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      1 // Copyright 2012 the V8 project authors. All rights reserved.
      2 // Redistribution and use in source and binary forms, with or without
      3 // modification, are permitted provided that the following conditions are
      4 // met:
      5 //
      6 //     * Redistributions of source code must retain the above copyright
      7 //       notice, this list of conditions and the following disclaimer.
      8 //     * Redistributions in binary form must reproduce the above
      9 //       copyright notice, this list of conditions and the following
     10 //       disclaimer in the documentation and/or other materials provided
     11 //       with the distribution.
     12 //     * Neither the name of Google Inc. nor the names of its
     13 //       contributors may be used to endorse or promote products derived
     14 //       from this software without specific prior written permission.
     15 //
     16 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
     17 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
     18 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
     19 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
     20 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
     21 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
     22 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
     23 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
     24 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
     25 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
     26 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
     27 
     28 #include "api.h"
     29 
     30 #include <string.h>  // For memcpy, strlen.
     31 #include <cmath>  // For isnan.
     32 #include "../include/v8-debug.h"
     33 #include "../include/v8-profiler.h"
     34 #include "../include/v8-testing.h"
     35 #include "assert-scope.h"
     36 #include "bootstrapper.h"
     37 #include "code-stubs.h"
     38 #include "compiler.h"
     39 #include "conversions-inl.h"
     40 #include "counters.h"
     41 #include "cpu-profiler.h"
     42 #include "debug.h"
     43 #include "deoptimizer.h"
     44 #include "execution.h"
     45 #include "global-handles.h"
     46 #include "heap-profiler.h"
     47 #include "heap-snapshot-generator-inl.h"
     48 #include "icu_util.h"
     49 #include "json-parser.h"
     50 #include "messages.h"
     51 #ifdef COMPRESS_STARTUP_DATA_BZ2
     52 #include "natives.h"
     53 #endif
     54 #include "parser.h"
     55 #include "platform.h"
     56 #include "platform/time.h"
     57 #include "profile-generator-inl.h"
     58 #include "property-details.h"
     59 #include "property.h"
     60 #include "runtime.h"
     61 #include "runtime-profiler.h"
     62 #include "scanner-character-streams.h"
     63 #include "snapshot.h"
     64 #include "unicode-inl.h"
     65 #include "utils/random-number-generator.h"
     66 #include "v8threads.h"
     67 #include "version.h"
     68 #include "vm-state-inl.h"
     69 
     70 
     71 #define LOG_API(isolate, expr) LOG(isolate, ApiEntryCall(expr))
     72 
     73 #define ENTER_V8(isolate)                                          \
     74   ASSERT((isolate)->IsInitialized());                              \
     75   i::VMState<i::OTHER> __state__((isolate))
     76 
     77 namespace v8 {
     78 
     79 #define ON_BAILOUT(isolate, location, code)                        \
     80   if (IsExecutionTerminatingCheck(isolate)) {                      \
     81     code;                                                          \
     82     UNREACHABLE();                                                 \
     83   }
     84 
     85 
     86 #define EXCEPTION_PREAMBLE(isolate)                                         \
     87   (isolate)->handle_scope_implementer()->IncrementCallDepth();              \
     88   ASSERT(!(isolate)->external_caught_exception());                          \
     89   bool has_pending_exception = false
     90 
     91 
     92 #define EXCEPTION_BAILOUT_CHECK_GENERIC(isolate, value, do_callback)           \
     93   do {                                                                         \
     94     i::HandleScopeImplementer* handle_scope_implementer =                      \
     95         (isolate)->handle_scope_implementer();                                 \
     96     handle_scope_implementer->DecrementCallDepth();                            \
     97     if (has_pending_exception) {                                               \
     98       if (handle_scope_implementer->CallDepthIsZero() &&                       \
     99           (isolate)->is_out_of_memory()) {                                     \
    100         if (!(isolate)->ignore_out_of_memory())                                \
    101           i::V8::FatalProcessOutOfMemory(NULL);                                \
    102       }                                                                        \
    103       bool call_depth_is_zero = handle_scope_implementer->CallDepthIsZero();   \
    104       (isolate)->OptionalRescheduleException(call_depth_is_zero);              \
    105       do_callback                                                              \
    106       return value;                                                            \
    107     }                                                                          \
    108     do_callback                                                                \
    109   } while (false)
    110 
    111 
    112 #define EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, value)                    \
    113   EXCEPTION_BAILOUT_CHECK_GENERIC(                                             \
    114       isolate, value, i::V8::FireCallCompletedCallback(isolate);)
    115 
    116 
    117 #define EXCEPTION_BAILOUT_CHECK(isolate, value)                                \
    118   EXCEPTION_BAILOUT_CHECK_GENERIC(isolate, value, ;)
    119 
    120 
    121 #define API_ENTRY_CHECK(isolate, msg)                                          \
    122   do {                                                                         \
    123     if (v8::Locker::IsActive()) {                                              \
    124       ApiCheck(isolate->thread_manager()->IsLockedByCurrentThread(),           \
    125                msg,                                                            \
    126                "Entering the V8 API without proper locking in place");         \
    127     }                                                                          \
    128   } while (false)
    129 
    130 
    131 // --- E x c e p t i o n   B e h a v i o r ---
    132 
    133 
    134 static void DefaultFatalErrorHandler(const char* location,
    135                                      const char* message) {
    136   i::Isolate* isolate = i::Isolate::Current();
    137   if (isolate->IsInitialized()) {
    138     i::VMState<i::OTHER> state(isolate);
    139     API_Fatal(location, message);
    140   } else {
    141     API_Fatal(location, message);
    142   }
    143 }
    144 
    145 
    146 static FatalErrorCallback GetFatalErrorHandler() {
    147   i::Isolate* isolate = i::Isolate::Current();
    148   if (isolate->exception_behavior() == NULL) {
    149     isolate->set_exception_behavior(DefaultFatalErrorHandler);
    150   }
    151   return isolate->exception_behavior();
    152 }
    153 
    154 
    155 void i::FatalProcessOutOfMemory(const char* location) {
    156   i::V8::FatalProcessOutOfMemory(location, false);
    157 }
    158 
    159 
    160 // When V8 cannot allocated memory FatalProcessOutOfMemory is called.
    161 // The default fatal error handler is called and execution is stopped.
    162 void i::V8::FatalProcessOutOfMemory(const char* location, bool take_snapshot) {
    163   i::HeapStats heap_stats;
    164   int start_marker;
    165   heap_stats.start_marker = &start_marker;
    166   int new_space_size;
    167   heap_stats.new_space_size = &new_space_size;
    168   int new_space_capacity;
    169   heap_stats.new_space_capacity = &new_space_capacity;
    170   intptr_t old_pointer_space_size;
    171   heap_stats.old_pointer_space_size = &old_pointer_space_size;
    172   intptr_t old_pointer_space_capacity;
    173   heap_stats.old_pointer_space_capacity = &old_pointer_space_capacity;
    174   intptr_t old_data_space_size;
    175   heap_stats.old_data_space_size = &old_data_space_size;
    176   intptr_t old_data_space_capacity;
    177   heap_stats.old_data_space_capacity = &old_data_space_capacity;
    178   intptr_t code_space_size;
    179   heap_stats.code_space_size = &code_space_size;
    180   intptr_t code_space_capacity;
    181   heap_stats.code_space_capacity = &code_space_capacity;
    182   intptr_t map_space_size;
    183   heap_stats.map_space_size = &map_space_size;
    184   intptr_t map_space_capacity;
    185   heap_stats.map_space_capacity = &map_space_capacity;
    186   intptr_t cell_space_size;
    187   heap_stats.cell_space_size = &cell_space_size;
    188   intptr_t cell_space_capacity;
    189   heap_stats.cell_space_capacity = &cell_space_capacity;
    190   intptr_t property_cell_space_size;
    191   heap_stats.property_cell_space_size = &property_cell_space_size;
    192   intptr_t property_cell_space_capacity;
    193   heap_stats.property_cell_space_capacity = &property_cell_space_capacity;
    194   intptr_t lo_space_size;
    195   heap_stats.lo_space_size = &lo_space_size;
    196   int global_handle_count;
    197   heap_stats.global_handle_count = &global_handle_count;
    198   int weak_global_handle_count;
    199   heap_stats.weak_global_handle_count = &weak_global_handle_count;
    200   int pending_global_handle_count;
    201   heap_stats.pending_global_handle_count = &pending_global_handle_count;
    202   int near_death_global_handle_count;
    203   heap_stats.near_death_global_handle_count = &near_death_global_handle_count;
    204   int free_global_handle_count;
    205   heap_stats.free_global_handle_count = &free_global_handle_count;
    206   intptr_t memory_allocator_size;
    207   heap_stats.memory_allocator_size = &memory_allocator_size;
    208   intptr_t memory_allocator_capacity;
    209   heap_stats.memory_allocator_capacity = &memory_allocator_capacity;
    210   int objects_per_type[LAST_TYPE + 1] = {0};
    211   heap_stats.objects_per_type = objects_per_type;
    212   int size_per_type[LAST_TYPE + 1] = {0};
    213   heap_stats.size_per_type = size_per_type;
    214   int os_error;
    215   heap_stats.os_error = &os_error;
    216   int end_marker;
    217   heap_stats.end_marker = &end_marker;
    218   i::Isolate* isolate = i::Isolate::Current();
    219   if (isolate->heap()->HasBeenSetUp()) {
    220     // BUG(1718): Don't use the take_snapshot since we don't support
    221     // HeapIterator here without doing a special GC.
    222     isolate->heap()->RecordStats(&heap_stats, false);
    223   }
    224   isolate->SignalFatalError();
    225   FatalErrorCallback callback = GetFatalErrorHandler();
    226   const char* message = "Allocation failed - process out of memory";
    227   callback(location, message);
    228   // If the callback returns, we stop execution.
    229   FATAL("API fatal error handler returned after process out of memory");
    230 }
    231 
    232 
    233 bool Utils::ReportApiFailure(const char* location, const char* message) {
    234   FatalErrorCallback callback = GetFatalErrorHandler();
    235   callback(location, message);
    236   i::Isolate* isolate = i::Isolate::Current();
    237   isolate->SignalFatalError();
    238   return false;
    239 }
    240 
    241 
    242 bool V8::IsDead() {
    243   i::Isolate* isolate = i::Isolate::Current();
    244   return isolate->IsDead();
    245 }
    246 
    247 
    248 static inline bool ApiCheck(bool condition,
    249                             const char* location,
    250                             const char* message) {
    251   return condition ? true : Utils::ReportApiFailure(location, message);
    252 }
    253 
    254 
    255 static bool ReportEmptyHandle(const char* location) {
    256   FatalErrorCallback callback = GetFatalErrorHandler();
    257   callback(location, "Reading from empty handle");
    258   return true;
    259 }
    260 
    261 
    262 static inline bool IsExecutionTerminatingCheck(i::Isolate* isolate) {
    263   if (!isolate->IsInitialized()) return false;
    264   if (isolate->has_scheduled_exception()) {
    265     return isolate->scheduled_exception() ==
    266         isolate->heap()->termination_exception();
    267   }
    268   return false;
    269 }
    270 
    271 
    272 static inline bool EmptyCheck(const char* location, v8::Handle<v8::Data> obj) {
    273   return obj.IsEmpty() ? ReportEmptyHandle(location) : false;
    274 }
    275 
    276 
    277 static inline bool EmptyCheck(const char* location, const v8::Data* obj) {
    278   return (obj == 0) ? ReportEmptyHandle(location) : false;
    279 }
    280 
    281 
    282 // --- S t a t i c s ---
    283 
    284 
    285 static bool InitializeHelper(i::Isolate* isolate) {
    286   // If the isolate has a function entry hook, it needs to re-build all its
    287   // code stubs with entry hooks embedded, so let's deserialize a snapshot.
    288   if (isolate == NULL || isolate->function_entry_hook() == NULL) {
    289     if (i::Snapshot::Initialize())
    290       return true;
    291   }
    292   return i::V8::Initialize(NULL);
    293 }
    294 
    295 
    296 static inline bool EnsureInitializedForIsolate(i::Isolate* isolate,
    297                                                const char* location) {
    298   if (isolate != NULL) {
    299     if (isolate->IsInitialized()) return true;
    300   }
    301   ASSERT(isolate == i::Isolate::Current());
    302   return ApiCheck(InitializeHelper(isolate), location, "Error initializing V8");
    303 }
    304 
    305 
    306 // Some initializing API functions are called early and may be
    307 // called on a thread different from static initializer thread.
    308 // If Isolate API is used, Isolate::Enter() will initialize TLS so
    309 // Isolate::Current() works. If it's a legacy case, then the thread
    310 // may not have TLS initialized yet. However, in initializing APIs it
    311 // may be too early to call EnsureInitialized() - some pre-init
    312 // parameters still have to be configured.
    313 static inline i::Isolate* EnterIsolateIfNeeded() {
    314   i::Isolate* isolate = i::Isolate::UncheckedCurrent();
    315   if (isolate != NULL)
    316     return isolate;
    317 
    318   i::Isolate::EnterDefaultIsolate();
    319   isolate = i::Isolate::Current();
    320   return isolate;
    321 }
    322 
    323 
    324 StartupDataDecompressor::StartupDataDecompressor()
    325     : raw_data(i::NewArray<char*>(V8::GetCompressedStartupDataCount())) {
    326   for (int i = 0; i < V8::GetCompressedStartupDataCount(); ++i) {
    327     raw_data[i] = NULL;
    328   }
    329 }
    330 
    331 
    332 StartupDataDecompressor::~StartupDataDecompressor() {
    333   for (int i = 0; i < V8::GetCompressedStartupDataCount(); ++i) {
    334     i::DeleteArray(raw_data[i]);
    335   }
    336   i::DeleteArray(raw_data);
    337 }
    338 
    339 
    340 int StartupDataDecompressor::Decompress() {
    341   int compressed_data_count = V8::GetCompressedStartupDataCount();
    342   StartupData* compressed_data =
    343       i::NewArray<StartupData>(compressed_data_count);
    344   V8::GetCompressedStartupData(compressed_data);
    345   for (int i = 0; i < compressed_data_count; ++i) {
    346     char* decompressed = raw_data[i] =
    347         i::NewArray<char>(compressed_data[i].raw_size);
    348     if (compressed_data[i].compressed_size != 0) {
    349       int result = DecompressData(decompressed,
    350                                   &compressed_data[i].raw_size,
    351                                   compressed_data[i].data,
    352                                   compressed_data[i].compressed_size);
    353       if (result != 0) return result;
    354     } else {
    355       ASSERT_EQ(0, compressed_data[i].raw_size);
    356     }
    357     compressed_data[i].data = decompressed;
    358   }
    359   V8::SetDecompressedStartupData(compressed_data);
    360   i::DeleteArray(compressed_data);
    361   return 0;
    362 }
    363 
    364 
    365 StartupData::CompressionAlgorithm V8::GetCompressedStartupDataAlgorithm() {
    366 #ifdef COMPRESS_STARTUP_DATA_BZ2
    367   return StartupData::kBZip2;
    368 #else
    369   return StartupData::kUncompressed;
    370 #endif
    371 }
    372 
    373 
    374 enum CompressedStartupDataItems {
    375   kSnapshot = 0,
    376   kSnapshotContext,
    377   kLibraries,
    378   kExperimentalLibraries,
    379   kCompressedStartupDataCount
    380 };
    381 
    382 
    383 int V8::GetCompressedStartupDataCount() {
    384 #ifdef COMPRESS_STARTUP_DATA_BZ2
    385   return kCompressedStartupDataCount;
    386 #else
    387   return 0;
    388 #endif
    389 }
    390 
    391 
    392 void V8::GetCompressedStartupData(StartupData* compressed_data) {
    393 #ifdef COMPRESS_STARTUP_DATA_BZ2
    394   compressed_data[kSnapshot].data =
    395       reinterpret_cast<const char*>(i::Snapshot::data());
    396   compressed_data[kSnapshot].compressed_size = i::Snapshot::size();
    397   compressed_data[kSnapshot].raw_size = i::Snapshot::raw_size();
    398 
    399   compressed_data[kSnapshotContext].data =
    400       reinterpret_cast<const char*>(i::Snapshot::context_data());
    401   compressed_data[kSnapshotContext].compressed_size =
    402       i::Snapshot::context_size();
    403   compressed_data[kSnapshotContext].raw_size = i::Snapshot::context_raw_size();
    404 
    405   i::Vector<const i::byte> libraries_source = i::Natives::GetScriptsSource();
    406   compressed_data[kLibraries].data =
    407       reinterpret_cast<const char*>(libraries_source.start());
    408   compressed_data[kLibraries].compressed_size = libraries_source.length();
    409   compressed_data[kLibraries].raw_size = i::Natives::GetRawScriptsSize();
    410 
    411   i::Vector<const i::byte> exp_libraries_source =
    412       i::ExperimentalNatives::GetScriptsSource();
    413   compressed_data[kExperimentalLibraries].data =
    414       reinterpret_cast<const char*>(exp_libraries_source.start());
    415   compressed_data[kExperimentalLibraries].compressed_size =
    416       exp_libraries_source.length();
    417   compressed_data[kExperimentalLibraries].raw_size =
    418       i::ExperimentalNatives::GetRawScriptsSize();
    419 #endif
    420 }
    421 
    422 
    423 void V8::SetDecompressedStartupData(StartupData* decompressed_data) {
    424 #ifdef COMPRESS_STARTUP_DATA_BZ2
    425   ASSERT_EQ(i::Snapshot::raw_size(), decompressed_data[kSnapshot].raw_size);
    426   i::Snapshot::set_raw_data(
    427       reinterpret_cast<const i::byte*>(decompressed_data[kSnapshot].data));
    428 
    429   ASSERT_EQ(i::Snapshot::context_raw_size(),
    430             decompressed_data[kSnapshotContext].raw_size);
    431   i::Snapshot::set_context_raw_data(
    432       reinterpret_cast<const i::byte*>(
    433           decompressed_data[kSnapshotContext].data));
    434 
    435   ASSERT_EQ(i::Natives::GetRawScriptsSize(),
    436             decompressed_data[kLibraries].raw_size);
    437   i::Vector<const char> libraries_source(
    438       decompressed_data[kLibraries].data,
    439       decompressed_data[kLibraries].raw_size);
    440   i::Natives::SetRawScriptsSource(libraries_source);
    441 
    442   ASSERT_EQ(i::ExperimentalNatives::GetRawScriptsSize(),
    443             decompressed_data[kExperimentalLibraries].raw_size);
    444   i::Vector<const char> exp_libraries_source(
    445       decompressed_data[kExperimentalLibraries].data,
    446       decompressed_data[kExperimentalLibraries].raw_size);
    447   i::ExperimentalNatives::SetRawScriptsSource(exp_libraries_source);
    448 #endif
    449 }
    450 
    451 
    452 void V8::SetFatalErrorHandler(FatalErrorCallback that) {
    453   i::Isolate* isolate = EnterIsolateIfNeeded();
    454   isolate->set_exception_behavior(that);
    455 }
    456 
    457 
    458 void V8::SetAllowCodeGenerationFromStringsCallback(
    459     AllowCodeGenerationFromStringsCallback callback) {
    460   i::Isolate* isolate = EnterIsolateIfNeeded();
    461   isolate->set_allow_code_gen_callback(callback);
    462 }
    463 
    464 
    465 void V8::SetFlagsFromString(const char* str, int length) {
    466   i::FlagList::SetFlagsFromString(str, length);
    467 }
    468 
    469 
    470 void V8::SetFlagsFromCommandLine(int* argc, char** argv, bool remove_flags) {
    471   i::FlagList::SetFlagsFromCommandLine(argc, argv, remove_flags);
    472 }
    473 
    474 
    475 v8::Handle<Value> ThrowException(v8::Handle<v8::Value> value) {
    476   return v8::Isolate::GetCurrent()->ThrowException(value);
    477 }
    478 
    479 
    480 RegisteredExtension* RegisteredExtension::first_extension_ = NULL;
    481 
    482 
    483 RegisteredExtension::RegisteredExtension(Extension* extension)
    484     : extension_(extension) { }
    485 
    486 
    487 void RegisteredExtension::Register(RegisteredExtension* that) {
    488   that->next_ = first_extension_;
    489   first_extension_ = that;
    490 }
    491 
    492 
    493 void RegisteredExtension::UnregisterAll() {
    494   RegisteredExtension* re = first_extension_;
    495   while (re != NULL) {
    496     RegisteredExtension* next = re->next();
    497     delete re;
    498     re = next;
    499   }
    500 }
    501 
    502 
    503 void RegisterExtension(Extension* that) {
    504   RegisteredExtension* extension = new RegisteredExtension(that);
    505   RegisteredExtension::Register(extension);
    506 }
    507 
    508 
    509 Extension::Extension(const char* name,
    510                      const char* source,
    511                      int dep_count,
    512                      const char** deps,
    513                      int source_length)
    514     : name_(name),
    515       source_length_(source_length >= 0 ?
    516                      source_length :
    517                      (source ? static_cast<int>(strlen(source)) : 0)),
    518       source_(source, source_length_),
    519       dep_count_(dep_count),
    520       deps_(deps),
    521       auto_enable_(false) {
    522   CHECK(source != NULL || source_length_ == 0);
    523 }
    524 
    525 
    526 v8::Handle<Primitive> Undefined() {
    527   i::Isolate* isolate = i::Isolate::Current();
    528   if (!EnsureInitializedForIsolate(isolate, "v8::Undefined()")) {
    529     return v8::Handle<v8::Primitive>();
    530   }
    531   return ToApiHandle<Primitive>(isolate->factory()->undefined_value());
    532 }
    533 
    534 
    535 v8::Handle<Primitive> Null() {
    536   i::Isolate* isolate = i::Isolate::Current();
    537   if (!EnsureInitializedForIsolate(isolate, "v8::Null()")) {
    538     return v8::Handle<v8::Primitive>();
    539   }
    540   return ToApiHandle<Primitive>(isolate->factory()->null_value());
    541 }
    542 
    543 
    544 v8::Handle<Boolean> True() {
    545   i::Isolate* isolate = i::Isolate::Current();
    546   if (!EnsureInitializedForIsolate(isolate, "v8::True()")) {
    547     return v8::Handle<Boolean>();
    548   }
    549   return ToApiHandle<Boolean>(isolate->factory()->true_value());
    550 }
    551 
    552 
    553 v8::Handle<Boolean> False() {
    554   i::Isolate* isolate = i::Isolate::Current();
    555   if (!EnsureInitializedForIsolate(isolate, "v8::False()")) {
    556     return v8::Handle<Boolean>();
    557   }
    558   return ToApiHandle<Boolean>(isolate->factory()->false_value());
    559 }
    560 
    561 
    562 ResourceConstraints::ResourceConstraints()
    563   : max_young_space_size_(0),
    564     max_old_space_size_(0),
    565     max_executable_size_(0),
    566     stack_limit_(NULL),
    567     max_available_threads_(0) { }
    568 
    569 void ResourceConstraints::ConfigureDefaults(uint64_t physical_memory,
    570                                             uint32_t number_of_processors) {
    571   const int lump_of_memory = (i::kPointerSize / 4) * i::MB;
    572 #if V8_OS_ANDROID
    573   // Android has higher physical memory requirements before raising the maximum
    574   // heap size limits since it has no swap space.
    575   const uint64_t low_limit = 512ul * i::MB;
    576   const uint64_t medium_limit = 1ul * i::GB;
    577   const uint64_t high_limit = 2ul * i::GB;
    578 #else
    579   const uint64_t low_limit = 512ul * i::MB;
    580   const uint64_t medium_limit = 768ul * i::MB;
    581   const uint64_t high_limit = 1ul  * i::GB;
    582 #endif
    583 
    584   // The young_space_size should be a power of 2 and old_generation_size should
    585   // be a multiple of Page::kPageSize.
    586   if (physical_memory <= low_limit) {
    587     set_max_young_space_size(2 * lump_of_memory);
    588     set_max_old_space_size(128 * lump_of_memory);
    589     set_max_executable_size(96 * lump_of_memory);
    590   } else if (physical_memory <= medium_limit) {
    591     set_max_young_space_size(8 * lump_of_memory);
    592     set_max_old_space_size(256 * lump_of_memory);
    593     set_max_executable_size(192 * lump_of_memory);
    594   } else if (physical_memory <= high_limit) {
    595     set_max_young_space_size(16 * lump_of_memory);
    596     set_max_old_space_size(512 * lump_of_memory);
    597     set_max_executable_size(256 * lump_of_memory);
    598   } else {
    599     set_max_young_space_size(16 * lump_of_memory);
    600     set_max_old_space_size(700 * lump_of_memory);
    601     set_max_executable_size(256 * lump_of_memory);
    602   }
    603 
    604   set_max_available_threads(i::Max(i::Min(number_of_processors, 4u), 1u));
    605 }
    606 
    607 
    608 void ResourceConstraints::ConfigureDefaults(uint64_t physical_memory) {
    609   ConfigureDefaults(physical_memory, i::CPU::NumberOfProcessorsOnline());
    610 }
    611 
    612 
    613 bool SetResourceConstraints(Isolate* v8_isolate,
    614                             ResourceConstraints* constraints) {
    615   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(v8_isolate);
    616   int young_space_size = constraints->max_young_space_size();
    617   int old_gen_size = constraints->max_old_space_size();
    618   int max_executable_size = constraints->max_executable_size();
    619   if (young_space_size != 0 || old_gen_size != 0 || max_executable_size != 0) {
    620     // After initialization it's too late to change Heap constraints.
    621     ASSERT(!isolate->IsInitialized());
    622     bool result = isolate->heap()->ConfigureHeap(young_space_size / 2,
    623                                                  old_gen_size,
    624                                                  max_executable_size);
    625     if (!result) return false;
    626   }
    627   if (constraints->stack_limit() != NULL) {
    628     uintptr_t limit = reinterpret_cast<uintptr_t>(constraints->stack_limit());
    629     isolate->stack_guard()->SetStackLimit(limit);
    630   }
    631 
    632   isolate->set_max_available_threads(constraints->max_available_threads());
    633   return true;
    634 }
    635 
    636 
    637 i::Object** V8::GlobalizeReference(i::Isolate* isolate, i::Object** obj) {
    638   LOG_API(isolate, "Persistent::New");
    639   i::Handle<i::Object> result = isolate->global_handles()->Create(*obj);
    640 #ifdef DEBUG
    641   (*obj)->Verify();
    642 #endif  // DEBUG
    643   return result.location();
    644 }
    645 
    646 
    647 i::Object** V8::CopyPersistent(i::Object** obj) {
    648   i::Handle<i::Object> result = i::GlobalHandles::CopyGlobal(obj);
    649 #ifdef DEBUG
    650   (*obj)->Verify();
    651 #endif  // DEBUG
    652   return result.location();
    653 }
    654 
    655 
    656 void V8::MakeWeak(i::Object** object,
    657                   void* parameters,
    658                   WeakCallback weak_callback,
    659                   RevivableCallback weak_reference_callback) {
    660   i::GlobalHandles::MakeWeak(object,
    661                              parameters,
    662                              weak_callback,
    663                              weak_reference_callback);
    664 }
    665 
    666 
    667 void V8::ClearWeak(i::Object** obj) {
    668   i::GlobalHandles::ClearWeakness(obj);
    669 }
    670 
    671 
    672 void V8::DisposeGlobal(i::Object** obj) {
    673   i::GlobalHandles::Destroy(obj);
    674 }
    675 
    676 
    677 void V8::Eternalize(Isolate* v8_isolate, Value* value, int* index) {
    678   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(v8_isolate);
    679   i::Object* object = *Utils::OpenHandle(value);
    680   isolate->eternal_handles()->Create(isolate, object, index);
    681 }
    682 
    683 
    684 Local<Value> V8::GetEternal(Isolate* v8_isolate, int index) {
    685   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(v8_isolate);
    686   return Utils::ToLocal(isolate->eternal_handles()->Get(index));
    687 }
    688 
    689 
    690 // --- H a n d l e s ---
    691 
    692 
    693 HandleScope::HandleScope(Isolate* isolate) {
    694   Initialize(isolate);
    695 }
    696 
    697 
    698 void HandleScope::Initialize(Isolate* isolate) {
    699   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
    700   API_ENTRY_CHECK(internal_isolate, "HandleScope::HandleScope");
    701   v8::ImplementationUtilities::HandleScopeData* current =
    702       internal_isolate->handle_scope_data();
    703   isolate_ = internal_isolate;
    704   prev_next_ = current->next;
    705   prev_limit_ = current->limit;
    706   is_closed_ = false;
    707   current->level++;
    708 }
    709 
    710 
    711 HandleScope::~HandleScope() {
    712   if (!is_closed_) {
    713     Leave();
    714   }
    715 }
    716 
    717 
    718 void HandleScope::Leave() {
    719   return i::HandleScope::CloseScope(isolate_, prev_next_, prev_limit_);
    720 }
    721 
    722 
    723 int HandleScope::NumberOfHandles() {
    724   i::Isolate* isolate = i::Isolate::Current();
    725   if (!EnsureInitializedForIsolate(isolate, "HandleScope::NumberOfHandles")) {
    726     return 0;
    727   }
    728   return i::HandleScope::NumberOfHandles(isolate);
    729 }
    730 
    731 
    732 i::Object** HandleScope::CreateHandle(i::Isolate* isolate, i::Object* value) {
    733   return i::HandleScope::CreateHandle(isolate, value);
    734 }
    735 
    736 
    737 i::Object** HandleScope::CreateHandle(i::HeapObject* heap_object,
    738                                       i::Object* value) {
    739   ASSERT(heap_object->IsHeapObject());
    740   return i::HandleScope::CreateHandle(heap_object->GetIsolate(), value);
    741 }
    742 
    743 
    744 EscapableHandleScope::EscapableHandleScope(Isolate* v8_isolate) {
    745   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(v8_isolate);
    746   escape_slot_ = CreateHandle(isolate, isolate->heap()->the_hole_value());
    747   Initialize(v8_isolate);
    748 }
    749 
    750 
    751 i::Object** EscapableHandleScope::Escape(i::Object** escape_value) {
    752   ApiCheck(*escape_slot_ == isolate_->heap()->the_hole_value(),
    753            "EscapeableHandleScope::Escape",
    754            "Escape value set twice");
    755   if (escape_value == NULL) {
    756     *escape_slot_ = isolate_->heap()->undefined_value();
    757     return NULL;
    758   }
    759   *escape_slot_ = *escape_value;
    760   return escape_slot_;
    761 }
    762 
    763 
    764 void Context::Enter() {
    765   i::Handle<i::Context> env = Utils::OpenHandle(this);
    766   i::Isolate* isolate = env->GetIsolate();
    767   ENTER_V8(isolate);
    768   isolate->handle_scope_implementer()->EnterContext(env);
    769   isolate->handle_scope_implementer()->SaveContext(isolate->context());
    770   isolate->set_context(*env);
    771 }
    772 
    773 
    774 void Context::Exit() {
    775   // TODO(dcarney): fix this once chrome is fixed.
    776   i::Isolate* isolate = i::Isolate::Current();
    777   i::Handle<i::Context> context = i::Handle<i::Context>::null();
    778   ENTER_V8(isolate);
    779   if (!ApiCheck(isolate->handle_scope_implementer()->LeaveContext(context),
    780                 "v8::Context::Exit()",
    781                 "Cannot exit non-entered context")) {
    782     return;
    783   }
    784   // Content of 'last_context' could be NULL.
    785   i::Context* last_context =
    786       isolate->handle_scope_implementer()->RestoreContext();
    787   isolate->set_context(last_context);
    788 }
    789 
    790 
    791 static void* DecodeSmiToAligned(i::Object* value, const char* location) {
    792   ApiCheck(value->IsSmi(), location, "Not a Smi");
    793   return reinterpret_cast<void*>(value);
    794 }
    795 
    796 
    797 static i::Smi* EncodeAlignedAsSmi(void* value, const char* location) {
    798   i::Smi* smi = reinterpret_cast<i::Smi*>(value);
    799   ApiCheck(smi->IsSmi(), location, "Pointer is not aligned");
    800   return smi;
    801 }
    802 
    803 
    804 static i::Handle<i::FixedArray> EmbedderDataFor(Context* context,
    805                                                 int index,
    806                                                 bool can_grow,
    807                                                 const char* location) {
    808   i::Handle<i::Context> env = Utils::OpenHandle(context);
    809   bool ok =
    810       ApiCheck(env->IsNativeContext(), location, "Not a native context") &&
    811       ApiCheck(index >= 0, location, "Negative index");
    812   if (!ok) return i::Handle<i::FixedArray>();
    813   i::Handle<i::FixedArray> data(env->embedder_data());
    814   if (index < data->length()) return data;
    815   if (!can_grow) {
    816     Utils::ReportApiFailure(location, "Index too large");
    817     return i::Handle<i::FixedArray>();
    818   }
    819   int new_size = i::Max(index, data->length() << 1) + 1;
    820   data = env->GetIsolate()->factory()->CopySizeFixedArray(data, new_size);
    821   env->set_embedder_data(*data);
    822   return data;
    823 }
    824 
    825 
    826 v8::Local<v8::Value> Context::SlowGetEmbedderData(int index) {
    827   const char* location = "v8::Context::GetEmbedderData()";
    828   i::Handle<i::FixedArray> data = EmbedderDataFor(this, index, false, location);
    829   if (data.is_null()) return Local<Value>();
    830   i::Handle<i::Object> result(data->get(index), data->GetIsolate());
    831   return Utils::ToLocal(result);
    832 }
    833 
    834 
    835 void Context::SetEmbedderData(int index, v8::Handle<Value> value) {
    836   const char* location = "v8::Context::SetEmbedderData()";
    837   i::Handle<i::FixedArray> data = EmbedderDataFor(this, index, true, location);
    838   if (data.is_null()) return;
    839   i::Handle<i::Object> val = Utils::OpenHandle(*value);
    840   data->set(index, *val);
    841   ASSERT_EQ(*Utils::OpenHandle(*value),
    842             *Utils::OpenHandle(*GetEmbedderData(index)));
    843 }
    844 
    845 
    846 void* Context::SlowGetAlignedPointerFromEmbedderData(int index) {
    847   const char* location = "v8::Context::GetAlignedPointerFromEmbedderData()";
    848   i::Handle<i::FixedArray> data = EmbedderDataFor(this, index, false, location);
    849   if (data.is_null()) return NULL;
    850   return DecodeSmiToAligned(data->get(index), location);
    851 }
    852 
    853 
    854 void Context::SetAlignedPointerInEmbedderData(int index, void* value) {
    855   const char* location = "v8::Context::SetAlignedPointerInEmbedderData()";
    856   i::Handle<i::FixedArray> data = EmbedderDataFor(this, index, true, location);
    857   data->set(index, EncodeAlignedAsSmi(value, location));
    858   ASSERT_EQ(value, GetAlignedPointerFromEmbedderData(index));
    859 }
    860 
    861 
    862 i::Object** v8::HandleScope::RawClose(i::Object** value) {
    863   if (!ApiCheck(!is_closed_,
    864                 "v8::HandleScope::Close()",
    865                 "Local scope has already been closed")) {
    866     return 0;
    867   }
    868   LOG_API(isolate_, "CloseHandleScope");
    869 
    870   // Read the result before popping the handle block.
    871   i::Object* result = NULL;
    872   if (value != NULL) {
    873     result = *value;
    874   }
    875   is_closed_ = true;
    876   Leave();
    877 
    878   if (value == NULL) {
    879     return NULL;
    880   }
    881 
    882   // Allocate a new handle on the previous handle block.
    883   i::Handle<i::Object> handle(result, isolate_);
    884   return handle.location();
    885 }
    886 
    887 
    888 // --- N e a n d e r ---
    889 
    890 
    891 // A constructor cannot easily return an error value, therefore it is necessary
    892 // to check for a dead VM with ON_BAILOUT before constructing any Neander
    893 // objects.  To remind you about this there is no HandleScope in the
    894 // NeanderObject constructor.  When you add one to the site calling the
    895 // constructor you should check that you ensured the VM was not dead first.
    896 NeanderObject::NeanderObject(int size) {
    897   i::Isolate* isolate = i::Isolate::Current();
    898   EnsureInitializedForIsolate(isolate, "v8::Nowhere");
    899   ENTER_V8(isolate);
    900   value_ = isolate->factory()->NewNeanderObject();
    901   i::Handle<i::FixedArray> elements = isolate->factory()->NewFixedArray(size);
    902   value_->set_elements(*elements);
    903 }
    904 
    905 
    906 int NeanderObject::size() {
    907   return i::FixedArray::cast(value_->elements())->length();
    908 }
    909 
    910 
    911 NeanderArray::NeanderArray() : obj_(2) {
    912   obj_.set(0, i::Smi::FromInt(0));
    913 }
    914 
    915 
    916 int NeanderArray::length() {
    917   return i::Smi::cast(obj_.get(0))->value();
    918 }
    919 
    920 
    921 i::Object* NeanderArray::get(int offset) {
    922   ASSERT(0 <= offset);
    923   ASSERT(offset < length());
    924   return obj_.get(offset + 1);
    925 }
    926 
    927 
    928 // This method cannot easily return an error value, therefore it is necessary
    929 // to check for a dead VM with ON_BAILOUT before calling it.  To remind you
    930 // about this there is no HandleScope in this method.  When you add one to the
    931 // site calling this method you should check that you ensured the VM was not
    932 // dead first.
    933 void NeanderArray::add(i::Handle<i::Object> value) {
    934   int length = this->length();
    935   int size = obj_.size();
    936   if (length == size - 1) {
    937     i::Factory* factory = i::Isolate::Current()->factory();
    938     i::Handle<i::FixedArray> new_elms = factory->NewFixedArray(2 * size);
    939     for (int i = 0; i < length; i++)
    940       new_elms->set(i + 1, get(i));
    941     obj_.value()->set_elements(*new_elms);
    942   }
    943   obj_.set(length + 1, *value);
    944   obj_.set(0, i::Smi::FromInt(length + 1));
    945 }
    946 
    947 
    948 void NeanderArray::set(int index, i::Object* value) {
    949   if (index < 0 || index >= this->length()) return;
    950   obj_.set(index + 1, value);
    951 }
    952 
    953 
    954 // --- T e m p l a t e ---
    955 
    956 
    957 static void InitializeTemplate(i::Handle<i::TemplateInfo> that, int type) {
    958   that->set_tag(i::Smi::FromInt(type));
    959 }
    960 
    961 
    962 static void TemplateSet(i::Isolate* isolate,
    963                         v8::Template* templ,
    964                         int length,
    965                         v8::Handle<v8::Data>* data) {
    966   i::Handle<i::Object> list(Utils::OpenHandle(templ)->property_list(), isolate);
    967   if (list->IsUndefined()) {
    968     list = NeanderArray().value();
    969     Utils::OpenHandle(templ)->set_property_list(*list);
    970   }
    971   NeanderArray array(list);
    972   array.add(Utils::OpenHandle(*v8::Integer::New(length)));
    973   for (int i = 0; i < length; i++) {
    974     i::Handle<i::Object> value = data[i].IsEmpty() ?
    975         i::Handle<i::Object>(isolate->factory()->undefined_value()) :
    976         Utils::OpenHandle(*data[i]);
    977     array.add(value);
    978   }
    979 }
    980 
    981 
    982 void Template::Set(v8::Handle<String> name,
    983                    v8::Handle<Data> value,
    984                    v8::PropertyAttribute attribute) {
    985   i::Isolate* isolate = i::Isolate::Current();
    986   ENTER_V8(isolate);
    987   i::HandleScope scope(isolate);
    988   const int kSize = 3;
    989   v8::Handle<v8::Data> data[kSize] = {
    990       name,
    991       value,
    992       v8::Integer::New(attribute)};
    993   TemplateSet(isolate, this, kSize, data);
    994 }
    995 
    996 
    997 void Template::SetAccessorProperty(
    998     v8::Local<v8::String> name,
    999     v8::Local<FunctionTemplate> getter,
   1000     v8::Local<FunctionTemplate> setter,
   1001     v8::PropertyAttribute attribute,
   1002     v8::AccessControl access_control) {
   1003   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1004   ENTER_V8(isolate);
   1005   ASSERT(!name.IsEmpty());
   1006   ASSERT(!getter.IsEmpty() || !setter.IsEmpty());
   1007   i::HandleScope scope(isolate);
   1008   const int kSize = 5;
   1009   v8::Handle<v8::Data> data[kSize] = {
   1010       name,
   1011       getter,
   1012       setter,
   1013       v8::Integer::New(attribute),
   1014       v8::Integer::New(access_control)};
   1015   TemplateSet(isolate, this, kSize, data);
   1016 }
   1017 
   1018 
   1019 // --- F u n c t i o n   T e m p l a t e ---
   1020 static void InitializeFunctionTemplate(
   1021       i::Handle<i::FunctionTemplateInfo> info) {
   1022   info->set_tag(i::Smi::FromInt(Consts::FUNCTION_TEMPLATE));
   1023   info->set_flag(0);
   1024 }
   1025 
   1026 
   1027 Local<ObjectTemplate> FunctionTemplate::PrototypeTemplate() {
   1028   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1029   ENTER_V8(isolate);
   1030   i::Handle<i::Object> result(Utils::OpenHandle(this)->prototype_template(),
   1031                               isolate);
   1032   if (result->IsUndefined()) {
   1033     result = Utils::OpenHandle(*ObjectTemplate::New());
   1034     Utils::OpenHandle(this)->set_prototype_template(*result);
   1035   }
   1036   return ToApiHandle<ObjectTemplate>(result);
   1037 }
   1038 
   1039 
   1040 void FunctionTemplate::Inherit(v8::Handle<FunctionTemplate> value) {
   1041   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1042   ENTER_V8(isolate);
   1043   Utils::OpenHandle(this)->set_parent_template(*Utils::OpenHandle(*value));
   1044 }
   1045 
   1046 
   1047 static Local<FunctionTemplate> FunctionTemplateNew(
   1048     i::Isolate* isolate,
   1049     FunctionCallback callback,
   1050     v8::Handle<Value> data,
   1051     v8::Handle<Signature> signature,
   1052     int length,
   1053     bool do_not_cache) {
   1054   i::Handle<i::Struct> struct_obj =
   1055       isolate->factory()->NewStruct(i::FUNCTION_TEMPLATE_INFO_TYPE);
   1056   i::Handle<i::FunctionTemplateInfo> obj =
   1057       i::Handle<i::FunctionTemplateInfo>::cast(struct_obj);
   1058   InitializeFunctionTemplate(obj);
   1059   obj->set_do_not_cache(do_not_cache);
   1060   int next_serial_number = 0;
   1061   if (!do_not_cache) {
   1062     next_serial_number = isolate->next_serial_number() + 1;
   1063     isolate->set_next_serial_number(next_serial_number);
   1064   }
   1065   obj->set_serial_number(i::Smi::FromInt(next_serial_number));
   1066   if (callback != 0) {
   1067     if (data.IsEmpty()) {
   1068       data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1069     }
   1070     Utils::ToLocal(obj)->SetCallHandler(callback, data);
   1071   }
   1072   obj->set_length(length);
   1073   obj->set_undetectable(false);
   1074   obj->set_needs_access_check(false);
   1075   if (!signature.IsEmpty())
   1076     obj->set_signature(*Utils::OpenHandle(*signature));
   1077   return Utils::ToLocal(obj);
   1078 }
   1079 
   1080 Local<FunctionTemplate> FunctionTemplate::New(
   1081     Isolate* isolate,
   1082     FunctionCallback callback,
   1083     v8::Handle<Value> data,
   1084     v8::Handle<Signature> signature,
   1085     int length) {
   1086   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   1087   EnsureInitializedForIsolate(i_isolate, "v8::FunctionTemplate::New()");
   1088   LOG_API(i_isolate, "FunctionTemplate::New");
   1089   ENTER_V8(i_isolate);
   1090   return FunctionTemplateNew(
   1091       i_isolate, callback, data, signature, length, false);
   1092 }
   1093 
   1094 
   1095 Local<FunctionTemplate> FunctionTemplate::New(
   1096     FunctionCallback callback,
   1097     v8::Handle<Value> data,
   1098     v8::Handle<Signature> signature,
   1099     int length) {
   1100   return New(Isolate::GetCurrent(), callback, data, signature, length);
   1101 }
   1102 
   1103 Local<Signature> Signature::New(Isolate* isolate,
   1104                                 Handle<FunctionTemplate> receiver, int argc,
   1105                                 Handle<FunctionTemplate> argv[]) {
   1106   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   1107   EnsureInitializedForIsolate(i_isolate, "v8::Signature::New()");
   1108   LOG_API(i_isolate, "Signature::New");
   1109   ENTER_V8(i_isolate);
   1110   i::Handle<i::Struct> struct_obj =
   1111       i_isolate->factory()->NewStruct(i::SIGNATURE_INFO_TYPE);
   1112   i::Handle<i::SignatureInfo> obj =
   1113       i::Handle<i::SignatureInfo>::cast(struct_obj);
   1114   if (!receiver.IsEmpty()) obj->set_receiver(*Utils::OpenHandle(*receiver));
   1115   if (argc > 0) {
   1116     i::Handle<i::FixedArray> args = i_isolate->factory()->NewFixedArray(argc);
   1117     for (int i = 0; i < argc; i++) {
   1118       if (!argv[i].IsEmpty())
   1119         args->set(i, *Utils::OpenHandle(*argv[i]));
   1120     }
   1121     obj->set_args(*args);
   1122   }
   1123   return Utils::ToLocal(obj);
   1124 }
   1125 
   1126 
   1127 Local<Signature> Signature::New(Handle<FunctionTemplate> receiver,
   1128       int argc, Handle<FunctionTemplate> argv[]) {
   1129   return New(Isolate::GetCurrent(), receiver, argc, argv);
   1130 }
   1131 
   1132 
   1133 Local<AccessorSignature> AccessorSignature::New(
   1134       Isolate* isolate,
   1135       Handle<FunctionTemplate> receiver) {
   1136   return Utils::AccessorSignatureToLocal(Utils::OpenHandle(*receiver));
   1137 }
   1138 
   1139 
   1140 // While this is just a cast, it's lame not to use an Isolate parameter.
   1141 Local<AccessorSignature> AccessorSignature::New(
   1142       Handle<FunctionTemplate> receiver) {
   1143   return Utils::AccessorSignatureToLocal(Utils::OpenHandle(*receiver));
   1144 }
   1145 
   1146 
   1147 template<typename Operation>
   1148 static Local<Operation> NewDescriptor(
   1149     Isolate* isolate,
   1150     const i::DeclaredAccessorDescriptorData& data,
   1151     Data* previous_descriptor) {
   1152   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   1153   i::Handle<i::DeclaredAccessorDescriptor> previous =
   1154       i::Handle<i::DeclaredAccessorDescriptor>();
   1155   if (previous_descriptor != NULL) {
   1156     previous = Utils::OpenHandle(
   1157       static_cast<DeclaredAccessorDescriptor*>(previous_descriptor));
   1158   }
   1159   i::Handle<i::DeclaredAccessorDescriptor> descriptor =
   1160       i::DeclaredAccessorDescriptor::Create(internal_isolate, data, previous);
   1161   return Utils::Convert<i::DeclaredAccessorDescriptor, Operation>(descriptor);
   1162 }
   1163 
   1164 
   1165 Local<RawOperationDescriptor>
   1166   ObjectOperationDescriptor::NewInternalFieldDereference(
   1167     Isolate* isolate,
   1168     int internal_field) {
   1169   i::DeclaredAccessorDescriptorData data;
   1170   data.type = i::kDescriptorObjectDereference;
   1171   data.object_dereference_descriptor.internal_field = internal_field;
   1172   return NewDescriptor<RawOperationDescriptor>(isolate, data, NULL);
   1173 }
   1174 
   1175 
   1176 Local<RawOperationDescriptor> RawOperationDescriptor::NewRawShift(
   1177     Isolate* isolate,
   1178     int16_t byte_offset) {
   1179   i::DeclaredAccessorDescriptorData data;
   1180   data.type = i::kDescriptorPointerShift;
   1181   data.pointer_shift_descriptor.byte_offset = byte_offset;
   1182   return NewDescriptor<RawOperationDescriptor>(isolate, data, this);
   1183 }
   1184 
   1185 
   1186 Local<DeclaredAccessorDescriptor> RawOperationDescriptor::NewHandleDereference(
   1187     Isolate* isolate) {
   1188   i::DeclaredAccessorDescriptorData data;
   1189   data.type = i::kDescriptorReturnObject;
   1190   return NewDescriptor<DeclaredAccessorDescriptor>(isolate, data, this);
   1191 }
   1192 
   1193 
   1194 Local<RawOperationDescriptor> RawOperationDescriptor::NewRawDereference(
   1195     Isolate* isolate) {
   1196   i::DeclaredAccessorDescriptorData data;
   1197   data.type = i::kDescriptorPointerDereference;
   1198   return NewDescriptor<RawOperationDescriptor>(isolate, data, this);
   1199 }
   1200 
   1201 
   1202 Local<DeclaredAccessorDescriptor> RawOperationDescriptor::NewPointerCompare(
   1203     Isolate* isolate,
   1204     void* compare_value) {
   1205   i::DeclaredAccessorDescriptorData data;
   1206   data.type = i::kDescriptorPointerCompare;
   1207   data.pointer_compare_descriptor.compare_value = compare_value;
   1208   return NewDescriptor<DeclaredAccessorDescriptor>(isolate, data, this);
   1209 }
   1210 
   1211 
   1212 Local<DeclaredAccessorDescriptor> RawOperationDescriptor::NewPrimitiveValue(
   1213     Isolate* isolate,
   1214     DeclaredAccessorDescriptorDataType data_type,
   1215     uint8_t bool_offset) {
   1216   i::DeclaredAccessorDescriptorData data;
   1217   data.type = i::kDescriptorPrimitiveValue;
   1218   data.primitive_value_descriptor.data_type = data_type;
   1219   data.primitive_value_descriptor.bool_offset = bool_offset;
   1220   return NewDescriptor<DeclaredAccessorDescriptor>(isolate, data, this);
   1221 }
   1222 
   1223 
   1224 template<typename T>
   1225 static Local<DeclaredAccessorDescriptor> NewBitmaskCompare(
   1226     Isolate* isolate,
   1227     T bitmask,
   1228     T compare_value,
   1229     RawOperationDescriptor* operation) {
   1230   i::DeclaredAccessorDescriptorData data;
   1231   data.type = i::kDescriptorBitmaskCompare;
   1232   data.bitmask_compare_descriptor.bitmask = bitmask;
   1233   data.bitmask_compare_descriptor.compare_value = compare_value;
   1234   data.bitmask_compare_descriptor.size = sizeof(T);
   1235   return NewDescriptor<DeclaredAccessorDescriptor>(isolate, data, operation);
   1236 }
   1237 
   1238 
   1239 Local<DeclaredAccessorDescriptor> RawOperationDescriptor::NewBitmaskCompare8(
   1240     Isolate* isolate,
   1241     uint8_t bitmask,
   1242     uint8_t compare_value) {
   1243   return NewBitmaskCompare(isolate, bitmask, compare_value, this);
   1244 }
   1245 
   1246 
   1247 Local<DeclaredAccessorDescriptor> RawOperationDescriptor::NewBitmaskCompare16(
   1248     Isolate* isolate,
   1249     uint16_t bitmask,
   1250     uint16_t compare_value) {
   1251   return NewBitmaskCompare(isolate, bitmask, compare_value, this);
   1252 }
   1253 
   1254 
   1255 Local<DeclaredAccessorDescriptor> RawOperationDescriptor::NewBitmaskCompare32(
   1256     Isolate* isolate,
   1257     uint32_t bitmask,
   1258     uint32_t compare_value) {
   1259   return NewBitmaskCompare(isolate, bitmask, compare_value, this);
   1260 }
   1261 
   1262 
   1263 Local<TypeSwitch> TypeSwitch::New(Handle<FunctionTemplate> type) {
   1264   Handle<FunctionTemplate> types[1] = { type };
   1265   return TypeSwitch::New(1, types);
   1266 }
   1267 
   1268 
   1269 Local<TypeSwitch> TypeSwitch::New(int argc, Handle<FunctionTemplate> types[]) {
   1270   i::Isolate* isolate = i::Isolate::Current();
   1271   EnsureInitializedForIsolate(isolate, "v8::TypeSwitch::New()");
   1272   LOG_API(isolate, "TypeSwitch::New");
   1273   ENTER_V8(isolate);
   1274   i::Handle<i::FixedArray> vector = isolate->factory()->NewFixedArray(argc);
   1275   for (int i = 0; i < argc; i++)
   1276     vector->set(i, *Utils::OpenHandle(*types[i]));
   1277   i::Handle<i::Struct> struct_obj =
   1278       isolate->factory()->NewStruct(i::TYPE_SWITCH_INFO_TYPE);
   1279   i::Handle<i::TypeSwitchInfo> obj =
   1280       i::Handle<i::TypeSwitchInfo>::cast(struct_obj);
   1281   obj->set_types(*vector);
   1282   return Utils::ToLocal(obj);
   1283 }
   1284 
   1285 
   1286 int TypeSwitch::match(v8::Handle<Value> value) {
   1287   i::Isolate* isolate = i::Isolate::Current();
   1288   LOG_API(isolate, "TypeSwitch::match");
   1289   USE(isolate);
   1290   i::Handle<i::Object> obj = Utils::OpenHandle(*value);
   1291   i::Handle<i::TypeSwitchInfo> info = Utils::OpenHandle(this);
   1292   i::FixedArray* types = i::FixedArray::cast(info->types());
   1293   for (int i = 0; i < types->length(); i++) {
   1294     if (i::FunctionTemplateInfo::cast(types->get(i))->IsTemplateFor(*obj))
   1295       return i + 1;
   1296   }
   1297   return 0;
   1298 }
   1299 
   1300 
   1301 #define SET_FIELD_WRAPPED(obj, setter, cdata) do {    \
   1302     i::Handle<i::Object> foreign = FromCData(obj->GetIsolate(), cdata);  \
   1303     (obj)->setter(*foreign);                          \
   1304   } while (false)
   1305 
   1306 
   1307 void FunctionTemplate::SetCallHandler(FunctionCallback callback,
   1308                                       v8::Handle<Value> data) {
   1309   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1310   ENTER_V8(isolate);
   1311   i::HandleScope scope(isolate);
   1312   i::Handle<i::Struct> struct_obj =
   1313       isolate->factory()->NewStruct(i::CALL_HANDLER_INFO_TYPE);
   1314   i::Handle<i::CallHandlerInfo> obj =
   1315       i::Handle<i::CallHandlerInfo>::cast(struct_obj);
   1316   SET_FIELD_WRAPPED(obj, set_callback, callback);
   1317   if (data.IsEmpty()) {
   1318     data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1319   }
   1320   obj->set_data(*Utils::OpenHandle(*data));
   1321   Utils::OpenHandle(this)->set_call_code(*obj);
   1322 }
   1323 
   1324 
   1325 static i::Handle<i::AccessorInfo> SetAccessorInfoProperties(
   1326     i::Handle<i::AccessorInfo> obj,
   1327     v8::Handle<String> name,
   1328     v8::AccessControl settings,
   1329     v8::PropertyAttribute attributes,
   1330     v8::Handle<AccessorSignature> signature) {
   1331   obj->set_name(*Utils::OpenHandle(*name));
   1332   if (settings & ALL_CAN_READ) obj->set_all_can_read(true);
   1333   if (settings & ALL_CAN_WRITE) obj->set_all_can_write(true);
   1334   if (settings & PROHIBITS_OVERWRITING) obj->set_prohibits_overwriting(true);
   1335   obj->set_property_attributes(static_cast<PropertyAttributes>(attributes));
   1336   if (!signature.IsEmpty()) {
   1337     obj->set_expected_receiver_type(*Utils::OpenHandle(*signature));
   1338   }
   1339   return obj;
   1340 }
   1341 
   1342 
   1343 template<typename Getter, typename Setter>
   1344 static i::Handle<i::AccessorInfo> MakeAccessorInfo(
   1345       v8::Handle<String> name,
   1346       Getter getter,
   1347       Setter setter,
   1348       v8::Handle<Value> data,
   1349       v8::AccessControl settings,
   1350       v8::PropertyAttribute attributes,
   1351       v8::Handle<AccessorSignature> signature) {
   1352   i::Isolate* isolate = Utils::OpenHandle(*name)->GetIsolate();
   1353   i::Handle<i::ExecutableAccessorInfo> obj =
   1354       isolate->factory()->NewExecutableAccessorInfo();
   1355   SET_FIELD_WRAPPED(obj, set_getter, getter);
   1356   SET_FIELD_WRAPPED(obj, set_setter, setter);
   1357   if (data.IsEmpty()) {
   1358     data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1359   }
   1360   obj->set_data(*Utils::OpenHandle(*data));
   1361   return SetAccessorInfoProperties(obj, name, settings, attributes, signature);
   1362 }
   1363 
   1364 
   1365 static i::Handle<i::AccessorInfo> MakeAccessorInfo(
   1366       v8::Handle<String> name,
   1367       v8::Handle<v8::DeclaredAccessorDescriptor> descriptor,
   1368       void* setter_ignored,
   1369       void* data_ignored,
   1370       v8::AccessControl settings,
   1371       v8::PropertyAttribute attributes,
   1372       v8::Handle<AccessorSignature> signature) {
   1373   i::Isolate* isolate = Utils::OpenHandle(*name)->GetIsolate();
   1374   if (descriptor.IsEmpty()) return i::Handle<i::DeclaredAccessorInfo>();
   1375   i::Handle<i::DeclaredAccessorInfo> obj =
   1376       isolate->factory()->NewDeclaredAccessorInfo();
   1377   obj->set_descriptor(*Utils::OpenHandle(*descriptor));
   1378   return SetAccessorInfoProperties(obj, name, settings, attributes, signature);
   1379 }
   1380 
   1381 
   1382 Local<ObjectTemplate> FunctionTemplate::InstanceTemplate() {
   1383   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1384   if (EmptyCheck("v8::FunctionTemplate::InstanceTemplate()", this))
   1385     return Local<ObjectTemplate>();
   1386   ENTER_V8(isolate);
   1387   i::Handle<i::FunctionTemplateInfo> handle = Utils::OpenHandle(this);
   1388   if (handle->instance_template()->IsUndefined()) {
   1389     Local<ObjectTemplate> templ =
   1390         ObjectTemplate::New(isolate, ToApiHandle<FunctionTemplate>(handle));
   1391     handle->set_instance_template(*Utils::OpenHandle(*templ));
   1392   }
   1393   i::Handle<i::ObjectTemplateInfo> result(
   1394       i::ObjectTemplateInfo::cast(handle->instance_template()));
   1395   return Utils::ToLocal(result);
   1396 }
   1397 
   1398 
   1399 void FunctionTemplate::SetLength(int length) {
   1400   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1401   ENTER_V8(isolate);
   1402   Utils::OpenHandle(this)->set_length(length);
   1403 }
   1404 
   1405 
   1406 void FunctionTemplate::SetClassName(Handle<String> name) {
   1407   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1408   ENTER_V8(isolate);
   1409   Utils::OpenHandle(this)->set_class_name(*Utils::OpenHandle(*name));
   1410 }
   1411 
   1412 
   1413 void FunctionTemplate::SetHiddenPrototype(bool value) {
   1414   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1415   ENTER_V8(isolate);
   1416   Utils::OpenHandle(this)->set_hidden_prototype(value);
   1417 }
   1418 
   1419 
   1420 void FunctionTemplate::ReadOnlyPrototype() {
   1421   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1422   ENTER_V8(isolate);
   1423   Utils::OpenHandle(this)->set_read_only_prototype(true);
   1424 }
   1425 
   1426 
   1427 void FunctionTemplate::RemovePrototype() {
   1428   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1429   ENTER_V8(isolate);
   1430   Utils::OpenHandle(this)->set_remove_prototype(true);
   1431 }
   1432 
   1433 
   1434 // --- O b j e c t T e m p l a t e ---
   1435 
   1436 
   1437 Local<ObjectTemplate> ObjectTemplate::New(Isolate* isolate) {
   1438   return New(reinterpret_cast<i::Isolate*>(isolate), Local<FunctionTemplate>());
   1439 }
   1440 
   1441 
   1442 Local<ObjectTemplate> ObjectTemplate::New() {
   1443   return New(i::Isolate::Current(), Local<FunctionTemplate>());
   1444 }
   1445 
   1446 
   1447 Local<ObjectTemplate> ObjectTemplate::New(
   1448       i::Isolate* isolate,
   1449       v8::Handle<FunctionTemplate> constructor) {
   1450   EnsureInitializedForIsolate(isolate, "v8::ObjectTemplate::New()");
   1451   LOG_API(isolate, "ObjectTemplate::New");
   1452   ENTER_V8(isolate);
   1453   i::Handle<i::Struct> struct_obj =
   1454       isolate->factory()->NewStruct(i::OBJECT_TEMPLATE_INFO_TYPE);
   1455   i::Handle<i::ObjectTemplateInfo> obj =
   1456       i::Handle<i::ObjectTemplateInfo>::cast(struct_obj);
   1457   InitializeTemplate(obj, Consts::OBJECT_TEMPLATE);
   1458   if (!constructor.IsEmpty())
   1459     obj->set_constructor(*Utils::OpenHandle(*constructor));
   1460   obj->set_internal_field_count(i::Smi::FromInt(0));
   1461   return Utils::ToLocal(obj);
   1462 }
   1463 
   1464 
   1465 // Ensure that the object template has a constructor.  If no
   1466 // constructor is available we create one.
   1467 static i::Handle<i::FunctionTemplateInfo> EnsureConstructor(
   1468     ObjectTemplate* object_template) {
   1469   i::Object* obj = Utils::OpenHandle(object_template)->constructor();
   1470   if (!obj ->IsUndefined()) {
   1471     i::FunctionTemplateInfo* info = i::FunctionTemplateInfo::cast(obj);
   1472     return i::Handle<i::FunctionTemplateInfo>(info, info->GetIsolate());
   1473   }
   1474   Local<FunctionTemplate> templ = FunctionTemplate::New();
   1475   i::Handle<i::FunctionTemplateInfo> constructor = Utils::OpenHandle(*templ);
   1476   constructor->set_instance_template(*Utils::OpenHandle(object_template));
   1477   Utils::OpenHandle(object_template)->set_constructor(*constructor);
   1478   return constructor;
   1479 }
   1480 
   1481 
   1482 static inline void AddPropertyToTemplate(
   1483     i::Handle<i::TemplateInfo> info,
   1484     i::Handle<i::AccessorInfo> obj) {
   1485   i::Handle<i::Object> list(info->property_accessors(), info->GetIsolate());
   1486   if (list->IsUndefined()) {
   1487     list = NeanderArray().value();
   1488     info->set_property_accessors(*list);
   1489   }
   1490   NeanderArray array(list);
   1491   array.add(obj);
   1492 }
   1493 
   1494 
   1495 static inline i::Handle<i::TemplateInfo> GetTemplateInfo(
   1496     Template* template_obj) {
   1497   return Utils::OpenHandle(template_obj);
   1498 }
   1499 
   1500 
   1501 // TODO(dcarney): remove this with ObjectTemplate::SetAccessor
   1502 static inline i::Handle<i::TemplateInfo> GetTemplateInfo(
   1503     ObjectTemplate* object_template) {
   1504   EnsureConstructor(object_template);
   1505   return Utils::OpenHandle(object_template);
   1506 }
   1507 
   1508 
   1509 template<typename Setter, typename Getter, typename Data, typename Template>
   1510 static bool TemplateSetAccessor(
   1511     Template* template_obj,
   1512     v8::Local<String> name,
   1513     Getter getter,
   1514     Setter setter,
   1515     Data data,
   1516     AccessControl settings,
   1517     PropertyAttribute attribute,
   1518     v8::Local<AccessorSignature> signature) {
   1519   i::Isolate* isolate = Utils::OpenHandle(template_obj)->GetIsolate();
   1520   ENTER_V8(isolate);
   1521   i::HandleScope scope(isolate);
   1522   i::Handle<i::AccessorInfo> obj = MakeAccessorInfo(
   1523       name, getter, setter, data, settings, attribute, signature);
   1524   if (obj.is_null()) return false;
   1525   i::Handle<i::TemplateInfo> info = GetTemplateInfo(template_obj);
   1526   AddPropertyToTemplate(info, obj);
   1527   return true;
   1528 }
   1529 
   1530 
   1531 bool Template::SetDeclaredAccessor(
   1532     Local<String> name,
   1533     Local<DeclaredAccessorDescriptor> descriptor,
   1534     PropertyAttribute attribute,
   1535     Local<AccessorSignature> signature,
   1536     AccessControl settings) {
   1537   void* null = NULL;
   1538   return TemplateSetAccessor(
   1539       this, name, descriptor, null, null, settings, attribute, signature);
   1540 }
   1541 
   1542 
   1543 void Template::SetNativeDataProperty(v8::Local<String> name,
   1544                                      AccessorGetterCallback getter,
   1545                                      AccessorSetterCallback setter,
   1546                                      v8::Handle<Value> data,
   1547                                      PropertyAttribute attribute,
   1548                                      v8::Local<AccessorSignature> signature,
   1549                                      AccessControl settings) {
   1550   TemplateSetAccessor(
   1551       this, name, getter, setter, data, settings, attribute, signature);
   1552 }
   1553 
   1554 
   1555 void ObjectTemplate::SetAccessor(v8::Handle<String> name,
   1556                                  AccessorGetterCallback getter,
   1557                                  AccessorSetterCallback setter,
   1558                                  v8::Handle<Value> data,
   1559                                  AccessControl settings,
   1560                                  PropertyAttribute attribute,
   1561                                  v8::Handle<AccessorSignature> signature) {
   1562   TemplateSetAccessor(
   1563       this, name, getter, setter, data, settings, attribute, signature);
   1564 }
   1565 
   1566 
   1567 void ObjectTemplate::SetNamedPropertyHandler(
   1568     NamedPropertyGetterCallback getter,
   1569     NamedPropertySetterCallback setter,
   1570     NamedPropertyQueryCallback query,
   1571     NamedPropertyDeleterCallback remover,
   1572     NamedPropertyEnumeratorCallback enumerator,
   1573     Handle<Value> data) {
   1574   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1575   ENTER_V8(isolate);
   1576   i::HandleScope scope(isolate);
   1577   EnsureConstructor(this);
   1578   i::FunctionTemplateInfo* constructor = i::FunctionTemplateInfo::cast(
   1579       Utils::OpenHandle(this)->constructor());
   1580   i::Handle<i::FunctionTemplateInfo> cons(constructor);
   1581   i::Handle<i::Struct> struct_obj =
   1582       isolate->factory()->NewStruct(i::INTERCEPTOR_INFO_TYPE);
   1583   i::Handle<i::InterceptorInfo> obj =
   1584       i::Handle<i::InterceptorInfo>::cast(struct_obj);
   1585 
   1586   if (getter != 0) SET_FIELD_WRAPPED(obj, set_getter, getter);
   1587   if (setter != 0) SET_FIELD_WRAPPED(obj, set_setter, setter);
   1588   if (query != 0) SET_FIELD_WRAPPED(obj, set_query, query);
   1589   if (remover != 0) SET_FIELD_WRAPPED(obj, set_deleter, remover);
   1590   if (enumerator != 0) SET_FIELD_WRAPPED(obj, set_enumerator, enumerator);
   1591 
   1592   if (data.IsEmpty()) {
   1593     data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1594   }
   1595   obj->set_data(*Utils::OpenHandle(*data));
   1596   cons->set_named_property_handler(*obj);
   1597 }
   1598 
   1599 
   1600 void ObjectTemplate::MarkAsUndetectable() {
   1601   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1602   ENTER_V8(isolate);
   1603   i::HandleScope scope(isolate);
   1604   EnsureConstructor(this);
   1605   i::FunctionTemplateInfo* constructor =
   1606       i::FunctionTemplateInfo::cast(Utils::OpenHandle(this)->constructor());
   1607   i::Handle<i::FunctionTemplateInfo> cons(constructor);
   1608   cons->set_undetectable(true);
   1609 }
   1610 
   1611 
   1612 void ObjectTemplate::SetAccessCheckCallbacks(
   1613       NamedSecurityCallback named_callback,
   1614       IndexedSecurityCallback indexed_callback,
   1615       Handle<Value> data,
   1616       bool turned_on_by_default) {
   1617   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1618   ENTER_V8(isolate);
   1619   i::HandleScope scope(isolate);
   1620   EnsureConstructor(this);
   1621 
   1622   i::Handle<i::Struct> struct_info =
   1623       isolate->factory()->NewStruct(i::ACCESS_CHECK_INFO_TYPE);
   1624   i::Handle<i::AccessCheckInfo> info =
   1625       i::Handle<i::AccessCheckInfo>::cast(struct_info);
   1626 
   1627   SET_FIELD_WRAPPED(info, set_named_callback, named_callback);
   1628   SET_FIELD_WRAPPED(info, set_indexed_callback, indexed_callback);
   1629 
   1630   if (data.IsEmpty()) {
   1631     data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1632   }
   1633   info->set_data(*Utils::OpenHandle(*data));
   1634 
   1635   i::FunctionTemplateInfo* constructor =
   1636       i::FunctionTemplateInfo::cast(Utils::OpenHandle(this)->constructor());
   1637   i::Handle<i::FunctionTemplateInfo> cons(constructor);
   1638   cons->set_access_check_info(*info);
   1639   cons->set_needs_access_check(turned_on_by_default);
   1640 }
   1641 
   1642 
   1643 void ObjectTemplate::SetIndexedPropertyHandler(
   1644       IndexedPropertyGetterCallback getter,
   1645       IndexedPropertySetterCallback setter,
   1646       IndexedPropertyQueryCallback query,
   1647       IndexedPropertyDeleterCallback remover,
   1648       IndexedPropertyEnumeratorCallback enumerator,
   1649       Handle<Value> data) {
   1650   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1651   ENTER_V8(isolate);
   1652   i::HandleScope scope(isolate);
   1653   EnsureConstructor(this);
   1654   i::FunctionTemplateInfo* constructor = i::FunctionTemplateInfo::cast(
   1655       Utils::OpenHandle(this)->constructor());
   1656   i::Handle<i::FunctionTemplateInfo> cons(constructor);
   1657   i::Handle<i::Struct> struct_obj =
   1658       isolate->factory()->NewStruct(i::INTERCEPTOR_INFO_TYPE);
   1659   i::Handle<i::InterceptorInfo> obj =
   1660       i::Handle<i::InterceptorInfo>::cast(struct_obj);
   1661 
   1662   if (getter != 0) SET_FIELD_WRAPPED(obj, set_getter, getter);
   1663   if (setter != 0) SET_FIELD_WRAPPED(obj, set_setter, setter);
   1664   if (query != 0) SET_FIELD_WRAPPED(obj, set_query, query);
   1665   if (remover != 0) SET_FIELD_WRAPPED(obj, set_deleter, remover);
   1666   if (enumerator != 0) SET_FIELD_WRAPPED(obj, set_enumerator, enumerator);
   1667 
   1668   if (data.IsEmpty()) {
   1669     data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1670   }
   1671   obj->set_data(*Utils::OpenHandle(*data));
   1672   cons->set_indexed_property_handler(*obj);
   1673 }
   1674 
   1675 
   1676 void ObjectTemplate::SetCallAsFunctionHandler(FunctionCallback callback,
   1677                                               Handle<Value> data) {
   1678   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1679   ENTER_V8(isolate);
   1680   i::HandleScope scope(isolate);
   1681   EnsureConstructor(this);
   1682   i::FunctionTemplateInfo* constructor = i::FunctionTemplateInfo::cast(
   1683       Utils::OpenHandle(this)->constructor());
   1684   i::Handle<i::FunctionTemplateInfo> cons(constructor);
   1685   i::Handle<i::Struct> struct_obj =
   1686       isolate->factory()->NewStruct(i::CALL_HANDLER_INFO_TYPE);
   1687   i::Handle<i::CallHandlerInfo> obj =
   1688       i::Handle<i::CallHandlerInfo>::cast(struct_obj);
   1689   SET_FIELD_WRAPPED(obj, set_callback, callback);
   1690   if (data.IsEmpty()) {
   1691     data = v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   1692   }
   1693   obj->set_data(*Utils::OpenHandle(*data));
   1694   cons->set_instance_call_handler(*obj);
   1695 }
   1696 
   1697 
   1698 int ObjectTemplate::InternalFieldCount() {
   1699   return i::Smi::cast(Utils::OpenHandle(this)->internal_field_count())->value();
   1700 }
   1701 
   1702 
   1703 void ObjectTemplate::SetInternalFieldCount(int value) {
   1704   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   1705   if (!ApiCheck(i::Smi::IsValid(value),
   1706                 "v8::ObjectTemplate::SetInternalFieldCount()",
   1707                 "Invalid internal field count")) {
   1708     return;
   1709   }
   1710   ENTER_V8(isolate);
   1711   if (value > 0) {
   1712     // The internal field count is set by the constructor function's
   1713     // construct code, so we ensure that there is a constructor
   1714     // function to do the setting.
   1715     EnsureConstructor(this);
   1716   }
   1717   Utils::OpenHandle(this)->set_internal_field_count(i::Smi::FromInt(value));
   1718 }
   1719 
   1720 
   1721 // --- S c r i p t D a t a ---
   1722 
   1723 
   1724 ScriptData* ScriptData::PreCompile(v8::Isolate* isolate,
   1725                                    const char* input,
   1726                                    int length) {
   1727   i::Utf8ToUtf16CharacterStream stream(
   1728       reinterpret_cast<const unsigned char*>(input), length);
   1729   return i::PreParserApi::PreParse(
   1730       reinterpret_cast<i::Isolate*>(isolate), &stream);
   1731 }
   1732 
   1733 
   1734 ScriptData* ScriptData::PreCompile(v8::Handle<String> source) {
   1735   i::Handle<i::String> str = Utils::OpenHandle(*source);
   1736   i::Isolate* isolate = str->GetIsolate();
   1737   if (str->IsExternalTwoByteString()) {
   1738     i::ExternalTwoByteStringUtf16CharacterStream stream(
   1739       i::Handle<i::ExternalTwoByteString>::cast(str), 0, str->length());
   1740     return i::PreParserApi::PreParse(isolate, &stream);
   1741   } else {
   1742     i::GenericStringUtf16CharacterStream stream(str, 0, str->length());
   1743     return i::PreParserApi::PreParse(isolate, &stream);
   1744   }
   1745 }
   1746 
   1747 
   1748 ScriptData* ScriptData::New(const char* data, int length) {
   1749   // Return an empty ScriptData if the length is obviously invalid.
   1750   if (length % sizeof(unsigned) != 0) {
   1751     return new i::ScriptDataImpl();
   1752   }
   1753 
   1754   // Copy the data to ensure it is properly aligned.
   1755   int deserialized_data_length = length / sizeof(unsigned);
   1756   // If aligned, don't create a copy of the data.
   1757   if (reinterpret_cast<intptr_t>(data) % sizeof(unsigned) == 0) {
   1758     return new i::ScriptDataImpl(data, length);
   1759   }
   1760   // Copy the data to align it.
   1761   unsigned* deserialized_data = i::NewArray<unsigned>(deserialized_data_length);
   1762   i::CopyBytes(reinterpret_cast<char*>(deserialized_data),
   1763                data, static_cast<size_t>(length));
   1764 
   1765   return new i::ScriptDataImpl(
   1766       i::Vector<unsigned>(deserialized_data, deserialized_data_length));
   1767 }
   1768 
   1769 
   1770 // --- S c r i p t ---
   1771 
   1772 
   1773 Local<Script> Script::New(v8::Handle<String> source,
   1774                           v8::ScriptOrigin* origin,
   1775                           v8::ScriptData* pre_data,
   1776                           v8::Handle<String> script_data) {
   1777   i::Handle<i::String> str = Utils::OpenHandle(*source);
   1778   i::Isolate* isolate = str->GetIsolate();
   1779   ON_BAILOUT(isolate, "v8::Script::New()", return Local<Script>());
   1780   LOG_API(isolate, "Script::New");
   1781   ENTER_V8(isolate);
   1782   i::SharedFunctionInfo* raw_result = NULL;
   1783   { i::HandleScope scope(isolate);
   1784     i::Handle<i::Object> name_obj;
   1785     int line_offset = 0;
   1786     int column_offset = 0;
   1787     bool is_shared_cross_origin = false;
   1788     if (origin != NULL) {
   1789       if (!origin->ResourceName().IsEmpty()) {
   1790         name_obj = Utils::OpenHandle(*origin->ResourceName());
   1791       }
   1792       if (!origin->ResourceLineOffset().IsEmpty()) {
   1793         line_offset = static_cast<int>(origin->ResourceLineOffset()->Value());
   1794       }
   1795       if (!origin->ResourceColumnOffset().IsEmpty()) {
   1796         column_offset =
   1797             static_cast<int>(origin->ResourceColumnOffset()->Value());
   1798       }
   1799       if (!origin->ResourceIsSharedCrossOrigin().IsEmpty()) {
   1800         v8::Isolate* v8_isolate = reinterpret_cast<v8::Isolate*>(isolate);
   1801         is_shared_cross_origin =
   1802             origin->ResourceIsSharedCrossOrigin() == v8::True(v8_isolate);
   1803       }
   1804     }
   1805     EXCEPTION_PREAMBLE(isolate);
   1806     i::ScriptDataImpl* pre_data_impl =
   1807         static_cast<i::ScriptDataImpl*>(pre_data);
   1808     // We assert that the pre-data is sane, even though we can actually
   1809     // handle it if it turns out not to be in release mode.
   1810     ASSERT(pre_data_impl == NULL || pre_data_impl->SanityCheck());
   1811     // If the pre-data isn't sane we simply ignore it
   1812     if (pre_data_impl != NULL && !pre_data_impl->SanityCheck()) {
   1813       pre_data_impl = NULL;
   1814     }
   1815     i::Handle<i::SharedFunctionInfo> result =
   1816       i::Compiler::Compile(str,
   1817                            name_obj,
   1818                            line_offset,
   1819                            column_offset,
   1820                            is_shared_cross_origin,
   1821                            isolate->global_context(),
   1822                            NULL,
   1823                            pre_data_impl,
   1824                            Utils::OpenHandle(*script_data, true),
   1825                            i::NOT_NATIVES_CODE);
   1826     has_pending_exception = result.is_null();
   1827     EXCEPTION_BAILOUT_CHECK(isolate, Local<Script>());
   1828     raw_result = *result;
   1829   }
   1830   i::Handle<i::SharedFunctionInfo> result(raw_result, isolate);
   1831   return ToApiHandle<Script>(result);
   1832 }
   1833 
   1834 
   1835 Local<Script> Script::New(v8::Handle<String> source,
   1836                           v8::Handle<Value> file_name) {
   1837   ScriptOrigin origin(file_name);
   1838   return New(source, &origin);
   1839 }
   1840 
   1841 
   1842 Local<Script> Script::Compile(v8::Handle<String> source,
   1843                               v8::ScriptOrigin* origin,
   1844                               v8::ScriptData* pre_data,
   1845                               v8::Handle<String> script_data) {
   1846   i::Handle<i::String> str = Utils::OpenHandle(*source);
   1847   i::Isolate* isolate = str->GetIsolate();
   1848   ON_BAILOUT(isolate, "v8::Script::Compile()", return Local<Script>());
   1849   LOG_API(isolate, "Script::Compile");
   1850   ENTER_V8(isolate);
   1851   Local<Script> generic = New(source, origin, pre_data, script_data);
   1852   if (generic.IsEmpty())
   1853     return generic;
   1854   i::Handle<i::Object> obj = Utils::OpenHandle(*generic);
   1855   i::Handle<i::SharedFunctionInfo> function =
   1856       i::Handle<i::SharedFunctionInfo>(i::SharedFunctionInfo::cast(*obj));
   1857   i::Handle<i::JSFunction> result =
   1858       isolate->factory()->NewFunctionFromSharedFunctionInfo(
   1859           function,
   1860           isolate->global_context());
   1861   return ToApiHandle<Script>(result);
   1862 }
   1863 
   1864 
   1865 Local<Script> Script::Compile(v8::Handle<String> source,
   1866                               v8::Handle<Value> file_name,
   1867                               v8::Handle<String> script_data) {
   1868   ScriptOrigin origin(file_name);
   1869   return Compile(source, &origin, 0, script_data);
   1870 }
   1871 
   1872 
   1873 Local<Value> Script::Run() {
   1874   // If execution is terminating, Compile(script)->Run() requires this check.
   1875   if (this == NULL) return Local<Value>();
   1876   i::Handle<i::HeapObject> obj =
   1877       i::Handle<i::HeapObject>::cast(Utils::OpenHandle(this));
   1878   i::Isolate* isolate = obj->GetIsolate();
   1879   ON_BAILOUT(isolate, "v8::Script::Run()", return Local<Value>());
   1880   LOG_API(isolate, "Script::Run");
   1881   ENTER_V8(isolate);
   1882   i::Logger::TimerEventScope timer_scope(
   1883       isolate, i::Logger::TimerEventScope::v8_execute);
   1884   i::Object* raw_result = NULL;
   1885   {
   1886     i::HandleScope scope(isolate);
   1887     i::Handle<i::JSFunction> fun;
   1888     if (obj->IsSharedFunctionInfo()) {
   1889       i::Handle<i::SharedFunctionInfo>
   1890           function_info(i::SharedFunctionInfo::cast(*obj), isolate);
   1891       fun = isolate->factory()->NewFunctionFromSharedFunctionInfo(
   1892           function_info, isolate->global_context());
   1893     } else {
   1894       fun = i::Handle<i::JSFunction>(i::JSFunction::cast(*obj), isolate);
   1895     }
   1896     EXCEPTION_PREAMBLE(isolate);
   1897     i::Handle<i::Object> receiver(
   1898         isolate->context()->global_proxy(), isolate);
   1899     i::Handle<i::Object> result = i::Execution::Call(
   1900         isolate, fun, receiver, 0, NULL, &has_pending_exception);
   1901     EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, Local<Value>());
   1902     raw_result = *result;
   1903   }
   1904   i::Handle<i::Object> result(raw_result, isolate);
   1905   return Utils::ToLocal(result);
   1906 }
   1907 
   1908 
   1909 static i::Handle<i::SharedFunctionInfo> OpenScript(Script* script) {
   1910   i::Handle<i::Object> obj = Utils::OpenHandle(script);
   1911   i::Handle<i::SharedFunctionInfo> result;
   1912   if (obj->IsSharedFunctionInfo()) {
   1913     result =
   1914         i::Handle<i::SharedFunctionInfo>(i::SharedFunctionInfo::cast(*obj));
   1915   } else {
   1916     result =
   1917         i::Handle<i::SharedFunctionInfo>(i::JSFunction::cast(*obj)->shared());
   1918   }
   1919   return result;
   1920 }
   1921 
   1922 
   1923 Local<Value> Script::Id() {
   1924   i::Handle<i::HeapObject> obj =
   1925       i::Handle<i::HeapObject>::cast(Utils::OpenHandle(this));
   1926   i::Isolate* isolate = obj->GetIsolate();
   1927   ON_BAILOUT(isolate, "v8::Script::Id()", return Local<Value>());
   1928   LOG_API(isolate, "Script::Id");
   1929   i::Object* raw_id = NULL;
   1930   {
   1931     i::HandleScope scope(isolate);
   1932     i::Handle<i::SharedFunctionInfo> function_info = OpenScript(this);
   1933     i::Handle<i::Script> script(i::Script::cast(function_info->script()));
   1934     i::Handle<i::Object> id(script->id(), isolate);
   1935     raw_id = *id;
   1936   }
   1937   i::Handle<i::Object> id(raw_id, isolate);
   1938   return Utils::ToLocal(id);
   1939 }
   1940 
   1941 
   1942 int Script::GetId() {
   1943   i::Handle<i::HeapObject> obj =
   1944       i::Handle<i::HeapObject>::cast(Utils::OpenHandle(this));
   1945   i::Isolate* isolate = obj->GetIsolate();
   1946   ON_BAILOUT(isolate, "v8::Script::Id()", return -1);
   1947   LOG_API(isolate, "Script::Id");
   1948   {
   1949     i::HandleScope scope(isolate);
   1950     i::Handle<i::SharedFunctionInfo> function_info = OpenScript(this);
   1951     i::Handle<i::Script> script(i::Script::cast(function_info->script()));
   1952     return script->id()->value();
   1953   }
   1954 }
   1955 
   1956 
   1957 int Script::GetLineNumber(int code_pos) {
   1958   i::Handle<i::HeapObject> obj =
   1959       i::Handle<i::HeapObject>::cast(Utils::OpenHandle(this));
   1960   i::Isolate* isolate = obj->GetIsolate();
   1961   ON_BAILOUT(isolate, "v8::Script::GetLineNumber()", return -1);
   1962   LOG_API(isolate, "Script::GetLineNumber");
   1963   if (obj->IsScript()) {
   1964     i::Handle<i::Script> script = i::Handle<i::Script>(i::Script::cast(*obj));
   1965     return i::GetScriptLineNumber(script, code_pos);
   1966   } else {
   1967     return -1;
   1968   }
   1969 }
   1970 
   1971 
   1972 Handle<Value> Script::GetScriptName() {
   1973   i::Handle<i::HeapObject> obj =
   1974       i::Handle<i::HeapObject>::cast(Utils::OpenHandle(this));
   1975   i::Isolate* isolate = obj->GetIsolate();
   1976   ON_BAILOUT(isolate, "v8::Script::GetName()", return Handle<String>());
   1977   LOG_API(isolate, "Script::GetName");
   1978   if (obj->IsScript()) {
   1979     i::Object* name = i::Script::cast(*obj)->name();
   1980     return Utils::ToLocal(i::Handle<i::Object>(name, isolate));
   1981   } else {
   1982     return Handle<String>();
   1983   }
   1984 }
   1985 
   1986 
   1987 void Script::SetData(v8::Handle<String> data) {
   1988   i::Handle<i::HeapObject> obj =
   1989       i::Handle<i::HeapObject>::cast(Utils::OpenHandle(this));
   1990   i::Isolate* isolate = obj->GetIsolate();
   1991   ON_BAILOUT(isolate, "v8::Script::SetData()", return);
   1992   LOG_API(isolate, "Script::SetData");
   1993   {
   1994     i::HandleScope scope(isolate);
   1995     i::Handle<i::SharedFunctionInfo> function_info = OpenScript(this);
   1996     i::Handle<i::Object> raw_data = Utils::OpenHandle(*data);
   1997     i::Handle<i::Script> script(i::Script::cast(function_info->script()));
   1998     script->set_data(*raw_data);
   1999   }
   2000 }
   2001 
   2002 
   2003 // --- E x c e p t i o n s ---
   2004 
   2005 
   2006 v8::TryCatch::TryCatch()
   2007     : isolate_(i::Isolate::Current()),
   2008       next_(isolate_->try_catch_handler_address()),
   2009       is_verbose_(false),
   2010       can_continue_(true),
   2011       capture_message_(true),
   2012       rethrow_(false),
   2013       has_terminated_(false) {
   2014   Reset();
   2015   isolate_->RegisterTryCatchHandler(this);
   2016 }
   2017 
   2018 
   2019 v8::TryCatch::~TryCatch() {
   2020   ASSERT(isolate_ == i::Isolate::Current());
   2021   if (rethrow_) {
   2022     v8::Isolate* isolate = reinterpret_cast<Isolate*>(isolate_);
   2023     v8::HandleScope scope(isolate);
   2024     v8::Local<v8::Value> exc = v8::Local<v8::Value>::New(isolate, Exception());
   2025     if (HasCaught() && capture_message_) {
   2026       // If an exception was caught and rethrow_ is indicated, the saved
   2027       // message, script, and location need to be restored to Isolate TLS
   2028       // for reuse.  capture_message_ needs to be disabled so that DoThrow()
   2029       // does not create a new message.
   2030       isolate_->thread_local_top()->rethrowing_message_ = true;
   2031       isolate_->RestorePendingMessageFromTryCatch(this);
   2032     }
   2033     isolate_->UnregisterTryCatchHandler(this);
   2034     reinterpret_cast<Isolate*>(isolate_)->ThrowException(exc);
   2035     ASSERT(!isolate_->thread_local_top()->rethrowing_message_);
   2036   } else {
   2037     isolate_->UnregisterTryCatchHandler(this);
   2038   }
   2039 }
   2040 
   2041 
   2042 bool v8::TryCatch::HasCaught() const {
   2043   return !reinterpret_cast<i::Object*>(exception_)->IsTheHole();
   2044 }
   2045 
   2046 
   2047 bool v8::TryCatch::CanContinue() const {
   2048   return can_continue_;
   2049 }
   2050 
   2051 
   2052 bool v8::TryCatch::HasTerminated() const {
   2053   return has_terminated_;
   2054 }
   2055 
   2056 
   2057 v8::Handle<v8::Value> v8::TryCatch::ReThrow() {
   2058   if (!HasCaught()) return v8::Local<v8::Value>();
   2059   rethrow_ = true;
   2060   return v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate_));
   2061 }
   2062 
   2063 
   2064 v8::Local<Value> v8::TryCatch::Exception() const {
   2065   ASSERT(isolate_ == i::Isolate::Current());
   2066   if (HasCaught()) {
   2067     // Check for out of memory exception.
   2068     i::Object* exception = reinterpret_cast<i::Object*>(exception_);
   2069     return v8::Utils::ToLocal(i::Handle<i::Object>(exception, isolate_));
   2070   } else {
   2071     return v8::Local<Value>();
   2072   }
   2073 }
   2074 
   2075 
   2076 v8::Local<Value> v8::TryCatch::StackTrace() const {
   2077   ASSERT(isolate_ == i::Isolate::Current());
   2078   if (HasCaught()) {
   2079     i::Object* raw_obj = reinterpret_cast<i::Object*>(exception_);
   2080     if (!raw_obj->IsJSObject()) return v8::Local<Value>();
   2081     i::HandleScope scope(isolate_);
   2082     i::Handle<i::JSObject> obj(i::JSObject::cast(raw_obj), isolate_);
   2083     i::Handle<i::String> name = isolate_->factory()->stack_string();
   2084     if (!i::JSReceiver::HasProperty(obj, name)) return v8::Local<Value>();
   2085     i::Handle<i::Object> value = i::GetProperty(isolate_, obj, name);
   2086     if (value.is_null()) return v8::Local<Value>();
   2087     return v8::Utils::ToLocal(scope.CloseAndEscape(value));
   2088   } else {
   2089     return v8::Local<Value>();
   2090   }
   2091 }
   2092 
   2093 
   2094 v8::Local<v8::Message> v8::TryCatch::Message() const {
   2095   ASSERT(isolate_ == i::Isolate::Current());
   2096   i::Object* message = reinterpret_cast<i::Object*>(message_obj_);
   2097   ASSERT(message->IsJSMessageObject() || message->IsTheHole());
   2098   if (HasCaught() && !message->IsTheHole()) {
   2099     return v8::Utils::MessageToLocal(i::Handle<i::Object>(message, isolate_));
   2100   } else {
   2101     return v8::Local<v8::Message>();
   2102   }
   2103 }
   2104 
   2105 
   2106 void v8::TryCatch::Reset() {
   2107   ASSERT(isolate_ == i::Isolate::Current());
   2108   i::Object* the_hole = isolate_->heap()->the_hole_value();
   2109   exception_ = the_hole;
   2110   message_obj_ = the_hole;
   2111   message_script_ = the_hole;
   2112   message_start_pos_ = 0;
   2113   message_end_pos_ = 0;
   2114 }
   2115 
   2116 
   2117 void v8::TryCatch::SetVerbose(bool value) {
   2118   is_verbose_ = value;
   2119 }
   2120 
   2121 
   2122 void v8::TryCatch::SetCaptureMessage(bool value) {
   2123   capture_message_ = value;
   2124 }
   2125 
   2126 
   2127 // --- M e s s a g e ---
   2128 
   2129 
   2130 Local<String> Message::Get() const {
   2131   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2132   ON_BAILOUT(isolate, "v8::Message::Get()", return Local<String>());
   2133   ENTER_V8(isolate);
   2134   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2135   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2136   i::Handle<i::String> raw_result = i::MessageHandler::GetMessage(isolate, obj);
   2137   Local<String> result = Utils::ToLocal(raw_result);
   2138   return scope.Escape(result);
   2139 }
   2140 
   2141 
   2142 v8::Handle<Value> Message::GetScriptResourceName() const {
   2143   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2144   ENTER_V8(isolate);
   2145   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2146   i::Handle<i::JSMessageObject> message =
   2147       i::Handle<i::JSMessageObject>::cast(Utils::OpenHandle(this));
   2148   // Return this.script.name.
   2149   i::Handle<i::JSValue> script =
   2150       i::Handle<i::JSValue>::cast(i::Handle<i::Object>(message->script(),
   2151                                                        isolate));
   2152   i::Handle<i::Object> resource_name(i::Script::cast(script->value())->name(),
   2153                                      isolate);
   2154   return scope.Escape(Utils::ToLocal(resource_name));
   2155 }
   2156 
   2157 
   2158 v8::Handle<Value> Message::GetScriptData() const {
   2159   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2160   ENTER_V8(isolate);
   2161   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2162   i::Handle<i::JSMessageObject> message =
   2163       i::Handle<i::JSMessageObject>::cast(Utils::OpenHandle(this));
   2164   // Return this.script.data.
   2165   i::Handle<i::JSValue> script =
   2166       i::Handle<i::JSValue>::cast(i::Handle<i::Object>(message->script(),
   2167                                                        isolate));
   2168   i::Handle<i::Object> data(i::Script::cast(script->value())->data(), isolate);
   2169   return scope.Escape(Utils::ToLocal(data));
   2170 }
   2171 
   2172 
   2173 v8::Handle<v8::StackTrace> Message::GetStackTrace() const {
   2174   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2175   ENTER_V8(isolate);
   2176   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2177   i::Handle<i::JSMessageObject> message =
   2178       i::Handle<i::JSMessageObject>::cast(Utils::OpenHandle(this));
   2179   i::Handle<i::Object> stackFramesObj(message->stack_frames(), isolate);
   2180   if (!stackFramesObj->IsJSArray()) return v8::Handle<v8::StackTrace>();
   2181   i::Handle<i::JSArray> stackTrace =
   2182       i::Handle<i::JSArray>::cast(stackFramesObj);
   2183   return scope.Escape(Utils::StackTraceToLocal(stackTrace));
   2184 }
   2185 
   2186 
   2187 static i::Handle<i::Object> CallV8HeapFunction(const char* name,
   2188                                                i::Handle<i::Object> recv,
   2189                                                int argc,
   2190                                                i::Handle<i::Object> argv[],
   2191                                                bool* has_pending_exception) {
   2192   i::Isolate* isolate = i::Isolate::Current();
   2193   i::Handle<i::String> fmt_str =
   2194       isolate->factory()->InternalizeUtf8String(name);
   2195   i::Object* object_fun =
   2196       isolate->js_builtins_object()->GetPropertyNoExceptionThrown(*fmt_str);
   2197   i::Handle<i::JSFunction> fun =
   2198       i::Handle<i::JSFunction>(i::JSFunction::cast(object_fun));
   2199   i::Handle<i::Object> value = i::Execution::Call(
   2200       isolate, fun, recv, argc, argv, has_pending_exception);
   2201   return value;
   2202 }
   2203 
   2204 
   2205 static i::Handle<i::Object> CallV8HeapFunction(const char* name,
   2206                                                i::Handle<i::Object> data,
   2207                                                bool* has_pending_exception) {
   2208   i::Handle<i::Object> argv[] = { data };
   2209   return CallV8HeapFunction(name,
   2210                             i::Isolate::Current()->js_builtins_object(),
   2211                             ARRAY_SIZE(argv),
   2212                             argv,
   2213                             has_pending_exception);
   2214 }
   2215 
   2216 
   2217 int Message::GetLineNumber() const {
   2218   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2219   ON_BAILOUT(isolate, "v8::Message::GetLineNumber()", return kNoLineNumberInfo);
   2220   ENTER_V8(isolate);
   2221   i::HandleScope scope(isolate);
   2222 
   2223   EXCEPTION_PREAMBLE(isolate);
   2224   i::Handle<i::Object> result = CallV8HeapFunction("GetLineNumber",
   2225                                                    Utils::OpenHandle(this),
   2226                                                    &has_pending_exception);
   2227   EXCEPTION_BAILOUT_CHECK(isolate, 0);
   2228   return static_cast<int>(result->Number());
   2229 }
   2230 
   2231 
   2232 int Message::GetStartPosition() const {
   2233   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2234   ENTER_V8(isolate);
   2235   i::HandleScope scope(isolate);
   2236   i::Handle<i::JSMessageObject> message =
   2237       i::Handle<i::JSMessageObject>::cast(Utils::OpenHandle(this));
   2238   return message->start_position();
   2239 }
   2240 
   2241 
   2242 int Message::GetEndPosition() const {
   2243   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2244   ENTER_V8(isolate);
   2245   i::HandleScope scope(isolate);
   2246   i::Handle<i::JSMessageObject> message =
   2247       i::Handle<i::JSMessageObject>::cast(Utils::OpenHandle(this));
   2248   return message->end_position();
   2249 }
   2250 
   2251 
   2252 int Message::GetStartColumn() const {
   2253   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2254   ENTER_V8(isolate);
   2255   i::HandleScope scope(isolate);
   2256   i::Handle<i::JSObject> data_obj = Utils::OpenHandle(this);
   2257   EXCEPTION_PREAMBLE(isolate);
   2258   i::Handle<i::Object> start_col_obj = CallV8HeapFunction(
   2259       "GetPositionInLine",
   2260       data_obj,
   2261       &has_pending_exception);
   2262   EXCEPTION_BAILOUT_CHECK(isolate, 0);
   2263   return static_cast<int>(start_col_obj->Number());
   2264 }
   2265 
   2266 
   2267 int Message::GetEndColumn() const {
   2268   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2269   ENTER_V8(isolate);
   2270   i::HandleScope scope(isolate);
   2271   i::Handle<i::JSObject> data_obj = Utils::OpenHandle(this);
   2272   EXCEPTION_PREAMBLE(isolate);
   2273   i::Handle<i::Object> start_col_obj = CallV8HeapFunction(
   2274       "GetPositionInLine",
   2275       data_obj,
   2276       &has_pending_exception);
   2277   EXCEPTION_BAILOUT_CHECK(isolate, 0);
   2278   i::Handle<i::JSMessageObject> message =
   2279       i::Handle<i::JSMessageObject>::cast(data_obj);
   2280   int start = message->start_position();
   2281   int end = message->end_position();
   2282   return static_cast<int>(start_col_obj->Number()) + (end - start);
   2283 }
   2284 
   2285 
   2286 bool Message::IsSharedCrossOrigin() const {
   2287   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2288   ENTER_V8(isolate);
   2289   i::HandleScope scope(isolate);
   2290   i::Handle<i::JSMessageObject> message =
   2291       i::Handle<i::JSMessageObject>::cast(Utils::OpenHandle(this));
   2292   i::Handle<i::JSValue> script =
   2293       i::Handle<i::JSValue>::cast(i::Handle<i::Object>(message->script(),
   2294                                                        isolate));
   2295   return i::Script::cast(script->value())->is_shared_cross_origin();
   2296 }
   2297 
   2298 
   2299 Local<String> Message::GetSourceLine() const {
   2300   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2301   ON_BAILOUT(isolate, "v8::Message::GetSourceLine()", return Local<String>());
   2302   ENTER_V8(isolate);
   2303   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2304   EXCEPTION_PREAMBLE(isolate);
   2305   i::Handle<i::Object> result = CallV8HeapFunction("GetSourceLine",
   2306                                                    Utils::OpenHandle(this),
   2307                                                    &has_pending_exception);
   2308   EXCEPTION_BAILOUT_CHECK(isolate, Local<v8::String>());
   2309   if (result->IsString()) {
   2310     return scope.Escape(Utils::ToLocal(i::Handle<i::String>::cast(result)));
   2311   } else {
   2312     return Local<String>();
   2313   }
   2314 }
   2315 
   2316 
   2317 void Message::PrintCurrentStackTrace(Isolate* isolate, FILE* out) {
   2318   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   2319   ENTER_V8(i_isolate);
   2320   i_isolate->PrintCurrentStackTrace(out);
   2321 }
   2322 
   2323 
   2324 void Message::PrintCurrentStackTrace(FILE* out) {
   2325   PrintCurrentStackTrace(Isolate::GetCurrent(), out);
   2326 }
   2327 
   2328 
   2329 // --- S t a c k T r a c e ---
   2330 
   2331 Local<StackFrame> StackTrace::GetFrame(uint32_t index) const {
   2332   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2333   ENTER_V8(isolate);
   2334   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2335   i::Handle<i::JSArray> self = Utils::OpenHandle(this);
   2336   i::Object* raw_object = self->GetElementNoExceptionThrown(isolate, index);
   2337   i::Handle<i::JSObject> obj(i::JSObject::cast(raw_object));
   2338   return scope.Escape(Utils::StackFrameToLocal(obj));
   2339 }
   2340 
   2341 
   2342 int StackTrace::GetFrameCount() const {
   2343   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2344   ENTER_V8(isolate);
   2345   return i::Smi::cast(Utils::OpenHandle(this)->length())->value();
   2346 }
   2347 
   2348 
   2349 Local<Array> StackTrace::AsArray() {
   2350   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2351   ENTER_V8(isolate);
   2352   return Utils::ToLocal(Utils::OpenHandle(this));
   2353 }
   2354 
   2355 
   2356 Local<StackTrace> StackTrace::CurrentStackTrace(
   2357     Isolate* isolate,
   2358     int frame_limit,
   2359     StackTraceOptions options) {
   2360   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   2361   ENTER_V8(i_isolate);
   2362   i::Handle<i::JSArray> stackTrace =
   2363       i_isolate->CaptureCurrentStackTrace(frame_limit, options);
   2364   return Utils::StackTraceToLocal(stackTrace);
   2365 }
   2366 
   2367 
   2368 Local<StackTrace> StackTrace::CurrentStackTrace(int frame_limit,
   2369     StackTraceOptions options) {
   2370   return CurrentStackTrace(Isolate::GetCurrent(), frame_limit, options);
   2371 }
   2372 
   2373 
   2374 // --- S t a c k F r a m e ---
   2375 
   2376 int StackFrame::GetLineNumber() const {
   2377   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2378   ENTER_V8(isolate);
   2379   i::HandleScope scope(isolate);
   2380   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2381   i::Handle<i::Object> line = GetProperty(self, "lineNumber");
   2382   if (!line->IsSmi()) {
   2383     return Message::kNoLineNumberInfo;
   2384   }
   2385   return i::Smi::cast(*line)->value();
   2386 }
   2387 
   2388 
   2389 int StackFrame::GetColumn() const {
   2390   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2391   ENTER_V8(isolate);
   2392   i::HandleScope scope(isolate);
   2393   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2394   i::Handle<i::Object> column = GetProperty(self, "column");
   2395   if (!column->IsSmi()) {
   2396     return Message::kNoColumnInfo;
   2397   }
   2398   return i::Smi::cast(*column)->value();
   2399 }
   2400 
   2401 
   2402 int StackFrame::GetScriptId() const {
   2403   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2404   ENTER_V8(isolate);
   2405   i::HandleScope scope(isolate);
   2406   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2407   i::Handle<i::Object> scriptId = GetProperty(self, "scriptId");
   2408   if (!scriptId->IsSmi()) {
   2409     return Message::kNoScriptIdInfo;
   2410   }
   2411   return i::Smi::cast(*scriptId)->value();
   2412 }
   2413 
   2414 
   2415 Local<String> StackFrame::GetScriptName() const {
   2416   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2417   ENTER_V8(isolate);
   2418   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2419   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2420   i::Handle<i::Object> name = GetProperty(self, "scriptName");
   2421   if (!name->IsString()) {
   2422     return Local<String>();
   2423   }
   2424   return scope.Escape(Local<String>::Cast(Utils::ToLocal(name)));
   2425 }
   2426 
   2427 
   2428 Local<String> StackFrame::GetScriptNameOrSourceURL() const {
   2429   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2430   ENTER_V8(isolate);
   2431   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2432   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2433   i::Handle<i::Object> name = GetProperty(self, "scriptNameOrSourceURL");
   2434   if (!name->IsString()) {
   2435     return Local<String>();
   2436   }
   2437   return scope.Escape(Local<String>::Cast(Utils::ToLocal(name)));
   2438 }
   2439 
   2440 
   2441 Local<String> StackFrame::GetFunctionName() const {
   2442   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2443   ENTER_V8(isolate);
   2444   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   2445   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2446   i::Handle<i::Object> name = GetProperty(self, "functionName");
   2447   if (!name->IsString()) {
   2448     return Local<String>();
   2449   }
   2450   return scope.Escape(Local<String>::Cast(Utils::ToLocal(name)));
   2451 }
   2452 
   2453 
   2454 bool StackFrame::IsEval() const {
   2455   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2456   ENTER_V8(isolate);
   2457   i::HandleScope scope(isolate);
   2458   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2459   i::Handle<i::Object> is_eval = GetProperty(self, "isEval");
   2460   return is_eval->IsTrue();
   2461 }
   2462 
   2463 
   2464 bool StackFrame::IsConstructor() const {
   2465   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   2466   ENTER_V8(isolate);
   2467   i::HandleScope scope(isolate);
   2468   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   2469   i::Handle<i::Object> is_constructor = GetProperty(self, "isConstructor");
   2470   return is_constructor->IsTrue();
   2471 }
   2472 
   2473 
   2474 // --- J S O N ---
   2475 
   2476 Local<Value> JSON::Parse(Local<String> json_string) {
   2477   i::Isolate* isolate = i::Isolate::Current();
   2478   EnsureInitializedForIsolate(isolate, "v8::JSON::Parse");
   2479   ENTER_V8(isolate);
   2480   i::HandleScope scope(isolate);
   2481   i::Handle<i::String> source = i::Handle<i::String>(
   2482       FlattenGetString(Utils::OpenHandle(*json_string)));
   2483   EXCEPTION_PREAMBLE(isolate);
   2484   i::Handle<i::Object> result;
   2485   if (source->IsSeqOneByteString()) {
   2486     result = i::JsonParser<true>::Parse(source);
   2487   } else {
   2488     result = i::JsonParser<false>::Parse(source);
   2489   }
   2490   has_pending_exception = result.is_null();
   2491   EXCEPTION_BAILOUT_CHECK(isolate, Local<Object>());
   2492   return Utils::ToLocal(
   2493       i::Handle<i::Object>::cast(scope.CloseAndEscape(result)));
   2494 }
   2495 
   2496 
   2497 // --- D a t a ---
   2498 
   2499 bool Value::FullIsUndefined() const {
   2500   bool result = Utils::OpenHandle(this)->IsUndefined();
   2501   ASSERT_EQ(result, QuickIsUndefined());
   2502   return result;
   2503 }
   2504 
   2505 
   2506 bool Value::FullIsNull() const {
   2507   bool result = Utils::OpenHandle(this)->IsNull();
   2508   ASSERT_EQ(result, QuickIsNull());
   2509   return result;
   2510 }
   2511 
   2512 
   2513 bool Value::IsTrue() const {
   2514   return Utils::OpenHandle(this)->IsTrue();
   2515 }
   2516 
   2517 
   2518 bool Value::IsFalse() const {
   2519   return Utils::OpenHandle(this)->IsFalse();
   2520 }
   2521 
   2522 
   2523 bool Value::IsFunction() const {
   2524   return Utils::OpenHandle(this)->IsJSFunction();
   2525 }
   2526 
   2527 
   2528 bool Value::FullIsString() const {
   2529   bool result = Utils::OpenHandle(this)->IsString();
   2530   ASSERT_EQ(result, QuickIsString());
   2531   return result;
   2532 }
   2533 
   2534 
   2535 bool Value::IsSymbol() const {
   2536   return Utils::OpenHandle(this)->IsSymbol();
   2537 }
   2538 
   2539 
   2540 bool Value::IsArray() const {
   2541   return Utils::OpenHandle(this)->IsJSArray();
   2542 }
   2543 
   2544 
   2545 bool Value::IsArrayBuffer() const {
   2546   return Utils::OpenHandle(this)->IsJSArrayBuffer();
   2547 }
   2548 
   2549 
   2550 bool Value::IsArrayBufferView() const {
   2551   return Utils::OpenHandle(this)->IsJSArrayBufferView();
   2552 }
   2553 
   2554 
   2555 bool Value::IsTypedArray() const {
   2556   return Utils::OpenHandle(this)->IsJSTypedArray();
   2557 }
   2558 
   2559 
   2560 #define TYPED_ARRAY_LIST(F) \
   2561 F(Uint8Array, kExternalUnsignedByteArray) \
   2562 F(Int8Array, kExternalByteArray) \
   2563 F(Uint16Array, kExternalUnsignedShortArray) \
   2564 F(Int16Array, kExternalShortArray) \
   2565 F(Uint32Array, kExternalUnsignedIntArray) \
   2566 F(Int32Array, kExternalIntArray) \
   2567 F(Float32Array, kExternalFloatArray) \
   2568 F(Float64Array, kExternalDoubleArray) \
   2569 F(Uint8ClampedArray, kExternalPixelArray)
   2570 
   2571 
   2572 #define VALUE_IS_TYPED_ARRAY(TypedArray, type_const)                          \
   2573   bool Value::Is##TypedArray() const {                                        \
   2574     i::Handle<i::Object> obj = Utils::OpenHandle(this);                       \
   2575     if (!obj->IsJSTypedArray()) return false;                                 \
   2576     return i::JSTypedArray::cast(*obj)->type() == type_const;                 \
   2577   }
   2578 
   2579 TYPED_ARRAY_LIST(VALUE_IS_TYPED_ARRAY)
   2580 
   2581 #undef VALUE_IS_TYPED_ARRAY
   2582 
   2583 
   2584 bool Value::IsDataView() const {
   2585   return Utils::OpenHandle(this)->IsJSDataView();
   2586 }
   2587 
   2588 
   2589 bool Value::IsObject() const {
   2590   return Utils::OpenHandle(this)->IsJSObject();
   2591 }
   2592 
   2593 
   2594 bool Value::IsNumber() const {
   2595   return Utils::OpenHandle(this)->IsNumber();
   2596 }
   2597 
   2598 
   2599 bool Value::IsBoolean() const {
   2600   return Utils::OpenHandle(this)->IsBoolean();
   2601 }
   2602 
   2603 
   2604 bool Value::IsExternal() const {
   2605   return Utils::OpenHandle(this)->IsExternal();
   2606 }
   2607 
   2608 
   2609 bool Value::IsInt32() const {
   2610   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2611   if (obj->IsSmi()) return true;
   2612   if (obj->IsNumber()) {
   2613     double value = obj->Number();
   2614     static const i::DoubleRepresentation minus_zero(-0.0);
   2615     i::DoubleRepresentation rep(value);
   2616     if (rep.bits == minus_zero.bits) {
   2617       return false;
   2618     }
   2619     return i::FastI2D(i::FastD2I(value)) == value;
   2620   }
   2621   return false;
   2622 }
   2623 
   2624 
   2625 bool Value::IsUint32() const {
   2626   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2627   if (obj->IsSmi()) return i::Smi::cast(*obj)->value() >= 0;
   2628   if (obj->IsNumber()) {
   2629     double value = obj->Number();
   2630     static const i::DoubleRepresentation minus_zero(-0.0);
   2631     i::DoubleRepresentation rep(value);
   2632     if (rep.bits == minus_zero.bits) {
   2633       return false;
   2634     }
   2635     return i::FastUI2D(i::FastD2UI(value)) == value;
   2636   }
   2637   return false;
   2638 }
   2639 
   2640 
   2641 bool Value::IsDate() const {
   2642   i::Isolate* isolate = i::Isolate::Current();
   2643   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2644   return obj->HasSpecificClassOf(isolate->heap()->Date_string());
   2645 }
   2646 
   2647 
   2648 bool Value::IsStringObject() const {
   2649   i::Isolate* isolate = i::Isolate::Current();
   2650   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2651   return obj->HasSpecificClassOf(isolate->heap()->String_string());
   2652 }
   2653 
   2654 
   2655 bool Value::IsSymbolObject() const {
   2656   // TODO(svenpanne): these and other test functions should be written such
   2657   // that they do not use Isolate::Current().
   2658   i::Isolate* isolate = i::Isolate::Current();
   2659   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2660   return obj->HasSpecificClassOf(isolate->heap()->Symbol_string());
   2661 }
   2662 
   2663 
   2664 bool Value::IsNumberObject() const {
   2665   i::Isolate* isolate = i::Isolate::Current();
   2666   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2667   return obj->HasSpecificClassOf(isolate->heap()->Number_string());
   2668 }
   2669 
   2670 
   2671 static i::Object* LookupBuiltin(i::Isolate* isolate,
   2672                                 const char* builtin_name) {
   2673   i::Handle<i::String> string =
   2674       isolate->factory()->InternalizeUtf8String(builtin_name);
   2675   i::Handle<i::JSBuiltinsObject> builtins = isolate->js_builtins_object();
   2676   return builtins->GetPropertyNoExceptionThrown(*string);
   2677 }
   2678 
   2679 
   2680 static bool CheckConstructor(i::Isolate* isolate,
   2681                              i::Handle<i::JSObject> obj,
   2682                              const char* class_name) {
   2683   i::Object* constr = obj->map()->constructor();
   2684   if (!constr->IsJSFunction()) return false;
   2685   i::JSFunction* func = i::JSFunction::cast(constr);
   2686   return func->shared()->native() &&
   2687          constr == LookupBuiltin(isolate, class_name);
   2688 }
   2689 
   2690 
   2691 bool Value::IsNativeError() const {
   2692   i::Isolate* isolate = i::Isolate::Current();
   2693   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2694   if (obj->IsJSObject()) {
   2695     i::Handle<i::JSObject> js_obj(i::JSObject::cast(*obj));
   2696     return CheckConstructor(isolate, js_obj, "$Error") ||
   2697         CheckConstructor(isolate, js_obj, "$EvalError") ||
   2698         CheckConstructor(isolate, js_obj, "$RangeError") ||
   2699         CheckConstructor(isolate, js_obj, "$ReferenceError") ||
   2700         CheckConstructor(isolate, js_obj, "$SyntaxError") ||
   2701         CheckConstructor(isolate, js_obj, "$TypeError") ||
   2702         CheckConstructor(isolate, js_obj, "$URIError");
   2703   } else {
   2704     return false;
   2705   }
   2706 }
   2707 
   2708 
   2709 bool Value::IsBooleanObject() const {
   2710   i::Isolate* isolate = i::Isolate::Current();
   2711   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2712   return obj->HasSpecificClassOf(isolate->heap()->Boolean_string());
   2713 }
   2714 
   2715 
   2716 bool Value::IsRegExp() const {
   2717   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2718   return obj->IsJSRegExp();
   2719 }
   2720 
   2721 
   2722 Local<String> Value::ToString() const {
   2723   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2724   i::Handle<i::Object> str;
   2725   if (obj->IsString()) {
   2726     str = obj;
   2727   } else {
   2728     i::Isolate* isolate = i::Isolate::Current();
   2729     LOG_API(isolate, "ToString");
   2730     ENTER_V8(isolate);
   2731     EXCEPTION_PREAMBLE(isolate);
   2732     str = i::Execution::ToString(isolate, obj, &has_pending_exception);
   2733     EXCEPTION_BAILOUT_CHECK(isolate, Local<String>());
   2734   }
   2735   return ToApiHandle<String>(str);
   2736 }
   2737 
   2738 
   2739 Local<String> Value::ToDetailString() const {
   2740   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2741   i::Handle<i::Object> str;
   2742   if (obj->IsString()) {
   2743     str = obj;
   2744   } else {
   2745     i::Isolate* isolate = i::Isolate::Current();
   2746     LOG_API(isolate, "ToDetailString");
   2747     ENTER_V8(isolate);
   2748     EXCEPTION_PREAMBLE(isolate);
   2749     str = i::Execution::ToDetailString(isolate, obj, &has_pending_exception);
   2750     EXCEPTION_BAILOUT_CHECK(isolate, Local<String>());
   2751   }
   2752   return ToApiHandle<String>(str);
   2753 }
   2754 
   2755 
   2756 Local<v8::Object> Value::ToObject() const {
   2757   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2758   i::Handle<i::Object> val;
   2759   if (obj->IsJSObject()) {
   2760     val = obj;
   2761   } else {
   2762     i::Isolate* isolate = i::Isolate::Current();
   2763     LOG_API(isolate, "ToObject");
   2764     ENTER_V8(isolate);
   2765     EXCEPTION_PREAMBLE(isolate);
   2766     val = i::Execution::ToObject(isolate, obj, &has_pending_exception);
   2767     EXCEPTION_BAILOUT_CHECK(isolate, Local<v8::Object>());
   2768   }
   2769   return ToApiHandle<Object>(val);
   2770 }
   2771 
   2772 
   2773 Local<Boolean> Value::ToBoolean() const {
   2774   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2775   if (obj->IsBoolean()) {
   2776     return ToApiHandle<Boolean>(obj);
   2777   } else {
   2778     i::Isolate* isolate = i::Isolate::Current();
   2779     LOG_API(isolate, "ToBoolean");
   2780     ENTER_V8(isolate);
   2781     i::Handle<i::Object> val =
   2782         isolate->factory()->ToBoolean(obj->BooleanValue());
   2783     return ToApiHandle<Boolean>(val);
   2784   }
   2785 }
   2786 
   2787 
   2788 Local<Number> Value::ToNumber() const {
   2789   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2790   i::Handle<i::Object> num;
   2791   if (obj->IsNumber()) {
   2792     num = obj;
   2793   } else {
   2794     i::Isolate* isolate = i::Isolate::Current();
   2795     LOG_API(isolate, "ToNumber");
   2796     ENTER_V8(isolate);
   2797     EXCEPTION_PREAMBLE(isolate);
   2798     num = i::Execution::ToNumber(isolate, obj, &has_pending_exception);
   2799     EXCEPTION_BAILOUT_CHECK(isolate, Local<Number>());
   2800   }
   2801   return ToApiHandle<Number>(num);
   2802 }
   2803 
   2804 
   2805 Local<Integer> Value::ToInteger() const {
   2806   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   2807   i::Handle<i::Object> num;
   2808   if (obj->IsSmi()) {
   2809     num = obj;
   2810   } else {
   2811     i::Isolate* isolate = i::Isolate::Current();
   2812     LOG_API(isolate, "ToInteger");
   2813     ENTER_V8(isolate);
   2814     EXCEPTION_PREAMBLE(isolate);
   2815     num = i::Execution::ToInteger(isolate, obj, &has_pending_exception);
   2816     EXCEPTION_BAILOUT_CHECK(isolate, Local<Integer>());
   2817   }
   2818   return ToApiHandle<Integer>(num);
   2819 }
   2820 
   2821 
   2822 void i::Internals::CheckInitializedImpl(v8::Isolate* external_isolate) {
   2823   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(external_isolate);
   2824   ApiCheck(isolate != NULL && isolate->IsInitialized() && !isolate->IsDead(),
   2825            "v8::internal::Internals::CheckInitialized()",
   2826            "Isolate is not initialized or V8 has died");
   2827 }
   2828 
   2829 
   2830 void External::CheckCast(v8::Value* that) {
   2831   ApiCheck(Utils::OpenHandle(that)->IsExternal(),
   2832            "v8::External::Cast()",
   2833            "Could not convert to external");
   2834 }
   2835 
   2836 
   2837 void v8::Object::CheckCast(Value* that) {
   2838   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2839   ApiCheck(obj->IsJSObject(),
   2840            "v8::Object::Cast()",
   2841            "Could not convert to object");
   2842 }
   2843 
   2844 
   2845 void v8::Function::CheckCast(Value* that) {
   2846   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2847   ApiCheck(obj->IsJSFunction(),
   2848            "v8::Function::Cast()",
   2849            "Could not convert to function");
   2850 }
   2851 
   2852 
   2853 void v8::String::CheckCast(v8::Value* that) {
   2854   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2855   ApiCheck(obj->IsString(),
   2856            "v8::String::Cast()",
   2857            "Could not convert to string");
   2858 }
   2859 
   2860 
   2861 void v8::Symbol::CheckCast(v8::Value* that) {
   2862   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2863   ApiCheck(obj->IsSymbol(),
   2864            "v8::Symbol::Cast()",
   2865            "Could not convert to symbol");
   2866 }
   2867 
   2868 
   2869 void v8::Number::CheckCast(v8::Value* that) {
   2870   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2871   ApiCheck(obj->IsNumber(),
   2872            "v8::Number::Cast()",
   2873            "Could not convert to number");
   2874 }
   2875 
   2876 
   2877 void v8::Integer::CheckCast(v8::Value* that) {
   2878   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2879   ApiCheck(obj->IsNumber(),
   2880            "v8::Integer::Cast()",
   2881            "Could not convert to number");
   2882 }
   2883 
   2884 
   2885 void v8::Array::CheckCast(Value* that) {
   2886   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2887   ApiCheck(obj->IsJSArray(),
   2888            "v8::Array::Cast()",
   2889            "Could not convert to array");
   2890 }
   2891 
   2892 
   2893 void v8::ArrayBuffer::CheckCast(Value* that) {
   2894   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2895   ApiCheck(obj->IsJSArrayBuffer(),
   2896            "v8::ArrayBuffer::Cast()",
   2897            "Could not convert to ArrayBuffer");
   2898 }
   2899 
   2900 
   2901 void v8::ArrayBufferView::CheckCast(Value* that) {
   2902   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2903   ApiCheck(obj->IsJSArrayBufferView(),
   2904            "v8::ArrayBufferView::Cast()",
   2905            "Could not convert to ArrayBufferView");
   2906 }
   2907 
   2908 
   2909 void v8::TypedArray::CheckCast(Value* that) {
   2910   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2911   ApiCheck(obj->IsJSTypedArray(),
   2912            "v8::TypedArray::Cast()",
   2913            "Could not convert to TypedArray");
   2914 }
   2915 
   2916 
   2917 #define CHECK_TYPED_ARRAY_CAST(ApiClass, typeConst)                         \
   2918   void v8::ApiClass::CheckCast(Value* that) {                               \
   2919     i::Handle<i::Object> obj = Utils::OpenHandle(that);                     \
   2920     ApiCheck(obj->IsJSTypedArray() &&                                       \
   2921              i::JSTypedArray::cast(*obj)->type() == typeConst,              \
   2922              "v8::" #ApiClass "::Cast()",                                   \
   2923              "Could not convert to " #ApiClass);                            \
   2924   }
   2925 
   2926 
   2927 TYPED_ARRAY_LIST(CHECK_TYPED_ARRAY_CAST)
   2928 
   2929 #undef CHECK_TYPED_ARRAY_CAST
   2930 
   2931 
   2932 void v8::DataView::CheckCast(Value* that) {
   2933   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2934   ApiCheck(obj->IsJSDataView(),
   2935            "v8::DataView::Cast()",
   2936            "Could not convert to DataView");
   2937 }
   2938 
   2939 
   2940 void v8::Date::CheckCast(v8::Value* that) {
   2941   i::Isolate* isolate = i::Isolate::Current();
   2942   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2943   ApiCheck(obj->HasSpecificClassOf(isolate->heap()->Date_string()),
   2944            "v8::Date::Cast()",
   2945            "Could not convert to date");
   2946 }
   2947 
   2948 
   2949 void v8::StringObject::CheckCast(v8::Value* that) {
   2950   i::Isolate* isolate = i::Isolate::Current();
   2951   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2952   ApiCheck(obj->HasSpecificClassOf(isolate->heap()->String_string()),
   2953            "v8::StringObject::Cast()",
   2954            "Could not convert to StringObject");
   2955 }
   2956 
   2957 
   2958 void v8::SymbolObject::CheckCast(v8::Value* that) {
   2959   i::Isolate* isolate = i::Isolate::Current();
   2960   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2961   ApiCheck(obj->HasSpecificClassOf(isolate->heap()->Symbol_string()),
   2962            "v8::SymbolObject::Cast()",
   2963            "Could not convert to SymbolObject");
   2964 }
   2965 
   2966 
   2967 void v8::NumberObject::CheckCast(v8::Value* that) {
   2968   i::Isolate* isolate = i::Isolate::Current();
   2969   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2970   ApiCheck(obj->HasSpecificClassOf(isolate->heap()->Number_string()),
   2971            "v8::NumberObject::Cast()",
   2972            "Could not convert to NumberObject");
   2973 }
   2974 
   2975 
   2976 void v8::BooleanObject::CheckCast(v8::Value* that) {
   2977   i::Isolate* isolate = i::Isolate::Current();
   2978   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2979   ApiCheck(obj->HasSpecificClassOf(isolate->heap()->Boolean_string()),
   2980            "v8::BooleanObject::Cast()",
   2981            "Could not convert to BooleanObject");
   2982 }
   2983 
   2984 
   2985 void v8::RegExp::CheckCast(v8::Value* that) {
   2986   i::Handle<i::Object> obj = Utils::OpenHandle(that);
   2987   ApiCheck(obj->IsJSRegExp(),
   2988            "v8::RegExp::Cast()",
   2989            "Could not convert to regular expression");
   2990 }
   2991 
   2992 
   2993 bool Value::BooleanValue() const {
   2994   return Utils::OpenHandle(this)->BooleanValue();
   2995 }
   2996 
   2997 
   2998 double Value::NumberValue() const {
   2999   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3000   i::Handle<i::Object> num;
   3001   if (obj->IsNumber()) {
   3002     num = obj;
   3003   } else {
   3004     i::Isolate* isolate = i::Isolate::Current();
   3005     LOG_API(isolate, "NumberValue");
   3006     ENTER_V8(isolate);
   3007     EXCEPTION_PREAMBLE(isolate);
   3008     num = i::Execution::ToNumber(isolate, obj, &has_pending_exception);
   3009     EXCEPTION_BAILOUT_CHECK(isolate, i::OS::nan_value());
   3010   }
   3011   return num->Number();
   3012 }
   3013 
   3014 
   3015 int64_t Value::IntegerValue() const {
   3016   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3017   i::Handle<i::Object> num;
   3018   if (obj->IsNumber()) {
   3019     num = obj;
   3020   } else {
   3021     i::Isolate* isolate = i::Isolate::Current();
   3022     LOG_API(isolate, "IntegerValue");
   3023     ENTER_V8(isolate);
   3024     EXCEPTION_PREAMBLE(isolate);
   3025     num = i::Execution::ToInteger(isolate, obj, &has_pending_exception);
   3026     EXCEPTION_BAILOUT_CHECK(isolate, 0);
   3027   }
   3028   if (num->IsSmi()) {
   3029     return i::Smi::cast(*num)->value();
   3030   } else {
   3031     return static_cast<int64_t>(num->Number());
   3032   }
   3033 }
   3034 
   3035 
   3036 Local<Int32> Value::ToInt32() const {
   3037   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3038   i::Handle<i::Object> num;
   3039   if (obj->IsSmi()) {
   3040     num = obj;
   3041   } else {
   3042     i::Isolate* isolate = i::Isolate::Current();
   3043     LOG_API(isolate, "ToInt32");
   3044     ENTER_V8(isolate);
   3045     EXCEPTION_PREAMBLE(isolate);
   3046     num = i::Execution::ToInt32(isolate, obj, &has_pending_exception);
   3047     EXCEPTION_BAILOUT_CHECK(isolate, Local<Int32>());
   3048   }
   3049   return ToApiHandle<Int32>(num);
   3050 }
   3051 
   3052 
   3053 Local<Uint32> Value::ToUint32() const {
   3054   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3055   i::Handle<i::Object> num;
   3056   if (obj->IsSmi()) {
   3057     num = obj;
   3058   } else {
   3059     i::Isolate* isolate = i::Isolate::Current();
   3060     LOG_API(isolate, "ToUInt32");
   3061     ENTER_V8(isolate);
   3062     EXCEPTION_PREAMBLE(isolate);
   3063     num = i::Execution::ToUint32(isolate, obj, &has_pending_exception);
   3064     EXCEPTION_BAILOUT_CHECK(isolate, Local<Uint32>());
   3065   }
   3066   return ToApiHandle<Uint32>(num);
   3067 }
   3068 
   3069 
   3070 Local<Uint32> Value::ToArrayIndex() const {
   3071   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3072   if (obj->IsSmi()) {
   3073     if (i::Smi::cast(*obj)->value() >= 0) return Utils::Uint32ToLocal(obj);
   3074     return Local<Uint32>();
   3075   }
   3076   i::Isolate* isolate = i::Isolate::Current();
   3077   LOG_API(isolate, "ToArrayIndex");
   3078   ENTER_V8(isolate);
   3079   EXCEPTION_PREAMBLE(isolate);
   3080   i::Handle<i::Object> string_obj =
   3081       i::Execution::ToString(isolate, obj, &has_pending_exception);
   3082   EXCEPTION_BAILOUT_CHECK(isolate, Local<Uint32>());
   3083   i::Handle<i::String> str = i::Handle<i::String>::cast(string_obj);
   3084   uint32_t index;
   3085   if (str->AsArrayIndex(&index)) {
   3086     i::Handle<i::Object> value;
   3087     if (index <= static_cast<uint32_t>(i::Smi::kMaxValue)) {
   3088       value = i::Handle<i::Object>(i::Smi::FromInt(index), isolate);
   3089     } else {
   3090       value = isolate->factory()->NewNumber(index);
   3091     }
   3092     return Utils::Uint32ToLocal(value);
   3093   }
   3094   return Local<Uint32>();
   3095 }
   3096 
   3097 
   3098 int32_t Value::Int32Value() const {
   3099   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3100   if (obj->IsSmi()) {
   3101     return i::Smi::cast(*obj)->value();
   3102   } else {
   3103     i::Isolate* isolate = i::Isolate::Current();
   3104     LOG_API(isolate, "Int32Value (slow)");
   3105     ENTER_V8(isolate);
   3106     EXCEPTION_PREAMBLE(isolate);
   3107     i::Handle<i::Object> num =
   3108         i::Execution::ToInt32(isolate, obj, &has_pending_exception);
   3109     EXCEPTION_BAILOUT_CHECK(isolate, 0);
   3110     if (num->IsSmi()) {
   3111       return i::Smi::cast(*num)->value();
   3112     } else {
   3113       return static_cast<int32_t>(num->Number());
   3114     }
   3115   }
   3116 }
   3117 
   3118 
   3119 bool Value::Equals(Handle<Value> that) const {
   3120   i::Isolate* isolate = i::Isolate::Current();
   3121   if (EmptyCheck("v8::Value::Equals()", this) ||
   3122       EmptyCheck("v8::Value::Equals()", that)) {
   3123     return false;
   3124   }
   3125   LOG_API(isolate, "Equals");
   3126   ENTER_V8(isolate);
   3127   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3128   i::Handle<i::Object> other = Utils::OpenHandle(*that);
   3129   // If both obj and other are JSObjects, we'd better compare by identity
   3130   // immediately when going into JS builtin.  The reason is Invoke
   3131   // would overwrite global object receiver with global proxy.
   3132   if (obj->IsJSObject() && other->IsJSObject()) {
   3133     return *obj == *other;
   3134   }
   3135   i::Handle<i::Object> args[] = { other };
   3136   EXCEPTION_PREAMBLE(isolate);
   3137   i::Handle<i::Object> result =
   3138       CallV8HeapFunction("EQUALS", obj, ARRAY_SIZE(args), args,
   3139                          &has_pending_exception);
   3140   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3141   return *result == i::Smi::FromInt(i::EQUAL);
   3142 }
   3143 
   3144 
   3145 bool Value::StrictEquals(Handle<Value> that) const {
   3146   i::Isolate* isolate = i::Isolate::Current();
   3147   if (EmptyCheck("v8::Value::StrictEquals()", this) ||
   3148       EmptyCheck("v8::Value::StrictEquals()", that)) {
   3149     return false;
   3150   }
   3151   LOG_API(isolate, "StrictEquals");
   3152   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3153   i::Handle<i::Object> other = Utils::OpenHandle(*that);
   3154   // Must check HeapNumber first, since NaN !== NaN.
   3155   if (obj->IsHeapNumber()) {
   3156     if (!other->IsNumber()) return false;
   3157     double x = obj->Number();
   3158     double y = other->Number();
   3159     // Must check explicitly for NaN:s on Windows, but -0 works fine.
   3160     return x == y && !std::isnan(x) && !std::isnan(y);
   3161   } else if (*obj == *other) {  // Also covers Booleans.
   3162     return true;
   3163   } else if (obj->IsSmi()) {
   3164     return other->IsNumber() && obj->Number() == other->Number();
   3165   } else if (obj->IsString()) {
   3166     return other->IsString() &&
   3167       i::String::cast(*obj)->Equals(i::String::cast(*other));
   3168   } else if (obj->IsUndefined() || obj->IsUndetectableObject()) {
   3169     return other->IsUndefined() || other->IsUndetectableObject();
   3170   } else {
   3171     return false;
   3172   }
   3173 }
   3174 
   3175 
   3176 bool Value::SameValue(Handle<Value> that) const {
   3177   i::Isolate* isolate = i::Isolate::Current();
   3178   if (EmptyCheck("v8::Value::SameValue()", this) ||
   3179       EmptyCheck("v8::Value::SameValue()", that)) {
   3180     return false;
   3181   }
   3182   LOG_API(isolate, "SameValue");
   3183   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3184   i::Handle<i::Object> other = Utils::OpenHandle(*that);
   3185   return obj->SameValue(*other);
   3186 }
   3187 
   3188 
   3189 uint32_t Value::Uint32Value() const {
   3190   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   3191   if (obj->IsSmi()) {
   3192     return i::Smi::cast(*obj)->value();
   3193   } else {
   3194     i::Isolate* isolate = i::Isolate::Current();
   3195     LOG_API(isolate, "Uint32Value");
   3196     ENTER_V8(isolate);
   3197     EXCEPTION_PREAMBLE(isolate);
   3198     i::Handle<i::Object> num =
   3199         i::Execution::ToUint32(isolate, obj, &has_pending_exception);
   3200     EXCEPTION_BAILOUT_CHECK(isolate, 0);
   3201     if (num->IsSmi()) {
   3202       return i::Smi::cast(*num)->value();
   3203     } else {
   3204       return static_cast<uint32_t>(num->Number());
   3205     }
   3206   }
   3207 }
   3208 
   3209 
   3210 bool v8::Object::Set(v8::Handle<Value> key, v8::Handle<Value> value,
   3211                      v8::PropertyAttribute attribs) {
   3212   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3213   ON_BAILOUT(isolate, "v8::Object::Set()", return false);
   3214   ENTER_V8(isolate);
   3215   i::HandleScope scope(isolate);
   3216   i::Handle<i::Object> self = Utils::OpenHandle(this);
   3217   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3218   i::Handle<i::Object> value_obj = Utils::OpenHandle(*value);
   3219   EXCEPTION_PREAMBLE(isolate);
   3220   i::Handle<i::Object> obj = i::Runtime::SetObjectProperty(
   3221       isolate,
   3222       self,
   3223       key_obj,
   3224       value_obj,
   3225       static_cast<PropertyAttributes>(attribs),
   3226       i::kNonStrictMode);
   3227   has_pending_exception = obj.is_null();
   3228   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3229   return true;
   3230 }
   3231 
   3232 
   3233 bool v8::Object::Set(uint32_t index, v8::Handle<Value> value) {
   3234   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3235   ON_BAILOUT(isolate, "v8::Object::Set()", return false);
   3236   ENTER_V8(isolate);
   3237   i::HandleScope scope(isolate);
   3238   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3239   i::Handle<i::Object> value_obj = Utils::OpenHandle(*value);
   3240   EXCEPTION_PREAMBLE(isolate);
   3241   i::Handle<i::Object> obj = i::JSObject::SetElement(
   3242       self,
   3243       index,
   3244       value_obj,
   3245       NONE,
   3246       i::kNonStrictMode);
   3247   has_pending_exception = obj.is_null();
   3248   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3249   return true;
   3250 }
   3251 
   3252 
   3253 bool v8::Object::ForceSet(v8::Handle<Value> key,
   3254                           v8::Handle<Value> value,
   3255                           v8::PropertyAttribute attribs) {
   3256   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3257   ON_BAILOUT(isolate, "v8::Object::ForceSet()", return false);
   3258   ENTER_V8(isolate);
   3259   i::HandleScope scope(isolate);
   3260   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3261   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3262   i::Handle<i::Object> value_obj = Utils::OpenHandle(*value);
   3263   EXCEPTION_PREAMBLE(isolate);
   3264   i::Handle<i::Object> obj = i::ForceSetProperty(
   3265       self,
   3266       key_obj,
   3267       value_obj,
   3268       static_cast<PropertyAttributes>(attribs));
   3269   has_pending_exception = obj.is_null();
   3270   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3271   return true;
   3272 }
   3273 
   3274 
   3275 bool v8::Object::SetPrivate(v8::Handle<Private> key, v8::Handle<Value> value) {
   3276   return Set(v8::Handle<Value>(reinterpret_cast<Value*>(*key)),
   3277              value, DontEnum);
   3278 }
   3279 
   3280 
   3281 bool v8::Object::ForceDelete(v8::Handle<Value> key) {
   3282   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3283   ON_BAILOUT(isolate, "v8::Object::ForceDelete()", return false);
   3284   ENTER_V8(isolate);
   3285   i::HandleScope scope(isolate);
   3286   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3287   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3288 
   3289   // When deleting a property on the global object using ForceDelete
   3290   // deoptimize all functions as optimized code does not check for the hole
   3291   // value with DontDelete properties.  We have to deoptimize all contexts
   3292   // because of possible cross-context inlined functions.
   3293   if (self->IsJSGlobalProxy() || self->IsGlobalObject()) {
   3294     i::Deoptimizer::DeoptimizeAll(isolate);
   3295   }
   3296 
   3297   EXCEPTION_PREAMBLE(isolate);
   3298   i::Handle<i::Object> obj = i::ForceDeleteProperty(self, key_obj);
   3299   has_pending_exception = obj.is_null();
   3300   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3301   return obj->IsTrue();
   3302 }
   3303 
   3304 
   3305 Local<Value> v8::Object::Get(v8::Handle<Value> key) {
   3306   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3307   ON_BAILOUT(isolate, "v8::Object::Get()", return Local<v8::Value>());
   3308   ENTER_V8(isolate);
   3309   i::Handle<i::Object> self = Utils::OpenHandle(this);
   3310   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3311   EXCEPTION_PREAMBLE(isolate);
   3312   i::Handle<i::Object> result = i::GetProperty(isolate, self, key_obj);
   3313   has_pending_exception = result.is_null();
   3314   EXCEPTION_BAILOUT_CHECK(isolate, Local<Value>());
   3315   return Utils::ToLocal(result);
   3316 }
   3317 
   3318 
   3319 Local<Value> v8::Object::Get(uint32_t index) {
   3320   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3321   ON_BAILOUT(isolate, "v8::Object::Get()", return Local<v8::Value>());
   3322   ENTER_V8(isolate);
   3323   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3324   EXCEPTION_PREAMBLE(isolate);
   3325   i::Handle<i::Object> result = i::Object::GetElement(isolate, self, index);
   3326   has_pending_exception = result.is_null();
   3327   EXCEPTION_BAILOUT_CHECK(isolate, Local<Value>());
   3328   return Utils::ToLocal(result);
   3329 }
   3330 
   3331 
   3332 Local<Value> v8::Object::GetPrivate(v8::Handle<Private> key) {
   3333   return Get(v8::Handle<Value>(reinterpret_cast<Value*>(*key)));
   3334 }
   3335 
   3336 
   3337 PropertyAttribute v8::Object::GetPropertyAttributes(v8::Handle<Value> key) {
   3338   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3339   ON_BAILOUT(isolate, "v8::Object::GetPropertyAttribute()",
   3340              return static_cast<PropertyAttribute>(NONE));
   3341   ENTER_V8(isolate);
   3342   i::HandleScope scope(isolate);
   3343   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3344   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3345   if (!key_obj->IsName()) {
   3346     EXCEPTION_PREAMBLE(isolate);
   3347     key_obj = i::Execution::ToString(isolate, key_obj, &has_pending_exception);
   3348     EXCEPTION_BAILOUT_CHECK(isolate, static_cast<PropertyAttribute>(NONE));
   3349   }
   3350   i::Handle<i::Name> key_name = i::Handle<i::Name>::cast(key_obj);
   3351   PropertyAttributes result = self->GetPropertyAttribute(*key_name);
   3352   if (result == ABSENT) return static_cast<PropertyAttribute>(NONE);
   3353   return static_cast<PropertyAttribute>(result);
   3354 }
   3355 
   3356 
   3357 Local<Value> v8::Object::GetPrototype() {
   3358   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3359   ON_BAILOUT(isolate, "v8::Object::GetPrototype()",
   3360              return Local<v8::Value>());
   3361   ENTER_V8(isolate);
   3362   i::Handle<i::Object> self = Utils::OpenHandle(this);
   3363   i::Handle<i::Object> result(self->GetPrototype(isolate), isolate);
   3364   return Utils::ToLocal(result);
   3365 }
   3366 
   3367 
   3368 bool v8::Object::SetPrototype(Handle<Value> value) {
   3369   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3370   ON_BAILOUT(isolate, "v8::Object::SetPrototype()", return false);
   3371   ENTER_V8(isolate);
   3372   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3373   i::Handle<i::Object> value_obj = Utils::OpenHandle(*value);
   3374   // We do not allow exceptions thrown while setting the prototype
   3375   // to propagate outside.
   3376   TryCatch try_catch;
   3377   EXCEPTION_PREAMBLE(isolate);
   3378   i::Handle<i::Object> result = i::JSObject::SetPrototype(self, value_obj);
   3379   has_pending_exception = result.is_null();
   3380   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3381   return true;
   3382 }
   3383 
   3384 
   3385 Local<Object> v8::Object::FindInstanceInPrototypeChain(
   3386     v8::Handle<FunctionTemplate> tmpl) {
   3387   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3388   ON_BAILOUT(isolate,
   3389              "v8::Object::FindInstanceInPrototypeChain()",
   3390              return Local<v8::Object>());
   3391   ENTER_V8(isolate);
   3392   i::JSObject* object = *Utils::OpenHandle(this);
   3393   i::FunctionTemplateInfo* tmpl_info = *Utils::OpenHandle(*tmpl);
   3394   while (!tmpl_info->IsTemplateFor(object)) {
   3395     i::Object* prototype = object->GetPrototype();
   3396     if (!prototype->IsJSObject()) return Local<Object>();
   3397     object = i::JSObject::cast(prototype);
   3398   }
   3399   return Utils::ToLocal(i::Handle<i::JSObject>(object));
   3400 }
   3401 
   3402 
   3403 Local<Array> v8::Object::GetPropertyNames() {
   3404   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3405   ON_BAILOUT(isolate, "v8::Object::GetPropertyNames()",
   3406              return Local<v8::Array>());
   3407   ENTER_V8(isolate);
   3408   i::HandleScope scope(isolate);
   3409   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3410   bool threw = false;
   3411   i::Handle<i::FixedArray> value =
   3412       i::GetKeysInFixedArrayFor(self, i::INCLUDE_PROTOS, &threw);
   3413   if (threw) return Local<v8::Array>();
   3414   // Because we use caching to speed up enumeration it is important
   3415   // to never change the result of the basic enumeration function so
   3416   // we clone the result.
   3417   i::Handle<i::FixedArray> elms = isolate->factory()->CopyFixedArray(value);
   3418   i::Handle<i::JSArray> result =
   3419       isolate->factory()->NewJSArrayWithElements(elms);
   3420   return Utils::ToLocal(scope.CloseAndEscape(result));
   3421 }
   3422 
   3423 
   3424 Local<Array> v8::Object::GetOwnPropertyNames() {
   3425   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3426   ON_BAILOUT(isolate, "v8::Object::GetOwnPropertyNames()",
   3427              return Local<v8::Array>());
   3428   ENTER_V8(isolate);
   3429   i::HandleScope scope(isolate);
   3430   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3431   bool threw = false;
   3432   i::Handle<i::FixedArray> value =
   3433       i::GetKeysInFixedArrayFor(self, i::LOCAL_ONLY, &threw);
   3434   if (threw) return Local<v8::Array>();
   3435   // Because we use caching to speed up enumeration it is important
   3436   // to never change the result of the basic enumeration function so
   3437   // we clone the result.
   3438   i::Handle<i::FixedArray> elms = isolate->factory()->CopyFixedArray(value);
   3439   i::Handle<i::JSArray> result =
   3440       isolate->factory()->NewJSArrayWithElements(elms);
   3441   return Utils::ToLocal(scope.CloseAndEscape(result));
   3442 }
   3443 
   3444 
   3445 Local<String> v8::Object::ObjectProtoToString() {
   3446   i::Isolate* i_isolate = Utils::OpenHandle(this)->GetIsolate();
   3447   Isolate* isolate = reinterpret_cast<Isolate*>(i_isolate);
   3448   ON_BAILOUT(i_isolate, "v8::Object::ObjectProtoToString()",
   3449              return Local<v8::String>());
   3450   ENTER_V8(i_isolate);
   3451   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3452 
   3453   i::Handle<i::Object> name(self->class_name(), i_isolate);
   3454 
   3455   // Native implementation of Object.prototype.toString (v8natives.js):
   3456   //   var c = %_ClassOf(this);
   3457   //   if (c === 'Arguments') c  = 'Object';
   3458   //   return "[object " + c + "]";
   3459 
   3460   if (!name->IsString()) {
   3461     return v8::String::NewFromUtf8(isolate, "[object ]");
   3462   } else {
   3463     i::Handle<i::String> class_name = i::Handle<i::String>::cast(name);
   3464     if (class_name->IsOneByteEqualTo(STATIC_ASCII_VECTOR("Arguments"))) {
   3465       return v8::String::NewFromUtf8(isolate, "[object Object]");
   3466     } else {
   3467       const char* prefix = "[object ";
   3468       Local<String> str = Utils::ToLocal(class_name);
   3469       const char* postfix = "]";
   3470 
   3471       int prefix_len = i::StrLength(prefix);
   3472       int str_len = str->Utf8Length();
   3473       int postfix_len = i::StrLength(postfix);
   3474 
   3475       int buf_len = prefix_len + str_len + postfix_len;
   3476       i::ScopedVector<char> buf(buf_len);
   3477 
   3478       // Write prefix.
   3479       char* ptr = buf.start();
   3480       i::OS::MemCopy(ptr, prefix, prefix_len * v8::internal::kCharSize);
   3481       ptr += prefix_len;
   3482 
   3483       // Write real content.
   3484       str->WriteUtf8(ptr, str_len);
   3485       ptr += str_len;
   3486 
   3487       // Write postfix.
   3488       i::OS::MemCopy(ptr, postfix, postfix_len * v8::internal::kCharSize);
   3489 
   3490       // Copy the buffer into a heap-allocated string and return it.
   3491       Local<String> result = v8::String::NewFromUtf8(
   3492           isolate, buf.start(), String::kNormalString, buf_len);
   3493       return result;
   3494     }
   3495   }
   3496 }
   3497 
   3498 
   3499 Local<Value> v8::Object::GetConstructor() {
   3500   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3501   ON_BAILOUT(isolate, "v8::Object::GetConstructor()",
   3502              return Local<v8::Function>());
   3503   ENTER_V8(isolate);
   3504   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3505   i::Handle<i::Object> constructor(self->GetConstructor(), isolate);
   3506   return Utils::ToLocal(constructor);
   3507 }
   3508 
   3509 
   3510 Local<String> v8::Object::GetConstructorName() {
   3511   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3512   ON_BAILOUT(isolate, "v8::Object::GetConstructorName()",
   3513              return Local<v8::String>());
   3514   ENTER_V8(isolate);
   3515   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3516   i::Handle<i::String> name(self->constructor_name());
   3517   return Utils::ToLocal(name);
   3518 }
   3519 
   3520 
   3521 bool v8::Object::Delete(v8::Handle<Value> key) {
   3522   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3523   ON_BAILOUT(isolate, "v8::Object::Delete()", return false);
   3524   ENTER_V8(isolate);
   3525   i::HandleScope scope(isolate);
   3526   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3527   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3528   EXCEPTION_PREAMBLE(isolate);
   3529   i::Handle<i::Object> obj = i::DeleteProperty(self, key_obj);
   3530   has_pending_exception = obj.is_null();
   3531   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3532   return obj->IsTrue();
   3533 }
   3534 
   3535 
   3536 bool v8::Object::DeletePrivate(v8::Handle<Private> key) {
   3537   return Delete(v8::Handle<Value>(reinterpret_cast<Value*>(*key)));
   3538 }
   3539 
   3540 
   3541 bool v8::Object::Has(v8::Handle<Value> key) {
   3542   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3543   ON_BAILOUT(isolate, "v8::Object::Has()", return false);
   3544   ENTER_V8(isolate);
   3545   i::Handle<i::JSReceiver> self = Utils::OpenHandle(this);
   3546   i::Handle<i::Object> key_obj = Utils::OpenHandle(*key);
   3547   EXCEPTION_PREAMBLE(isolate);
   3548   i::Handle<i::Object> obj = i::HasProperty(self, key_obj);
   3549   has_pending_exception = obj.is_null();
   3550   EXCEPTION_BAILOUT_CHECK(isolate, false);
   3551   return obj->IsTrue();
   3552 }
   3553 
   3554 
   3555 bool v8::Object::HasPrivate(v8::Handle<Private> key) {
   3556   return Has(v8::Handle<Value>(reinterpret_cast<Value*>(*key)));
   3557 }
   3558 
   3559 
   3560 bool v8::Object::Delete(uint32_t index) {
   3561   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3562   ON_BAILOUT(isolate, "v8::Object::DeleteProperty()",
   3563              return false);
   3564   ENTER_V8(isolate);
   3565   HandleScope scope(reinterpret_cast<Isolate*>(isolate));
   3566   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3567   return i::JSReceiver::DeleteElement(self, index)->IsTrue();
   3568 }
   3569 
   3570 
   3571 bool v8::Object::Has(uint32_t index) {
   3572   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3573   ON_BAILOUT(isolate, "v8::Object::HasProperty()", return false);
   3574   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3575   return i::JSReceiver::HasElement(self, index);
   3576 }
   3577 
   3578 
   3579 template<typename Setter, typename Getter, typename Data>
   3580 static inline bool ObjectSetAccessor(Object* obj,
   3581                                      Handle<String> name,
   3582                                      Setter getter,
   3583                                      Getter setter,
   3584                                      Data data,
   3585                                      AccessControl settings,
   3586                                      PropertyAttribute attributes) {
   3587   i::Isolate* isolate = Utils::OpenHandle(obj)->GetIsolate();
   3588   ON_BAILOUT(isolate, "v8::Object::SetAccessor()", return false);
   3589   ENTER_V8(isolate);
   3590   i::HandleScope scope(isolate);
   3591   v8::Handle<AccessorSignature> signature;
   3592   i::Handle<i::AccessorInfo> info = MakeAccessorInfo(
   3593       name, getter, setter, data, settings, attributes, signature);
   3594   if (info.is_null()) return false;
   3595   bool fast = Utils::OpenHandle(obj)->HasFastProperties();
   3596   i::Handle<i::Object> result =
   3597       i::JSObject::SetAccessor(Utils::OpenHandle(obj), info);
   3598   if (result.is_null() || result->IsUndefined()) return false;
   3599   if (fast) i::JSObject::TransformToFastProperties(Utils::OpenHandle(obj), 0);
   3600   return true;
   3601 }
   3602 
   3603 
   3604 bool Object::SetAccessor(Handle<String> name,
   3605                          AccessorGetterCallback getter,
   3606                          AccessorSetterCallback setter,
   3607                          v8::Handle<Value> data,
   3608                          AccessControl settings,
   3609                          PropertyAttribute attributes) {
   3610   return ObjectSetAccessor(
   3611       this, name, getter, setter, data, settings, attributes);
   3612 }
   3613 
   3614 
   3615 bool Object::SetDeclaredAccessor(Local<String> name,
   3616                                  Local<DeclaredAccessorDescriptor> descriptor,
   3617                                  PropertyAttribute attributes,
   3618                                  AccessControl settings) {
   3619   void* null = NULL;
   3620   return ObjectSetAccessor(
   3621       this, name, descriptor, null, null, settings, attributes);
   3622 }
   3623 
   3624 
   3625 bool v8::Object::HasOwnProperty(Handle<String> key) {
   3626   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3627   ON_BAILOUT(isolate, "v8::Object::HasOwnProperty()",
   3628              return false);
   3629   return i::JSReceiver::HasLocalProperty(
   3630       Utils::OpenHandle(this), Utils::OpenHandle(*key));
   3631 }
   3632 
   3633 
   3634 bool v8::Object::HasRealNamedProperty(Handle<String> key) {
   3635   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3636   ON_BAILOUT(isolate, "v8::Object::HasRealNamedProperty()",
   3637              return false);
   3638   return i::JSObject::HasRealNamedProperty(Utils::OpenHandle(this),
   3639                                            Utils::OpenHandle(*key));
   3640 }
   3641 
   3642 
   3643 bool v8::Object::HasRealIndexedProperty(uint32_t index) {
   3644   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3645   ON_BAILOUT(isolate, "v8::Object::HasRealIndexedProperty()",
   3646              return false);
   3647   return i::JSObject::HasRealElementProperty(Utils::OpenHandle(this), index);
   3648 }
   3649 
   3650 
   3651 bool v8::Object::HasRealNamedCallbackProperty(Handle<String> key) {
   3652   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3653   ON_BAILOUT(isolate,
   3654              "v8::Object::HasRealNamedCallbackProperty()",
   3655              return false);
   3656   ENTER_V8(isolate);
   3657   return i::JSObject::HasRealNamedCallbackProperty(Utils::OpenHandle(this),
   3658                                                    Utils::OpenHandle(*key));
   3659 }
   3660 
   3661 
   3662 bool v8::Object::HasNamedLookupInterceptor() {
   3663   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3664   ON_BAILOUT(isolate, "v8::Object::HasNamedLookupInterceptor()",
   3665              return false);
   3666   return Utils::OpenHandle(this)->HasNamedInterceptor();
   3667 }
   3668 
   3669 
   3670 bool v8::Object::HasIndexedLookupInterceptor() {
   3671   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3672   ON_BAILOUT(isolate, "v8::Object::HasIndexedLookupInterceptor()",
   3673              return false);
   3674   return Utils::OpenHandle(this)->HasIndexedInterceptor();
   3675 }
   3676 
   3677 
   3678 static Local<Value> GetPropertyByLookup(i::Isolate* isolate,
   3679                                         i::Handle<i::JSObject> receiver,
   3680                                         i::Handle<i::String> name,
   3681                                         i::LookupResult* lookup) {
   3682   if (!lookup->IsProperty()) {
   3683     // No real property was found.
   3684     return Local<Value>();
   3685   }
   3686 
   3687   // If the property being looked up is a callback, it can throw
   3688   // an exception.
   3689   EXCEPTION_PREAMBLE(isolate);
   3690   PropertyAttributes ignored;
   3691   i::Handle<i::Object> result =
   3692       i::Object::GetProperty(receiver, receiver, lookup, name,
   3693                              &ignored);
   3694   has_pending_exception = result.is_null();
   3695   EXCEPTION_BAILOUT_CHECK(isolate, Local<Value>());
   3696 
   3697   return Utils::ToLocal(result);
   3698 }
   3699 
   3700 
   3701 Local<Value> v8::Object::GetRealNamedPropertyInPrototypeChain(
   3702       Handle<String> key) {
   3703   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3704   ON_BAILOUT(isolate,
   3705              "v8::Object::GetRealNamedPropertyInPrototypeChain()",
   3706              return Local<Value>());
   3707   ENTER_V8(isolate);
   3708   i::Handle<i::JSObject> self_obj = Utils::OpenHandle(this);
   3709   i::Handle<i::String> key_obj = Utils::OpenHandle(*key);
   3710   i::LookupResult lookup(isolate);
   3711   self_obj->LookupRealNamedPropertyInPrototypes(*key_obj, &lookup);
   3712   return GetPropertyByLookup(isolate, self_obj, key_obj, &lookup);
   3713 }
   3714 
   3715 
   3716 Local<Value> v8::Object::GetRealNamedProperty(Handle<String> key) {
   3717   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3718   ON_BAILOUT(isolate, "v8::Object::GetRealNamedProperty()",
   3719              return Local<Value>());
   3720   ENTER_V8(isolate);
   3721   i::Handle<i::JSObject> self_obj = Utils::OpenHandle(this);
   3722   i::Handle<i::String> key_obj = Utils::OpenHandle(*key);
   3723   i::LookupResult lookup(isolate);
   3724   self_obj->LookupRealNamedProperty(*key_obj, &lookup);
   3725   return GetPropertyByLookup(isolate, self_obj, key_obj, &lookup);
   3726 }
   3727 
   3728 
   3729 // Turns on access checks by copying the map and setting the check flag.
   3730 // Because the object gets a new map, existing inline cache caching
   3731 // the old map of this object will fail.
   3732 void v8::Object::TurnOnAccessCheck() {
   3733   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3734   ON_BAILOUT(isolate, "v8::Object::TurnOnAccessCheck()", return);
   3735   ENTER_V8(isolate);
   3736   i::HandleScope scope(isolate);
   3737   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   3738 
   3739   // When turning on access checks for a global object deoptimize all functions
   3740   // as optimized code does not always handle access checks.
   3741   i::Deoptimizer::DeoptimizeGlobalObject(*obj);
   3742 
   3743   i::Handle<i::Map> new_map =
   3744       isolate->factory()->CopyMap(i::Handle<i::Map>(obj->map()));
   3745   new_map->set_is_access_check_needed(true);
   3746   obj->set_map(*new_map);
   3747 }
   3748 
   3749 
   3750 bool v8::Object::IsDirty() {
   3751   return Utils::OpenHandle(this)->IsDirty();
   3752 }
   3753 
   3754 
   3755 Local<v8::Object> v8::Object::Clone() {
   3756   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3757   ON_BAILOUT(isolate, "v8::Object::Clone()", return Local<Object>());
   3758   ENTER_V8(isolate);
   3759   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3760   EXCEPTION_PREAMBLE(isolate);
   3761   i::Handle<i::JSObject> result = i::JSObject::Copy(self);
   3762   has_pending_exception = result.is_null();
   3763   EXCEPTION_BAILOUT_CHECK(isolate, Local<Object>());
   3764   return Utils::ToLocal(result);
   3765 }
   3766 
   3767 
   3768 static i::Context* GetCreationContext(i::JSObject* object) {
   3769   i::Object* constructor = object->map()->constructor();
   3770   i::JSFunction* function;
   3771   if (!constructor->IsJSFunction()) {
   3772     // Functions have null as a constructor,
   3773     // but any JSFunction knows its context immediately.
   3774     ASSERT(object->IsJSFunction());
   3775     function = i::JSFunction::cast(object);
   3776   } else {
   3777     function = i::JSFunction::cast(constructor);
   3778   }
   3779   return function->context()->native_context();
   3780 }
   3781 
   3782 
   3783 Local<v8::Context> v8::Object::CreationContext() {
   3784   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3785   ON_BAILOUT(isolate,
   3786              "v8::Object::CreationContext()", return Local<v8::Context>());
   3787   ENTER_V8(isolate);
   3788   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3789   i::Context* context = GetCreationContext(*self);
   3790   return Utils::ToLocal(i::Handle<i::Context>(context));
   3791 }
   3792 
   3793 
   3794 int v8::Object::GetIdentityHash() {
   3795   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3796   ON_BAILOUT(isolate, "v8::Object::GetIdentityHash()", return 0);
   3797   ENTER_V8(isolate);
   3798   i::HandleScope scope(isolate);
   3799   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3800   return i::Handle<i::Smi>::cast(
   3801       i::JSReceiver::GetOrCreateIdentityHash(self))->value();
   3802 }
   3803 
   3804 
   3805 bool v8::Object::SetHiddenValue(v8::Handle<v8::String> key,
   3806                                 v8::Handle<v8::Value> value) {
   3807   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3808   ON_BAILOUT(isolate, "v8::Object::SetHiddenValue()", return false);
   3809   if (value.IsEmpty()) return DeleteHiddenValue(key);
   3810   ENTER_V8(isolate);
   3811   i::HandleScope scope(isolate);
   3812   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3813   i::Handle<i::String> key_obj = Utils::OpenHandle(*key);
   3814   i::Handle<i::String> key_string =
   3815       isolate->factory()->InternalizeString(key_obj);
   3816   i::Handle<i::Object> value_obj = Utils::OpenHandle(*value);
   3817   i::Handle<i::Object> result =
   3818       i::JSObject::SetHiddenProperty(self, key_string, value_obj);
   3819   return *result == *self;
   3820 }
   3821 
   3822 
   3823 v8::Local<v8::Value> v8::Object::GetHiddenValue(v8::Handle<v8::String> key) {
   3824   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3825   ON_BAILOUT(isolate, "v8::Object::GetHiddenValue()",
   3826              return Local<v8::Value>());
   3827   ENTER_V8(isolate);
   3828   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3829   i::Handle<i::String> key_obj = Utils::OpenHandle(*key);
   3830   i::Handle<i::String> key_string =
   3831       isolate->factory()->InternalizeString(key_obj);
   3832   i::Handle<i::Object> result(self->GetHiddenProperty(*key_string), isolate);
   3833   if (result->IsTheHole()) return v8::Local<v8::Value>();
   3834   return Utils::ToLocal(result);
   3835 }
   3836 
   3837 
   3838 bool v8::Object::DeleteHiddenValue(v8::Handle<v8::String> key) {
   3839   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3840   ON_BAILOUT(isolate, "v8::DeleteHiddenValue()", return false);
   3841   ENTER_V8(isolate);
   3842   i::HandleScope scope(isolate);
   3843   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3844   i::Handle<i::String> key_obj = Utils::OpenHandle(*key);
   3845   i::Handle<i::String> key_string =
   3846       isolate->factory()->InternalizeString(key_obj);
   3847   i::JSObject::DeleteHiddenProperty(self, key_string);
   3848   return true;
   3849 }
   3850 
   3851 
   3852 namespace {
   3853 
   3854 static i::ElementsKind GetElementsKindFromExternalArrayType(
   3855     ExternalArrayType array_type) {
   3856   switch (array_type) {
   3857     case kExternalByteArray:
   3858       return i::EXTERNAL_BYTE_ELEMENTS;
   3859       break;
   3860     case kExternalUnsignedByteArray:
   3861       return i::EXTERNAL_UNSIGNED_BYTE_ELEMENTS;
   3862       break;
   3863     case kExternalShortArray:
   3864       return i::EXTERNAL_SHORT_ELEMENTS;
   3865       break;
   3866     case kExternalUnsignedShortArray:
   3867       return i::EXTERNAL_UNSIGNED_SHORT_ELEMENTS;
   3868       break;
   3869     case kExternalIntArray:
   3870       return i::EXTERNAL_INT_ELEMENTS;
   3871       break;
   3872     case kExternalUnsignedIntArray:
   3873       return i::EXTERNAL_UNSIGNED_INT_ELEMENTS;
   3874       break;
   3875     case kExternalFloatArray:
   3876       return i::EXTERNAL_FLOAT_ELEMENTS;
   3877       break;
   3878     case kExternalDoubleArray:
   3879       return i::EXTERNAL_DOUBLE_ELEMENTS;
   3880       break;
   3881     case kExternalPixelArray:
   3882       return i::EXTERNAL_PIXEL_ELEMENTS;
   3883       break;
   3884   }
   3885   UNREACHABLE();
   3886   return i::DICTIONARY_ELEMENTS;
   3887 }
   3888 
   3889 
   3890 void PrepareExternalArrayElements(i::Handle<i::JSObject> object,
   3891                                   void* data,
   3892                                   ExternalArrayType array_type,
   3893                                   int length) {
   3894   i::Isolate* isolate = object->GetIsolate();
   3895   i::Handle<i::ExternalArray> array =
   3896       isolate->factory()->NewExternalArray(length, array_type, data);
   3897 
   3898   i::Handle<i::Map> external_array_map =
   3899       isolate->factory()->GetElementsTransitionMap(
   3900           object,
   3901           GetElementsKindFromExternalArrayType(array_type));
   3902 
   3903   object->set_map(*external_array_map);
   3904   object->set_elements(*array);
   3905 }
   3906 
   3907 }  // namespace
   3908 
   3909 
   3910 void v8::Object::SetIndexedPropertiesToPixelData(uint8_t* data, int length) {
   3911   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3912   ON_BAILOUT(isolate, "v8::SetElementsToPixelData()", return);
   3913   ENTER_V8(isolate);
   3914   i::HandleScope scope(isolate);
   3915   if (!ApiCheck(length >= 0 && length <= i::ExternalPixelArray::kMaxLength,
   3916                 "v8::Object::SetIndexedPropertiesToPixelData()",
   3917                 "length exceeds max acceptable value")) {
   3918     return;
   3919   }
   3920   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3921   if (!ApiCheck(!self->IsJSArray(),
   3922                 "v8::Object::SetIndexedPropertiesToPixelData()",
   3923                 "JSArray is not supported")) {
   3924     return;
   3925   }
   3926   PrepareExternalArrayElements(self, data, kExternalPixelArray, length);
   3927 }
   3928 
   3929 
   3930 bool v8::Object::HasIndexedPropertiesInPixelData() {
   3931   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3932   ON_BAILOUT(self->GetIsolate(), "v8::HasIndexedPropertiesInPixelData()",
   3933              return false);
   3934   return self->HasExternalPixelElements();
   3935 }
   3936 
   3937 
   3938 uint8_t* v8::Object::GetIndexedPropertiesPixelData() {
   3939   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3940   ON_BAILOUT(self->GetIsolate(), "v8::GetIndexedPropertiesPixelData()",
   3941              return NULL);
   3942   if (self->HasExternalPixelElements()) {
   3943     return i::ExternalPixelArray::cast(self->elements())->
   3944         external_pixel_pointer();
   3945   } else {
   3946     return NULL;
   3947   }
   3948 }
   3949 
   3950 
   3951 int v8::Object::GetIndexedPropertiesPixelDataLength() {
   3952   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3953   ON_BAILOUT(self->GetIsolate(), "v8::GetIndexedPropertiesPixelDataLength()",
   3954              return -1);
   3955   if (self->HasExternalPixelElements()) {
   3956     return i::ExternalPixelArray::cast(self->elements())->length();
   3957   } else {
   3958     return -1;
   3959   }
   3960 }
   3961 
   3962 
   3963 void v8::Object::SetIndexedPropertiesToExternalArrayData(
   3964     void* data,
   3965     ExternalArrayType array_type,
   3966     int length) {
   3967   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   3968   ON_BAILOUT(isolate, "v8::SetIndexedPropertiesToExternalArrayData()", return);
   3969   ENTER_V8(isolate);
   3970   i::HandleScope scope(isolate);
   3971   if (!ApiCheck(length >= 0 && length <= i::ExternalArray::kMaxLength,
   3972                 "v8::Object::SetIndexedPropertiesToExternalArrayData()",
   3973                 "length exceeds max acceptable value")) {
   3974     return;
   3975   }
   3976   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3977   if (!ApiCheck(!self->IsJSArray(),
   3978                 "v8::Object::SetIndexedPropertiesToExternalArrayData()",
   3979                 "JSArray is not supported")) {
   3980     return;
   3981   }
   3982   PrepareExternalArrayElements(self, data, array_type, length);
   3983 }
   3984 
   3985 
   3986 bool v8::Object::HasIndexedPropertiesInExternalArrayData() {
   3987   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3988   ON_BAILOUT(self->GetIsolate(),
   3989              "v8::HasIndexedPropertiesInExternalArrayData()",
   3990              return false);
   3991   return self->HasExternalArrayElements();
   3992 }
   3993 
   3994 
   3995 void* v8::Object::GetIndexedPropertiesExternalArrayData() {
   3996   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   3997   ON_BAILOUT(self->GetIsolate(),
   3998              "v8::GetIndexedPropertiesExternalArrayData()",
   3999              return NULL);
   4000   if (self->HasExternalArrayElements()) {
   4001     return i::ExternalArray::cast(self->elements())->external_pointer();
   4002   } else {
   4003     return NULL;
   4004   }
   4005 }
   4006 
   4007 
   4008 ExternalArrayType v8::Object::GetIndexedPropertiesExternalArrayDataType() {
   4009   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   4010   ON_BAILOUT(self->GetIsolate(),
   4011              "v8::GetIndexedPropertiesExternalArrayDataType()",
   4012              return static_cast<ExternalArrayType>(-1));
   4013   switch (self->elements()->map()->instance_type()) {
   4014     case i::EXTERNAL_BYTE_ARRAY_TYPE:
   4015       return kExternalByteArray;
   4016     case i::EXTERNAL_UNSIGNED_BYTE_ARRAY_TYPE:
   4017       return kExternalUnsignedByteArray;
   4018     case i::EXTERNAL_SHORT_ARRAY_TYPE:
   4019       return kExternalShortArray;
   4020     case i::EXTERNAL_UNSIGNED_SHORT_ARRAY_TYPE:
   4021       return kExternalUnsignedShortArray;
   4022     case i::EXTERNAL_INT_ARRAY_TYPE:
   4023       return kExternalIntArray;
   4024     case i::EXTERNAL_UNSIGNED_INT_ARRAY_TYPE:
   4025       return kExternalUnsignedIntArray;
   4026     case i::EXTERNAL_FLOAT_ARRAY_TYPE:
   4027       return kExternalFloatArray;
   4028     case i::EXTERNAL_DOUBLE_ARRAY_TYPE:
   4029       return kExternalDoubleArray;
   4030     case i::EXTERNAL_PIXEL_ARRAY_TYPE:
   4031       return kExternalPixelArray;
   4032     default:
   4033       return static_cast<ExternalArrayType>(-1);
   4034   }
   4035 }
   4036 
   4037 
   4038 int v8::Object::GetIndexedPropertiesExternalArrayDataLength() {
   4039   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   4040   ON_BAILOUT(self->GetIsolate(),
   4041              "v8::GetIndexedPropertiesExternalArrayDataLength()",
   4042              return 0);
   4043   if (self->HasExternalArrayElements()) {
   4044     return i::ExternalArray::cast(self->elements())->length();
   4045   } else {
   4046     return -1;
   4047   }
   4048 }
   4049 
   4050 
   4051 bool v8::Object::IsCallable() {
   4052   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4053   ON_BAILOUT(isolate, "v8::Object::IsCallable()", return false);
   4054   ENTER_V8(isolate);
   4055   i::HandleScope scope(isolate);
   4056   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   4057   return obj->IsCallable();
   4058 }
   4059 
   4060 
   4061 Local<v8::Value> Object::CallAsFunction(v8::Handle<v8::Value> recv,
   4062                                         int argc,
   4063                                         v8::Handle<v8::Value> argv[]) {
   4064   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4065   ON_BAILOUT(isolate, "v8::Object::CallAsFunction()",
   4066              return Local<v8::Value>());
   4067   LOG_API(isolate, "Object::CallAsFunction");
   4068   ENTER_V8(isolate);
   4069   i::Logger::TimerEventScope timer_scope(
   4070       isolate, i::Logger::TimerEventScope::v8_execute);
   4071   i::HandleScope scope(isolate);
   4072   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   4073   i::Handle<i::Object> recv_obj = Utils::OpenHandle(*recv);
   4074   STATIC_ASSERT(sizeof(v8::Handle<v8::Value>) == sizeof(i::Object**));
   4075   i::Handle<i::Object>* args = reinterpret_cast<i::Handle<i::Object>*>(argv);
   4076   i::Handle<i::JSFunction> fun = i::Handle<i::JSFunction>();
   4077   if (obj->IsJSFunction()) {
   4078     fun = i::Handle<i::JSFunction>::cast(obj);
   4079   } else {
   4080     EXCEPTION_PREAMBLE(isolate);
   4081     i::Handle<i::Object> delegate = i::Execution::TryGetFunctionDelegate(
   4082         isolate, obj, &has_pending_exception);
   4083     EXCEPTION_BAILOUT_CHECK(isolate, Local<Value>());
   4084     fun = i::Handle<i::JSFunction>::cast(delegate);
   4085     recv_obj = obj;
   4086   }
   4087   EXCEPTION_PREAMBLE(isolate);
   4088   i::Handle<i::Object> returned = i::Execution::Call(
   4089       isolate, fun, recv_obj, argc, args, &has_pending_exception, true);
   4090   EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, Local<Value>());
   4091   return Utils::ToLocal(scope.CloseAndEscape(returned));
   4092 }
   4093 
   4094 
   4095 Local<v8::Value> Object::CallAsConstructor(int argc,
   4096                                            v8::Handle<v8::Value> argv[]) {
   4097   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4098   ON_BAILOUT(isolate, "v8::Object::CallAsConstructor()",
   4099              return Local<v8::Object>());
   4100   LOG_API(isolate, "Object::CallAsConstructor");
   4101   ENTER_V8(isolate);
   4102   i::Logger::TimerEventScope timer_scope(
   4103       isolate, i::Logger::TimerEventScope::v8_execute);
   4104   i::HandleScope scope(isolate);
   4105   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   4106   STATIC_ASSERT(sizeof(v8::Handle<v8::Value>) == sizeof(i::Object**));
   4107   i::Handle<i::Object>* args = reinterpret_cast<i::Handle<i::Object>*>(argv);
   4108   if (obj->IsJSFunction()) {
   4109     i::Handle<i::JSFunction> fun = i::Handle<i::JSFunction>::cast(obj);
   4110     EXCEPTION_PREAMBLE(isolate);
   4111     i::Handle<i::Object> returned =
   4112         i::Execution::New(fun, argc, args, &has_pending_exception);
   4113     EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, Local<v8::Object>());
   4114     return Utils::ToLocal(scope.CloseAndEscape(
   4115         i::Handle<i::JSObject>::cast(returned)));
   4116   }
   4117   EXCEPTION_PREAMBLE(isolate);
   4118   i::Handle<i::Object> delegate = i::Execution::TryGetConstructorDelegate(
   4119       isolate, obj, &has_pending_exception);
   4120   EXCEPTION_BAILOUT_CHECK(isolate, Local<v8::Object>());
   4121   if (!delegate->IsUndefined()) {
   4122     i::Handle<i::JSFunction> fun = i::Handle<i::JSFunction>::cast(delegate);
   4123     EXCEPTION_PREAMBLE(isolate);
   4124     i::Handle<i::Object> returned = i::Execution::Call(
   4125         isolate, fun, obj, argc, args, &has_pending_exception);
   4126     EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, Local<v8::Object>());
   4127     ASSERT(!delegate->IsUndefined());
   4128     return Utils::ToLocal(scope.CloseAndEscape(returned));
   4129   }
   4130   return Local<v8::Object>();
   4131 }
   4132 
   4133 
   4134 Local<Function> Function::New(Isolate* v8_isolate,
   4135                               FunctionCallback callback,
   4136                               Local<Value> data,
   4137                               int length) {
   4138   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(v8_isolate);
   4139   LOG_API(isolate, "Function::New");
   4140   ENTER_V8(isolate);
   4141   return FunctionTemplateNew(
   4142       isolate, callback, data, Local<Signature>(), length, true)->
   4143           GetFunction();
   4144 }
   4145 
   4146 
   4147 Local<v8::Object> Function::NewInstance() const {
   4148   return NewInstance(0, NULL);
   4149 }
   4150 
   4151 
   4152 Local<v8::Object> Function::NewInstance(int argc,
   4153                                         v8::Handle<v8::Value> argv[]) const {
   4154   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4155   ON_BAILOUT(isolate, "v8::Function::NewInstance()",
   4156              return Local<v8::Object>());
   4157   LOG_API(isolate, "Function::NewInstance");
   4158   ENTER_V8(isolate);
   4159   i::Logger::TimerEventScope timer_scope(
   4160       isolate, i::Logger::TimerEventScope::v8_execute);
   4161   EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   4162   i::Handle<i::JSFunction> function = Utils::OpenHandle(this);
   4163   STATIC_ASSERT(sizeof(v8::Handle<v8::Value>) == sizeof(i::Object**));
   4164   i::Handle<i::Object>* args = reinterpret_cast<i::Handle<i::Object>*>(argv);
   4165   EXCEPTION_PREAMBLE(isolate);
   4166   i::Handle<i::Object> returned =
   4167       i::Execution::New(function, argc, args, &has_pending_exception);
   4168   EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, Local<v8::Object>());
   4169   return scope.Escape(Utils::ToLocal(i::Handle<i::JSObject>::cast(returned)));
   4170 }
   4171 
   4172 
   4173 Local<v8::Value> Function::Call(v8::Handle<v8::Value> recv, int argc,
   4174                                 v8::Handle<v8::Value> argv[]) {
   4175   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4176   ON_BAILOUT(isolate, "v8::Function::Call()", return Local<v8::Value>());
   4177   LOG_API(isolate, "Function::Call");
   4178   ENTER_V8(isolate);
   4179   i::Logger::TimerEventScope timer_scope(
   4180       isolate, i::Logger::TimerEventScope::v8_execute);
   4181   i::Object* raw_result = NULL;
   4182   {
   4183     i::HandleScope scope(isolate);
   4184     i::Handle<i::JSFunction> fun = Utils::OpenHandle(this);
   4185     i::Handle<i::Object> recv_obj = Utils::OpenHandle(*recv);
   4186     STATIC_ASSERT(sizeof(v8::Handle<v8::Value>) == sizeof(i::Object**));
   4187     i::Handle<i::Object>* args = reinterpret_cast<i::Handle<i::Object>*>(argv);
   4188     EXCEPTION_PREAMBLE(isolate);
   4189     i::Handle<i::Object> returned = i::Execution::Call(
   4190         isolate, fun, recv_obj, argc, args, &has_pending_exception, true);
   4191     EXCEPTION_BAILOUT_CHECK_DO_CALLBACK(isolate, Local<Object>());
   4192     raw_result = *returned;
   4193   }
   4194   i::Handle<i::Object> result(raw_result, isolate);
   4195   return Utils::ToLocal(result);
   4196 }
   4197 
   4198 
   4199 void Function::SetName(v8::Handle<v8::String> name) {
   4200   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4201   ENTER_V8(isolate);
   4202   USE(isolate);
   4203   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4204   func->shared()->set_name(*Utils::OpenHandle(*name));
   4205 }
   4206 
   4207 
   4208 Handle<Value> Function::GetName() const {
   4209   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4210   return Utils::ToLocal(i::Handle<i::Object>(func->shared()->name(),
   4211                                              func->GetIsolate()));
   4212 }
   4213 
   4214 
   4215 Handle<Value> Function::GetInferredName() const {
   4216   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4217   return Utils::ToLocal(i::Handle<i::Object>(func->shared()->inferred_name(),
   4218                                              func->GetIsolate()));
   4219 }
   4220 
   4221 
   4222 Handle<Value> Function::GetDisplayName() const {
   4223   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4224   ON_BAILOUT(isolate, "v8::Function::GetDisplayName()",
   4225              return ToApiHandle<Primitive>(
   4226                 isolate->factory()->undefined_value()));
   4227   ENTER_V8(isolate);
   4228   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4229   i::Handle<i::String> property_name =
   4230       isolate->factory()->InternalizeOneByteString(
   4231           STATIC_ASCII_VECTOR("displayName"));
   4232   i::LookupResult lookup(isolate);
   4233   func->LookupRealNamedProperty(*property_name, &lookup);
   4234   if (lookup.IsFound()) {
   4235     i::Object* value = lookup.GetLazyValue();
   4236     if (value && value->IsString()) {
   4237       i::String* name = i::String::cast(value);
   4238       if (name->length() > 0) return Utils::ToLocal(i::Handle<i::String>(name));
   4239     }
   4240   }
   4241   return ToApiHandle<Primitive>(isolate->factory()->undefined_value());
   4242 }
   4243 
   4244 
   4245 ScriptOrigin Function::GetScriptOrigin() const {
   4246   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4247   if (func->shared()->script()->IsScript()) {
   4248     i::Handle<i::Script> script(i::Script::cast(func->shared()->script()));
   4249     i::Handle<i::Object> scriptName = GetScriptNameOrSourceURL(script);
   4250     v8::ScriptOrigin origin(
   4251       Utils::ToLocal(scriptName),
   4252       v8::Integer::New(script->line_offset()->value()),
   4253       v8::Integer::New(script->column_offset()->value()));
   4254     return origin;
   4255   }
   4256   return v8::ScriptOrigin(Handle<Value>());
   4257 }
   4258 
   4259 
   4260 const int Function::kLineOffsetNotFound = -1;
   4261 
   4262 
   4263 int Function::GetScriptLineNumber() const {
   4264   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4265   if (func->shared()->script()->IsScript()) {
   4266     i::Handle<i::Script> script(i::Script::cast(func->shared()->script()));
   4267     return i::GetScriptLineNumber(script, func->shared()->start_position());
   4268   }
   4269   return kLineOffsetNotFound;
   4270 }
   4271 
   4272 
   4273 int Function::GetScriptColumnNumber() const {
   4274   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4275   if (func->shared()->script()->IsScript()) {
   4276     i::Handle<i::Script> script(i::Script::cast(func->shared()->script()));
   4277     return i::GetScriptColumnNumber(script, func->shared()->start_position());
   4278   }
   4279   return kLineOffsetNotFound;
   4280 }
   4281 
   4282 
   4283 bool Function::IsBuiltin() const {
   4284   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4285   return func->IsBuiltin();
   4286 }
   4287 
   4288 
   4289 Handle<Value> Function::GetScriptId() const {
   4290   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4291   i::Isolate* isolate = func->GetIsolate();
   4292   if (!func->shared()->script()->IsScript()) {
   4293     return v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   4294   }
   4295   i::Handle<i::Script> script(i::Script::cast(func->shared()->script()));
   4296   return Utils::ToLocal(i::Handle<i::Object>(script->id(), isolate));
   4297 }
   4298 
   4299 
   4300 int Function::ScriptId() const {
   4301   i::Handle<i::JSFunction> func = Utils::OpenHandle(this);
   4302   if (!func->shared()->script()->IsScript()) return v8::Script::kNoScriptId;
   4303   i::Handle<i::Script> script(i::Script::cast(func->shared()->script()));
   4304   return script->id()->value();
   4305 }
   4306 
   4307 
   4308 int String::Length() const {
   4309   i::Handle<i::String> str = Utils::OpenHandle(this);
   4310   return str->length();
   4311 }
   4312 
   4313 
   4314 bool String::IsOneByte() const {
   4315   i::Handle<i::String> str = Utils::OpenHandle(this);
   4316   return str->HasOnlyOneByteChars();
   4317 }
   4318 
   4319 
   4320 // Helpers for ContainsOnlyOneByteHelper
   4321 template<size_t size> struct OneByteMask;
   4322 template<> struct OneByteMask<4> {
   4323   static const uint32_t value = 0xFF00FF00;
   4324 };
   4325 template<> struct OneByteMask<8> {
   4326   static const uint64_t value = V8_2PART_UINT64_C(0xFF00FF00, FF00FF00);
   4327 };
   4328 static const uintptr_t kOneByteMask = OneByteMask<sizeof(uintptr_t)>::value;
   4329 static const uintptr_t kAlignmentMask = sizeof(uintptr_t) - 1;
   4330 static inline bool Unaligned(const uint16_t* chars) {
   4331   return reinterpret_cast<const uintptr_t>(chars) & kAlignmentMask;
   4332 }
   4333 
   4334 
   4335 static inline const uint16_t* Align(const uint16_t* chars) {
   4336   return reinterpret_cast<uint16_t*>(
   4337     reinterpret_cast<uintptr_t>(chars) & ~kAlignmentMask);
   4338 }
   4339 
   4340 class ContainsOnlyOneByteHelper {
   4341  public:
   4342   ContainsOnlyOneByteHelper() : is_one_byte_(true) {}
   4343   bool Check(i::String* string) {
   4344     i::ConsString* cons_string = i::String::VisitFlat(this, string, 0);
   4345     if (cons_string == NULL) return is_one_byte_;
   4346     return CheckCons(cons_string);
   4347   }
   4348   void VisitOneByteString(const uint8_t* chars, int length) {
   4349     // Nothing to do.
   4350   }
   4351   void VisitTwoByteString(const uint16_t* chars, int length) {
   4352     // Accumulated bits.
   4353     uintptr_t acc = 0;
   4354     // Align to uintptr_t.
   4355     const uint16_t* end = chars + length;
   4356     while (Unaligned(chars) && chars != end) {
   4357         acc |= *chars++;
   4358     }
   4359     // Read word aligned in blocks,
   4360     // checking the return value at the end of each block.
   4361     const uint16_t* aligned_end = Align(end);
   4362     const int increment = sizeof(uintptr_t)/sizeof(uint16_t);
   4363     const int inner_loops = 16;
   4364     while (chars + inner_loops*increment < aligned_end) {
   4365       for (int i = 0; i < inner_loops; i++) {
   4366         acc |= *reinterpret_cast<const uintptr_t*>(chars);
   4367         chars += increment;
   4368       }
   4369       // Check for early return.
   4370       if ((acc & kOneByteMask) != 0) {
   4371         is_one_byte_ = false;
   4372         return;
   4373       }
   4374     }
   4375     // Read the rest.
   4376     while (chars != end) {
   4377       acc |= *chars++;
   4378     }
   4379     // Check result.
   4380     if ((acc & kOneByteMask) != 0) is_one_byte_ = false;
   4381   }
   4382 
   4383  private:
   4384   bool CheckCons(i::ConsString* cons_string) {
   4385     while (true) {
   4386       // Check left side if flat.
   4387       i::String* left = cons_string->first();
   4388       i::ConsString* left_as_cons =
   4389           i::String::VisitFlat(this, left, 0);
   4390       if (!is_one_byte_) return false;
   4391       // Check right side if flat.
   4392       i::String* right = cons_string->second();
   4393       i::ConsString* right_as_cons =
   4394           i::String::VisitFlat(this, right, 0);
   4395       if (!is_one_byte_) return false;
   4396       // Standard recurse/iterate trick.
   4397       if (left_as_cons != NULL && right_as_cons != NULL) {
   4398         if (left->length() < right->length()) {
   4399           CheckCons(left_as_cons);
   4400           cons_string = right_as_cons;
   4401         } else {
   4402           CheckCons(right_as_cons);
   4403           cons_string = left_as_cons;
   4404         }
   4405         // Check fast return.
   4406         if (!is_one_byte_) return false;
   4407         continue;
   4408       }
   4409       // Descend left in place.
   4410       if (left_as_cons != NULL) {
   4411         cons_string = left_as_cons;
   4412         continue;
   4413       }
   4414       // Descend right in place.
   4415       if (right_as_cons != NULL) {
   4416         cons_string = right_as_cons;
   4417         continue;
   4418       }
   4419       // Terminate.
   4420       break;
   4421     }
   4422     return is_one_byte_;
   4423   }
   4424   bool is_one_byte_;
   4425   DISALLOW_COPY_AND_ASSIGN(ContainsOnlyOneByteHelper);
   4426 };
   4427 
   4428 
   4429 bool String::ContainsOnlyOneByte() const {
   4430   i::Handle<i::String> str = Utils::OpenHandle(this);
   4431   if (str->HasOnlyOneByteChars()) return true;
   4432   ContainsOnlyOneByteHelper helper;
   4433   return helper.Check(*str);
   4434 }
   4435 
   4436 
   4437 class Utf8LengthHelper : public i::AllStatic {
   4438  public:
   4439   enum State {
   4440     kEndsWithLeadingSurrogate = 1 << 0,
   4441     kStartsWithTrailingSurrogate = 1 << 1,
   4442     kLeftmostEdgeIsCalculated = 1 << 2,
   4443     kRightmostEdgeIsCalculated = 1 << 3,
   4444     kLeftmostEdgeIsSurrogate = 1 << 4,
   4445     kRightmostEdgeIsSurrogate = 1 << 5
   4446   };
   4447 
   4448   static const uint8_t kInitialState = 0;
   4449 
   4450   static inline bool EndsWithSurrogate(uint8_t state) {
   4451     return state & kEndsWithLeadingSurrogate;
   4452   }
   4453 
   4454   static inline bool StartsWithSurrogate(uint8_t state) {
   4455     return state & kStartsWithTrailingSurrogate;
   4456   }
   4457 
   4458   class Visitor {
   4459    public:
   4460     inline explicit Visitor()
   4461       : utf8_length_(0),
   4462         state_(kInitialState) {}
   4463 
   4464     void VisitOneByteString(const uint8_t* chars, int length) {
   4465       int utf8_length = 0;
   4466       // Add in length 1 for each non-ASCII character.
   4467       for (int i = 0; i < length; i++) {
   4468         utf8_length += *chars++ >> 7;
   4469       }
   4470       // Add in length 1 for each character.
   4471       utf8_length_ = utf8_length + length;
   4472       state_ = kInitialState;
   4473     }
   4474 
   4475     void VisitTwoByteString(const uint16_t* chars, int length) {
   4476       int utf8_length = 0;
   4477       int last_character = unibrow::Utf16::kNoPreviousCharacter;
   4478       for (int i = 0; i < length; i++) {
   4479         uint16_t c = chars[i];
   4480         utf8_length += unibrow::Utf8::Length(c, last_character);
   4481         last_character = c;
   4482       }
   4483       utf8_length_ = utf8_length;
   4484       uint8_t state = 0;
   4485       if (unibrow::Utf16::IsTrailSurrogate(chars[0])) {
   4486         state |= kStartsWithTrailingSurrogate;
   4487       }
   4488       if (unibrow::Utf16::IsLeadSurrogate(chars[length-1])) {
   4489         state |= kEndsWithLeadingSurrogate;
   4490       }
   4491       state_ = state;
   4492     }
   4493 
   4494     static i::ConsString* VisitFlat(i::String* string,
   4495                                     int* length,
   4496                                     uint8_t* state) {
   4497       Visitor visitor;
   4498       i::ConsString* cons_string = i::String::VisitFlat(&visitor, string);
   4499       *length = visitor.utf8_length_;
   4500       *state = visitor.state_;
   4501       return cons_string;
   4502     }
   4503 
   4504    private:
   4505     int utf8_length_;
   4506     uint8_t state_;
   4507     DISALLOW_COPY_AND_ASSIGN(Visitor);
   4508   };
   4509 
   4510   static inline void MergeLeafLeft(int* length,
   4511                                    uint8_t* state,
   4512                                    uint8_t leaf_state) {
   4513     bool edge_surrogate = StartsWithSurrogate(leaf_state);
   4514     if (!(*state & kLeftmostEdgeIsCalculated)) {
   4515       ASSERT(!(*state & kLeftmostEdgeIsSurrogate));
   4516       *state |= kLeftmostEdgeIsCalculated
   4517           | (edge_surrogate ? kLeftmostEdgeIsSurrogate : 0);
   4518     } else if (EndsWithSurrogate(*state) && edge_surrogate) {
   4519       *length -= unibrow::Utf8::kBytesSavedByCombiningSurrogates;
   4520     }
   4521     if (EndsWithSurrogate(leaf_state)) {
   4522       *state |= kEndsWithLeadingSurrogate;
   4523     } else {
   4524       *state &= ~kEndsWithLeadingSurrogate;
   4525     }
   4526   }
   4527 
   4528   static inline void MergeLeafRight(int* length,
   4529                                     uint8_t* state,
   4530                                     uint8_t leaf_state) {
   4531     bool edge_surrogate = EndsWithSurrogate(leaf_state);
   4532     if (!(*state & kRightmostEdgeIsCalculated)) {
   4533       ASSERT(!(*state & kRightmostEdgeIsSurrogate));
   4534       *state |= (kRightmostEdgeIsCalculated
   4535           | (edge_surrogate ? kRightmostEdgeIsSurrogate : 0));
   4536     } else if (edge_surrogate && StartsWithSurrogate(*state)) {
   4537       *length -= unibrow::Utf8::kBytesSavedByCombiningSurrogates;
   4538     }
   4539     if (StartsWithSurrogate(leaf_state)) {
   4540       *state |= kStartsWithTrailingSurrogate;
   4541     } else {
   4542       *state &= ~kStartsWithTrailingSurrogate;
   4543     }
   4544   }
   4545 
   4546   static inline void MergeTerminal(int* length,
   4547                                    uint8_t state,
   4548                                    uint8_t* state_out) {
   4549     ASSERT((state & kLeftmostEdgeIsCalculated) &&
   4550            (state & kRightmostEdgeIsCalculated));
   4551     if (EndsWithSurrogate(state) && StartsWithSurrogate(state)) {
   4552       *length -= unibrow::Utf8::kBytesSavedByCombiningSurrogates;
   4553     }
   4554     *state_out = kInitialState |
   4555         (state & kLeftmostEdgeIsSurrogate ? kStartsWithTrailingSurrogate : 0) |
   4556         (state & kRightmostEdgeIsSurrogate ? kEndsWithLeadingSurrogate : 0);
   4557   }
   4558 
   4559   static int Calculate(i::ConsString* current, uint8_t* state_out) {
   4560     using namespace internal;
   4561     int total_length = 0;
   4562     uint8_t state = kInitialState;
   4563     while (true) {
   4564       i::String* left = current->first();
   4565       i::String* right = current->second();
   4566       uint8_t right_leaf_state;
   4567       uint8_t left_leaf_state;
   4568       int leaf_length;
   4569       ConsString* left_as_cons =
   4570           Visitor::VisitFlat(left, &leaf_length, &left_leaf_state);
   4571       if (left_as_cons == NULL) {
   4572         total_length += leaf_length;
   4573         MergeLeafLeft(&total_length, &state, left_leaf_state);
   4574       }
   4575       ConsString* right_as_cons =
   4576           Visitor::VisitFlat(right, &leaf_length, &right_leaf_state);
   4577       if (right_as_cons == NULL) {
   4578         total_length += leaf_length;
   4579         MergeLeafRight(&total_length, &state, right_leaf_state);
   4580         if (left_as_cons != NULL) {
   4581           // 1 Leaf node. Descend in place.
   4582           current = left_as_cons;
   4583           continue;
   4584         } else {
   4585           // Terminal node.
   4586           MergeTerminal(&total_length, state, state_out);
   4587           return total_length;
   4588         }
   4589       } else if (left_as_cons == NULL) {
   4590         // 1 Leaf node. Descend in place.
   4591         current = right_as_cons;
   4592         continue;
   4593       }
   4594       // Both strings are ConsStrings.
   4595       // Recurse on smallest.
   4596       if (left->length() < right->length()) {
   4597         total_length += Calculate(left_as_cons, &left_leaf_state);
   4598         MergeLeafLeft(&total_length, &state, left_leaf_state);
   4599         current = right_as_cons;
   4600       } else {
   4601         total_length += Calculate(right_as_cons, &right_leaf_state);
   4602         MergeLeafRight(&total_length, &state, right_leaf_state);
   4603         current = left_as_cons;
   4604       }
   4605     }
   4606     UNREACHABLE();
   4607     return 0;
   4608   }
   4609 
   4610   static inline int Calculate(i::ConsString* current) {
   4611     uint8_t state = kInitialState;
   4612     return Calculate(current, &state);
   4613   }
   4614 
   4615  private:
   4616   DISALLOW_IMPLICIT_CONSTRUCTORS(Utf8LengthHelper);
   4617 };
   4618 
   4619 
   4620 static int Utf8Length(i::String* str, i::Isolate* isolate) {
   4621   int length = str->length();
   4622   if (length == 0) return 0;
   4623   uint8_t state;
   4624   i::ConsString* cons_string =
   4625       Utf8LengthHelper::Visitor::VisitFlat(str, &length, &state);
   4626   if (cons_string == NULL) return length;
   4627   return Utf8LengthHelper::Calculate(cons_string);
   4628 }
   4629 
   4630 
   4631 int String::Utf8Length() const {
   4632   i::Handle<i::String> str = Utils::OpenHandle(this);
   4633   i::Isolate* isolate = str->GetIsolate();
   4634   return v8::Utf8Length(*str, isolate);
   4635 }
   4636 
   4637 
   4638 class Utf8WriterVisitor {
   4639  public:
   4640   Utf8WriterVisitor(
   4641       char* buffer, int capacity, bool skip_capacity_check)
   4642     : early_termination_(false),
   4643       last_character_(unibrow::Utf16::kNoPreviousCharacter),
   4644       buffer_(buffer),
   4645       start_(buffer),
   4646       capacity_(capacity),
   4647       skip_capacity_check_(capacity == -1 || skip_capacity_check),
   4648       utf16_chars_read_(0) {
   4649   }
   4650 
   4651   static int WriteEndCharacter(uint16_t character,
   4652                                int last_character,
   4653                                int remaining,
   4654                                char* const buffer) {
   4655     using namespace unibrow;
   4656     ASSERT(remaining > 0);
   4657     // We can't use a local buffer here because Encode needs to modify
   4658     // previous characters in the stream.  We know, however, that
   4659     // exactly one character will be advanced.
   4660     if (Utf16::IsTrailSurrogate(character) &&
   4661         Utf16::IsLeadSurrogate(last_character)) {
   4662       int written = Utf8::Encode(buffer, character, last_character);
   4663       ASSERT(written == 1);
   4664       return written;
   4665     }
   4666     // Use a scratch buffer to check the required characters.
   4667     char temp_buffer[Utf8::kMaxEncodedSize];
   4668     // Can't encode using last_character as gcc has array bounds issues.
   4669     int written = Utf8::Encode(temp_buffer,
   4670                                character,
   4671                                Utf16::kNoPreviousCharacter);
   4672     // Won't fit.
   4673     if (written > remaining) return 0;
   4674     // Copy over the character from temp_buffer.
   4675     for (int j = 0; j < written; j++) {
   4676       buffer[j] = temp_buffer[j];
   4677     }
   4678     return written;
   4679   }
   4680 
   4681   template<typename Char>
   4682   void Visit(const Char* chars, const int length) {
   4683     using namespace unibrow;
   4684     ASSERT(!early_termination_);
   4685     if (length == 0) return;
   4686     // Copy state to stack.
   4687     char* buffer = buffer_;
   4688     int last_character =
   4689         sizeof(Char) == 1 ? Utf16::kNoPreviousCharacter : last_character_;
   4690     int i = 0;
   4691     // Do a fast loop where there is no exit capacity check.
   4692     while (true) {
   4693       int fast_length;
   4694       if (skip_capacity_check_) {
   4695         fast_length = length;
   4696       } else {
   4697         int remaining_capacity = capacity_ - static_cast<int>(buffer - start_);
   4698         // Need enough space to write everything but one character.
   4699         STATIC_ASSERT(Utf16::kMaxExtraUtf8BytesForOneUtf16CodeUnit == 3);
   4700         int max_size_per_char =  sizeof(Char) == 1 ? 2 : 3;
   4701         int writable_length =
   4702             (remaining_capacity - max_size_per_char)/max_size_per_char;
   4703         // Need to drop into slow loop.
   4704         if (writable_length <= 0) break;
   4705         fast_length = i + writable_length;
   4706         if (fast_length > length) fast_length = length;
   4707       }
   4708       // Write the characters to the stream.
   4709       if (sizeof(Char) == 1) {
   4710         for (; i < fast_length; i++) {
   4711           buffer +=
   4712               Utf8::EncodeOneByte(buffer, static_cast<uint8_t>(*chars++));
   4713           ASSERT(capacity_ == -1 || (buffer - start_) <= capacity_);
   4714         }
   4715       } else {
   4716         for (; i < fast_length; i++) {
   4717           uint16_t character = *chars++;
   4718           buffer += Utf8::Encode(buffer, character, last_character);
   4719           last_character = character;
   4720           ASSERT(capacity_ == -1 || (buffer - start_) <= capacity_);
   4721         }
   4722       }
   4723       // Array is fully written. Exit.
   4724       if (fast_length == length) {
   4725         // Write state back out to object.
   4726         last_character_ = last_character;
   4727         buffer_ = buffer;
   4728         utf16_chars_read_ += length;
   4729         return;
   4730       }
   4731     }
   4732     ASSERT(!skip_capacity_check_);
   4733     // Slow loop. Must check capacity on each iteration.
   4734     int remaining_capacity = capacity_ - static_cast<int>(buffer - start_);
   4735     ASSERT(remaining_capacity >= 0);
   4736     for (; i < length && remaining_capacity > 0; i++) {
   4737       uint16_t character = *chars++;
   4738       int written = WriteEndCharacter(character,
   4739                                       last_character,
   4740                                       remaining_capacity,
   4741                                       buffer);
   4742       if (written == 0) {
   4743         early_termination_ = true;
   4744         break;
   4745       }
   4746       buffer += written;
   4747       remaining_capacity -= written;
   4748       last_character = character;
   4749     }
   4750     // Write state back out to object.
   4751     last_character_ = last_character;
   4752     buffer_ = buffer;
   4753     utf16_chars_read_ += i;
   4754   }
   4755 
   4756   inline bool IsDone() {
   4757     return early_termination_;
   4758   }
   4759 
   4760   inline void VisitOneByteString(const uint8_t* chars, int length) {
   4761     Visit(chars, length);
   4762   }
   4763 
   4764   inline void VisitTwoByteString(const uint16_t* chars, int length) {
   4765     Visit(chars, length);
   4766   }
   4767 
   4768   int CompleteWrite(bool write_null, int* utf16_chars_read_out) {
   4769     // Write out number of utf16 characters written to the stream.
   4770     if (utf16_chars_read_out != NULL) {
   4771       *utf16_chars_read_out = utf16_chars_read_;
   4772     }
   4773     // Only null terminate if all of the string was written and there's space.
   4774     if (write_null &&
   4775         !early_termination_ &&
   4776         (capacity_ == -1 || (buffer_ - start_) < capacity_)) {
   4777       *buffer_++ = '\0';
   4778     }
   4779     return static_cast<int>(buffer_ - start_);
   4780   }
   4781 
   4782  private:
   4783   bool early_termination_;
   4784   int last_character_;
   4785   char* buffer_;
   4786   char* const start_;
   4787   int capacity_;
   4788   bool const skip_capacity_check_;
   4789   int utf16_chars_read_;
   4790   DISALLOW_IMPLICIT_CONSTRUCTORS(Utf8WriterVisitor);
   4791 };
   4792 
   4793 
   4794 static bool RecursivelySerializeToUtf8(i::String* current,
   4795                                       Utf8WriterVisitor* writer,
   4796                                       int recursion_budget) {
   4797   while (!writer->IsDone()) {
   4798     i::ConsString* cons_string = i::String::VisitFlat(writer, current);
   4799     if (cons_string == NULL) return true;  // Leaf node.
   4800     if (recursion_budget <= 0) return false;
   4801     // Must write the left branch first.
   4802     i::String* first = cons_string->first();
   4803     bool success = RecursivelySerializeToUtf8(first,
   4804                                               writer,
   4805                                               recursion_budget - 1);
   4806     if (!success) return false;
   4807     // Inline tail recurse for right branch.
   4808     current = cons_string->second();
   4809   }
   4810   return true;
   4811 }
   4812 
   4813 
   4814 int String::WriteUtf8(char* buffer,
   4815                       int capacity,
   4816                       int* nchars_ref,
   4817                       int options) const {
   4818   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   4819   LOG_API(isolate, "String::WriteUtf8");
   4820   ENTER_V8(isolate);
   4821   i::Handle<i::String> str = Utils::OpenHandle(this);
   4822   if (options & HINT_MANY_WRITES_EXPECTED) {
   4823     FlattenString(str);  // Flatten the string for efficiency.
   4824   }
   4825   const int string_length = str->length();
   4826   bool write_null = !(options & NO_NULL_TERMINATION);
   4827   // First check if we can just write the string without checking capacity.
   4828   if (capacity == -1 || capacity / 3 >= string_length) {
   4829     Utf8WriterVisitor writer(buffer, capacity, true);
   4830     const int kMaxRecursion = 100;
   4831     bool success = RecursivelySerializeToUtf8(*str, &writer, kMaxRecursion);
   4832     if (success) return writer.CompleteWrite(write_null, nchars_ref);
   4833   } else if (capacity >= string_length) {
   4834     // First check that the buffer is large enough.
   4835     int utf8_bytes = v8::Utf8Length(*str, str->GetIsolate());
   4836     if (utf8_bytes <= capacity) {
   4837       // ASCII fast path.
   4838       if (utf8_bytes == string_length) {
   4839         WriteOneByte(reinterpret_cast<uint8_t*>(buffer), 0, capacity, options);
   4840         if (nchars_ref != NULL) *nchars_ref = string_length;
   4841         if (write_null && (utf8_bytes+1 <= capacity)) {
   4842           return string_length + 1;
   4843         }
   4844         return string_length;
   4845       }
   4846       if (write_null && (utf8_bytes+1 > capacity)) {
   4847         options |= NO_NULL_TERMINATION;
   4848       }
   4849       // Recurse once without a capacity limit.
   4850       // This will get into the first branch above.
   4851       // TODO(dcarney) Check max left rec. in Utf8Length and fall through.
   4852       return WriteUtf8(buffer, -1, nchars_ref, options);
   4853     }
   4854   }
   4855   // Recursive slow path can potentially be unreasonable slow. Flatten.
   4856   str = FlattenGetString(str);
   4857   Utf8WriterVisitor writer(buffer, capacity, false);
   4858   i::String::VisitFlat(&writer, *str);
   4859   return writer.CompleteWrite(write_null, nchars_ref);
   4860 }
   4861 
   4862 
   4863 template<typename CharType>
   4864 static inline int WriteHelper(const String* string,
   4865                               CharType* buffer,
   4866                               int start,
   4867                               int length,
   4868                               int options) {
   4869   i::Isolate* isolate = Utils::OpenHandle(string)->GetIsolate();
   4870   LOG_API(isolate, "String::Write");
   4871   ENTER_V8(isolate);
   4872   ASSERT(start >= 0 && length >= -1);
   4873   i::Handle<i::String> str = Utils::OpenHandle(string);
   4874   isolate->string_tracker()->RecordWrite(str);
   4875   if (options & String::HINT_MANY_WRITES_EXPECTED) {
   4876     // Flatten the string for efficiency.  This applies whether we are
   4877     // using StringCharacterStream or Get(i) to access the characters.
   4878     FlattenString(str);
   4879   }
   4880   int end = start + length;
   4881   if ((length == -1) || (length > str->length() - start) )
   4882     end = str->length();
   4883   if (end < 0) return 0;
   4884   i::String::WriteToFlat(*str, buffer, start, end);
   4885   if (!(options & String::NO_NULL_TERMINATION) &&
   4886       (length == -1 || end - start < length)) {
   4887     buffer[end - start] = '\0';
   4888   }
   4889   return end - start;
   4890 }
   4891 
   4892 
   4893 int String::WriteOneByte(uint8_t* buffer,
   4894                          int start,
   4895                          int length,
   4896                          int options) const {
   4897   return WriteHelper(this, buffer, start, length, options);
   4898 }
   4899 
   4900 
   4901 int String::Write(uint16_t* buffer,
   4902                   int start,
   4903                   int length,
   4904                   int options) const {
   4905   return WriteHelper(this, buffer, start, length, options);
   4906 }
   4907 
   4908 
   4909 bool v8::String::IsExternal() const {
   4910   i::Handle<i::String> str = Utils::OpenHandle(this);
   4911   EnsureInitializedForIsolate(str->GetIsolate(), "v8::String::IsExternal()");
   4912   return i::StringShape(*str).IsExternalTwoByte();
   4913 }
   4914 
   4915 
   4916 bool v8::String::IsExternalAscii() const {
   4917   i::Handle<i::String> str = Utils::OpenHandle(this);
   4918   return i::StringShape(*str).IsExternalAscii();
   4919 }
   4920 
   4921 
   4922 void v8::String::VerifyExternalStringResource(
   4923     v8::String::ExternalStringResource* value) const {
   4924   i::Handle<i::String> str = Utils::OpenHandle(this);
   4925   const v8::String::ExternalStringResource* expected;
   4926   if (i::StringShape(*str).IsExternalTwoByte()) {
   4927     const void* resource =
   4928         i::Handle<i::ExternalTwoByteString>::cast(str)->resource();
   4929     expected = reinterpret_cast<const ExternalStringResource*>(resource);
   4930   } else {
   4931     expected = NULL;
   4932   }
   4933   CHECK_EQ(expected, value);
   4934 }
   4935 
   4936 void v8::String::VerifyExternalStringResourceBase(
   4937     v8::String::ExternalStringResourceBase* value, Encoding encoding) const {
   4938   i::Handle<i::String> str = Utils::OpenHandle(this);
   4939   const v8::String::ExternalStringResourceBase* expected;
   4940   Encoding expectedEncoding;
   4941   if (i::StringShape(*str).IsExternalAscii()) {
   4942     const void* resource =
   4943         i::Handle<i::ExternalAsciiString>::cast(str)->resource();
   4944     expected = reinterpret_cast<const ExternalStringResourceBase*>(resource);
   4945     expectedEncoding = ASCII_ENCODING;
   4946   } else if (i::StringShape(*str).IsExternalTwoByte()) {
   4947     const void* resource =
   4948         i::Handle<i::ExternalTwoByteString>::cast(str)->resource();
   4949     expected = reinterpret_cast<const ExternalStringResourceBase*>(resource);
   4950     expectedEncoding = TWO_BYTE_ENCODING;
   4951   } else {
   4952     expected = NULL;
   4953     expectedEncoding = str->IsOneByteRepresentation() ? ASCII_ENCODING
   4954                                                     : TWO_BYTE_ENCODING;
   4955   }
   4956   CHECK_EQ(expected, value);
   4957   CHECK_EQ(expectedEncoding, encoding);
   4958 }
   4959 
   4960 const v8::String::ExternalAsciiStringResource*
   4961       v8::String::GetExternalAsciiStringResource() const {
   4962   i::Handle<i::String> str = Utils::OpenHandle(this);
   4963   if (i::StringShape(*str).IsExternalAscii()) {
   4964     const void* resource =
   4965         i::Handle<i::ExternalAsciiString>::cast(str)->resource();
   4966     return reinterpret_cast<const ExternalAsciiStringResource*>(resource);
   4967   } else {
   4968     return NULL;
   4969   }
   4970 }
   4971 
   4972 
   4973 Local<Value> Symbol::Name() const {
   4974   i::Handle<i::Symbol> sym = Utils::OpenHandle(this);
   4975   i::Handle<i::Object> name(sym->name(), sym->GetIsolate());
   4976   return Utils::ToLocal(name);
   4977 }
   4978 
   4979 
   4980 Local<Value> Private::Name() const {
   4981   return reinterpret_cast<const Symbol*>(this)->Name();
   4982 }
   4983 
   4984 
   4985 double Number::Value() const {
   4986   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   4987   return obj->Number();
   4988 }
   4989 
   4990 
   4991 bool Boolean::Value() const {
   4992   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   4993   return obj->IsTrue();
   4994 }
   4995 
   4996 
   4997 int64_t Integer::Value() const {
   4998   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   4999   if (obj->IsSmi()) {
   5000     return i::Smi::cast(*obj)->value();
   5001   } else {
   5002     return static_cast<int64_t>(obj->Number());
   5003   }
   5004 }
   5005 
   5006 
   5007 int32_t Int32::Value() const {
   5008   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5009   if (obj->IsSmi()) {
   5010     return i::Smi::cast(*obj)->value();
   5011   } else {
   5012     return static_cast<int32_t>(obj->Number());
   5013   }
   5014 }
   5015 
   5016 
   5017 uint32_t Uint32::Value() const {
   5018   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5019   if (obj->IsSmi()) {
   5020     return i::Smi::cast(*obj)->value();
   5021   } else {
   5022     return static_cast<uint32_t>(obj->Number());
   5023   }
   5024 }
   5025 
   5026 
   5027 int v8::Object::InternalFieldCount() {
   5028   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   5029   return obj->GetInternalFieldCount();
   5030 }
   5031 
   5032 
   5033 static bool InternalFieldOK(i::Handle<i::JSObject> obj,
   5034                             int index,
   5035                             const char* location) {
   5036   return ApiCheck(index < obj->GetInternalFieldCount(),
   5037                   location,
   5038                   "Internal field out of bounds");
   5039 }
   5040 
   5041 
   5042 Local<Value> v8::Object::SlowGetInternalField(int index) {
   5043   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   5044   const char* location = "v8::Object::GetInternalField()";
   5045   if (!InternalFieldOK(obj, index, location)) return Local<Value>();
   5046   i::Handle<i::Object> value(obj->GetInternalField(index), obj->GetIsolate());
   5047   return Utils::ToLocal(value);
   5048 }
   5049 
   5050 
   5051 void v8::Object::SetInternalField(int index, v8::Handle<Value> value) {
   5052   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   5053   const char* location = "v8::Object::SetInternalField()";
   5054   if (!InternalFieldOK(obj, index, location)) return;
   5055   i::Handle<i::Object> val = Utils::OpenHandle(*value);
   5056   obj->SetInternalField(index, *val);
   5057   ASSERT_EQ(value, GetInternalField(index));
   5058 }
   5059 
   5060 
   5061 void* v8::Object::SlowGetAlignedPointerFromInternalField(int index) {
   5062   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   5063   const char* location = "v8::Object::GetAlignedPointerFromInternalField()";
   5064   if (!InternalFieldOK(obj, index, location)) return NULL;
   5065   return DecodeSmiToAligned(obj->GetInternalField(index), location);
   5066 }
   5067 
   5068 
   5069 void v8::Object::SetAlignedPointerInInternalField(int index, void* value) {
   5070   i::Handle<i::JSObject> obj = Utils::OpenHandle(this);
   5071   const char* location = "v8::Object::SetAlignedPointerInInternalField()";
   5072   if (!InternalFieldOK(obj, index, location)) return;
   5073   obj->SetInternalField(index, EncodeAlignedAsSmi(value, location));
   5074   ASSERT_EQ(value, GetAlignedPointerFromInternalField(index));
   5075 }
   5076 
   5077 
   5078 static void* ExternalValue(i::Object* obj) {
   5079   // Obscure semantics for undefined, but somehow checked in our unit tests...
   5080   if (obj->IsUndefined()) return NULL;
   5081   i::Object* foreign = i::JSObject::cast(obj)->GetInternalField(0);
   5082   return i::Foreign::cast(foreign)->foreign_address();
   5083 }
   5084 
   5085 
   5086 // --- E n v i r o n m e n t ---
   5087 
   5088 
   5089 void v8::V8::InitializePlatform(Platform* platform) {
   5090 #ifdef V8_USE_DEFAULT_PLATFORM
   5091   FATAL("Can't override v8::Platform when using default implementation");
   5092 #else
   5093   i::V8::InitializePlatform(platform);
   5094 #endif
   5095 }
   5096 
   5097 
   5098 void v8::V8::ShutdownPlatform() {
   5099 #ifdef V8_USE_DEFAULT_PLATFORM
   5100   FATAL("Can't override v8::Platform when using default implementation");
   5101 #else
   5102   i::V8::ShutdownPlatform();
   5103 #endif
   5104 }
   5105 
   5106 
   5107 bool v8::V8::Initialize() {
   5108   i::Isolate* isolate = i::Isolate::UncheckedCurrent();
   5109   if (isolate != NULL && isolate->IsInitialized()) {
   5110     return true;
   5111   }
   5112   return InitializeHelper(isolate);
   5113 }
   5114 
   5115 
   5116 void v8::V8::SetEntropySource(EntropySource entropy_source) {
   5117   i::RandomNumberGenerator::SetEntropySource(entropy_source);
   5118 }
   5119 
   5120 
   5121 void v8::V8::SetReturnAddressLocationResolver(
   5122       ReturnAddressLocationResolver return_address_resolver) {
   5123   i::V8::SetReturnAddressLocationResolver(return_address_resolver);
   5124 }
   5125 
   5126 
   5127 bool v8::V8::SetFunctionEntryHook(Isolate* ext_isolate,
   5128                                   FunctionEntryHook entry_hook) {
   5129   ASSERT(ext_isolate != NULL);
   5130   ASSERT(entry_hook != NULL);
   5131 
   5132   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(ext_isolate);
   5133 
   5134   // The entry hook can only be set before the Isolate is initialized, as
   5135   // otherwise the Isolate's code stubs generated at initialization won't
   5136   // contain entry hooks.
   5137   if (isolate->IsInitialized())
   5138     return false;
   5139 
   5140   // Setting an entry hook is a one-way operation, once set, it cannot be
   5141   // changed or unset.
   5142   if (isolate->function_entry_hook() != NULL)
   5143     return false;
   5144 
   5145   isolate->set_function_entry_hook(entry_hook);
   5146   return true;
   5147 }
   5148 
   5149 
   5150 void v8::V8::SetJitCodeEventHandler(
   5151     JitCodeEventOptions options, JitCodeEventHandler event_handler) {
   5152   i::Isolate* isolate = i::Isolate::Current();
   5153   // Ensure that logging is initialized for our isolate.
   5154   isolate->InitializeLoggingAndCounters();
   5155   isolate->logger()->SetCodeEventHandler(options, event_handler);
   5156 }
   5157 
   5158 void v8::V8::SetArrayBufferAllocator(
   5159     ArrayBuffer::Allocator* allocator) {
   5160   if (!ApiCheck(i::V8::ArrayBufferAllocator() == NULL,
   5161                 "v8::V8::SetArrayBufferAllocator",
   5162                 "ArrayBufferAllocator might only be set once"))
   5163     return;
   5164   i::V8::SetArrayBufferAllocator(allocator);
   5165 }
   5166 
   5167 
   5168 bool v8::V8::Dispose() {
   5169   i::Isolate* isolate = i::Isolate::Current();
   5170   if (!ApiCheck(isolate != NULL && isolate->IsDefaultIsolate(),
   5171                 "v8::V8::Dispose()",
   5172                 "Use v8::Isolate::Dispose() for a non-default isolate.")) {
   5173     return false;
   5174   }
   5175   i::V8::TearDown();
   5176   return true;
   5177 }
   5178 
   5179 
   5180 HeapStatistics::HeapStatistics(): total_heap_size_(0),
   5181                                   total_heap_size_executable_(0),
   5182                                   total_physical_size_(0),
   5183                                   used_heap_size_(0),
   5184                                   heap_size_limit_(0) { }
   5185 
   5186 
   5187 void v8::V8::VisitExternalResources(ExternalResourceVisitor* visitor) {
   5188   i::Isolate* isolate = i::Isolate::Current();
   5189   isolate->heap()->VisitExternalResources(visitor);
   5190 }
   5191 
   5192 
   5193 class VisitorAdapter : public i::ObjectVisitor {
   5194  public:
   5195   explicit VisitorAdapter(PersistentHandleVisitor* visitor)
   5196       : visitor_(visitor) {}
   5197   virtual void VisitPointers(i::Object** start, i::Object** end) {
   5198     UNREACHABLE();
   5199   }
   5200   virtual void VisitEmbedderReference(i::Object** p, uint16_t class_id) {
   5201     Value* value = ToApi<Value>(i::Handle<i::Object>(p));
   5202     visitor_->VisitPersistentHandle(
   5203         reinterpret_cast<Persistent<Value>*>(&value), class_id);
   5204   }
   5205  private:
   5206   PersistentHandleVisitor* visitor_;
   5207 };
   5208 
   5209 
   5210 void v8::V8::VisitHandlesWithClassIds(PersistentHandleVisitor* visitor) {
   5211   i::Isolate* isolate = i::Isolate::Current();
   5212   i::DisallowHeapAllocation no_allocation;
   5213 
   5214   VisitorAdapter visitor_adapter(visitor);
   5215   isolate->global_handles()->IterateAllRootsWithClassIds(&visitor_adapter);
   5216 }
   5217 
   5218 
   5219 void v8::V8::VisitHandlesForPartialDependence(
   5220     Isolate* exported_isolate, PersistentHandleVisitor* visitor) {
   5221   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(exported_isolate);
   5222   ASSERT(isolate == i::Isolate::Current());
   5223   i::DisallowHeapAllocation no_allocation;
   5224 
   5225   VisitorAdapter visitor_adapter(visitor);
   5226   isolate->global_handles()->IterateAllRootsInNewSpaceWithClassIds(
   5227       &visitor_adapter);
   5228 }
   5229 
   5230 
   5231 bool v8::V8::IdleNotification(int hint) {
   5232   // Returning true tells the caller that it need not
   5233   // continue to call IdleNotification.
   5234   i::Isolate* isolate = i::Isolate::Current();
   5235   if (isolate == NULL || !isolate->IsInitialized()) return true;
   5236   if (!i::FLAG_use_idle_notification) return true;
   5237   return isolate->heap()->IdleNotification(hint);
   5238 }
   5239 
   5240 
   5241 void v8::V8::LowMemoryNotification() {
   5242   i::Isolate* isolate = i::Isolate::Current();
   5243   if (isolate == NULL || !isolate->IsInitialized()) return;
   5244   isolate->heap()->CollectAllAvailableGarbage("low memory notification");
   5245 }
   5246 
   5247 
   5248 int v8::V8::ContextDisposedNotification() {
   5249   i::Isolate* isolate = i::Isolate::Current();
   5250   if (!isolate->IsInitialized()) return 0;
   5251   return isolate->heap()->NotifyContextDisposed();
   5252 }
   5253 
   5254 
   5255 bool v8::V8::InitializeICU() {
   5256   return i::InitializeICU();
   5257 }
   5258 
   5259 
   5260 const char* v8::V8::GetVersion() {
   5261   return i::Version::GetVersion();
   5262 }
   5263 
   5264 
   5265 static i::Handle<i::Context> CreateEnvironment(
   5266     i::Isolate* isolate,
   5267     v8::ExtensionConfiguration* extensions,
   5268     v8::Handle<ObjectTemplate> global_template,
   5269     v8::Handle<Value> global_object) {
   5270   i::Handle<i::Context> env;
   5271 
   5272   // Enter V8 via an ENTER_V8 scope.
   5273   {
   5274     ENTER_V8(isolate);
   5275     v8::Handle<ObjectTemplate> proxy_template = global_template;
   5276     i::Handle<i::FunctionTemplateInfo> proxy_constructor;
   5277     i::Handle<i::FunctionTemplateInfo> global_constructor;
   5278 
   5279     if (!global_template.IsEmpty()) {
   5280       // Make sure that the global_template has a constructor.
   5281       global_constructor = EnsureConstructor(*global_template);
   5282 
   5283       // Create a fresh template for the global proxy object.
   5284       proxy_template = ObjectTemplate::New();
   5285       proxy_constructor = EnsureConstructor(*proxy_template);
   5286 
   5287       // Set the global template to be the prototype template of
   5288       // global proxy template.
   5289       proxy_constructor->set_prototype_template(
   5290           *Utils::OpenHandle(*global_template));
   5291 
   5292       // Migrate security handlers from global_template to
   5293       // proxy_template.  Temporarily removing access check
   5294       // information from the global template.
   5295       if (!global_constructor->access_check_info()->IsUndefined()) {
   5296         proxy_constructor->set_access_check_info(
   5297             global_constructor->access_check_info());
   5298         proxy_constructor->set_needs_access_check(
   5299             global_constructor->needs_access_check());
   5300         global_constructor->set_needs_access_check(false);
   5301         global_constructor->set_access_check_info(
   5302             isolate->heap()->undefined_value());
   5303       }
   5304     }
   5305 
   5306     // Create the environment.
   5307     env = isolate->bootstrapper()->CreateEnvironment(
   5308         Utils::OpenHandle(*global_object, true),
   5309         proxy_template,
   5310         extensions);
   5311 
   5312     // Restore the access check info on the global template.
   5313     if (!global_template.IsEmpty()) {
   5314       ASSERT(!global_constructor.is_null());
   5315       ASSERT(!proxy_constructor.is_null());
   5316       global_constructor->set_access_check_info(
   5317           proxy_constructor->access_check_info());
   5318       global_constructor->set_needs_access_check(
   5319           proxy_constructor->needs_access_check());
   5320     }
   5321     isolate->runtime_profiler()->Reset();
   5322   }
   5323   // Leave V8.
   5324 
   5325   return env;
   5326 }
   5327 
   5328 Local<Context> v8::Context::New(
   5329     v8::Isolate* external_isolate,
   5330     v8::ExtensionConfiguration* extensions,
   5331     v8::Handle<ObjectTemplate> global_template,
   5332     v8::Handle<Value> global_object) {
   5333   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(external_isolate);
   5334   EnsureInitializedForIsolate(isolate, "v8::Context::New()");
   5335   LOG_API(isolate, "Context::New");
   5336   ON_BAILOUT(isolate, "v8::Context::New()", return Local<Context>());
   5337   i::HandleScope scope(isolate);
   5338   i::Handle<i::Context> env =
   5339       CreateEnvironment(isolate, extensions, global_template, global_object);
   5340   if (env.is_null()) return Local<Context>();
   5341   return Utils::ToLocal(scope.CloseAndEscape(env));
   5342 }
   5343 
   5344 
   5345 void v8::Context::SetSecurityToken(Handle<Value> token) {
   5346   i::Isolate* isolate = i::Isolate::Current();
   5347   ENTER_V8(isolate);
   5348   i::Handle<i::Context> env = Utils::OpenHandle(this);
   5349   i::Handle<i::Object> token_handle = Utils::OpenHandle(*token);
   5350   env->set_security_token(*token_handle);
   5351 }
   5352 
   5353 
   5354 void v8::Context::UseDefaultSecurityToken() {
   5355   i::Isolate* isolate = i::Isolate::Current();
   5356   ENTER_V8(isolate);
   5357   i::Handle<i::Context> env = Utils::OpenHandle(this);
   5358   env->set_security_token(env->global_object());
   5359 }
   5360 
   5361 
   5362 Handle<Value> v8::Context::GetSecurityToken() {
   5363   i::Isolate* isolate = i::Isolate::Current();
   5364   i::Handle<i::Context> env = Utils::OpenHandle(this);
   5365   i::Object* security_token = env->security_token();
   5366   i::Handle<i::Object> token_handle(security_token, isolate);
   5367   return Utils::ToLocal(token_handle);
   5368 }
   5369 
   5370 
   5371 bool Context::HasOutOfMemoryException() {
   5372   i::Handle<i::Context> env = Utils::OpenHandle(this);
   5373   return env->has_out_of_memory();
   5374 }
   5375 
   5376 
   5377 bool Context::InContext() {
   5378   return i::Isolate::Current()->context() != NULL;
   5379 }
   5380 
   5381 
   5382 v8::Isolate* Context::GetIsolate() {
   5383   i::Handle<i::Context> env = Utils::OpenHandle(this);
   5384   return reinterpret_cast<Isolate*>(env->GetIsolate());
   5385 }
   5386 
   5387 
   5388 v8::Local<v8::Context> Context::GetEntered() {
   5389   i::Isolate* isolate = i::Isolate::Current();
   5390   if (!EnsureInitializedForIsolate(isolate, "v8::Context::GetEntered()")) {
   5391     return Local<Context>();
   5392   }
   5393   return reinterpret_cast<Isolate*>(isolate)->GetEnteredContext();
   5394 }
   5395 
   5396 
   5397 v8::Local<v8::Context> Context::GetCurrent() {
   5398   i::Isolate* isolate = i::Isolate::Current();
   5399   return reinterpret_cast<Isolate*>(isolate)->GetCurrentContext();
   5400 }
   5401 
   5402 
   5403 v8::Local<v8::Context> Context::GetCalling() {
   5404   i::Isolate* isolate = i::Isolate::Current();
   5405   return reinterpret_cast<Isolate*>(isolate)->GetCallingContext();
   5406 }
   5407 
   5408 
   5409 v8::Local<v8::Object> Context::Global() {
   5410   i::Handle<i::Context> context = Utils::OpenHandle(this);
   5411   i::Isolate* isolate = context->GetIsolate();
   5412   i::Handle<i::Object> global(context->global_proxy(), isolate);
   5413   // TODO(dcarney): This should always return the global proxy
   5414   // but can't presently as calls to GetProtoype will return the wrong result.
   5415   if (i::Handle<i::JSGlobalProxy>::cast(
   5416           global)->IsDetachedFrom(context->global_object())) {
   5417      global = i::Handle<i::Object>(context->global_object(), isolate);
   5418   }
   5419   return Utils::ToLocal(i::Handle<i::JSObject>::cast(global));
   5420 }
   5421 
   5422 
   5423 void Context::DetachGlobal() {
   5424   i::Handle<i::Context> context = Utils::OpenHandle(this);
   5425   i::Isolate* isolate = context->GetIsolate();
   5426   ENTER_V8(isolate);
   5427   isolate->bootstrapper()->DetachGlobal(context);
   5428 }
   5429 
   5430 
   5431 void Context::AllowCodeGenerationFromStrings(bool allow) {
   5432   i::Handle<i::Context> context = Utils::OpenHandle(this);
   5433   i::Isolate* isolate = context->GetIsolate();
   5434   ENTER_V8(isolate);
   5435   context->set_allow_code_gen_from_strings(
   5436       allow ? isolate->heap()->true_value() : isolate->heap()->false_value());
   5437 }
   5438 
   5439 
   5440 bool Context::IsCodeGenerationFromStringsAllowed() {
   5441   i::Handle<i::Context> context = Utils::OpenHandle(this);
   5442   return !context->allow_code_gen_from_strings()->IsFalse();
   5443 }
   5444 
   5445 
   5446 void Context::SetErrorMessageForCodeGenerationFromStrings(
   5447     Handle<String> error) {
   5448   i::Handle<i::Context> context = Utils::OpenHandle(this);
   5449   i::Handle<i::String> error_handle = Utils::OpenHandle(*error);
   5450   context->set_error_message_for_code_gen_from_strings(*error_handle);
   5451 }
   5452 
   5453 
   5454 Local<v8::Object> ObjectTemplate::NewInstance() {
   5455   i::Isolate* isolate = i::Isolate::Current();
   5456   ON_BAILOUT(isolate, "v8::ObjectTemplate::NewInstance()",
   5457              return Local<v8::Object>());
   5458   LOG_API(isolate, "ObjectTemplate::NewInstance");
   5459   ENTER_V8(isolate);
   5460   EXCEPTION_PREAMBLE(isolate);
   5461   i::Handle<i::Object> obj =
   5462       i::Execution::InstantiateObject(Utils::OpenHandle(this),
   5463                                       &has_pending_exception);
   5464   EXCEPTION_BAILOUT_CHECK(isolate, Local<v8::Object>());
   5465   return Utils::ToLocal(i::Handle<i::JSObject>::cast(obj));
   5466 }
   5467 
   5468 
   5469 Local<v8::Function> FunctionTemplate::GetFunction() {
   5470   i::Isolate* isolate = i::Isolate::Current();
   5471   ON_BAILOUT(isolate, "v8::FunctionTemplate::GetFunction()",
   5472              return Local<v8::Function>());
   5473   LOG_API(isolate, "FunctionTemplate::GetFunction");
   5474   ENTER_V8(isolate);
   5475   EXCEPTION_PREAMBLE(isolate);
   5476   i::Handle<i::Object> obj =
   5477       i::Execution::InstantiateFunction(Utils::OpenHandle(this),
   5478                                         &has_pending_exception);
   5479   EXCEPTION_BAILOUT_CHECK(isolate, Local<v8::Function>());
   5480   return Utils::ToLocal(i::Handle<i::JSFunction>::cast(obj));
   5481 }
   5482 
   5483 
   5484 bool FunctionTemplate::HasInstance(v8::Handle<v8::Value> value) {
   5485   ON_BAILOUT(i::Isolate::Current(), "v8::FunctionTemplate::HasInstanceOf()",
   5486              return false);
   5487   i::Object* obj = *Utils::OpenHandle(*value);
   5488   return Utils::OpenHandle(this)->IsTemplateFor(obj);
   5489 }
   5490 
   5491 
   5492 Local<External> v8::External::New(Isolate* isolate, void* value) {
   5493   STATIC_ASSERT(sizeof(value) == sizeof(i::Address));
   5494   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5495   EnsureInitializedForIsolate(i_isolate, "v8::External::New()");
   5496   LOG_API(i_isolate, "External::New");
   5497   ENTER_V8(i_isolate);
   5498   i::Handle<i::JSObject> external = i_isolate->factory()->NewExternal(value);
   5499   return Utils::ExternalToLocal(external);
   5500 }
   5501 
   5502 
   5503 Local<External> v8::External::New(void* value) {
   5504   return v8::External::New(Isolate::GetCurrent(), value);
   5505 }
   5506 
   5507 
   5508 void* External::Value() const {
   5509   return ExternalValue(*Utils::OpenHandle(this));
   5510 }
   5511 
   5512 
   5513 Local<String> v8::String::Empty() {
   5514   i::Isolate* isolate = i::Isolate::Current();
   5515   if (!EnsureInitializedForIsolate(isolate, "v8::String::Empty()")) {
   5516     return v8::Local<String>();
   5517   }
   5518   LOG_API(isolate, "String::Empty()");
   5519   return Utils::ToLocal(isolate->factory()->empty_string());
   5520 }
   5521 
   5522 
   5523 // anonymous namespace for string creation helper functions
   5524 namespace {
   5525 
   5526 inline int StringLength(const char* string) {
   5527   return i::StrLength(string);
   5528 }
   5529 
   5530 
   5531 inline int StringLength(const uint8_t* string) {
   5532   return i::StrLength(reinterpret_cast<const char*>(string));
   5533 }
   5534 
   5535 
   5536 inline int StringLength(const uint16_t* string) {
   5537   int length = 0;
   5538   while (string[length] != '\0')
   5539     length++;
   5540   return length;
   5541 }
   5542 
   5543 
   5544 inline i::Handle<i::String> NewString(i::Factory* factory,
   5545                                       String::NewStringType type,
   5546                                       i::Vector<const char> string) {
   5547   if (type ==String::kInternalizedString) {
   5548     return factory->InternalizeUtf8String(string);
   5549   }
   5550   return factory->NewStringFromUtf8(string);
   5551 }
   5552 
   5553 
   5554 inline i::Handle<i::String> NewString(i::Factory* factory,
   5555                                       String::NewStringType type,
   5556                                       i::Vector<const uint8_t> string) {
   5557   if (type == String::kInternalizedString) {
   5558     return factory->InternalizeOneByteString(string);
   5559   }
   5560   return factory->NewStringFromOneByte(string);
   5561 }
   5562 
   5563 
   5564 inline i::Handle<i::String> NewString(i::Factory* factory,
   5565                                       String::NewStringType type,
   5566                                       i::Vector<const uint16_t> string) {
   5567   if (type == String::kInternalizedString) {
   5568     return factory->InternalizeTwoByteString(string);
   5569   }
   5570   return factory->NewStringFromTwoByte(string);
   5571 }
   5572 
   5573 
   5574 template<typename Char>
   5575 inline Local<String> NewString(Isolate* v8_isolate,
   5576                                const char* location,
   5577                                const char* env,
   5578                                const Char* data,
   5579                                String::NewStringType type,
   5580                                int length) {
   5581   i::Isolate* isolate = reinterpret_cast<internal::Isolate*>(v8_isolate);
   5582   EnsureInitializedForIsolate(isolate, location);
   5583   LOG_API(isolate, env);
   5584   if (length == 0 && type != String::kUndetectableString) {
   5585     return String::Empty();
   5586   }
   5587   ENTER_V8(isolate);
   5588   if (length == -1) length = StringLength(data);
   5589   i::Handle<i::String> result = NewString(
   5590       isolate->factory(), type, i::Vector<const Char>(data, length));
   5591   if (type == String::kUndetectableString) {
   5592     result->MarkAsUndetectable();
   5593   }
   5594   return Utils::ToLocal(result);
   5595 }
   5596 
   5597 }  // anonymous namespace
   5598 
   5599 
   5600 Local<String> String::NewFromUtf8(Isolate* isolate,
   5601                                   const char* data,
   5602                                   NewStringType type,
   5603                                   int length) {
   5604   return NewString(isolate,
   5605                    "v8::String::NewFromUtf8()",
   5606                    "String::NewFromUtf8",
   5607                    data,
   5608                    type,
   5609                    length);
   5610 }
   5611 
   5612 
   5613 Local<String> String::NewFromOneByte(Isolate* isolate,
   5614                                      const uint8_t* data,
   5615                                      NewStringType type,
   5616                                      int length) {
   5617   return NewString(isolate,
   5618                    "v8::String::NewFromOneByte()",
   5619                    "String::NewFromOneByte",
   5620                    data,
   5621                    type,
   5622                    length);
   5623 }
   5624 
   5625 
   5626 Local<String> String::NewFromTwoByte(Isolate* isolate,
   5627                                      const uint16_t* data,
   5628                                      NewStringType type,
   5629                                      int length) {
   5630   return NewString(isolate,
   5631                    "v8::String::NewFromTwoByte()",
   5632                    "String::NewFromTwoByte",
   5633                    data,
   5634                    type,
   5635                    length);
   5636 }
   5637 
   5638 
   5639 Local<String> v8::String::Concat(Handle<String> left, Handle<String> right) {
   5640   i::Handle<i::String> left_string = Utils::OpenHandle(*left);
   5641   i::Isolate* isolate = left_string->GetIsolate();
   5642   EnsureInitializedForIsolate(isolate, "v8::String::New()");
   5643   LOG_API(isolate, "String::New(char)");
   5644   ENTER_V8(isolate);
   5645   i::Handle<i::String> right_string = Utils::OpenHandle(*right);
   5646   i::Handle<i::String> result = isolate->factory()->NewConsString(left_string,
   5647                                                                   right_string);
   5648   return Utils::ToLocal(result);
   5649 }
   5650 
   5651 
   5652 i::Handle<i::String> NewExternalStringHandle(i::Isolate* isolate,
   5653       v8::String::ExternalStringResource* resource) {
   5654   i::Handle<i::String> result =
   5655       isolate->factory()->NewExternalStringFromTwoByte(resource);
   5656   return result;
   5657 }
   5658 
   5659 
   5660 i::Handle<i::String> NewExternalAsciiStringHandle(i::Isolate* isolate,
   5661       v8::String::ExternalAsciiStringResource* resource) {
   5662   i::Handle<i::String> result =
   5663       isolate->factory()->NewExternalStringFromAscii(resource);
   5664   return result;
   5665 }
   5666 
   5667 
   5668 bool RedirectToExternalString(i::Isolate* isolate,
   5669                               i::Handle<i::String> parent,
   5670                               i::Handle<i::String> external) {
   5671   if (parent->IsConsString()) {
   5672     i::Handle<i::ConsString> cons = i::Handle<i::ConsString>::cast(parent);
   5673     cons->set_first(*external);
   5674     cons->set_second(isolate->heap()->empty_string());
   5675   } else {
   5676     ASSERT(parent->IsSlicedString());
   5677     i::Handle<i::SlicedString> slice = i::Handle<i::SlicedString>::cast(parent);
   5678     slice->set_parent(*external);
   5679     slice->set_offset(0);
   5680   }
   5681   return true;
   5682 }
   5683 
   5684 
   5685 Local<String> v8::String::NewExternal(
   5686       Isolate* isolate,
   5687       v8::String::ExternalStringResource* resource) {
   5688   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5689   EnsureInitializedForIsolate(i_isolate, "v8::String::NewExternal()");
   5690   LOG_API(i_isolate, "String::NewExternal");
   5691   ENTER_V8(i_isolate);
   5692   CHECK(resource && resource->data());
   5693   i::Handle<i::String> result = NewExternalStringHandle(i_isolate, resource);
   5694   i_isolate->heap()->external_string_table()->AddString(*result);
   5695   return Utils::ToLocal(result);
   5696 }
   5697 
   5698 
   5699 Local<String> v8::String::NewExternal(
   5700       v8::String::ExternalStringResource* resource) {
   5701   return NewExternal(Isolate::GetCurrent(), resource);
   5702 }
   5703 
   5704 
   5705 bool v8::String::MakeExternal(v8::String::ExternalStringResource* resource) {
   5706   i::Handle<i::String> obj = Utils::OpenHandle(this);
   5707   i::Isolate* isolate = obj->GetIsolate();
   5708   if (i::StringShape(*obj).IsExternalTwoByte()) {
   5709     return false;  // Already an external string.
   5710   }
   5711   ENTER_V8(isolate);
   5712   if (isolate->string_tracker()->IsFreshUnusedString(obj)) {
   5713     return false;
   5714   }
   5715   if (isolate->heap()->IsInGCPostProcessing()) {
   5716     return false;
   5717   }
   5718   CHECK(resource && resource->data());
   5719 
   5720   bool result;
   5721   i::Handle<i::String> external;
   5722   if (isolate->heap()->old_pointer_space()->Contains(*obj)) {
   5723     // We do not allow external strings in the old pointer space.  Instead of
   5724     // converting the string in-place, we keep the cons/sliced string and
   5725     // point it to a newly-allocated external string.
   5726     external = NewExternalStringHandle(isolate, resource);
   5727     result = RedirectToExternalString(isolate, obj, external);
   5728   } else {
   5729     result = obj->MakeExternal(resource);
   5730     external = obj;
   5731   }
   5732 
   5733   ASSERT(external->IsExternalString());
   5734   if (result && !external->IsInternalizedString()) {
   5735     isolate->heap()->external_string_table()->AddString(*external);
   5736   }
   5737   return result;
   5738 }
   5739 
   5740 
   5741 Local<String> v8::String::NewExternal(
   5742       Isolate* isolate,
   5743       v8::String::ExternalAsciiStringResource* resource) {
   5744   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5745   EnsureInitializedForIsolate(i_isolate, "v8::String::NewExternal()");
   5746   LOG_API(i_isolate, "String::NewExternal");
   5747   ENTER_V8(i_isolate);
   5748   CHECK(resource && resource->data());
   5749   i::Handle<i::String> result =
   5750       NewExternalAsciiStringHandle(i_isolate, resource);
   5751   i_isolate->heap()->external_string_table()->AddString(*result);
   5752   return Utils::ToLocal(result);
   5753 }
   5754 
   5755 
   5756 Local<String> v8::String::NewExternal(
   5757       v8::String::ExternalAsciiStringResource* resource) {
   5758   return NewExternal(Isolate::GetCurrent(), resource);
   5759 }
   5760 
   5761 
   5762 bool v8::String::MakeExternal(
   5763     v8::String::ExternalAsciiStringResource* resource) {
   5764   i::Handle<i::String> obj = Utils::OpenHandle(this);
   5765   i::Isolate* isolate = obj->GetIsolate();
   5766   if (i::StringShape(*obj).IsExternalTwoByte()) {
   5767     return false;  // Already an external string.
   5768   }
   5769   ENTER_V8(isolate);
   5770   if (isolate->string_tracker()->IsFreshUnusedString(obj)) {
   5771     return false;
   5772   }
   5773   if (isolate->heap()->IsInGCPostProcessing()) {
   5774     return false;
   5775   }
   5776   CHECK(resource && resource->data());
   5777 
   5778   bool result;
   5779   i::Handle<i::String> external;
   5780   if (isolate->heap()->old_pointer_space()->Contains(*obj)) {
   5781     // We do not allow external strings in the old pointer space.  Instead of
   5782     // converting the string in-place, we keep the cons/sliced string and
   5783     // point it to a newly-allocated external string.
   5784     external = NewExternalAsciiStringHandle(isolate, resource);
   5785     result = RedirectToExternalString(isolate, obj, external);
   5786   } else {
   5787     result = obj->MakeExternal(resource);
   5788     external = obj;
   5789   }
   5790 
   5791   ASSERT(external->IsExternalString());
   5792   if (result && !external->IsInternalizedString()) {
   5793     isolate->heap()->external_string_table()->AddString(*external);
   5794   }
   5795   return result;
   5796 }
   5797 
   5798 
   5799 bool v8::String::CanMakeExternal() {
   5800   if (!internal::FLAG_clever_optimizations) return false;
   5801   i::Handle<i::String> obj = Utils::OpenHandle(this);
   5802   i::Isolate* isolate = obj->GetIsolate();
   5803 
   5804   // TODO(yangguo): Externalizing sliced/cons strings allocates.
   5805   // This rule can be removed when all code that can
   5806   // trigger an access check is handlified and therefore GC safe.
   5807   if (isolate->heap()->old_pointer_space()->Contains(*obj)) return false;
   5808 
   5809   if (isolate->string_tracker()->IsFreshUnusedString(obj)) return false;
   5810   int size = obj->Size();  // Byte size of the original string.
   5811   if (size < i::ExternalString::kShortSize) return false;
   5812   i::StringShape shape(*obj);
   5813   return !shape.IsExternal();
   5814 }
   5815 
   5816 
   5817 Local<v8::Object> v8::Object::New(Isolate* isolate) {
   5818   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5819   EnsureInitializedForIsolate(i_isolate, "v8::Object::New()");
   5820   LOG_API(i_isolate, "Object::New");
   5821   ENTER_V8(i_isolate);
   5822   i::Handle<i::JSObject> obj =
   5823       i_isolate->factory()->NewJSObject(i_isolate->object_function());
   5824   return Utils::ToLocal(obj);
   5825 }
   5826 
   5827 
   5828 Local<v8::Object> v8::Object::New() {
   5829   return New(Isolate::GetCurrent());
   5830 }
   5831 
   5832 
   5833 Local<v8::Value> v8::NumberObject::New(Isolate* isolate, double value) {
   5834   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5835   EnsureInitializedForIsolate(i_isolate, "v8::NumberObject::New()");
   5836   LOG_API(i_isolate, "NumberObject::New");
   5837   ENTER_V8(i_isolate);
   5838   i::Handle<i::Object> number = i_isolate->factory()->NewNumber(value);
   5839   i::Handle<i::Object> obj = i_isolate->factory()->ToObject(number);
   5840   return Utils::ToLocal(obj);
   5841 }
   5842 
   5843 
   5844 Local<v8::Value> v8::NumberObject::New(double value) {
   5845   return New(Isolate::GetCurrent(), value);
   5846 }
   5847 
   5848 
   5849 double v8::NumberObject::ValueOf() const {
   5850   i::Isolate* isolate = i::Isolate::Current();
   5851   LOG_API(isolate, "NumberObject::NumberValue");
   5852   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5853   i::Handle<i::JSValue> jsvalue = i::Handle<i::JSValue>::cast(obj);
   5854   return jsvalue->value()->Number();
   5855 }
   5856 
   5857 
   5858 Local<v8::Value> v8::BooleanObject::New(bool value) {
   5859   i::Isolate* isolate = i::Isolate::Current();
   5860   EnsureInitializedForIsolate(isolate, "v8::BooleanObject::New()");
   5861   LOG_API(isolate, "BooleanObject::New");
   5862   ENTER_V8(isolate);
   5863   i::Handle<i::Object> boolean(value
   5864                                ? isolate->heap()->true_value()
   5865                                : isolate->heap()->false_value(),
   5866                                isolate);
   5867   i::Handle<i::Object> obj = isolate->factory()->ToObject(boolean);
   5868   return Utils::ToLocal(obj);
   5869 }
   5870 
   5871 
   5872 bool v8::BooleanObject::ValueOf() const {
   5873   i::Isolate* isolate = i::Isolate::Current();
   5874   LOG_API(isolate, "BooleanObject::BooleanValue");
   5875   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5876   i::Handle<i::JSValue> jsvalue = i::Handle<i::JSValue>::cast(obj);
   5877   return jsvalue->value()->IsTrue();
   5878 }
   5879 
   5880 
   5881 Local<v8::Value> v8::StringObject::New(Handle<String> value) {
   5882   i::Isolate* isolate = i::Isolate::Current();
   5883   EnsureInitializedForIsolate(isolate, "v8::StringObject::New()");
   5884   LOG_API(isolate, "StringObject::New");
   5885   ENTER_V8(isolate);
   5886   i::Handle<i::Object> obj =
   5887       isolate->factory()->ToObject(Utils::OpenHandle(*value));
   5888   return Utils::ToLocal(obj);
   5889 }
   5890 
   5891 
   5892 Local<v8::String> v8::StringObject::ValueOf() const {
   5893   i::Isolate* isolate = i::Isolate::Current();
   5894   LOG_API(isolate, "StringObject::StringValue");
   5895   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5896   i::Handle<i::JSValue> jsvalue = i::Handle<i::JSValue>::cast(obj);
   5897   return Utils::ToLocal(
   5898       i::Handle<i::String>(i::String::cast(jsvalue->value())));
   5899 }
   5900 
   5901 
   5902 Local<v8::Value> v8::SymbolObject::New(Isolate* isolate, Handle<Symbol> value) {
   5903   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5904   EnsureInitializedForIsolate(i_isolate, "v8::SymbolObject::New()");
   5905   LOG_API(i_isolate, "SymbolObject::New");
   5906   ENTER_V8(i_isolate);
   5907   i::Handle<i::Object> obj =
   5908       i_isolate->factory()->ToObject(Utils::OpenHandle(*value));
   5909   return Utils::ToLocal(obj);
   5910 }
   5911 
   5912 
   5913 Local<v8::Symbol> v8::SymbolObject::ValueOf() const {
   5914   i::Isolate* isolate = i::Isolate::Current();
   5915   LOG_API(isolate, "SymbolObject::SymbolValue");
   5916   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5917   i::Handle<i::JSValue> jsvalue = i::Handle<i::JSValue>::cast(obj);
   5918   return Utils::ToLocal(
   5919       i::Handle<i::Symbol>(i::Symbol::cast(jsvalue->value())));
   5920 }
   5921 
   5922 
   5923 Local<v8::Value> v8::Date::New(Isolate* isolate, double time) {
   5924   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5925   EnsureInitializedForIsolate(i_isolate, "v8::Date::New()");
   5926   LOG_API(i_isolate, "Date::New");
   5927   if (std::isnan(time)) {
   5928     // Introduce only canonical NaN value into the VM, to avoid signaling NaNs.
   5929     time = i::OS::nan_value();
   5930   }
   5931   ENTER_V8(i_isolate);
   5932   EXCEPTION_PREAMBLE(i_isolate);
   5933   i::Handle<i::Object> obj =
   5934       i::Execution::NewDate(i_isolate, time, &has_pending_exception);
   5935   EXCEPTION_BAILOUT_CHECK(i_isolate, Local<v8::Value>());
   5936   return Utils::ToLocal(obj);
   5937 }
   5938 
   5939 
   5940 Local<v8::Value> v8::Date::New(double time) {
   5941   return New(Isolate::GetCurrent(), time);
   5942 }
   5943 
   5944 
   5945 double v8::Date::ValueOf() const {
   5946   i::Isolate* isolate = i::Isolate::Current();
   5947   LOG_API(isolate, "Date::NumberValue");
   5948   i::Handle<i::Object> obj = Utils::OpenHandle(this);
   5949   i::Handle<i::JSDate> jsdate = i::Handle<i::JSDate>::cast(obj);
   5950   return jsdate->value()->Number();
   5951 }
   5952 
   5953 
   5954 void v8::Date::DateTimeConfigurationChangeNotification(Isolate* isolate) {
   5955   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   5956   ON_BAILOUT(i_isolate, "v8::Date::DateTimeConfigurationChangeNotification()",
   5957              return);
   5958   LOG_API(i_isolate, "Date::DateTimeConfigurationChangeNotification");
   5959   ENTER_V8(i_isolate);
   5960 
   5961   i_isolate->date_cache()->ResetDateCache();
   5962 
   5963   i::HandleScope scope(i_isolate);
   5964   // Get the function ResetDateCache (defined in date.js).
   5965   i::Handle<i::String> func_name_str =
   5966       i_isolate->factory()->InternalizeOneByteString(
   5967           STATIC_ASCII_VECTOR("ResetDateCache"));
   5968   i::MaybeObject* result =
   5969       i_isolate->js_builtins_object()->GetProperty(*func_name_str);
   5970   i::Object* object_func;
   5971   if (!result->ToObject(&object_func)) {
   5972     return;
   5973   }
   5974 
   5975   if (object_func->IsJSFunction()) {
   5976     i::Handle<i::JSFunction> func =
   5977         i::Handle<i::JSFunction>(i::JSFunction::cast(object_func));
   5978 
   5979     // Call ResetDateCache(0 but expect no exceptions:
   5980     bool caught_exception = false;
   5981     i::Execution::TryCall(func,
   5982                           i_isolate->js_builtins_object(),
   5983                           0,
   5984                           NULL,
   5985                           &caught_exception);
   5986   }
   5987 }
   5988 
   5989 
   5990 void v8::Date::DateTimeConfigurationChangeNotification() {
   5991   DateTimeConfigurationChangeNotification(Isolate::GetCurrent());
   5992 }
   5993 
   5994 
   5995 static i::Handle<i::String> RegExpFlagsToString(RegExp::Flags flags) {
   5996   i::Isolate* isolate = i::Isolate::Current();
   5997   uint8_t flags_buf[3];
   5998   int num_flags = 0;
   5999   if ((flags & RegExp::kGlobal) != 0) flags_buf[num_flags++] = 'g';
   6000   if ((flags & RegExp::kMultiline) != 0) flags_buf[num_flags++] = 'm';
   6001   if ((flags & RegExp::kIgnoreCase) != 0) flags_buf[num_flags++] = 'i';
   6002   ASSERT(num_flags <= static_cast<int>(ARRAY_SIZE(flags_buf)));
   6003   return isolate->factory()->InternalizeOneByteString(
   6004       i::Vector<const uint8_t>(flags_buf, num_flags));
   6005 }
   6006 
   6007 
   6008 Local<v8::RegExp> v8::RegExp::New(Handle<String> pattern,
   6009                                   Flags flags) {
   6010   i::Isolate* isolate = Utils::OpenHandle(*pattern)->GetIsolate();
   6011   EnsureInitializedForIsolate(isolate, "v8::RegExp::New()");
   6012   LOG_API(isolate, "RegExp::New");
   6013   ENTER_V8(isolate);
   6014   EXCEPTION_PREAMBLE(isolate);
   6015   i::Handle<i::JSRegExp> obj = i::Execution::NewJSRegExp(
   6016       Utils::OpenHandle(*pattern),
   6017       RegExpFlagsToString(flags),
   6018       &has_pending_exception);
   6019   EXCEPTION_BAILOUT_CHECK(isolate, Local<v8::RegExp>());
   6020   return Utils::ToLocal(i::Handle<i::JSRegExp>::cast(obj));
   6021 }
   6022 
   6023 
   6024 Local<v8::String> v8::RegExp::GetSource() const {
   6025   i::Handle<i::JSRegExp> obj = Utils::OpenHandle(this);
   6026   return Utils::ToLocal(i::Handle<i::String>(obj->Pattern()));
   6027 }
   6028 
   6029 
   6030 // Assert that the static flags cast in GetFlags is valid.
   6031 #define REGEXP_FLAG_ASSERT_EQ(api_flag, internal_flag)        \
   6032   STATIC_ASSERT(static_cast<int>(v8::RegExp::api_flag) ==     \
   6033                 static_cast<int>(i::JSRegExp::internal_flag))
   6034 REGEXP_FLAG_ASSERT_EQ(kNone, NONE);
   6035 REGEXP_FLAG_ASSERT_EQ(kGlobal, GLOBAL);
   6036 REGEXP_FLAG_ASSERT_EQ(kIgnoreCase, IGNORE_CASE);
   6037 REGEXP_FLAG_ASSERT_EQ(kMultiline, MULTILINE);
   6038 #undef REGEXP_FLAG_ASSERT_EQ
   6039 
   6040 v8::RegExp::Flags v8::RegExp::GetFlags() const {
   6041   i::Handle<i::JSRegExp> obj = Utils::OpenHandle(this);
   6042   return static_cast<RegExp::Flags>(obj->GetFlags().value());
   6043 }
   6044 
   6045 
   6046 Local<v8::Array> v8::Array::New(Isolate* isolate, int length) {
   6047   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6048   EnsureInitializedForIsolate(i_isolate, "v8::Array::New()");
   6049   LOG_API(i_isolate, "Array::New");
   6050   ENTER_V8(i_isolate);
   6051   int real_length = length > 0 ? length : 0;
   6052   i::Handle<i::JSArray> obj = i_isolate->factory()->NewJSArray(real_length);
   6053   i::Handle<i::Object> length_obj =
   6054       i_isolate->factory()->NewNumberFromInt(real_length);
   6055   obj->set_length(*length_obj);
   6056   return Utils::ToLocal(obj);
   6057 }
   6058 
   6059 
   6060 Local<v8::Array> v8::Array::New(int length) {
   6061   return New(Isolate::GetCurrent(), length);
   6062 }
   6063 
   6064 
   6065 uint32_t v8::Array::Length() const {
   6066   i::Handle<i::JSArray> obj = Utils::OpenHandle(this);
   6067   i::Object* length = obj->length();
   6068   if (length->IsSmi()) {
   6069     return i::Smi::cast(length)->value();
   6070   } else {
   6071     return static_cast<uint32_t>(length->Number());
   6072   }
   6073 }
   6074 
   6075 
   6076 Local<Object> Array::CloneElementAt(uint32_t index) {
   6077   i::Isolate* isolate = Utils::OpenHandle(this)->GetIsolate();
   6078   ON_BAILOUT(isolate, "v8::Array::CloneElementAt()", return Local<Object>());
   6079   i::Handle<i::JSObject> self = Utils::OpenHandle(this);
   6080   if (!self->HasFastObjectElements()) {
   6081     return Local<Object>();
   6082   }
   6083   i::FixedArray* elms = i::FixedArray::cast(self->elements());
   6084   i::Object* paragon = elms->get(index);
   6085   if (!paragon->IsJSObject()) {
   6086     return Local<Object>();
   6087   }
   6088   i::Handle<i::JSObject> paragon_handle(i::JSObject::cast(paragon));
   6089   EXCEPTION_PREAMBLE(isolate);
   6090   ENTER_V8(isolate);
   6091   i::Handle<i::JSObject> result = i::JSObject::Copy(paragon_handle);
   6092   has_pending_exception = result.is_null();
   6093   EXCEPTION_BAILOUT_CHECK(isolate, Local<Object>());
   6094   return Utils::ToLocal(result);
   6095 }
   6096 
   6097 
   6098 bool v8::ArrayBuffer::IsExternal() const {
   6099   return Utils::OpenHandle(this)->is_external();
   6100 }
   6101 
   6102 
   6103 v8::ArrayBuffer::Contents v8::ArrayBuffer::Externalize() {
   6104   i::Handle<i::JSArrayBuffer> obj = Utils::OpenHandle(this);
   6105   ApiCheck(!obj->is_external(),
   6106             "v8::ArrayBuffer::Externalize",
   6107             "ArrayBuffer already externalized");
   6108   obj->set_is_external(true);
   6109   size_t byte_length = static_cast<size_t>(obj->byte_length()->Number());
   6110   Contents contents;
   6111   contents.data_ = obj->backing_store();
   6112   contents.byte_length_ = byte_length;
   6113   return contents;
   6114 }
   6115 
   6116 
   6117 void v8::ArrayBuffer::Neuter() {
   6118   i::Handle<i::JSArrayBuffer> obj = Utils::OpenHandle(this);
   6119   i::Isolate* isolate = obj->GetIsolate();
   6120   ApiCheck(obj->is_external(),
   6121            "v8::ArrayBuffer::Neuter",
   6122            "Only externalized ArrayBuffers can be neutered");
   6123   LOG_API(obj->GetIsolate(), "v8::ArrayBuffer::Neuter()");
   6124   ENTER_V8(isolate);
   6125 
   6126   for (i::Handle<i::Object> view_obj(obj->weak_first_view(), isolate);
   6127        !view_obj->IsUndefined();) {
   6128     i::Handle<i::JSArrayBufferView> view(i::JSArrayBufferView::cast(*view_obj));
   6129     if (view->IsJSTypedArray()) {
   6130       i::JSTypedArray::cast(*view)->Neuter();
   6131     } else if (view->IsJSDataView()) {
   6132       i::JSDataView::cast(*view)->Neuter();
   6133     } else {
   6134       UNREACHABLE();
   6135     }
   6136     view_obj = i::handle(view->weak_next(), isolate);
   6137   }
   6138   obj->Neuter();
   6139 }
   6140 
   6141 
   6142 size_t v8::ArrayBuffer::ByteLength() const {
   6143   i::Handle<i::JSArrayBuffer> obj = Utils::OpenHandle(this);
   6144   return static_cast<size_t>(obj->byte_length()->Number());
   6145 }
   6146 
   6147 
   6148 Local<ArrayBuffer> v8::ArrayBuffer::New(Isolate* isolate, size_t byte_length) {
   6149   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6150   EnsureInitializedForIsolate(i_isolate, "v8::ArrayBuffer::New(size_t)");
   6151   LOG_API(i_isolate, "v8::ArrayBuffer::New(size_t)");
   6152   ENTER_V8(i_isolate);
   6153   i::Handle<i::JSArrayBuffer> obj =
   6154       i_isolate->factory()->NewJSArrayBuffer();
   6155   i::Runtime::SetupArrayBufferAllocatingData(i_isolate, obj, byte_length);
   6156   return Utils::ToLocal(obj);
   6157 }
   6158 
   6159 
   6160 Local<ArrayBuffer> v8::ArrayBuffer::New(size_t byte_length) {
   6161   return New(Isolate::GetCurrent(), byte_length);
   6162 }
   6163 
   6164 
   6165 Local<ArrayBuffer> v8::ArrayBuffer::New(Isolate* isolate, void* data,
   6166                                         size_t byte_length) {
   6167   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6168   EnsureInitializedForIsolate(i_isolate, "v8::ArrayBuffer::New(void*, size_t)");
   6169   LOG_API(i_isolate, "v8::ArrayBuffer::New(void*, size_t)");
   6170   ENTER_V8(i_isolate);
   6171   i::Handle<i::JSArrayBuffer> obj =
   6172       i_isolate->factory()->NewJSArrayBuffer();
   6173   i::Runtime::SetupArrayBuffer(i_isolate, obj, true, data, byte_length);
   6174   return Utils::ToLocal(obj);
   6175 }
   6176 
   6177 
   6178 Local<ArrayBuffer> v8::ArrayBuffer::New(void* data, size_t byte_length) {
   6179   return New(Isolate::GetCurrent(), data, byte_length);
   6180 }
   6181 
   6182 
   6183 Local<ArrayBuffer> v8::ArrayBufferView::Buffer() {
   6184   i::Handle<i::JSArrayBufferView> obj = Utils::OpenHandle(this);
   6185   ASSERT(obj->buffer()->IsJSArrayBuffer());
   6186   i::Handle<i::JSArrayBuffer> buffer(i::JSArrayBuffer::cast(obj->buffer()));
   6187   return Utils::ToLocal(buffer);
   6188 }
   6189 
   6190 
   6191 size_t v8::ArrayBufferView::ByteOffset() {
   6192   i::Handle<i::JSArrayBufferView> obj = Utils::OpenHandle(this);
   6193   return static_cast<size_t>(obj->byte_offset()->Number());
   6194 }
   6195 
   6196 
   6197 size_t v8::ArrayBufferView::ByteLength() {
   6198   i::Handle<i::JSArrayBufferView> obj = Utils::OpenHandle(this);
   6199   return static_cast<size_t>(obj->byte_length()->Number());
   6200 }
   6201 
   6202 
   6203 size_t v8::TypedArray::Length() {
   6204   i::Handle<i::JSTypedArray> obj = Utils::OpenHandle(this);
   6205   return static_cast<size_t>(obj->length()->Number());
   6206 }
   6207 
   6208 
   6209 static inline void SetupArrayBufferView(
   6210     i::Isolate* isolate,
   6211     i::Handle<i::JSArrayBufferView> obj,
   6212     i::Handle<i::JSArrayBuffer> buffer,
   6213     size_t byte_offset,
   6214     size_t byte_length) {
   6215   ASSERT(byte_offset + byte_length <=
   6216       static_cast<size_t>(buffer->byte_length()->Number()));
   6217 
   6218   obj->set_buffer(*buffer);
   6219 
   6220   obj->set_weak_next(buffer->weak_first_view());
   6221   buffer->set_weak_first_view(*obj);
   6222 
   6223   i::Handle<i::Object> byte_offset_object =
   6224     isolate->factory()->NewNumberFromSize(byte_offset);
   6225   obj->set_byte_offset(*byte_offset_object);
   6226 
   6227   i::Handle<i::Object> byte_length_object =
   6228     isolate->factory()->NewNumberFromSize(byte_length);
   6229   obj->set_byte_length(*byte_length_object);
   6230 }
   6231 
   6232 template<typename ElementType,
   6233          ExternalArrayType array_type,
   6234          i::ElementsKind elements_kind>
   6235 i::Handle<i::JSTypedArray> NewTypedArray(
   6236     i::Isolate* isolate,
   6237     Handle<ArrayBuffer> array_buffer, size_t byte_offset, size_t length) {
   6238   i::Handle<i::JSTypedArray> obj =
   6239       isolate->factory()->NewJSTypedArray(array_type);
   6240   i::Handle<i::JSArrayBuffer> buffer = Utils::OpenHandle(*array_buffer);
   6241 
   6242   ASSERT(byte_offset % sizeof(ElementType) == 0);
   6243 
   6244   CHECK(length <= (std::numeric_limits<size_t>::max() / sizeof(ElementType)));
   6245   size_t byte_length = length * sizeof(ElementType);
   6246   SetupArrayBufferView(
   6247       isolate, obj, buffer, byte_offset, byte_length);
   6248 
   6249   i::Handle<i::Object> length_object =
   6250     isolate->factory()->NewNumberFromSize(length);
   6251   obj->set_length(*length_object);
   6252 
   6253   i::Handle<i::ExternalArray> elements =
   6254       isolate->factory()->NewExternalArray(
   6255           static_cast<int>(length), array_type,
   6256           static_cast<uint8_t*>(buffer->backing_store()) + byte_offset);
   6257   obj->set_elements(*elements);
   6258   return obj;
   6259 }
   6260 
   6261 
   6262 #define TYPED_ARRAY_NEW(TypedArray, element_type, array_type, elements_kind) \
   6263   Local<TypedArray> TypedArray::New(Handle<ArrayBuffer> array_buffer,        \
   6264                                     size_t byte_offset, size_t length) {     \
   6265     i::Isolate* isolate = i::Isolate::Current();                             \
   6266     EnsureInitializedForIsolate(isolate,                                     \
   6267         "v8::" #TypedArray "::New(Handle<ArrayBuffer>, size_t, size_t)");    \
   6268     LOG_API(isolate,                                                         \
   6269         "v8::" #TypedArray "::New(Handle<ArrayBuffer>, size_t, size_t)");    \
   6270     ENTER_V8(isolate);                                                       \
   6271     i::Handle<i::JSTypedArray> obj =                                         \
   6272         NewTypedArray<element_type, array_type, elements_kind>(              \
   6273             isolate, array_buffer, byte_offset, length);                     \
   6274     return Utils::ToLocal##TypedArray(obj);                                  \
   6275   }
   6276 
   6277 
   6278 TYPED_ARRAY_NEW(Uint8Array, uint8_t, kExternalUnsignedByteArray,
   6279                 i::EXTERNAL_UNSIGNED_BYTE_ELEMENTS)
   6280 TYPED_ARRAY_NEW(Uint8ClampedArray, uint8_t, kExternalPixelArray,
   6281                 i::EXTERNAL_PIXEL_ELEMENTS)
   6282 TYPED_ARRAY_NEW(Int8Array, int8_t, kExternalByteArray,
   6283                 i::EXTERNAL_BYTE_ELEMENTS)
   6284 TYPED_ARRAY_NEW(Uint16Array, uint16_t, kExternalUnsignedShortArray,
   6285                 i::EXTERNAL_UNSIGNED_SHORT_ELEMENTS)
   6286 TYPED_ARRAY_NEW(Int16Array, int16_t, kExternalShortArray,
   6287                 i::EXTERNAL_SHORT_ELEMENTS)
   6288 TYPED_ARRAY_NEW(Uint32Array, uint32_t, kExternalUnsignedIntArray,
   6289                 i::EXTERNAL_UNSIGNED_INT_ELEMENTS)
   6290 TYPED_ARRAY_NEW(Int32Array, int32_t, kExternalIntArray,
   6291                 i::EXTERNAL_INT_ELEMENTS)
   6292 TYPED_ARRAY_NEW(Float32Array, float, kExternalFloatArray,
   6293                 i::EXTERNAL_FLOAT_ELEMENTS)
   6294 TYPED_ARRAY_NEW(Float64Array, double, kExternalDoubleArray,
   6295                 i::EXTERNAL_DOUBLE_ELEMENTS)
   6296 
   6297 #undef TYPED_ARRAY_NEW
   6298 
   6299 Local<DataView> DataView::New(Handle<ArrayBuffer> array_buffer,
   6300                               size_t byte_offset, size_t byte_length) {
   6301   i::Isolate* isolate = i::Isolate::Current();
   6302   EnsureInitializedForIsolate(
   6303       isolate, "v8::DataView::New(void*, size_t, size_t)");
   6304   LOG_API(isolate, "v8::DataView::New(void*, size_t, size_t)");
   6305   ENTER_V8(isolate);
   6306   i::Handle<i::JSDataView> obj = isolate->factory()->NewJSDataView();
   6307   i::Handle<i::JSArrayBuffer> buffer = Utils::OpenHandle(*array_buffer);
   6308   SetupArrayBufferView(
   6309       isolate, obj, buffer, byte_offset, byte_length);
   6310   return Utils::ToLocal(obj);
   6311 }
   6312 
   6313 
   6314 Local<Symbol> v8::Symbol::New(Isolate* isolate, const char* data, int length) {
   6315   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6316   EnsureInitializedForIsolate(i_isolate, "v8::Symbol::New()");
   6317   LOG_API(i_isolate, "Symbol::New()");
   6318   ENTER_V8(i_isolate);
   6319   i::Handle<i::Symbol> result = i_isolate->factory()->NewSymbol();
   6320   if (data != NULL) {
   6321     if (length == -1) length = i::StrLength(data);
   6322     i::Handle<i::String> name = i_isolate->factory()->NewStringFromUtf8(
   6323         i::Vector<const char>(data, length));
   6324     result->set_name(*name);
   6325   }
   6326   return Utils::ToLocal(result);
   6327 }
   6328 
   6329 
   6330 Local<Private> v8::Private::New(
   6331     Isolate* isolate, const char* data, int length) {
   6332   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6333   EnsureInitializedForIsolate(i_isolate, "v8::Private::New()");
   6334   LOG_API(i_isolate, "Private::New()");
   6335   ENTER_V8(i_isolate);
   6336   i::Handle<i::Symbol> symbol = i_isolate->factory()->NewPrivateSymbol();
   6337   if (data != NULL) {
   6338     if (length == -1) length = i::StrLength(data);
   6339     i::Handle<i::String> name = i_isolate->factory()->NewStringFromUtf8(
   6340         i::Vector<const char>(data, length));
   6341     symbol->set_name(*name);
   6342   }
   6343   Local<Symbol> result = Utils::ToLocal(symbol);
   6344   return v8::Handle<Private>(reinterpret_cast<Private*>(*result));
   6345 }
   6346 
   6347 
   6348 Local<Number> v8::Number::New(double value) {
   6349   i::Isolate* isolate = i::Isolate::Current();
   6350   EnsureInitializedForIsolate(isolate, "v8::Number::New()");
   6351   return Number::New(reinterpret_cast<Isolate*>(isolate), value);
   6352 }
   6353 
   6354 
   6355 Local<Number> v8::Number::New(Isolate* isolate, double value) {
   6356   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6357   ASSERT(internal_isolate->IsInitialized());
   6358   if (std::isnan(value)) {
   6359     // Introduce only canonical NaN value into the VM, to avoid signaling NaNs.
   6360     value = i::OS::nan_value();
   6361   }
   6362   ENTER_V8(internal_isolate);
   6363   i::Handle<i::Object> result = internal_isolate->factory()->NewNumber(value);
   6364   return Utils::NumberToLocal(result);
   6365 }
   6366 
   6367 
   6368 Local<Integer> v8::Integer::New(int32_t value) {
   6369   i::Isolate* isolate = i::Isolate::UncheckedCurrent();
   6370   EnsureInitializedForIsolate(isolate, "v8::Integer::New()");
   6371   return v8::Integer::New(reinterpret_cast<Isolate*>(isolate), value);
   6372 }
   6373 
   6374 
   6375 Local<Integer> Integer::NewFromUnsigned(uint32_t value) {
   6376   i::Isolate* isolate = i::Isolate::Current();
   6377   EnsureInitializedForIsolate(isolate, "v8::Integer::NewFromUnsigned()");
   6378   return Integer::NewFromUnsigned(reinterpret_cast<Isolate*>(isolate), value);
   6379 }
   6380 
   6381 
   6382 Local<Integer> v8::Integer::New(int32_t value, Isolate* isolate) {
   6383   return Integer::New(isolate, value);
   6384 }
   6385 
   6386 
   6387 Local<Integer> v8::Integer::NewFromUnsigned(uint32_t value, Isolate* isolate) {
   6388   return Integer::NewFromUnsigned(isolate, value);
   6389 }
   6390 
   6391 
   6392 Local<Integer> v8::Integer::New(Isolate* isolate, int32_t value) {
   6393   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6394   ASSERT(internal_isolate->IsInitialized());
   6395   if (i::Smi::IsValid(value)) {
   6396     return Utils::IntegerToLocal(i::Handle<i::Object>(i::Smi::FromInt(value),
   6397                                                       internal_isolate));
   6398   }
   6399   ENTER_V8(internal_isolate);
   6400   i::Handle<i::Object> result = internal_isolate->factory()->NewNumber(value);
   6401   return Utils::IntegerToLocal(result);
   6402 }
   6403 
   6404 
   6405 Local<Integer> v8::Integer::NewFromUnsigned(Isolate* isolate, uint32_t value) {
   6406   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6407   ASSERT(internal_isolate->IsInitialized());
   6408   bool fits_into_int32_t = (value & (1 << 31)) == 0;
   6409   if (fits_into_int32_t) {
   6410     return Integer::New(static_cast<int32_t>(value), isolate);
   6411   }
   6412   ENTER_V8(internal_isolate);
   6413   i::Handle<i::Object> result = internal_isolate->factory()->NewNumber(value);
   6414   return Utils::IntegerToLocal(result);
   6415 }
   6416 
   6417 
   6418 #ifdef DEBUG
   6419 v8::AssertNoGCScope::AssertNoGCScope(v8::Isolate* isolate) {
   6420   disallow_heap_allocation_ = new i::DisallowHeapAllocation();
   6421 }
   6422 
   6423 
   6424 v8::AssertNoGCScope::~AssertNoGCScope() {
   6425   delete static_cast<i::DisallowHeapAllocation*>(disallow_heap_allocation_);
   6426 }
   6427 #endif
   6428 
   6429 
   6430 void V8::IgnoreOutOfMemoryException() {
   6431   EnterIsolateIfNeeded()->set_ignore_out_of_memory(true);
   6432 }
   6433 
   6434 
   6435 bool V8::AddMessageListener(MessageCallback that, Handle<Value> data) {
   6436   i::Isolate* isolate = i::Isolate::Current();
   6437   EnsureInitializedForIsolate(isolate, "v8::V8::AddMessageListener()");
   6438   ON_BAILOUT(isolate, "v8::V8::AddMessageListener()", return false);
   6439   ENTER_V8(isolate);
   6440   i::HandleScope scope(isolate);
   6441   NeanderArray listeners(isolate->factory()->message_listeners());
   6442   NeanderObject obj(2);
   6443   obj.set(0, *isolate->factory()->NewForeign(FUNCTION_ADDR(that)));
   6444   obj.set(1, data.IsEmpty() ? isolate->heap()->undefined_value()
   6445                             : *Utils::OpenHandle(*data));
   6446   listeners.add(obj.value());
   6447   return true;
   6448 }
   6449 
   6450 
   6451 void V8::RemoveMessageListeners(MessageCallback that) {
   6452   i::Isolate* isolate = i::Isolate::Current();
   6453   EnsureInitializedForIsolate(isolate, "v8::V8::RemoveMessageListener()");
   6454   ON_BAILOUT(isolate, "v8::V8::RemoveMessageListeners()", return);
   6455   ENTER_V8(isolate);
   6456   i::HandleScope scope(isolate);
   6457   NeanderArray listeners(isolate->factory()->message_listeners());
   6458   for (int i = 0; i < listeners.length(); i++) {
   6459     if (listeners.get(i)->IsUndefined()) continue;  // skip deleted ones
   6460 
   6461     NeanderObject listener(i::JSObject::cast(listeners.get(i)));
   6462     i::Handle<i::Foreign> callback_obj(i::Foreign::cast(listener.get(0)));
   6463     if (callback_obj->foreign_address() == FUNCTION_ADDR(that)) {
   6464       listeners.set(i, isolate->heap()->undefined_value());
   6465     }
   6466   }
   6467 }
   6468 
   6469 
   6470 void V8::SetCaptureStackTraceForUncaughtExceptions(
   6471       bool capture,
   6472       int frame_limit,
   6473       StackTrace::StackTraceOptions options) {
   6474   i::Isolate::Current()->SetCaptureStackTraceForUncaughtExceptions(
   6475       capture,
   6476       frame_limit,
   6477       options);
   6478 }
   6479 
   6480 
   6481 void V8::SetCounterFunction(CounterLookupCallback callback) {
   6482   i::Isolate* isolate = EnterIsolateIfNeeded();
   6483   isolate->stats_table()->SetCounterFunction(callback);
   6484 }
   6485 
   6486 
   6487 void V8::SetCreateHistogramFunction(CreateHistogramCallback callback) {
   6488   i::Isolate* isolate = EnterIsolateIfNeeded();
   6489   isolate->stats_table()->SetCreateHistogramFunction(callback);
   6490   isolate->InitializeLoggingAndCounters();
   6491   isolate->counters()->ResetHistograms();
   6492 }
   6493 
   6494 
   6495 void V8::SetAddHistogramSampleFunction(AddHistogramSampleCallback callback) {
   6496   i::Isolate* isolate = EnterIsolateIfNeeded();
   6497   isolate->stats_table()->
   6498       SetAddHistogramSampleFunction(callback);
   6499 }
   6500 
   6501 void V8::SetFailedAccessCheckCallbackFunction(
   6502       FailedAccessCheckCallback callback) {
   6503   i::Isolate* isolate = i::Isolate::Current();
   6504   isolate->SetFailedAccessCheckCallback(callback);
   6505 }
   6506 
   6507 
   6508 int64_t Isolate::AdjustAmountOfExternalAllocatedMemory(
   6509     int64_t change_in_bytes) {
   6510   i::Heap* heap = reinterpret_cast<i::Isolate*>(this)->heap();
   6511   return heap->AdjustAmountOfExternalAllocatedMemory(change_in_bytes);
   6512 }
   6513 
   6514 
   6515 int64_t V8::AdjustAmountOfExternalAllocatedMemory(int64_t change_in_bytes) {
   6516   i::Isolate* isolate = i::Isolate::UncheckedCurrent();
   6517   if (isolate == NULL || !isolate->IsInitialized()) {
   6518     return 0;
   6519   }
   6520   Isolate* isolate_ext = reinterpret_cast<Isolate*>(isolate);
   6521   return isolate_ext->AdjustAmountOfExternalAllocatedMemory(change_in_bytes);
   6522 }
   6523 
   6524 
   6525 HeapProfiler* Isolate::GetHeapProfiler() {
   6526   i::HeapProfiler* heap_profiler =
   6527       reinterpret_cast<i::Isolate*>(this)->heap_profiler();
   6528   return reinterpret_cast<HeapProfiler*>(heap_profiler);
   6529 }
   6530 
   6531 
   6532 CpuProfiler* Isolate::GetCpuProfiler() {
   6533   i::CpuProfiler* cpu_profiler =
   6534       reinterpret_cast<i::Isolate*>(this)->cpu_profiler();
   6535   return reinterpret_cast<CpuProfiler*>(cpu_profiler);
   6536 }
   6537 
   6538 
   6539 bool Isolate::InContext() {
   6540   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6541   return isolate->context() != NULL;
   6542 }
   6543 
   6544 
   6545 v8::Local<v8::Context> Isolate::GetCurrentContext() {
   6546   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6547   i::Context* context = isolate->context();
   6548   if (context == NULL) return Local<Context>();
   6549   i::Context* native_context = context->global_object()->native_context();
   6550   if (native_context == NULL) return Local<Context>();
   6551   return Utils::ToLocal(i::Handle<i::Context>(native_context));
   6552 }
   6553 
   6554 
   6555 v8::Local<v8::Context> Isolate::GetCallingContext() {
   6556   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6557   i::Handle<i::Object> calling = isolate->GetCallingNativeContext();
   6558   if (calling.is_null()) return Local<Context>();
   6559   return Utils::ToLocal(i::Handle<i::Context>::cast(calling));
   6560 }
   6561 
   6562 
   6563 v8::Local<v8::Context> Isolate::GetEnteredContext() {
   6564   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6565   i::Handle<i::Object> last =
   6566       isolate->handle_scope_implementer()->LastEnteredContext();
   6567   if (last.is_null()) return Local<Context>();
   6568   return Utils::ToLocal(i::Handle<i::Context>::cast(last));
   6569 }
   6570 
   6571 
   6572 v8::Local<Value> Isolate::ThrowException(v8::Local<v8::Value> value) {
   6573   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6574   ENTER_V8(isolate);
   6575   // If we're passed an empty handle, we throw an undefined exception
   6576   // to deal more gracefully with out of memory situations.
   6577   if (value.IsEmpty()) {
   6578     isolate->ScheduleThrow(isolate->heap()->undefined_value());
   6579   } else {
   6580     isolate->ScheduleThrow(*Utils::OpenHandle(*value));
   6581   }
   6582   return v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   6583 }
   6584 
   6585 
   6586 void Isolate::SetObjectGroupId(internal::Object** object, UniqueId id) {
   6587   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(this);
   6588   internal_isolate->global_handles()->SetObjectGroupId(
   6589       v8::internal::Handle<v8::internal::Object>(object).location(),
   6590       id);
   6591 }
   6592 
   6593 
   6594 void Isolate::SetReferenceFromGroup(UniqueId id, internal::Object** object) {
   6595   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(this);
   6596   internal_isolate->global_handles()->SetReferenceFromGroup(
   6597       id,
   6598       v8::internal::Handle<v8::internal::Object>(object).location());
   6599 }
   6600 
   6601 
   6602 void Isolate::SetReference(internal::Object** parent,
   6603                            internal::Object** child) {
   6604   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(this);
   6605   i::Object** parent_location =
   6606       v8::internal::Handle<v8::internal::Object>(parent).location();
   6607   internal_isolate->global_handles()->SetReference(
   6608       reinterpret_cast<i::HeapObject**>(parent_location),
   6609       v8::internal::Handle<v8::internal::Object>(child).location());
   6610 }
   6611 
   6612 
   6613 void Isolate::AddGCPrologueCallback(GCPrologueCallback callback,
   6614                                     GCType gc_type) {
   6615   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6616   isolate->heap()->AddGCPrologueCallback(callback, gc_type);
   6617 }
   6618 
   6619 
   6620 void Isolate::RemoveGCPrologueCallback(GCPrologueCallback callback) {
   6621   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6622   isolate->heap()->RemoveGCPrologueCallback(callback);
   6623 }
   6624 
   6625 
   6626 void Isolate::AddGCEpilogueCallback(GCEpilogueCallback callback,
   6627                                     GCType gc_type) {
   6628   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6629   isolate->heap()->AddGCEpilogueCallback(callback, gc_type);
   6630 }
   6631 
   6632 
   6633 void Isolate::RemoveGCEpilogueCallback(GCEpilogueCallback callback) {
   6634   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6635   isolate->heap()->RemoveGCEpilogueCallback(callback);
   6636 }
   6637 
   6638 
   6639 void V8::AddGCPrologueCallback(GCPrologueCallback callback, GCType gc_type) {
   6640   i::Isolate* isolate = i::Isolate::Current();
   6641   isolate->heap()->AddGCPrologueCallback(
   6642       reinterpret_cast<v8::Isolate::GCPrologueCallback>(callback),
   6643       gc_type,
   6644       false);
   6645 }
   6646 
   6647 
   6648 void V8::RemoveGCPrologueCallback(GCPrologueCallback callback) {
   6649   i::Isolate* isolate = i::Isolate::Current();
   6650   isolate->heap()->RemoveGCPrologueCallback(
   6651       reinterpret_cast<v8::Isolate::GCPrologueCallback>(callback));
   6652 }
   6653 
   6654 
   6655 void V8::AddGCEpilogueCallback(GCEpilogueCallback callback, GCType gc_type) {
   6656   i::Isolate* isolate = i::Isolate::Current();
   6657   isolate->heap()->AddGCEpilogueCallback(
   6658       reinterpret_cast<v8::Isolate::GCEpilogueCallback>(callback),
   6659       gc_type,
   6660       false);
   6661 }
   6662 
   6663 
   6664 void V8::RemoveGCEpilogueCallback(GCEpilogueCallback callback) {
   6665   i::Isolate* isolate = i::Isolate::Current();
   6666   isolate->heap()->RemoveGCEpilogueCallback(
   6667       reinterpret_cast<v8::Isolate::GCEpilogueCallback>(callback));
   6668 }
   6669 
   6670 
   6671 void V8::AddMemoryAllocationCallback(MemoryAllocationCallback callback,
   6672                                      ObjectSpace space,
   6673                                      AllocationAction action) {
   6674   i::Isolate* isolate = i::Isolate::Current();
   6675   isolate->memory_allocator()->AddMemoryAllocationCallback(
   6676       callback, space, action);
   6677 }
   6678 
   6679 
   6680 void V8::RemoveMemoryAllocationCallback(MemoryAllocationCallback callback) {
   6681   i::Isolate* isolate = i::Isolate::Current();
   6682   isolate->memory_allocator()->RemoveMemoryAllocationCallback(
   6683       callback);
   6684 }
   6685 
   6686 
   6687 void V8::AddCallCompletedCallback(CallCompletedCallback callback) {
   6688   if (callback == NULL) return;
   6689   i::V8::AddCallCompletedCallback(callback);
   6690 }
   6691 
   6692 
   6693 void V8::RemoveCallCompletedCallback(CallCompletedCallback callback) {
   6694   i::V8::RemoveCallCompletedCallback(callback);
   6695 }
   6696 
   6697 
   6698 void V8::TerminateExecution(Isolate* isolate) {
   6699   // If no isolate is supplied, use the default isolate.
   6700   if (isolate != NULL) {
   6701     reinterpret_cast<i::Isolate*>(isolate)->stack_guard()->TerminateExecution();
   6702   } else {
   6703     i::Isolate::GetDefaultIsolateStackGuard()->TerminateExecution();
   6704   }
   6705 }
   6706 
   6707 
   6708 bool V8::IsExecutionTerminating(Isolate* isolate) {
   6709   i::Isolate* i_isolate = isolate != NULL ?
   6710       reinterpret_cast<i::Isolate*>(isolate) : i::Isolate::Current();
   6711   return IsExecutionTerminatingCheck(i_isolate);
   6712 }
   6713 
   6714 
   6715 void V8::CancelTerminateExecution(Isolate* isolate) {
   6716   i::Isolate* i_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6717   i_isolate->stack_guard()->CancelTerminateExecution();
   6718 }
   6719 
   6720 
   6721 Isolate* Isolate::GetCurrent() {
   6722   i::Isolate* isolate = i::Isolate::UncheckedCurrent();
   6723   return reinterpret_cast<Isolate*>(isolate);
   6724 }
   6725 
   6726 
   6727 Isolate* Isolate::New() {
   6728   i::Isolate* isolate = new i::Isolate();
   6729   return reinterpret_cast<Isolate*>(isolate);
   6730 }
   6731 
   6732 
   6733 void Isolate::Dispose() {
   6734   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6735   if (!ApiCheck(!isolate->IsInUse(),
   6736                 "v8::Isolate::Dispose()",
   6737                 "Disposing the isolate that is entered by a thread.")) {
   6738     return;
   6739   }
   6740   isolate->TearDown();
   6741 }
   6742 
   6743 
   6744 void Isolate::Enter() {
   6745   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6746   isolate->Enter();
   6747 }
   6748 
   6749 
   6750 void Isolate::Exit() {
   6751   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6752   isolate->Exit();
   6753 }
   6754 
   6755 
   6756 void Isolate::GetHeapStatistics(HeapStatistics* heap_statistics) {
   6757   i::Isolate* isolate = reinterpret_cast<i::Isolate*>(this);
   6758   if (!isolate->IsInitialized()) {
   6759     heap_statistics->total_heap_size_ = 0;
   6760     heap_statistics->total_heap_size_executable_ = 0;
   6761     heap_statistics->total_physical_size_ = 0;
   6762     heap_statistics->used_heap_size_ = 0;
   6763     heap_statistics->heap_size_limit_ = 0;
   6764     return;
   6765   }
   6766   i::Heap* heap = isolate->heap();
   6767   heap_statistics->total_heap_size_ = heap->CommittedMemory();
   6768   heap_statistics->total_heap_size_executable_ =
   6769       heap->CommittedMemoryExecutable();
   6770   heap_statistics->total_physical_size_ = heap->CommittedPhysicalMemory();
   6771   heap_statistics->used_heap_size_ = heap->SizeOfObjects();
   6772   heap_statistics->heap_size_limit_ = heap->MaxReserved();
   6773 }
   6774 
   6775 
   6776 String::Utf8Value::Utf8Value(v8::Handle<v8::Value> obj)
   6777     : str_(NULL), length_(0) {
   6778   i::Isolate* isolate = i::Isolate::Current();
   6779   if (obj.IsEmpty()) return;
   6780   ENTER_V8(isolate);
   6781   i::HandleScope scope(isolate);
   6782   TryCatch try_catch;
   6783   Handle<String> str = obj->ToString();
   6784   if (str.IsEmpty()) return;
   6785   i::Handle<i::String> i_str = Utils::OpenHandle(*str);
   6786   length_ = v8::Utf8Length(*i_str, isolate);
   6787   str_ = i::NewArray<char>(length_ + 1);
   6788   str->WriteUtf8(str_);
   6789 }
   6790 
   6791 
   6792 String::Utf8Value::~Utf8Value() {
   6793   i::DeleteArray(str_);
   6794 }
   6795 
   6796 
   6797 String::AsciiValue::AsciiValue(v8::Handle<v8::Value> obj)
   6798     : str_(NULL), length_(0) {
   6799   i::Isolate* isolate = i::Isolate::Current();
   6800   if (obj.IsEmpty()) return;
   6801   ENTER_V8(isolate);
   6802   i::HandleScope scope(isolate);
   6803   TryCatch try_catch;
   6804   Handle<String> str = obj->ToString();
   6805   if (str.IsEmpty()) return;
   6806   length_ = str->Utf8Length();
   6807   str_ = i::NewArray<char>(length_ + 1);
   6808   str->WriteUtf8(str_);
   6809   ASSERT(i::String::NonAsciiStart(str_, length_) >= length_);
   6810 }
   6811 
   6812 
   6813 String::AsciiValue::~AsciiValue() {
   6814   i::DeleteArray(str_);
   6815 }
   6816 
   6817 
   6818 String::Value::Value(v8::Handle<v8::Value> obj)
   6819     : str_(NULL), length_(0) {
   6820   i::Isolate* isolate = i::Isolate::Current();
   6821   if (obj.IsEmpty()) return;
   6822   ENTER_V8(isolate);
   6823   i::HandleScope scope(isolate);
   6824   TryCatch try_catch;
   6825   Handle<String> str = obj->ToString();
   6826   if (str.IsEmpty()) return;
   6827   length_ = str->Length();
   6828   str_ = i::NewArray<uint16_t>(length_ + 1);
   6829   str->Write(str_);
   6830 }
   6831 
   6832 
   6833 String::Value::~Value() {
   6834   i::DeleteArray(str_);
   6835 }
   6836 
   6837 
   6838 Local<Value> Exception::RangeError(v8::Handle<v8::String> raw_message) {
   6839   i::Isolate* isolate = i::Isolate::Current();
   6840   LOG_API(isolate, "RangeError");
   6841   ON_BAILOUT(isolate, "v8::Exception::RangeError()", return Local<Value>());
   6842   ENTER_V8(isolate);
   6843   i::Object* error;
   6844   {
   6845     i::HandleScope scope(isolate);
   6846     i::Handle<i::String> message = Utils::OpenHandle(*raw_message);
   6847     i::Handle<i::Object> result = isolate->factory()->NewRangeError(message);
   6848     error = *result;
   6849   }
   6850   i::Handle<i::Object> result(error, isolate);
   6851   return Utils::ToLocal(result);
   6852 }
   6853 
   6854 
   6855 Local<Value> Exception::ReferenceError(v8::Handle<v8::String> raw_message) {
   6856   i::Isolate* isolate = i::Isolate::Current();
   6857   LOG_API(isolate, "ReferenceError");
   6858   ON_BAILOUT(isolate, "v8::Exception::ReferenceError()", return Local<Value>());
   6859   ENTER_V8(isolate);
   6860   i::Object* error;
   6861   {
   6862     i::HandleScope scope(isolate);
   6863     i::Handle<i::String> message = Utils::OpenHandle(*raw_message);
   6864     i::Handle<i::Object> result =
   6865         isolate->factory()->NewReferenceError(message);
   6866     error = *result;
   6867   }
   6868   i::Handle<i::Object> result(error, isolate);
   6869   return Utils::ToLocal(result);
   6870 }
   6871 
   6872 
   6873 Local<Value> Exception::SyntaxError(v8::Handle<v8::String> raw_message) {
   6874   i::Isolate* isolate = i::Isolate::Current();
   6875   LOG_API(isolate, "SyntaxError");
   6876   ON_BAILOUT(isolate, "v8::Exception::SyntaxError()", return Local<Value>());
   6877   ENTER_V8(isolate);
   6878   i::Object* error;
   6879   {
   6880     i::HandleScope scope(isolate);
   6881     i::Handle<i::String> message = Utils::OpenHandle(*raw_message);
   6882     i::Handle<i::Object> result = isolate->factory()->NewSyntaxError(message);
   6883     error = *result;
   6884   }
   6885   i::Handle<i::Object> result(error, isolate);
   6886   return Utils::ToLocal(result);
   6887 }
   6888 
   6889 
   6890 Local<Value> Exception::TypeError(v8::Handle<v8::String> raw_message) {
   6891   i::Isolate* isolate = i::Isolate::Current();
   6892   LOG_API(isolate, "TypeError");
   6893   ON_BAILOUT(isolate, "v8::Exception::TypeError()", return Local<Value>());
   6894   ENTER_V8(isolate);
   6895   i::Object* error;
   6896   {
   6897     i::HandleScope scope(isolate);
   6898     i::Handle<i::String> message = Utils::OpenHandle(*raw_message);
   6899     i::Handle<i::Object> result = isolate->factory()->NewTypeError(message);
   6900     error = *result;
   6901   }
   6902   i::Handle<i::Object> result(error, isolate);
   6903   return Utils::ToLocal(result);
   6904 }
   6905 
   6906 
   6907 Local<Value> Exception::Error(v8::Handle<v8::String> raw_message) {
   6908   i::Isolate* isolate = i::Isolate::Current();
   6909   LOG_API(isolate, "Error");
   6910   ON_BAILOUT(isolate, "v8::Exception::Error()", return Local<Value>());
   6911   ENTER_V8(isolate);
   6912   i::Object* error;
   6913   {
   6914     i::HandleScope scope(isolate);
   6915     i::Handle<i::String> message = Utils::OpenHandle(*raw_message);
   6916     i::Handle<i::Object> result = isolate->factory()->NewError(message);
   6917     error = *result;
   6918   }
   6919   i::Handle<i::Object> result(error, isolate);
   6920   return Utils::ToLocal(result);
   6921 }
   6922 
   6923 
   6924 // --- D e b u g   S u p p o r t ---
   6925 
   6926 #ifdef ENABLE_DEBUGGER_SUPPORT
   6927 
   6928 bool Debug::SetDebugEventListener2(EventCallback2 that, Handle<Value> data) {
   6929   i::Isolate* isolate = i::Isolate::Current();
   6930   EnsureInitializedForIsolate(isolate, "v8::Debug::SetDebugEventListener2()");
   6931   ON_BAILOUT(isolate, "v8::Debug::SetDebugEventListener2()", return false);
   6932   ENTER_V8(isolate);
   6933   i::HandleScope scope(isolate);
   6934   i::Handle<i::Object> foreign = isolate->factory()->undefined_value();
   6935   if (that != NULL) {
   6936     foreign = isolate->factory()->NewForeign(FUNCTION_ADDR(that));
   6937   }
   6938   isolate->debugger()->SetEventListener(foreign,
   6939                                         Utils::OpenHandle(*data, true));
   6940   return true;
   6941 }
   6942 
   6943 
   6944 bool Debug::SetDebugEventListener(v8::Handle<v8::Object> that,
   6945                                   Handle<Value> data) {
   6946   i::Isolate* isolate = i::Isolate::Current();
   6947   ON_BAILOUT(isolate, "v8::Debug::SetDebugEventListener()", return false);
   6948   ENTER_V8(isolate);
   6949   isolate->debugger()->SetEventListener(Utils::OpenHandle(*that),
   6950                                         Utils::OpenHandle(*data, true));
   6951   return true;
   6952 }
   6953 
   6954 
   6955 void Debug::DebugBreak(Isolate* isolate) {
   6956   // If no isolate is supplied, use the default isolate.
   6957   if (isolate != NULL) {
   6958     reinterpret_cast<i::Isolate*>(isolate)->stack_guard()->DebugBreak();
   6959   } else {
   6960     i::Isolate::GetDefaultIsolateStackGuard()->DebugBreak();
   6961   }
   6962 }
   6963 
   6964 
   6965 void Debug::CancelDebugBreak(Isolate* isolate) {
   6966   // If no isolate is supplied, use the default isolate.
   6967   if (isolate != NULL) {
   6968     i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6969     internal_isolate->stack_guard()->Continue(i::DEBUGBREAK);
   6970   } else {
   6971     i::Isolate::GetDefaultIsolateStackGuard()->Continue(i::DEBUGBREAK);
   6972   }
   6973 }
   6974 
   6975 
   6976 void Debug::DebugBreakForCommand(ClientData* data, Isolate* isolate) {
   6977   // If no isolate is supplied, use the default isolate.
   6978   if (isolate != NULL) {
   6979     i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   6980     internal_isolate->debugger()->EnqueueDebugCommand(data);
   6981   } else {
   6982     i::Isolate::GetDefaultIsolateDebugger()->EnqueueDebugCommand(data);
   6983   }
   6984 }
   6985 
   6986 
   6987 void Debug::SetMessageHandler2(v8::Debug::MessageHandler2 handler) {
   6988   i::Isolate* isolate = i::Isolate::Current();
   6989   EnsureInitializedForIsolate(isolate, "v8::Debug::SetMessageHandler");
   6990   ENTER_V8(isolate);
   6991   isolate->debugger()->SetMessageHandler(handler);
   6992 }
   6993 
   6994 
   6995 void Debug::SendCommand(Isolate* isolate,
   6996                         const uint16_t* command,
   6997                         int length,
   6998                         ClientData* client_data) {
   6999   i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   7000   internal_isolate->debugger()->ProcessCommand(
   7001       i::Vector<const uint16_t>(command, length), client_data);
   7002 }
   7003 
   7004 
   7005 void Debug::SendCommand(const uint16_t* command, int length,
   7006                         ClientData* client_data,
   7007                         Isolate* isolate) {
   7008   // If no isolate is supplied, use the default isolate.
   7009   if (isolate != NULL) {
   7010     i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   7011     internal_isolate->debugger()->ProcessCommand(
   7012         i::Vector<const uint16_t>(command, length), client_data);
   7013   } else {
   7014     i::Isolate::GetDefaultIsolateDebugger()->ProcessCommand(
   7015         i::Vector<const uint16_t>(command, length), client_data);
   7016   }
   7017 }
   7018 
   7019 
   7020 void Debug::SetHostDispatchHandler(HostDispatchHandler handler,
   7021                                    int period) {
   7022   i::Isolate* isolate = i::Isolate::Current();
   7023   EnsureInitializedForIsolate(isolate, "v8::Debug::SetHostDispatchHandler");
   7024   ENTER_V8(isolate);
   7025   isolate->debugger()->SetHostDispatchHandler(
   7026       handler, i::TimeDelta::FromMilliseconds(period));
   7027 }
   7028 
   7029 
   7030 void Debug::SetDebugMessageDispatchHandler(
   7031     DebugMessageDispatchHandler handler, bool provide_locker) {
   7032   i::Isolate* isolate = i::Isolate::Current();
   7033   EnsureInitializedForIsolate(isolate,
   7034                               "v8::Debug::SetDebugMessageDispatchHandler");
   7035   ENTER_V8(isolate);
   7036   isolate->debugger()->SetDebugMessageDispatchHandler(
   7037       handler, provide_locker);
   7038 }
   7039 
   7040 
   7041 Local<Value> Debug::Call(v8::Handle<v8::Function> fun,
   7042                          v8::Handle<v8::Value> data) {
   7043   i::Isolate* isolate = i::Isolate::Current();
   7044   if (!isolate->IsInitialized()) return Local<Value>();
   7045   ON_BAILOUT(isolate, "v8::Debug::Call()", return Local<Value>());
   7046   ENTER_V8(isolate);
   7047   i::Handle<i::Object> result;
   7048   EXCEPTION_PREAMBLE(isolate);
   7049   if (data.IsEmpty()) {
   7050     result = isolate->debugger()->Call(Utils::OpenHandle(*fun),
   7051                                        isolate->factory()->undefined_value(),
   7052                                        &has_pending_exception);
   7053   } else {
   7054     result = isolate->debugger()->Call(Utils::OpenHandle(*fun),
   7055                                        Utils::OpenHandle(*data),
   7056                                        &has_pending_exception);
   7057   }
   7058   EXCEPTION_BAILOUT_CHECK(isolate, Local<Value>());
   7059   return Utils::ToLocal(result);
   7060 }
   7061 
   7062 
   7063 Local<Value> Debug::GetMirror(v8::Handle<v8::Value> obj) {
   7064   i::Isolate* isolate = i::Isolate::Current();
   7065   if (!isolate->IsInitialized()) return Local<Value>();
   7066   ON_BAILOUT(isolate, "v8::Debug::GetMirror()", return Local<Value>());
   7067   ENTER_V8(isolate);
   7068   v8::EscapableHandleScope scope(reinterpret_cast<Isolate*>(isolate));
   7069   i::Debug* isolate_debug = isolate->debug();
   7070   isolate_debug->Load();
   7071   i::Handle<i::JSObject> debug(isolate_debug->debug_context()->global_object());
   7072   i::Handle<i::String> name = isolate->factory()->InternalizeOneByteString(
   7073       STATIC_ASCII_VECTOR("MakeMirror"));
   7074   i::Handle<i::Object> fun_obj = i::GetProperty(isolate, debug, name);
   7075   i::Handle<i::JSFunction> fun = i::Handle<i::JSFunction>::cast(fun_obj);
   7076   v8::Handle<v8::Function> v8_fun = Utils::ToLocal(fun);
   7077   const int kArgc = 1;
   7078   v8::Handle<v8::Value> argv[kArgc] = { obj };
   7079   EXCEPTION_PREAMBLE(isolate);
   7080   v8::Local<v8::Value> result =
   7081       v8_fun->Call(Utils::ToLocal(debug), kArgc, argv);
   7082   EXCEPTION_BAILOUT_CHECK(isolate, Local<Value>());
   7083   return scope.Escape(result);
   7084 }
   7085 
   7086 
   7087 bool Debug::EnableAgent(const char* name, int port, bool wait_for_connection) {
   7088   return i::Isolate::Current()->debugger()->StartAgent(name, port,
   7089                                                        wait_for_connection);
   7090 }
   7091 
   7092 
   7093 void Debug::DisableAgent() {
   7094   return i::Isolate::Current()->debugger()->StopAgent();
   7095 }
   7096 
   7097 
   7098 void Debug::ProcessDebugMessages() {
   7099   i::Execution::ProcessDebugMessages(i::Isolate::Current(), true);
   7100 }
   7101 
   7102 
   7103 Local<Context> Debug::GetDebugContext() {
   7104   i::Isolate* isolate = i::Isolate::Current();
   7105   EnsureInitializedForIsolate(isolate, "v8::Debug::GetDebugContext()");
   7106   ENTER_V8(isolate);
   7107   return Utils::ToLocal(i::Isolate::Current()->debugger()->GetDebugContext());
   7108 }
   7109 
   7110 
   7111 void Debug::SetLiveEditEnabled(bool enable, Isolate* isolate) {
   7112   // If no isolate is supplied, use the default isolate.
   7113   i::Debugger* debugger;
   7114   if (isolate != NULL) {
   7115     i::Isolate* internal_isolate = reinterpret_cast<i::Isolate*>(isolate);
   7116     debugger = internal_isolate->debugger();
   7117   } else {
   7118     debugger = i::Isolate::GetDefaultIsolateDebugger();
   7119   }
   7120   debugger->set_live_edit_enabled(enable);
   7121 }
   7122 
   7123 
   7124 #endif  // ENABLE_DEBUGGER_SUPPORT
   7125 
   7126 
   7127 Handle<String> CpuProfileNode::GetFunctionName() const {
   7128   i::Isolate* isolate = i::Isolate::Current();
   7129   const i::ProfileNode* node = reinterpret_cast<const i::ProfileNode*>(this);
   7130   const i::CodeEntry* entry = node->entry();
   7131   if (!entry->has_name_prefix()) {
   7132     return ToApiHandle<String>(
   7133         isolate->factory()->InternalizeUtf8String(entry->name()));
   7134   } else {
   7135     return ToApiHandle<String>(isolate->factory()->NewConsString(
   7136         isolate->factory()->InternalizeUtf8String(entry->name_prefix()),
   7137         isolate->factory()->InternalizeUtf8String(entry->name())));
   7138   }
   7139 }
   7140 
   7141 
   7142 int CpuProfileNode::GetScriptId() const {
   7143   const i::ProfileNode* node = reinterpret_cast<const i::ProfileNode*>(this);
   7144   const i::CodeEntry* entry = node->entry();
   7145   return entry->script_id();
   7146 }
   7147 
   7148 
   7149 Handle<String> CpuProfileNode::GetScriptResourceName() const {
   7150   i::Isolate* isolate = i::Isolate::Current();
   7151   const i::ProfileNode* node = reinterpret_cast<const i::ProfileNode*>(this);
   7152   return ToApiHandle<String>(isolate->factory()->InternalizeUtf8String(
   7153       node->entry()->resource_name()));
   7154 }
   7155 
   7156 
   7157 int CpuProfileNode::GetLineNumber() const {
   7158   return reinterpret_cast<const i::ProfileNode*>(this)->entry()->line_number();
   7159 }
   7160 
   7161 
   7162 int CpuProfileNode::GetColumnNumber() const {
   7163   return reinterpret_cast<const i::ProfileNode*>(this)->
   7164       entry()->column_number();
   7165 }
   7166 
   7167 
   7168 const char* CpuProfileNode::GetBailoutReason() const {
   7169   const i::ProfileNode* node = reinterpret_cast<const i::ProfileNode*>(this);
   7170   return node->entry()->bailout_reason();
   7171 }
   7172 
   7173 
   7174 unsigned CpuProfileNode::GetHitCount() const {
   7175   return reinterpret_cast<const i::ProfileNode*>(this)->self_ticks();
   7176 }
   7177 
   7178 
   7179 unsigned CpuProfileNode::GetCallUid() const {
   7180   return reinterpret_cast<const i::ProfileNode*>(this)->entry()->GetCallUid();
   7181 }
   7182 
   7183 
   7184 unsigned CpuProfileNode::GetNodeId() const {
   7185   return reinterpret_cast<const i::ProfileNode*>(this)->id();
   7186 }
   7187 
   7188 
   7189 int CpuProfileNode::GetChildrenCount() const {
   7190   return reinterpret_cast<const i::ProfileNode*>(this)->children()->length();
   7191 }
   7192 
   7193 
   7194 const CpuProfileNode* CpuProfileNode::GetChild(int index) const {
   7195   const i::ProfileNode* child =
   7196       reinterpret_cast<const i::ProfileNode*>(this)->children()->at(index);
   7197   return reinterpret_cast<const CpuProfileNode*>(child);
   7198 }
   7199 
   7200 
   7201 void CpuProfile::Delete() {
   7202   i::Isolate* isolate = i::Isolate::Current();
   7203   i::CpuProfiler* profiler = isolate->cpu_profiler();
   7204   ASSERT(profiler != NULL);
   7205   profiler->DeleteProfile(reinterpret_cast<i::CpuProfile*>(this));
   7206   if (profiler->GetProfilesCount() == 0) {
   7207     // If this was the last profile, clean up all accessory data as well.
   7208     profiler->DeleteAllProfiles();
   7209   }
   7210 }
   7211 
   7212 
   7213 unsigned CpuProfile::GetUid() const {
   7214   return reinterpret_cast<const i::CpuProfile*>(this)->uid();
   7215 }
   7216 
   7217 
   7218 Handle<String> CpuProfile::GetTitle() const {
   7219   i::Isolate* isolate = i::Isolate::Current();
   7220   const i::CpuProfile* profile = reinterpret_cast<const i::CpuProfile*>(this);
   7221   return ToApiHandle<String>(isolate->factory()->InternalizeUtf8String(
   7222       profile->title()));
   7223 }
   7224 
   7225 
   7226 const CpuProfileNode* CpuProfile::GetTopDownRoot() const {
   7227   const i::CpuProfile* profile = reinterpret_cast<const i::CpuProfile*>(this);
   7228   return reinterpret_cast<const CpuProfileNode*>(profile->top_down()->root());
   7229 }
   7230 
   7231 
   7232 const CpuProfileNode* CpuProfile::GetSample(int index) const {
   7233   const i::CpuProfile* profile = reinterpret_cast<const i::CpuProfile*>(this);
   7234   return reinterpret_cast<const CpuProfileNode*>(profile->sample(index));
   7235 }
   7236 
   7237 
   7238 int64_t CpuProfile::GetStartTime() const {
   7239   const i::CpuProfile* profile = reinterpret_cast<const i::CpuProfile*>(this);
   7240   return (profile->start_time() - i::Time::UnixEpoch()).InMicroseconds();
   7241 }
   7242 
   7243 
   7244 int64_t CpuProfile::GetEndTime() const {
   7245   const i::CpuProfile* profile = reinterpret_cast<const i::CpuProfile*>(this);
   7246   return (profile->end_time() - i::Time::UnixEpoch()).InMicroseconds();
   7247 }
   7248 
   7249 
   7250 int CpuProfile::GetSamplesCount() const {
   7251   return reinterpret_cast<const i::CpuProfile*>(this)->samples_count();
   7252 }
   7253 
   7254 
   7255 int CpuProfiler::GetProfileCount() {
   7256   return reinterpret_cast<i::CpuProfiler*>(this)->GetProfilesCount();
   7257 }
   7258 
   7259 
   7260 void CpuProfiler::SetSamplingInterval(int us) {
   7261   ASSERT(us >= 0);
   7262   return reinterpret_cast<i::CpuProfiler*>(this)->set_sampling_interval(
   7263       i::TimeDelta::FromMicroseconds(us));
   7264 }
   7265 
   7266 
   7267 const CpuProfile* CpuProfiler::GetCpuProfile(int index) {
   7268   return reinterpret_cast<const CpuProfile*>(
   7269       reinterpret_cast<i::CpuProfiler*>(this)->GetProfile(index));
   7270 }
   7271 
   7272 
   7273 void CpuProfiler::StartCpuProfiling(Handle<String> title, bool record_samples) {
   7274   reinterpret_cast<i::CpuProfiler*>(this)->StartProfiling(
   7275       *Utils::OpenHandle(*title), record_samples);
   7276 }
   7277 
   7278 
   7279 const CpuProfile* CpuProfiler::StopCpuProfiling(Handle<String> title) {
   7280   return reinterpret_cast<const CpuProfile*>(
   7281       reinterpret_cast<i::CpuProfiler*>(this)->StopProfiling(
   7282           *Utils::OpenHandle(*title)));
   7283 }
   7284 
   7285 
   7286 void CpuProfiler::DeleteAllCpuProfiles() {
   7287   reinterpret_cast<i::CpuProfiler*>(this)->DeleteAllProfiles();
   7288 }
   7289 
   7290 
   7291 void CpuProfiler::SetIdle(bool is_idle) {
   7292   i::Isolate* isolate = reinterpret_cast<i::CpuProfiler*>(this)->isolate();
   7293   i::StateTag state = isolate->current_vm_state();
   7294   ASSERT(state == i::EXTERNAL || state == i::IDLE);
   7295   if (isolate->js_entry_sp() != NULL) return;
   7296   if (is_idle) {
   7297     isolate->set_current_vm_state(i::IDLE);
   7298   } else if (state == i::IDLE) {
   7299     isolate->set_current_vm_state(i::EXTERNAL);
   7300   }
   7301 }
   7302 
   7303 
   7304 static i::HeapGraphEdge* ToInternal(const HeapGraphEdge* edge) {
   7305   return const_cast<i::HeapGraphEdge*>(
   7306       reinterpret_cast<const i::HeapGraphEdge*>(edge));
   7307 }
   7308 
   7309 
   7310 HeapGraphEdge::Type HeapGraphEdge::GetType() const {
   7311   return static_cast<HeapGraphEdge::Type>(ToInternal(this)->type());
   7312 }
   7313 
   7314 
   7315 Handle<Value> HeapGraphEdge::GetName() const {
   7316   i::Isolate* isolate = i::Isolate::Current();
   7317   i::HeapGraphEdge* edge = ToInternal(this);
   7318   switch (edge->type()) {
   7319     case i::HeapGraphEdge::kContextVariable:
   7320     case i::HeapGraphEdge::kInternal:
   7321     case i::HeapGraphEdge::kProperty:
   7322     case i::HeapGraphEdge::kShortcut:
   7323       return ToApiHandle<String>(
   7324           isolate->factory()->InternalizeUtf8String(edge->name()));
   7325     case i::HeapGraphEdge::kElement:
   7326     case i::HeapGraphEdge::kHidden:
   7327     case i::HeapGraphEdge::kWeak:
   7328       return ToApiHandle<Number>(
   7329           isolate->factory()->NewNumberFromInt(edge->index()));
   7330     default: UNREACHABLE();
   7331   }
   7332   return v8::Undefined(reinterpret_cast<v8::Isolate*>(isolate));
   7333 }
   7334 
   7335 
   7336 const HeapGraphNode* HeapGraphEdge::GetFromNode() const {
   7337   const i::HeapEntry* from = ToInternal(this)->from();
   7338   return reinterpret_cast<const HeapGraphNode*>(from);
   7339 }
   7340 
   7341 
   7342 const HeapGraphNode* HeapGraphEdge::GetToNode() const {
   7343   const i::HeapEntry* to = ToInternal(this)->to();
   7344   return reinterpret_cast<const HeapGraphNode*>(to);
   7345 }
   7346 
   7347 
   7348 static i::HeapEntry* ToInternal(const HeapGraphNode* entry) {
   7349   return const_cast<i::HeapEntry*>(
   7350       reinterpret_cast<const i::HeapEntry*>(entry));
   7351 }
   7352 
   7353 
   7354 HeapGraphNode::Type HeapGraphNode::GetType() const {
   7355   return static_cast<HeapGraphNode::Type>(ToInternal(this)->type());
   7356 }
   7357 
   7358 
   7359 Handle<String> HeapGraphNode::GetName() const {
   7360   i::Isolate* isolate = i::Isolate::Current();
   7361   return ToApiHandle<String>(
   7362       isolate->factory()->InternalizeUtf8String(ToInternal(this)->name()));
   7363 }
   7364 
   7365 
   7366 SnapshotObjectId HeapGraphNode::GetId() const {
   7367   return ToInternal(this)->id();
   7368 }
   7369 
   7370 
   7371 int HeapGraphNode::GetSelfSize() const {
   7372   return ToInternal(this)->self_size();
   7373 }
   7374 
   7375 
   7376 int HeapGraphNode::GetChildrenCount() const {
   7377   return ToInternal(this)->children().length();
   7378 }
   7379 
   7380 
   7381 const HeapGraphEdge* HeapGraphNode::GetChild(int index) const {
   7382   return reinterpret_cast<const HeapGraphEdge*>(
   7383       ToInternal(this)->children()[index]);
   7384 }
   7385 
   7386 
   7387 v8::Handle<v8::Value> HeapGraphNode::GetHeapValue() const {
   7388   i::Isolate* isolate = i::Isolate::Current();
   7389   i::Handle<i::HeapObject> object = ToInternal(this)->GetHeapObject();
   7390   return !object.is_null() ?
   7391       ToApiHandle<Value>(object) :
   7392       ToApiHandle<Value>(isolate->factory()->undefined_value());
   7393 }
   7394 
   7395 
   7396 static i::HeapSnapshot* ToInternal(const HeapSnapshot* snapshot) {
   7397   return const_cast<i::HeapSnapshot*>(
   7398       reinterpret_cast<const i::HeapSnapshot*>(snapshot));
   7399 }
   7400 
   7401 
   7402 void HeapSnapshot::Delete() {
   7403   i::Isolate* isolate = i::Isolate::Current();
   7404   if (isolate->heap_profiler()->GetSnapshotsCount() > 1) {
   7405     ToInternal(this)->Delete();
   7406   } else {
   7407     // If this is the last snapshot, clean up all accessory data as well.
   7408     isolate->heap_profiler()->DeleteAllSnapshots();
   7409   }
   7410 }
   7411 
   7412 
   7413 unsigned HeapSnapshot::GetUid() const {
   7414   return ToInternal(this)->uid();
   7415 }
   7416 
   7417 
   7418 Handle<String> HeapSnapshot::GetTitle() const {
   7419   i::Isolate* isolate = i::Isolate::Current();
   7420   return ToApiHandle<String>(
   7421       isolate->factory()->InternalizeUtf8String(ToInternal(this)->title()));
   7422 }
   7423 
   7424 
   7425 const HeapGraphNode* HeapSnapshot::GetRoot() const {
   7426   return reinterpret_cast<const HeapGraphNode*>(ToInternal(this)->root());
   7427 }
   7428 
   7429 
   7430 const HeapGraphNode* HeapSnapshot::GetNodeById(SnapshotObjectId id) const {
   7431   return reinterpret_cast<const HeapGraphNode*>(
   7432       ToInternal(this)->GetEntryById(id));
   7433 }
   7434 
   7435 
   7436 int HeapSnapshot::GetNodesCount() const {
   7437   return ToInternal(this)->entries().length();
   7438 }
   7439 
   7440 
   7441 const HeapGraphNode* HeapSnapshot::GetNode(int index) const {
   7442   return reinterpret_cast<const HeapGraphNode*>(
   7443       &ToInternal(this)->entries().at(index));
   7444 }
   7445 
   7446 
   7447 SnapshotObjectId HeapSnapshot::GetMaxSnapshotJSObjectId() const {
   7448   return ToInternal(this)->max_snapshot_js_object_id();
   7449 }
   7450 
   7451 
   7452 void HeapSnapshot::Serialize(OutputStream* stream,
   7453                              HeapSnapshot::SerializationFormat format) const {
   7454   ApiCheck(format == kJSON,
   7455            "v8::HeapSnapshot::Serialize",
   7456            "Unknown serialization format");
   7457   ApiCheck(stream->GetOutputEncoding() == OutputStream::kAscii,
   7458            "v8::HeapSnapshot::Serialize",
   7459            "Unsupported output encoding");
   7460   ApiCheck(stream->GetChunkSize() > 0,
   7461            "v8::HeapSnapshot::Serialize",
   7462            "Invalid stream chunk size");
   7463   i::HeapSnapshotJSONSerializer serializer(ToInternal(this));
   7464   serializer.Serialize(stream);
   7465 }
   7466 
   7467 
   7468 int HeapProfiler::GetSnapshotCount() {
   7469   return reinterpret_cast<i::HeapProfiler*>(this)->GetSnapshotsCount();
   7470 }
   7471 
   7472 
   7473 const HeapSnapshot* HeapProfiler::GetHeapSnapshot(int index) {
   7474   return reinterpret_cast<const HeapSnapshot*>(
   7475       reinterpret_cast<i::HeapProfiler*>(this)->GetSnapshot(index));
   7476 }
   7477 
   7478 
   7479 SnapshotObjectId HeapProfiler::GetObjectId(Handle<Value> value) {
   7480   i::Handle<i::Object> obj = Utils::OpenHandle(*value);
   7481   return reinterpret_cast<i::HeapProfiler*>(this)->GetSnapshotObjectId(obj);
   7482 }
   7483 
   7484 
   7485 const HeapSnapshot* HeapProfiler::TakeHeapSnapshot(
   7486     Handle<String> title,
   7487     ActivityControl* control,
   7488     ObjectNameResolver* resolver) {
   7489   return reinterpret_cast<const HeapSnapshot*>(
   7490       reinterpret_cast<i::HeapProfiler*>(this)->TakeSnapshot(
   7491           *Utils::OpenHandle(*title), control, resolver));
   7492 }
   7493 
   7494 
   7495 void HeapProfiler::StartTrackingHeapObjects(bool track_allocations) {
   7496   reinterpret_cast<i::HeapProfiler*>(this)->StartHeapObjectsTracking(
   7497       track_allocations);
   7498 }
   7499 
   7500 
   7501 void HeapProfiler::StopTrackingHeapObjects() {
   7502   reinterpret_cast<i::HeapProfiler*>(this)->StopHeapObjectsTracking();
   7503 }
   7504 
   7505 
   7506 SnapshotObjectId HeapProfiler::GetHeapStats(OutputStream* stream) {
   7507   return reinterpret_cast<i::HeapProfiler*>(this)->PushHeapObjectsStats(stream);
   7508 }
   7509 
   7510 
   7511 void HeapProfiler::DeleteAllHeapSnapshots() {
   7512   reinterpret_cast<i::HeapProfiler*>(this)->DeleteAllSnapshots();
   7513 }
   7514 
   7515 
   7516 void HeapProfiler::SetWrapperClassInfoProvider(uint16_t class_id,
   7517                                                WrapperInfoCallback callback) {
   7518   reinterpret_cast<i::HeapProfiler*>(this)->DefineWrapperClass(class_id,
   7519                                                                callback);
   7520 }
   7521 
   7522 
   7523 size_t HeapProfiler::GetProfilerMemorySize() {
   7524   return reinterpret_cast<i::HeapProfiler*>(this)->
   7525       GetMemorySizeUsedByProfiler();
   7526 }
   7527 
   7528 
   7529 void HeapProfiler::SetRetainedObjectInfo(UniqueId id,
   7530                                          RetainedObjectInfo* info) {
   7531   reinterpret_cast<i::HeapProfiler*>(this)->SetRetainedObjectInfo(id, info);
   7532 }
   7533 
   7534 
   7535 void HeapProfiler::StartRecordingHeapAllocations() {
   7536   reinterpret_cast<i::HeapProfiler*>(this)->StartHeapObjectsTracking(true);
   7537 }
   7538 
   7539 
   7540 void HeapProfiler::StopRecordingHeapAllocations() {
   7541   reinterpret_cast<i::HeapProfiler*>(this)->StopHeapObjectsTracking();
   7542 }
   7543 
   7544 
   7545 v8::Testing::StressType internal::Testing::stress_type_ =
   7546     v8::Testing::kStressTypeOpt;
   7547 
   7548 
   7549 void Testing::SetStressRunType(Testing::StressType type) {
   7550   internal::Testing::set_stress_type(type);
   7551 }
   7552 
   7553 
   7554 int Testing::GetStressRuns() {
   7555   if (internal::FLAG_stress_runs != 0) return internal::FLAG_stress_runs;
   7556 #ifdef DEBUG
   7557   // In debug mode the code runs much slower so stressing will only make two
   7558   // runs.
   7559   return 2;
   7560 #else
   7561   return 5;
   7562 #endif
   7563 }
   7564 
   7565 
   7566 static void SetFlagsFromString(const char* flags) {
   7567   V8::SetFlagsFromString(flags, i::StrLength(flags));
   7568 }
   7569 
   7570 
   7571 void Testing::PrepareStressRun(int run) {
   7572   static const char* kLazyOptimizations =
   7573       "--prepare-always-opt "
   7574       "--max-inlined-source-size=999999 "
   7575       "--max-inlined-nodes=999999 "
   7576       "--max-inlined-nodes-cumulative=999999 "
   7577       "--noalways-opt";
   7578   static const char* kForcedOptimizations = "--always-opt";
   7579 
   7580   // If deoptimization stressed turn on frequent deoptimization. If no value
   7581   // is spefified through --deopt-every-n-times use a default default value.
   7582   static const char* kDeoptEvery13Times = "--deopt-every-n-times=13";
   7583   if (internal::Testing::stress_type() == Testing::kStressTypeDeopt &&
   7584       internal::FLAG_deopt_every_n_times == 0) {
   7585     SetFlagsFromString(kDeoptEvery13Times);
   7586   }
   7587 
   7588 #ifdef DEBUG
   7589   // As stressing in debug mode only make two runs skip the deopt stressing
   7590   // here.
   7591   if (run == GetStressRuns() - 1) {
   7592     SetFlagsFromString(kForcedOptimizations);
   7593   } else {
   7594     SetFlagsFromString(kLazyOptimizations);
   7595   }
   7596 #else
   7597   if (run == GetStressRuns() - 1) {
   7598     SetFlagsFromString(kForcedOptimizations);
   7599   } else if (run != GetStressRuns() - 2) {
   7600     SetFlagsFromString(kLazyOptimizations);
   7601   }
   7602 #endif
   7603 }
   7604 
   7605 
   7606 // TODO(svenpanne) Deprecate this.
   7607 void Testing::DeoptimizeAll() {
   7608   i::Isolate* isolate = i::Isolate::Current();
   7609   i::HandleScope scope(isolate);
   7610   internal::Deoptimizer::DeoptimizeAll(isolate);
   7611 }
   7612 
   7613 
   7614 namespace internal {
   7615 
   7616 
   7617 void HandleScopeImplementer::FreeThreadResources() {
   7618   Free();
   7619 }
   7620 
   7621 
   7622 char* HandleScopeImplementer::ArchiveThread(char* storage) {
   7623   v8::ImplementationUtilities::HandleScopeData* current =
   7624       isolate_->handle_scope_data();
   7625   handle_scope_data_ = *current;
   7626   OS::MemCopy(storage, this, sizeof(*this));
   7627 
   7628   ResetAfterArchive();
   7629   current->Initialize();
   7630 
   7631   return storage + ArchiveSpacePerThread();
   7632 }
   7633 
   7634 
   7635 int HandleScopeImplementer::ArchiveSpacePerThread() {
   7636   return sizeof(HandleScopeImplementer);
   7637 }
   7638 
   7639 
   7640 char* HandleScopeImplementer::RestoreThread(char* storage) {
   7641   OS::MemCopy(this, storage, sizeof(*this));
   7642   *isolate_->handle_scope_data() = handle_scope_data_;
   7643   return storage + ArchiveSpacePerThread();
   7644 }
   7645 
   7646 
   7647 void HandleScopeImplementer::IterateThis(ObjectVisitor* v) {
   7648 #ifdef DEBUG
   7649   bool found_block_before_deferred = false;
   7650 #endif
   7651   // Iterate over all handles in the blocks except for the last.
   7652   for (int i = blocks()->length() - 2; i >= 0; --i) {
   7653     Object** block = blocks()->at(i);
   7654     if (last_handle_before_deferred_block_ != NULL &&
   7655         (last_handle_before_deferred_block_ <= &block[kHandleBlockSize]) &&
   7656         (last_handle_before_deferred_block_ >= block)) {
   7657       v->VisitPointers(block, last_handle_before_deferred_block_);
   7658       ASSERT(!found_block_before_deferred);
   7659 #ifdef DEBUG
   7660       found_block_before_deferred = true;
   7661 #endif
   7662     } else {
   7663       v->VisitPointers(block, &block[kHandleBlockSize]);
   7664     }
   7665   }
   7666 
   7667   ASSERT(last_handle_before_deferred_block_ == NULL ||
   7668          found_block_before_deferred);
   7669 
   7670   // Iterate over live handles in the last block (if any).
   7671   if (!blocks()->is_empty()) {
   7672     v->VisitPointers(blocks()->last(), handle_scope_data_.next);
   7673   }
   7674 
   7675   List<Context*>* context_lists[2] = { &saved_contexts_, &entered_contexts_};
   7676   for (unsigned i = 0; i < ARRAY_SIZE(context_lists); i++) {
   7677     if (context_lists[i]->is_empty()) continue;
   7678     Object** start = reinterpret_cast<Object**>(&context_lists[i]->first());
   7679     v->VisitPointers(start, start + context_lists[i]->length());
   7680   }
   7681 }
   7682 
   7683 
   7684 void HandleScopeImplementer::Iterate(ObjectVisitor* v) {
   7685   v8::ImplementationUtilities::HandleScopeData* current =
   7686       isolate_->handle_scope_data();
   7687   handle_scope_data_ = *current;
   7688   IterateThis(v);
   7689 }
   7690 
   7691 
   7692 char* HandleScopeImplementer::Iterate(ObjectVisitor* v, char* storage) {
   7693   HandleScopeImplementer* scope_implementer =
   7694       reinterpret_cast<HandleScopeImplementer*>(storage);
   7695   scope_implementer->IterateThis(v);
   7696   return storage + ArchiveSpacePerThread();
   7697 }
   7698 
   7699 
   7700 DeferredHandles* HandleScopeImplementer::Detach(Object** prev_limit) {
   7701   DeferredHandles* deferred =
   7702       new DeferredHandles(isolate()->handle_scope_data()->next, isolate());
   7703 
   7704   while (!blocks_.is_empty()) {
   7705     Object** block_start = blocks_.last();
   7706     Object** block_limit = &block_start[kHandleBlockSize];
   7707     // We should not need to check for SealHandleScope here. Assert this.
   7708     ASSERT(prev_limit == block_limit ||
   7709            !(block_start <= prev_limit && prev_limit <= block_limit));
   7710     if (prev_limit == block_limit) break;
   7711     deferred->blocks_.Add(blocks_.last());
   7712     blocks_.RemoveLast();
   7713   }
   7714 
   7715   // deferred->blocks_ now contains the blocks installed on the
   7716   // HandleScope stack since BeginDeferredScope was called, but in
   7717   // reverse order.
   7718 
   7719   ASSERT(prev_limit == NULL || !blocks_.is_empty());
   7720 
   7721   ASSERT(!blocks_.is_empty() && prev_limit != NULL);
   7722   ASSERT(last_handle_before_deferred_block_ != NULL);
   7723   last_handle_before_deferred_block_ = NULL;
   7724   return deferred;
   7725 }
   7726 
   7727 
   7728 void HandleScopeImplementer::BeginDeferredScope() {
   7729   ASSERT(last_handle_before_deferred_block_ == NULL);
   7730   last_handle_before_deferred_block_ = isolate()->handle_scope_data()->next;
   7731 }
   7732 
   7733 
   7734 DeferredHandles::~DeferredHandles() {
   7735   isolate_->UnlinkDeferredHandles(this);
   7736 
   7737   for (int i = 0; i < blocks_.length(); i++) {
   7738 #ifdef ENABLE_HANDLE_ZAPPING
   7739     HandleScope::ZapRange(blocks_[i], &blocks_[i][kHandleBlockSize]);
   7740 #endif
   7741     isolate_->handle_scope_implementer()->ReturnBlock(blocks_[i]);
   7742   }
   7743 }
   7744 
   7745 
   7746 void DeferredHandles::Iterate(ObjectVisitor* v) {
   7747   ASSERT(!blocks_.is_empty());
   7748 
   7749   ASSERT((first_block_limit_ >= blocks_.first()) &&
   7750          (first_block_limit_ <= &(blocks_.first())[kHandleBlockSize]));
   7751 
   7752   v->VisitPointers(blocks_.first(), first_block_limit_);
   7753 
   7754   for (int i = 1; i < blocks_.length(); i++) {
   7755     v->VisitPointers(blocks_[i], &blocks_[i][kHandleBlockSize]);
   7756   }
   7757 }
   7758 
   7759 
   7760 void InvokeAccessorGetterCallback(
   7761     v8::Local<v8::String> property,
   7762     const v8::PropertyCallbackInfo<v8::Value>& info,
   7763     v8::AccessorGetterCallback getter) {
   7764   // Leaving JavaScript.
   7765   Isolate* isolate = reinterpret_cast<Isolate*>(info.GetIsolate());
   7766   Address getter_address = reinterpret_cast<Address>(reinterpret_cast<intptr_t>(
   7767       getter));
   7768   VMState<EXTERNAL> state(isolate);
   7769   ExternalCallbackScope call_scope(isolate, getter_address);
   7770   getter(property, info);
   7771 }
   7772 
   7773 
   7774 void InvokeFunctionCallback(const v8::FunctionCallbackInfo<v8::Value>& info,
   7775                             v8::FunctionCallback callback) {
   7776   Isolate* isolate = reinterpret_cast<Isolate*>(info.GetIsolate());
   7777   Address callback_address =
   7778       reinterpret_cast<Address>(reinterpret_cast<intptr_t>(callback));
   7779   VMState<EXTERNAL> state(isolate);
   7780   ExternalCallbackScope call_scope(isolate, callback_address);
   7781   callback(info);
   7782 }
   7783 
   7784 
   7785 } }  // namespace v8::internal
   7786