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      1 // Copyright 2012 the V8 project authors. All rights reserved.
      2 // Use of this source code is governed by a BSD-style license that can be
      3 // found in the LICENSE file.
      4 
      5 #include "src/ic/ic.h"
      6 
      7 #include <iostream>
      8 
      9 #include "src/accessors.h"
     10 #include "src/api-arguments-inl.h"
     11 #include "src/api.h"
     12 #include "src/arguments.h"
     13 #include "src/base/bits.h"
     14 #include "src/codegen.h"
     15 #include "src/conversions.h"
     16 #include "src/execution.h"
     17 #include "src/field-type.h"
     18 #include "src/frames-inl.h"
     19 #include "src/ic/call-optimization.h"
     20 #include "src/ic/handler-compiler.h"
     21 #include "src/ic/handler-configuration-inl.h"
     22 #include "src/ic/ic-inl.h"
     23 #include "src/ic/ic-stats.h"
     24 #include "src/ic/stub-cache.h"
     25 #include "src/isolate-inl.h"
     26 #include "src/macro-assembler.h"
     27 #include "src/prototype.h"
     28 #include "src/runtime-profiler.h"
     29 #include "src/runtime/runtime-utils.h"
     30 #include "src/runtime/runtime.h"
     31 #include "src/tracing/trace-event.h"
     32 #include "src/tracing/tracing-category-observer.h"
     33 
     34 namespace v8 {
     35 namespace internal {
     36 
     37 char IC::TransitionMarkFromState(IC::State state) {
     38   switch (state) {
     39     case UNINITIALIZED:
     40       return '0';
     41     case PREMONOMORPHIC:
     42       return '.';
     43     case MONOMORPHIC:
     44       return '1';
     45     case RECOMPUTE_HANDLER:
     46       return '^';
     47     case POLYMORPHIC:
     48       return 'P';
     49     case MEGAMORPHIC:
     50       return 'N';
     51     case GENERIC:
     52       return 'G';
     53   }
     54   UNREACHABLE();
     55   return 0;
     56 }
     57 
     58 
     59 const char* GetTransitionMarkModifier(KeyedAccessStoreMode mode) {
     60   if (mode == STORE_NO_TRANSITION_HANDLE_COW) return ".COW";
     61   if (mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS) {
     62     return ".IGNORE_OOB";
     63   }
     64   if (IsGrowStoreMode(mode)) return ".GROW";
     65   return "";
     66 }
     67 
     68 #define TRACE_GENERIC_IC(reason) set_slow_stub_reason(reason);
     69 
     70 void IC::TraceIC(const char* type, Handle<Object> name) {
     71   if (FLAG_ic_stats) {
     72     if (AddressIsDeoptimizedCode()) return;
     73     DCHECK(UseVector());
     74     State new_state = nexus()->StateFromFeedback();
     75     TraceIC(type, name, state(), new_state);
     76   }
     77 }
     78 
     79 Address IC::GetAbstractPC(int* line, int* column) const {
     80   JavaScriptFrameIterator it(isolate());
     81 
     82   JavaScriptFrame* frame = it.frame();
     83   DCHECK(!frame->is_builtin());
     84   int position = frame->position();
     85 
     86   Object* maybe_script = frame->function()->shared()->script();
     87   if (maybe_script->IsScript()) {
     88     Handle<Script> script(Script::cast(maybe_script), isolate());
     89     Script::PositionInfo info;
     90     Script::GetPositionInfo(script, position, &info, Script::WITH_OFFSET);
     91     *line = info.line + 1;
     92     *column = info.column + 1;
     93   } else {
     94     *line = position;
     95     *column = -1;
     96   }
     97 
     98   if (frame->is_interpreted()) {
     99     InterpretedFrame* iframe = static_cast<InterpretedFrame*>(frame);
    100     Address bytecode_start =
    101         reinterpret_cast<Address>(iframe->GetBytecodeArray()) - kHeapObjectTag +
    102         BytecodeArray::kHeaderSize;
    103     return bytecode_start + iframe->GetBytecodeOffset();
    104   }
    105 
    106   return frame->pc();
    107 }
    108 
    109 void IC::TraceIC(const char* type, Handle<Object> name, State old_state,
    110                  State new_state) {
    111   if (V8_LIKELY(!FLAG_ic_stats)) return;
    112 
    113   Map* map = nullptr;
    114   if (!receiver_map().is_null()) {
    115     map = *receiver_map();
    116   }
    117 
    118   const char* modifier = "";
    119   if (IsKeyedStoreIC()) {
    120     KeyedAccessStoreMode mode =
    121         casted_nexus<KeyedStoreICNexus>()->GetKeyedAccessStoreMode();
    122     modifier = GetTransitionMarkModifier(mode);
    123   }
    124 
    125   if (!(FLAG_ic_stats &
    126         v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING)) {
    127     int line;
    128     int column;
    129     Address pc = GetAbstractPC(&line, &column);
    130     LOG(isolate(), ICEvent(type, is_keyed(), pc, line, column, map, *name,
    131                            TransitionMarkFromState(old_state),
    132                            TransitionMarkFromState(new_state), modifier,
    133                            slow_stub_reason_));
    134     return;
    135   }
    136 
    137   ICStats::instance()->Begin();
    138   ICInfo& ic_info = ICStats::instance()->Current();
    139   ic_info.type = is_keyed() ? "Keyed" : "";
    140   ic_info.type += type;
    141 
    142   Object* maybe_function =
    143       Memory::Object_at(fp_ + JavaScriptFrameConstants::kFunctionOffset);
    144   DCHECK(maybe_function->IsJSFunction());
    145   JSFunction* function = JSFunction::cast(maybe_function);
    146   int code_offset = 0;
    147   if (function->IsInterpreted()) {
    148     code_offset = InterpretedFrame::GetBytecodeOffset(fp());
    149   } else {
    150     code_offset =
    151         static_cast<int>(pc() - function->code()->instruction_start());
    152   }
    153   JavaScriptFrame::CollectFunctionAndOffsetForICStats(
    154       function, function->abstract_code(), code_offset);
    155 
    156   // Reserve enough space for IC transition state, the longest length is 17.
    157   ic_info.state.reserve(17);
    158   ic_info.state = "(";
    159   ic_info.state += TransitionMarkFromState(old_state);
    160   ic_info.state += "->";
    161   ic_info.state += TransitionMarkFromState(new_state);
    162   ic_info.state += modifier;
    163   ic_info.state += ")";
    164   ic_info.map = reinterpret_cast<void*>(map);
    165   if (map != nullptr) {
    166     ic_info.is_dictionary_map = map->is_dictionary_map();
    167     ic_info.number_of_own_descriptors = map->NumberOfOwnDescriptors();
    168     ic_info.instance_type = std::to_string(map->instance_type());
    169   }
    170   // TODO(lpy) Add name as key field in ICStats.
    171   ICStats::instance()->End();
    172 }
    173 
    174 
    175 #define TRACE_IC(type, name) TraceIC(type, name)
    176 
    177 IC::IC(FrameDepth depth, Isolate* isolate, FeedbackNexus* nexus)
    178     : isolate_(isolate),
    179       vector_set_(false),
    180       kind_(FeedbackSlotKind::kInvalid),
    181       target_maps_set_(false),
    182       slow_stub_reason_(nullptr),
    183       nexus_(nexus) {
    184   // To improve the performance of the (much used) IC code, we unfold a few
    185   // levels of the stack frame iteration code. This yields a ~35% speedup when
    186   // running DeltaBlue and a ~25% speedup of gbemu with the '--nouse-ic' flag.
    187   const Address entry = Isolate::c_entry_fp(isolate->thread_local_top());
    188   Address* constant_pool = NULL;
    189   if (FLAG_enable_embedded_constant_pool) {
    190     constant_pool = reinterpret_cast<Address*>(
    191         entry + ExitFrameConstants::kConstantPoolOffset);
    192   }
    193   Address* pc_address =
    194       reinterpret_cast<Address*>(entry + ExitFrameConstants::kCallerPCOffset);
    195   Address fp = Memory::Address_at(entry + ExitFrameConstants::kCallerFPOffset);
    196   // If there's another JavaScript frame on the stack or a
    197   // StubFailureTrampoline, we need to look one frame further down the stack to
    198   // find the frame pointer and the return address stack slot.
    199   if (depth == EXTRA_CALL_FRAME) {
    200     if (FLAG_enable_embedded_constant_pool) {
    201       constant_pool = reinterpret_cast<Address*>(
    202           fp + StandardFrameConstants::kConstantPoolOffset);
    203     }
    204     const int kCallerPCOffset = StandardFrameConstants::kCallerPCOffset;
    205     pc_address = reinterpret_cast<Address*>(fp + kCallerPCOffset);
    206     fp = Memory::Address_at(fp + StandardFrameConstants::kCallerFPOffset);
    207   }
    208 #ifdef DEBUG
    209   StackFrameIterator it(isolate);
    210   for (int i = 0; i < depth + 1; i++) it.Advance();
    211   StackFrame* frame = it.frame();
    212   DCHECK(fp == frame->fp() && pc_address == frame->pc_address());
    213 #endif
    214   // For interpreted functions, some bytecode handlers construct a
    215   // frame. We have to skip the constructed frame to find the interpreted
    216   // function's frame. Check if the there is an additional frame, and if there
    217   // is skip this frame. However, the pc should not be updated. The call to
    218   // ICs happen from bytecode handlers.
    219   intptr_t frame_marker =
    220       Memory::intptr_at(fp + TypedFrameConstants::kFrameTypeOffset);
    221   if (frame_marker == StackFrame::TypeToMarker(StackFrame::STUB)) {
    222     fp = Memory::Address_at(fp + TypedFrameConstants::kCallerFPOffset);
    223   }
    224   fp_ = fp;
    225   if (FLAG_enable_embedded_constant_pool) {
    226     constant_pool_address_ = constant_pool;
    227   }
    228   pc_address_ = StackFrame::ResolveReturnAddressLocation(pc_address);
    229   if (nexus) {
    230     kind_ = nexus->kind();
    231     DCHECK(UseVector());
    232     state_ = nexus->StateFromFeedback();
    233     extra_ic_state_ = kNoExtraICState;
    234   } else {
    235     Code* target = this->target();
    236     Code::Kind kind = target->kind();
    237     if (kind == Code::BINARY_OP_IC) {
    238       kind_ = FeedbackSlotKind::kBinaryOp;
    239     } else if (kind == Code::COMPARE_IC) {
    240       kind_ = FeedbackSlotKind::kCompareOp;
    241     } else if (kind == Code::TO_BOOLEAN_IC) {
    242       kind_ = FeedbackSlotKind::kToBoolean;
    243     } else {
    244       UNREACHABLE();
    245       kind_ = FeedbackSlotKind::kInvalid;
    246     }
    247     DCHECK(!UseVector());
    248     state_ = StateFromCode(target);
    249     extra_ic_state_ = target->extra_ic_state();
    250   }
    251   old_state_ = state_;
    252 }
    253 
    254 // The ICs that don't pass slot and vector through the stack have to
    255 // save/restore them in the dispatcher.
    256 bool IC::ShouldPushPopSlotAndVector(Code::Kind kind) {
    257   if (kind == Code::LOAD_IC || kind == Code::LOAD_GLOBAL_IC ||
    258       kind == Code::KEYED_LOAD_IC) {
    259     return true;
    260   }
    261   if (kind == Code::STORE_IC || kind == Code::KEYED_STORE_IC) {
    262     return !StoreWithVectorDescriptor::kPassLastArgsOnStack;
    263   }
    264   return false;
    265 }
    266 
    267 InlineCacheState IC::StateFromCode(Code* code) {
    268   Isolate* isolate = code->GetIsolate();
    269   switch (code->kind()) {
    270     case Code::BINARY_OP_IC: {
    271       BinaryOpICState state(isolate, code->extra_ic_state());
    272       return state.GetICState();
    273     }
    274     case Code::COMPARE_IC: {
    275       CompareICStub stub(isolate, code->extra_ic_state());
    276       return stub.GetICState();
    277     }
    278     case Code::TO_BOOLEAN_IC: {
    279       ToBooleanICStub stub(isolate, code->extra_ic_state());
    280       return stub.GetICState();
    281     }
    282     default:
    283       if (code->is_debug_stub()) return UNINITIALIZED;
    284       UNREACHABLE();
    285       return UNINITIALIZED;
    286   }
    287 }
    288 
    289 JSFunction* IC::GetHostFunction() const {
    290   // Compute the JavaScript frame for the frame pointer of this IC
    291   // structure. We need this to be able to find the function
    292   // corresponding to the frame.
    293   StackFrameIterator it(isolate());
    294   while (it.frame()->fp() != this->fp()) it.Advance();
    295   JavaScriptFrame* frame = JavaScriptFrame::cast(it.frame());
    296   // Find the function on the stack and both the active code for the
    297   // function and the original code.
    298   return frame->function();
    299 }
    300 
    301 static void LookupForRead(LookupIterator* it) {
    302   for (; it->IsFound(); it->Next()) {
    303     switch (it->state()) {
    304       case LookupIterator::NOT_FOUND:
    305       case LookupIterator::TRANSITION:
    306         UNREACHABLE();
    307       case LookupIterator::JSPROXY:
    308         return;
    309       case LookupIterator::INTERCEPTOR: {
    310         // If there is a getter, return; otherwise loop to perform the lookup.
    311         Handle<JSObject> holder = it->GetHolder<JSObject>();
    312         if (!holder->GetNamedInterceptor()->getter()->IsUndefined(
    313                 it->isolate())) {
    314           return;
    315         }
    316         break;
    317       }
    318       case LookupIterator::ACCESS_CHECK:
    319         // PropertyHandlerCompiler::CheckPrototypes() knows how to emit
    320         // access checks for global proxies.
    321         if (it->GetHolder<JSObject>()->IsJSGlobalProxy() && it->HasAccess()) {
    322           break;
    323         }
    324         return;
    325       case LookupIterator::ACCESSOR:
    326       case LookupIterator::INTEGER_INDEXED_EXOTIC:
    327       case LookupIterator::DATA:
    328         return;
    329     }
    330   }
    331 }
    332 
    333 bool IC::ShouldRecomputeHandler(Handle<String> name) {
    334   if (!RecomputeHandlerForName(name)) return false;
    335 
    336   DCHECK(UseVector());
    337   maybe_handler_ = nexus()->FindHandlerForMap(receiver_map());
    338 
    339   // This is a contextual access, always just update the handler and stay
    340   // monomorphic.
    341   if (IsLoadGlobalIC()) return true;
    342 
    343   // The current map wasn't handled yet. There's no reason to stay monomorphic,
    344   // *unless* we're moving from a deprecated map to its replacement, or
    345   // to a more general elements kind.
    346   // TODO(verwaest): Check if the current map is actually what the old map
    347   // would transition to.
    348   if (maybe_handler_.is_null()) {
    349     if (!receiver_map()->IsJSObjectMap()) return false;
    350     Map* first_map = FirstTargetMap();
    351     if (first_map == NULL) return false;
    352     Handle<Map> old_map(first_map);
    353     if (old_map->is_deprecated()) return true;
    354     return IsMoreGeneralElementsKindTransition(old_map->elements_kind(),
    355                                                receiver_map()->elements_kind());
    356   }
    357 
    358   return true;
    359 }
    360 
    361 bool IC::RecomputeHandlerForName(Handle<Object> name) {
    362   if (is_keyed()) {
    363     // Determine whether the failure is due to a name failure.
    364     if (!name->IsName()) return false;
    365     DCHECK(UseVector());
    366     Name* stub_name = nexus()->FindFirstName();
    367     if (*name != stub_name) return false;
    368   }
    369 
    370   return true;
    371 }
    372 
    373 
    374 void IC::UpdateState(Handle<Object> receiver, Handle<Object> name) {
    375   update_receiver_map(receiver);
    376   if (!name->IsString()) return;
    377   if (state() != MONOMORPHIC && state() != POLYMORPHIC) return;
    378   if (receiver->IsNullOrUndefined(isolate())) return;
    379 
    380   // Remove the target from the code cache if it became invalid
    381   // because of changes in the prototype chain to avoid hitting it
    382   // again.
    383   if (ShouldRecomputeHandler(Handle<String>::cast(name))) {
    384     MarkRecomputeHandler(name);
    385   }
    386 }
    387 
    388 
    389 MaybeHandle<Object> IC::TypeError(MessageTemplate::Template index,
    390                                   Handle<Object> object, Handle<Object> key) {
    391   HandleScope scope(isolate());
    392   THROW_NEW_ERROR(isolate(), NewTypeError(index, key, object), Object);
    393 }
    394 
    395 
    396 MaybeHandle<Object> IC::ReferenceError(Handle<Name> name) {
    397   HandleScope scope(isolate());
    398   THROW_NEW_ERROR(
    399       isolate(), NewReferenceError(MessageTemplate::kNotDefined, name), Object);
    400 }
    401 
    402 
    403 static void ComputeTypeInfoCountDelta(IC::State old_state, IC::State new_state,
    404                                       int* polymorphic_delta,
    405                                       int* generic_delta) {
    406   switch (old_state) {
    407     case UNINITIALIZED:
    408     case PREMONOMORPHIC:
    409       if (new_state == UNINITIALIZED || new_state == PREMONOMORPHIC) break;
    410       if (new_state == MONOMORPHIC || new_state == POLYMORPHIC) {
    411         *polymorphic_delta = 1;
    412       } else if (new_state == MEGAMORPHIC || new_state == GENERIC) {
    413         *generic_delta = 1;
    414       }
    415       break;
    416     case MONOMORPHIC:
    417     case POLYMORPHIC:
    418       if (new_state == MONOMORPHIC || new_state == POLYMORPHIC) break;
    419       *polymorphic_delta = -1;
    420       if (new_state == MEGAMORPHIC || new_state == GENERIC) {
    421         *generic_delta = 1;
    422       }
    423       break;
    424     case MEGAMORPHIC:
    425     case GENERIC:
    426       if (new_state == MEGAMORPHIC || new_state == GENERIC) break;
    427       *generic_delta = -1;
    428       if (new_state == MONOMORPHIC || new_state == POLYMORPHIC) {
    429         *polymorphic_delta = 1;
    430       }
    431       break;
    432     case RECOMPUTE_HANDLER:
    433       UNREACHABLE();
    434   }
    435 }
    436 
    437 // static
    438 void IC::OnFeedbackChanged(Isolate* isolate, JSFunction* host_function) {
    439   Code* host = host_function->shared()->code();
    440 
    441   if (host->kind() == Code::FUNCTION) {
    442     TypeFeedbackInfo* info = TypeFeedbackInfo::cast(host->type_feedback_info());
    443     info->change_own_type_change_checksum();
    444     host->set_profiler_ticks(0);
    445   }
    446   isolate->runtime_profiler()->NotifyICChanged();
    447   // TODO(2029): When an optimized function is patched, it would
    448   // be nice to propagate the corresponding type information to its
    449   // unoptimized version for the benefit of later inlining.
    450 }
    451 
    452 void IC::PostPatching(Address address, Code* target, Code* old_target) {
    453   // Type vector based ICs update these statistics at a different time because
    454   // they don't always patch on state change.
    455   // TODO(ishell): DCHECK
    456   if (ICUseVector(target->kind())) return;
    457 
    458   DCHECK(old_target->is_inline_cache_stub());
    459   DCHECK(target->is_inline_cache_stub());
    460   State old_state = StateFromCode(old_target);
    461   State new_state = StateFromCode(target);
    462 
    463   Isolate* isolate = target->GetIsolate();
    464   Code* host =
    465       isolate->inner_pointer_to_code_cache()->GetCacheEntry(address)->code;
    466   if (host->kind() != Code::FUNCTION) return;
    467 
    468   // Not all Code objects have TypeFeedbackInfo.
    469   if (host->type_feedback_info()->IsTypeFeedbackInfo()) {
    470     if (FLAG_type_info_threshold > 0) {
    471       int polymorphic_delta = 0;  // "Polymorphic" here includes monomorphic.
    472       int generic_delta = 0;      // "Generic" here includes megamorphic.
    473       ComputeTypeInfoCountDelta(old_state, new_state, &polymorphic_delta,
    474                                 &generic_delta);
    475       TypeFeedbackInfo* info =
    476           TypeFeedbackInfo::cast(host->type_feedback_info());
    477       info->change_ic_with_type_info_count(polymorphic_delta);
    478       info->change_ic_generic_count(generic_delta);
    479     }
    480     TypeFeedbackInfo* info = TypeFeedbackInfo::cast(host->type_feedback_info());
    481     info->change_own_type_change_checksum();
    482   }
    483   host->set_profiler_ticks(0);
    484   isolate->runtime_profiler()->NotifyICChanged();
    485   // TODO(2029): When an optimized function is patched, it would
    486   // be nice to propagate the corresponding type information to its
    487   // unoptimized version for the benefit of later inlining.
    488 }
    489 
    490 void IC::Clear(Isolate* isolate, Address address, Address constant_pool) {
    491   Code* target = GetTargetAtAddress(address, constant_pool);
    492 
    493   // Don't clear debug break inline cache as it will remove the break point.
    494   if (target->is_debug_stub()) return;
    495 
    496   if (target->kind() == Code::COMPARE_IC) {
    497     CompareIC::Clear(isolate, address, target, constant_pool);
    498   }
    499 }
    500 
    501 void CompareIC::Clear(Isolate* isolate, Address address, Code* target,
    502                       Address constant_pool) {
    503   DCHECK(CodeStub::GetMajorKey(target) == CodeStub::CompareIC);
    504   CompareICStub stub(target->stub_key(), isolate);
    505   // Only clear CompareICs that can retain objects.
    506   if (stub.state() != CompareICState::KNOWN_RECEIVER) return;
    507   SetTargetAtAddress(address, GetRawUninitialized(isolate, stub.op()),
    508                      constant_pool);
    509   PatchInlinedSmiCode(isolate, address, DISABLE_INLINED_SMI_CHECK);
    510 }
    511 
    512 static bool MigrateDeprecated(Handle<Object> object) {
    513   if (!object->IsJSObject()) return false;
    514   Handle<JSObject> receiver = Handle<JSObject>::cast(object);
    515   if (!receiver->map()->is_deprecated()) return false;
    516   JSObject::MigrateInstance(Handle<JSObject>::cast(object));
    517   return true;
    518 }
    519 
    520 void IC::ConfigureVectorState(IC::State new_state, Handle<Object> key) {
    521   DCHECK(UseVector());
    522   if (new_state == PREMONOMORPHIC) {
    523     nexus()->ConfigurePremonomorphic();
    524   } else if (new_state == MEGAMORPHIC) {
    525     if (IsLoadIC() || IsStoreIC() || IsStoreOwnIC()) {
    526       nexus()->ConfigureMegamorphic();
    527     } else if (IsKeyedLoadIC()) {
    528       KeyedLoadICNexus* nexus = casted_nexus<KeyedLoadICNexus>();
    529       nexus->ConfigureMegamorphicKeyed(key->IsName() ? PROPERTY : ELEMENT);
    530     } else {
    531       DCHECK(IsKeyedStoreIC());
    532       KeyedStoreICNexus* nexus = casted_nexus<KeyedStoreICNexus>();
    533       nexus->ConfigureMegamorphicKeyed(key->IsName() ? PROPERTY : ELEMENT);
    534     }
    535   } else {
    536     UNREACHABLE();
    537   }
    538 
    539   vector_set_ = true;
    540   OnFeedbackChanged(isolate(), GetHostFunction());
    541 }
    542 
    543 void IC::ConfigureVectorState(Handle<Name> name, Handle<Map> map,
    544                               Handle<Object> handler) {
    545   DCHECK(UseVector());
    546   switch (kind_) {
    547     case FeedbackSlotKind::kLoadProperty: {
    548       LoadICNexus* nexus = casted_nexus<LoadICNexus>();
    549       nexus->ConfigureMonomorphic(map, handler);
    550       break;
    551     }
    552     case FeedbackSlotKind::kLoadGlobalNotInsideTypeof:
    553     case FeedbackSlotKind::kLoadGlobalInsideTypeof: {
    554       LoadGlobalICNexus* nexus = casted_nexus<LoadGlobalICNexus>();
    555       nexus->ConfigureHandlerMode(handler);
    556       break;
    557     }
    558     case FeedbackSlotKind::kLoadKeyed: {
    559       KeyedLoadICNexus* nexus = casted_nexus<KeyedLoadICNexus>();
    560       nexus->ConfigureMonomorphic(name, map, handler);
    561       break;
    562     }
    563     case FeedbackSlotKind::kStoreNamedSloppy:
    564     case FeedbackSlotKind::kStoreNamedStrict:
    565     case FeedbackSlotKind::kStoreOwnNamed: {
    566       StoreICNexus* nexus = casted_nexus<StoreICNexus>();
    567       nexus->ConfigureMonomorphic(map, handler);
    568       break;
    569     }
    570     case FeedbackSlotKind::kStoreKeyedSloppy:
    571     case FeedbackSlotKind::kStoreKeyedStrict: {
    572       KeyedStoreICNexus* nexus = casted_nexus<KeyedStoreICNexus>();
    573       nexus->ConfigureMonomorphic(name, map, handler);
    574       break;
    575     }
    576     case FeedbackSlotKind::kCall:
    577     case FeedbackSlotKind::kBinaryOp:
    578     case FeedbackSlotKind::kCompareOp:
    579     case FeedbackSlotKind::kToBoolean:
    580     case FeedbackSlotKind::kCreateClosure:
    581     case FeedbackSlotKind::kLiteral:
    582     case FeedbackSlotKind::kGeneral:
    583     case FeedbackSlotKind::kStoreDataPropertyInLiteral:
    584     case FeedbackSlotKind::kInvalid:
    585     case FeedbackSlotKind::kKindsNumber:
    586       UNREACHABLE();
    587       break;
    588   }
    589 
    590   vector_set_ = true;
    591   OnFeedbackChanged(isolate(), GetHostFunction());
    592 }
    593 
    594 void IC::ConfigureVectorState(Handle<Name> name, MapHandleList* maps,
    595                               List<Handle<Object>>* handlers) {
    596   DCHECK(UseVector());
    597   switch (kind_) {
    598     case FeedbackSlotKind::kLoadProperty: {
    599       LoadICNexus* nexus = casted_nexus<LoadICNexus>();
    600       nexus->ConfigurePolymorphic(maps, handlers);
    601       break;
    602     }
    603     case FeedbackSlotKind::kLoadKeyed: {
    604       KeyedLoadICNexus* nexus = casted_nexus<KeyedLoadICNexus>();
    605       nexus->ConfigurePolymorphic(name, maps, handlers);
    606       break;
    607     }
    608     case FeedbackSlotKind::kStoreNamedSloppy:
    609     case FeedbackSlotKind::kStoreNamedStrict:
    610     case FeedbackSlotKind::kStoreOwnNamed: {
    611       StoreICNexus* nexus = casted_nexus<StoreICNexus>();
    612       nexus->ConfigurePolymorphic(maps, handlers);
    613       break;
    614     }
    615     case FeedbackSlotKind::kStoreKeyedSloppy:
    616     case FeedbackSlotKind::kStoreKeyedStrict: {
    617       KeyedStoreICNexus* nexus = casted_nexus<KeyedStoreICNexus>();
    618       nexus->ConfigurePolymorphic(name, maps, handlers);
    619       break;
    620     }
    621     case FeedbackSlotKind::kCall:
    622     case FeedbackSlotKind::kLoadGlobalNotInsideTypeof:
    623     case FeedbackSlotKind::kLoadGlobalInsideTypeof:
    624     case FeedbackSlotKind::kBinaryOp:
    625     case FeedbackSlotKind::kCompareOp:
    626     case FeedbackSlotKind::kToBoolean:
    627     case FeedbackSlotKind::kCreateClosure:
    628     case FeedbackSlotKind::kLiteral:
    629     case FeedbackSlotKind::kGeneral:
    630     case FeedbackSlotKind::kStoreDataPropertyInLiteral:
    631     case FeedbackSlotKind::kInvalid:
    632     case FeedbackSlotKind::kKindsNumber:
    633       UNREACHABLE();
    634       break;
    635   }
    636 
    637   vector_set_ = true;
    638   OnFeedbackChanged(isolate(), GetHostFunction());
    639 }
    640 
    641 void IC::ConfigureVectorState(MapHandleList* maps,
    642                               MapHandleList* transitioned_maps,
    643                               List<Handle<Object>>* handlers) {
    644   DCHECK(UseVector());
    645   DCHECK(IsKeyedStoreIC());
    646   KeyedStoreICNexus* nexus = casted_nexus<KeyedStoreICNexus>();
    647   nexus->ConfigurePolymorphic(maps, transitioned_maps, handlers);
    648 
    649   vector_set_ = true;
    650   OnFeedbackChanged(isolate(), GetHostFunction());
    651 }
    652 
    653 
    654 MaybeHandle<Object> LoadIC::Load(Handle<Object> object, Handle<Name> name) {
    655   // If the object is undefined or null it's illegal to try to get any
    656   // of its properties; throw a TypeError in that case.
    657   if (object->IsNullOrUndefined(isolate())) {
    658     if (FLAG_use_ic && state() != UNINITIALIZED && state() != PREMONOMORPHIC) {
    659       // Ensure the IC state progresses.
    660       TRACE_HANDLER_STATS(isolate(), LoadIC_NonReceiver);
    661       update_receiver_map(object);
    662       PatchCache(name, slow_stub());
    663       TRACE_IC("LoadIC", name);
    664     }
    665     return TypeError(MessageTemplate::kNonObjectPropertyLoad, object, name);
    666   }
    667 
    668   bool use_ic = MigrateDeprecated(object) ? false : FLAG_use_ic;
    669 
    670   if (state() != UNINITIALIZED) {
    671     JSObject::MakePrototypesFast(object, kStartAtReceiver, isolate());
    672     update_receiver_map(object);
    673   }
    674   // Named lookup in the object.
    675   LookupIterator it(object, name);
    676   LookupForRead(&it);
    677 
    678   if (it.IsFound() || !ShouldThrowReferenceError()) {
    679     // Update inline cache and stub cache.
    680     if (use_ic) UpdateCaches(&it);
    681 
    682     // Get the property.
    683     Handle<Object> result;
    684 
    685     ASSIGN_RETURN_ON_EXCEPTION(isolate(), result, Object::GetProperty(&it),
    686                                Object);
    687     if (it.IsFound()) {
    688       return result;
    689     } else if (!ShouldThrowReferenceError()) {
    690       LOG(isolate(), SuspectReadEvent(*name, *object));
    691       return result;
    692     }
    693   }
    694   return ReferenceError(name);
    695 }
    696 
    697 MaybeHandle<Object> LoadGlobalIC::Load(Handle<Name> name) {
    698   Handle<JSGlobalObject> global = isolate()->global_object();
    699 
    700   if (name->IsString()) {
    701     // Look up in script context table.
    702     Handle<String> str_name = Handle<String>::cast(name);
    703     Handle<ScriptContextTable> script_contexts(
    704         global->native_context()->script_context_table());
    705 
    706     ScriptContextTable::LookupResult lookup_result;
    707     if (ScriptContextTable::Lookup(script_contexts, str_name, &lookup_result)) {
    708       Handle<Object> result =
    709           FixedArray::get(*ScriptContextTable::GetContext(
    710                               script_contexts, lookup_result.context_index),
    711                           lookup_result.slot_index, isolate());
    712       if (result->IsTheHole(isolate())) {
    713         // Do not install stubs and stay pre-monomorphic for
    714         // uninitialized accesses.
    715         return ReferenceError(name);
    716       }
    717 
    718       if (FLAG_use_ic && LoadScriptContextFieldStub::Accepted(&lookup_result)) {
    719         TRACE_HANDLER_STATS(isolate(), LoadIC_LoadScriptContextFieldStub);
    720         LoadScriptContextFieldStub stub(isolate(), &lookup_result);
    721         PatchCache(name, stub.GetCode());
    722         TRACE_IC("LoadGlobalIC", name);
    723       }
    724       return result;
    725     }
    726   }
    727   return LoadIC::Load(global, name);
    728 }
    729 
    730 static bool AddOneReceiverMapIfMissing(MapHandleList* receiver_maps,
    731                                        Handle<Map> new_receiver_map) {
    732   DCHECK(!new_receiver_map.is_null());
    733   for (int current = 0; current < receiver_maps->length(); ++current) {
    734     if (!receiver_maps->at(current).is_null() &&
    735         receiver_maps->at(current).is_identical_to(new_receiver_map)) {
    736       return false;
    737     }
    738   }
    739   receiver_maps->Add(new_receiver_map);
    740   return true;
    741 }
    742 
    743 bool IC::UpdatePolymorphicIC(Handle<Name> name, Handle<Object> handler) {
    744   DCHECK(IsHandler(*handler));
    745   if (is_keyed() && state() != RECOMPUTE_HANDLER) return false;
    746   Handle<Map> map = receiver_map();
    747   MapHandleList maps;
    748   List<Handle<Object>> handlers;
    749 
    750   TargetMaps(&maps);
    751   int number_of_maps = maps.length();
    752   int deprecated_maps = 0;
    753   int handler_to_overwrite = -1;
    754 
    755   for (int i = 0; i < number_of_maps; i++) {
    756     Handle<Map> current_map = maps.at(i);
    757     if (current_map->is_deprecated()) {
    758       // Filter out deprecated maps to ensure their instances get migrated.
    759       ++deprecated_maps;
    760     } else if (map.is_identical_to(current_map)) {
    761       // If the receiver type is already in the polymorphic IC, this indicates
    762       // there was a prototoype chain failure. In that case, just overwrite the
    763       // handler.
    764       handler_to_overwrite = i;
    765     } else if (handler_to_overwrite == -1 &&
    766                IsTransitionOfMonomorphicTarget(*current_map, *map)) {
    767       handler_to_overwrite = i;
    768     }
    769   }
    770 
    771   int number_of_valid_maps =
    772       number_of_maps - deprecated_maps - (handler_to_overwrite != -1);
    773 
    774   if (number_of_valid_maps >= 4) return false;
    775   if (number_of_maps == 0 && state() != MONOMORPHIC && state() != POLYMORPHIC) {
    776     return false;
    777   }
    778   DCHECK(UseVector());
    779   if (!nexus()->FindHandlers(&handlers, maps.length())) return false;
    780 
    781   number_of_valid_maps++;
    782   if (number_of_valid_maps > 1 && is_keyed()) return false;
    783   if (number_of_valid_maps == 1) {
    784     ConfigureVectorState(name, receiver_map(), handler);
    785   } else {
    786     if (handler_to_overwrite >= 0) {
    787       handlers.Set(handler_to_overwrite, handler);
    788       if (!map.is_identical_to(maps.at(handler_to_overwrite))) {
    789         maps.Set(handler_to_overwrite, map);
    790       }
    791     } else {
    792       maps.Add(map);
    793       handlers.Add(handler);
    794     }
    795 
    796     ConfigureVectorState(name, &maps, &handlers);
    797   }
    798 
    799   return true;
    800 }
    801 
    802 void IC::UpdateMonomorphicIC(Handle<Object> handler, Handle<Name> name) {
    803   DCHECK(IsHandler(*handler));
    804   ConfigureVectorState(name, receiver_map(), handler);
    805 }
    806 
    807 
    808 void IC::CopyICToMegamorphicCache(Handle<Name> name) {
    809   MapHandleList maps;
    810   List<Handle<Object>> handlers;
    811   TargetMaps(&maps);
    812   if (!nexus()->FindHandlers(&handlers, maps.length())) return;
    813   for (int i = 0; i < maps.length(); i++) {
    814     UpdateMegamorphicCache(*maps.at(i), *name, *handlers.at(i));
    815   }
    816 }
    817 
    818 
    819 bool IC::IsTransitionOfMonomorphicTarget(Map* source_map, Map* target_map) {
    820   if (source_map == NULL) return true;
    821   if (target_map == NULL) return false;
    822   ElementsKind target_elements_kind = target_map->elements_kind();
    823   bool more_general_transition = IsMoreGeneralElementsKindTransition(
    824       source_map->elements_kind(), target_elements_kind);
    825   Map* transitioned_map = nullptr;
    826   if (more_general_transition) {
    827     MapHandleList map_list;
    828     map_list.Add(handle(target_map));
    829     transitioned_map = source_map->FindElementsKindTransitionedMap(&map_list);
    830   }
    831   return transitioned_map == target_map;
    832 }
    833 
    834 void IC::PatchCache(Handle<Name> name, Handle<Object> handler) {
    835   DCHECK(IsHandler(*handler));
    836   // Currently only load and store ICs support non-code handlers.
    837   DCHECK_IMPLIES(!handler->IsCode(), IsAnyLoad() || IsAnyStore());
    838   switch (state()) {
    839     case UNINITIALIZED:
    840     case PREMONOMORPHIC:
    841       UpdateMonomorphicIC(handler, name);
    842       break;
    843     case RECOMPUTE_HANDLER:
    844     case MONOMORPHIC:
    845       if (IsLoadGlobalIC()) {
    846         UpdateMonomorphicIC(handler, name);
    847         break;
    848       }
    849     // Fall through.
    850     case POLYMORPHIC:
    851       if (!is_keyed() || state() == RECOMPUTE_HANDLER) {
    852         if (UpdatePolymorphicIC(name, handler)) break;
    853         // For keyed stubs, we can't know whether old handlers were for the
    854         // same key.
    855         CopyICToMegamorphicCache(name);
    856       }
    857       DCHECK(UseVector());
    858       ConfigureVectorState(MEGAMORPHIC, name);
    859     // Fall through.
    860     case MEGAMORPHIC:
    861       UpdateMegamorphicCache(*receiver_map(), *name, *handler);
    862       // Indicate that we've handled this case.
    863       DCHECK(UseVector());
    864       vector_set_ = true;
    865       break;
    866     case GENERIC:
    867       UNREACHABLE();
    868       break;
    869   }
    870 }
    871 
    872 Handle<Object> LoadIC::SimpleFieldLoad(Isolate* isolate, FieldIndex index) {
    873   TRACE_HANDLER_STATS(isolate, LoadIC_LoadFieldDH);
    874   return LoadHandler::LoadField(isolate, index);
    875 }
    876 
    877 namespace {
    878 
    879 template <bool fill_array = true>
    880 int InitPrototypeChecks(Isolate* isolate, Handle<Map> receiver_map,
    881                         Handle<JSObject> holder, Handle<Name> name,
    882                         Handle<FixedArray> array, int first_index) {
    883   DCHECK(holder.is_null() || holder->HasFastProperties());
    884 
    885   // We don't encode the requirement to check access rights because we already
    886   // passed the access check for current native context and the access
    887   // can't be revoked.
    888 
    889   HandleScope scope(isolate);
    890   int checks_count = 0;
    891 
    892   if (receiver_map->IsPrimitiveMap() || receiver_map->IsJSGlobalProxyMap()) {
    893     // The validity cell check for primitive and global proxy receivers does
    894     // not guarantee that certain native context ever had access to other
    895     // native context. However, a handler created for one native context could
    896     // be used in other native context through the megamorphic stub cache.
    897     // So we record the original native context to which this handler
    898     // corresponds.
    899     if (fill_array) {
    900       Handle<Context> native_context = isolate->native_context();
    901       array->set(LoadHandler::kFirstPrototypeIndex + checks_count,
    902                  native_context->self_weak_cell());
    903     }
    904     checks_count++;
    905 
    906   } else if (receiver_map->IsJSGlobalObjectMap()) {
    907     if (fill_array) {
    908       Handle<JSGlobalObject> global = isolate->global_object();
    909       Handle<PropertyCell> cell = JSGlobalObject::EnsureEmptyPropertyCell(
    910           global, name, PropertyCellType::kInvalidated);
    911       DCHECK(cell->value()->IsTheHole(isolate));
    912       Handle<WeakCell> weak_cell = isolate->factory()->NewWeakCell(cell);
    913       array->set(LoadHandler::kFirstPrototypeIndex + checks_count, *weak_cell);
    914     }
    915     checks_count++;
    916   }
    917 
    918   // Create/count entries for each global or dictionary prototype appeared in
    919   // the prototype chain contains from receiver till holder.
    920   PrototypeIterator::WhereToEnd end = name->IsPrivate()
    921                                           ? PrototypeIterator::END_AT_NON_HIDDEN
    922                                           : PrototypeIterator::END_AT_NULL;
    923   for (PrototypeIterator iter(receiver_map, end); !iter.IsAtEnd();
    924        iter.Advance()) {
    925     Handle<JSObject> current = PrototypeIterator::GetCurrent<JSObject>(iter);
    926     if (holder.is_identical_to(current)) break;
    927     Handle<Map> current_map(current->map(), isolate);
    928 
    929     if (current_map->IsJSGlobalObjectMap()) {
    930       if (fill_array) {
    931         Handle<JSGlobalObject> global = Handle<JSGlobalObject>::cast(current);
    932         Handle<PropertyCell> cell = JSGlobalObject::EnsureEmptyPropertyCell(
    933             global, name, PropertyCellType::kInvalidated);
    934         DCHECK(cell->value()->IsTheHole(isolate));
    935         Handle<WeakCell> weak_cell = isolate->factory()->NewWeakCell(cell);
    936         array->set(first_index + checks_count, *weak_cell);
    937       }
    938       checks_count++;
    939 
    940     } else if (current_map->is_dictionary_map()) {
    941       DCHECK(!current_map->IsJSGlobalProxyMap());  // Proxy maps are fast.
    942       if (fill_array) {
    943         DCHECK_EQ(NameDictionary::kNotFound,
    944                   current->property_dictionary()->FindEntry(name));
    945         Handle<WeakCell> weak_cell =
    946             Map::GetOrCreatePrototypeWeakCell(current, isolate);
    947         array->set(first_index + checks_count, *weak_cell);
    948       }
    949       checks_count++;
    950     }
    951   }
    952   return checks_count;
    953 }
    954 
    955 // Returns 0 if the validity cell check is enough to ensure that the
    956 // prototype chain from |receiver_map| till |holder| did not change.
    957 // If the |holder| is an empty handle then the full prototype chain is
    958 // checked.
    959 // Returns -1 if the handler has to be compiled or the number of prototype
    960 // checks otherwise.
    961 int GetPrototypeCheckCount(Isolate* isolate, Handle<Map> receiver_map,
    962                            Handle<JSObject> holder, Handle<Name> name) {
    963   return InitPrototypeChecks<false>(isolate, receiver_map, holder, name,
    964                                     Handle<FixedArray>(), 0);
    965 }
    966 
    967 }  // namespace
    968 
    969 Handle<Object> LoadIC::LoadFromPrototype(Handle<Map> receiver_map,
    970                                          Handle<JSObject> holder,
    971                                          Handle<Name> name,
    972                                          Handle<Object> smi_handler) {
    973   int checks_count =
    974       GetPrototypeCheckCount(isolate(), receiver_map, holder, name);
    975   DCHECK_LE(0, checks_count);
    976 
    977   if (receiver_map->IsPrimitiveMap() || receiver_map->IsJSGlobalProxyMap()) {
    978     DCHECK(!receiver_map->is_dictionary_map());
    979     DCHECK_LE(1, checks_count);  // For native context.
    980     smi_handler =
    981         LoadHandler::EnableAccessCheckOnReceiver(isolate(), smi_handler);
    982   } else if (receiver_map->is_dictionary_map() &&
    983              !receiver_map->IsJSGlobalObjectMap()) {
    984     smi_handler =
    985         LoadHandler::EnableNegativeLookupOnReceiver(isolate(), smi_handler);
    986   }
    987 
    988   Handle<Cell> validity_cell =
    989       Map::GetOrCreatePrototypeChainValidityCell(receiver_map, isolate());
    990   DCHECK(!validity_cell.is_null());
    991 
    992   Handle<WeakCell> holder_cell =
    993       Map::GetOrCreatePrototypeWeakCell(holder, isolate());
    994 
    995   if (checks_count == 0) {
    996     return isolate()->factory()->NewTuple3(holder_cell, smi_handler,
    997                                            validity_cell);
    998   }
    999   Handle<FixedArray> handler_array(isolate()->factory()->NewFixedArray(
   1000       LoadHandler::kFirstPrototypeIndex + checks_count, TENURED));
   1001   handler_array->set(LoadHandler::kSmiHandlerIndex, *smi_handler);
   1002   handler_array->set(LoadHandler::kValidityCellIndex, *validity_cell);
   1003   handler_array->set(LoadHandler::kHolderCellIndex, *holder_cell);
   1004   InitPrototypeChecks(isolate(), receiver_map, holder, name, handler_array,
   1005                       LoadHandler::kFirstPrototypeIndex);
   1006   return handler_array;
   1007 }
   1008 
   1009 Handle<Object> LoadIC::LoadNonExistent(Handle<Map> receiver_map,
   1010                                        Handle<Name> name) {
   1011   Handle<JSObject> holder;  // null handle
   1012   int checks_count =
   1013       GetPrototypeCheckCount(isolate(), receiver_map, holder, name);
   1014   DCHECK_LE(0, checks_count);
   1015 
   1016   bool do_negative_lookup_on_receiver =
   1017       receiver_map->is_dictionary_map() && !receiver_map->IsJSGlobalObjectMap();
   1018   Handle<Object> smi_handler =
   1019       LoadHandler::LoadNonExistent(isolate(), do_negative_lookup_on_receiver);
   1020 
   1021   if (receiver_map->IsPrimitiveMap() || receiver_map->IsJSGlobalProxyMap()) {
   1022     DCHECK(!receiver_map->is_dictionary_map());
   1023     DCHECK_LE(1, checks_count);  // For native context.
   1024     smi_handler =
   1025         LoadHandler::EnableAccessCheckOnReceiver(isolate(), smi_handler);
   1026   }
   1027 
   1028   Handle<Object> validity_cell =
   1029       Map::GetOrCreatePrototypeChainValidityCell(receiver_map, isolate());
   1030   if (validity_cell.is_null()) {
   1031     DCHECK_EQ(0, checks_count);
   1032     validity_cell = handle(Smi::FromInt(0), isolate());
   1033   }
   1034 
   1035   Factory* factory = isolate()->factory();
   1036   if (checks_count == 0) {
   1037     return factory->NewTuple3(factory->null_value(), smi_handler,
   1038                               validity_cell);
   1039   }
   1040   Handle<FixedArray> handler_array(factory->NewFixedArray(
   1041       LoadHandler::kFirstPrototypeIndex + checks_count, TENURED));
   1042   handler_array->set(LoadHandler::kSmiHandlerIndex, *smi_handler);
   1043   handler_array->set(LoadHandler::kValidityCellIndex, *validity_cell);
   1044   handler_array->set(LoadHandler::kHolderCellIndex, *factory->null_value());
   1045   InitPrototypeChecks(isolate(), receiver_map, holder, name, handler_array,
   1046                       LoadHandler::kFirstPrototypeIndex);
   1047   return handler_array;
   1048 }
   1049 
   1050 bool IsCompatibleReceiver(LookupIterator* lookup, Handle<Map> receiver_map) {
   1051   DCHECK(lookup->state() == LookupIterator::ACCESSOR);
   1052   Isolate* isolate = lookup->isolate();
   1053   Handle<Object> accessors = lookup->GetAccessors();
   1054   if (accessors->IsAccessorInfo()) {
   1055     Handle<AccessorInfo> info = Handle<AccessorInfo>::cast(accessors);
   1056     if (info->getter() != NULL &&
   1057         !AccessorInfo::IsCompatibleReceiverMap(isolate, info, receiver_map)) {
   1058       return false;
   1059     }
   1060   } else if (accessors->IsAccessorPair()) {
   1061     Handle<Object> getter(Handle<AccessorPair>::cast(accessors)->getter(),
   1062                           isolate);
   1063     if (!getter->IsJSFunction() && !getter->IsFunctionTemplateInfo()) {
   1064       return false;
   1065     }
   1066     Handle<JSObject> holder = lookup->GetHolder<JSObject>();
   1067     Handle<Object> receiver = lookup->GetReceiver();
   1068     if (holder->HasFastProperties()) {
   1069       if (getter->IsJSFunction()) {
   1070         Handle<JSFunction> function = Handle<JSFunction>::cast(getter);
   1071         if (!receiver->IsJSObject() && function->shared()->IsUserJavaScript() &&
   1072             is_sloppy(function->shared()->language_mode())) {
   1073           // Calling sloppy non-builtins with a value as the receiver
   1074           // requires boxing.
   1075           return false;
   1076         }
   1077       }
   1078       CallOptimization call_optimization(getter);
   1079       if (call_optimization.is_simple_api_call() &&
   1080           !call_optimization.IsCompatibleReceiverMap(receiver_map, holder)) {
   1081         return false;
   1082       }
   1083     }
   1084   }
   1085   return true;
   1086 }
   1087 
   1088 
   1089 void LoadIC::UpdateCaches(LookupIterator* lookup) {
   1090   if (state() == UNINITIALIZED && !IsLoadGlobalIC()) {
   1091     // This is the first time we execute this inline cache. Set the target to
   1092     // the pre monomorphic stub to delay setting the monomorphic state.
   1093     TRACE_HANDLER_STATS(isolate(), LoadIC_Premonomorphic);
   1094     ConfigureVectorState(PREMONOMORPHIC, Handle<Object>());
   1095     TRACE_IC("LoadIC", lookup->name());
   1096     return;
   1097   }
   1098 
   1099   Handle<Object> code;
   1100   if (lookup->state() == LookupIterator::JSPROXY ||
   1101       lookup->state() == LookupIterator::ACCESS_CHECK) {
   1102     code = slow_stub();
   1103   } else if (!lookup->IsFound()) {
   1104     TRACE_HANDLER_STATS(isolate(), LoadIC_LoadNonexistentDH);
   1105     code = LoadNonExistent(receiver_map(), lookup->name());
   1106   } else {
   1107     if (IsLoadGlobalIC() && lookup->state() == LookupIterator::DATA &&
   1108         lookup->GetReceiver().is_identical_to(lookup->GetHolder<Object>())) {
   1109       DCHECK(lookup->GetReceiver()->IsJSGlobalObject());
   1110       // Now update the cell in the feedback vector.
   1111       LoadGlobalICNexus* nexus = casted_nexus<LoadGlobalICNexus>();
   1112       nexus->ConfigurePropertyCellMode(lookup->GetPropertyCell());
   1113       TRACE_IC("LoadGlobalIC", lookup->name());
   1114       return;
   1115     } else if (lookup->state() == LookupIterator::ACCESSOR) {
   1116       if (!IsCompatibleReceiver(lookup, receiver_map())) {
   1117         TRACE_GENERIC_IC("incompatible receiver type");
   1118         code = slow_stub();
   1119       }
   1120     } else if (lookup->state() == LookupIterator::INTERCEPTOR) {
   1121       // Perform a lookup behind the interceptor. Copy the LookupIterator
   1122       // since the original iterator will be used to fetch the value.
   1123       LookupIterator it = *lookup;
   1124       it.Next();
   1125       LookupForRead(&it);
   1126       if (it.state() == LookupIterator::ACCESSOR &&
   1127           !IsCompatibleReceiver(&it, receiver_map())) {
   1128         TRACE_GENERIC_IC("incompatible receiver type");
   1129         code = slow_stub();
   1130       }
   1131     }
   1132     if (code.is_null()) code = ComputeHandler(lookup);
   1133   }
   1134 
   1135   PatchCache(lookup->name(), code);
   1136   TRACE_IC("LoadIC", lookup->name());
   1137 }
   1138 
   1139 StubCache* IC::stub_cache() {
   1140   if (IsAnyLoad()) {
   1141     return isolate()->load_stub_cache();
   1142   } else {
   1143     DCHECK(IsAnyStore());
   1144     return isolate()->store_stub_cache();
   1145   }
   1146 }
   1147 
   1148 void IC::UpdateMegamorphicCache(Map* map, Name* name, Object* handler) {
   1149   stub_cache()->Set(name, map, handler);
   1150 }
   1151 
   1152 void IC::TraceHandlerCacheHitStats(LookupIterator* lookup) {
   1153   if (!FLAG_runtime_call_stats) return;
   1154 
   1155   if (IsAnyLoad()) {
   1156     switch (lookup->state()) {
   1157       case LookupIterator::ACCESS_CHECK:
   1158         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_AccessCheck);
   1159         break;
   1160       case LookupIterator::INTEGER_INDEXED_EXOTIC:
   1161         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_Exotic);
   1162         break;
   1163       case LookupIterator::INTERCEPTOR:
   1164         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_Interceptor);
   1165         break;
   1166       case LookupIterator::JSPROXY:
   1167         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_JSProxy);
   1168         break;
   1169       case LookupIterator::NOT_FOUND:
   1170         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_NonExistent);
   1171         break;
   1172       case LookupIterator::ACCESSOR:
   1173         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_Accessor);
   1174         break;
   1175       case LookupIterator::DATA:
   1176         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_Data);
   1177         break;
   1178       case LookupIterator::TRANSITION:
   1179         TRACE_HANDLER_STATS(isolate(), LoadIC_HandlerCacheHit_Transition);
   1180         break;
   1181     }
   1182   } else if (IsAnyStore()) {
   1183     switch (lookup->state()) {
   1184       case LookupIterator::ACCESS_CHECK:
   1185         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_AccessCheck);
   1186         break;
   1187       case LookupIterator::INTEGER_INDEXED_EXOTIC:
   1188         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_Exotic);
   1189         break;
   1190       case LookupIterator::INTERCEPTOR:
   1191         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_Interceptor);
   1192         break;
   1193       case LookupIterator::JSPROXY:
   1194         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_JSProxy);
   1195         break;
   1196       case LookupIterator::NOT_FOUND:
   1197         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_NonExistent);
   1198         break;
   1199       case LookupIterator::ACCESSOR:
   1200         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_Accessor);
   1201         break;
   1202       case LookupIterator::DATA:
   1203         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_Data);
   1204         break;
   1205       case LookupIterator::TRANSITION:
   1206         TRACE_HANDLER_STATS(isolate(), StoreIC_HandlerCacheHit_Transition);
   1207         break;
   1208     }
   1209   } else {
   1210     TRACE_HANDLER_STATS(isolate(), IC_HandlerCacheHit);
   1211   }
   1212 }
   1213 
   1214 Handle<Object> IC::ComputeHandler(LookupIterator* lookup,
   1215                                   Handle<Object> value) {
   1216   // Try to find a globally shared handler stub.
   1217   Handle<Object> shared_handler = GetMapIndependentHandler(lookup);
   1218   if (!shared_handler.is_null()) {
   1219     DCHECK(IC::IsHandler(*shared_handler));
   1220     return shared_handler;
   1221   }
   1222 
   1223   // Otherwise check the map's handler cache for a map-specific handler, and
   1224   // compile one if the cache comes up empty.
   1225   bool receiver_is_holder =
   1226       lookup->GetReceiver().is_identical_to(lookup->GetHolder<JSObject>());
   1227   CacheHolderFlag flag;
   1228   Handle<Map> stub_holder_map;
   1229   if (IsAnyLoad()) {
   1230     stub_holder_map = IC::GetHandlerCacheHolder(
   1231         receiver_map(), receiver_is_holder, isolate(), &flag);
   1232   } else {
   1233     DCHECK(IsAnyStore());
   1234     // Store handlers cannot be cached on prototypes.
   1235     flag = kCacheOnReceiver;
   1236     stub_holder_map = receiver_map();
   1237   }
   1238 
   1239   Handle<Object> handler = PropertyHandlerCompiler::Find(
   1240       lookup->name(), stub_holder_map, handler_kind(), flag);
   1241   // Use the cached value if it exists, and if it is different from the
   1242   // handler that just missed.
   1243   if (!handler.is_null()) {
   1244     Handle<Object> current_handler;
   1245     if (maybe_handler_.ToHandle(&current_handler)) {
   1246       if (!current_handler.is_identical_to(handler)) {
   1247         TraceHandlerCacheHitStats(lookup);
   1248         return handler;
   1249       }
   1250     } else {
   1251       // maybe_handler_ is only populated for MONOMORPHIC and POLYMORPHIC ICs.
   1252       // In MEGAMORPHIC case, check if the handler in the megamorphic stub
   1253       // cache (which just missed) is different from the cached handler.
   1254       if (state() == MEGAMORPHIC && lookup->GetReceiver()->IsHeapObject()) {
   1255         Map* map = Handle<HeapObject>::cast(lookup->GetReceiver())->map();
   1256         Object* megamorphic_cached_handler =
   1257             stub_cache()->Get(*lookup->name(), map);
   1258         if (megamorphic_cached_handler != *handler) {
   1259           TraceHandlerCacheHitStats(lookup);
   1260           return handler;
   1261         }
   1262       } else {
   1263         TraceHandlerCacheHitStats(lookup);
   1264         return handler;
   1265       }
   1266     }
   1267   }
   1268 
   1269   handler = CompileHandler(lookup, value, flag);
   1270   DCHECK(IC::IsHandler(*handler));
   1271   if (handler->IsCode()) {
   1272     Handle<Code> code = Handle<Code>::cast(handler);
   1273     DCHECK_EQ(Code::ExtractCacheHolderFromFlags(code->flags()), flag);
   1274     Map::UpdateCodeCache(stub_holder_map, lookup->name(), code);
   1275   }
   1276   return handler;
   1277 }
   1278 
   1279 Handle<Object> LoadIC::GetMapIndependentHandler(LookupIterator* lookup) {
   1280   Handle<Object> receiver = lookup->GetReceiver();
   1281   if (receiver->IsString() &&
   1282       Name::Equals(isolate()->factory()->length_string(), lookup->name())) {
   1283     FieldIndex index = FieldIndex::ForInObjectOffset(String::kLengthOffset);
   1284     return SimpleFieldLoad(isolate(), index);
   1285   }
   1286 
   1287   if (receiver->IsStringWrapper() &&
   1288       Name::Equals(isolate()->factory()->length_string(), lookup->name())) {
   1289     TRACE_HANDLER_STATS(isolate(), LoadIC_StringLengthStub);
   1290     StringLengthStub string_length_stub(isolate());
   1291     return string_length_stub.GetCode();
   1292   }
   1293 
   1294   // Use specialized code for getting prototype of functions.
   1295   if (receiver->IsJSFunction() &&
   1296       Name::Equals(isolate()->factory()->prototype_string(), lookup->name()) &&
   1297       receiver->IsConstructor() &&
   1298       !Handle<JSFunction>::cast(receiver)
   1299            ->map()
   1300            ->has_non_instance_prototype()) {
   1301     Handle<Code> stub;
   1302     TRACE_HANDLER_STATS(isolate(), LoadIC_FunctionPrototypeStub);
   1303     return isolate()->builtins()->LoadIC_FunctionPrototype();
   1304   }
   1305 
   1306   Handle<Map> map = receiver_map();
   1307   Handle<JSObject> holder = lookup->GetHolder<JSObject>();
   1308   bool receiver_is_holder = receiver.is_identical_to(holder);
   1309   switch (lookup->state()) {
   1310     case LookupIterator::INTERCEPTOR:
   1311       break;  // Custom-compiled handler.
   1312 
   1313     case LookupIterator::ACCESSOR: {
   1314       // Use simple field loads for some well-known callback properties.
   1315       // The method will only return true for absolute truths based on the
   1316       // receiver maps.
   1317       int object_offset;
   1318       if (Accessors::IsJSObjectFieldAccessor(map, lookup->name(),
   1319                                              &object_offset)) {
   1320         FieldIndex index = FieldIndex::ForInObjectOffset(object_offset, *map);
   1321         return SimpleFieldLoad(isolate(), index);
   1322       }
   1323 
   1324       if (IsCompatibleReceiver(lookup, map)) {
   1325         Handle<Object> accessors = lookup->GetAccessors();
   1326         if (accessors->IsAccessorPair()) {
   1327           if (!holder->HasFastProperties()) {
   1328             TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1329             return slow_stub();
   1330           }
   1331           // When debugging we need to go the slow path to flood the accessor.
   1332           if (GetHostFunction()->shared()->HasDebugInfo()) {
   1333             TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1334             return slow_stub();
   1335           }
   1336           break;  // Custom-compiled handler.
   1337         } else if (accessors->IsAccessorInfo()) {
   1338           Handle<AccessorInfo> info = Handle<AccessorInfo>::cast(accessors);
   1339           if (v8::ToCData<Address>(info->getter()) == nullptr) {
   1340             TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1341             return slow_stub();
   1342           }
   1343           // Ruled out by IsCompatibleReceiver() above.
   1344           DCHECK(AccessorInfo::IsCompatibleReceiverMap(isolate(), info, map));
   1345           if (!holder->HasFastProperties() ||
   1346               (info->is_sloppy() && !receiver->IsJSReceiver())) {
   1347             DCHECK(!holder->HasFastProperties() || !receiver_is_holder);
   1348             TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1349             return slow_stub();
   1350           }
   1351           Handle<Object> smi_handler =
   1352               LoadHandler::LoadApiGetter(isolate(), lookup->GetAccessorIndex());
   1353           if (receiver_is_holder) {
   1354             TRACE_HANDLER_STATS(isolate(), LoadIC_LoadApiGetterDH);
   1355             return smi_handler;
   1356           }
   1357           if (!IsLoadGlobalIC()) {
   1358             TRACE_HANDLER_STATS(isolate(), LoadIC_LoadApiGetterFromPrototypeDH);
   1359             return LoadFromPrototype(map, holder, lookup->name(), smi_handler);
   1360           }
   1361           break;  // Custom-compiled handler.
   1362         }
   1363       }
   1364       TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1365       return slow_stub();
   1366     }
   1367 
   1368     case LookupIterator::DATA: {
   1369       DCHECK_EQ(kData, lookup->property_details().kind());
   1370       if (lookup->is_dictionary_holder()) {
   1371         if (!IsLoadIC() && !IsLoadGlobalIC()) {  // IsKeyedLoadIC()?
   1372           TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1373           return slow_stub();
   1374         }
   1375         if (holder->IsJSGlobalObject()) {
   1376           break;  // Custom-compiled handler.
   1377         }
   1378         // There is only one shared stub for loading normalized
   1379         // properties. It does not traverse the prototype chain, so the
   1380         // property must be found in the object for the stub to be
   1381         // applicable.
   1382         if (!receiver_is_holder) {
   1383           TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1384           return slow_stub();
   1385         }
   1386         TRACE_HANDLER_STATS(isolate(), LoadIC_LoadNormal);
   1387         return isolate()->builtins()->LoadIC_Normal();
   1388       }
   1389 
   1390       // -------------- Fields --------------
   1391       if (lookup->property_details().location() == kField) {
   1392         FieldIndex field = lookup->GetFieldIndex();
   1393         Handle<Object> smi_handler = SimpleFieldLoad(isolate(), field);
   1394         if (receiver_is_holder) {
   1395           return smi_handler;
   1396         }
   1397         TRACE_HANDLER_STATS(isolate(), LoadIC_LoadFieldFromPrototypeDH);
   1398         return LoadFromPrototype(map, holder, lookup->name(), smi_handler);
   1399       }
   1400 
   1401       // -------------- Constant properties --------------
   1402       DCHECK_EQ(kDescriptor, lookup->property_details().location());
   1403       Handle<Object> smi_handler =
   1404           LoadHandler::LoadConstant(isolate(), lookup->GetConstantIndex());
   1405       if (receiver_is_holder) {
   1406         TRACE_HANDLER_STATS(isolate(), LoadIC_LoadConstantDH);
   1407         return smi_handler;
   1408       }
   1409       TRACE_HANDLER_STATS(isolate(), LoadIC_LoadConstantFromPrototypeDH);
   1410       return LoadFromPrototype(map, holder, lookup->name(), smi_handler);
   1411     }
   1412 
   1413     case LookupIterator::INTEGER_INDEXED_EXOTIC:
   1414       TRACE_HANDLER_STATS(isolate(), LoadIC_SlowStub);
   1415       return slow_stub();
   1416     case LookupIterator::ACCESS_CHECK:
   1417     case LookupIterator::JSPROXY:
   1418     case LookupIterator::NOT_FOUND:
   1419     case LookupIterator::TRANSITION:
   1420       UNREACHABLE();
   1421   }
   1422 
   1423   return Handle<Code>::null();
   1424 }
   1425 
   1426 Handle<Object> LoadIC::CompileHandler(LookupIterator* lookup,
   1427                                       Handle<Object> unused,
   1428                                       CacheHolderFlag cache_holder) {
   1429   Handle<JSObject> holder = lookup->GetHolder<JSObject>();
   1430 #ifdef DEBUG
   1431   // Only used by DCHECKs below.
   1432   Handle<Object> receiver = lookup->GetReceiver();
   1433   bool receiver_is_holder = receiver.is_identical_to(holder);
   1434 #endif
   1435   // Non-map-specific handler stubs have already been selected.
   1436   DCHECK(!receiver->IsString() ||
   1437          !Name::Equals(isolate()->factory()->length_string(), lookup->name()));
   1438   DCHECK(!receiver->IsStringWrapper() ||
   1439          !Name::Equals(isolate()->factory()->length_string(), lookup->name()));
   1440 
   1441   DCHECK(!(
   1442       receiver->IsJSFunction() &&
   1443       Name::Equals(isolate()->factory()->prototype_string(), lookup->name()) &&
   1444       receiver->IsConstructor() &&
   1445       !Handle<JSFunction>::cast(receiver)
   1446            ->map()
   1447            ->has_non_instance_prototype()));
   1448 
   1449   Handle<Map> map = receiver_map();
   1450   switch (lookup->state()) {
   1451     case LookupIterator::INTERCEPTOR: {
   1452       DCHECK(!holder->GetNamedInterceptor()->getter()->IsUndefined(isolate()));
   1453       TRACE_HANDLER_STATS(isolate(), LoadIC_LoadInterceptor);
   1454       NamedLoadHandlerCompiler compiler(isolate(), map, holder, cache_holder);
   1455       // Perform a lookup behind the interceptor. Copy the LookupIterator since
   1456       // the original iterator will be used to fetch the value.
   1457       LookupIterator it = *lookup;
   1458       it.Next();
   1459       LookupForRead(&it);
   1460       return compiler.CompileLoadInterceptor(&it);
   1461     }
   1462 
   1463     case LookupIterator::ACCESSOR: {
   1464 #ifdef DEBUG
   1465       int object_offset;
   1466       DCHECK(!Accessors::IsJSObjectFieldAccessor(map, lookup->name(),
   1467                                                  &object_offset));
   1468 #endif
   1469 
   1470       DCHECK(IsCompatibleReceiver(lookup, map));
   1471       Handle<Object> accessors = lookup->GetAccessors();
   1472       if (accessors->IsAccessorPair()) {
   1473         if (lookup->TryLookupCachedProperty()) {
   1474           DCHECK_EQ(LookupIterator::DATA, lookup->state());
   1475           return ComputeHandler(lookup);
   1476         }
   1477         DCHECK(holder->HasFastProperties());
   1478         DCHECK(!GetHostFunction()->shared()->HasDebugInfo());
   1479         Handle<Object> getter(Handle<AccessorPair>::cast(accessors)->getter(),
   1480                               isolate());
   1481         CallOptimization call_optimization(getter);
   1482         NamedLoadHandlerCompiler compiler(isolate(), map, holder, cache_holder);
   1483         if (call_optimization.is_simple_api_call()) {
   1484           TRACE_HANDLER_STATS(isolate(), LoadIC_LoadCallback);
   1485           int index = lookup->GetAccessorIndex();
   1486           Handle<Code> code = compiler.CompileLoadCallback(
   1487               lookup->name(), call_optimization, index, slow_stub());
   1488           return code;
   1489         }
   1490         TRACE_HANDLER_STATS(isolate(), LoadIC_LoadViaGetter);
   1491         int expected_arguments = Handle<JSFunction>::cast(getter)
   1492                                      ->shared()
   1493                                      ->internal_formal_parameter_count();
   1494         return compiler.CompileLoadViaGetter(
   1495             lookup->name(), lookup->GetAccessorIndex(), expected_arguments);
   1496       } else {
   1497         DCHECK(accessors->IsAccessorInfo());
   1498         Handle<AccessorInfo> info = Handle<AccessorInfo>::cast(accessors);
   1499         DCHECK(v8::ToCData<Address>(info->getter()) != nullptr);
   1500         DCHECK(AccessorInfo::IsCompatibleReceiverMap(isolate(), info, map));
   1501         DCHECK(holder->HasFastProperties());
   1502         DCHECK(!receiver_is_holder);
   1503         DCHECK(!info->is_sloppy() || receiver->IsJSReceiver());
   1504         TRACE_HANDLER_STATS(isolate(), LoadIC_LoadCallback);
   1505         NamedLoadHandlerCompiler compiler(isolate(), map, holder, cache_holder);
   1506         Handle<Code> code =
   1507             compiler.CompileLoadCallback(lookup->name(), info, slow_stub());
   1508         return code;
   1509       }
   1510       UNREACHABLE();
   1511     }
   1512 
   1513     case LookupIterator::DATA: {
   1514       DCHECK(lookup->is_dictionary_holder());
   1515       DCHECK(IsLoadIC() || IsLoadGlobalIC());
   1516       DCHECK(holder->IsJSGlobalObject());
   1517       TRACE_HANDLER_STATS(isolate(), LoadIC_LoadGlobal);
   1518       NamedLoadHandlerCompiler compiler(isolate(), map, holder, cache_holder);
   1519       Handle<PropertyCell> cell = lookup->GetPropertyCell();
   1520       Handle<Code> code = compiler.CompileLoadGlobal(cell, lookup->name(),
   1521                                                      lookup->IsConfigurable());
   1522       return code;
   1523     }
   1524 
   1525     case LookupIterator::INTEGER_INDEXED_EXOTIC:
   1526     case LookupIterator::ACCESS_CHECK:
   1527     case LookupIterator::JSPROXY:
   1528     case LookupIterator::NOT_FOUND:
   1529     case LookupIterator::TRANSITION:
   1530       UNREACHABLE();
   1531   }
   1532   UNREACHABLE();
   1533   return slow_stub();
   1534 }
   1535 
   1536 
   1537 static Handle<Object> TryConvertKey(Handle<Object> key, Isolate* isolate) {
   1538   // This helper implements a few common fast cases for converting
   1539   // non-smi keys of keyed loads/stores to a smi or a string.
   1540   if (key->IsHeapNumber()) {
   1541     double value = Handle<HeapNumber>::cast(key)->value();
   1542     if (std::isnan(value)) {
   1543       key = isolate->factory()->nan_string();
   1544     } else {
   1545       int int_value = FastD2I(value);
   1546       if (value == int_value && Smi::IsValid(int_value)) {
   1547         key = handle(Smi::FromInt(int_value), isolate);
   1548       }
   1549     }
   1550   } else if (key->IsUndefined(isolate)) {
   1551     key = isolate->factory()->undefined_string();
   1552   } else if (key->IsString()) {
   1553     key = isolate->factory()->InternalizeString(Handle<String>::cast(key));
   1554   }
   1555   return key;
   1556 }
   1557 
   1558 void KeyedLoadIC::UpdateLoadElement(Handle<HeapObject> receiver) {
   1559   Handle<Map> receiver_map(receiver->map(), isolate());
   1560   DCHECK(receiver_map->instance_type() != JS_VALUE_TYPE &&
   1561          receiver_map->instance_type() != JS_PROXY_TYPE);  // Checked by caller.
   1562   MapHandleList target_receiver_maps;
   1563   TargetMaps(&target_receiver_maps);
   1564 
   1565   if (target_receiver_maps.length() == 0) {
   1566     Handle<Object> handler =
   1567         ElementHandlerCompiler::GetKeyedLoadHandler(receiver_map, isolate());
   1568     return ConfigureVectorState(Handle<Name>(), receiver_map, handler);
   1569   }
   1570 
   1571   for (int i = 0; i < target_receiver_maps.length(); i++) {
   1572     Handle<Map> map = target_receiver_maps.at(i);
   1573     if (map.is_null()) continue;
   1574     if (map->instance_type() == JS_VALUE_TYPE) {
   1575       TRACE_GENERIC_IC("JSValue");
   1576       return;
   1577     }
   1578     if (map->instance_type() == JS_PROXY_TYPE) {
   1579       TRACE_GENERIC_IC("JSProxy");
   1580       return;
   1581     }
   1582   }
   1583 
   1584   // The first time a receiver is seen that is a transitioned version of the
   1585   // previous monomorphic receiver type, assume the new ElementsKind is the
   1586   // monomorphic type. This benefits global arrays that only transition
   1587   // once, and all call sites accessing them are faster if they remain
   1588   // monomorphic. If this optimistic assumption is not true, the IC will
   1589   // miss again and it will become polymorphic and support both the
   1590   // untransitioned and transitioned maps.
   1591   if (state() == MONOMORPHIC && !receiver->IsString() &&
   1592       IsMoreGeneralElementsKindTransition(
   1593           target_receiver_maps.at(0)->elements_kind(),
   1594           Handle<JSObject>::cast(receiver)->GetElementsKind())) {
   1595     Handle<Object> handler =
   1596         ElementHandlerCompiler::GetKeyedLoadHandler(receiver_map, isolate());
   1597     return ConfigureVectorState(Handle<Name>(), receiver_map, handler);
   1598   }
   1599 
   1600   DCHECK(state() != GENERIC);
   1601 
   1602   // Determine the list of receiver maps that this call site has seen,
   1603   // adding the map that was just encountered.
   1604   if (!AddOneReceiverMapIfMissing(&target_receiver_maps, receiver_map)) {
   1605     // If the miss wasn't due to an unseen map, a polymorphic stub
   1606     // won't help, use the generic stub.
   1607     TRACE_GENERIC_IC("same map added twice");
   1608     return;
   1609   }
   1610 
   1611   // If the maximum number of receiver maps has been exceeded, use the generic
   1612   // version of the IC.
   1613   if (target_receiver_maps.length() > kMaxKeyedPolymorphism) {
   1614     TRACE_GENERIC_IC("max polymorph exceeded");
   1615     return;
   1616   }
   1617 
   1618   List<Handle<Object>> handlers(target_receiver_maps.length());
   1619   ElementHandlerCompiler compiler(isolate());
   1620   compiler.CompileElementHandlers(&target_receiver_maps, &handlers);
   1621   ConfigureVectorState(Handle<Name>(), &target_receiver_maps, &handlers);
   1622 }
   1623 
   1624 
   1625 MaybeHandle<Object> KeyedLoadIC::Load(Handle<Object> object,
   1626                                       Handle<Object> key) {
   1627   if (MigrateDeprecated(object)) {
   1628     Handle<Object> result;
   1629     ASSIGN_RETURN_ON_EXCEPTION(
   1630         isolate(), result, Runtime::GetObjectProperty(isolate(), object, key),
   1631         Object);
   1632     return result;
   1633   }
   1634 
   1635   Handle<Object> load_handle;
   1636 
   1637   // Check for non-string values that can be converted into an
   1638   // internalized string directly or is representable as a smi.
   1639   key = TryConvertKey(key, isolate());
   1640 
   1641   uint32_t index;
   1642   if ((key->IsInternalizedString() &&
   1643        !String::cast(*key)->AsArrayIndex(&index)) ||
   1644       key->IsSymbol()) {
   1645     ASSIGN_RETURN_ON_EXCEPTION(isolate(), load_handle,
   1646                                LoadIC::Load(object, Handle<Name>::cast(key)),
   1647                                Object);
   1648   } else if (FLAG_use_ic && !object->IsAccessCheckNeeded() &&
   1649              !object->IsJSValue()) {
   1650     if ((object->IsJSObject() && key->IsSmi()) ||
   1651         (object->IsString() && key->IsNumber())) {
   1652       UpdateLoadElement(Handle<HeapObject>::cast(object));
   1653       if (is_vector_set()) {
   1654         TRACE_IC("LoadIC", key);
   1655       }
   1656     }
   1657   }
   1658 
   1659   if (!is_vector_set()) {
   1660     ConfigureVectorState(MEGAMORPHIC, key);
   1661     TRACE_IC("LoadIC", key);
   1662   }
   1663 
   1664   if (!load_handle.is_null()) return load_handle;
   1665 
   1666   Handle<Object> result;
   1667   ASSIGN_RETURN_ON_EXCEPTION(isolate(), result,
   1668                              Runtime::GetObjectProperty(isolate(), object, key),
   1669                              Object);
   1670   return result;
   1671 }
   1672 
   1673 
   1674 bool StoreIC::LookupForWrite(LookupIterator* it, Handle<Object> value,
   1675                              JSReceiver::StoreFromKeyed store_mode) {
   1676   // Disable ICs for non-JSObjects for now.
   1677   Handle<Object> object = it->GetReceiver();
   1678   if (!object->IsJSObject()) return false;
   1679   Handle<JSObject> receiver = Handle<JSObject>::cast(object);
   1680   DCHECK(!receiver->map()->is_deprecated());
   1681 
   1682   for (; it->IsFound(); it->Next()) {
   1683     switch (it->state()) {
   1684       case LookupIterator::NOT_FOUND:
   1685       case LookupIterator::TRANSITION:
   1686         UNREACHABLE();
   1687       case LookupIterator::JSPROXY:
   1688         return false;
   1689       case LookupIterator::INTERCEPTOR: {
   1690         Handle<JSObject> holder = it->GetHolder<JSObject>();
   1691         InterceptorInfo* info = holder->GetNamedInterceptor();
   1692         if (it->HolderIsReceiverOrHiddenPrototype()) {
   1693           return !info->non_masking() && receiver.is_identical_to(holder) &&
   1694                  !info->setter()->IsUndefined(it->isolate());
   1695         } else if (!info->getter()->IsUndefined(it->isolate()) ||
   1696                    !info->query()->IsUndefined(it->isolate())) {
   1697           return false;
   1698         }
   1699         break;
   1700       }
   1701       case LookupIterator::ACCESS_CHECK:
   1702         if (it->GetHolder<JSObject>()->IsAccessCheckNeeded()) return false;
   1703         break;
   1704       case LookupIterator::ACCESSOR:
   1705         return !it->IsReadOnly();
   1706       case LookupIterator::INTEGER_INDEXED_EXOTIC:
   1707         return false;
   1708       case LookupIterator::DATA: {
   1709         if (it->IsReadOnly()) return false;
   1710         Handle<JSObject> holder = it->GetHolder<JSObject>();
   1711         if (receiver.is_identical_to(holder)) {
   1712           it->PrepareForDataProperty(value);
   1713           // The previous receiver map might just have been deprecated,
   1714           // so reload it.
   1715           update_receiver_map(receiver);
   1716           return true;
   1717         }
   1718 
   1719         // Receiver != holder.
   1720         if (receiver->IsJSGlobalProxy()) {
   1721           PrototypeIterator iter(it->isolate(), receiver);
   1722           return it->GetHolder<Object>().is_identical_to(
   1723               PrototypeIterator::GetCurrent(iter));
   1724         }
   1725 
   1726         if (it->HolderIsReceiverOrHiddenPrototype()) return false;
   1727 
   1728         if (it->ExtendingNonExtensible(receiver)) return false;
   1729         it->PrepareTransitionToDataProperty(receiver, value, NONE, store_mode);
   1730         return it->IsCacheableTransition();
   1731       }
   1732     }
   1733   }
   1734 
   1735   receiver = it->GetStoreTarget();
   1736   if (it->ExtendingNonExtensible(receiver)) return false;
   1737   it->PrepareTransitionToDataProperty(receiver, value, NONE, store_mode);
   1738   return it->IsCacheableTransition();
   1739 }
   1740 
   1741 
   1742 MaybeHandle<Object> StoreIC::Store(Handle<Object> object, Handle<Name> name,
   1743                                    Handle<Object> value,
   1744                                    JSReceiver::StoreFromKeyed store_mode) {
   1745   if (object->IsJSGlobalObject() && name->IsString()) {
   1746     // Look up in script context table.
   1747     Handle<String> str_name = Handle<String>::cast(name);
   1748     Handle<JSGlobalObject> global = Handle<JSGlobalObject>::cast(object);
   1749     Handle<ScriptContextTable> script_contexts(
   1750         global->native_context()->script_context_table());
   1751 
   1752     ScriptContextTable::LookupResult lookup_result;
   1753     if (ScriptContextTable::Lookup(script_contexts, str_name, &lookup_result)) {
   1754       Handle<Context> script_context = ScriptContextTable::GetContext(
   1755           script_contexts, lookup_result.context_index);
   1756       if (lookup_result.mode == CONST) {
   1757         return TypeError(MessageTemplate::kConstAssign, object, name);
   1758       }
   1759 
   1760       Handle<Object> previous_value =
   1761           FixedArray::get(*script_context, lookup_result.slot_index, isolate());
   1762 
   1763       if (previous_value->IsTheHole(isolate())) {
   1764         // Do not install stubs and stay pre-monomorphic for
   1765         // uninitialized accesses.
   1766         return ReferenceError(name);
   1767       }
   1768 
   1769       if (FLAG_use_ic &&
   1770           StoreScriptContextFieldStub::Accepted(&lookup_result)) {
   1771         TRACE_HANDLER_STATS(isolate(), StoreIC_StoreScriptContextFieldStub);
   1772         StoreScriptContextFieldStub stub(isolate(), &lookup_result);
   1773         PatchCache(name, stub.GetCode());
   1774       }
   1775 
   1776       script_context->set(lookup_result.slot_index, *value);
   1777       return value;
   1778     }
   1779   }
   1780 
   1781   // TODO(verwaest): Let SetProperty do the migration, since storing a property
   1782   // might deprecate the current map again, if value does not fit.
   1783   if (MigrateDeprecated(object) || object->IsJSProxy()) {
   1784     Handle<Object> result;
   1785     ASSIGN_RETURN_ON_EXCEPTION(
   1786         isolate(), result,
   1787         Object::SetProperty(object, name, value, language_mode()), Object);
   1788     return result;
   1789   }
   1790 
   1791   // If the object is undefined or null it's illegal to try to set any
   1792   // properties on it; throw a TypeError in that case.
   1793   if (object->IsNullOrUndefined(isolate())) {
   1794     if (FLAG_use_ic && state() != UNINITIALIZED && state() != PREMONOMORPHIC) {
   1795       // Ensure the IC state progresses.
   1796       TRACE_HANDLER_STATS(isolate(), StoreIC_NonReceiver);
   1797       update_receiver_map(object);
   1798       PatchCache(name, slow_stub());
   1799       TRACE_IC("StoreIC", name);
   1800     }
   1801     return TypeError(MessageTemplate::kNonObjectPropertyStore, object, name);
   1802   }
   1803 
   1804   if (state() != UNINITIALIZED) {
   1805     JSObject::MakePrototypesFast(object, kStartAtPrototype, isolate());
   1806   }
   1807   LookupIterator it(object, name);
   1808   if (FLAG_use_ic) UpdateCaches(&it, value, store_mode);
   1809 
   1810   MAYBE_RETURN_NULL(
   1811       Object::SetProperty(&it, value, language_mode(), store_mode));
   1812   return value;
   1813 }
   1814 
   1815 void StoreIC::UpdateCaches(LookupIterator* lookup, Handle<Object> value,
   1816                            JSReceiver::StoreFromKeyed store_mode) {
   1817   if (state() == UNINITIALIZED) {
   1818     // This is the first time we execute this inline cache. Set the target to
   1819     // the pre monomorphic stub to delay setting the monomorphic state.
   1820     TRACE_HANDLER_STATS(isolate(), StoreIC_Premonomorphic);
   1821     ConfigureVectorState(PREMONOMORPHIC, Handle<Object>());
   1822     TRACE_IC("StoreIC", lookup->name());
   1823     return;
   1824   }
   1825 
   1826   Handle<Object> handler;
   1827   if (LookupForWrite(lookup, value, store_mode)) {
   1828     handler = ComputeHandler(lookup, value);
   1829   } else {
   1830     TRACE_GENERIC_IC("LookupForWrite said 'false'");
   1831     handler = slow_stub();
   1832   }
   1833 
   1834   PatchCache(lookup->name(), handler);
   1835   TRACE_IC("StoreIC", lookup->name());
   1836 }
   1837 
   1838 Handle<Object> StoreIC::StoreTransition(Handle<Map> receiver_map,
   1839                                         Handle<JSObject> holder,
   1840                                         Handle<Map> transition,
   1841                                         Handle<Name> name) {
   1842   int descriptor = transition->LastAdded();
   1843   Handle<DescriptorArray> descriptors(transition->instance_descriptors());
   1844   PropertyDetails details = descriptors->GetDetails(descriptor);
   1845   Representation representation = details.representation();
   1846   DCHECK(!representation.IsNone());
   1847 
   1848   // Declarative handlers don't support access checks.
   1849   DCHECK(!transition->is_access_check_needed());
   1850 
   1851   Handle<Object> smi_handler;
   1852   DCHECK_EQ(kData, details.kind());
   1853   if (details.location() == kDescriptor) {
   1854     smi_handler = StoreHandler::TransitionToConstant(isolate(), descriptor);
   1855 
   1856   } else {
   1857     DCHECK_EQ(kField, details.location());
   1858     bool extend_storage =
   1859         Map::cast(transition->GetBackPointer())->unused_property_fields() == 0;
   1860 
   1861     FieldIndex index = FieldIndex::ForDescriptor(*transition, descriptor);
   1862     smi_handler = StoreHandler::TransitionToField(
   1863         isolate(), descriptor, index, representation, extend_storage);
   1864   }
   1865   // |holder| is either a receiver if the property is non-existent or
   1866   // one of the prototypes.
   1867   DCHECK(!holder.is_null());
   1868   bool is_nonexistent = holder->map() == transition->GetBackPointer();
   1869   if (is_nonexistent) holder = Handle<JSObject>::null();
   1870 
   1871   int checks_count =
   1872       GetPrototypeCheckCount(isolate(), receiver_map, holder, name);
   1873   DCHECK_LE(0, checks_count);
   1874   DCHECK(!receiver_map->IsJSGlobalObjectMap());
   1875 
   1876   Handle<Object> validity_cell =
   1877       Map::GetOrCreatePrototypeChainValidityCell(receiver_map, isolate());
   1878   if (validity_cell.is_null()) {
   1879     DCHECK_EQ(0, checks_count);
   1880     validity_cell = handle(Smi::FromInt(0), isolate());
   1881   }
   1882 
   1883   Handle<WeakCell> transition_cell = Map::WeakCellForMap(transition);
   1884 
   1885   Factory* factory = isolate()->factory();
   1886   if (checks_count == 0) {
   1887     return factory->NewTuple3(transition_cell, smi_handler, validity_cell);
   1888   }
   1889   Handle<FixedArray> handler_array(factory->NewFixedArray(
   1890       StoreHandler::kFirstPrototypeIndex + checks_count, TENURED));
   1891   handler_array->set(StoreHandler::kSmiHandlerIndex, *smi_handler);
   1892   handler_array->set(StoreHandler::kValidityCellIndex, *validity_cell);
   1893   handler_array->set(StoreHandler::kTransitionCellIndex, *transition_cell);
   1894   InitPrototypeChecks(isolate(), receiver_map, holder, name, handler_array,
   1895                       StoreHandler::kFirstPrototypeIndex);
   1896   return handler_array;
   1897 }
   1898 
   1899 static Handle<Code> PropertyCellStoreHandler(
   1900     Isolate* isolate, Handle<JSObject> receiver, Handle<JSGlobalObject> holder,
   1901     Handle<Name> name, Handle<PropertyCell> cell, PropertyCellType type) {
   1902   auto constant_type = Nothing<PropertyCellConstantType>();
   1903   if (type == PropertyCellType::kConstantType) {
   1904     constant_type = Just(cell->GetConstantType());
   1905   }
   1906   StoreGlobalStub stub(isolate, type, constant_type,
   1907                        receiver->IsJSGlobalProxy());
   1908   auto code = stub.GetCodeCopyFromTemplate(holder, cell);
   1909   // TODO(verwaest): Move caching of these NORMAL stubs outside as well.
   1910   HeapObject::UpdateMapCodeCache(receiver, name, code);
   1911   return code;
   1912 }
   1913 
   1914 Handle<Object> StoreIC::GetMapIndependentHandler(LookupIterator* lookup) {
   1915   DCHECK_NE(LookupIterator::JSPROXY, lookup->state());
   1916 
   1917   // This is currently guaranteed by checks in StoreIC::Store.
   1918   Handle<JSObject> receiver = Handle<JSObject>::cast(lookup->GetReceiver());
   1919   Handle<JSObject> holder = lookup->GetHolder<JSObject>();
   1920   DCHECK(!receiver->IsAccessCheckNeeded() || lookup->name()->IsPrivate());
   1921 
   1922   switch (lookup->state()) {
   1923     case LookupIterator::TRANSITION: {
   1924       auto store_target = lookup->GetStoreTarget();
   1925       if (store_target->IsJSGlobalObject()) {
   1926         break;  // Custom-compiled handler.
   1927       }
   1928       // Currently not handled by CompileStoreTransition.
   1929       if (!holder->HasFastProperties()) {
   1930         TRACE_GENERIC_IC("transition from slow");
   1931         TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1932         return slow_stub();
   1933       }
   1934       DCHECK(lookup->IsCacheableTransition());
   1935       Handle<Map> transition = lookup->transition_map();
   1936       TRACE_HANDLER_STATS(isolate(), StoreIC_StoreTransitionDH);
   1937       return StoreTransition(receiver_map(), holder, transition,
   1938                              lookup->name());
   1939     }
   1940 
   1941     case LookupIterator::INTERCEPTOR: {
   1942       DCHECK(!holder->GetNamedInterceptor()->setter()->IsUndefined(isolate()));
   1943       TRACE_HANDLER_STATS(isolate(), StoreIC_StoreInterceptorStub);
   1944       StoreInterceptorStub stub(isolate());
   1945       return stub.GetCode();
   1946     }
   1947 
   1948     case LookupIterator::ACCESSOR: {
   1949       if (!holder->HasFastProperties()) {
   1950         TRACE_GENERIC_IC("accessor on slow map");
   1951         TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1952         return slow_stub();
   1953       }
   1954       Handle<Object> accessors = lookup->GetAccessors();
   1955       if (accessors->IsAccessorInfo()) {
   1956         Handle<AccessorInfo> info = Handle<AccessorInfo>::cast(accessors);
   1957         if (v8::ToCData<Address>(info->setter()) == nullptr) {
   1958           TRACE_GENERIC_IC("setter == nullptr");
   1959           TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1960           return slow_stub();
   1961         }
   1962         if (AccessorInfo::cast(*accessors)->is_special_data_property() &&
   1963             !lookup->HolderIsReceiverOrHiddenPrototype()) {
   1964           TRACE_GENERIC_IC("special data property in prototype chain");
   1965           TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1966           return slow_stub();
   1967         }
   1968         if (!AccessorInfo::IsCompatibleReceiverMap(isolate(), info,
   1969                                                    receiver_map())) {
   1970           TRACE_GENERIC_IC("incompatible receiver type");
   1971           TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1972           return slow_stub();
   1973         }
   1974         if (info->is_sloppy() && !receiver->IsJSReceiver()) {
   1975           TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1976           return slow_stub();
   1977         }
   1978         break;  // Custom-compiled handler.
   1979       } else if (accessors->IsAccessorPair()) {
   1980         Handle<Object> setter(Handle<AccessorPair>::cast(accessors)->setter(),
   1981                               isolate());
   1982         if (!setter->IsJSFunction() && !setter->IsFunctionTemplateInfo()) {
   1983           TRACE_GENERIC_IC("setter not a function");
   1984           TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1985           return slow_stub();
   1986         }
   1987         CallOptimization call_optimization(setter);
   1988         if (call_optimization.is_simple_api_call()) {
   1989           if (call_optimization.IsCompatibleReceiver(receiver, holder)) {
   1990             break;  // Custom-compiled handler.
   1991           }
   1992           TRACE_GENERIC_IC("incompatible receiver");
   1993           TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1994           return slow_stub();
   1995         }
   1996         break;  // Custom-compiled handler.
   1997       }
   1998       TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   1999       return slow_stub();
   2000     }
   2001 
   2002     case LookupIterator::DATA: {
   2003       DCHECK_EQ(kData, lookup->property_details().kind());
   2004       if (lookup->is_dictionary_holder()) {
   2005         if (holder->IsJSGlobalObject()) {
   2006           break;  // Custom-compiled handler.
   2007         }
   2008         TRACE_HANDLER_STATS(isolate(), StoreIC_StoreNormal);
   2009         DCHECK(holder.is_identical_to(receiver));
   2010         return isolate()->builtins()->StoreIC_Normal();
   2011       }
   2012 
   2013       // -------------- Fields --------------
   2014       if (lookup->property_details().location() == kField) {
   2015         TRACE_HANDLER_STATS(isolate(), StoreIC_StoreFieldDH);
   2016         int descriptor = lookup->GetFieldDescriptorIndex();
   2017         FieldIndex index = lookup->GetFieldIndex();
   2018         return StoreHandler::StoreField(isolate(), descriptor, index,
   2019                                         lookup->constness(),
   2020                                         lookup->representation());
   2021       }
   2022 
   2023       // -------------- Constant properties --------------
   2024       DCHECK_EQ(kDescriptor, lookup->property_details().location());
   2025       TRACE_GENERIC_IC("constant property");
   2026       TRACE_HANDLER_STATS(isolate(), StoreIC_SlowStub);
   2027       return slow_stub();
   2028     }
   2029 
   2030     case LookupIterator::INTEGER_INDEXED_EXOTIC:
   2031     case LookupIterator::ACCESS_CHECK:
   2032     case LookupIterator::JSPROXY:
   2033     case LookupIterator::NOT_FOUND:
   2034       UNREACHABLE();
   2035   }
   2036   return Handle<Code>::null();
   2037 }
   2038 
   2039 Handle<Object> StoreIC::CompileHandler(LookupIterator* lookup,
   2040                                        Handle<Object> value,
   2041                                        CacheHolderFlag cache_holder) {
   2042   DCHECK_NE(LookupIterator::JSPROXY, lookup->state());
   2043 
   2044   // This is currently guaranteed by checks in StoreIC::Store.
   2045   Handle<JSObject> receiver = Handle<JSObject>::cast(lookup->GetReceiver());
   2046   Handle<JSObject> holder = lookup->GetHolder<JSObject>();
   2047   DCHECK(!receiver->IsAccessCheckNeeded() || lookup->name()->IsPrivate());
   2048 
   2049   switch (lookup->state()) {
   2050     case LookupIterator::TRANSITION: {
   2051       auto store_target = lookup->GetStoreTarget();
   2052       if (store_target->IsJSGlobalObject()) {
   2053         TRACE_HANDLER_STATS(isolate(), StoreIC_StoreGlobalTransition);
   2054         Handle<PropertyCell> cell = lookup->transition_cell();
   2055         cell->set_value(*value);
   2056         Handle<Code> code = PropertyCellStoreHandler(
   2057             isolate(), store_target, Handle<JSGlobalObject>::cast(store_target),
   2058             lookup->name(), cell, PropertyCellType::kConstant);
   2059         cell->set_value(isolate()->heap()->the_hole_value());
   2060         return code;
   2061       }
   2062       UNREACHABLE();
   2063     }
   2064 
   2065     case LookupIterator::INTERCEPTOR:
   2066       UNREACHABLE();
   2067 
   2068     case LookupIterator::ACCESSOR: {
   2069       DCHECK(holder->HasFastProperties());
   2070       Handle<Object> accessors = lookup->GetAccessors();
   2071       if (accessors->IsAccessorInfo()) {
   2072         Handle<AccessorInfo> info = Handle<AccessorInfo>::cast(accessors);
   2073         DCHECK(v8::ToCData<Address>(info->setter()) != 0);
   2074         DCHECK(!AccessorInfo::cast(*accessors)->is_special_data_property() ||
   2075                lookup->HolderIsReceiverOrHiddenPrototype());
   2076         DCHECK(AccessorInfo::IsCompatibleReceiverMap(isolate(), info,
   2077                                                      receiver_map()));
   2078         DCHECK(!info->is_sloppy() || receiver->IsJSReceiver());
   2079         TRACE_HANDLER_STATS(isolate(), StoreIC_StoreCallback);
   2080         NamedStoreHandlerCompiler compiler(isolate(), receiver_map(), holder);
   2081         // TODO(ishell): don't hard-code language mode into the handler because
   2082         // this handler can be re-used through megamorphic stub cache for wrong
   2083         // language mode.
   2084         // Better pass vector/slot to Runtime::kStoreCallbackProperty and
   2085         // let it decode the language mode from the IC kind.
   2086         Handle<Code> code = compiler.CompileStoreCallback(
   2087             receiver, lookup->name(), info, language_mode());
   2088         return code;
   2089       } else {
   2090         DCHECK(accessors->IsAccessorPair());
   2091         Handle<Object> setter(Handle<AccessorPair>::cast(accessors)->setter(),
   2092                               isolate());
   2093         DCHECK(setter->IsJSFunction() || setter->IsFunctionTemplateInfo());
   2094         CallOptimization call_optimization(setter);
   2095         NamedStoreHandlerCompiler compiler(isolate(), receiver_map(), holder);
   2096         if (call_optimization.is_simple_api_call()) {
   2097           DCHECK(call_optimization.IsCompatibleReceiver(receiver, holder));
   2098           TRACE_HANDLER_STATS(isolate(), StoreIC_StoreCallback);
   2099           Handle<Code> code = compiler.CompileStoreCallback(
   2100               receiver, lookup->name(), call_optimization,
   2101               lookup->GetAccessorIndex(), slow_stub());
   2102           return code;
   2103         }
   2104         TRACE_HANDLER_STATS(isolate(), StoreIC_StoreViaSetter);
   2105         int expected_arguments = JSFunction::cast(*setter)
   2106                                      ->shared()
   2107                                      ->internal_formal_parameter_count();
   2108         return compiler.CompileStoreViaSetter(receiver, lookup->name(),
   2109                                               lookup->GetAccessorIndex(),
   2110                                               expected_arguments);
   2111       }
   2112     }
   2113 
   2114     case LookupIterator::DATA: {
   2115       DCHECK(lookup->is_dictionary_holder());
   2116       DCHECK(holder->IsJSGlobalObject());
   2117       TRACE_HANDLER_STATS(isolate(), StoreIC_StoreGlobal);
   2118       DCHECK(holder.is_identical_to(receiver) ||
   2119              receiver->map()->prototype() == *holder);
   2120       auto cell = lookup->GetPropertyCell();
   2121       auto updated_type =
   2122           PropertyCell::UpdatedType(cell, value, lookup->property_details());
   2123       auto code = PropertyCellStoreHandler(isolate(), receiver,
   2124                                            Handle<JSGlobalObject>::cast(holder),
   2125                                            lookup->name(), cell, updated_type);
   2126       return code;
   2127     }
   2128 
   2129     case LookupIterator::INTEGER_INDEXED_EXOTIC:
   2130     case LookupIterator::ACCESS_CHECK:
   2131     case LookupIterator::JSPROXY:
   2132     case LookupIterator::NOT_FOUND:
   2133       UNREACHABLE();
   2134   }
   2135   UNREACHABLE();
   2136   return slow_stub();
   2137 }
   2138 
   2139 void KeyedStoreIC::UpdateStoreElement(Handle<Map> receiver_map,
   2140                                       KeyedAccessStoreMode store_mode) {
   2141   MapHandleList target_receiver_maps;
   2142   TargetMaps(&target_receiver_maps);
   2143   if (target_receiver_maps.length() == 0) {
   2144     Handle<Map> monomorphic_map =
   2145         ComputeTransitionedMap(receiver_map, store_mode);
   2146     store_mode = GetNonTransitioningStoreMode(store_mode);
   2147     Handle<Object> handler = StoreElementHandler(monomorphic_map, store_mode);
   2148     return ConfigureVectorState(Handle<Name>(), monomorphic_map, handler);
   2149   }
   2150 
   2151   for (int i = 0; i < target_receiver_maps.length(); i++) {
   2152     if (!target_receiver_maps.at(i).is_null() &&
   2153         target_receiver_maps.at(i)->instance_type() == JS_VALUE_TYPE) {
   2154       TRACE_GENERIC_IC("JSValue");
   2155       return;
   2156     }
   2157   }
   2158 
   2159   // There are several special cases where an IC that is MONOMORPHIC can still
   2160   // transition to a different GetNonTransitioningStoreMode IC that handles a
   2161   // superset of the original IC. Handle those here if the receiver map hasn't
   2162   // changed or it has transitioned to a more general kind.
   2163   KeyedAccessStoreMode old_store_mode = GetKeyedAccessStoreMode();
   2164   Handle<Map> previous_receiver_map = target_receiver_maps.at(0);
   2165   if (state() == MONOMORPHIC) {
   2166     Handle<Map> transitioned_receiver_map = receiver_map;
   2167     if (IsTransitionStoreMode(store_mode)) {
   2168       transitioned_receiver_map =
   2169           ComputeTransitionedMap(receiver_map, store_mode);
   2170     }
   2171     if ((receiver_map.is_identical_to(previous_receiver_map) &&
   2172          IsTransitionStoreMode(store_mode)) ||
   2173         IsTransitionOfMonomorphicTarget(*previous_receiver_map,
   2174                                         *transitioned_receiver_map)) {
   2175       // If the "old" and "new" maps are in the same elements map family, or
   2176       // if they at least come from the same origin for a transitioning store,
   2177       // stay MONOMORPHIC and use the map for the most generic ElementsKind.
   2178       store_mode = GetNonTransitioningStoreMode(store_mode);
   2179       Handle<Object> handler =
   2180           StoreElementHandler(transitioned_receiver_map, store_mode);
   2181       ConfigureVectorState(Handle<Name>(), transitioned_receiver_map, handler);
   2182       return;
   2183     }
   2184     if (receiver_map.is_identical_to(previous_receiver_map) &&
   2185         old_store_mode == STANDARD_STORE &&
   2186         (store_mode == STORE_AND_GROW_NO_TRANSITION ||
   2187          store_mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS ||
   2188          store_mode == STORE_NO_TRANSITION_HANDLE_COW)) {
   2189       // A "normal" IC that handles stores can switch to a version that can
   2190       // grow at the end of the array, handle OOB accesses or copy COW arrays
   2191       // and still stay MONOMORPHIC.
   2192       Handle<Object> handler = StoreElementHandler(receiver_map, store_mode);
   2193       return ConfigureVectorState(Handle<Name>(), receiver_map, handler);
   2194     }
   2195   }
   2196 
   2197   DCHECK(state() != GENERIC);
   2198 
   2199   bool map_added =
   2200       AddOneReceiverMapIfMissing(&target_receiver_maps, receiver_map);
   2201 
   2202   if (IsTransitionStoreMode(store_mode)) {
   2203     Handle<Map> transitioned_receiver_map =
   2204         ComputeTransitionedMap(receiver_map, store_mode);
   2205     map_added |= AddOneReceiverMapIfMissing(&target_receiver_maps,
   2206                                             transitioned_receiver_map);
   2207   }
   2208 
   2209   if (!map_added) {
   2210     // If the miss wasn't due to an unseen map, a polymorphic stub
   2211     // won't help, use the megamorphic stub which can handle everything.
   2212     TRACE_GENERIC_IC("same map added twice");
   2213     return;
   2214   }
   2215 
   2216   // If the maximum number of receiver maps has been exceeded, use the
   2217   // megamorphic version of the IC.
   2218   if (target_receiver_maps.length() > kMaxKeyedPolymorphism) return;
   2219 
   2220   // Make sure all polymorphic handlers have the same store mode, otherwise the
   2221   // megamorphic stub must be used.
   2222   store_mode = GetNonTransitioningStoreMode(store_mode);
   2223   if (old_store_mode != STANDARD_STORE) {
   2224     if (store_mode == STANDARD_STORE) {
   2225       store_mode = old_store_mode;
   2226     } else if (store_mode != old_store_mode) {
   2227       TRACE_GENERIC_IC("store mode mismatch");
   2228       return;
   2229     }
   2230   }
   2231 
   2232   // If the store mode isn't the standard mode, make sure that all polymorphic
   2233   // receivers are either external arrays, or all "normal" arrays. Otherwise,
   2234   // use the megamorphic stub.
   2235   if (store_mode != STANDARD_STORE) {
   2236     int external_arrays = 0;
   2237     for (int i = 0; i < target_receiver_maps.length(); ++i) {
   2238       if (target_receiver_maps[i]->has_fixed_typed_array_elements()) {
   2239         external_arrays++;
   2240       }
   2241     }
   2242     if (external_arrays != 0 &&
   2243         external_arrays != target_receiver_maps.length()) {
   2244       TRACE_GENERIC_IC("unsupported combination of external and normal arrays");
   2245       return;
   2246     }
   2247   }
   2248 
   2249   MapHandleList transitioned_maps(target_receiver_maps.length());
   2250   List<Handle<Object>> handlers(target_receiver_maps.length());
   2251   StoreElementPolymorphicHandlers(&target_receiver_maps, &transitioned_maps,
   2252                                   &handlers, store_mode);
   2253   ConfigureVectorState(&target_receiver_maps, &transitioned_maps, &handlers);
   2254 }
   2255 
   2256 
   2257 Handle<Map> KeyedStoreIC::ComputeTransitionedMap(
   2258     Handle<Map> map, KeyedAccessStoreMode store_mode) {
   2259   switch (store_mode) {
   2260     case STORE_TRANSITION_TO_OBJECT:
   2261     case STORE_AND_GROW_TRANSITION_TO_OBJECT: {
   2262       ElementsKind kind = IsFastHoleyElementsKind(map->elements_kind())
   2263                               ? FAST_HOLEY_ELEMENTS
   2264                               : FAST_ELEMENTS;
   2265       return Map::TransitionElementsTo(map, kind);
   2266     }
   2267     case STORE_TRANSITION_TO_DOUBLE:
   2268     case STORE_AND_GROW_TRANSITION_TO_DOUBLE: {
   2269       ElementsKind kind = IsFastHoleyElementsKind(map->elements_kind())
   2270                               ? FAST_HOLEY_DOUBLE_ELEMENTS
   2271                               : FAST_DOUBLE_ELEMENTS;
   2272       return Map::TransitionElementsTo(map, kind);
   2273     }
   2274     case STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS:
   2275       DCHECK(map->has_fixed_typed_array_elements());
   2276     // Fall through
   2277     case STORE_NO_TRANSITION_HANDLE_COW:
   2278     case STANDARD_STORE:
   2279     case STORE_AND_GROW_NO_TRANSITION:
   2280       return map;
   2281   }
   2282   UNREACHABLE();
   2283   return MaybeHandle<Map>().ToHandleChecked();
   2284 }
   2285 
   2286 Handle<Object> KeyedStoreIC::StoreElementHandler(
   2287     Handle<Map> receiver_map, KeyedAccessStoreMode store_mode) {
   2288   DCHECK(store_mode == STANDARD_STORE ||
   2289          store_mode == STORE_AND_GROW_NO_TRANSITION ||
   2290          store_mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS ||
   2291          store_mode == STORE_NO_TRANSITION_HANDLE_COW);
   2292 
   2293   ElementsKind elements_kind = receiver_map->elements_kind();
   2294   bool is_jsarray = receiver_map->instance_type() == JS_ARRAY_TYPE;
   2295   Handle<Code> stub;
   2296   if (receiver_map->has_sloppy_arguments_elements()) {
   2297     TRACE_HANDLER_STATS(isolate(), KeyedStoreIC_KeyedStoreSloppyArgumentsStub);
   2298     stub = KeyedStoreSloppyArgumentsStub(isolate(), store_mode).GetCode();
   2299   } else if (receiver_map->has_fast_elements() ||
   2300              receiver_map->has_fixed_typed_array_elements()) {
   2301     TRACE_HANDLER_STATS(isolate(), KeyedStoreIC_StoreFastElementStub);
   2302     stub =
   2303         StoreFastElementStub(isolate(), is_jsarray, elements_kind, store_mode)
   2304             .GetCode();
   2305   } else {
   2306     TRACE_HANDLER_STATS(isolate(), KeyedStoreIC_StoreElementStub);
   2307     DCHECK_EQ(DICTIONARY_ELEMENTS, elements_kind);
   2308     stub = StoreSlowElementStub(isolate(), store_mode).GetCode();
   2309   }
   2310   Handle<Object> validity_cell =
   2311       Map::GetOrCreatePrototypeChainValidityCell(receiver_map, isolate());
   2312   if (validity_cell.is_null()) {
   2313     return stub;
   2314   }
   2315   return isolate()->factory()->NewTuple2(validity_cell, stub);
   2316 }
   2317 
   2318 void KeyedStoreIC::StoreElementPolymorphicHandlers(
   2319     MapHandleList* receiver_maps, MapHandleList* transitioned_maps,
   2320     List<Handle<Object>>* handlers, KeyedAccessStoreMode store_mode) {
   2321   DCHECK(store_mode == STANDARD_STORE ||
   2322          store_mode == STORE_AND_GROW_NO_TRANSITION ||
   2323          store_mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS ||
   2324          store_mode == STORE_NO_TRANSITION_HANDLE_COW);
   2325 
   2326   for (int i = 0; i < receiver_maps->length(); ++i) {
   2327     Handle<Map> receiver_map(receiver_maps->at(i));
   2328     Handle<Object> handler;
   2329     Handle<Map> transitioned_map;
   2330     {
   2331       Map* tmap = receiver_map->FindElementsKindTransitionedMap(receiver_maps);
   2332       if (tmap != nullptr) transitioned_map = handle(tmap);
   2333     }
   2334 
   2335     // TODO(mvstanton): The code below is doing pessimistic elements
   2336     // transitions. I would like to stop doing that and rely on Allocation Site
   2337     // Tracking to do a better job of ensuring the data types are what they need
   2338     // to be. Not all the elements are in place yet, pessimistic elements
   2339     // transitions are still important for performance.
   2340     if (!transitioned_map.is_null()) {
   2341       bool is_js_array = receiver_map->instance_type() == JS_ARRAY_TYPE;
   2342       ElementsKind elements_kind = receiver_map->elements_kind();
   2343       TRACE_HANDLER_STATS(isolate(),
   2344                           KeyedStoreIC_ElementsTransitionAndStoreStub);
   2345       Handle<Code> stub =
   2346           ElementsTransitionAndStoreStub(isolate(), elements_kind,
   2347                                          transitioned_map->elements_kind(),
   2348                                          is_js_array, store_mode)
   2349               .GetCode();
   2350       Handle<Object> validity_cell =
   2351           Map::GetOrCreatePrototypeChainValidityCell(receiver_map, isolate());
   2352       if (validity_cell.is_null()) {
   2353         handler = stub;
   2354       } else {
   2355         handler = isolate()->factory()->NewTuple2(validity_cell, stub);
   2356       }
   2357 
   2358     } else if (receiver_map->instance_type() < FIRST_JS_RECEIVER_TYPE) {
   2359       // TODO(mvstanton): Consider embedding store_mode in the state of the slow
   2360       // keyed store ic for uniformity.
   2361       TRACE_HANDLER_STATS(isolate(), KeyedStoreIC_SlowStub);
   2362       handler = isolate()->builtins()->KeyedStoreIC_Slow();
   2363     } else {
   2364       handler = StoreElementHandler(receiver_map, store_mode);
   2365     }
   2366     DCHECK(!handler.is_null());
   2367     handlers->Add(handler);
   2368     transitioned_maps->Add(transitioned_map);
   2369   }
   2370 }
   2371 
   2372 bool IsOutOfBoundsAccess(Handle<JSObject> receiver, uint32_t index) {
   2373   uint32_t length = 0;
   2374   if (receiver->IsJSArray()) {
   2375     JSArray::cast(*receiver)->length()->ToArrayLength(&length);
   2376   } else {
   2377     length = static_cast<uint32_t>(receiver->elements()->length());
   2378   }
   2379   return index >= length;
   2380 }
   2381 
   2382 
   2383 static KeyedAccessStoreMode GetStoreMode(Handle<JSObject> receiver,
   2384                                          uint32_t index, Handle<Object> value) {
   2385   bool oob_access = IsOutOfBoundsAccess(receiver, index);
   2386   // Don't consider this a growing store if the store would send the receiver to
   2387   // dictionary mode.
   2388   bool allow_growth = receiver->IsJSArray() && oob_access &&
   2389                       !receiver->WouldConvertToSlowElements(index);
   2390   if (allow_growth) {
   2391     // Handle growing array in stub if necessary.
   2392     if (receiver->HasFastSmiElements()) {
   2393       if (value->IsHeapNumber()) {
   2394         return STORE_AND_GROW_TRANSITION_TO_DOUBLE;
   2395       }
   2396       if (value->IsHeapObject()) {
   2397         return STORE_AND_GROW_TRANSITION_TO_OBJECT;
   2398       }
   2399     } else if (receiver->HasFastDoubleElements()) {
   2400       if (!value->IsSmi() && !value->IsHeapNumber()) {
   2401         return STORE_AND_GROW_TRANSITION_TO_OBJECT;
   2402       }
   2403     }
   2404     return STORE_AND_GROW_NO_TRANSITION;
   2405   } else {
   2406     // Handle only in-bounds elements accesses.
   2407     if (receiver->HasFastSmiElements()) {
   2408       if (value->IsHeapNumber()) {
   2409         return STORE_TRANSITION_TO_DOUBLE;
   2410       } else if (value->IsHeapObject()) {
   2411         return STORE_TRANSITION_TO_OBJECT;
   2412       }
   2413     } else if (receiver->HasFastDoubleElements()) {
   2414       if (!value->IsSmi() && !value->IsHeapNumber()) {
   2415         return STORE_TRANSITION_TO_OBJECT;
   2416       }
   2417     }
   2418     if (!FLAG_trace_external_array_abuse &&
   2419         receiver->map()->has_fixed_typed_array_elements() && oob_access) {
   2420       return STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS;
   2421     }
   2422     Heap* heap = receiver->GetHeap();
   2423     if (receiver->elements()->map() == heap->fixed_cow_array_map()) {
   2424       return STORE_NO_TRANSITION_HANDLE_COW;
   2425     } else {
   2426       return STANDARD_STORE;
   2427     }
   2428   }
   2429 }
   2430 
   2431 
   2432 MaybeHandle<Object> KeyedStoreIC::Store(Handle<Object> object,
   2433                                         Handle<Object> key,
   2434                                         Handle<Object> value) {
   2435   // TODO(verwaest): Let SetProperty do the migration, since storing a property
   2436   // might deprecate the current map again, if value does not fit.
   2437   if (MigrateDeprecated(object)) {
   2438     Handle<Object> result;
   2439     ASSIGN_RETURN_ON_EXCEPTION(
   2440         isolate(), result, Runtime::SetObjectProperty(isolate(), object, key,
   2441                                                       value, language_mode()),
   2442         Object);
   2443     return result;
   2444   }
   2445 
   2446   // Check for non-string values that can be converted into an
   2447   // internalized string directly or is representable as a smi.
   2448   key = TryConvertKey(key, isolate());
   2449 
   2450   Handle<Object> store_handle;
   2451 
   2452   uint32_t index;
   2453   if ((key->IsInternalizedString() &&
   2454        !String::cast(*key)->AsArrayIndex(&index)) ||
   2455       key->IsSymbol()) {
   2456     ASSIGN_RETURN_ON_EXCEPTION(
   2457         isolate(), store_handle,
   2458         StoreIC::Store(object, Handle<Name>::cast(key), value,
   2459                        JSReceiver::MAY_BE_STORE_FROM_KEYED),
   2460         Object);
   2461     if (!is_vector_set()) {
   2462       ConfigureVectorState(MEGAMORPHIC, key);
   2463       TRACE_GENERIC_IC("unhandled internalized string key");
   2464       TRACE_IC("StoreIC", key);
   2465     }
   2466     return store_handle;
   2467   }
   2468 
   2469   bool use_ic = FLAG_use_ic && !object->IsStringWrapper() &&
   2470                 !object->IsAccessCheckNeeded() && !object->IsJSGlobalProxy();
   2471   if (use_ic && !object->IsSmi()) {
   2472     // Don't use ICs for maps of the objects in Array's prototype chain. We
   2473     // expect to be able to trap element sets to objects with those maps in
   2474     // the runtime to enable optimization of element hole access.
   2475     Handle<HeapObject> heap_object = Handle<HeapObject>::cast(object);
   2476     if (heap_object->map()->IsMapInArrayPrototypeChain()) {
   2477       TRACE_GENERIC_IC("map in array prototype");
   2478       use_ic = false;
   2479     }
   2480   }
   2481 
   2482   Handle<Map> old_receiver_map;
   2483   bool is_arguments = false;
   2484   bool key_is_valid_index = false;
   2485   KeyedAccessStoreMode store_mode = STANDARD_STORE;
   2486   if (use_ic && object->IsJSObject()) {
   2487     Handle<JSObject> receiver = Handle<JSObject>::cast(object);
   2488     old_receiver_map = handle(receiver->map(), isolate());
   2489     is_arguments = receiver->IsJSArgumentsObject();
   2490     if (!is_arguments) {
   2491       key_is_valid_index = key->IsSmi() && Smi::cast(*key)->value() >= 0;
   2492       if (key_is_valid_index) {
   2493         uint32_t index = static_cast<uint32_t>(Smi::cast(*key)->value());
   2494         store_mode = GetStoreMode(receiver, index, value);
   2495       }
   2496     }
   2497   }
   2498 
   2499   DCHECK(store_handle.is_null());
   2500   ASSIGN_RETURN_ON_EXCEPTION(isolate(), store_handle,
   2501                              Runtime::SetObjectProperty(isolate(), object, key,
   2502                                                         value, language_mode()),
   2503                              Object);
   2504 
   2505   if (use_ic) {
   2506     if (!old_receiver_map.is_null()) {
   2507       if (is_arguments) {
   2508         TRACE_GENERIC_IC("arguments receiver");
   2509       } else if (key_is_valid_index) {
   2510         // We should go generic if receiver isn't a dictionary, but our
   2511         // prototype chain does have dictionary elements. This ensures that
   2512         // other non-dictionary receivers in the polymorphic case benefit
   2513         // from fast path keyed stores.
   2514         if (!old_receiver_map->DictionaryElementsInPrototypeChainOnly()) {
   2515           UpdateStoreElement(old_receiver_map, store_mode);
   2516         } else {
   2517           TRACE_GENERIC_IC("dictionary or proxy prototype");
   2518         }
   2519       } else {
   2520         TRACE_GENERIC_IC("non-smi-like key");
   2521       }
   2522     } else {
   2523       TRACE_GENERIC_IC("non-JSObject receiver");
   2524     }
   2525   }
   2526 
   2527   if (!is_vector_set()) {
   2528     ConfigureVectorState(MEGAMORPHIC, key);
   2529   }
   2530   TRACE_IC("StoreIC", key);
   2531 
   2532   return store_handle;
   2533 }
   2534 
   2535 
   2536 #undef TRACE_IC
   2537 
   2538 
   2539 // ----------------------------------------------------------------------------
   2540 // Static IC stub generators.
   2541 //
   2542 
   2543 // Used from ic-<arch>.cc.
   2544 RUNTIME_FUNCTION(Runtime_LoadIC_Miss) {
   2545   HandleScope scope(isolate);
   2546   DCHECK_EQ(4, args.length());
   2547   // Runtime functions don't follow the IC's calling convention.
   2548   Handle<Object> receiver = args.at(0);
   2549   Handle<Name> key = args.at<Name>(1);
   2550   Handle<Smi> slot = args.at<Smi>(2);
   2551   Handle<FeedbackVector> vector = args.at<FeedbackVector>(3);
   2552   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2553   // A monomorphic or polymorphic KeyedLoadIC with a string key can call the
   2554   // LoadIC miss handler if the handler misses. Since the vector Nexus is
   2555   // set up outside the IC, handle that here.
   2556   FeedbackSlotKind kind = vector->GetKind(vector_slot);
   2557   if (IsLoadICKind(kind)) {
   2558     LoadICNexus nexus(vector, vector_slot);
   2559     LoadIC ic(isolate, &nexus);
   2560     ic.UpdateState(receiver, key);
   2561     RETURN_RESULT_OR_FAILURE(isolate, ic.Load(receiver, key));
   2562 
   2563   } else if (IsLoadGlobalICKind(kind)) {
   2564     DCHECK_EQ(*isolate->global_object(), *receiver);
   2565     LoadGlobalICNexus nexus(vector, vector_slot);
   2566     LoadGlobalIC ic(isolate, &nexus);
   2567     ic.UpdateState(receiver, key);
   2568     RETURN_RESULT_OR_FAILURE(isolate, ic.Load(key));
   2569 
   2570   } else {
   2571     DCHECK(IsKeyedLoadICKind(kind));
   2572     KeyedLoadICNexus nexus(vector, vector_slot);
   2573     KeyedLoadIC ic(isolate, &nexus);
   2574     ic.UpdateState(receiver, key);
   2575     RETURN_RESULT_OR_FAILURE(isolate, ic.Load(receiver, key));
   2576   }
   2577 }
   2578 
   2579 // Used from ic-<arch>.cc.
   2580 RUNTIME_FUNCTION(Runtime_LoadGlobalIC_Miss) {
   2581   HandleScope scope(isolate);
   2582   DCHECK_EQ(3, args.length());
   2583   // Runtime functions don't follow the IC's calling convention.
   2584   Handle<JSGlobalObject> global = isolate->global_object();
   2585   Handle<String> name = args.at<String>(0);
   2586   Handle<Smi> slot = args.at<Smi>(1);
   2587   Handle<FeedbackVector> vector = args.at<FeedbackVector>(2);
   2588   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2589 
   2590   LoadGlobalICNexus nexus(vector, vector_slot);
   2591   LoadGlobalIC ic(isolate, &nexus);
   2592   ic.UpdateState(global, name);
   2593 
   2594   Handle<Object> result;
   2595   ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, ic.Load(name));
   2596   return *result;
   2597 }
   2598 
   2599 RUNTIME_FUNCTION(Runtime_LoadGlobalIC_Slow) {
   2600   HandleScope scope(isolate);
   2601   DCHECK_EQ(3, args.length());
   2602   CONVERT_ARG_HANDLE_CHECKED(String, name, 0);
   2603 
   2604   Handle<Context> native_context = isolate->native_context();
   2605   Handle<ScriptContextTable> script_contexts(
   2606       native_context->script_context_table());
   2607 
   2608   ScriptContextTable::LookupResult lookup_result;
   2609   if (ScriptContextTable::Lookup(script_contexts, name, &lookup_result)) {
   2610     Handle<Context> script_context = ScriptContextTable::GetContext(
   2611         script_contexts, lookup_result.context_index);
   2612     Handle<Object> result =
   2613         FixedArray::get(*script_context, lookup_result.slot_index, isolate);
   2614     if (*result == isolate->heap()->the_hole_value()) {
   2615       THROW_NEW_ERROR_RETURN_FAILURE(
   2616           isolate, NewReferenceError(MessageTemplate::kNotDefined, name));
   2617     }
   2618     return *result;
   2619   }
   2620 
   2621   Handle<JSGlobalObject> global(native_context->global_object(), isolate);
   2622   Handle<Object> result;
   2623   bool is_found = false;
   2624   ASSIGN_RETURN_FAILURE_ON_EXCEPTION(
   2625       isolate, result,
   2626       Runtime::GetObjectProperty(isolate, global, name, &is_found));
   2627   if (!is_found) {
   2628     Handle<Smi> slot = args.at<Smi>(1);
   2629     Handle<FeedbackVector> vector = args.at<FeedbackVector>(2);
   2630     FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2631     FeedbackSlotKind kind = vector->GetKind(vector_slot);
   2632     // It is actually a LoadGlobalICs here but the predicate handles this case
   2633     // properly.
   2634     if (LoadIC::ShouldThrowReferenceError(kind)) {
   2635       THROW_NEW_ERROR_RETURN_FAILURE(
   2636           isolate, NewReferenceError(MessageTemplate::kNotDefined, name));
   2637     }
   2638   }
   2639   return *result;
   2640 }
   2641 
   2642 // Used from ic-<arch>.cc
   2643 RUNTIME_FUNCTION(Runtime_KeyedLoadIC_Miss) {
   2644   HandleScope scope(isolate);
   2645   DCHECK_EQ(4, args.length());
   2646   // Runtime functions don't follow the IC's calling convention.
   2647   Handle<Object> receiver = args.at(0);
   2648   Handle<Object> key = args.at(1);
   2649   Handle<Smi> slot = args.at<Smi>(2);
   2650   Handle<FeedbackVector> vector = args.at<FeedbackVector>(3);
   2651   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2652   KeyedLoadICNexus nexus(vector, vector_slot);
   2653   KeyedLoadIC ic(isolate, &nexus);
   2654   ic.UpdateState(receiver, key);
   2655   RETURN_RESULT_OR_FAILURE(isolate, ic.Load(receiver, key));
   2656 }
   2657 
   2658 // Used from ic-<arch>.cc.
   2659 RUNTIME_FUNCTION(Runtime_StoreIC_Miss) {
   2660   HandleScope scope(isolate);
   2661   DCHECK_EQ(5, args.length());
   2662   // Runtime functions don't follow the IC's calling convention.
   2663   Handle<Object> value = args.at(0);
   2664   Handle<Smi> slot = args.at<Smi>(1);
   2665   Handle<FeedbackVector> vector = args.at<FeedbackVector>(2);
   2666   Handle<Object> receiver = args.at(3);
   2667   Handle<Name> key = args.at<Name>(4);
   2668   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2669   FeedbackSlotKind kind = vector->GetKind(vector_slot);
   2670   if (IsStoreICKind(kind) || IsStoreOwnICKind(kind)) {
   2671     StoreICNexus nexus(vector, vector_slot);
   2672     StoreIC ic(isolate, &nexus);
   2673     ic.UpdateState(receiver, key);
   2674     RETURN_RESULT_OR_FAILURE(isolate, ic.Store(receiver, key, value));
   2675   } else {
   2676     DCHECK(IsKeyedStoreICKind(kind));
   2677     KeyedStoreICNexus nexus(vector, vector_slot);
   2678     KeyedStoreIC ic(isolate, &nexus);
   2679     ic.UpdateState(receiver, key);
   2680     RETURN_RESULT_OR_FAILURE(isolate, ic.Store(receiver, key, value));
   2681   }
   2682 }
   2683 
   2684 // Used from ic-<arch>.cc.
   2685 RUNTIME_FUNCTION(Runtime_KeyedStoreIC_Miss) {
   2686   HandleScope scope(isolate);
   2687   DCHECK_EQ(5, args.length());
   2688   // Runtime functions don't follow the IC's calling convention.
   2689   Handle<Object> value = args.at(0);
   2690   Handle<Smi> slot = args.at<Smi>(1);
   2691   Handle<FeedbackVector> vector = args.at<FeedbackVector>(2);
   2692   Handle<Object> receiver = args.at(3);
   2693   Handle<Object> key = args.at(4);
   2694   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2695   KeyedStoreICNexus nexus(vector, vector_slot);
   2696   KeyedStoreIC ic(isolate, &nexus);
   2697   ic.UpdateState(receiver, key);
   2698   RETURN_RESULT_OR_FAILURE(isolate, ic.Store(receiver, key, value));
   2699 }
   2700 
   2701 
   2702 RUNTIME_FUNCTION(Runtime_KeyedStoreIC_Slow) {
   2703   HandleScope scope(isolate);
   2704   DCHECK_EQ(5, args.length());
   2705   // Runtime functions don't follow the IC's calling convention.
   2706   Handle<Object> value = args.at(0);
   2707   Handle<Smi> slot = args.at<Smi>(1);
   2708   Handle<FeedbackVector> vector = args.at<FeedbackVector>(2);
   2709   Handle<Object> object = args.at(3);
   2710   Handle<Object> key = args.at(4);
   2711   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2712   LanguageMode language_mode = vector->GetLanguageMode(vector_slot);
   2713   RETURN_RESULT_OR_FAILURE(
   2714       isolate,
   2715       Runtime::SetObjectProperty(isolate, object, key, value, language_mode));
   2716 }
   2717 
   2718 
   2719 RUNTIME_FUNCTION(Runtime_ElementsTransitionAndStoreIC_Miss) {
   2720   HandleScope scope(isolate);
   2721   DCHECK_EQ(6, args.length());
   2722   // Runtime functions don't follow the IC's calling convention.
   2723   Handle<Object> object = args.at(0);
   2724   Handle<Object> key = args.at(1);
   2725   Handle<Object> value = args.at(2);
   2726   Handle<Map> map = args.at<Map>(3);
   2727   Handle<Smi> slot = args.at<Smi>(4);
   2728   Handle<FeedbackVector> vector = args.at<FeedbackVector>(5);
   2729   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   2730   LanguageMode language_mode = vector->GetLanguageMode(vector_slot);
   2731   if (object->IsJSObject()) {
   2732     JSObject::TransitionElementsKind(Handle<JSObject>::cast(object),
   2733                                      map->elements_kind());
   2734   }
   2735   RETURN_RESULT_OR_FAILURE(
   2736       isolate,
   2737       Runtime::SetObjectProperty(isolate, object, key, value, language_mode));
   2738 }
   2739 
   2740 
   2741 MaybeHandle<Object> BinaryOpIC::Transition(
   2742     Handle<AllocationSite> allocation_site, Handle<Object> left,
   2743     Handle<Object> right) {
   2744   BinaryOpICState state(isolate(), extra_ic_state());
   2745 
   2746   // Compute the actual result using the builtin for the binary operation.
   2747   Handle<Object> result;
   2748   switch (state.op()) {
   2749     default:
   2750       UNREACHABLE();
   2751     case Token::ADD:
   2752       ASSIGN_RETURN_ON_EXCEPTION(isolate(), result,
   2753                                  Object::Add(isolate(), left, right), Object);
   2754       break;
   2755     case Token::SUB:
   2756       ASSIGN_RETURN_ON_EXCEPTION(
   2757           isolate(), result, Object::Subtract(isolate(), left, right), Object);
   2758       break;
   2759     case Token::MUL:
   2760       ASSIGN_RETURN_ON_EXCEPTION(
   2761           isolate(), result, Object::Multiply(isolate(), left, right), Object);
   2762       break;
   2763     case Token::DIV:
   2764       ASSIGN_RETURN_ON_EXCEPTION(
   2765           isolate(), result, Object::Divide(isolate(), left, right), Object);
   2766       break;
   2767     case Token::MOD:
   2768       ASSIGN_RETURN_ON_EXCEPTION(
   2769           isolate(), result, Object::Modulus(isolate(), left, right), Object);
   2770       break;
   2771     case Token::BIT_OR:
   2772       ASSIGN_RETURN_ON_EXCEPTION(
   2773           isolate(), result, Object::BitwiseOr(isolate(), left, right), Object);
   2774       break;
   2775     case Token::BIT_AND:
   2776       ASSIGN_RETURN_ON_EXCEPTION(isolate(), result,
   2777                                  Object::BitwiseAnd(isolate(), left, right),
   2778                                  Object);
   2779       break;
   2780     case Token::BIT_XOR:
   2781       ASSIGN_RETURN_ON_EXCEPTION(isolate(), result,
   2782                                  Object::BitwiseXor(isolate(), left, right),
   2783                                  Object);
   2784       break;
   2785     case Token::SAR:
   2786       ASSIGN_RETURN_ON_EXCEPTION(isolate(), result,
   2787                                  Object::ShiftRight(isolate(), left, right),
   2788                                  Object);
   2789       break;
   2790     case Token::SHR:
   2791       ASSIGN_RETURN_ON_EXCEPTION(
   2792           isolate(), result, Object::ShiftRightLogical(isolate(), left, right),
   2793           Object);
   2794       break;
   2795     case Token::SHL:
   2796       ASSIGN_RETURN_ON_EXCEPTION(
   2797           isolate(), result, Object::ShiftLeft(isolate(), left, right), Object);
   2798       break;
   2799   }
   2800 
   2801   // Do not try to update the target if the code was marked for lazy
   2802   // deoptimization. (Since we do not relocate addresses in these
   2803   // code objects, an attempt to access the target could fail.)
   2804   if (AddressIsDeoptimizedCode()) {
   2805     return result;
   2806   }
   2807 
   2808   // Compute the new state.
   2809   BinaryOpICState old_state(isolate(), target()->extra_ic_state());
   2810   state.Update(left, right, result);
   2811 
   2812   // Check if we have a string operation here.
   2813   Handle<Code> new_target;
   2814   if (!allocation_site.is_null() || state.ShouldCreateAllocationMementos()) {
   2815     // Setup the allocation site on-demand.
   2816     if (allocation_site.is_null()) {
   2817       allocation_site = isolate()->factory()->NewAllocationSite();
   2818     }
   2819 
   2820     // Install the stub with an allocation site.
   2821     BinaryOpICWithAllocationSiteStub stub(isolate(), state);
   2822     new_target = stub.GetCodeCopyFromTemplate(allocation_site);
   2823 
   2824     // Sanity check the trampoline stub.
   2825     DCHECK_EQ(*allocation_site, new_target->FindFirstAllocationSite());
   2826   } else {
   2827     // Install the generic stub.
   2828     BinaryOpICStub stub(isolate(), state);
   2829     new_target = stub.GetCode();
   2830 
   2831     // Sanity check the generic stub.
   2832     DCHECK_NULL(new_target->FindFirstAllocationSite());
   2833   }
   2834   set_target(*new_target);
   2835 
   2836   if (FLAG_ic_stats &
   2837       v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING) {
   2838     auto ic_stats = ICStats::instance();
   2839     ic_stats->Begin();
   2840     ICInfo& ic_info = ic_stats->Current();
   2841     ic_info.type = "BinaryOpIC";
   2842     ic_info.state = old_state.ToString();
   2843     ic_info.state += " => ";
   2844     ic_info.state += state.ToString();
   2845     JavaScriptFrame::CollectTopFrameForICStats(isolate());
   2846     ic_stats->End();
   2847   } else if (FLAG_ic_stats) {
   2848     int line;
   2849     int column;
   2850     Address pc = GetAbstractPC(&line, &column);
   2851     LOG(isolate(),
   2852         BinaryOpIC(pc, line, column, *new_target, old_state.ToString().c_str(),
   2853                    state.ToString().c_str(),
   2854                    allocation_site.is_null() ? nullptr : *allocation_site));
   2855   }
   2856 
   2857   // Patch the inlined smi code as necessary.
   2858   if (!old_state.UseInlinedSmiCode() && state.UseInlinedSmiCode()) {
   2859     PatchInlinedSmiCode(isolate(), address(), ENABLE_INLINED_SMI_CHECK);
   2860   } else if (old_state.UseInlinedSmiCode() && !state.UseInlinedSmiCode()) {
   2861     PatchInlinedSmiCode(isolate(), address(), DISABLE_INLINED_SMI_CHECK);
   2862   }
   2863 
   2864   return result;
   2865 }
   2866 
   2867 
   2868 RUNTIME_FUNCTION(Runtime_BinaryOpIC_Miss) {
   2869   HandleScope scope(isolate);
   2870   DCHECK_EQ(2, args.length());
   2871   typedef BinaryOpDescriptor Descriptor;
   2872   Handle<Object> left = args.at(Descriptor::kLeft);
   2873   Handle<Object> right = args.at(Descriptor::kRight);
   2874   BinaryOpIC ic(isolate);
   2875   RETURN_RESULT_OR_FAILURE(
   2876       isolate, ic.Transition(Handle<AllocationSite>::null(), left, right));
   2877 }
   2878 
   2879 
   2880 RUNTIME_FUNCTION(Runtime_BinaryOpIC_MissWithAllocationSite) {
   2881   HandleScope scope(isolate);
   2882   DCHECK_EQ(3, args.length());
   2883   typedef BinaryOpWithAllocationSiteDescriptor Descriptor;
   2884   Handle<AllocationSite> allocation_site =
   2885       args.at<AllocationSite>(Descriptor::kAllocationSite);
   2886   Handle<Object> left = args.at(Descriptor::kLeft);
   2887   Handle<Object> right = args.at(Descriptor::kRight);
   2888   BinaryOpIC ic(isolate);
   2889   RETURN_RESULT_OR_FAILURE(isolate,
   2890                            ic.Transition(allocation_site, left, right));
   2891 }
   2892 
   2893 Code* CompareIC::GetRawUninitialized(Isolate* isolate, Token::Value op) {
   2894   CompareICStub stub(isolate, op, CompareICState::UNINITIALIZED,
   2895                      CompareICState::UNINITIALIZED,
   2896                      CompareICState::UNINITIALIZED);
   2897   Code* code = NULL;
   2898   CHECK(stub.FindCodeInCache(&code));
   2899   return code;
   2900 }
   2901 
   2902 Code* CompareIC::UpdateCaches(Handle<Object> x, Handle<Object> y) {
   2903   HandleScope scope(isolate());
   2904   CompareICStub old_stub(target()->stub_key(), isolate());
   2905   CompareICState::State new_left =
   2906       CompareICState::NewInputState(old_stub.left(), x);
   2907   CompareICState::State new_right =
   2908       CompareICState::NewInputState(old_stub.right(), y);
   2909   CompareICState::State state = CompareICState::TargetState(
   2910       isolate(), old_stub.state(), old_stub.left(), old_stub.right(), op_,
   2911       HasInlinedSmiCode(address()), x, y);
   2912   CompareICStub stub(isolate(), op_, new_left, new_right, state);
   2913   if (state == CompareICState::KNOWN_RECEIVER) {
   2914     stub.set_known_map(
   2915         Handle<Map>(Handle<JSReceiver>::cast(x)->map(), isolate()));
   2916   }
   2917   Handle<Code> new_target = stub.GetCode();
   2918   set_target(*new_target);
   2919 
   2920   if (FLAG_ic_stats &
   2921       v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING) {
   2922     auto ic_stats = ICStats::instance();
   2923     ic_stats->Begin();
   2924     ICInfo& ic_info = ic_stats->Current();
   2925     ic_info.type = "CompareIC";
   2926     JavaScriptFrame::CollectTopFrameForICStats(isolate());
   2927     ic_info.state = "((";
   2928     ic_info.state += CompareICState::GetStateName(old_stub.left());
   2929     ic_info.state += "+";
   2930     ic_info.state += CompareICState::GetStateName(old_stub.right());
   2931     ic_info.state += "=";
   2932     ic_info.state += CompareICState::GetStateName(old_stub.state());
   2933     ic_info.state += ")->(";
   2934     ic_info.state += CompareICState::GetStateName(new_left);
   2935     ic_info.state += "+";
   2936     ic_info.state += CompareICState::GetStateName(new_right);
   2937     ic_info.state += "=";
   2938     ic_info.state += CompareICState::GetStateName(state);
   2939     ic_info.state += "))#";
   2940     ic_info.state += Token::Name(op_);
   2941     ic_stats->End();
   2942   } else if (FLAG_ic_stats) {
   2943     int line;
   2944     int column;
   2945     Address pc = GetAbstractPC(&line, &column);
   2946     LOG(isolate(),
   2947         CompareIC(pc, line, column, *stub.GetCode(), Token::Name(op_),
   2948                   CompareICState::GetStateName(old_stub.left()),
   2949                   CompareICState::GetStateName(old_stub.right()),
   2950                   CompareICState::GetStateName(old_stub.state()),
   2951                   CompareICState::GetStateName(new_left),
   2952                   CompareICState::GetStateName(new_right),
   2953                   CompareICState::GetStateName(state)));
   2954   }
   2955 
   2956   // Activate inlined smi code.
   2957   if (old_stub.state() == CompareICState::UNINITIALIZED) {
   2958     PatchInlinedSmiCode(isolate(), address(), ENABLE_INLINED_SMI_CHECK);
   2959   }
   2960 
   2961   return *new_target;
   2962 }
   2963 
   2964 
   2965 // Used from CompareICStub::GenerateMiss in code-stubs-<arch>.cc.
   2966 RUNTIME_FUNCTION(Runtime_CompareIC_Miss) {
   2967   HandleScope scope(isolate);
   2968   DCHECK(args.length() == 3);
   2969   CompareIC ic(isolate, static_cast<Token::Value>(args.smi_at(2)));
   2970   return ic.UpdateCaches(args.at(0), args.at(1));
   2971 }
   2972 
   2973 
   2974 RUNTIME_FUNCTION(Runtime_Unreachable) {
   2975   UNREACHABLE();
   2976   CHECK(false);
   2977   return isolate->heap()->undefined_value();
   2978 }
   2979 
   2980 
   2981 Handle<Object> ToBooleanIC::ToBoolean(Handle<Object> object) {
   2982   ToBooleanICStub stub(isolate(), extra_ic_state());
   2983   ToBooleanHints old_hints = stub.hints();
   2984   bool to_boolean_value = stub.UpdateStatus(object);
   2985   ToBooleanHints new_hints = stub.hints();
   2986   Handle<Code> code = stub.GetCode();
   2987   set_target(*code);
   2988 
   2989   // Note: Although a no-op transition is semantically OK, it is hinting at a
   2990   // bug somewhere in our state transition machinery.
   2991   DCHECK_NE(old_hints, new_hints);
   2992   if (V8_UNLIKELY(FLAG_ic_stats)) {
   2993     if (FLAG_ic_stats &
   2994         v8::tracing::TracingCategoryObserver::ENABLED_BY_TRACING) {
   2995       auto ic_stats = ICStats::instance();
   2996       ic_stats->Begin();
   2997       ICInfo& ic_info = ic_stats->Current();
   2998       ic_info.type = "ToBooleanIC";
   2999       ic_info.state = ToString(old_hints);
   3000       ic_info.state += "=>";
   3001       ic_info.state += ToString(new_hints);
   3002       ic_stats->End();
   3003     } else {
   3004       int line;
   3005       int column;
   3006       Address pc = GetAbstractPC(&line, &column);
   3007       LOG(isolate(),
   3008           ToBooleanIC(pc, line, column, *code, ToString(old_hints).c_str(),
   3009                       ToString(new_hints).c_str()));
   3010     }
   3011   }
   3012 
   3013   return isolate()->factory()->ToBoolean(to_boolean_value);
   3014 }
   3015 
   3016 
   3017 RUNTIME_FUNCTION(Runtime_ToBooleanIC_Miss) {
   3018   DCHECK(args.length() == 1);
   3019   HandleScope scope(isolate);
   3020   Handle<Object> object = args.at(0);
   3021   ToBooleanIC ic(isolate);
   3022   return *ic.ToBoolean(object);
   3023 }
   3024 
   3025 
   3026 RUNTIME_FUNCTION(Runtime_StoreCallbackProperty) {
   3027   Handle<JSObject> receiver = args.at<JSObject>(0);
   3028   Handle<JSObject> holder = args.at<JSObject>(1);
   3029   Handle<HeapObject> callback_or_cell = args.at<HeapObject>(2);
   3030   Handle<Name> name = args.at<Name>(3);
   3031   Handle<Object> value = args.at(4);
   3032   CONVERT_LANGUAGE_MODE_ARG_CHECKED(language_mode, 5);
   3033   HandleScope scope(isolate);
   3034 
   3035   if (V8_UNLIKELY(FLAG_runtime_stats)) {
   3036     RETURN_RESULT_OR_FAILURE(
   3037         isolate, Runtime::SetObjectProperty(isolate, receiver, name, value,
   3038                                             language_mode));
   3039   }
   3040 
   3041   Handle<AccessorInfo> callback(
   3042       callback_or_cell->IsWeakCell()
   3043           ? AccessorInfo::cast(WeakCell::cast(*callback_or_cell)->value())
   3044           : AccessorInfo::cast(*callback_or_cell));
   3045 
   3046   DCHECK(callback->IsCompatibleReceiver(*receiver));
   3047 
   3048   Address setter_address = v8::ToCData<Address>(callback->setter());
   3049   v8::AccessorNameSetterCallback fun =
   3050       FUNCTION_CAST<v8::AccessorNameSetterCallback>(setter_address);
   3051   DCHECK(fun != NULL);
   3052 
   3053   Object::ShouldThrow should_throw =
   3054       is_sloppy(language_mode) ? Object::DONT_THROW : Object::THROW_ON_ERROR;
   3055   PropertyCallbackArguments custom_args(isolate, callback->data(), *receiver,
   3056                                         *holder, should_throw);
   3057   custom_args.Call(fun, name, value);
   3058   RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate);
   3059   return *value;
   3060 }
   3061 
   3062 
   3063 /**
   3064  * Attempts to load a property with an interceptor (which must be present),
   3065  * but doesn't search the prototype chain.
   3066  *
   3067  * Returns |Heap::no_interceptor_result_sentinel()| if interceptor doesn't
   3068  * provide any value for the given name.
   3069  */
   3070 RUNTIME_FUNCTION(Runtime_LoadPropertyWithInterceptorOnly) {
   3071   DCHECK(args.length() == NamedLoadHandlerCompiler::kInterceptorArgsLength);
   3072   Handle<Name> name =
   3073       args.at<Name>(NamedLoadHandlerCompiler::kInterceptorArgsNameIndex);
   3074   Handle<Object> receiver =
   3075       args.at(NamedLoadHandlerCompiler::kInterceptorArgsThisIndex);
   3076   Handle<JSObject> holder =
   3077       args.at<JSObject>(NamedLoadHandlerCompiler::kInterceptorArgsHolderIndex);
   3078   HandleScope scope(isolate);
   3079 
   3080   if (!receiver->IsJSReceiver()) {
   3081     ASSIGN_RETURN_FAILURE_ON_EXCEPTION(
   3082         isolate, receiver, Object::ConvertReceiver(isolate, receiver));
   3083   }
   3084 
   3085   InterceptorInfo* interceptor = holder->GetNamedInterceptor();
   3086   PropertyCallbackArguments arguments(isolate, interceptor->data(), *receiver,
   3087                                       *holder, Object::DONT_THROW);
   3088 
   3089   v8::GenericNamedPropertyGetterCallback getter =
   3090       v8::ToCData<v8::GenericNamedPropertyGetterCallback>(
   3091           interceptor->getter());
   3092   Handle<Object> result = arguments.Call(getter, name);
   3093 
   3094   RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate);
   3095 
   3096   if (!result.is_null()) return *result;
   3097   return isolate->heap()->no_interceptor_result_sentinel();
   3098 }
   3099 
   3100 
   3101 /**
   3102  * Loads a property with an interceptor performing post interceptor
   3103  * lookup if interceptor failed.
   3104  */
   3105 RUNTIME_FUNCTION(Runtime_LoadPropertyWithInterceptor) {
   3106   HandleScope scope(isolate);
   3107   DCHECK(args.length() == NamedLoadHandlerCompiler::kInterceptorArgsLength + 2);
   3108   Handle<Name> name =
   3109       args.at<Name>(NamedLoadHandlerCompiler::kInterceptorArgsNameIndex);
   3110   Handle<Object> receiver =
   3111       args.at(NamedLoadHandlerCompiler::kInterceptorArgsThisIndex);
   3112   Handle<JSObject> holder =
   3113       args.at<JSObject>(NamedLoadHandlerCompiler::kInterceptorArgsHolderIndex);
   3114 
   3115   if (!receiver->IsJSReceiver()) {
   3116     ASSIGN_RETURN_FAILURE_ON_EXCEPTION(
   3117         isolate, receiver, Object::ConvertReceiver(isolate, receiver));
   3118   }
   3119 
   3120   InterceptorInfo* interceptor = holder->GetNamedInterceptor();
   3121   PropertyCallbackArguments arguments(isolate, interceptor->data(), *receiver,
   3122                                       *holder, Object::DONT_THROW);
   3123 
   3124   v8::GenericNamedPropertyGetterCallback getter =
   3125       v8::ToCData<v8::GenericNamedPropertyGetterCallback>(
   3126           interceptor->getter());
   3127   Handle<Object> result = arguments.Call(getter, name);
   3128 
   3129   RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate);
   3130 
   3131   if (!result.is_null()) return *result;
   3132 
   3133   LookupIterator it(receiver, name, holder);
   3134   // Skip any lookup work until we hit the (possibly non-masking) interceptor.
   3135   while (it.state() != LookupIterator::INTERCEPTOR ||
   3136          !it.GetHolder<JSObject>().is_identical_to(holder)) {
   3137     DCHECK(it.state() != LookupIterator::ACCESS_CHECK || it.HasAccess());
   3138     it.Next();
   3139   }
   3140   // Skip past the interceptor.
   3141   it.Next();
   3142   ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result, Object::GetProperty(&it));
   3143 
   3144   if (it.IsFound()) return *result;
   3145 
   3146   Handle<Smi> slot = args.at<Smi>(3);
   3147   Handle<FeedbackVector> vector = args.at<FeedbackVector>(4);
   3148   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   3149   FeedbackSlotKind slot_kind = vector->GetKind(vector_slot);
   3150   // It could actually be any kind of load IC slot here but the predicate
   3151   // handles all the cases properly.
   3152   if (!LoadIC::ShouldThrowReferenceError(slot_kind)) {
   3153     return isolate->heap()->undefined_value();
   3154   }
   3155 
   3156   // Throw a reference error.
   3157   THROW_NEW_ERROR_RETURN_FAILURE(
   3158       isolate, NewReferenceError(MessageTemplate::kNotDefined, it.name()));
   3159 }
   3160 
   3161 
   3162 RUNTIME_FUNCTION(Runtime_StorePropertyWithInterceptor) {
   3163   HandleScope scope(isolate);
   3164   DCHECK_EQ(5, args.length());
   3165   // Runtime functions don't follow the IC's calling convention.
   3166   Handle<Object> value = args.at(0);
   3167   Handle<Smi> slot = args.at<Smi>(1);
   3168   Handle<FeedbackVector> vector = args.at<FeedbackVector>(2);
   3169   Handle<JSObject> receiver = args.at<JSObject>(3);
   3170   Handle<Name> name = args.at<Name>(4);
   3171   FeedbackSlot vector_slot = vector->ToSlot(slot->value());
   3172   LanguageMode language_mode = vector->GetLanguageMode(vector_slot);
   3173 
   3174   DCHECK(receiver->HasNamedInterceptor());
   3175   InterceptorInfo* interceptor = receiver->GetNamedInterceptor();
   3176   DCHECK(!interceptor->non_masking());
   3177   PropertyCallbackArguments arguments(isolate, interceptor->data(), *receiver,
   3178                                       *receiver, Object::DONT_THROW);
   3179 
   3180   v8::GenericNamedPropertySetterCallback setter =
   3181       v8::ToCData<v8::GenericNamedPropertySetterCallback>(
   3182           interceptor->setter());
   3183   Handle<Object> result = arguments.Call(setter, name, value);
   3184   RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate);
   3185   if (!result.is_null()) return *value;
   3186 
   3187   LookupIterator it(receiver, name, receiver);
   3188   // Skip past any access check on the receiver.
   3189   if (it.state() == LookupIterator::ACCESS_CHECK) {
   3190     DCHECK(it.HasAccess());
   3191     it.Next();
   3192   }
   3193   // Skip past the interceptor on the receiver.
   3194   DCHECK_EQ(LookupIterator::INTERCEPTOR, it.state());
   3195   it.Next();
   3196 
   3197   MAYBE_RETURN(Object::SetProperty(&it, value, language_mode,
   3198                                    JSReceiver::CERTAINLY_NOT_STORE_FROM_KEYED),
   3199                isolate->heap()->exception());
   3200   return *value;
   3201 }
   3202 
   3203 
   3204 RUNTIME_FUNCTION(Runtime_LoadElementWithInterceptor) {
   3205   // TODO(verwaest): This should probably get the holder and receiver as input.
   3206   HandleScope scope(isolate);
   3207   Handle<JSObject> receiver = args.at<JSObject>(0);
   3208   DCHECK(args.smi_at(1) >= 0);
   3209   uint32_t index = args.smi_at(1);
   3210 
   3211   InterceptorInfo* interceptor = receiver->GetIndexedInterceptor();
   3212   PropertyCallbackArguments arguments(isolate, interceptor->data(), *receiver,
   3213                                       *receiver, Object::DONT_THROW);
   3214 
   3215   v8::IndexedPropertyGetterCallback getter =
   3216       v8::ToCData<v8::IndexedPropertyGetterCallback>(interceptor->getter());
   3217   Handle<Object> result = arguments.Call(getter, index);
   3218 
   3219   RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate);
   3220 
   3221   if (result.is_null()) {
   3222     LookupIterator it(isolate, receiver, index, receiver);
   3223     DCHECK_EQ(LookupIterator::INTERCEPTOR, it.state());
   3224     it.Next();
   3225     ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, result,
   3226                                        Object::GetProperty(&it));
   3227   }
   3228 
   3229   return *result;
   3230 }
   3231 }  // namespace internal
   3232 }  // namespace v8
   3233