(#Type "Array",                                        \
1129           TYPE##_ELEMENTS,                                                    \
1130           &fun,                                                               \
1131           &external_map);                                                     \
1132       native_context()->set_##type##_array_fun(*fun);                         \
1133       native_context()->set_##type##_array_external_map(*external_map);       \
1134     }
1135     TYPED_ARRAYS(INSTALL_TYPED_ARRAY)
1136 #undef INSTALL_TYPED_ARRAY
1137 
1138     Handle<JSFunction> data_view_fun =
1139         InstallFunction(
1140             global, "DataView", JS_DATA_VIEW_TYPE,
1141             JSDataView::kSizeWithInternalFields,
1142             isolate->initial_object_prototype(),
1143             Builtins::kIllegal);
1144     native_context()->set_data_view_fun(*data_view_fun);
1145   }
1146 
1147   // -- M a p
1148   InstallFunction(global, "Map", JS_MAP_TYPE, JSMap::kSize,
1149                   isolate->initial_object_prototype(), Builtins::kIllegal);
1150 
1151   // -- S e t
1152   InstallFunction(global, "Set", JS_SET_TYPE, JSSet::kSize,
1153                   isolate->initial_object_prototype(), Builtins::kIllegal);
1154 
1155   {  // Set up the iterator result object
1156     STATIC_ASSERT(JSGeneratorObject::kResultPropertyCount == 2);
1157     Handle<JSFunction> object_function(native_context()->object_function());
1158     Handle<Map> iterator_result_map =
1159         Map::Create(isolate, JSGeneratorObject::kResultPropertyCount);
1160     DCHECK_EQ(JSGeneratorObject::kResultSize,
1161               iterator_result_map->instance_size());
1162     DCHECK_EQ(JSGeneratorObject::kResultPropertyCount,
1163               iterator_result_map->inobject_properties());
1164     Map::EnsureDescriptorSlack(iterator_result_map,
1165                                JSGeneratorObject::kResultPropertyCount);
1166 
1167     FieldDescriptor value_descr(factory->value_string(),
1168                                 JSGeneratorObject::kResultValuePropertyIndex,
1169                                 NONE, Representation::Tagged());
1170     iterator_result_map->AppendDescriptor(&value_descr);
1171 
1172     FieldDescriptor done_descr(factory->done_string(),
1173                                JSGeneratorObject::kResultDonePropertyIndex,
1174                                NONE, Representation::Tagged());
1175     iterator_result_map->AppendDescriptor(&done_descr);
1176 
1177     iterator_result_map->set_unused_property_fields(0);
1178     iterator_result_map->set_pre_allocated_property_fields(
1179         JSGeneratorObject::kResultPropertyCount);
1180     DCHECK_EQ(JSGeneratorObject::kResultSize,
1181               iterator_result_map->instance_size());
1182     native_context()->set_iterator_result_map(*iterator_result_map);
1183   }
1184 
1185   // -- W e a k M a p
1186   InstallFunction(global, "WeakMap", JS_WEAK_MAP_TYPE, JSWeakMap::kSize,
1187                   isolate->initial_object_prototype(), Builtins::kIllegal);
1188   // -- W e a k S e t
1189   InstallFunction(global, "WeakSet", JS_WEAK_SET_TYPE, JSWeakSet::kSize,
1190                   isolate->initial_object_prototype(), Builtins::kIllegal);
1191 
1192   {  // --- sloppy arguments map
1193     // Make sure we can recognize argument objects at runtime.
1194     // This is done by introducing an anonymous function with
1195     // class_name equals 'Arguments'.
1196     Handle<String> arguments_string = factory->Arguments_string();
1197     Handle<Code> code(isolate->builtins()->builtin(Builtins::kIllegal));
1198     Handle<JSFunction> function = factory->NewFunctionWithoutPrototype(
1199         arguments_string, code);
1200     function->shared()->set_instance_class_name(*arguments_string);
1201 
1202     Handle<Map> map =
1203         factory->NewMap(JS_OBJECT_TYPE, Heap::kSloppyArgumentsObjectSize);
1204     // Create the descriptor array for the arguments object.
1205     Map::EnsureDescriptorSlack(map, 2);
1206 
1207     {  // length
1208       FieldDescriptor d(factory->length_string(), Heap::kArgumentsLengthIndex,
1209                         DONT_ENUM, Representation::Tagged());
1210       map->AppendDescriptor(&d);
1211     }
1212     {  // callee
1213       FieldDescriptor d(factory->callee_string(), Heap::kArgumentsCalleeIndex,
1214                         DONT_ENUM, Representation::Tagged());
1215       map->AppendDescriptor(&d);
1216     }
1217     // @@iterator method is added later.
1218 
1219     map->set_function_with_prototype(true);
1220     map->set_pre_allocated_property_fields(2);
1221     map->set_inobject_properties(2);
1222     native_context()->set_sloppy_arguments_map(*map);
1223 
1224     DCHECK(!function->has_initial_map());
1225     JSFunction::SetInitialMap(function, map,
1226                               isolate->initial_object_prototype());
1227 
1228     DCHECK(map->inobject_properties() > Heap::kArgumentsCalleeIndex);
1229     DCHECK(map->inobject_properties() > Heap::kArgumentsLengthIndex);
1230     DCHECK(!map->is_dictionary_map());
1231     DCHECK(IsFastObjectElementsKind(map->elements_kind()));
1232   }
1233 
1234   {  // --- aliased arguments map
1235     Handle<Map> map = Map::Copy(isolate->sloppy_arguments_map());
1236     map->set_elements_kind(SLOPPY_ARGUMENTS_ELEMENTS);
1237     DCHECK_EQ(2, map->pre_allocated_property_fields());
1238     native_context()->set_aliased_arguments_map(*map);
1239   }
1240 
1241   {  // --- strict mode arguments map
1242     const PropertyAttributes attributes =
1243       static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE | READ_ONLY);
1244 
1245     // Create the ThrowTypeError functions.
1246     Handle<AccessorPair> callee = factory->NewAccessorPair();
1247     Handle<AccessorPair> caller = factory->NewAccessorPair();
1248 
1249     Handle<JSFunction> poison = GetStrictPoisonFunction();
1250 
1251     // Install the ThrowTypeError functions.
1252     callee->set_getter(*poison);
1253     callee->set_setter(*poison);
1254     caller->set_getter(*poison);
1255     caller->set_setter(*poison);
1256 
1257     // Create the map. Allocate one in-object field for length.
1258     Handle<Map> map = factory->NewMap(JS_OBJECT_TYPE,
1259                                       Heap::kStrictArgumentsObjectSize);
1260     // Create the descriptor array for the arguments object.
1261     Map::EnsureDescriptorSlack(map, 3);
1262 
1263     {  // length
1264       FieldDescriptor d(factory->length_string(), Heap::kArgumentsLengthIndex,
1265                         DONT_ENUM, Representation::Tagged());
1266       map->AppendDescriptor(&d);
1267     }
1268     {  // callee
1269       CallbacksDescriptor d(factory->callee_string(), callee, attributes);
1270       map->AppendDescriptor(&d);
1271     }
1272     {  // caller
1273       CallbacksDescriptor d(factory->caller_string(), caller, attributes);
1274       map->AppendDescriptor(&d);
1275     }
1276     // @@iterator method is added later.
1277 
1278     map->set_function_with_prototype(true);
1279     map->set_prototype(native_context()->object_function()->prototype());
1280     map->set_pre_allocated_property_fields(1);
1281     map->set_inobject_properties(1);
1282 
1283     // Copy constructor from the sloppy arguments boilerplate.
1284     map->set_constructor(
1285         native_context()->sloppy_arguments_map()->constructor());
1286 
1287     native_context()->set_strict_arguments_map(*map);
1288 
1289     DCHECK(map->inobject_properties() > Heap::kArgumentsLengthIndex);
1290     DCHECK(!map->is_dictionary_map());
1291     DCHECK(IsFastObjectElementsKind(map->elements_kind()));
1292   }
1293 
1294   {  // --- context extension
1295     // Create a function for the context extension objects.
1296     Handle<Code> code = Handle<Code>(
1297         isolate->builtins()->builtin(Builtins::kIllegal));
1298     Handle<JSFunction> context_extension_fun = factory->NewFunction(
1299         factory->empty_string(), code, JS_CONTEXT_EXTENSION_OBJECT_TYPE,
1300         JSObject::kHeaderSize);
1301 
1302     Handle<String> name = factory->InternalizeOneByteString(
1303         STATIC_CHAR_VECTOR("context_extension"));
1304     context_extension_fun->shared()->set_instance_class_name(*name);
1305     native_context()->set_context_extension_function(*context_extension_fun);
1306   }
1307 
1308 
1309   {
1310     // Set up the call-as-function delegate.
1311     Handle<Code> code =
1312         Handle<Code>(isolate->builtins()->builtin(
1313             Builtins::kHandleApiCallAsFunction));
1314     Handle<JSFunction> delegate = factory->NewFunction(
1315         factory->empty_string(), code, JS_OBJECT_TYPE, JSObject::kHeaderSize);
1316     native_context()->set_call_as_function_delegate(*delegate);
1317     delegate->shared()->DontAdaptArguments();
1318   }
1319 
1320   {
1321     // Set up the call-as-constructor delegate.
1322     Handle<Code> code =
1323         Handle<Code>(isolate->builtins()->builtin(
1324             Builtins::kHandleApiCallAsConstructor));
1325     Handle<JSFunction> delegate = factory->NewFunction(
1326         factory->empty_string(), code, JS_OBJECT_TYPE, JSObject::kHeaderSize);
1327     native_context()->set_call_as_constructor_delegate(*delegate);
1328     delegate->shared()->DontAdaptArguments();
1329   }
1330 
1331   // Initialize the embedder data slot.
1332   Handle<FixedArray> embedder_data = factory->NewFixedArray(3);
1333   native_context()->set_embedder_data(*embedder_data);
1334 }
1335 
1336 
InstallTypedArray(const char * name,ElementsKind elements_kind,Handle<JSFunction> * fun,Handle<Map> * external_map)1337 void Genesis::InstallTypedArray(
1338     const char* name,
1339     ElementsKind elements_kind,
1340     Handle<JSFunction>* fun,
1341     Handle<Map>* external_map) {
1342   Handle<JSObject> global = Handle<JSObject>(native_context()->global_object());
1343   Handle<JSFunction> result = InstallFunction(
1344       global, name, JS_TYPED_ARRAY_TYPE, JSTypedArray::kSize,
1345       isolate()->initial_object_prototype(), Builtins::kIllegal);
1346 
1347   Handle<Map> initial_map = isolate()->factory()->NewMap(
1348       JS_TYPED_ARRAY_TYPE,
1349       JSTypedArray::kSizeWithInternalFields,
1350       elements_kind);
1351   JSFunction::SetInitialMap(result, initial_map,
1352                             handle(initial_map->prototype(), isolate()));
1353   *fun = result;
1354 
1355   ElementsKind external_kind = GetNextTransitionElementsKind(elements_kind);
1356   *external_map = Map::AsElementsKind(initial_map, external_kind);
1357 }
1358 
1359 
InitializeExperimentalGlobal()1360 void Genesis::InitializeExperimentalGlobal() {
1361   // TODO(erikcorry): Move this into Genesis::InitializeGlobal once we no
1362   // longer need to live behind a flag.
1363   Handle<JSObject> builtins(native_context()->builtins());
1364 
1365   Handle<HeapObject> flag(
1366       FLAG_harmony_regexps ? heap()->true_value() : heap()->false_value());
1367   PropertyAttributes attributes =
1368       static_cast<PropertyAttributes>(DONT_DELETE | READ_ONLY);
1369   Runtime::DefineObjectProperty(builtins, factory()->harmony_regexps_string(),
1370                                 flag, attributes).Assert();
1371 }
1372 
1373 
CompileBuiltin(Isolate * isolate,int index)1374 bool Genesis::CompileBuiltin(Isolate* isolate, int index) {
1375   Vector<const char> name = Natives::GetScriptName(index);
1376   Handle<String> source_code =
1377       isolate->bootstrapper()->NativesSourceLookup(index);
1378   return CompileNative(isolate, name, source_code);
1379 }
1380 
1381 
CompileExperimentalBuiltin(Isolate * isolate,int index)1382 bool Genesis::CompileExperimentalBuiltin(Isolate* isolate, int index) {
1383   Vector<const char> name = ExperimentalNatives::GetScriptName(index);
1384   Factory* factory = isolate->factory();
1385   Handle<String> source_code;
1386   ASSIGN_RETURN_ON_EXCEPTION_VALUE(
1387       isolate, source_code, factory->NewStringFromAscii(
1388                                 ExperimentalNatives::GetRawScriptSource(index)),
1389       false);
1390   return CompileNative(isolate, name, source_code);
1391 }
1392 
1393 
CompileNative(Isolate * isolate,Vector<const char> name,Handle<String> source)1394 bool Genesis::CompileNative(Isolate* isolate,
1395                             Vector<const char> name,
1396                             Handle<String> source) {
1397   HandleScope scope(isolate);
1398   SuppressDebug compiling_natives(isolate->debug());
1399   // During genesis, the boilerplate for stack overflow won't work until the
1400   // environment has been at least partially initialized. Add a stack check
1401   // before entering JS code to catch overflow early.
1402   StackLimitCheck check(isolate);
1403   if (check.HasOverflowed()) return false;
1404 
1405   bool result = CompileScriptCached(isolate,
1406                                     name,
1407                                     source,
1408                                     NULL,
1409                                     NULL,
1410                                     Handle<Context>(isolate->context()),
1411                                     true);
1412   DCHECK(isolate->has_pending_exception() != result);
1413   if (!result) isolate->clear_pending_exception();
1414   return result;
1415 }
1416 
1417 
CompileScriptCached(Isolate * isolate,Vector<const char> name,Handle<String> source,SourceCodeCache * cache,v8::Extension * extension,Handle<Context> top_context,bool use_runtime_context)1418 bool Genesis::CompileScriptCached(Isolate* isolate,
1419                                   Vector<const char> name,
1420                                   Handle<String> source,
1421                                   SourceCodeCache* cache,
1422                                   v8::Extension* extension,
1423                                   Handle<Context> top_context,
1424                                   bool use_runtime_context) {
1425   Factory* factory = isolate->factory();
1426   HandleScope scope(isolate);
1427   Handle<SharedFunctionInfo> function_info;
1428 
1429   // If we can't find the function in the cache, we compile a new
1430   // function and insert it into the cache.
1431   if (cache == NULL || !cache->Lookup(name, &function_info)) {
1432     DCHECK(source->IsOneByteRepresentation());
1433     Handle<String> script_name =
1434         factory->NewStringFromUtf8(name).ToHandleChecked();
1435     function_info = Compiler::CompileScript(
1436         source, script_name, 0, 0, false, top_context, extension, NULL,
1437         ScriptCompiler::kNoCompileOptions,
1438         use_runtime_context ? NATIVES_CODE : NOT_NATIVES_CODE);
1439     if (function_info.is_null()) return false;
1440     if (cache != NULL) cache->Add(name, function_info);
1441   }
1442 
1443   // Set up the function context. Conceptually, we should clone the
1444   // function before overwriting the context but since we're in a
1445   // single-threaded environment it is not strictly necessary.
1446   DCHECK(top_context->IsNativeContext());
1447   Handle<Context> context =
1448       Handle<Context>(use_runtime_context
1449                       ? Handle<Context>(top_context->runtime_context())
1450                       : top_context);
1451   Handle<JSFunction> fun =
1452       factory->NewFunctionFromSharedFunctionInfo(function_info, context);
1453 
1454   // Call function using either the runtime object or the global
1455   // object as the receiver. Provide no parameters.
1456   Handle<Object> receiver =
1457       Handle<Object>(use_runtime_context
1458                      ? top_context->builtins()
1459                      : top_context->global_object(),
1460                      isolate);
1461   return !Execution::Call(
1462       isolate, fun, receiver, 0, NULL).is_null();
1463 }
1464 
1465 
ResolveBuiltinIdHolder(Handle<Context> native_context,const char * holder_expr)1466 static Handle<JSObject> ResolveBuiltinIdHolder(Handle<Context> native_context,
1467                                                const char* holder_expr) {
1468   Isolate* isolate = native_context->GetIsolate();
1469   Factory* factory = isolate->factory();
1470   Handle<GlobalObject> global(native_context->global_object());
1471   const char* period_pos = strchr(holder_expr, '.');
1472   if (period_pos == NULL) {
1473     return Handle<JSObject>::cast(
1474         Object::GetPropertyOrElement(
1475             global, factory->InternalizeUtf8String(holder_expr))
1476             .ToHandleChecked());
1477   }
1478   const char* inner = period_pos + 1;
1479   DCHECK_EQ(NULL, strchr(inner, '.'));
1480   Vector<const char> property(holder_expr,
1481                               static_cast<int>(period_pos - holder_expr));
1482   Handle<String> property_string = factory->InternalizeUtf8String(property);
1483   DCHECK(!property_string.is_null());
1484   Handle<JSObject> object = Handle<JSObject>::cast(
1485       Object::GetProperty(global, property_string).ToHandleChecked());
1486   if (strcmp("prototype", inner) == 0) {
1487     Handle<JSFunction> function = Handle<JSFunction>::cast(object);
1488     return Handle<JSObject>(JSObject::cast(function->prototype()));
1489   }
1490   Handle<String> inner_string = factory->InternalizeUtf8String(inner);
1491   DCHECK(!inner_string.is_null());
1492   Handle<Object> value =
1493       Object::GetProperty(object, inner_string).ToHandleChecked();
1494   return Handle<JSObject>::cast(value);
1495 }
1496 
1497 
1498 #define INSTALL_NATIVE(Type, name, var)                                     \
1499   Handle<String> var##_name =                                               \
1500       factory()->InternalizeOneByteString(STATIC_CHAR_VECTOR(name));        \
1501   Handle<Object> var##_native =                                             \
1502       Object::GetProperty(handle(native_context()->builtins()), var##_name) \
1503           .ToHandleChecked();                                               \
1504   native_context()->set_##var(Type::cast(*var##_native));
1505 
1506 #define INSTALL_NATIVE_MATH(name)                                    \
1507   {                                                                  \
1508     Handle<Object> fun =                                             \
1509         ResolveBuiltinIdHolder(native_context(), "Math." #name);     \
1510     native_context()->set_math_##name##_fun(JSFunction::cast(*fun)); \
1511   }
1512 
InstallNativeFunctions()1513 void Genesis::InstallNativeFunctions() {
1514   HandleScope scope(isolate());
1515   INSTALL_NATIVE(JSFunction, "CreateDate", create_date_fun);
1516 
1517   INSTALL_NATIVE(JSFunction, "ToNumber", to_number_fun);
1518   INSTALL_NATIVE(JSFunction, "ToString", to_string_fun);
1519   INSTALL_NATIVE(JSFunction, "ToDetailString", to_detail_string_fun);
1520   INSTALL_NATIVE(JSFunction, "ToObject", to_object_fun);
1521   INSTALL_NATIVE(JSFunction, "ToInteger", to_integer_fun);
1522   INSTALL_NATIVE(JSFunction, "ToUint32", to_uint32_fun);
1523   INSTALL_NATIVE(JSFunction, "ToInt32", to_int32_fun);
1524 
1525   INSTALL_NATIVE(JSFunction, "GlobalEval", global_eval_fun);
1526   INSTALL_NATIVE(JSFunction, "Instantiate", instantiate_fun);
1527   INSTALL_NATIVE(JSFunction, "ConfigureTemplateInstance",
1528                  configure_instance_fun);
1529   INSTALL_NATIVE(JSFunction, "GetStackTraceLine", get_stack_trace_line_fun);
1530   INSTALL_NATIVE(JSObject, "functionCache", function_cache);
1531   INSTALL_NATIVE(JSFunction, "ToCompletePropertyDescriptor",
1532                  to_complete_property_descriptor);
1533 
1534   INSTALL_NATIVE(JSFunction, "IsPromise", is_promise);
1535   INSTALL_NATIVE(JSFunction, "PromiseCreate", promise_create);
1536   INSTALL_NATIVE(JSFunction, "PromiseResolve", promise_resolve);
1537   INSTALL_NATIVE(JSFunction, "PromiseReject", promise_reject);
1538   INSTALL_NATIVE(JSFunction, "PromiseChain", promise_chain);
1539   INSTALL_NATIVE(JSFunction, "PromiseCatch", promise_catch);
1540   INSTALL_NATIVE(JSFunction, "PromiseThen", promise_then);
1541 
1542   INSTALL_NATIVE(JSFunction, "NotifyChange", observers_notify_change);
1543   INSTALL_NATIVE(JSFunction, "EnqueueSpliceRecord", observers_enqueue_splice);
1544   INSTALL_NATIVE(JSFunction, "BeginPerformSplice",
1545                  observers_begin_perform_splice);
1546   INSTALL_NATIVE(JSFunction, "EndPerformSplice",
1547                  observers_end_perform_splice);
1548   INSTALL_NATIVE(JSFunction, "NativeObjectObserve",
1549                  native_object_observe);
1550   INSTALL_NATIVE(JSFunction, "NativeObjectGetNotifier",
1551                  native_object_get_notifier);
1552   INSTALL_NATIVE(JSFunction, "NativeObjectNotifierPerformChange",
1553                  native_object_notifier_perform_change);
1554 
1555   INSTALL_NATIVE(Symbol, "symbolIterator", iterator_symbol);
1556   INSTALL_NATIVE(Symbol, "symbolUnscopables", unscopables_symbol);
1557   INSTALL_NATIVE(JSFunction, "ArrayValues", array_values_iterator);
1558 
1559   INSTALL_NATIVE_MATH(abs)
1560   INSTALL_NATIVE_MATH(acos)
1561   INSTALL_NATIVE_MATH(asin)
1562   INSTALL_NATIVE_MATH(atan)
1563   INSTALL_NATIVE_MATH(atan2)
1564   INSTALL_NATIVE_MATH(ceil)
1565   INSTALL_NATIVE_MATH(cos)
1566   INSTALL_NATIVE_MATH(exp)
1567   INSTALL_NATIVE_MATH(floor)
1568   INSTALL_NATIVE_MATH(imul)
1569   INSTALL_NATIVE_MATH(log)
1570   INSTALL_NATIVE_MATH(max)
1571   INSTALL_NATIVE_MATH(min)
1572   INSTALL_NATIVE_MATH(pow)
1573   INSTALL_NATIVE_MATH(random)
1574   INSTALL_NATIVE_MATH(round)
1575   INSTALL_NATIVE_MATH(sin)
1576   INSTALL_NATIVE_MATH(sqrt)
1577   INSTALL_NATIVE_MATH(tan)
1578 }
1579 
1580 
InstallExperimentalNativeFunctions()1581 void Genesis::InstallExperimentalNativeFunctions() {
1582   if (FLAG_harmony_proxies) {
1583     INSTALL_NATIVE(JSFunction, "DerivedHasTrap", derived_has_trap);
1584     INSTALL_NATIVE(JSFunction, "DerivedGetTrap", derived_get_trap);
1585     INSTALL_NATIVE(JSFunction, "DerivedSetTrap", derived_set_trap);
1586     INSTALL_NATIVE(JSFunction, "ProxyEnumerate", proxy_enumerate);
1587   }
1588 }
1589 
1590 #undef INSTALL_NATIVE
1591 
1592 
InstallInternalArray(Handle<JSBuiltinsObject> builtins,const char * name,ElementsKind elements_kind)1593 Handle<JSFunction> Genesis::InstallInternalArray(
1594     Handle<JSBuiltinsObject> builtins,
1595     const char* name,
1596     ElementsKind elements_kind) {
1597   // --- I n t e r n a l   A r r a y ---
1598   // An array constructor on the builtins object that works like
1599   // the public Array constructor, except that its prototype
1600   // doesn't inherit from Object.prototype.
1601   // To be used only for internal work by builtins. Instances
1602   // must not be leaked to user code.
1603   Handle<JSObject> prototype =
1604       factory()->NewJSObject(isolate()->object_function(), TENURED);
1605   Handle<JSFunction> array_function = InstallFunction(
1606       builtins, name, JS_ARRAY_TYPE, JSArray::kSize,
1607       prototype, Builtins::kInternalArrayCode);
1608 
1609   InternalArrayConstructorStub internal_array_constructor_stub(isolate());
1610   Handle<Code> code = internal_array_constructor_stub.GetCode();
1611   array_function->shared()->set_construct_stub(*code);
1612   array_function->shared()->DontAdaptArguments();
1613 
1614   Handle<Map> original_map(array_function->initial_map());
1615   Handle<Map> initial_map = Map::Copy(original_map);
1616   initial_map->set_elements_kind(elements_kind);
1617   JSFunction::SetInitialMap(array_function, initial_map, prototype);
1618 
1619   // Make "length" magic on instances.
1620   Map::EnsureDescriptorSlack(initial_map, 1);
1621 
1622   PropertyAttributes attribs = static_cast<PropertyAttributes>(
1623       DONT_ENUM | DONT_DELETE);
1624 
1625   Handle<AccessorInfo> array_length =
1626       Accessors::ArrayLengthInfo(isolate(), attribs);
1627   {  // Add length.
1628     CallbacksDescriptor d(
1629         Handle<Name>(Name::cast(array_length->name())), array_length, attribs);
1630     array_function->initial_map()->AppendDescriptor(&d);
1631   }
1632 
1633   return array_function;
1634 }
1635 
1636 
InstallNatives()1637 bool Genesis::InstallNatives() {
1638   HandleScope scope(isolate());
1639 
1640   // Create a function for the builtins object. Allocate space for the
1641   // JavaScript builtins, a reference to the builtins object
1642   // (itself) and a reference to the native_context directly in the object.
1643   Handle<Code> code = Handle<Code>(
1644       isolate()->builtins()->builtin(Builtins::kIllegal));
1645   Handle<JSFunction> builtins_fun = factory()->NewFunction(
1646       factory()->empty_string(), code, JS_BUILTINS_OBJECT_TYPE,
1647       JSBuiltinsObject::kSize);
1648 
1649   Handle<String> name =
1650       factory()->InternalizeOneByteString(STATIC_CHAR_VECTOR("builtins"));
1651   builtins_fun->shared()->set_instance_class_name(*name);
1652   builtins_fun->initial_map()->set_dictionary_map(true);
1653   builtins_fun->initial_map()->set_prototype(heap()->null_value());
1654 
1655   // Allocate the builtins object.
1656   Handle<JSBuiltinsObject> builtins =
1657       Handle<JSBuiltinsObject>::cast(factory()->NewGlobalObject(builtins_fun));
1658   builtins->set_builtins(*builtins);
1659   builtins->set_native_context(*native_context());
1660   builtins->set_global_context(*native_context());
1661   builtins->set_global_proxy(native_context()->global_proxy());
1662 
1663 
1664   // Set up the 'global' properties of the builtins object. The
1665   // 'global' property that refers to the global object is the only
1666   // way to get from code running in the builtins context to the
1667   // global object.
1668   static const PropertyAttributes attributes =
1669       static_cast<PropertyAttributes>(READ_ONLY | DONT_DELETE);
1670   Handle<String> global_string =
1671       factory()->InternalizeOneByteString(STATIC_CHAR_VECTOR("global"));
1672   Handle<Object> global_obj(native_context()->global_object(), isolate());
1673   JSObject::AddProperty(builtins, global_string, global_obj, attributes);
1674   Handle<String> builtins_string =
1675       factory()->InternalizeOneByteString(STATIC_CHAR_VECTOR("builtins"));
1676   JSObject::AddProperty(builtins, builtins_string, builtins, attributes);
1677 
1678   // Set up the reference from the global object to the builtins object.
1679   JSGlobalObject::cast(native_context()->global_object())->
1680       set_builtins(*builtins);
1681 
1682   // Create a bridge function that has context in the native context.
1683   Handle<JSFunction> bridge = factory()->NewFunction(factory()->empty_string());
1684   DCHECK(bridge->context() == *isolate()->native_context());
1685 
1686   // Allocate the builtins context.
1687   Handle<Context> context =
1688     factory()->NewFunctionContext(Context::MIN_CONTEXT_SLOTS, bridge);
1689   context->set_global_object(*builtins);  // override builtins global object
1690 
1691   native_context()->set_runtime_context(*context);
1692 
1693   {  // -- S c r i p t
1694     // Builtin functions for Script.
1695     Handle<JSFunction> script_fun = InstallFunction(
1696         builtins, "Script", JS_VALUE_TYPE, JSValue::kSize,
1697         isolate()->initial_object_prototype(), Builtins::kIllegal);
1698     Handle<JSObject> prototype =
1699         factory()->NewJSObject(isolate()->object_function(), TENURED);
1700     Accessors::FunctionSetPrototype(script_fun, prototype);
1701     native_context()->set_script_function(*script_fun);
1702 
1703     Handle<Map> script_map = Handle<Map>(script_fun->initial_map());
1704     Map::EnsureDescriptorSlack(script_map, 14);
1705 
1706     PropertyAttributes attribs =
1707         static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE | READ_ONLY);
1708 
1709     Handle<AccessorInfo> script_column =
1710         Accessors::ScriptColumnOffsetInfo(isolate(), attribs);
1711     {
1712       CallbacksDescriptor d(Handle<Name>(Name::cast(script_column->name())),
1713                            script_column, attribs);
1714       script_map->AppendDescriptor(&d);
1715     }
1716 
1717     Handle<AccessorInfo> script_id =
1718         Accessors::ScriptIdInfo(isolate(), attribs);
1719     {
1720       CallbacksDescriptor d(Handle<Name>(Name::cast(script_id->name())),
1721                             script_id, attribs);
1722       script_map->AppendDescriptor(&d);
1723     }
1724 
1725 
1726     Handle<AccessorInfo> script_name =
1727         Accessors::ScriptNameInfo(isolate(), attribs);
1728     {
1729       CallbacksDescriptor d(Handle<Name>(Name::cast(script_name->name())),
1730                             script_name, attribs);
1731       script_map->AppendDescriptor(&d);
1732     }
1733 
1734     Handle<AccessorInfo> script_line =
1735         Accessors::ScriptLineOffsetInfo(isolate(), attribs);
1736     {
1737       CallbacksDescriptor d(Handle<Name>(Name::cast(script_line->name())),
1738                            script_line, attribs);
1739       script_map->AppendDescriptor(&d);
1740     }
1741 
1742     Handle<AccessorInfo> script_source =
1743         Accessors::ScriptSourceInfo(isolate(), attribs);
1744     {
1745       CallbacksDescriptor d(Handle<Name>(Name::cast(script_source->name())),
1746                             script_source, attribs);
1747       script_map->AppendDescriptor(&d);
1748     }
1749 
1750     Handle<AccessorInfo> script_type =
1751         Accessors::ScriptTypeInfo(isolate(), attribs);
1752     {
1753       CallbacksDescriptor d(Handle<Name>(Name::cast(script_type->name())),
1754                             script_type, attribs);
1755       script_map->AppendDescriptor(&d);
1756     }
1757 
1758     Handle<AccessorInfo> script_compilation_type =
1759         Accessors::ScriptCompilationTypeInfo(isolate(), attribs);
1760     {
1761       CallbacksDescriptor d(
1762           Handle<Name>(Name::cast(script_compilation_type->name())),
1763           script_compilation_type, attribs);
1764       script_map->AppendDescriptor(&d);
1765     }
1766 
1767     Handle<AccessorInfo> script_line_ends =
1768         Accessors::ScriptLineEndsInfo(isolate(), attribs);
1769     {
1770       CallbacksDescriptor d(Handle<Name>(Name::cast(script_line_ends->name())),
1771                             script_line_ends, attribs);
1772       script_map->AppendDescriptor(&d);
1773     }
1774 
1775     Handle<AccessorInfo> script_context_data =
1776         Accessors::ScriptContextDataInfo(isolate(), attribs);
1777     {
1778       CallbacksDescriptor d(
1779           Handle<Name>(Name::cast(script_context_data->name())),
1780           script_context_data, attribs);
1781       script_map->AppendDescriptor(&d);
1782     }
1783 
1784     Handle<AccessorInfo> script_eval_from_script =
1785         Accessors::ScriptEvalFromScriptInfo(isolate(), attribs);
1786     {
1787       CallbacksDescriptor d(
1788           Handle<Name>(Name::cast(script_eval_from_script->name())),
1789           script_eval_from_script, attribs);
1790       script_map->AppendDescriptor(&d);
1791     }
1792 
1793     Handle<AccessorInfo> script_eval_from_script_position =
1794         Accessors::ScriptEvalFromScriptPositionInfo(isolate(), attribs);
1795     {
1796       CallbacksDescriptor d(
1797           Handle<Name>(Name::cast(script_eval_from_script_position->name())),
1798           script_eval_from_script_position, attribs);
1799       script_map->AppendDescriptor(&d);
1800     }
1801 
1802     Handle<AccessorInfo> script_eval_from_function_name =
1803         Accessors::ScriptEvalFromFunctionNameInfo(isolate(), attribs);
1804     {
1805       CallbacksDescriptor d(
1806           Handle<Name>(Name::cast(script_eval_from_function_name->name())),
1807           script_eval_from_function_name, attribs);
1808       script_map->AppendDescriptor(&d);
1809     }
1810 
1811     Handle<AccessorInfo> script_source_url =
1812         Accessors::ScriptSourceUrlInfo(isolate(), attribs);
1813     {
1814       CallbacksDescriptor d(Handle<Name>(Name::cast(script_source_url->name())),
1815                             script_source_url, attribs);
1816       script_map->AppendDescriptor(&d);
1817     }
1818 
1819     Handle<AccessorInfo> script_source_mapping_url =
1820         Accessors::ScriptSourceMappingUrlInfo(isolate(), attribs);
1821     {
1822       CallbacksDescriptor d(
1823           Handle<Name>(Name::cast(script_source_mapping_url->name())),
1824           script_source_mapping_url, attribs);
1825       script_map->AppendDescriptor(&d);
1826     }
1827 
1828     // Allocate the empty script.
1829     Handle<Script> script = factory()->NewScript(factory()->empty_string());
1830     script->set_type(Smi::FromInt(Script::TYPE_NATIVE));
1831     heap()->public_set_empty_script(*script);
1832   }
1833   {
1834     // Builtin function for OpaqueReference -- a JSValue-based object,
1835     // that keeps its field isolated from JavaScript code. It may store
1836     // objects, that JavaScript code may not access.
1837     Handle<JSFunction> opaque_reference_fun = InstallFunction(
1838         builtins, "OpaqueReference", JS_VALUE_TYPE, JSValue::kSize,
1839         isolate()->initial_object_prototype(), Builtins::kIllegal);
1840     Handle<JSObject> prototype =
1841         factory()->NewJSObject(isolate()->object_function(), TENURED);
1842     Accessors::FunctionSetPrototype(opaque_reference_fun, prototype);
1843     native_context()->set_opaque_reference_function(*opaque_reference_fun);
1844   }
1845 
1846   // InternalArrays should not use Smi-Only array optimizations. There are too
1847   // many places in the C++ runtime code (e.g. RegEx) that assume that
1848   // elements in InternalArrays can be set to non-Smi values without going
1849   // through a common bottleneck that would make the SMI_ONLY -> FAST_ELEMENT
1850   // transition easy to trap. Moreover, they rarely are smi-only.
1851   {
1852     Handle<JSFunction> array_function =
1853         InstallInternalArray(builtins, "InternalArray", FAST_HOLEY_ELEMENTS);
1854     native_context()->set_internal_array_function(*array_function);
1855   }
1856 
1857   {
1858     InstallInternalArray(builtins, "InternalPackedArray", FAST_ELEMENTS);
1859   }
1860 
1861   {  // -- S e t I t e r a t o r
1862     Handle<JSFunction> set_iterator_function = InstallFunction(
1863         builtins, "SetIterator", JS_SET_ITERATOR_TYPE, JSSetIterator::kSize,
1864         isolate()->initial_object_prototype(), Builtins::kIllegal);
1865     native_context()->set_set_iterator_map(
1866         set_iterator_function->initial_map());
1867   }
1868 
1869   {  // -- M a p I t e r a t o r
1870     Handle<JSFunction> map_iterator_function = InstallFunction(
1871         builtins, "MapIterator", JS_MAP_ITERATOR_TYPE, JSMapIterator::kSize,
1872         isolate()->initial_object_prototype(), Builtins::kIllegal);
1873     native_context()->set_map_iterator_map(
1874         map_iterator_function->initial_map());
1875   }
1876 
1877   {
1878     // Create generator meta-objects and install them on the builtins object.
1879     Handle<JSObject> builtins(native_context()->builtins());
1880     Handle<JSObject> generator_object_prototype =
1881         factory()->NewJSObject(isolate()->object_function(), TENURED);
1882     Handle<JSFunction> generator_function_prototype =
1883         InstallFunction(builtins, "GeneratorFunctionPrototype",
1884                         JS_FUNCTION_TYPE, JSFunction::kHeaderSize,
1885                         generator_object_prototype, Builtins::kIllegal);
1886     InstallFunction(builtins, "GeneratorFunction", JS_FUNCTION_TYPE,
1887                     JSFunction::kSize, generator_function_prototype,
1888                     Builtins::kIllegal);
1889 
1890     // Create maps for generator functions and their prototypes.  Store those
1891     // maps in the native context.
1892     Handle<Map> generator_function_map =
1893         Map::Copy(sloppy_function_map_writable_prototype_);
1894     generator_function_map->set_prototype(*generator_function_prototype);
1895     native_context()->set_sloppy_generator_function_map(
1896         *generator_function_map);
1897 
1898     // The "arguments" and "caller" instance properties aren't specified, so
1899     // technically we could leave them out.  They make even less sense for
1900     // generators than for functions.  Still, the same argument that it makes
1901     // sense to keep them around but poisoned in strict mode applies to
1902     // generators as well.  With poisoned accessors, naive callers can still
1903     // iterate over the properties without accessing them.
1904     //
1905     // We can't use PoisonArgumentsAndCaller because that mutates accessor pairs
1906     // in place, and the initial state of the generator function map shares the
1907     // accessor pair with sloppy functions.  Also the error message should be
1908     // different.  Also unhappily, we can't use the API accessors to implement
1909     // poisoning, because API accessors present themselves as data properties,
1910     // not accessor properties, and so getOwnPropertyDescriptor raises an
1911     // exception as it tries to get the values.  Sadness.
1912     Handle<AccessorPair> poison_pair(factory()->NewAccessorPair());
1913     PropertyAttributes rw_attribs =
1914         static_cast<PropertyAttributes>(DONT_ENUM | DONT_DELETE);
1915     Handle<JSFunction> poison_function = GetGeneratorPoisonFunction();
1916     poison_pair->set_getter(*poison_function);
1917     poison_pair->set_setter(*poison_function);
1918     ReplaceAccessors(generator_function_map, factory()->arguments_string(),
1919                      rw_attribs, poison_pair);
1920     ReplaceAccessors(generator_function_map, factory()->caller_string(),
1921                      rw_attribs, poison_pair);
1922 
1923     Handle<Map> strict_function_map(native_context()->strict_function_map());
1924     Handle<Map> strict_generator_function_map = Map::Copy(strict_function_map);
1925     // "arguments" and "caller" already poisoned.
1926     strict_generator_function_map->set_prototype(*generator_function_prototype);
1927     native_context()->set_strict_generator_function_map(
1928         *strict_generator_function_map);
1929 
1930     Handle<JSFunction> object_function(native_context()->object_function());
1931     Handle<Map> generator_object_prototype_map = Map::Create(isolate(), 0);
1932     generator_object_prototype_map->set_prototype(*generator_object_prototype);
1933     native_context()->set_generator_object_prototype_map(
1934         *generator_object_prototype_map);
1935   }
1936 
1937   if (FLAG_disable_native_files) {
1938     PrintF("Warning: Running without installed natives!\n");
1939     return true;
1940   }
1941 
1942   // Install natives.
1943   for (int i = Natives::GetDebuggerCount();
1944        i < Natives::GetBuiltinsCount();
1945        i++) {
1946     if (!CompileBuiltin(isolate(), i)) return false;
1947     // TODO(ager): We really only need to install the JS builtin
1948     // functions on the builtins object after compiling and running
1949     // runtime.js.
1950     if (!InstallJSBuiltins(builtins)) return false;
1951   }
1952 
1953   InstallNativeFunctions();
1954 
1955   // Store the map for the string prototype after the natives has been compiled
1956   // and the String function has been set up.
1957   Handle<JSFunction> string_function(native_context()->string_function());
1958   DCHECK(JSObject::cast(
1959       string_function->initial_map()->prototype())->HasFastProperties());
1960   native_context()->set_string_function_prototype_map(
1961       HeapObject::cast(string_function->initial_map()->prototype())->map());
1962 
1963   // Install Function.prototype.call and apply.
1964   {
1965     Handle<String> key = factory()->Function_string();
1966     Handle<JSFunction> function =
1967         Handle<JSFunction>::cast(Object::GetProperty(
1968             handle(native_context()->global_object()), key).ToHandleChecked());
1969     Handle<JSObject> proto =
1970         Handle<JSObject>(JSObject::cast(function->instance_prototype()));
1971 
1972     // Install the call and the apply functions.
1973     Handle<JSFunction> call =
1974         InstallFunction(proto, "call", JS_OBJECT_TYPE, JSObject::kHeaderSize,
1975                         MaybeHandle<JSObject>(), Builtins::kFunctionCall);
1976     Handle<JSFunction> apply =
1977         InstallFunction(proto, "apply", JS_OBJECT_TYPE, JSObject::kHeaderSize,
1978                         MaybeHandle<JSObject>(), Builtins::kFunctionApply);
1979     if (FLAG_vector_ics) {
1980       // Apply embeds an IC, so we need a type vector of size 1 in the shared
1981       // function info.
1982       Handle<TypeFeedbackVector> feedback_vector =
1983           factory()->NewTypeFeedbackVector(1);
1984       apply->shared()->set_feedback_vector(*feedback_vector);
1985     }
1986 
1987     // Make sure that Function.prototype.call appears to be compiled.
1988     // The code will never be called, but inline caching for call will
1989     // only work if it appears to be compiled.
1990     call->shared()->DontAdaptArguments();
1991     DCHECK(call->is_compiled());
1992 
1993     // Set the expected parameters for apply to 2; required by builtin.
1994     apply->shared()->set_formal_parameter_count(2);
1995 
1996     // Set the lengths for the functions to satisfy ECMA-262.
1997     call->shared()->set_length(1);
1998     apply->shared()->set_length(2);
1999   }
2000 
2001   InstallBuiltinFunctionIds();
2002 
2003   // Create a constructor for RegExp results (a variant of Array that
2004   // predefines the two properties index and match).
2005   {
2006     // RegExpResult initial map.
2007 
2008     // Find global.Array.prototype to inherit from.
2009     Handle<JSFunction> array_constructor(native_context()->array_function());
2010     Handle<JSObject> array_prototype(
2011         JSObject::cast(array_constructor->instance_prototype()));
2012 
2013     // Add initial map.
2014     Handle<Map> initial_map =
2015         factory()->NewMap(JS_ARRAY_TYPE, JSRegExpResult::kSize);
2016     initial_map->set_constructor(*array_constructor);
2017 
2018     // Set prototype on map.
2019     initial_map->set_non_instance_prototype(false);
2020     initial_map->set_prototype(*array_prototype);
2021 
2022     // Update map with length accessor from Array and add "index" and "input".
2023     Map::EnsureDescriptorSlack(initial_map, 3);
2024 
2025     {
2026       JSFunction* array_function = native_context()->array_function();
2027       Handle<DescriptorArray> array_descriptors(
2028           array_function->initial_map()->instance_descriptors());
2029       Handle<String> length = factory()->length_string();
2030       int old = array_descriptors->SearchWithCache(
2031           *length, array_function->initial_map());
2032       DCHECK(old != DescriptorArray::kNotFound);
2033       CallbacksDescriptor desc(length,
2034                                handle(array_descriptors->GetValue(old),
2035                                       isolate()),
2036                                array_descriptors->GetDetails(old).attributes());
2037       initial_map->AppendDescriptor(&desc);
2038     }
2039     {
2040       FieldDescriptor index_field(factory()->index_string(),
2041                                   JSRegExpResult::kIndexIndex,
2042                                   NONE,
2043                                   Representation::Tagged());
2044       initial_map->AppendDescriptor(&index_field);
2045     }
2046 
2047     {
2048       FieldDescriptor input_field(factory()->input_string(),
2049                                   JSRegExpResult::kInputIndex,
2050                                   NONE,
2051                                   Representation::Tagged());
2052       initial_map->AppendDescriptor(&input_field);
2053     }
2054 
2055     initial_map->set_inobject_properties(2);
2056     initial_map->set_pre_allocated_property_fields(2);
2057     initial_map->set_unused_property_fields(0);
2058 
2059     native_context()->set_regexp_result_map(*initial_map);
2060   }
2061 
2062   // Add @@iterator method to the arguments object maps.
2063   {
2064     PropertyAttributes attribs = DONT_ENUM;
2065     Handle<AccessorInfo> arguments_iterator =
2066         Accessors::ArgumentsIteratorInfo(isolate(), attribs);
2067     {
2068       CallbacksDescriptor d(Handle<Name>(native_context()->iterator_symbol()),
2069                             arguments_iterator, attribs);
2070       Handle<Map> map(native_context()->sloppy_arguments_map());
2071       Map::EnsureDescriptorSlack(map, 1);
2072       map->AppendDescriptor(&d);
2073     }
2074     {
2075       CallbacksDescriptor d(Handle<Name>(native_context()->iterator_symbol()),
2076                             arguments_iterator, attribs);
2077       Handle<Map> map(native_context()->aliased_arguments_map());
2078       Map::EnsureDescriptorSlack(map, 1);
2079       map->AppendDescriptor(&d);
2080     }
2081     {
2082       CallbacksDescriptor d(Handle<Name>(native_context()->iterator_symbol()),
2083                             arguments_iterator, attribs);
2084       Handle<Map> map(native_context()->strict_arguments_map());
2085       Map::EnsureDescriptorSlack(map, 1);
2086       map->AppendDescriptor(&d);
2087     }
2088   }
2089 
2090 #ifdef VERIFY_HEAP
2091   builtins->ObjectVerify();
2092 #endif
2093 
2094   return true;
2095 }
2096 
2097 
2098 #define INSTALL_EXPERIMENTAL_NATIVE(i, flag, file)                \
2099   if (FLAG_harmony_##flag &&                                      \
2100       strcmp(ExperimentalNatives::GetScriptName(i).start(),       \
2101           "native " file) == 0) {                                 \
2102     if (!CompileExperimentalBuiltin(isolate(), i)) return false;  \
2103   }
2104 
2105 
InstallExperimentalNatives()2106 bool Genesis::InstallExperimentalNatives() {
2107   for (int i = ExperimentalNatives::GetDebuggerCount();
2108        i < ExperimentalNatives::GetBuiltinsCount();
2109        i++) {
2110     INSTALL_EXPERIMENTAL_NATIVE(i, proxies, "proxy.js")
2111     INSTALL_EXPERIMENTAL_NATIVE(i, strings, "harmony-string.js")
2112     INSTALL_EXPERIMENTAL_NATIVE(i, arrays, "harmony-array.js")
2113     INSTALL_EXPERIMENTAL_NATIVE(i, classes, "harmony-classes.js")
2114   }
2115 
2116   InstallExperimentalNativeFunctions();
2117   return true;
2118 }
2119 
2120 
InstallBuiltinFunctionId(Handle<JSObject> holder,const char * function_name,BuiltinFunctionId id)2121 static void InstallBuiltinFunctionId(Handle<JSObject> holder,
2122                                      const char* function_name,
2123                                      BuiltinFunctionId id) {
2124   Isolate* isolate = holder->GetIsolate();
2125   Handle<Object> function_object =
2126       Object::GetProperty(isolate, holder, function_name).ToHandleChecked();
2127   Handle<JSFunction> function = Handle<JSFunction>::cast(function_object);
2128   function->shared()->set_function_data(Smi::FromInt(id));
2129 }
2130 
2131 
InstallBuiltinFunctionIds()2132 void Genesis::InstallBuiltinFunctionIds() {
2133   HandleScope scope(isolate());
2134 #define INSTALL_BUILTIN_ID(holder_expr, fun_name, name) \
2135   {                                                     \
2136     Handle<JSObject> holder = ResolveBuiltinIdHolder(   \
2137         native_context(), #holder_expr);                \
2138     BuiltinFunctionId id = k##name;                     \
2139     InstallBuiltinFunctionId(holder, #fun_name, id);    \
2140   }
2141   FUNCTIONS_WITH_ID_LIST(INSTALL_BUILTIN_ID)
2142 #undef INSTALL_BUILTIN_ID
2143 }
2144 
2145 
2146 // Do not forget to update macros.py with named constant
2147 // of cache id.
2148 #define JSFUNCTION_RESULT_CACHE_LIST(F) \
2149   F(16, native_context()->regexp_function())
2150 
2151 
CreateCache(int size,Handle<JSFunction> factory_function)2152 static FixedArray* CreateCache(int size, Handle<JSFunction> factory_function) {
2153   Factory* factory = factory_function->GetIsolate()->factory();
2154   // Caches are supposed to live for a long time, allocate in old space.
2155   int array_size = JSFunctionResultCache::kEntriesIndex + 2 * size;
2156   // Cannot use cast as object is not fully initialized yet.
2157   JSFunctionResultCache* cache = reinterpret_cast<JSFunctionResultCache*>(
2158       *factory->NewFixedArrayWithHoles(array_size, TENURED));
2159   cache->set(JSFunctionResultCache::kFactoryIndex, *factory_function);
2160   cache->MakeZeroSize();
2161   return cache;
2162 }
2163 
2164 
InstallJSFunctionResultCaches()2165 void Genesis::InstallJSFunctionResultCaches() {
2166   const int kNumberOfCaches = 0 +
2167 #define F(size, func) + 1
2168     JSFUNCTION_RESULT_CACHE_LIST(F)
2169 #undef F
2170   ;
2171 
2172   Handle<FixedArray> caches =
2173       factory()->NewFixedArray(kNumberOfCaches, TENURED);
2174 
2175   int index = 0;
2176 
2177 #define F(size, func) do {                                              \
2178     FixedArray* cache = CreateCache((size), Handle<JSFunction>(func));  \
2179     caches->set(index++, cache);                                        \
2180   } while (false)
2181 
2182   JSFUNCTION_RESULT_CACHE_LIST(F);
2183 
2184 #undef F
2185 
2186   native_context()->set_jsfunction_result_caches(*caches);
2187 }
2188 
2189 
InitializeNormalizedMapCaches()2190 void Genesis::InitializeNormalizedMapCaches() {
2191   Handle<NormalizedMapCache> cache = NormalizedMapCache::New(isolate());
2192   native_context()->set_normalized_map_cache(*cache);
2193 }
2194 
2195 
InstallExtensions(Handle<Context> native_context,v8::ExtensionConfiguration * extensions)2196 bool Bootstrapper::InstallExtensions(Handle<Context> native_context,
2197                                      v8::ExtensionConfiguration* extensions) {
2198   BootstrapperActive active(this);
2199   SaveContext saved_context(isolate_);
2200   isolate_->set_context(*native_context);
2201   return Genesis::InstallExtensions(native_context, extensions) &&
2202       Genesis::InstallSpecialObjects(native_context);
2203 }
2204 
2205 
InstallSpecialObjects(Handle<Context> native_context)2206 bool Genesis::InstallSpecialObjects(Handle<Context> native_context) {
2207   Isolate* isolate = native_context->GetIsolate();
2208   // Don't install extensions into the snapshot.
2209   if (isolate->serializer_enabled()) return true;
2210 
2211   Factory* factory = isolate->factory();
2212   HandleScope scope(isolate);
2213   Handle<JSGlobalObject> global(JSGlobalObject::cast(
2214       native_context->global_object()));
2215 
2216   Handle<JSObject> Error = Handle<JSObject>::cast(
2217       Object::GetProperty(isolate, global, "Error").ToHandleChecked());
2218   Handle<String> name =
2219       factory->InternalizeOneByteString(STATIC_CHAR_VECTOR("stackTraceLimit"));
2220   Handle<Smi> stack_trace_limit(Smi::FromInt(FLAG_stack_trace_limit), isolate);
2221   JSObject::AddProperty(Error, name, stack_trace_limit, NONE);
2222 
2223   // Expose the natives in global if a name for it is specified.
2224   if (FLAG_expose_natives_as != NULL && strlen(FLAG_expose_natives_as) != 0) {
2225     Handle<String> natives =
2226         factory->InternalizeUtf8String(FLAG_expose_natives_as);
2227     uint32_t dummy_index;
2228     if (natives->AsArrayIndex(&dummy_index)) return true;
2229     JSObject::AddProperty(global, natives, handle(global->builtins()),
2230                           DONT_ENUM);
2231   }
2232 
2233   // Expose the stack trace symbol to native JS.
2234   RETURN_ON_EXCEPTION_VALUE(isolate,
2235                             JSObject::SetOwnPropertyIgnoreAttributes(
2236                                 handle(native_context->builtins(), isolate),
2237                                 factory->InternalizeOneByteString(
2238                                     STATIC_CHAR_VECTOR("stack_trace_symbol")),
2239                                 factory->stack_trace_symbol(), NONE),
2240                             false);
2241 
2242   // Expose the debug global object in global if a name for it is specified.
2243   if (FLAG_expose_debug_as != NULL && strlen(FLAG_expose_debug_as) != 0) {
2244     // If loading fails we just bail out without installing the
2245     // debugger but without tanking the whole context.
2246     Debug* debug = isolate->debug();
2247     if (!debug->Load()) return true;
2248     Handle<Context> debug_context = debug->debug_context();
2249     // Set the security token for the debugger context to the same as
2250     // the shell native context to allow calling between these (otherwise
2251     // exposing debug global object doesn't make much sense).
2252     debug_context->set_security_token(native_context->security_token());
2253     Handle<String> debug_string =
2254         factory->InternalizeUtf8String(FLAG_expose_debug_as);
2255     uint32_t index;
2256     if (debug_string->AsArrayIndex(&index)) return true;
2257     Handle<Object> global_proxy(debug_context->global_proxy(), isolate);
2258     JSObject::AddProperty(global, debug_string, global_proxy, DONT_ENUM);
2259   }
2260   return true;
2261 }
2262 
2263 
Hash(RegisteredExtension * extension)2264 static uint32_t Hash(RegisteredExtension* extension) {
2265   return v8::internal::ComputePointerHash(extension);
2266 }
2267 
2268 
ExtensionStates()2269 Genesis::ExtensionStates::ExtensionStates() : map_(HashMap::PointersMatch, 8) {}
2270 
get_state(RegisteredExtension * extension)2271 Genesis::ExtensionTraversalState Genesis::ExtensionStates::get_state(
2272     RegisteredExtension* extension) {
2273   i::HashMap::Entry* entry = map_.Lookup(extension, Hash(extension), false);
2274   if (entry == NULL) {
2275     return UNVISITED;
2276   }
2277   return static_cast<ExtensionTraversalState>(
2278       reinterpret_cast<intptr_t>(entry->value));
2279 }
2280 
set_state(RegisteredExtension * extension,ExtensionTraversalState state)2281 void Genesis::ExtensionStates::set_state(RegisteredExtension* extension,
2282                                          ExtensionTraversalState state) {
2283   map_.Lookup(extension, Hash(extension), true)->value =
2284       reinterpret_cast<void*>(static_cast<intptr_t>(state));
2285 }
2286 
2287 
InstallExtensions(Handle<Context> native_context,v8::ExtensionConfiguration * extensions)2288 bool Genesis::InstallExtensions(Handle<Context> native_context,
2289                                 v8::ExtensionConfiguration* extensions) {
2290   Isolate* isolate = native_context->GetIsolate();
2291   ExtensionStates extension_states;  // All extensions have state UNVISITED.
2292   return InstallAutoExtensions(isolate, &extension_states) &&
2293       (!FLAG_expose_free_buffer ||
2294        InstallExtension(isolate, "v8/free-buffer", &extension_states)) &&
2295       (!FLAG_expose_gc ||
2296        InstallExtension(isolate, "v8/gc", &extension_states)) &&
2297       (!FLAG_expose_externalize_string ||
2298        InstallExtension(isolate, "v8/externalize", &extension_states)) &&
2299       (!FLAG_track_gc_object_stats ||
2300        InstallExtension(isolate, "v8/statistics", &extension_states)) &&
2301       (!FLAG_expose_trigger_failure ||
2302        InstallExtension(isolate, "v8/trigger-failure", &extension_states)) &&
2303       InstallRequestedExtensions(isolate, extensions, &extension_states);
2304 }
2305 
2306 
InstallAutoExtensions(Isolate * isolate,ExtensionStates * extension_states)2307 bool Genesis::InstallAutoExtensions(Isolate* isolate,
2308                                     ExtensionStates* extension_states) {
2309   for (v8::RegisteredExtension* it = v8::RegisteredExtension::first_extension();
2310        it != NULL;
2311        it = it->next()) {
2312     if (it->extension()->auto_enable() &&
2313         !InstallExtension(isolate, it, extension_states)) {
2314       return false;
2315     }
2316   }
2317   return true;
2318 }
2319 
2320 
InstallRequestedExtensions(Isolate * isolate,v8::ExtensionConfiguration * extensions,ExtensionStates * extension_states)2321 bool Genesis::InstallRequestedExtensions(Isolate* isolate,
2322                                          v8::ExtensionConfiguration* extensions,
2323                                          ExtensionStates* extension_states) {
2324   for (const char** it = extensions->begin(); it != extensions->end(); ++it) {
2325     if (!InstallExtension(isolate, *it, extension_states)) return false;
2326   }
2327   return true;
2328 }
2329 
2330 
2331 // Installs a named extension.  This methods is unoptimized and does
2332 // not scale well if we want to support a large number of extensions.
InstallExtension(Isolate * isolate,const char * name,ExtensionStates * extension_states)2333 bool Genesis::InstallExtension(Isolate* isolate,
2334                                const char* name,
2335                                ExtensionStates* extension_states) {
2336   for (v8::RegisteredExtension* it = v8::RegisteredExtension::first_extension();
2337        it != NULL;
2338        it = it->next()) {
2339     if (strcmp(name, it->extension()->name()) == 0) {
2340       return InstallExtension(isolate, it, extension_states);
2341     }
2342   }
2343   return Utils::ApiCheck(false,
2344                          "v8::Context::New()",
2345                          "Cannot find required extension");
2346 }
2347 
2348 
InstallExtension(Isolate * isolate,v8::RegisteredExtension * current,ExtensionStates * extension_states)2349 bool Genesis::InstallExtension(Isolate* isolate,
2350                                v8::RegisteredExtension* current,
2351                                ExtensionStates* extension_states) {
2352   HandleScope scope(isolate);
2353 
2354   if (extension_states->get_state(current) == INSTALLED) return true;
2355   // The current node has already been visited so there must be a
2356   // cycle in the dependency graph; fail.
2357   if (!Utils::ApiCheck(extension_states->get_state(current) != VISITED,
2358                        "v8::Context::New()",
2359                        "Circular extension dependency")) {
2360     return false;
2361   }
2362   DCHECK(extension_states->get_state(current) == UNVISITED);
2363   extension_states->set_state(current, VISITED);
2364   v8::Extension* extension = current->extension();
2365   // Install the extension's dependencies
2366   for (int i = 0; i < extension->dependency_count(); i++) {
2367     if (!InstallExtension(isolate,
2368                           extension->dependencies()[i],
2369                           extension_states)) {
2370       return false;
2371     }
2372   }
2373   // We do not expect this to throw an exception. Change this if it does.
2374   Handle<String> source_code =
2375       isolate->factory()
2376           ->NewExternalStringFromOneByte(extension->source())
2377           .ToHandleChecked();
2378   bool result = CompileScriptCached(isolate,
2379                                     CStrVector(extension->name()),
2380                                     source_code,
2381                                     isolate->bootstrapper()->extensions_cache(),
2382                                     extension,
2383                                     Handle<Context>(isolate->context()),
2384                                     false);
2385   DCHECK(isolate->has_pending_exception() != result);
2386   if (!result) {
2387     // We print out the name of the extension that fail to install.
2388     // When an error is thrown during bootstrapping we automatically print
2389     // the line number at which this happened to the console in the isolate
2390     // error throwing functionality.
2391     base::OS::PrintError("Error installing extension '%s'.\n",
2392                          current->extension()->name());
2393     isolate->clear_pending_exception();
2394   }
2395   extension_states->set_state(current, INSTALLED);
2396   isolate->NotifyExtensionInstalled();
2397   return result;
2398 }
2399 
2400 
InstallJSBuiltins(Handle<JSBuiltinsObject> builtins)2401 bool Genesis::InstallJSBuiltins(Handle<JSBuiltinsObject> builtins) {
2402   HandleScope scope(isolate());
2403   for (int i = 0; i < Builtins::NumberOfJavaScriptBuiltins(); i++) {
2404     Builtins::JavaScript id = static_cast<Builtins::JavaScript>(i);
2405     Handle<Object> function_object = Object::GetProperty(
2406         isolate(), builtins, Builtins::GetName(id)).ToHandleChecked();
2407     Handle<JSFunction> function = Handle<JSFunction>::cast(function_object);
2408     builtins->set_javascript_builtin(id, *function);
2409     // TODO(mstarzinger): This is just a temporary hack to make TurboFan work,
2410     // the correct solution is to restore the context register after invoking
2411     // builtins from full-codegen.
2412     function->shared()->set_optimization_disabled(true);
2413     if (!Compiler::EnsureCompiled(function, CLEAR_EXCEPTION)) {
2414       return false;
2415     }
2416     builtins->set_javascript_builtin_code(id, function->shared()->code());
2417   }
2418   return true;
2419 }
2420 
2421 
ConfigureGlobalObjects(v8::Handle<v8::ObjectTemplate> global_proxy_template)2422 bool Genesis::ConfigureGlobalObjects(
2423     v8::Handle<v8::ObjectTemplate> global_proxy_template) {
2424   Handle<JSObject> global_proxy(
2425       JSObject::cast(native_context()->global_proxy()));
2426   Handle<JSObject> global_object(
2427       JSObject::cast(native_context()->global_object()));
2428 
2429   if (!global_proxy_template.IsEmpty()) {
2430     // Configure the global proxy object.
2431     Handle<ObjectTemplateInfo> global_proxy_data =
2432         v8::Utils::OpenHandle(*global_proxy_template);
2433     if (!ConfigureApiObject(global_proxy, global_proxy_data)) return false;
2434 
2435     // Configure the global object.
2436     Handle<FunctionTemplateInfo> proxy_constructor(
2437         FunctionTemplateInfo::cast(global_proxy_data->constructor()));
2438     if (!proxy_constructor->prototype_template()->IsUndefined()) {
2439       Handle<ObjectTemplateInfo> global_object_data(
2440           ObjectTemplateInfo::cast(proxy_constructor->prototype_template()));
2441       if (!ConfigureApiObject(global_object, global_object_data)) return false;
2442     }
2443   }
2444 
2445   SetObjectPrototype(global_proxy, global_object);
2446 
2447   native_context()->set_initial_array_prototype(
2448       JSArray::cast(native_context()->array_function()->prototype()));
2449 
2450   return true;
2451 }
2452 
2453 
ConfigureApiObject(Handle<JSObject> object,Handle<ObjectTemplateInfo> object_template)2454 bool Genesis::ConfigureApiObject(Handle<JSObject> object,
2455                                  Handle<ObjectTemplateInfo> object_template) {
2456   DCHECK(!object_template.is_null());
2457   DCHECK(FunctionTemplateInfo::cast(object_template->constructor())
2458              ->IsTemplateFor(object->map()));;
2459 
2460   MaybeHandle<JSObject> maybe_obj =
2461       Execution::InstantiateObject(object_template);
2462   Handle<JSObject> obj;
2463   if (!maybe_obj.ToHandle(&obj)) {
2464     DCHECK(isolate()->has_pending_exception());
2465     isolate()->clear_pending_exception();
2466     return false;
2467   }
2468   TransferObject(obj, object);
2469   return true;
2470 }
2471 
2472 
TransferNamedProperties(Handle<JSObject> from,Handle<JSObject> to)2473 void Genesis::TransferNamedProperties(Handle<JSObject> from,
2474                                       Handle<JSObject> to) {
2475   if (from->HasFastProperties()) {
2476     Handle<DescriptorArray> descs =
2477         Handle<DescriptorArray>(from->map()->instance_descriptors());
2478     for (int i = 0; i < from->map()->NumberOfOwnDescriptors(); i++) {
2479       PropertyDetails details = descs->GetDetails(i);
2480       switch (details.type()) {
2481         case FIELD: {
2482           HandleScope inner(isolate());
2483           Handle<Name> key = Handle<Name>(descs->GetKey(i));
2484           FieldIndex index = FieldIndex::ForDescriptor(from->map(), i);
2485           DCHECK(!descs->GetDetails(i).representation().IsDouble());
2486           Handle<Object> value = Handle<Object>(from->RawFastPropertyAt(index),
2487                                                 isolate());
2488           JSObject::AddProperty(to, key, value, details.attributes());
2489           break;
2490         }
2491         case CONSTANT: {
2492           HandleScope inner(isolate());
2493           Handle<Name> key = Handle<Name>(descs->GetKey(i));
2494           Handle<Object> constant(descs->GetConstant(i), isolate());
2495           JSObject::AddProperty(to, key, constant, details.attributes());
2496           break;
2497         }
2498         case CALLBACKS: {
2499           Handle<Name> key(descs->GetKey(i));
2500           LookupIterator it(to, key, LookupIterator::OWN_SKIP_INTERCEPTOR);
2501           CHECK_NE(LookupIterator::ACCESS_CHECK, it.state());
2502           // If the property is already there we skip it
2503           if (it.IsFound()) continue;
2504           HandleScope inner(isolate());
2505           DCHECK(!to->HasFastProperties());
2506           // Add to dictionary.
2507           Handle<Object> callbacks(descs->GetCallbacksObject(i), isolate());
2508           PropertyDetails d = PropertyDetails(
2509               details.attributes(), CALLBACKS, i + 1);
2510           JSObject::SetNormalizedProperty(to, key, callbacks, d);
2511           break;
2512         }
2513         // Do not occur since the from object has fast properties.
2514         case NORMAL:
2515           UNREACHABLE();
2516           break;
2517       }
2518     }
2519   } else {
2520     Handle<NameDictionary> properties =
2521         Handle<NameDictionary>(from->property_dictionary());
2522     int capacity = properties->Capacity();
2523     for (int i = 0; i < capacity; i++) {
2524       Object* raw_key(properties->KeyAt(i));
2525       if (properties->IsKey(raw_key)) {
2526         DCHECK(raw_key->IsName());
2527         // If the property is already there we skip it.
2528         Handle<Name> key(Name::cast(raw_key));
2529         LookupIterator it(to, key, LookupIterator::OWN_SKIP_INTERCEPTOR);
2530         CHECK_NE(LookupIterator::ACCESS_CHECK, it.state());
2531         if (it.IsFound()) continue;
2532         // Set the property.
2533         Handle<Object> value = Handle<Object>(properties->ValueAt(i),
2534                                               isolate());
2535         DCHECK(!value->IsCell());
2536         if (value->IsPropertyCell()) {
2537           value = Handle<Object>(PropertyCell::cast(*value)->value(),
2538                                  isolate());
2539         }
2540         PropertyDetails details = properties->DetailsAt(i);
2541         JSObject::AddProperty(to, key, value, details.attributes());
2542       }
2543     }
2544   }
2545 }
2546 
2547 
TransferIndexedProperties(Handle<JSObject> from,Handle<JSObject> to)2548 void Genesis::TransferIndexedProperties(Handle<JSObject> from,
2549                                         Handle<JSObject> to) {
2550   // Cloning the elements array is sufficient.
2551   Handle<FixedArray> from_elements =
2552       Handle<FixedArray>(FixedArray::cast(from->elements()));
2553   Handle<FixedArray> to_elements = factory()->CopyFixedArray(from_elements);
2554   to->set_elements(*to_elements);
2555 }
2556 
2557 
TransferObject(Handle<JSObject> from,Handle<JSObject> to)2558 void Genesis::TransferObject(Handle<JSObject> from, Handle<JSObject> to) {
2559   HandleScope outer(isolate());
2560 
2561   DCHECK(!from->IsJSArray());
2562   DCHECK(!to->IsJSArray());
2563 
2564   TransferNamedProperties(from, to);
2565   TransferIndexedProperties(from, to);
2566 
2567   // Transfer the prototype (new map is needed).
2568   Handle<Object> proto(from->map()->prototype(), isolate());
2569   SetObjectPrototype(to, proto);
2570 }
2571 
2572 
MakeFunctionInstancePrototypeWritable()2573 void Genesis::MakeFunctionInstancePrototypeWritable() {
2574   // The maps with writable prototype are created in CreateEmptyFunction
2575   // and CreateStrictModeFunctionMaps respectively. Initially the maps are
2576   // created with read-only prototype for JS builtins processing.
2577   DCHECK(!sloppy_function_map_writable_prototype_.is_null());
2578   DCHECK(!strict_function_map_writable_prototype_.is_null());
2579 
2580   // Replace function instance maps to make prototype writable.
2581   native_context()->set_sloppy_function_map(
2582       *sloppy_function_map_writable_prototype_);
2583   native_context()->set_strict_function_map(
2584       *strict_function_map_writable_prototype_);
2585 }
2586 
2587 
2588 class NoTrackDoubleFieldsForSerializerScope {
2589  public:
NoTrackDoubleFieldsForSerializerScope(Isolate * isolate)2590   explicit NoTrackDoubleFieldsForSerializerScope(Isolate* isolate)
2591       : flag_(FLAG_track_double_fields) {
2592     if (isolate->serializer_enabled()) {
2593       // Disable tracking double fields because heap numbers treated as
2594       // immutable by the serializer.
2595       FLAG_track_double_fields = false;
2596     }
2597   }
2598 
~NoTrackDoubleFieldsForSerializerScope()2599   ~NoTrackDoubleFieldsForSerializerScope() {
2600     FLAG_track_double_fields = flag_;
2601   }
2602 
2603  private:
2604   bool flag_;
2605 };
2606 
2607 
Genesis(Isolate * isolate,MaybeHandle<JSGlobalProxy> maybe_global_proxy,v8::Handle<v8::ObjectTemplate> global_proxy_template,v8::ExtensionConfiguration * extensions)2608 Genesis::Genesis(Isolate* isolate,
2609                  MaybeHandle<JSGlobalProxy> maybe_global_proxy,
2610                  v8::Handle<v8::ObjectTemplate> global_proxy_template,
2611                  v8::ExtensionConfiguration* extensions)
2612     : isolate_(isolate),
2613       active_(isolate->bootstrapper()) {
2614   NoTrackDoubleFieldsForSerializerScope disable_scope(isolate);
2615   result_ = Handle<Context>::null();
2616   // Before creating the roots we must save the context and restore it
2617   // on all function exits.
2618   SaveContext saved_context(isolate);
2619 
2620   // During genesis, the boilerplate for stack overflow won't work until the
2621   // environment has been at least partially initialized. Add a stack check
2622   // before entering JS code to catch overflow early.
2623   StackLimitCheck check(isolate);
2624   if (check.HasOverflowed()) return;
2625 
2626   // We can only de-serialize a context if the isolate was initialized from
2627   // a snapshot. Otherwise we have to build the context from scratch.
2628   if (isolate->initialized_from_snapshot()) {
2629     native_context_ = Snapshot::NewContextFromSnapshot(isolate);
2630   } else {
2631     native_context_ = Handle<Context>();
2632   }
2633 
2634   if (!native_context().is_null()) {
2635     AddToWeakNativeContextList(*native_context());
2636     isolate->set_context(*native_context());
2637     isolate->counters()->contexts_created_by_snapshot()->Increment();
2638     Handle<GlobalObject> global_object;
2639     Handle<JSGlobalProxy> global_proxy = CreateNewGlobals(
2640         global_proxy_template, maybe_global_proxy, &global_object);
2641 
2642     HookUpGlobalProxy(global_object, global_proxy);
2643     HookUpGlobalObject(global_object);
2644     native_context()->builtins()->set_global_proxy(
2645         native_context()->global_proxy());
2646 
2647     if (!ConfigureGlobalObjects(global_proxy_template)) return;
2648   } else {
2649     // We get here if there was no context snapshot.
2650     CreateRoots();
2651     Handle<JSFunction> empty_function = CreateEmptyFunction(isolate);
2652     CreateStrictModeFunctionMaps(empty_function);
2653     Handle<GlobalObject> global_object;
2654     Handle<JSGlobalProxy> global_proxy = CreateNewGlobals(
2655         global_proxy_template, maybe_global_proxy, &global_object);
2656     HookUpGlobalProxy(global_object, global_proxy);
2657     InitializeGlobal(global_object, empty_function);
2658     InstallJSFunctionResultCaches();
2659     InitializeNormalizedMapCaches();
2660     if (!InstallNatives()) return;
2661 
2662     MakeFunctionInstancePrototypeWritable();
2663 
2664     if (!ConfigureGlobalObjects(global_proxy_template)) return;
2665     isolate->counters()->contexts_created_from_scratch()->Increment();
2666   }
2667 
2668   // Install experimental natives.
2669   if (!InstallExperimentalNatives()) return;
2670   InitializeExperimentalGlobal();
2671 
2672   // We can't (de-)serialize typed arrays currently, but we are lucky: The state
2673   // of the random number generator needs no initialization during snapshot
2674   // creation time and we don't need trigonometric functions then.
2675   if (!isolate->serializer_enabled()) {
2676     // Initially seed the per-context random number generator using the
2677     // per-isolate random number generator.
2678     const int num_elems = 2;
2679     const int num_bytes = num_elems * sizeof(uint32_t);
2680     uint32_t* state = reinterpret_cast<uint32_t*>(malloc(num_bytes));
2681 
2682     do {
2683       isolate->random_number_generator()->NextBytes(state, num_bytes);
2684     } while (state[0] == 0 || state[1] == 0);
2685 
2686     v8::Local<v8::ArrayBuffer> buffer = v8::ArrayBuffer::New(
2687         reinterpret_cast<v8::Isolate*>(isolate), state, num_bytes);
2688     Utils::OpenHandle(*buffer)->set_should_be_freed(true);
2689     v8::Local<v8::Uint32Array> ta = v8::Uint32Array::New(buffer, 0, num_elems);
2690     Handle<JSBuiltinsObject> builtins(native_context()->builtins());
2691     Runtime::DefineObjectProperty(builtins, factory()->InternalizeOneByteString(
2692                                                 STATIC_CHAR_VECTOR("rngstate")),
2693                                   Utils::OpenHandle(*ta), NONE).Assert();
2694 
2695     // Initialize trigonometric lookup tables and constants.
2696     const int constants_size = arraysize(fdlibm::MathConstants::constants);
2697     const int table_num_bytes = constants_size * kDoubleSize;
2698     v8::Local<v8::ArrayBuffer> trig_buffer = v8::ArrayBuffer::New(
2699         reinterpret_cast<v8::Isolate*>(isolate),
2700         const_cast<double*>(fdlibm::MathConstants::constants), table_num_bytes);
2701     v8::Local<v8::Float64Array> trig_table =
2702         v8::Float64Array::New(trig_buffer, 0, constants_size);
2703 
2704     Runtime::DefineObjectProperty(
2705         builtins,
2706         factory()->InternalizeOneByteString(STATIC_CHAR_VECTOR("kMath")),
2707         Utils::OpenHandle(*trig_table), NONE).Assert();
2708   }
2709 
2710   result_ = native_context();
2711 }
2712 
2713 
2714 // Support for thread preemption.
2715 
2716 // Reserve space for statics needing saving and restoring.
ArchiveSpacePerThread()2717 int Bootstrapper::ArchiveSpacePerThread() {
2718   return sizeof(NestingCounterType);
2719 }
2720 
2721 
2722 // Archive statics that are thread-local.
ArchiveState(char * to)2723 char* Bootstrapper::ArchiveState(char* to) {
2724   *reinterpret_cast<NestingCounterType*>(to) = nesting_;
2725   nesting_ = 0;
2726   return to + sizeof(NestingCounterType);
2727 }
2728 
2729 
2730 // Restore statics that are thread-local.
RestoreState(char * from)2731 char* Bootstrapper::RestoreState(char* from) {
2732   nesting_ = *reinterpret_cast<NestingCounterType*>(from);
2733   return from + sizeof(NestingCounterType);
2734 }
2735 
2736 
2737 // Called when the top-level V8 mutex is destroyed.
FreeThreadResources()2738 void Bootstrapper::FreeThreadResources() {
2739   DCHECK(!IsActive());
2740 }
2741 
2742 } }  // namespace v8::internal
2743