| // Copyright 2012 the V8 project authors. All rights reserved. |
| // Redistribution and use in source and binary forms, with or without |
| // modification, are permitted provided that the following conditions are |
| // met: |
| // |
| // * Redistributions of source code must retain the above copyright |
| // notice, this list of conditions and the following disclaimer. |
| // * Redistributions in binary form must reproduce the above |
| // copyright notice, this list of conditions and the following |
| // disclaimer in the documentation and/or other materials provided |
| // with the distribution. |
| // * Neither the name of Google Inc. nor the names of its |
| // contributors may be used to endorse or promote products derived |
| // from this software without specific prior written permission. |
| // |
| // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS |
| // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT |
| // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR |
| // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT |
| // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
| // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT |
| // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
| // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
| // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
| // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
| // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| |
| #include "v8.h" |
| |
| #include "accessors.h" |
| #include "api.h" |
| #include "arguments.h" |
| #include "codegen.h" |
| #include "execution.h" |
| #include "ic-inl.h" |
| #include "runtime.h" |
| #include "stub-cache.h" |
| #include "v8conversions.h" |
| |
| namespace v8 { |
| namespace internal { |
| |
| #ifdef DEBUG |
| char IC::TransitionMarkFromState(IC::State state) { |
| switch (state) { |
| case UNINITIALIZED: return '0'; |
| case PREMONOMORPHIC: return '.'; |
| case MONOMORPHIC: return '1'; |
| case MONOMORPHIC_PROTOTYPE_FAILURE: return '^'; |
| case POLYMORPHIC: return 'P'; |
| case MEGAMORPHIC: return 'N'; |
| case GENERIC: return 'G'; |
| |
| // We never see the debugger states here, because the state is |
| // computed from the original code - not the patched code. Let |
| // these cases fall through to the unreachable code below. |
| case DEBUG_STUB: break; |
| } |
| UNREACHABLE(); |
| return 0; |
| } |
| |
| |
| const char* GetTransitionMarkModifier(KeyedAccessStoreMode mode) { |
| if (mode == STORE_NO_TRANSITION_HANDLE_COW) return ".COW"; |
| if (mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS) { |
| return ".IGNORE_OOB"; |
| } |
| if (IsGrowStoreMode(mode)) return ".GROW"; |
| return ""; |
| } |
| |
| |
| void IC::TraceIC(const char* type, |
| Handle<Object> name) { |
| if (FLAG_trace_ic) { |
| Code* new_target = raw_target(); |
| State new_state = new_target->ic_state(); |
| PrintF("[%s%s in ", new_target->is_keyed_stub() ? "Keyed" : "", type); |
| StackFrameIterator it(isolate()); |
| while (it.frame()->fp() != this->fp()) it.Advance(); |
| StackFrame* raw_frame = it.frame(); |
| if (raw_frame->is_internal()) { |
| Code* apply_builtin = isolate()->builtins()->builtin( |
| Builtins::kFunctionApply); |
| if (raw_frame->unchecked_code() == apply_builtin) { |
| PrintF("apply from "); |
| it.Advance(); |
| raw_frame = it.frame(); |
| } |
| } |
| JavaScriptFrame::PrintTop(isolate(), stdout, false, true); |
| ExtraICState extra_state = new_target->extra_ic_state(); |
| const char* modifier = |
| GetTransitionMarkModifier( |
| KeyedStoreIC::GetKeyedAccessStoreMode(extra_state)); |
| PrintF(" (%c->%c%s)", |
| TransitionMarkFromState(state()), |
| TransitionMarkFromState(new_state), |
| modifier); |
| name->Print(); |
| PrintF("]\n"); |
| } |
| } |
| |
| #define TRACE_GENERIC_IC(isolate, type, reason) \ |
| do { \ |
| if (FLAG_trace_ic) { \ |
| PrintF("[%s patching generic stub in ", type); \ |
| JavaScriptFrame::PrintTop(isolate, stdout, false, true); \ |
| PrintF(" (%s)]\n", reason); \ |
| } \ |
| } while (false) |
| |
| #else |
| #define TRACE_GENERIC_IC(isolate, type, reason) |
| #endif // DEBUG |
| |
| #define TRACE_IC(type, name) \ |
| ASSERT((TraceIC(type, name), true)) |
| |
| IC::IC(FrameDepth depth, Isolate* isolate) |
| : isolate_(isolate), |
| target_set_(false) { |
| // To improve the performance of the (much used) IC code, we unfold a few |
| // levels of the stack frame iteration code. This yields a ~35% speedup when |
| // running DeltaBlue and a ~25% speedup of gbemu with the '--nouse-ic' flag. |
| const Address entry = |
| Isolate::c_entry_fp(isolate->thread_local_top()); |
| Address constant_pool = NULL; |
| if (FLAG_enable_ool_constant_pool) { |
| constant_pool = Memory::Address_at( |
| entry + ExitFrameConstants::kConstantPoolOffset); |
| } |
| Address* pc_address = |
| reinterpret_cast<Address*>(entry + ExitFrameConstants::kCallerPCOffset); |
| Address fp = Memory::Address_at(entry + ExitFrameConstants::kCallerFPOffset); |
| // If there's another JavaScript frame on the stack or a |
| // StubFailureTrampoline, we need to look one frame further down the stack to |
| // find the frame pointer and the return address stack slot. |
| if (depth == EXTRA_CALL_FRAME) { |
| if (FLAG_enable_ool_constant_pool) { |
| constant_pool = Memory::Address_at( |
| fp + StandardFrameConstants::kConstantPoolOffset); |
| } |
| const int kCallerPCOffset = StandardFrameConstants::kCallerPCOffset; |
| pc_address = reinterpret_cast<Address*>(fp + kCallerPCOffset); |
| fp = Memory::Address_at(fp + StandardFrameConstants::kCallerFPOffset); |
| } |
| #ifdef DEBUG |
| StackFrameIterator it(isolate); |
| for (int i = 0; i < depth + 1; i++) it.Advance(); |
| StackFrame* frame = it.frame(); |
| ASSERT(fp == frame->fp() && pc_address == frame->pc_address()); |
| #endif |
| fp_ = fp; |
| if (FLAG_enable_ool_constant_pool) { |
| raw_constant_pool_ = handle( |
| ConstantPoolArray::cast(reinterpret_cast<Object*>(constant_pool)), |
| isolate); |
| } |
| pc_address_ = StackFrame::ResolveReturnAddressLocation(pc_address); |
| target_ = handle(raw_target(), isolate); |
| state_ = target_->ic_state(); |
| extra_ic_state_ = target_->extra_ic_state(); |
| } |
| |
| |
| #ifdef ENABLE_DEBUGGER_SUPPORT |
| SharedFunctionInfo* IC::GetSharedFunctionInfo() const { |
| // Compute the JavaScript frame for the frame pointer of this IC |
| // structure. We need this to be able to find the function |
| // corresponding to the frame. |
| StackFrameIterator it(isolate()); |
| while (it.frame()->fp() != this->fp()) it.Advance(); |
| JavaScriptFrame* frame = JavaScriptFrame::cast(it.frame()); |
| // Find the function on the stack and both the active code for the |
| // function and the original code. |
| JSFunction* function = frame->function(); |
| return function->shared(); |
| } |
| |
| |
| Code* IC::GetCode() const { |
| HandleScope scope(isolate()); |
| Handle<SharedFunctionInfo> shared(GetSharedFunctionInfo(), isolate()); |
| Code* code = shared->code(); |
| return code; |
| } |
| |
| |
| Code* IC::GetOriginalCode() const { |
| HandleScope scope(isolate()); |
| Handle<SharedFunctionInfo> shared(GetSharedFunctionInfo(), isolate()); |
| ASSERT(Debug::HasDebugInfo(shared)); |
| Code* original_code = Debug::GetDebugInfo(shared)->original_code(); |
| ASSERT(original_code->IsCode()); |
| return original_code; |
| } |
| #endif |
| |
| |
| static bool HasInterceptorGetter(JSObject* object) { |
| return !object->GetNamedInterceptor()->getter()->IsUndefined(); |
| } |
| |
| |
| static bool HasInterceptorSetter(JSObject* object) { |
| return !object->GetNamedInterceptor()->setter()->IsUndefined(); |
| } |
| |
| |
| static void LookupForRead(Handle<Object> object, |
| Handle<String> name, |
| LookupResult* lookup) { |
| // Skip all the objects with named interceptors, but |
| // without actual getter. |
| while (true) { |
| object->Lookup(*name, lookup); |
| // Besides normal conditions (property not found or it's not |
| // an interceptor), bail out if lookup is not cacheable: we won't |
| // be able to IC it anyway and regular lookup should work fine. |
| if (!lookup->IsInterceptor() || !lookup->IsCacheable()) { |
| return; |
| } |
| |
| Handle<JSObject> holder(lookup->holder(), lookup->isolate()); |
| if (HasInterceptorGetter(*holder)) { |
| return; |
| } |
| |
| holder->LocalLookupRealNamedProperty(*name, lookup); |
| if (lookup->IsFound()) { |
| ASSERT(!lookup->IsInterceptor()); |
| return; |
| } |
| |
| Handle<Object> proto(holder->GetPrototype(), lookup->isolate()); |
| if (proto->IsNull()) { |
| ASSERT(!lookup->IsFound()); |
| return; |
| } |
| |
| object = proto; |
| } |
| } |
| |
| |
| bool IC::TryRemoveInvalidPrototypeDependentStub(Handle<Object> receiver, |
| Handle<String> name) { |
| if (target()->is_keyed_stub()) { |
| // Determine whether the failure is due to a name failure. |
| if (!name->IsName()) return false; |
| Name* stub_name = target()->FindFirstName(); |
| if (*name != stub_name) return false; |
| } |
| |
| InlineCacheHolderFlag cache_holder = |
| Code::ExtractCacheHolderFromFlags(target()->flags()); |
| |
| switch (cache_holder) { |
| case OWN_MAP: |
| // The stub was generated for JSObject but called for non-JSObject. |
| // IC::GetCodeCacheHolder is not applicable. |
| if (!receiver->IsJSObject()) return false; |
| break; |
| case PROTOTYPE_MAP: |
| // IC::GetCodeCacheHolder is not applicable. |
| if (receiver->GetPrototype(isolate())->IsNull()) return false; |
| break; |
| } |
| |
| Handle<Map> map( |
| IC::GetCodeCacheHolder(isolate(), *receiver, cache_holder)->map()); |
| |
| // Decide whether the inline cache failed because of changes to the |
| // receiver itself or changes to one of its prototypes. |
| // |
| // If there are changes to the receiver itself, the map of the |
| // receiver will have changed and the current target will not be in |
| // the receiver map's code cache. Therefore, if the current target |
| // is in the receiver map's code cache, the inline cache failed due |
| // to prototype check failure. |
| int index = map->IndexInCodeCache(*name, *target()); |
| if (index >= 0) { |
| map->RemoveFromCodeCache(*name, *target(), index); |
| // Handlers are stored in addition to the ICs on the map. Remove those, too. |
| TryRemoveInvalidHandlers(map, name); |
| return true; |
| } |
| |
| // The stub is not in the cache. We've ruled out all other kinds of failure |
| // except for proptotype chain changes, a deprecated map, a map that's |
| // different from the one that the stub expects, elements kind changes, or a |
| // constant global property that will become mutable. Threat all those |
| // situations as prototype failures (stay monomorphic if possible). |
| |
| // If the IC is shared between multiple receivers (slow dictionary mode), then |
| // the map cannot be deprecated and the stub invalidated. |
| if (cache_holder == OWN_MAP) { |
| Map* old_map = target()->FindFirstMap(); |
| if (old_map == *map) return true; |
| if (old_map != NULL) { |
| if (old_map->is_deprecated()) return true; |
| if (IsMoreGeneralElementsKindTransition(old_map->elements_kind(), |
| map->elements_kind())) { |
| return true; |
| } |
| } |
| } |
| |
| if (receiver->IsGlobalObject()) { |
| LookupResult lookup(isolate()); |
| GlobalObject* global = GlobalObject::cast(*receiver); |
| global->LocalLookupRealNamedProperty(*name, &lookup); |
| if (!lookup.IsFound()) return false; |
| PropertyCell* cell = global->GetPropertyCell(&lookup); |
| return cell->type()->IsConstant(); |
| } |
| |
| return false; |
| } |
| |
| |
| void IC::TryRemoveInvalidHandlers(Handle<Map> map, Handle<String> name) { |
| CodeHandleList handlers; |
| target()->FindHandlers(&handlers); |
| for (int i = 0; i < handlers.length(); i++) { |
| Handle<Code> handler = handlers.at(i); |
| int index = map->IndexInCodeCache(*name, *handler); |
| if (index >= 0) { |
| map->RemoveFromCodeCache(*name, *handler, index); |
| return; |
| } |
| } |
| } |
| |
| |
| void IC::UpdateState(Handle<Object> receiver, Handle<Object> name) { |
| if (!name->IsString()) return; |
| if (state() != MONOMORPHIC) { |
| if (state() == POLYMORPHIC && receiver->IsHeapObject()) { |
| TryRemoveInvalidHandlers( |
| handle(Handle<HeapObject>::cast(receiver)->map()), |
| Handle<String>::cast(name)); |
| } |
| return; |
| } |
| if (receiver->IsUndefined() || receiver->IsNull()) return; |
| |
| // Remove the target from the code cache if it became invalid |
| // because of changes in the prototype chain to avoid hitting it |
| // again. |
| if (TryRemoveInvalidPrototypeDependentStub( |
| receiver, Handle<String>::cast(name))) { |
| return MarkMonomorphicPrototypeFailure(); |
| } |
| |
| // The builtins object is special. It only changes when JavaScript |
| // builtins are loaded lazily. It is important to keep inline |
| // caches for the builtins object monomorphic. Therefore, if we get |
| // an inline cache miss for the builtins object after lazily loading |
| // JavaScript builtins, we return uninitialized as the state to |
| // force the inline cache back to monomorphic state. |
| if (receiver->IsJSBuiltinsObject()) state_ = UNINITIALIZED; |
| } |
| |
| |
| Failure* IC::TypeError(const char* type, |
| Handle<Object> object, |
| Handle<Object> key) { |
| HandleScope scope(isolate()); |
| Handle<Object> args[2] = { key, object }; |
| Handle<Object> error = isolate()->factory()->NewTypeError( |
| type, HandleVector(args, 2)); |
| return isolate()->Throw(*error); |
| } |
| |
| |
| Failure* IC::ReferenceError(const char* type, Handle<String> name) { |
| HandleScope scope(isolate()); |
| Handle<Object> error = isolate()->factory()->NewReferenceError( |
| type, HandleVector(&name, 1)); |
| return isolate()->Throw(*error); |
| } |
| |
| |
| static int ComputeTypeInfoCountDelta(IC::State old_state, IC::State new_state) { |
| bool was_uninitialized = |
| old_state == UNINITIALIZED || old_state == PREMONOMORPHIC; |
| bool is_uninitialized = |
| new_state == UNINITIALIZED || new_state == PREMONOMORPHIC; |
| return (was_uninitialized && !is_uninitialized) ? 1 : |
| (!was_uninitialized && is_uninitialized) ? -1 : 0; |
| } |
| |
| |
| void IC::PostPatching(Address address, Code* target, Code* old_target) { |
| Isolate* isolate = target->GetHeap()->isolate(); |
| Code* host = isolate-> |
| inner_pointer_to_code_cache()->GetCacheEntry(address)->code; |
| if (host->kind() != Code::FUNCTION) return; |
| |
| if (FLAG_type_info_threshold > 0 && |
| old_target->is_inline_cache_stub() && |
| target->is_inline_cache_stub()) { |
| int delta = ComputeTypeInfoCountDelta(old_target->ic_state(), |
| target->ic_state()); |
| // Not all Code objects have TypeFeedbackInfo. |
| if (host->type_feedback_info()->IsTypeFeedbackInfo() && delta != 0) { |
| TypeFeedbackInfo* info = |
| TypeFeedbackInfo::cast(host->type_feedback_info()); |
| info->change_ic_with_type_info_count(delta); |
| } |
| } |
| if (host->type_feedback_info()->IsTypeFeedbackInfo()) { |
| TypeFeedbackInfo* info = |
| TypeFeedbackInfo::cast(host->type_feedback_info()); |
| info->change_own_type_change_checksum(); |
| } |
| host->set_profiler_ticks(0); |
| isolate->runtime_profiler()->NotifyICChanged(); |
| // TODO(2029): When an optimized function is patched, it would |
| // be nice to propagate the corresponding type information to its |
| // unoptimized version for the benefit of later inlining. |
| } |
| |
| |
| void IC::Clear(Isolate* isolate, Address address, |
| ConstantPoolArray* constant_pool) { |
| Code* target = GetTargetAtAddress(address, constant_pool); |
| |
| // Don't clear debug break inline cache as it will remove the break point. |
| if (target->is_debug_stub()) return; |
| |
| switch (target->kind()) { |
| case Code::LOAD_IC: |
| return LoadIC::Clear(isolate, address, target, constant_pool); |
| case Code::KEYED_LOAD_IC: |
| return KeyedLoadIC::Clear(isolate, address, target, constant_pool); |
| case Code::STORE_IC: |
| return StoreIC::Clear(isolate, address, target, constant_pool); |
| case Code::KEYED_STORE_IC: |
| return KeyedStoreIC::Clear(isolate, address, target, constant_pool); |
| case Code::COMPARE_IC: |
| return CompareIC::Clear(isolate, address, target, constant_pool); |
| case Code::COMPARE_NIL_IC: |
| return CompareNilIC::Clear(address, target, constant_pool); |
| case Code::BINARY_OP_IC: |
| case Code::TO_BOOLEAN_IC: |
| // Clearing these is tricky and does not |
| // make any performance difference. |
| return; |
| default: UNREACHABLE(); |
| } |
| } |
| |
| |
| void KeyedLoadIC::Clear(Isolate* isolate, |
| Address address, |
| Code* target, |
| ConstantPoolArray* constant_pool) { |
| if (IsCleared(target)) return; |
| // Make sure to also clear the map used in inline fast cases. If we |
| // do not clear these maps, cached code can keep objects alive |
| // through the embedded maps. |
| SetTargetAtAddress(address, *pre_monomorphic_stub(isolate), constant_pool); |
| } |
| |
| |
| void LoadIC::Clear(Isolate* isolate, |
| Address address, |
| Code* target, |
| ConstantPoolArray* constant_pool) { |
| if (IsCleared(target)) return; |
| Code* code = target->GetIsolate()->stub_cache()->FindPreMonomorphicIC( |
| Code::LOAD_IC, target->extra_ic_state()); |
| SetTargetAtAddress(address, code, constant_pool); |
| } |
| |
| |
| void StoreIC::Clear(Isolate* isolate, |
| Address address, |
| Code* target, |
| ConstantPoolArray* constant_pool) { |
| if (IsCleared(target)) return; |
| Code* code = target->GetIsolate()->stub_cache()->FindPreMonomorphicIC( |
| Code::STORE_IC, target->extra_ic_state()); |
| SetTargetAtAddress(address, code, constant_pool); |
| } |
| |
| |
| void KeyedStoreIC::Clear(Isolate* isolate, |
| Address address, |
| Code* target, |
| ConstantPoolArray* constant_pool) { |
| if (IsCleared(target)) return; |
| SetTargetAtAddress(address, |
| *pre_monomorphic_stub( |
| isolate, StoreIC::GetStrictMode(target->extra_ic_state())), |
| constant_pool); |
| } |
| |
| |
| void CompareIC::Clear(Isolate* isolate, |
| Address address, |
| Code* target, |
| ConstantPoolArray* constant_pool) { |
| ASSERT(target->major_key() == CodeStub::CompareIC); |
| CompareIC::State handler_state; |
| Token::Value op; |
| ICCompareStub::DecodeMinorKey(target->stub_info(), NULL, NULL, |
| &handler_state, &op); |
| // Only clear CompareICs that can retain objects. |
| if (handler_state != KNOWN_OBJECT) return; |
| SetTargetAtAddress(address, GetRawUninitialized(isolate, op), constant_pool); |
| PatchInlinedSmiCode(address, DISABLE_INLINED_SMI_CHECK); |
| } |
| |
| |
| static bool MigrateDeprecated(Handle<Object> object) { |
| if (!object->IsJSObject()) return false; |
| Handle<JSObject> receiver = Handle<JSObject>::cast(object); |
| if (!receiver->map()->is_deprecated()) return false; |
| JSObject::MigrateInstance(Handle<JSObject>::cast(object)); |
| return true; |
| } |
| |
| |
| MaybeObject* LoadIC::Load(Handle<Object> object, |
| Handle<String> name) { |
| // If the object is undefined or null it's illegal to try to get any |
| // of its properties; throw a TypeError in that case. |
| if (object->IsUndefined() || object->IsNull()) { |
| return TypeError("non_object_property_load", object, name); |
| } |
| |
| if (FLAG_use_ic) { |
| // Use specialized code for getting prototype of functions. |
| if (object->IsJSFunction() && |
| name->Equals(isolate()->heap()->prototype_string()) && |
| Handle<JSFunction>::cast(object)->should_have_prototype()) { |
| Handle<Code> stub; |
| if (state() == UNINITIALIZED) { |
| stub = pre_monomorphic_stub(); |
| } else if (state() == PREMONOMORPHIC) { |
| FunctionPrototypeStub function_prototype_stub(kind()); |
| stub = function_prototype_stub.GetCode(isolate()); |
| } else if (state() != MEGAMORPHIC) { |
| ASSERT(state() != GENERIC); |
| stub = megamorphic_stub(); |
| } |
| if (!stub.is_null()) { |
| set_target(*stub); |
| if (FLAG_trace_ic) PrintF("[LoadIC : +#prototype /function]\n"); |
| } |
| return *Accessors::FunctionGetPrototype(Handle<JSFunction>::cast(object)); |
| } |
| } |
| |
| // Check if the name is trivially convertible to an index and get |
| // the element or char if so. |
| uint32_t index; |
| if (kind() == Code::KEYED_LOAD_IC && name->AsArrayIndex(&index)) { |
| // Rewrite to the generic keyed load stub. |
| if (FLAG_use_ic) set_target(*generic_stub()); |
| Handle<Object> result = |
| Runtime::GetElementOrCharAt(isolate(), object, index); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| bool use_ic = MigrateDeprecated(object) ? false : FLAG_use_ic; |
| |
| // Named lookup in the object. |
| LookupResult lookup(isolate()); |
| LookupForRead(object, name, &lookup); |
| |
| // If we did not find a property, check if we need to throw an exception. |
| if (!lookup.IsFound()) { |
| if (IsUndeclaredGlobal(object)) { |
| return ReferenceError("not_defined", name); |
| } |
| LOG(isolate(), SuspectReadEvent(*name, *object)); |
| } |
| |
| // Update inline cache and stub cache. |
| if (use_ic) UpdateCaches(&lookup, object, name); |
| |
| PropertyAttributes attr; |
| // Get the property. |
| Handle<Object> result = |
| Object::GetProperty(object, object, &lookup, name, &attr); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| // If the property is not present, check if we need to throw an |
| // exception. |
| if ((lookup.IsInterceptor() || lookup.IsHandler()) && |
| attr == ABSENT && IsUndeclaredGlobal(object)) { |
| return ReferenceError("not_defined", name); |
| } |
| |
| return *result; |
| } |
| |
| |
| static bool AddOneReceiverMapIfMissing(MapHandleList* receiver_maps, |
| Handle<Map> new_receiver_map) { |
| ASSERT(!new_receiver_map.is_null()); |
| for (int current = 0; current < receiver_maps->length(); ++current) { |
| if (!receiver_maps->at(current).is_null() && |
| receiver_maps->at(current).is_identical_to(new_receiver_map)) { |
| return false; |
| } |
| } |
| receiver_maps->Add(new_receiver_map); |
| return true; |
| } |
| |
| |
| bool IC::UpdatePolymorphicIC(Handle<HeapType> type, |
| Handle<String> name, |
| Handle<Code> code) { |
| if (!code->is_handler()) return false; |
| TypeHandleList types; |
| CodeHandleList handlers; |
| |
| target()->FindAllTypes(&types); |
| int number_of_types = types.length(); |
| int deprecated_types = 0; |
| int handler_to_overwrite = -1; |
| |
| for (int i = 0; i < number_of_types; i++) { |
| Handle<HeapType> current_type = types.at(i); |
| if (current_type->IsClass() && current_type->AsClass()->is_deprecated()) { |
| // Filter out deprecated maps to ensure their instances get migrated. |
| ++deprecated_types; |
| } else if (type->IsCurrently(current_type)) { |
| // If the receiver type is already in the polymorphic IC, this indicates |
| // there was a prototoype chain failure. In that case, just overwrite the |
| // handler. |
| handler_to_overwrite = i; |
| } else if (handler_to_overwrite == -1 && |
| current_type->IsClass() && |
| type->IsClass() && |
| IsTransitionOfMonomorphicTarget(*current_type->AsClass(), |
| *type->AsClass())) { |
| handler_to_overwrite = i; |
| } |
| } |
| |
| int number_of_valid_types = |
| number_of_types - deprecated_types - (handler_to_overwrite != -1); |
| |
| if (number_of_valid_types >= 4) return false; |
| if (number_of_types == 0) return false; |
| if (!target()->FindHandlers(&handlers, types.length())) return false; |
| |
| number_of_valid_types++; |
| if (handler_to_overwrite >= 0) { |
| handlers.Set(handler_to_overwrite, code); |
| if (!type->IsCurrently(types.at(handler_to_overwrite))) { |
| types.Set(handler_to_overwrite, type); |
| } |
| } else { |
| types.Add(type); |
| handlers.Add(code); |
| } |
| |
| Handle<Code> ic = isolate()->stub_cache()->ComputePolymorphicIC( |
| kind(), &types, &handlers, number_of_valid_types, name, extra_ic_state()); |
| set_target(*ic); |
| return true; |
| } |
| |
| |
| Handle<HeapType> IC::CurrentTypeOf(Handle<Object> object, Isolate* isolate) { |
| return object->IsJSGlobalObject() |
| ? HeapType::Constant(Handle<JSGlobalObject>::cast(object), isolate) |
| : HeapType::OfCurrently(object, isolate); |
| } |
| |
| |
| Handle<Map> IC::TypeToMap(HeapType* type, Isolate* isolate) { |
| if (type->Is(HeapType::Number())) |
| return isolate->factory()->heap_number_map(); |
| if (type->Is(HeapType::Boolean())) return isolate->factory()->oddball_map(); |
| if (type->IsConstant()) { |
| return handle(Handle<JSGlobalObject>::cast(type->AsConstant())->map()); |
| } |
| ASSERT(type->IsClass()); |
| return type->AsClass(); |
| } |
| |
| |
| template <class T> |
| typename T::TypeHandle IC::MapToType(Handle<Map> map, |
| typename T::Region* region) { |
| if (map->instance_type() == HEAP_NUMBER_TYPE) { |
| return T::Number(region); |
| } else if (map->instance_type() == ODDBALL_TYPE) { |
| // The only oddballs that can be recorded in ICs are booleans. |
| return T::Boolean(region); |
| } else { |
| return T::Class(map, region); |
| } |
| } |
| |
| |
| template |
| Type* IC::MapToType<Type>(Handle<Map> map, Zone* zone); |
| |
| |
| template |
| Handle<HeapType> IC::MapToType<HeapType>(Handle<Map> map, Isolate* region); |
| |
| |
| void IC::UpdateMonomorphicIC(Handle<HeapType> type, |
| Handle<Code> handler, |
| Handle<String> name) { |
| if (!handler->is_handler()) return set_target(*handler); |
| Handle<Code> ic = isolate()->stub_cache()->ComputeMonomorphicIC( |
| kind(), name, type, handler, extra_ic_state()); |
| set_target(*ic); |
| } |
| |
| |
| void IC::CopyICToMegamorphicCache(Handle<String> name) { |
| TypeHandleList types; |
| CodeHandleList handlers; |
| target()->FindAllTypes(&types); |
| if (!target()->FindHandlers(&handlers, types.length())) return; |
| for (int i = 0; i < types.length(); i++) { |
| UpdateMegamorphicCache(*types.at(i), *name, *handlers.at(i)); |
| } |
| } |
| |
| |
| bool IC::IsTransitionOfMonomorphicTarget(Map* source_map, Map* target_map) { |
| if (source_map == NULL) return true; |
| if (target_map == NULL) return false; |
| ElementsKind target_elements_kind = target_map->elements_kind(); |
| bool more_general_transition = |
| IsMoreGeneralElementsKindTransition( |
| source_map->elements_kind(), target_elements_kind); |
| Map* transitioned_map = more_general_transition |
| ? source_map->LookupElementsTransitionMap(target_elements_kind) |
| : NULL; |
| |
| return transitioned_map == target_map; |
| } |
| |
| |
| void IC::PatchCache(Handle<HeapType> type, |
| Handle<String> name, |
| Handle<Code> code) { |
| switch (state()) { |
| case UNINITIALIZED: |
| case PREMONOMORPHIC: |
| case MONOMORPHIC_PROTOTYPE_FAILURE: |
| UpdateMonomorphicIC(type, code, name); |
| break; |
| case MONOMORPHIC: // Fall through. |
| case POLYMORPHIC: |
| if (!target()->is_keyed_stub()) { |
| if (UpdatePolymorphicIC(type, name, code)) break; |
| CopyICToMegamorphicCache(name); |
| } |
| set_target(*megamorphic_stub()); |
| // Fall through. |
| case MEGAMORPHIC: |
| UpdateMegamorphicCache(*type, *name, *code); |
| break; |
| case DEBUG_STUB: |
| break; |
| case GENERIC: |
| UNREACHABLE(); |
| break; |
| } |
| } |
| |
| |
| Handle<Code> LoadIC::initialize_stub(Isolate* isolate, |
| ExtraICState extra_state) { |
| return isolate->stub_cache()->ComputeLoad(UNINITIALIZED, extra_state); |
| } |
| |
| |
| Handle<Code> LoadIC::pre_monomorphic_stub(Isolate* isolate, |
| ExtraICState extra_state) { |
| return isolate->stub_cache()->ComputeLoad(PREMONOMORPHIC, extra_state); |
| } |
| |
| |
| Handle<Code> LoadIC::megamorphic_stub() { |
| return isolate()->stub_cache()->ComputeLoad(MEGAMORPHIC, extra_ic_state()); |
| } |
| |
| |
| Handle<Code> LoadIC::SimpleFieldLoad(int offset, |
| bool inobject, |
| Representation representation) { |
| if (kind() == Code::LOAD_IC) { |
| LoadFieldStub stub(inobject, offset, representation); |
| return stub.GetCode(isolate()); |
| } else { |
| KeyedLoadFieldStub stub(inobject, offset, representation); |
| return stub.GetCode(isolate()); |
| } |
| } |
| |
| |
| void LoadIC::UpdateCaches(LookupResult* lookup, |
| Handle<Object> object, |
| Handle<String> name) { |
| if (state() == UNINITIALIZED) { |
| // This is the first time we execute this inline cache. |
| // Set the target to the pre monomorphic stub to delay |
| // setting the monomorphic state. |
| set_target(*pre_monomorphic_stub()); |
| TRACE_IC("LoadIC", name); |
| return; |
| } |
| |
| Handle<HeapType> type = CurrentTypeOf(object, isolate()); |
| Handle<Code> code; |
| if (!lookup->IsCacheable()) { |
| // Bail out if the result is not cacheable. |
| code = slow_stub(); |
| } else if (!lookup->IsProperty()) { |
| if (kind() == Code::LOAD_IC) { |
| code = isolate()->stub_cache()->ComputeLoadNonexistent(name, type); |
| } else { |
| code = slow_stub(); |
| } |
| } else { |
| code = ComputeHandler(lookup, object, name); |
| } |
| |
| PatchCache(type, name, code); |
| TRACE_IC("LoadIC", name); |
| } |
| |
| |
| void IC::UpdateMegamorphicCache(HeapType* type, Name* name, Code* code) { |
| // Cache code holding map should be consistent with |
| // GenerateMonomorphicCacheProbe. |
| Map* map = *TypeToMap(type, isolate()); |
| isolate()->stub_cache()->Set(name, map, code); |
| } |
| |
| |
| Handle<Code> IC::ComputeHandler(LookupResult* lookup, |
| Handle<Object> object, |
| Handle<String> name, |
| Handle<Object> value) { |
| InlineCacheHolderFlag cache_holder = GetCodeCacheForObject(*object); |
| Handle<HeapObject> stub_holder(GetCodeCacheHolder( |
| isolate(), *object, cache_holder)); |
| |
| Handle<Code> code = isolate()->stub_cache()->FindHandler( |
| name, handle(stub_holder->map()), kind(), cache_holder, |
| lookup->holder()->HasFastProperties() ? Code::FAST : Code::NORMAL); |
| if (!code.is_null()) { |
| return code; |
| } |
| |
| code = CompileHandler(lookup, object, name, value, cache_holder); |
| ASSERT(code->is_handler()); |
| |
| if (code->type() != Code::NORMAL) { |
| HeapObject::UpdateMapCodeCache(stub_holder, name, code); |
| } |
| |
| return code; |
| } |
| |
| |
| Handle<Code> LoadIC::CompileHandler(LookupResult* lookup, |
| Handle<Object> object, |
| Handle<String> name, |
| Handle<Object> unused, |
| InlineCacheHolderFlag cache_holder) { |
| if (object->IsString() && name->Equals(isolate()->heap()->length_string())) { |
| int length_index = String::kLengthOffset / kPointerSize; |
| return SimpleFieldLoad(length_index); |
| } |
| |
| if (object->IsStringWrapper() && |
| name->Equals(isolate()->heap()->length_string())) { |
| if (kind() == Code::LOAD_IC) { |
| StringLengthStub string_length_stub; |
| return string_length_stub.GetCode(isolate()); |
| } else { |
| KeyedStringLengthStub string_length_stub; |
| return string_length_stub.GetCode(isolate()); |
| } |
| } |
| |
| Handle<HeapType> type = CurrentTypeOf(object, isolate()); |
| Handle<JSObject> holder(lookup->holder()); |
| LoadStubCompiler compiler(isolate(), kNoExtraICState, cache_holder, kind()); |
| |
| switch (lookup->type()) { |
| case FIELD: { |
| PropertyIndex field = lookup->GetFieldIndex(); |
| if (object.is_identical_to(holder)) { |
| return SimpleFieldLoad(field.translate(holder), |
| field.is_inobject(holder), |
| lookup->representation()); |
| } |
| return compiler.CompileLoadField( |
| type, holder, name, field, lookup->representation()); |
| } |
| case CONSTANT: { |
| Handle<Object> constant(lookup->GetConstant(), isolate()); |
| // TODO(2803): Don't compute a stub for cons strings because they cannot |
| // be embedded into code. |
| if (constant->IsConsString()) break; |
| return compiler.CompileLoadConstant(type, holder, name, constant); |
| } |
| case NORMAL: |
| if (kind() != Code::LOAD_IC) break; |
| if (holder->IsGlobalObject()) { |
| Handle<GlobalObject> global = Handle<GlobalObject>::cast(holder); |
| Handle<PropertyCell> cell( |
| global->GetPropertyCell(lookup), isolate()); |
| Handle<Code> code = compiler.CompileLoadGlobal( |
| type, global, cell, name, lookup->IsDontDelete()); |
| // TODO(verwaest): Move caching of these NORMAL stubs outside as well. |
| Handle<HeapObject> stub_holder(GetCodeCacheHolder( |
| isolate(), *object, cache_holder)); |
| HeapObject::UpdateMapCodeCache(stub_holder, name, code); |
| return code; |
| } |
| // There is only one shared stub for loading normalized |
| // properties. It does not traverse the prototype chain, so the |
| // property must be found in the object for the stub to be |
| // applicable. |
| if (!object.is_identical_to(holder)) break; |
| return isolate()->builtins()->LoadIC_Normal(); |
| case CALLBACKS: { |
| // Use simple field loads for some well-known callback properties. |
| if (object->IsJSObject()) { |
| Handle<JSObject> receiver = Handle<JSObject>::cast(object); |
| Handle<HeapType> type = IC::MapToType<HeapType>( |
| handle(receiver->map()), isolate()); |
| int object_offset; |
| if (Accessors::IsJSObjectFieldAccessor<HeapType>( |
| type, name, &object_offset)) { |
| return SimpleFieldLoad(object_offset / kPointerSize); |
| } |
| } |
| |
| Handle<Object> callback(lookup->GetCallbackObject(), isolate()); |
| if (callback->IsExecutableAccessorInfo()) { |
| Handle<ExecutableAccessorInfo> info = |
| Handle<ExecutableAccessorInfo>::cast(callback); |
| if (v8::ToCData<Address>(info->getter()) == 0) break; |
| if (!info->IsCompatibleReceiver(*object)) break; |
| return compiler.CompileLoadCallback(type, holder, name, info); |
| } else if (callback->IsAccessorPair()) { |
| Handle<Object> getter(Handle<AccessorPair>::cast(callback)->getter(), |
| isolate()); |
| if (!getter->IsJSFunction()) break; |
| if (holder->IsGlobalObject()) break; |
| if (!holder->HasFastProperties()) break; |
| Handle<JSFunction> function = Handle<JSFunction>::cast(getter); |
| if (!object->IsJSObject() && |
| !function->IsBuiltin() && |
| function->shared()->strict_mode() == SLOPPY) { |
| // Calling sloppy non-builtins with a value as the receiver |
| // requires boxing. |
| break; |
| } |
| CallOptimization call_optimization(function); |
| if (call_optimization.is_simple_api_call() && |
| call_optimization.IsCompatibleReceiver(object, holder)) { |
| return compiler.CompileLoadCallback( |
| type, holder, name, call_optimization); |
| } |
| return compiler.CompileLoadViaGetter(type, holder, name, function); |
| } |
| // TODO(dcarney): Handle correctly. |
| if (callback->IsDeclaredAccessorInfo()) break; |
| ASSERT(callback->IsForeign()); |
| // No IC support for old-style native accessors. |
| break; |
| } |
| case INTERCEPTOR: |
| ASSERT(HasInterceptorGetter(*holder)); |
| return compiler.CompileLoadInterceptor(type, holder, name); |
| default: |
| break; |
| } |
| |
| return slow_stub(); |
| } |
| |
| |
| static Handle<Object> TryConvertKey(Handle<Object> key, Isolate* isolate) { |
| // This helper implements a few common fast cases for converting |
| // non-smi keys of keyed loads/stores to a smi or a string. |
| if (key->IsHeapNumber()) { |
| double value = Handle<HeapNumber>::cast(key)->value(); |
| if (std::isnan(value)) { |
| key = isolate->factory()->nan_string(); |
| } else { |
| int int_value = FastD2I(value); |
| if (value == int_value && Smi::IsValid(int_value)) { |
| key = Handle<Smi>(Smi::FromInt(int_value), isolate); |
| } |
| } |
| } else if (key->IsUndefined()) { |
| key = isolate->factory()->undefined_string(); |
| } |
| return key; |
| } |
| |
| |
| Handle<Code> KeyedLoadIC::LoadElementStub(Handle<JSObject> receiver) { |
| // Don't handle megamorphic property accesses for INTERCEPTORS or CALLBACKS |
| // via megamorphic stubs, since they don't have a map in their relocation info |
| // and so the stubs can't be harvested for the object needed for a map check. |
| if (target()->type() != Code::NORMAL) { |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "non-NORMAL target type"); |
| return generic_stub(); |
| } |
| |
| Handle<Map> receiver_map(receiver->map(), isolate()); |
| MapHandleList target_receiver_maps; |
| if (state() == UNINITIALIZED || state() == PREMONOMORPHIC) { |
| // Optimistically assume that ICs that haven't reached the MONOMORPHIC state |
| // yet will do so and stay there. |
| return isolate()->stub_cache()->ComputeKeyedLoadElement(receiver_map); |
| } |
| |
| if (target().is_identical_to(string_stub())) { |
| target_receiver_maps.Add(isolate()->factory()->string_map()); |
| } else { |
| target()->FindAllMaps(&target_receiver_maps); |
| if (target_receiver_maps.length() == 0) { |
| return isolate()->stub_cache()->ComputeKeyedLoadElement(receiver_map); |
| } |
| } |
| |
| // The first time a receiver is seen that is a transitioned version of the |
| // previous monomorphic receiver type, assume the new ElementsKind is the |
| // monomorphic type. This benefits global arrays that only transition |
| // once, and all call sites accessing them are faster if they remain |
| // monomorphic. If this optimistic assumption is not true, the IC will |
| // miss again and it will become polymorphic and support both the |
| // untransitioned and transitioned maps. |
| if (state() == MONOMORPHIC && |
| IsMoreGeneralElementsKindTransition( |
| target_receiver_maps.at(0)->elements_kind(), |
| receiver->GetElementsKind())) { |
| return isolate()->stub_cache()->ComputeKeyedLoadElement(receiver_map); |
| } |
| |
| ASSERT(state() != GENERIC); |
| |
| // Determine the list of receiver maps that this call site has seen, |
| // adding the map that was just encountered. |
| if (!AddOneReceiverMapIfMissing(&target_receiver_maps, receiver_map)) { |
| // If the miss wasn't due to an unseen map, a polymorphic stub |
| // won't help, use the generic stub. |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "same map added twice"); |
| return generic_stub(); |
| } |
| |
| // If the maximum number of receiver maps has been exceeded, use the generic |
| // version of the IC. |
| if (target_receiver_maps.length() > kMaxKeyedPolymorphism) { |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "max polymorph exceeded"); |
| return generic_stub(); |
| } |
| |
| return isolate()->stub_cache()->ComputeLoadElementPolymorphic( |
| &target_receiver_maps); |
| } |
| |
| |
| MaybeObject* KeyedLoadIC::Load(Handle<Object> object, Handle<Object> key) { |
| if (MigrateDeprecated(object)) { |
| Handle<Object> result = Runtime::GetObjectProperty(isolate(), object, key); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| MaybeObject* maybe_object = NULL; |
| Handle<Code> stub = generic_stub(); |
| |
| // Check for non-string values that can be converted into an |
| // internalized string directly or is representable as a smi. |
| key = TryConvertKey(key, isolate()); |
| |
| if (key->IsInternalizedString()) { |
| maybe_object = LoadIC::Load(object, Handle<String>::cast(key)); |
| if (maybe_object->IsFailure()) return maybe_object; |
| } else if (FLAG_use_ic && !object->IsAccessCheckNeeded()) { |
| if (object->IsString() && key->IsNumber()) { |
| if (state() == UNINITIALIZED) stub = string_stub(); |
| } else if (object->IsJSObject()) { |
| Handle<JSObject> receiver = Handle<JSObject>::cast(object); |
| if (receiver->elements()->map() == |
| isolate()->heap()->sloppy_arguments_elements_map()) { |
| stub = sloppy_arguments_stub(); |
| } else if (receiver->HasIndexedInterceptor()) { |
| stub = indexed_interceptor_stub(); |
| } else if (!key->ToSmi()->IsFailure() && |
| (!target().is_identical_to(sloppy_arguments_stub()))) { |
| stub = LoadElementStub(receiver); |
| } |
| } |
| } |
| |
| if (!is_target_set()) { |
| if (*stub == *generic_stub()) { |
| TRACE_GENERIC_IC(isolate(), "KeyedLoadIC", "set generic"); |
| } |
| set_target(*stub); |
| TRACE_IC("LoadIC", key); |
| } |
| |
| if (maybe_object != NULL) return maybe_object; |
| Handle<Object> result = Runtime::GetObjectProperty(isolate(), object, key); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| |
| static bool LookupForWrite(Handle<JSObject> receiver, |
| Handle<String> name, |
| Handle<Object> value, |
| LookupResult* lookup, |
| IC* ic) { |
| Handle<JSObject> holder = receiver; |
| receiver->Lookup(*name, lookup); |
| if (lookup->IsFound()) { |
| if (lookup->IsInterceptor() && !HasInterceptorSetter(lookup->holder())) { |
| receiver->LocalLookupRealNamedProperty(*name, lookup); |
| if (!lookup->IsFound()) return false; |
| } |
| |
| if (lookup->IsReadOnly() || !lookup->IsCacheable()) return false; |
| if (lookup->holder() == *receiver) return lookup->CanHoldValue(value); |
| if (lookup->IsPropertyCallbacks()) return true; |
| // JSGlobalProxy either stores on the global object in the prototype, or |
| // goes into the runtime if access checks are needed, so this is always |
| // safe. |
| if (receiver->IsJSGlobalProxy()) { |
| return lookup->holder() == receiver->GetPrototype(); |
| } |
| // Currently normal holders in the prototype chain are not supported. They |
| // would require a runtime positive lookup and verification that the details |
| // have not changed. |
| if (lookup->IsInterceptor() || lookup->IsNormal()) return false; |
| holder = Handle<JSObject>(lookup->holder(), lookup->isolate()); |
| } |
| |
| // While normally LookupTransition gets passed the receiver, in this case we |
| // pass the holder of the property that we overwrite. This keeps the holder in |
| // the LookupResult intact so we can later use it to generate a prototype |
| // chain check. This avoids a double lookup, but requires us to pass in the |
| // receiver when trying to fetch extra information from the transition. |
| receiver->map()->LookupTransition(*holder, *name, lookup); |
| if (!lookup->IsTransition()) return false; |
| PropertyDetails target_details = lookup->GetTransitionDetails(); |
| if (target_details.IsReadOnly()) return false; |
| |
| // If the value that's being stored does not fit in the field that the |
| // instance would transition to, create a new transition that fits the value. |
| // This has to be done before generating the IC, since that IC will embed the |
| // transition target. |
| // Ensure the instance and its map were migrated before trying to update the |
| // transition target. |
| ASSERT(!receiver->map()->is_deprecated()); |
| if (!value->FitsRepresentation(target_details.representation())) { |
| Handle<Map> target(lookup->GetTransitionTarget()); |
| Map::GeneralizeRepresentation( |
| target, target->LastAdded(), |
| value->OptimalRepresentation(), FORCE_FIELD); |
| // Lookup the transition again since the transition tree may have changed |
| // entirely by the migration above. |
| receiver->map()->LookupTransition(*holder, *name, lookup); |
| if (!lookup->IsTransition()) return false; |
| ic->MarkMonomorphicPrototypeFailure(); |
| } |
| return true; |
| } |
| |
| |
| MaybeObject* StoreIC::Store(Handle<Object> object, |
| Handle<String> name, |
| Handle<Object> value, |
| JSReceiver::StoreFromKeyed store_mode) { |
| if (MigrateDeprecated(object) || object->IsJSProxy()) { |
| Handle<Object> result = JSReceiver::SetProperty( |
| Handle<JSReceiver>::cast(object), name, value, NONE, strict_mode()); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| // If the object is undefined or null it's illegal to try to set any |
| // properties on it; throw a TypeError in that case. |
| if (object->IsUndefined() || object->IsNull()) { |
| return TypeError("non_object_property_store", object, name); |
| } |
| |
| // The length property of string values is read-only. Throw in strict mode. |
| if (strict_mode() == STRICT && object->IsString() && |
| name->Equals(isolate()->heap()->length_string())) { |
| return TypeError("strict_read_only_property", object, name); |
| } |
| |
| // Ignore other stores where the receiver is not a JSObject. |
| // TODO(1475): Must check prototype chains of object wrappers. |
| if (!object->IsJSObject()) return *value; |
| |
| Handle<JSObject> receiver = Handle<JSObject>::cast(object); |
| |
| // Check if the given name is an array index. |
| uint32_t index; |
| if (name->AsArrayIndex(&index)) { |
| Handle<Object> result = |
| JSObject::SetElement(receiver, index, value, NONE, strict_mode()); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *value; |
| } |
| |
| // Observed objects are always modified through the runtime. |
| if (receiver->map()->is_observed()) { |
| Handle<Object> result = JSReceiver::SetProperty( |
| receiver, name, value, NONE, strict_mode(), store_mode); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| LookupResult lookup(isolate()); |
| bool can_store = LookupForWrite(receiver, name, value, &lookup, this); |
| if (!can_store && |
| strict_mode() == STRICT && |
| !(lookup.IsProperty() && lookup.IsReadOnly()) && |
| object->IsGlobalObject()) { |
| // Strict mode doesn't allow setting non-existent global property. |
| return ReferenceError("not_defined", name); |
| } |
| if (FLAG_use_ic) { |
| if (state() == UNINITIALIZED) { |
| Handle<Code> stub = pre_monomorphic_stub(); |
| set_target(*stub); |
| TRACE_IC("StoreIC", name); |
| } else if (can_store) { |
| UpdateCaches(&lookup, receiver, name, value); |
| } else if (!name->IsCacheable(isolate()) || |
| lookup.IsNormal() || |
| (lookup.IsField() && lookup.CanHoldValue(value))) { |
| Handle<Code> stub = generic_stub(); |
| set_target(*stub); |
| } |
| } |
| |
| // Set the property. |
| Handle<Object> result = JSReceiver::SetProperty( |
| receiver, name, value, NONE, strict_mode(), store_mode); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| |
| Handle<Code> StoreIC::initialize_stub(Isolate* isolate, |
| StrictMode strict_mode) { |
| ExtraICState extra_state = ComputeExtraICState(strict_mode); |
| Handle<Code> ic = isolate->stub_cache()->ComputeStore( |
| UNINITIALIZED, extra_state); |
| return ic; |
| } |
| |
| |
| Handle<Code> StoreIC::megamorphic_stub() { |
| return isolate()->stub_cache()->ComputeStore(MEGAMORPHIC, extra_ic_state()); |
| } |
| |
| |
| Handle<Code> StoreIC::generic_stub() const { |
| return isolate()->stub_cache()->ComputeStore(GENERIC, extra_ic_state()); |
| } |
| |
| |
| Handle<Code> StoreIC::pre_monomorphic_stub(Isolate* isolate, |
| StrictMode strict_mode) { |
| ExtraICState state = ComputeExtraICState(strict_mode); |
| return isolate->stub_cache()->ComputeStore(PREMONOMORPHIC, state); |
| } |
| |
| |
| void StoreIC::UpdateCaches(LookupResult* lookup, |
| Handle<JSObject> receiver, |
| Handle<String> name, |
| Handle<Object> value) { |
| ASSERT(lookup->IsFound()); |
| |
| // These are not cacheable, so we never see such LookupResults here. |
| ASSERT(!lookup->IsHandler()); |
| |
| Handle<Code> code = ComputeHandler(lookup, receiver, name, value); |
| |
| PatchCache(CurrentTypeOf(receiver, isolate()), name, code); |
| TRACE_IC("StoreIC", name); |
| } |
| |
| |
| Handle<Code> StoreIC::CompileHandler(LookupResult* lookup, |
| Handle<Object> object, |
| Handle<String> name, |
| Handle<Object> value, |
| InlineCacheHolderFlag cache_holder) { |
| if (object->IsAccessCheckNeeded()) return slow_stub(); |
| ASSERT(cache_holder == OWN_MAP); |
| // This is currently guaranteed by checks in StoreIC::Store. |
| Handle<JSObject> receiver = Handle<JSObject>::cast(object); |
| |
| Handle<JSObject> holder(lookup->holder()); |
| // Handlers do not use strict mode. |
| StoreStubCompiler compiler(isolate(), SLOPPY, kind()); |
| switch (lookup->type()) { |
| case FIELD: |
| return compiler.CompileStoreField(receiver, lookup, name); |
| case TRANSITION: { |
| // Explicitly pass in the receiver map since LookupForWrite may have |
| // stored something else than the receiver in the holder. |
| Handle<Map> transition(lookup->GetTransitionTarget()); |
| PropertyDetails details = transition->GetLastDescriptorDetails(); |
| |
| if (details.type() == CALLBACKS || details.attributes() != NONE) break; |
| |
| return compiler.CompileStoreTransition( |
| receiver, lookup, transition, name); |
| } |
| case NORMAL: |
| if (kind() == Code::KEYED_STORE_IC) break; |
| if (receiver->IsJSGlobalProxy() || receiver->IsGlobalObject()) { |
| // The stub generated for the global object picks the value directly |
| // from the property cell. So the property must be directly on the |
| // global object. |
| Handle<GlobalObject> global = receiver->IsJSGlobalProxy() |
| ? handle(GlobalObject::cast(receiver->GetPrototype())) |
| : Handle<GlobalObject>::cast(receiver); |
| Handle<PropertyCell> cell(global->GetPropertyCell(lookup), isolate()); |
| Handle<HeapType> union_type = PropertyCell::UpdatedType(cell, value); |
| StoreGlobalStub stub( |
| union_type->IsConstant(), receiver->IsJSGlobalProxy()); |
| Handle<Code> code = stub.GetCodeCopyFromTemplate( |
| isolate(), global, cell); |
| // TODO(verwaest): Move caching of these NORMAL stubs outside as well. |
| HeapObject::UpdateMapCodeCache(receiver, name, code); |
| return code; |
| } |
| ASSERT(holder.is_identical_to(receiver)); |
| return isolate()->builtins()->StoreIC_Normal(); |
| case CALLBACKS: { |
| Handle<Object> callback(lookup->GetCallbackObject(), isolate()); |
| if (callback->IsExecutableAccessorInfo()) { |
| Handle<ExecutableAccessorInfo> info = |
| Handle<ExecutableAccessorInfo>::cast(callback); |
| if (v8::ToCData<Address>(info->setter()) == 0) break; |
| if (!holder->HasFastProperties()) break; |
| if (!info->IsCompatibleReceiver(*receiver)) break; |
| return compiler.CompileStoreCallback(receiver, holder, name, info); |
| } else if (callback->IsAccessorPair()) { |
| Handle<Object> setter( |
| Handle<AccessorPair>::cast(callback)->setter(), isolate()); |
| if (!setter->IsJSFunction()) break; |
| if (holder->IsGlobalObject()) break; |
| if (!holder->HasFastProperties()) break; |
| Handle<JSFunction> function = Handle<JSFunction>::cast(setter); |
| CallOptimization call_optimization(function); |
| if (call_optimization.is_simple_api_call() && |
| call_optimization.IsCompatibleReceiver(receiver, holder)) { |
| return compiler.CompileStoreCallback( |
| receiver, holder, name, call_optimization); |
| } |
| return compiler.CompileStoreViaSetter( |
| receiver, holder, name, Handle<JSFunction>::cast(setter)); |
| } |
| // TODO(dcarney): Handle correctly. |
| if (callback->IsDeclaredAccessorInfo()) break; |
| ASSERT(callback->IsForeign()); |
| |
| // Use specialized code for setting the length of arrays with fast |
| // properties. Slow properties might indicate redefinition of the length |
| // property. |
| if (receiver->IsJSArray() && |
| name->Equals(isolate()->heap()->length_string()) && |
| Handle<JSArray>::cast(receiver)->AllowsSetElementsLength() && |
| receiver->HasFastProperties()) { |
| return compiler.CompileStoreArrayLength(receiver, lookup, name); |
| } |
| |
| // No IC support for old-style native accessors. |
| break; |
| } |
| case INTERCEPTOR: |
| if (kind() == Code::KEYED_STORE_IC) break; |
| ASSERT(HasInterceptorSetter(*holder)); |
| return compiler.CompileStoreInterceptor(receiver, name); |
| case CONSTANT: |
| break; |
| case NONEXISTENT: |
| case HANDLER: |
| UNREACHABLE(); |
| break; |
| } |
| return slow_stub(); |
| } |
| |
| |
| Handle<Code> KeyedStoreIC::StoreElementStub(Handle<JSObject> receiver, |
| KeyedAccessStoreMode store_mode) { |
| // Don't handle megamorphic property accesses for INTERCEPTORS or CALLBACKS |
| // via megamorphic stubs, since they don't have a map in their relocation info |
| // and so the stubs can't be harvested for the object needed for a map check. |
| if (target()->type() != Code::NORMAL) { |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "non-NORMAL target type"); |
| return generic_stub(); |
| } |
| |
| Handle<Map> receiver_map(receiver->map(), isolate()); |
| if (state() == UNINITIALIZED || state() == PREMONOMORPHIC) { |
| // Optimistically assume that ICs that haven't reached the MONOMORPHIC state |
| // yet will do so and stay there. |
| Handle<Map> monomorphic_map = ComputeTransitionedMap(receiver, store_mode); |
| store_mode = GetNonTransitioningStoreMode(store_mode); |
| return isolate()->stub_cache()->ComputeKeyedStoreElement( |
| monomorphic_map, strict_mode(), store_mode); |
| } |
| |
| MapHandleList target_receiver_maps; |
| target()->FindAllMaps(&target_receiver_maps); |
| if (target_receiver_maps.length() == 0) { |
| // In the case that there is a non-map-specific IC is installed (e.g. keyed |
| // stores into properties in dictionary mode), then there will be not |
| // receiver maps in the target. |
| return generic_stub(); |
| } |
| |
| // There are several special cases where an IC that is MONOMORPHIC can still |
| // transition to a different GetNonTransitioningStoreMode IC that handles a |
| // superset of the original IC. Handle those here if the receiver map hasn't |
| // changed or it has transitioned to a more general kind. |
| KeyedAccessStoreMode old_store_mode = |
| KeyedStoreIC::GetKeyedAccessStoreMode(target()->extra_ic_state()); |
| Handle<Map> previous_receiver_map = target_receiver_maps.at(0); |
| if (state() == MONOMORPHIC) { |
| Handle<Map> transitioned_receiver_map = receiver_map; |
| if (IsTransitionStoreMode(store_mode)) { |
| transitioned_receiver_map = ComputeTransitionedMap(receiver, store_mode); |
| } |
| if ((receiver_map.is_identical_to(previous_receiver_map) && |
| IsTransitionStoreMode(store_mode)) || |
| IsTransitionOfMonomorphicTarget(*previous_receiver_map, |
| *transitioned_receiver_map)) { |
| // If the "old" and "new" maps are in the same elements map family, or |
| // if they at least come from the same origin for a transitioning store, |
| // stay MONOMORPHIC and use the map for the most generic ElementsKind. |
| store_mode = GetNonTransitioningStoreMode(store_mode); |
| return isolate()->stub_cache()->ComputeKeyedStoreElement( |
| transitioned_receiver_map, strict_mode(), store_mode); |
| } else if (*previous_receiver_map == receiver->map() && |
| old_store_mode == STANDARD_STORE && |
| (store_mode == STORE_AND_GROW_NO_TRANSITION || |
| store_mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS || |
| store_mode == STORE_NO_TRANSITION_HANDLE_COW)) { |
| // A "normal" IC that handles stores can switch to a version that can |
| // grow at the end of the array, handle OOB accesses or copy COW arrays |
| // and still stay MONOMORPHIC. |
| return isolate()->stub_cache()->ComputeKeyedStoreElement( |
| receiver_map, strict_mode(), store_mode); |
| } |
| } |
| |
| ASSERT(state() != GENERIC); |
| |
| bool map_added = |
| AddOneReceiverMapIfMissing(&target_receiver_maps, receiver_map); |
| |
| if (IsTransitionStoreMode(store_mode)) { |
| Handle<Map> transitioned_receiver_map = |
| ComputeTransitionedMap(receiver, store_mode); |
| map_added |= AddOneReceiverMapIfMissing(&target_receiver_maps, |
| transitioned_receiver_map); |
| } |
| |
| if (!map_added) { |
| // If the miss wasn't due to an unseen map, a polymorphic stub |
| // won't help, use the generic stub. |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "same map added twice"); |
| return generic_stub(); |
| } |
| |
| // If the maximum number of receiver maps has been exceeded, use the generic |
| // version of the IC. |
| if (target_receiver_maps.length() > kMaxKeyedPolymorphism) { |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "max polymorph exceeded"); |
| return generic_stub(); |
| } |
| |
| // Make sure all polymorphic handlers have the same store mode, otherwise the |
| // generic stub must be used. |
| store_mode = GetNonTransitioningStoreMode(store_mode); |
| if (old_store_mode != STANDARD_STORE) { |
| if (store_mode == STANDARD_STORE) { |
| store_mode = old_store_mode; |
| } else if (store_mode != old_store_mode) { |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", "store mode mismatch"); |
| return generic_stub(); |
| } |
| } |
| |
| // If the store mode isn't the standard mode, make sure that all polymorphic |
| // receivers are either external arrays, or all "normal" arrays. Otherwise, |
| // use the generic stub. |
| if (store_mode != STANDARD_STORE) { |
| int external_arrays = 0; |
| for (int i = 0; i < target_receiver_maps.length(); ++i) { |
| if (target_receiver_maps[i]->has_external_array_elements() || |
| target_receiver_maps[i]->has_fixed_typed_array_elements()) { |
| external_arrays++; |
| } |
| } |
| if (external_arrays != 0 && |
| external_arrays != target_receiver_maps.length()) { |
| TRACE_GENERIC_IC(isolate(), "KeyedIC", |
| "unsupported combination of external and normal arrays"); |
| return generic_stub(); |
| } |
| } |
| |
| return isolate()->stub_cache()->ComputeStoreElementPolymorphic( |
| &target_receiver_maps, store_mode, strict_mode()); |
| } |
| |
| |
| Handle<Map> KeyedStoreIC::ComputeTransitionedMap( |
| Handle<JSObject> receiver, |
| KeyedAccessStoreMode store_mode) { |
| switch (store_mode) { |
| case STORE_TRANSITION_SMI_TO_OBJECT: |
| case STORE_TRANSITION_DOUBLE_TO_OBJECT: |
| case STORE_AND_GROW_TRANSITION_SMI_TO_OBJECT: |
| case STORE_AND_GROW_TRANSITION_DOUBLE_TO_OBJECT: |
| return JSObject::GetElementsTransitionMap(receiver, FAST_ELEMENTS); |
| case STORE_TRANSITION_SMI_TO_DOUBLE: |
| case STORE_AND_GROW_TRANSITION_SMI_TO_DOUBLE: |
| return JSObject::GetElementsTransitionMap(receiver, FAST_DOUBLE_ELEMENTS); |
| case STORE_TRANSITION_HOLEY_SMI_TO_OBJECT: |
| case STORE_TRANSITION_HOLEY_DOUBLE_TO_OBJECT: |
| case STORE_AND_GROW_TRANSITION_HOLEY_SMI_TO_OBJECT: |
| case STORE_AND_GROW_TRANSITION_HOLEY_DOUBLE_TO_OBJECT: |
| return JSObject::GetElementsTransitionMap(receiver, |
| FAST_HOLEY_ELEMENTS); |
| case STORE_TRANSITION_HOLEY_SMI_TO_DOUBLE: |
| case STORE_AND_GROW_TRANSITION_HOLEY_SMI_TO_DOUBLE: |
| return JSObject::GetElementsTransitionMap(receiver, |
| FAST_HOLEY_DOUBLE_ELEMENTS); |
| case STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS: |
| ASSERT(receiver->map()->has_external_array_elements()); |
| // Fall through |
| case STORE_NO_TRANSITION_HANDLE_COW: |
| case STANDARD_STORE: |
| case STORE_AND_GROW_NO_TRANSITION: |
| return Handle<Map>(receiver->map(), isolate()); |
| } |
| return Handle<Map>::null(); |
| } |
| |
| |
| bool IsOutOfBoundsAccess(Handle<JSObject> receiver, |
| int index) { |
| if (receiver->IsJSArray()) { |
| return JSArray::cast(*receiver)->length()->IsSmi() && |
| index >= Smi::cast(JSArray::cast(*receiver)->length())->value(); |
| } |
| return index >= receiver->elements()->length(); |
| } |
| |
| |
| KeyedAccessStoreMode KeyedStoreIC::GetStoreMode(Handle<JSObject> receiver, |
| Handle<Object> key, |
| Handle<Object> value) { |
| ASSERT(!key->ToSmi()->IsFailure()); |
| Smi* smi_key = NULL; |
| key->ToSmi()->To(&smi_key); |
| int index = smi_key->value(); |
| bool oob_access = IsOutOfBoundsAccess(receiver, index); |
| // Don't consider this a growing store if the store would send the receiver to |
| // dictionary mode. |
| bool allow_growth = receiver->IsJSArray() && oob_access && |
| !receiver->WouldConvertToSlowElements(key); |
| if (allow_growth) { |
| // Handle growing array in stub if necessary. |
| if (receiver->HasFastSmiElements()) { |
| if (value->IsHeapNumber()) { |
| if (receiver->HasFastHoleyElements()) { |
| return STORE_AND_GROW_TRANSITION_HOLEY_SMI_TO_DOUBLE; |
| } else { |
| return STORE_AND_GROW_TRANSITION_SMI_TO_DOUBLE; |
| } |
| } |
| if (value->IsHeapObject()) { |
| if (receiver->HasFastHoleyElements()) { |
| return STORE_AND_GROW_TRANSITION_HOLEY_SMI_TO_OBJECT; |
| } else { |
| return STORE_AND_GROW_TRANSITION_SMI_TO_OBJECT; |
| } |
| } |
| } else if (receiver->HasFastDoubleElements()) { |
| if (!value->IsSmi() && !value->IsHeapNumber()) { |
| if (receiver->HasFastHoleyElements()) { |
| return STORE_AND_GROW_TRANSITION_HOLEY_DOUBLE_TO_OBJECT; |
| } else { |
| return STORE_AND_GROW_TRANSITION_DOUBLE_TO_OBJECT; |
| } |
| } |
| } |
| return STORE_AND_GROW_NO_TRANSITION; |
| } else { |
| // Handle only in-bounds elements accesses. |
| if (receiver->HasFastSmiElements()) { |
| if (value->IsHeapNumber()) { |
| if (receiver->HasFastHoleyElements()) { |
| return STORE_TRANSITION_HOLEY_SMI_TO_DOUBLE; |
| } else { |
| return STORE_TRANSITION_SMI_TO_DOUBLE; |
| } |
| } else if (value->IsHeapObject()) { |
| if (receiver->HasFastHoleyElements()) { |
| return STORE_TRANSITION_HOLEY_SMI_TO_OBJECT; |
| } else { |
| return STORE_TRANSITION_SMI_TO_OBJECT; |
| } |
| } |
| } else if (receiver->HasFastDoubleElements()) { |
| if (!value->IsSmi() && !value->IsHeapNumber()) { |
| if (receiver->HasFastHoleyElements()) { |
| return STORE_TRANSITION_HOLEY_DOUBLE_TO_OBJECT; |
| } else { |
| return STORE_TRANSITION_DOUBLE_TO_OBJECT; |
| } |
| } |
| } |
| if (!FLAG_trace_external_array_abuse && |
| receiver->map()->has_external_array_elements() && oob_access) { |
| return STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS; |
| } |
| Heap* heap = receiver->GetHeap(); |
| if (receiver->elements()->map() == heap->fixed_cow_array_map()) { |
| return STORE_NO_TRANSITION_HANDLE_COW; |
| } else { |
| return STANDARD_STORE; |
| } |
| } |
| } |
| |
| |
| MaybeObject* KeyedStoreIC::Store(Handle<Object> object, |
| Handle<Object> key, |
| Handle<Object> value) { |
| if (MigrateDeprecated(object)) { |
| Handle<Object> result = Runtime::SetObjectProperty(isolate(), object, |
| key, |
| value, |
| NONE, |
| strict_mode()); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| // Check for non-string values that can be converted into an |
| // internalized string directly or is representable as a smi. |
| key = TryConvertKey(key, isolate()); |
| |
| MaybeObject* maybe_object = NULL; |
| Handle<Code> stub = generic_stub(); |
| |
| if (key->IsInternalizedString()) { |
| maybe_object = StoreIC::Store(object, |
| Handle<String>::cast(key), |
| value, |
| JSReceiver::MAY_BE_STORE_FROM_KEYED); |
| if (maybe_object->IsFailure()) return maybe_object; |
| } else { |
| bool use_ic = FLAG_use_ic && |
| !object->IsAccessCheckNeeded() && |
| !object->IsJSGlobalProxy() && |
| !(object->IsJSObject() && |
| JSObject::cast(*object)->map()->is_observed()); |
| if (use_ic && !object->IsSmi()) { |
| // Don't use ICs for maps of the objects in Array's prototype chain. We |
| // expect to be able to trap element sets to objects with those maps in |
| // the runtime to enable optimization of element hole access. |
| Handle<HeapObject> heap_object = Handle<HeapObject>::cast(object); |
| if (heap_object->map()->IsMapInArrayPrototypeChain()) use_ic = false; |
| } |
| |
| if (use_ic) { |
| ASSERT(!object->IsAccessCheckNeeded()); |
| |
| if (object->IsJSObject()) { |
| Handle<JSObject> receiver = Handle<JSObject>::cast(object); |
| bool key_is_smi_like = key->IsSmi() || !key->ToSmi()->IsFailure(); |
| if (receiver->elements()->map() == |
| isolate()->heap()->sloppy_arguments_elements_map()) { |
| if (strict_mode() == SLOPPY) { |
| stub = sloppy_arguments_stub(); |
| } |
| } else if (key_is_smi_like && |
| !(target().is_identical_to(sloppy_arguments_stub()))) { |
| // We should go generic if receiver isn't a dictionary, but our |
| // prototype chain does have dictionary elements. This ensures that |
| // other non-dictionary receivers in the polymorphic case benefit |
| // from fast path keyed stores. |
| if (!(receiver->map()->DictionaryElementsInPrototypeChainOnly())) { |
| KeyedAccessStoreMode store_mode = |
| GetStoreMode(receiver, key, value); |
| stub = StoreElementStub(receiver, store_mode); |
| } |
| } |
| } |
| } |
| } |
| |
| if (!is_target_set()) { |
| if (*stub == *generic_stub()) { |
| TRACE_GENERIC_IC(isolate(), "KeyedStoreIC", "set generic"); |
| } |
| ASSERT(!stub.is_null()); |
| set_target(*stub); |
| TRACE_IC("StoreIC", key); |
| } |
| |
| if (maybe_object) return maybe_object; |
| Handle<Object> result = Runtime::SetObjectProperty(isolate(), object, key, |
| value, |
| NONE, |
| strict_mode()); |
| RETURN_IF_EMPTY_HANDLE(isolate(), result); |
| return *result; |
| } |
| |
| |
| #undef TRACE_IC |
| |
| |
| // ---------------------------------------------------------------------------- |
| // Static IC stub generators. |
| // |
| |
| // Used from ic-<arch>.cc. |
| // Used from ic-<arch>.cc. |
| RUNTIME_FUNCTION(MaybeObject*, LoadIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 2); |
| LoadIC ic(IC::NO_EXTRA_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<String> key = args.at<String>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Load(receiver, key); |
| } |
| |
| |
| // Used from ic-<arch>.cc |
| RUNTIME_FUNCTION(MaybeObject*, KeyedLoadIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 2); |
| KeyedLoadIC ic(IC::NO_EXTRA_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<Object> key = args.at<Object>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Load(receiver, key); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, KeyedLoadIC_MissFromStubFailure) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 2); |
| KeyedLoadIC ic(IC::EXTRA_CALL_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<Object> key = args.at<Object>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Load(receiver, key); |
| } |
| |
| |
| // Used from ic-<arch>.cc. |
| RUNTIME_FUNCTION(MaybeObject*, StoreIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| StoreIC ic(IC::NO_EXTRA_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<String> key = args.at<String>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Store(receiver, key, args.at<Object>(2)); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, StoreIC_MissFromStubFailure) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| StoreIC ic(IC::EXTRA_CALL_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<String> key = args.at<String>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Store(receiver, key, args.at<Object>(2)); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, StoreIC_ArrayLength) { |
| HandleScope scope(isolate); |
| |
| ASSERT(args.length() == 2); |
| Handle<JSArray> receiver = args.at<JSArray>(0); |
| Handle<Object> len = args.at<Object>(1); |
| |
| // The generated code should filter out non-Smis before we get here. |
| ASSERT(len->IsSmi()); |
| |
| #ifdef DEBUG |
| // The length property has to be a writable callback property. |
| LookupResult debug_lookup(isolate); |
| receiver->LocalLookup(isolate->heap()->length_string(), &debug_lookup); |
| ASSERT(debug_lookup.IsPropertyCallbacks() && !debug_lookup.IsReadOnly()); |
| #endif |
| |
| RETURN_IF_EMPTY_HANDLE(isolate, |
| JSArray::SetElementsLength(receiver, len)); |
| return *len; |
| } |
| |
| |
| // Extend storage is called in a store inline cache when |
| // it is necessary to extend the properties array of a |
| // JSObject. |
| RUNTIME_FUNCTION(MaybeObject*, SharedStoreIC_ExtendStorage) { |
| SealHandleScope shs(isolate); |
| ASSERT(args.length() == 3); |
| |
| // Convert the parameters |
| JSObject* object = JSObject::cast(args[0]); |
| Map* transition = Map::cast(args[1]); |
| Object* value = args[2]; |
| |
| // Check the object has run out out property space. |
| ASSERT(object->HasFastProperties()); |
| ASSERT(object->map()->unused_property_fields() == 0); |
| |
| // Expand the properties array. |
| FixedArray* old_storage = object->properties(); |
| int new_unused = transition->unused_property_fields(); |
| int new_size = old_storage->length() + new_unused + 1; |
| Object* result; |
| MaybeObject* maybe_result = old_storage->CopySize(new_size); |
| if (!maybe_result->ToObject(&result)) return maybe_result; |
| |
| FixedArray* new_storage = FixedArray::cast(result); |
| |
| Object* to_store = value; |
| |
| DescriptorArray* descriptors = transition->instance_descriptors(); |
| PropertyDetails details = descriptors->GetDetails(transition->LastAdded()); |
| if (details.representation().IsDouble()) { |
| MaybeObject* maybe_storage = |
| isolate->heap()->AllocateHeapNumber(value->Number()); |
| if (!maybe_storage->To(&to_store)) return maybe_storage; |
| } |
| |
| new_storage->set(old_storage->length(), to_store); |
| |
| // Set the new property value and do the map transition. |
| object->set_properties(new_storage); |
| object->set_map(transition); |
| |
| // Return the stored value. |
| return value; |
| } |
| |
| |
| // Used from ic-<arch>.cc. |
| RUNTIME_FUNCTION(MaybeObject*, KeyedStoreIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| KeyedStoreIC ic(IC::NO_EXTRA_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<Object> key = args.at<Object>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Store(receiver, key, args.at<Object>(2)); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, KeyedStoreIC_MissFromStubFailure) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| KeyedStoreIC ic(IC::EXTRA_CALL_FRAME, isolate); |
| Handle<Object> receiver = args.at<Object>(0); |
| Handle<Object> key = args.at<Object>(1); |
| ic.UpdateState(receiver, key); |
| return ic.Store(receiver, key, args.at<Object>(2)); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, StoreIC_Slow) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| StoreIC ic(IC::NO_EXTRA_FRAME, isolate); |
| Handle<Object> object = args.at<Object>(0); |
| Handle<Object> key = args.at<Object>(1); |
| Handle<Object> value = args.at<Object>(2); |
| StrictMode strict_mode = ic.strict_mode(); |
| Handle<Object> result = Runtime::SetObjectProperty(isolate, object, key, |
| value, |
| NONE, |
| strict_mode); |
| RETURN_IF_EMPTY_HANDLE(isolate, result); |
| return *result; |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, KeyedStoreIC_Slow) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| KeyedStoreIC ic(IC::NO_EXTRA_FRAME, isolate); |
| Handle<Object> object = args.at<Object>(0); |
| Handle<Object> key = args.at<Object>(1); |
| Handle<Object> value = args.at<Object>(2); |
| StrictMode strict_mode = ic.strict_mode(); |
| Handle<Object> result = Runtime::SetObjectProperty(isolate, object, key, |
| value, |
| NONE, |
| strict_mode); |
| RETURN_IF_EMPTY_HANDLE(isolate, result); |
| return *result; |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, ElementsTransitionAndStoreIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 4); |
| KeyedStoreIC ic(IC::EXTRA_CALL_FRAME, isolate); |
| Handle<Object> value = args.at<Object>(0); |
| Handle<Map> map = args.at<Map>(1); |
| Handle<Object> key = args.at<Object>(2); |
| Handle<Object> object = args.at<Object>(3); |
| StrictMode strict_mode = ic.strict_mode(); |
| if (object->IsJSObject()) { |
| JSObject::TransitionElementsKind(Handle<JSObject>::cast(object), |
| map->elements_kind()); |
| } |
| Handle<Object> result = Runtime::SetObjectProperty(isolate, object, key, |
| value, |
| NONE, |
| strict_mode); |
| RETURN_IF_EMPTY_HANDLE(isolate, result); |
| return *result; |
| } |
| |
| |
| BinaryOpIC::State::State(ExtraICState extra_ic_state) { |
| // We don't deserialize the SSE2 Field, since this is only used to be able |
| // to include SSE2 as well as non-SSE2 versions in the snapshot. For code |
| // generation we always want it to reflect the current state. |
| op_ = static_cast<Token::Value>( |
| FIRST_TOKEN + OpField::decode(extra_ic_state)); |
| mode_ = OverwriteModeField::decode(extra_ic_state); |
| fixed_right_arg_ = Maybe<int>( |
| HasFixedRightArgField::decode(extra_ic_state), |
| 1 << FixedRightArgValueField::decode(extra_ic_state)); |
| left_kind_ = LeftKindField::decode(extra_ic_state); |
| if (fixed_right_arg_.has_value) { |
| right_kind_ = Smi::IsValid(fixed_right_arg_.value) ? SMI : INT32; |
| } else { |
| right_kind_ = RightKindField::decode(extra_ic_state); |
| } |
| result_kind_ = ResultKindField::decode(extra_ic_state); |
| ASSERT_LE(FIRST_TOKEN, op_); |
| ASSERT_LE(op_, LAST_TOKEN); |
| } |
| |
| |
| ExtraICState BinaryOpIC::State::GetExtraICState() const { |
| bool sse2 = (Max(result_kind_, Max(left_kind_, right_kind_)) > SMI && |
| CpuFeatures::IsSafeForSnapshot(SSE2)); |
| ExtraICState extra_ic_state = |
| SSE2Field::encode(sse2) | |
| OpField::encode(op_ - FIRST_TOKEN) | |
| OverwriteModeField::encode(mode_) | |
| LeftKindField::encode(left_kind_) | |
| ResultKindField::encode(result_kind_) | |
| HasFixedRightArgField::encode(fixed_right_arg_.has_value); |
| if (fixed_right_arg_.has_value) { |
| extra_ic_state = FixedRightArgValueField::update( |
| extra_ic_state, WhichPowerOf2(fixed_right_arg_.value)); |
| } else { |
| extra_ic_state = RightKindField::update(extra_ic_state, right_kind_); |
| } |
| return extra_ic_state; |
| } |
| |
| |
| // static |
| void BinaryOpIC::State::GenerateAheadOfTime( |
| Isolate* isolate, void (*Generate)(Isolate*, const State&)) { |
| // TODO(olivf) We should investigate why adding stubs to the snapshot is so |
| // expensive at runtime. When solved we should be able to add most binops to |
| // the snapshot instead of hand-picking them. |
| // Generated list of commonly used stubs |
| #define GENERATE(op, left_kind, right_kind, result_kind, mode) \ |
| do { \ |
| State state(op, mode); \ |
| state.left_kind_ = left_kind; \ |
| state.fixed_right_arg_.has_value = false; \ |
| state.right_kind_ = right_kind; \ |
| state.result_kind_ = result_kind; \ |
| Generate(isolate, state); \ |
| } while (false) |
| GENERATE(Token::ADD, INT32, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::ADD, INT32, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, INT32, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, INT32, INT32, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, INT32, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, INT32, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, INT32, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::ADD, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::ADD, INT32, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::ADD, NUMBER, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, NUMBER, INT32, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::ADD, NUMBER, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::ADD, SMI, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::ADD, SMI, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, SMI, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, SMI, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::ADD, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::ADD, SMI, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::ADD, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, INT32, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, INT32, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_AND, INT32, INT32, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, INT32, INT32, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, INT32, INT32, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, INT32, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, INT32, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_AND, INT32, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, NUMBER, INT32, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, NUMBER, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, NUMBER, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, SMI, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, SMI, INT32, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, SMI, NUMBER, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_AND, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_AND, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_AND, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, INT32, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, INT32, INT32, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, INT32, INT32, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_OR, INT32, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, INT32, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_OR, INT32, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, NUMBER, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_OR, NUMBER, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, SMI, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, SMI, INT32, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, SMI, INT32, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_OR, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_OR, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_XOR, INT32, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, INT32, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_XOR, INT32, INT32, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_XOR, INT32, INT32, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, INT32, INT32, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_XOR, INT32, NUMBER, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, INT32, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_XOR, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::BIT_XOR, NUMBER, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, NUMBER, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, NUMBER, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, SMI, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, SMI, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_XOR, SMI, INT32, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_XOR, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::BIT_XOR, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::BIT_XOR, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::DIV, INT32, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::DIV, INT32, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, INT32, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, INT32, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::DIV, INT32, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, NUMBER, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::DIV, NUMBER, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, SMI, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::DIV, SMI, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, SMI, INT32, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, SMI, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::DIV, SMI, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::DIV, SMI, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, SMI, SMI, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::DIV, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::DIV, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::DIV, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::MOD, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MOD, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::MOD, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, INT32, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::MUL, INT32, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, INT32, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, INT32, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::MUL, INT32, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, INT32, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, NUMBER, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, NUMBER, INT32, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::MUL, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, NUMBER, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::MUL, SMI, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::MUL, SMI, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, SMI, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, SMI, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::MUL, SMI, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::MUL, SMI, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::MUL, SMI, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::MUL, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::MUL, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SAR, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::SAR, INT32, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SAR, INT32, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SAR, NUMBER, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SAR, NUMBER, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SAR, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::SAR, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SHL, INT32, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::SHL, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::SHL, INT32, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SHL, INT32, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SHL, NUMBER, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SHL, SMI, SMI, INT32, NO_OVERWRITE); |
| GENERATE(Token::SHL, SMI, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::SHL, SMI, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::SHL, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SHL, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::SHL, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SHR, INT32, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SHR, INT32, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::SHR, INT32, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SHR, NUMBER, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SHR, NUMBER, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::SHR, NUMBER, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::SHR, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SHR, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::SHR, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| GENERATE(Token::SUB, INT32, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::SUB, INT32, INT32, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, INT32, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::SUB, INT32, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::SUB, INT32, SMI, INT32, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, INT32, SMI, INT32, OVERWRITE_RIGHT); |
| GENERATE(Token::SUB, NUMBER, INT32, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::SUB, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::SUB, NUMBER, SMI, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::SUB, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::SUB, SMI, INT32, INT32, NO_OVERWRITE); |
| GENERATE(Token::SUB, SMI, NUMBER, NUMBER, NO_OVERWRITE); |
| GENERATE(Token::SUB, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); |
| GENERATE(Token::SUB, SMI, SMI, SMI, NO_OVERWRITE); |
| GENERATE(Token::SUB, SMI, SMI, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::SUB, SMI, SMI, SMI, OVERWRITE_RIGHT); |
| #undef GENERATE |
| #define GENERATE(op, left_kind, fixed_right_arg_value, result_kind, mode) \ |
| do { \ |
| State state(op, mode); \ |
| state.left_kind_ = left_kind; \ |
| state.fixed_right_arg_.has_value = true; \ |
| state.fixed_right_arg_.value = fixed_right_arg_value; \ |
| state.right_kind_ = SMI; \ |
| state.result_kind_ = result_kind; \ |
| Generate(isolate, state); \ |
| } while (false) |
| GENERATE(Token::MOD, SMI, 2, SMI, NO_OVERWRITE); |
| GENERATE(Token::MOD, SMI, 4, SMI, NO_OVERWRITE); |
| GENERATE(Token::MOD, SMI, 4, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::MOD, SMI, 8, SMI, NO_OVERWRITE); |
| GENERATE(Token::MOD, SMI, 16, SMI, OVERWRITE_LEFT); |
| GENERATE(Token::MOD, SMI, 32, SMI, NO_OVERWRITE); |
| GENERATE(Token::MOD, SMI, 2048, SMI, NO_OVERWRITE); |
| #undef GENERATE |
| } |
| |
| |
| Type* BinaryOpIC::State::GetResultType(Zone* zone) const { |
| Kind result_kind = result_kind_; |
| if (HasSideEffects()) { |
| result_kind = NONE; |
| } else if (result_kind == GENERIC && op_ == Token::ADD) { |
| return Type::Union(Type::Number(zone), Type::String(zone), zone); |
| } else if (result_kind == NUMBER && op_ == Token::SHR) { |
| return Type::Unsigned32(zone); |
| } |
| ASSERT_NE(GENERIC, result_kind); |
| return KindToType(result_kind, zone); |
| } |
| |
| |
| void BinaryOpIC::State::Print(StringStream* stream) const { |
| stream->Add("(%s", Token::Name(op_)); |
| if (mode_ == OVERWRITE_LEFT) stream->Add("_ReuseLeft"); |
| else if (mode_ == OVERWRITE_RIGHT) stream->Add("_ReuseRight"); |
| if (CouldCreateAllocationMementos()) stream->Add("_CreateAllocationMementos"); |
| stream->Add(":%s*", KindToString(left_kind_)); |
| if (fixed_right_arg_.has_value) { |
| stream->Add("%d", fixed_right_arg_.value); |
| } else { |
| stream->Add("%s", KindToString(right_kind_)); |
| } |
| stream->Add("->%s)", KindToString(result_kind_)); |
| } |
| |
| |
| void BinaryOpIC::State::Update(Handle<Object> left, |
| Handle<Object> right, |
| Handle<Object> result) { |
| ExtraICState old_extra_ic_state = GetExtraICState(); |
| |
| left_kind_ = UpdateKind(left, left_kind_); |
| right_kind_ = UpdateKind(right, right_kind_); |
| |
| int32_t fixed_right_arg_value = 0; |
| bool has_fixed_right_arg = |
| op_ == Token::MOD && |
| right->ToInt32(&fixed_right_arg_value) && |
| fixed_right_arg_value > 0 && |
| IsPowerOf2(fixed_right_arg_value) && |
| FixedRightArgValueField::is_valid(WhichPowerOf2(fixed_right_arg_value)) && |
| (left_kind_ == SMI || left_kind_ == INT32) && |
| (result_kind_ == NONE || !fixed_right_arg_.has_value); |
| fixed_right_arg_ = Maybe<int32_t>(has_fixed_right_arg, |
| fixed_right_arg_value); |
| |
| result_kind_ = UpdateKind(result, result_kind_); |
| |
| if (!Token::IsTruncatingBinaryOp(op_)) { |
| Kind input_kind = Max(left_kind_, right_kind_); |
| if (result_kind_ < input_kind && input_kind <= NUMBER) { |
| result_kind_ = input_kind; |
| } |
| } |
| |
| // We don't want to distinguish INT32 and NUMBER for string add (because |
| // NumberToString can't make use of this anyway). |
| if (left_kind_ == STRING && right_kind_ == INT32) { |
| ASSERT_EQ(STRING, result_kind_); |
| ASSERT_EQ(Token::ADD, op_); |
| right_kind_ = NUMBER; |
| } else if (right_kind_ == STRING && left_kind_ == INT32) { |
| ASSERT_EQ(STRING, result_kind_); |
| ASSERT_EQ(Token::ADD, op_); |
| left_kind_ = NUMBER; |
| } |
| |
| // Reset overwrite mode unless we can actually make use of it, or may be able |
| // to make use of it at some point in the future. |
| if ((mode_ == OVERWRITE_LEFT && left_kind_ > NUMBER) || |
| (mode_ == OVERWRITE_RIGHT && right_kind_ > NUMBER) || |
| result_kind_ > NUMBER) { |
| mode_ = NO_OVERWRITE; |
| } |
| |
| if (old_extra_ic_state == GetExtraICState()) { |
| // Tagged operations can lead to non-truncating HChanges |
| if (left->IsUndefined() || left->IsBoolean()) { |
| left_kind_ = GENERIC; |
| } else if (right->IsUndefined() || right->IsBoolean()) { |
| right_kind_ = GENERIC; |
| } else { |
| // Since the X87 is too precise, we might bail out on numbers which |
| // actually would truncate with 64 bit precision. |
| ASSERT(!CpuFeatures::IsSupported(SSE2)); |
| ASSERT(result_kind_ < NUMBER); |
| result_kind_ = NUMBER; |
| } |
| } |
| } |
| |
| |
| BinaryOpIC::State::Kind BinaryOpIC::State::UpdateKind(Handle<Object> object, |
| Kind kind) const { |
| Kind new_kind = GENERIC; |
| bool is_truncating = Token::IsTruncatingBinaryOp(op()); |
| if (object->IsBoolean() && is_truncating) { |
| // Booleans will be automatically truncated by HChange. |
| new_kind = INT32; |
| } else if (object->IsUndefined()) { |
| // Undefined will be automatically truncated by HChange. |
| new_kind = is_truncating ? INT32 : NUMBER; |
| } else if (object->IsSmi()) { |
| new_kind = SMI; |
| } else if (object->IsHeapNumber()) { |
| double value = Handle<HeapNumber>::cast(object)->value(); |
| new_kind = IsInt32Double(value) ? INT32 : NUMBER; |
| } else if (object->IsString() && op() == Token::ADD) { |
| new_kind = STRING; |
| } |
| if (new_kind == INT32 && SmiValuesAre32Bits()) { |
| new_kind = NUMBER; |
| } |
| if (kind != NONE && |
| ((new_kind <= NUMBER && kind > NUMBER) || |
| (new_kind > NUMBER && kind <= NUMBER))) { |
| new_kind = GENERIC; |
| } |
| return Max(kind, new_kind); |
| } |
| |
| |
| // static |
| const char* BinaryOpIC::State::KindToString(Kind kind) { |
| switch (kind) { |
| case NONE: return "None"; |
| case SMI: return "Smi"; |
| case INT32: return "Int32"; |
| case NUMBER: return "Number"; |
| case STRING: return "String"; |
| case GENERIC: return "Generic"; |
| } |
| UNREACHABLE(); |
| return NULL; |
| } |
| |
| |
| // static |
| Type* BinaryOpIC::State::KindToType(Kind kind, Zone* zone) { |
| switch (kind) { |
| case NONE: return Type::None(zone); |
| case SMI: return Type::SignedSmall(zone); |
| case INT32: return Type::Signed32(zone); |
| case NUMBER: return Type::Number(zone); |
| case STRING: return Type::String(zone); |
| case GENERIC: return Type::Any(zone); |
| } |
| UNREACHABLE(); |
| return NULL; |
| } |
| |
| |
| MaybeObject* BinaryOpIC::Transition(Handle<AllocationSite> allocation_site, |
| Handle<Object> left, |
| Handle<Object> right) { |
| State state(target()->extra_ic_state()); |
| |
| // Compute the actual result using the builtin for the binary operation. |
| Object* builtin = isolate()->js_builtins_object()->javascript_builtin( |
| TokenToJSBuiltin(state.op())); |
| Handle<JSFunction> function = handle(JSFunction::cast(builtin), isolate()); |
| bool caught_exception; |
| Handle<Object> result = Execution::Call( |
| isolate(), function, left, 1, &right, &caught_exception); |
| if (caught_exception) return Failure::Exception(); |
| |
| // Execution::Call can execute arbitrary JavaScript, hence potentially |
| // update the state of this very IC, so we must update the stored state. |
| UpdateTarget(); |
| // Compute the new state. |
| State old_state(target()->extra_ic_state()); |
| state.Update(left, right, result); |
| |
| // Check if we have a string operation here. |
| Handle<Code> target; |
| if (!allocation_site.is_null() || state.ShouldCreateAllocationMementos()) { |
| // Setup the allocation site on-demand. |
| if (allocation_site.is_null()) { |
| allocation_site = isolate()->factory()->NewAllocationSite(); |
| } |
| |
| // Install the stub with an allocation site. |
| BinaryOpICWithAllocationSiteStub stub(state); |
| target = stub.GetCodeCopyFromTemplate(isolate(), allocation_site); |
| |
| // Sanity check the trampoline stub. |
| ASSERT_EQ(*allocation_site, target->FindFirstAllocationSite()); |
| } else { |
| // Install the generic stub. |
| BinaryOpICStub stub(state); |
| target = stub.GetCode(isolate()); |
| |
| // Sanity check the generic stub. |
| ASSERT_EQ(NULL, target->FindFirstAllocationSite()); |
| } |
| set_target(*target); |
| |
| if (FLAG_trace_ic) { |
| char buffer[150]; |
| NoAllocationStringAllocator allocator( |
| buffer, static_cast<unsigned>(sizeof(buffer))); |
| StringStream stream(&allocator); |
| stream.Add("[BinaryOpIC"); |
| old_state.Print(&stream); |
| stream.Add(" => "); |
| state.Print(&stream); |
| stream.Add(" @ %p <- ", static_cast<void*>(*target)); |
| stream.OutputToStdOut(); |
| JavaScriptFrame::PrintTop(isolate(), stdout, false, true); |
| if (!allocation_site.is_null()) { |
| PrintF(" using allocation site %p", static_cast<void*>(*allocation_site)); |
| } |
| PrintF("]\n"); |
| } |
| |
| // Patch the inlined smi code as necessary. |
| if (!old_state.UseInlinedSmiCode() && state.UseInlinedSmiCode()) { |
| PatchInlinedSmiCode(address(), ENABLE_INLINED_SMI_CHECK); |
| } else if (old_state.UseInlinedSmiCode() && !state.UseInlinedSmiCode()) { |
| PatchInlinedSmiCode(address(), DISABLE_INLINED_SMI_CHECK); |
| } |
| |
| return *result; |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, BinaryOpIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT_EQ(2, args.length()); |
| Handle<Object> left = args.at<Object>(BinaryOpICStub::kLeft); |
| Handle<Object> right = args.at<Object>(BinaryOpICStub::kRight); |
| BinaryOpIC ic(isolate); |
| return ic.Transition(Handle<AllocationSite>::null(), left, right); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, BinaryOpIC_MissWithAllocationSite) { |
| HandleScope scope(isolate); |
| ASSERT_EQ(3, args.length()); |
| Handle<AllocationSite> allocation_site = args.at<AllocationSite>( |
| BinaryOpWithAllocationSiteStub::kAllocationSite); |
| Handle<Object> left = args.at<Object>( |
| BinaryOpWithAllocationSiteStub::kLeft); |
| Handle<Object> right = args.at<Object>( |
| BinaryOpWithAllocationSiteStub::kRight); |
| BinaryOpIC ic(isolate); |
| return ic.Transition(allocation_site, left, right); |
| } |
| |
| |
| Code* CompareIC::GetRawUninitialized(Isolate* isolate, Token::Value op) { |
| ICCompareStub stub(op, UNINITIALIZED, UNINITIALIZED, UNINITIALIZED); |
| Code* code = NULL; |
| CHECK(stub.FindCodeInCache(&code, isolate)); |
| return code; |
| } |
| |
| |
| Handle<Code> CompareIC::GetUninitialized(Isolate* isolate, Token::Value op) { |
| ICCompareStub stub(op, UNINITIALIZED, UNINITIALIZED, UNINITIALIZED); |
| return stub.GetCode(isolate); |
| } |
| |
| |
| const char* CompareIC::GetStateName(State state) { |
| switch (state) { |
| case UNINITIALIZED: return "UNINITIALIZED"; |
| case SMI: return "SMI"; |
| case NUMBER: return "NUMBER"; |
| case INTERNALIZED_STRING: return "INTERNALIZED_STRING"; |
| case STRING: return "STRING"; |
| case UNIQUE_NAME: return "UNIQUE_NAME"; |
| case OBJECT: return "OBJECT"; |
| case KNOWN_OBJECT: return "KNOWN_OBJECT"; |
| case GENERIC: return "GENERIC"; |
| } |
| UNREACHABLE(); |
| return NULL; |
| } |
| |
| |
| Type* CompareIC::StateToType( |
| Zone* zone, |
| CompareIC::State state, |
| Handle<Map> map) { |
| switch (state) { |
| case CompareIC::UNINITIALIZED: return Type::None(zone); |
| case CompareIC::SMI: return Type::SignedSmall(zone); |
| case CompareIC::NUMBER: return Type::Number(zone); |
| case CompareIC::STRING: return Type::String(zone); |
| case CompareIC::INTERNALIZED_STRING: return Type::InternalizedString(zone); |
| case CompareIC::UNIQUE_NAME: return Type::UniqueName(zone); |
| case CompareIC::OBJECT: return Type::Receiver(zone); |
| case CompareIC::KNOWN_OBJECT: |
| return map.is_null() ? Type::Receiver(zone) : Type::Class(map, zone); |
| case CompareIC::GENERIC: return Type::Any(zone); |
| } |
| UNREACHABLE(); |
| return NULL; |
| } |
| |
| |
| void CompareIC::StubInfoToType(int stub_minor_key, |
| Type** left_type, |
| Type** right_type, |
| Type** overall_type, |
| Handle<Map> map, |
| Zone* zone) { |
| State left_state, right_state, handler_state; |
| ICCompareStub::DecodeMinorKey(stub_minor_key, &left_state, &right_state, |
| &handler_state, NULL); |
| *left_type = StateToType(zone, left_state); |
| *right_type = StateToType(zone, right_state); |
| *overall_type = StateToType(zone, handler_state, map); |
| } |
| |
| |
| CompareIC::State CompareIC::NewInputState(State old_state, |
| Handle<Object> value) { |
| switch (old_state) { |
| case UNINITIALIZED: |
| if (value->IsSmi()) return SMI; |
| if (value->IsHeapNumber()) return NUMBER; |
| if (value->IsInternalizedString()) return INTERNALIZED_STRING; |
| if (value->IsString()) return STRING; |
| if (value->IsSymbol()) return UNIQUE_NAME; |
| if (value->IsJSObject()) return OBJECT; |
| break; |
| case SMI: |
| if (value->IsSmi()) return SMI; |
| if (value->IsHeapNumber()) return NUMBER; |
| break; |
| case NUMBER: |
| if (value->IsNumber()) return NUMBER; |
| break; |
| case INTERNALIZED_STRING: |
| if (value->IsInternalizedString()) return INTERNALIZED_STRING; |
| if (value->IsString()) return STRING; |
| if (value->IsSymbol()) return UNIQUE_NAME; |
| break; |
| case STRING: |
| if (value->IsString()) return STRING; |
| break; |
| case UNIQUE_NAME: |
| if (value->IsUniqueName()) return UNIQUE_NAME; |
| break; |
| case OBJECT: |
| if (value->IsJSObject()) return OBJECT; |
| break; |
| case GENERIC: |
| break; |
| case KNOWN_OBJECT: |
| UNREACHABLE(); |
| break; |
| } |
| return GENERIC; |
| } |
| |
| |
| CompareIC::State CompareIC::TargetState(State old_state, |
| State old_left, |
| State old_right, |
| bool has_inlined_smi_code, |
| Handle<Object> x, |
| Handle<Object> y) { |
| switch (old_state) { |
| case UNINITIALIZED: |
| if (x->IsSmi() && y->IsSmi()) return SMI; |
| if (x->IsNumber() && y->IsNumber()) return NUMBER; |
| if (Token::IsOrderedRelationalCompareOp(op_)) { |
| // Ordered comparisons treat undefined as NaN, so the |
| // NUMBER stub will do the right thing. |
| if ((x->IsNumber() && y->IsUndefined()) || |
| (y->IsNumber() && x->IsUndefined())) { |
| return NUMBER; |
| } |
| } |
| if (x->IsInternalizedString() && y->IsInternalizedString()) { |
| // We compare internalized strings as plain ones if we need to determine |
| // the order in a non-equality compare. |
| return Token::IsEqualityOp(op_) ? INTERNALIZED_STRING : STRING; |
| } |
| if (x->IsString() && y->IsString()) return STRING; |
| if (!Token::IsEqualityOp(op_)) return GENERIC; |
| if (x->IsUniqueName() && y->IsUniqueName()) return UNIQUE_NAME; |
| if (x->IsJSObject() && y->IsJSObject()) { |
| if (Handle<JSObject>::cast(x)->map() == |
| Handle<JSObject>::cast(y)->map()) { |
| return KNOWN_OBJECT; |
| } else { |
| return OBJECT; |
| } |
| } |
| return GENERIC; |
| case SMI: |
| return x->IsNumber() && y->IsNumber() ? NUMBER : GENERIC; |
| case INTERNALIZED_STRING: |
| ASSERT(Token::IsEqualityOp(op_)); |
| if (x->IsString() && y->IsString()) return STRING; |
| if (x->IsUniqueName() && y->IsUniqueName()) return UNIQUE_NAME; |
| return GENERIC; |
| case NUMBER: |
| // If the failure was due to one side changing from smi to heap number, |
| // then keep the state (if other changed at the same time, we will get |
| // a second miss and then go to generic). |
| if (old_left == SMI && x->IsHeapNumber()) return NUMBER; |
| if (old_right == SMI && y->IsHeapNumber()) return NUMBER; |
| return GENERIC; |
| case KNOWN_OBJECT: |
| ASSERT(Token::IsEqualityOp(op_)); |
| if (x->IsJSObject() && y->IsJSObject()) return OBJECT; |
| return GENERIC; |
| case STRING: |
| case UNIQUE_NAME: |
| case OBJECT: |
| case GENERIC: |
| return GENERIC; |
| } |
| UNREACHABLE(); |
| return GENERIC; // Make the compiler happy. |
| } |
| |
| |
| Code* CompareIC::UpdateCaches(Handle<Object> x, Handle<Object> y) { |
| HandleScope scope(isolate()); |
| State previous_left, previous_right, previous_state; |
| ICCompareStub::DecodeMinorKey(target()->stub_info(), &previous_left, |
| &previous_right, &previous_state, NULL); |
| State new_left = NewInputState(previous_left, x); |
| State new_right = NewInputState(previous_right, y); |
| State state = TargetState(previous_state, previous_left, previous_right, |
| HasInlinedSmiCode(address()), x, y); |
| ICCompareStub stub(op_, new_left, new_right, state); |
| if (state == KNOWN_OBJECT) { |
| stub.set_known_map( |
| Handle<Map>(Handle<JSObject>::cast(x)->map(), isolate())); |
| } |
| Handle<Code> new_target = stub.GetCode(isolate()); |
| set_target(*new_target); |
| |
| if (FLAG_trace_ic) { |
| PrintF("[CompareIC in "); |
| JavaScriptFrame::PrintTop(isolate(), stdout, false, true); |
| PrintF(" ((%s+%s=%s)->(%s+%s=%s))#%s @ %p]\n", |
| GetStateName(previous_left), |
| GetStateName(previous_right), |
| GetStateName(previous_state), |
| GetStateName(new_left), |
| GetStateName(new_right), |
| GetStateName(state), |
| Token::Name(op_), |
| static_cast<void*>(*stub.GetCode(isolate()))); |
| } |
| |
| // Activate inlined smi code. |
| if (previous_state == UNINITIALIZED) { |
| PatchInlinedSmiCode(address(), ENABLE_INLINED_SMI_CHECK); |
| } |
| |
| return *new_target; |
| } |
| |
| |
| // Used from ICCompareStub::GenerateMiss in code-stubs-<arch>.cc. |
| RUNTIME_FUNCTION(Code*, CompareIC_Miss) { |
| HandleScope scope(isolate); |
| ASSERT(args.length() == 3); |
| CompareIC ic(isolate, static_cast<Token::Value>(args.smi_at(2))); |
| return ic.UpdateCaches(args.at<Object>(0), args.at<Object>(1)); |
| } |
| |
| |
| void CompareNilIC::Clear(Address address, |
| Code* target, |
| ConstantPoolArray* constant_pool) { |
| if (IsCleared(target)) return; |
| ExtraICState state = target->extra_ic_state(); |
| |
| CompareNilICStub stub(state, HydrogenCodeStub::UNINITIALIZED); |
| stub.ClearState(); |
| |
| Code* code = NULL; |
| CHECK(stub.FindCodeInCache(&code, target->GetIsolate())); |
| |
| SetTargetAtAddress(address, code, constant_pool); |
| } |
| |
| |
| MaybeObject* CompareNilIC::DoCompareNilSlow(NilValue nil, |
| Handle<Object> object) { |
| if (object->IsNull() || object->IsUndefined()) { |
| return Smi::FromInt(true); |
| } |
| return Smi::FromInt(object->IsUndetectableObject()); |
| } |
| |
| |
| MaybeObject* CompareNilIC::CompareNil(Handle<Object> object) { |
| ExtraICState extra_ic_state = target()->extra_ic_state(); |
| |
| CompareNilICStub stub(extra_ic_state); |
| |
| // Extract the current supported types from the patched IC and calculate what |
| // types must be supported as a result of the miss. |
| bool already_monomorphic = stub.IsMonomorphic(); |
| |
| stub.UpdateStatus(object); |
| |
| NilValue nil = stub.GetNilValue(); |
| |
| // Find or create the specialized stub to support the new set of types. |
| Handle<Code> code; |
| if (stub.IsMonomorphic()) { |
| Handle<Map> monomorphic_map(already_monomorphic |
| ? target()->FindFirstMap() |
| : HeapObject::cast(*object)->map()); |
| code = isolate()->stub_cache()->ComputeCompareNil(monomorphic_map, stub); |
| } else { |
| code = stub.GetCode(isolate()); |
| } |
| set_target(*code); |
| return DoCompareNilSlow(nil, object); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, CompareNilIC_Miss) { |
| HandleScope scope(isolate); |
| Handle<Object> object = args.at<Object>(0); |
| CompareNilIC ic(isolate); |
| return ic.CompareNil(object); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, Unreachable) { |
| UNREACHABLE(); |
| CHECK(false); |
| return isolate->heap()->undefined_value(); |
| } |
| |
| |
| Builtins::JavaScript BinaryOpIC::TokenToJSBuiltin(Token::Value op) { |
| switch (op) { |
| default: |
| UNREACHABLE(); |
| case Token::ADD: |
| return Builtins::ADD; |
| break; |
| case Token::SUB: |
| return Builtins::SUB; |
| break; |
| case Token::MUL: |
| return Builtins::MUL; |
| break; |
| case Token::DIV: |
| return Builtins::DIV; |
| break; |
| case Token::MOD: |
| return Builtins::MOD; |
| break; |
| case Token::BIT_OR: |
| return Builtins::BIT_OR; |
| break; |
| case Token::BIT_AND: |
| return Builtins::BIT_AND; |
| break; |
| case Token::BIT_XOR: |
| return Builtins::BIT_XOR; |
| break; |
| case Token::SAR: |
| return Builtins::SAR; |
| break; |
| case Token::SHR: |
| return Builtins::SHR; |
| break; |
| case Token::SHL: |
| return Builtins::SHL; |
| break; |
| } |
| } |
| |
| |
| MaybeObject* ToBooleanIC::ToBoolean(Handle<Object> object) { |
| ToBooleanStub stub(target()->extra_ic_state()); |
| bool to_boolean_value = stub.UpdateStatus(object); |
| Handle<Code> code = stub.GetCode(isolate()); |
| set_target(*code); |
| return Smi::FromInt(to_boolean_value ? 1 : 0); |
| } |
| |
| |
| RUNTIME_FUNCTION(MaybeObject*, ToBooleanIC_Miss) { |
| ASSERT(args.length() == 1); |
| HandleScope scope(isolate); |
| Handle<Object> object = args.at<Object>(0); |
| ToBooleanIC ic(isolate); |
| return ic.ToBoolean(object); |
| } |
| |
| |
| static const Address IC_utilities[] = { |
| #define ADDR(name) FUNCTION_ADDR(name), |
| IC_UTIL_LIST(ADDR) |
| NULL |
| #undef ADDR |
| }; |
| |
| |
| Address IC::AddressFromUtilityId(IC::UtilityId id) { |
| return IC_utilities[id]; |
| } |
| |
| |
| } } // namespace v8::internal |