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 "v8.h" 29 30 #include "objects.h" 31 #include "elements.h" 32 #include "utils.h" 33 34 35 // Each concrete ElementsAccessor can handle exactly one ElementsKind, 36 // several abstract ElementsAccessor classes are used to allow sharing 37 // common code. 38 // 39 // Inheritance hierarchy: 40 // - ElementsAccessorBase (abstract) 41 // - FastElementsAccessor (abstract) 42 // - FastObjectElementsAccessor 43 // - FastDoubleElementsAccessor 44 // - ExternalElementsAccessor (abstract) 45 // - ExternalByteElementsAccessor 46 // - ExternalUnsignedByteElementsAccessor 47 // - ExternalShortElementsAccessor 48 // - ExternalUnsignedShortElementsAccessor 49 // - ExternalIntElementsAccessor 50 // - ExternalUnsignedIntElementsAccessor 51 // - ExternalFloatElementsAccessor 52 // - ExternalDoubleElementsAccessor 53 // - PixelElementsAccessor 54 // - DictionaryElementsAccessor 55 // - NonStrictArgumentsElementsAccessor 56 57 58 namespace v8 { 59 namespace internal { 60 61 62 // First argument in list is the accessor class, the second argument is the 63 // accessor ElementsKind, and the third is the backing store class. Use the 64 // fast element handler for smi-only arrays. The implementation is currently 65 // identical. Note that the order must match that of the ElementsKind enum for 66 // the |accessor_array[]| below to work. 67 #define ELEMENTS_LIST(V) \ 68 V(FastObjectElementsAccessor, FAST_SMI_ONLY_ELEMENTS, FixedArray) \ 69 V(FastObjectElementsAccessor, FAST_ELEMENTS, FixedArray) \ 70 V(FastDoubleElementsAccessor, FAST_DOUBLE_ELEMENTS, FixedDoubleArray) \ 71 V(DictionaryElementsAccessor, DICTIONARY_ELEMENTS, \ 72 SeededNumberDictionary) \ 73 V(NonStrictArgumentsElementsAccessor, NON_STRICT_ARGUMENTS_ELEMENTS, \ 74 FixedArray) \ 75 V(ExternalByteElementsAccessor, EXTERNAL_BYTE_ELEMENTS, \ 76 ExternalByteArray) \ 77 V(ExternalUnsignedByteElementsAccessor, \ 78 EXTERNAL_UNSIGNED_BYTE_ELEMENTS, ExternalUnsignedByteArray) \ 79 V(ExternalShortElementsAccessor, EXTERNAL_SHORT_ELEMENTS, \ 80 ExternalShortArray) \ 81 V(ExternalUnsignedShortElementsAccessor, \ 82 EXTERNAL_UNSIGNED_SHORT_ELEMENTS, ExternalUnsignedShortArray) \ 83 V(ExternalIntElementsAccessor, EXTERNAL_INT_ELEMENTS, \ 84 ExternalIntArray) \ 85 V(ExternalUnsignedIntElementsAccessor, \ 86 EXTERNAL_UNSIGNED_INT_ELEMENTS, ExternalUnsignedIntArray) \ 87 V(ExternalFloatElementsAccessor, \ 88 EXTERNAL_FLOAT_ELEMENTS, ExternalFloatArray) \ 89 V(ExternalDoubleElementsAccessor, \ 90 EXTERNAL_DOUBLE_ELEMENTS, ExternalDoubleArray) \ 91 V(PixelElementsAccessor, EXTERNAL_PIXEL_ELEMENTS, ExternalPixelArray) 92 93 94 template<ElementsKind Kind> class ElementsKindTraits { 95 public: 96 typedef FixedArrayBase BackingStore; 97 }; 98 99 #define ELEMENTS_TRAITS(Class, KindParam, Store) \ 100 template<> class ElementsKindTraits<KindParam> { \ 101 public: \ 102 static const ElementsKind Kind = KindParam; \ 103 typedef Store BackingStore; \ 104 }; 105 ELEMENTS_LIST(ELEMENTS_TRAITS) 106 #undef ELEMENTS_TRAITS 107 108 109 ElementsAccessor** ElementsAccessor::elements_accessors_; 110 111 112 static bool HasKey(FixedArray* array, Object* key) { 113 int len0 = array->length(); 114 for (int i = 0; i < len0; i++) { 115 Object* element = array->get(i); 116 if (element->IsSmi() && element == key) return true; 117 if (element->IsString() && 118 key->IsString() && String::cast(element)->Equals(String::cast(key))) { 119 return true; 120 } 121 } 122 return false; 123 } 124 125 126 static Failure* ThrowArrayLengthRangeError(Heap* heap) { 127 HandleScope scope(heap->isolate()); 128 return heap->isolate()->Throw( 129 *heap->isolate()->factory()->NewRangeError("invalid_array_length", 130 HandleVector<Object>(NULL, 0))); 131 } 132 133 134 void CopyObjectToObjectElements(FixedArray* from, 135 ElementsKind from_kind, 136 uint32_t from_start, 137 FixedArray* to, 138 ElementsKind to_kind, 139 uint32_t to_start, 140 int raw_copy_size) { 141 ASSERT(to->map() != HEAP->fixed_cow_array_map()); 142 ASSERT(from_kind == FAST_ELEMENTS || from_kind == FAST_SMI_ONLY_ELEMENTS); 143 ASSERT(to_kind == FAST_ELEMENTS || to_kind == FAST_SMI_ONLY_ELEMENTS); 144 int copy_size = raw_copy_size; 145 if (raw_copy_size < 0) { 146 ASSERT(raw_copy_size == ElementsAccessor::kCopyToEnd || 147 raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); 148 copy_size = Min(from->length() - from_start, 149 to->length() - to_start); 150 #ifdef DEBUG 151 // FAST_ELEMENT arrays cannot be uninitialized. Ensure they are already 152 // marked with the hole. 153 if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { 154 for (int i = to_start + copy_size; i < to->length(); ++i) { 155 ASSERT(to->get(i)->IsTheHole()); 156 } 157 } 158 #endif 159 } 160 ASSERT((copy_size + static_cast<int>(to_start)) <= to->length() && 161 (copy_size + static_cast<int>(from_start)) <= from->length()); 162 if (copy_size == 0) return; 163 Address to_address = to->address() + FixedArray::kHeaderSize; 164 Address from_address = from->address() + FixedArray::kHeaderSize; 165 CopyWords(reinterpret_cast<Object**>(to_address) + to_start, 166 reinterpret_cast<Object**>(from_address) + from_start, 167 copy_size); 168 if (from_kind == FAST_ELEMENTS && to_kind == FAST_ELEMENTS) { 169 Heap* heap = from->GetHeap(); 170 if (!heap->InNewSpace(to)) { 171 heap->RecordWrites(to->address(), 172 to->OffsetOfElementAt(to_start), 173 copy_size); 174 } 175 heap->incremental_marking()->RecordWrites(to); 176 } 177 } 178 179 180 static void CopyDictionaryToObjectElements(SeededNumberDictionary* from, 181 uint32_t from_start, 182 FixedArray* to, 183 ElementsKind to_kind, 184 uint32_t to_start, 185 int raw_copy_size) { 186 int copy_size = raw_copy_size; 187 Heap* heap = from->GetHeap(); 188 if (raw_copy_size < 0) { 189 ASSERT(raw_copy_size == ElementsAccessor::kCopyToEnd || 190 raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); 191 copy_size = from->max_number_key() + 1 - from_start; 192 #ifdef DEBUG 193 // FAST_ELEMENT arrays cannot be uninitialized. Ensure they are already 194 // marked with the hole. 195 if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { 196 for (int i = to_start + copy_size; i < to->length(); ++i) { 197 ASSERT(to->get(i)->IsTheHole()); 198 } 199 } 200 #endif 201 } 202 ASSERT(to != from); 203 ASSERT(to_kind == FAST_ELEMENTS || to_kind == FAST_SMI_ONLY_ELEMENTS); 204 if (copy_size == 0) return; 205 uint32_t to_length = to->length(); 206 if (to_start + copy_size > to_length) { 207 copy_size = to_length - to_start; 208 } 209 for (int i = 0; i < copy_size; i++) { 210 int entry = from->FindEntry(i + from_start); 211 if (entry != SeededNumberDictionary::kNotFound) { 212 Object* value = from->ValueAt(entry); 213 ASSERT(!value->IsTheHole()); 214 to->set(i + to_start, value, SKIP_WRITE_BARRIER); 215 } else { 216 to->set_the_hole(i + to_start); 217 } 218 } 219 if (to_kind == FAST_ELEMENTS) { 220 if (!heap->InNewSpace(to)) { 221 heap->RecordWrites(to->address(), 222 to->OffsetOfElementAt(to_start), 223 copy_size); 224 } 225 heap->incremental_marking()->RecordWrites(to); 226 } 227 } 228 229 230 MUST_USE_RESULT static MaybeObject* CopyDoubleToObjectElements( 231 FixedDoubleArray* from, 232 uint32_t from_start, 233 FixedArray* to, 234 ElementsKind to_kind, 235 uint32_t to_start, 236 int raw_copy_size) { 237 ASSERT(to_kind == FAST_ELEMENTS || to_kind == FAST_SMI_ONLY_ELEMENTS); 238 int copy_size = raw_copy_size; 239 if (raw_copy_size < 0) { 240 ASSERT(raw_copy_size == ElementsAccessor::kCopyToEnd || 241 raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); 242 copy_size = Min(from->length() - from_start, 243 to->length() - to_start); 244 #ifdef DEBUG 245 // FAST_ELEMENT arrays cannot be uninitialized. Ensure they are already 246 // marked with the hole. 247 if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { 248 for (int i = to_start + copy_size; i < to->length(); ++i) { 249 ASSERT(to->get(i)->IsTheHole()); 250 } 251 } 252 #endif 253 } 254 ASSERT((copy_size + static_cast<int>(to_start)) <= to->length() && 255 (copy_size + static_cast<int>(from_start)) <= from->length()); 256 if (copy_size == 0) return from; 257 for (int i = 0; i < copy_size; ++i) { 258 if (to_kind == FAST_SMI_ONLY_ELEMENTS) { 259 UNIMPLEMENTED(); 260 return Failure::Exception(); 261 } else { 262 MaybeObject* maybe_value = from->get(i + from_start); 263 Object* value; 264 ASSERT(to_kind == FAST_ELEMENTS); 265 // Because FAST_DOUBLE_ELEMENTS -> FAST_ELEMENT allocate HeapObjects 266 // iteratively, the allocate must succeed within a single GC cycle, 267 // otherwise the retry after the GC will also fail. In order to ensure 268 // that no GC is triggered, allocate HeapNumbers from old space if they 269 // can't be taken from new space. 270 if (!maybe_value->ToObject(&value)) { 271 ASSERT(maybe_value->IsRetryAfterGC() || maybe_value->IsOutOfMemory()); 272 Heap* heap = from->GetHeap(); 273 MaybeObject* maybe_value_object = 274 heap->AllocateHeapNumber(from->get_scalar(i + from_start), 275 TENURED); 276 if (!maybe_value_object->ToObject(&value)) return maybe_value_object; 277 } 278 to->set(i + to_start, value, UPDATE_WRITE_BARRIER); 279 } 280 } 281 return to; 282 } 283 284 285 static void CopyDoubleToDoubleElements(FixedDoubleArray* from, 286 uint32_t from_start, 287 FixedDoubleArray* to, 288 uint32_t to_start, 289 int raw_copy_size) { 290 int copy_size = raw_copy_size; 291 if (raw_copy_size < 0) { 292 ASSERT(raw_copy_size == ElementsAccessor::kCopyToEnd || 293 raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); 294 copy_size = Min(from->length() - from_start, 295 to->length() - to_start); 296 if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { 297 for (int i = to_start + copy_size; i < to->length(); ++i) { 298 to->set_the_hole(i); 299 } 300 } 301 } 302 ASSERT((copy_size + static_cast<int>(to_start)) <= to->length() && 303 (copy_size + static_cast<int>(from_start)) <= from->length()); 304 if (copy_size == 0) return; 305 Address to_address = to->address() + FixedDoubleArray::kHeaderSize; 306 Address from_address = from->address() + FixedDoubleArray::kHeaderSize; 307 to_address += kDoubleSize * to_start; 308 from_address += kDoubleSize * from_start; 309 int words_per_double = (kDoubleSize / kPointerSize); 310 CopyWords(reinterpret_cast<Object**>(to_address), 311 reinterpret_cast<Object**>(from_address), 312 words_per_double * copy_size); 313 } 314 315 316 static void CopyObjectToDoubleElements(FixedArray* from, 317 uint32_t from_start, 318 FixedDoubleArray* to, 319 uint32_t to_start, 320 int raw_copy_size) { 321 int copy_size = raw_copy_size; 322 if (raw_copy_size < 0) { 323 ASSERT(raw_copy_size == ElementsAccessor::kCopyToEnd || 324 raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); 325 copy_size = from->length() - from_start; 326 if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { 327 for (int i = to_start + copy_size; i < to->length(); ++i) { 328 to->set_the_hole(i); 329 } 330 } 331 } 332 ASSERT((copy_size + static_cast<int>(to_start)) <= to->length() && 333 (copy_size + static_cast<int>(from_start)) <= from->length()); 334 if (copy_size == 0) return; 335 for (int i = 0; i < copy_size; i++) { 336 Object* hole_or_object = from->get(i + from_start); 337 if (hole_or_object->IsTheHole()) { 338 to->set_the_hole(i + to_start); 339 } else { 340 to->set(i + to_start, hole_or_object->Number()); 341 } 342 } 343 } 344 345 346 static void CopyDictionaryToDoubleElements(SeededNumberDictionary* from, 347 uint32_t from_start, 348 FixedDoubleArray* to, 349 uint32_t to_start, 350 int raw_copy_size) { 351 int copy_size = raw_copy_size; 352 if (copy_size < 0) { 353 ASSERT(copy_size == ElementsAccessor::kCopyToEnd || 354 copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole); 355 copy_size = from->max_number_key() + 1 - from_start; 356 if (raw_copy_size == ElementsAccessor::kCopyToEndAndInitializeToHole) { 357 for (int i = to_start + copy_size; i < to->length(); ++i) { 358 to->set_the_hole(i); 359 } 360 } 361 } 362 if (copy_size == 0) return; 363 uint32_t to_length = to->length(); 364 if (to_start + copy_size > to_length) { 365 copy_size = to_length - to_start; 366 } 367 for (int i = 0; i < copy_size; i++) { 368 int entry = from->FindEntry(i + from_start); 369 if (entry != SeededNumberDictionary::kNotFound) { 370 to->set(i + to_start, from->ValueAt(entry)->Number()); 371 } else { 372 to->set_the_hole(i + to_start); 373 } 374 } 375 } 376 377 378 // Base class for element handler implementations. Contains the 379 // the common logic for objects with different ElementsKinds. 380 // Subclasses must specialize method for which the element 381 // implementation differs from the base class implementation. 382 // 383 // This class is intended to be used in the following way: 384 // 385 // class SomeElementsAccessor : 386 // public ElementsAccessorBase<SomeElementsAccessor, 387 // BackingStoreClass> { 388 // ... 389 // } 390 // 391 // This is an example of the Curiously Recurring Template Pattern (see 392 // http://en.wikipedia.org/wiki/Curiously_recurring_template_pattern). We use 393 // CRTP to guarantee aggressive compile time optimizations (i.e. inlining and 394 // specialization of SomeElementsAccessor methods). 395 template <typename ElementsAccessorSubclass, 396 typename ElementsTraitsParam> 397 class ElementsAccessorBase : public ElementsAccessor { 398 protected: 399 explicit ElementsAccessorBase(const char* name) 400 : ElementsAccessor(name) { } 401 402 typedef ElementsTraitsParam ElementsTraits; 403 typedef typename ElementsTraitsParam::BackingStore BackingStore; 404 405 virtual ElementsKind kind() const { return ElementsTraits::Kind; } 406 407 static bool HasElementImpl(Object* receiver, 408 JSObject* holder, 409 uint32_t key, 410 BackingStore* backing_store) { 411 MaybeObject* element = 412 ElementsAccessorSubclass::GetImpl(receiver, holder, key, backing_store); 413 return !element->IsTheHole(); 414 } 415 416 virtual bool HasElement(Object* receiver, 417 JSObject* holder, 418 uint32_t key, 419 FixedArrayBase* backing_store) { 420 if (backing_store == NULL) { 421 backing_store = holder->elements(); 422 } 423 return ElementsAccessorSubclass::HasElementImpl( 424 receiver, holder, key, BackingStore::cast(backing_store)); 425 } 426 427 virtual MaybeObject* Get(Object* receiver, 428 JSObject* holder, 429 uint32_t key, 430 FixedArrayBase* backing_store) { 431 if (backing_store == NULL) { 432 backing_store = holder->elements(); 433 } 434 return ElementsAccessorSubclass::GetImpl( 435 receiver, holder, key, BackingStore::cast(backing_store)); 436 } 437 438 static MaybeObject* GetImpl(Object* receiver, 439 JSObject* obj, 440 uint32_t key, 441 BackingStore* backing_store) { 442 return (key < ElementsAccessorSubclass::GetCapacityImpl(backing_store)) 443 ? backing_store->get(key) 444 : backing_store->GetHeap()->the_hole_value(); 445 } 446 447 virtual MaybeObject* SetLength(JSArray* array, 448 Object* length) { 449 return ElementsAccessorSubclass::SetLengthImpl( 450 array, length, BackingStore::cast(array->elements())); 451 } 452 453 static MaybeObject* SetLengthImpl(JSObject* obj, 454 Object* length, 455 BackingStore* backing_store); 456 457 virtual MaybeObject* SetCapacityAndLength(JSArray* array, 458 int capacity, 459 int length) { 460 return ElementsAccessorSubclass::SetFastElementsCapacityAndLength( 461 array, 462 capacity, 463 length); 464 } 465 466 static MaybeObject* SetFastElementsCapacityAndLength(JSObject* obj, 467 int capacity, 468 int length) { 469 UNIMPLEMENTED(); 470 return obj; 471 } 472 473 virtual MaybeObject* Delete(JSObject* obj, 474 uint32_t key, 475 JSReceiver::DeleteMode mode) = 0; 476 477 static MaybeObject* CopyElementsImpl(FixedArrayBase* from, 478 uint32_t from_start, 479 FixedArrayBase* to, 480 ElementsKind to_kind, 481 uint32_t to_start, 482 int copy_size) { 483 UNREACHABLE(); 484 return NULL; 485 } 486 487 virtual MaybeObject* CopyElements(JSObject* from_holder, 488 uint32_t from_start, 489 FixedArrayBase* to, 490 ElementsKind to_kind, 491 uint32_t to_start, 492 int copy_size, 493 FixedArrayBase* from) { 494 if (from == NULL) { 495 from = from_holder->elements(); 496 } 497 if (from->length() == 0) { 498 return from; 499 } 500 return ElementsAccessorSubclass::CopyElementsImpl( 501 from, from_start, to, to_kind, to_start, copy_size); 502 } 503 504 virtual MaybeObject* AddElementsToFixedArray(Object* receiver, 505 JSObject* holder, 506 FixedArray* to, 507 FixedArrayBase* from) { 508 int len0 = to->length(); 509 #ifdef DEBUG 510 if (FLAG_enable_slow_asserts) { 511 for (int i = 0; i < len0; i++) { 512 ASSERT(!to->get(i)->IsTheHole()); 513 } 514 } 515 #endif 516 if (from == NULL) { 517 from = holder->elements(); 518 } 519 BackingStore* backing_store = BackingStore::cast(from); 520 uint32_t len1 = ElementsAccessorSubclass::GetCapacityImpl(backing_store); 521 522 // Optimize if 'other' is empty. 523 // We cannot optimize if 'this' is empty, as other may have holes. 524 if (len1 == 0) return to; 525 526 // Compute how many elements are not in other. 527 uint32_t extra = 0; 528 for (uint32_t y = 0; y < len1; y++) { 529 uint32_t key = 530 ElementsAccessorSubclass::GetKeyForIndexImpl(backing_store, y); 531 if (ElementsAccessorSubclass::HasElementImpl( 532 receiver, holder, key, backing_store)) { 533 MaybeObject* maybe_value = 534 ElementsAccessorSubclass::GetImpl(receiver, holder, 535 key, backing_store); 536 Object* value; 537 if (!maybe_value->ToObject(&value)) return maybe_value; 538 ASSERT(!value->IsTheHole()); 539 if (!HasKey(to, value)) { 540 extra++; 541 } 542 } 543 } 544 545 if (extra == 0) return to; 546 547 // Allocate the result 548 FixedArray* result; 549 MaybeObject* maybe_obj = 550 backing_store->GetHeap()->AllocateFixedArray(len0 + extra); 551 if (!maybe_obj->To<FixedArray>(&result)) return maybe_obj; 552 553 // Fill in the content 554 { 555 AssertNoAllocation no_gc; 556 WriteBarrierMode mode = result->GetWriteBarrierMode(no_gc); 557 for (int i = 0; i < len0; i++) { 558 Object* e = to->get(i); 559 ASSERT(e->IsString() || e->IsNumber()); 560 result->set(i, e, mode); 561 } 562 } 563 // Fill in the extra values. 564 uint32_t index = 0; 565 for (uint32_t y = 0; y < len1; y++) { 566 uint32_t key = 567 ElementsAccessorSubclass::GetKeyForIndexImpl(backing_store, y); 568 if (ElementsAccessorSubclass::HasElementImpl( 569 receiver, holder, key, backing_store)) { 570 MaybeObject* maybe_value = 571 ElementsAccessorSubclass::GetImpl(receiver, holder, 572 key, backing_store); 573 Object* value; 574 if (!maybe_value->ToObject(&value)) return maybe_value; 575 if (!value->IsTheHole() && !HasKey(to, value)) { 576 result->set(len0 + index, value); 577 index++; 578 } 579 } 580 } 581 ASSERT(extra == index); 582 return result; 583 } 584 585 protected: 586 static uint32_t GetCapacityImpl(BackingStore* backing_store) { 587 return backing_store->length(); 588 } 589 590 virtual uint32_t GetCapacity(FixedArrayBase* backing_store) { 591 return ElementsAccessorSubclass::GetCapacityImpl( 592 BackingStore::cast(backing_store)); 593 } 594 595 static uint32_t GetKeyForIndexImpl(BackingStore* backing_store, 596 uint32_t index) { 597 return index; 598 } 599 600 virtual uint32_t GetKeyForIndex(FixedArrayBase* backing_store, 601 uint32_t index) { 602 return ElementsAccessorSubclass::GetKeyForIndexImpl( 603 BackingStore::cast(backing_store), index); 604 } 605 606 private: 607 DISALLOW_COPY_AND_ASSIGN(ElementsAccessorBase); 608 }; 609 610 611 // Super class for all fast element arrays. 612 template<typename FastElementsAccessorSubclass, 613 typename KindTraits, 614 int ElementSize> 615 class FastElementsAccessor 616 : public ElementsAccessorBase<FastElementsAccessorSubclass, KindTraits> { 617 public: 618 explicit FastElementsAccessor(const char* name) 619 : ElementsAccessorBase<FastElementsAccessorSubclass, 620 KindTraits>(name) {} 621 protected: 622 friend class ElementsAccessorBase<FastElementsAccessorSubclass, KindTraits>; 623 624 typedef typename KindTraits::BackingStore BackingStore; 625 626 // Adjusts the length of the fast backing store or returns the new length or 627 // undefined in case conversion to a slow backing store should be performed. 628 static MaybeObject* SetLengthWithoutNormalize(BackingStore* backing_store, 629 JSArray* array, 630 Object* length_object, 631 uint32_t length) { 632 uint32_t old_capacity = backing_store->length(); 633 634 // Check whether the backing store should be shrunk. 635 if (length <= old_capacity) { 636 if (array->HasFastTypeElements()) { 637 MaybeObject* maybe_obj = array->EnsureWritableFastElements(); 638 if (!maybe_obj->To(&backing_store)) return maybe_obj; 639 } 640 if (2 * length <= old_capacity) { 641 // If more than half the elements won't be used, trim the array. 642 if (length == 0) { 643 array->initialize_elements(); 644 } else { 645 backing_store->set_length(length); 646 Address filler_start = backing_store->address() + 647 BackingStore::OffsetOfElementAt(length); 648 int filler_size = (old_capacity - length) * ElementSize; 649 array->GetHeap()->CreateFillerObjectAt(filler_start, filler_size); 650 } 651 } else { 652 // Otherwise, fill the unused tail with holes. 653 int old_length = FastD2I(array->length()->Number()); 654 for (int i = length; i < old_length; i++) { 655 backing_store->set_the_hole(i); 656 } 657 } 658 return length_object; 659 } 660 661 // Check whether the backing store should be expanded. 662 uint32_t min = JSObject::NewElementsCapacity(old_capacity); 663 uint32_t new_capacity = length > min ? length : min; 664 if (!array->ShouldConvertToSlowElements(new_capacity)) { 665 MaybeObject* result = FastElementsAccessorSubclass:: 666 SetFastElementsCapacityAndLength(array, new_capacity, length); 667 if (result->IsFailure()) return result; 668 return length_object; 669 } 670 671 // Request conversion to slow elements. 672 return array->GetHeap()->undefined_value(); 673 } 674 }; 675 676 677 class FastObjectElementsAccessor 678 : public FastElementsAccessor<FastObjectElementsAccessor, 679 ElementsKindTraits<FAST_ELEMENTS>, 680 kPointerSize> { 681 public: 682 explicit FastObjectElementsAccessor(const char* name) 683 : FastElementsAccessor<FastObjectElementsAccessor, 684 ElementsKindTraits<FAST_ELEMENTS>, 685 kPointerSize>(name) {} 686 687 static MaybeObject* DeleteCommon(JSObject* obj, 688 uint32_t key) { 689 ASSERT(obj->HasFastElements() || 690 obj->HasFastSmiOnlyElements() || 691 obj->HasFastArgumentsElements()); 692 Heap* heap = obj->GetHeap(); 693 FixedArray* backing_store = FixedArray::cast(obj->elements()); 694 if (backing_store->map() == heap->non_strict_arguments_elements_map()) { 695 backing_store = FixedArray::cast(backing_store->get(1)); 696 } else { 697 Object* writable; 698 MaybeObject* maybe = obj->EnsureWritableFastElements(); 699 if (!maybe->ToObject(&writable)) return maybe; 700 backing_store = FixedArray::cast(writable); 701 } 702 uint32_t length = static_cast<uint32_t>( 703 obj->IsJSArray() 704 ? Smi::cast(JSArray::cast(obj)->length())->value() 705 : backing_store->length()); 706 if (key < length) { 707 backing_store->set_the_hole(key); 708 // If an old space backing store is larger than a certain size and 709 // has too few used values, normalize it. 710 // To avoid doing the check on every delete we require at least 711 // one adjacent hole to the value being deleted. 712 Object* hole = heap->the_hole_value(); 713 const int kMinLengthForSparsenessCheck = 64; 714 if (backing_store->length() >= kMinLengthForSparsenessCheck && 715 !heap->InNewSpace(backing_store) && 716 ((key > 0 && backing_store->get(key - 1) == hole) || 717 (key + 1 < length && backing_store->get(key + 1) == hole))) { 718 int num_used = 0; 719 for (int i = 0; i < backing_store->length(); ++i) { 720 if (backing_store->get(i) != hole) ++num_used; 721 // Bail out early if more than 1/4 is used. 722 if (4 * num_used > backing_store->length()) break; 723 } 724 if (4 * num_used <= backing_store->length()) { 725 MaybeObject* result = obj->NormalizeElements(); 726 if (result->IsFailure()) return result; 727 } 728 } 729 } 730 return heap->true_value(); 731 } 732 733 static MaybeObject* CopyElementsImpl(FixedArrayBase* from, 734 uint32_t from_start, 735 FixedArrayBase* to, 736 ElementsKind to_kind, 737 uint32_t to_start, 738 int copy_size) { 739 switch (to_kind) { 740 case FAST_SMI_ONLY_ELEMENTS: 741 case FAST_ELEMENTS: { 742 CopyObjectToObjectElements( 743 FixedArray::cast(from), ElementsTraits::Kind, from_start, 744 FixedArray::cast(to), to_kind, to_start, copy_size); 745 return from; 746 } 747 case FAST_DOUBLE_ELEMENTS: 748 CopyObjectToDoubleElements( 749 FixedArray::cast(from), from_start, 750 FixedDoubleArray::cast(to), to_start, copy_size); 751 return from; 752 default: 753 UNREACHABLE(); 754 } 755 return to->GetHeap()->undefined_value(); 756 } 757 758 759 static MaybeObject* SetFastElementsCapacityAndLength(JSObject* obj, 760 uint32_t capacity, 761 uint32_t length) { 762 JSObject::SetFastElementsCapacityMode set_capacity_mode = 763 obj->HasFastSmiOnlyElements() 764 ? JSObject::kAllowSmiOnlyElements 765 : JSObject::kDontAllowSmiOnlyElements; 766 return obj->SetFastElementsCapacityAndLength(capacity, 767 length, 768 set_capacity_mode); 769 } 770 771 protected: 772 friend class FastElementsAccessor<FastObjectElementsAccessor, 773 ElementsKindTraits<FAST_ELEMENTS>, 774 kPointerSize>; 775 776 virtual MaybeObject* Delete(JSObject* obj, 777 uint32_t key, 778 JSReceiver::DeleteMode mode) { 779 return DeleteCommon(obj, key); 780 } 781 }; 782 783 784 class FastDoubleElementsAccessor 785 : public FastElementsAccessor<FastDoubleElementsAccessor, 786 ElementsKindTraits<FAST_DOUBLE_ELEMENTS>, 787 kDoubleSize> { 788 public: 789 explicit FastDoubleElementsAccessor(const char* name) 790 : FastElementsAccessor<FastDoubleElementsAccessor, 791 ElementsKindTraits<FAST_DOUBLE_ELEMENTS>, 792 kDoubleSize>(name) {} 793 794 static MaybeObject* SetFastElementsCapacityAndLength(JSObject* obj, 795 uint32_t capacity, 796 uint32_t length) { 797 return obj->SetFastDoubleElementsCapacityAndLength(capacity, length); 798 } 799 800 protected: 801 friend class ElementsAccessorBase<FastDoubleElementsAccessor, 802 ElementsKindTraits<FAST_DOUBLE_ELEMENTS> >; 803 friend class FastElementsAccessor<FastDoubleElementsAccessor, 804 ElementsKindTraits<FAST_DOUBLE_ELEMENTS>, 805 kDoubleSize>; 806 807 static MaybeObject* CopyElementsImpl(FixedArrayBase* from, 808 uint32_t from_start, 809 FixedArrayBase* to, 810 ElementsKind to_kind, 811 uint32_t to_start, 812 int copy_size) { 813 switch (to_kind) { 814 case FAST_SMI_ONLY_ELEMENTS: 815 case FAST_ELEMENTS: 816 return CopyDoubleToObjectElements( 817 FixedDoubleArray::cast(from), from_start, FixedArray::cast(to), 818 to_kind, to_start, copy_size); 819 case FAST_DOUBLE_ELEMENTS: 820 CopyDoubleToDoubleElements(FixedDoubleArray::cast(from), from_start, 821 FixedDoubleArray::cast(to), 822 to_start, copy_size); 823 return from; 824 default: 825 UNREACHABLE(); 826 } 827 return to->GetHeap()->undefined_value(); 828 } 829 830 virtual MaybeObject* Delete(JSObject* obj, 831 uint32_t key, 832 JSReceiver::DeleteMode mode) { 833 int length = obj->IsJSArray() 834 ? Smi::cast(JSArray::cast(obj)->length())->value() 835 : FixedDoubleArray::cast(obj->elements())->length(); 836 if (key < static_cast<uint32_t>(length)) { 837 FixedDoubleArray::cast(obj->elements())->set_the_hole(key); 838 } 839 return obj->GetHeap()->true_value(); 840 } 841 842 static bool HasElementImpl(Object* receiver, 843 JSObject* holder, 844 uint32_t key, 845 FixedDoubleArray* backing_store) { 846 return key < static_cast<uint32_t>(backing_store->length()) && 847 !backing_store->is_the_hole(key); 848 } 849 }; 850 851 852 // Super class for all external element arrays. 853 template<typename ExternalElementsAccessorSubclass, 854 ElementsKind Kind> 855 class ExternalElementsAccessor 856 : public ElementsAccessorBase<ExternalElementsAccessorSubclass, 857 ElementsKindTraits<Kind> > { 858 public: 859 explicit ExternalElementsAccessor(const char* name) 860 : ElementsAccessorBase<ExternalElementsAccessorSubclass, 861 ElementsKindTraits<Kind> >(name) {} 862 863 protected: 864 typedef typename ElementsKindTraits<Kind>::BackingStore BackingStore; 865 866 friend class ElementsAccessorBase<ExternalElementsAccessorSubclass, 867 ElementsKindTraits<Kind> >; 868 869 static MaybeObject* GetImpl(Object* receiver, 870 JSObject* obj, 871 uint32_t key, 872 BackingStore* backing_store) { 873 return 874 key < ExternalElementsAccessorSubclass::GetCapacityImpl(backing_store) 875 ? backing_store->get(key) 876 : backing_store->GetHeap()->undefined_value(); 877 } 878 879 static MaybeObject* SetLengthImpl(JSObject* obj, 880 Object* length, 881 BackingStore* backing_store) { 882 // External arrays do not support changing their length. 883 UNREACHABLE(); 884 return obj; 885 } 886 887 virtual MaybeObject* Delete(JSObject* obj, 888 uint32_t key, 889 JSReceiver::DeleteMode mode) { 890 // External arrays always ignore deletes. 891 return obj->GetHeap()->true_value(); 892 } 893 894 static bool HasElementImpl(Object* receiver, 895 JSObject* holder, 896 uint32_t key, 897 BackingStore* backing_store) { 898 uint32_t capacity = 899 ExternalElementsAccessorSubclass::GetCapacityImpl(backing_store); 900 return key < capacity; 901 } 902 }; 903 904 905 class ExternalByteElementsAccessor 906 : public ExternalElementsAccessor<ExternalByteElementsAccessor, 907 EXTERNAL_BYTE_ELEMENTS> { 908 public: 909 explicit ExternalByteElementsAccessor(const char* name) 910 : ExternalElementsAccessor<ExternalByteElementsAccessor, 911 EXTERNAL_BYTE_ELEMENTS>(name) {} 912 }; 913 914 915 class ExternalUnsignedByteElementsAccessor 916 : public ExternalElementsAccessor<ExternalUnsignedByteElementsAccessor, 917 EXTERNAL_UNSIGNED_BYTE_ELEMENTS> { 918 public: 919 explicit ExternalUnsignedByteElementsAccessor(const char* name) 920 : ExternalElementsAccessor<ExternalUnsignedByteElementsAccessor, 921 EXTERNAL_UNSIGNED_BYTE_ELEMENTS>(name) {} 922 }; 923 924 925 class ExternalShortElementsAccessor 926 : public ExternalElementsAccessor<ExternalShortElementsAccessor, 927 EXTERNAL_SHORT_ELEMENTS> { 928 public: 929 explicit ExternalShortElementsAccessor(const char* name) 930 : ExternalElementsAccessor<ExternalShortElementsAccessor, 931 EXTERNAL_SHORT_ELEMENTS>(name) {} 932 }; 933 934 935 class ExternalUnsignedShortElementsAccessor 936 : public ExternalElementsAccessor<ExternalUnsignedShortElementsAccessor, 937 EXTERNAL_UNSIGNED_SHORT_ELEMENTS> { 938 public: 939 explicit ExternalUnsignedShortElementsAccessor(const char* name) 940 : ExternalElementsAccessor<ExternalUnsignedShortElementsAccessor, 941 EXTERNAL_UNSIGNED_SHORT_ELEMENTS>(name) {} 942 }; 943 944 945 class ExternalIntElementsAccessor 946 : public ExternalElementsAccessor<ExternalIntElementsAccessor, 947 EXTERNAL_INT_ELEMENTS> { 948 public: 949 explicit ExternalIntElementsAccessor(const char* name) 950 : ExternalElementsAccessor<ExternalIntElementsAccessor, 951 EXTERNAL_INT_ELEMENTS>(name) {} 952 }; 953 954 955 class ExternalUnsignedIntElementsAccessor 956 : public ExternalElementsAccessor<ExternalUnsignedIntElementsAccessor, 957 EXTERNAL_UNSIGNED_INT_ELEMENTS> { 958 public: 959 explicit ExternalUnsignedIntElementsAccessor(const char* name) 960 : ExternalElementsAccessor<ExternalUnsignedIntElementsAccessor, 961 EXTERNAL_UNSIGNED_INT_ELEMENTS>(name) {} 962 }; 963 964 965 class ExternalFloatElementsAccessor 966 : public ExternalElementsAccessor<ExternalFloatElementsAccessor, 967 EXTERNAL_FLOAT_ELEMENTS> { 968 public: 969 explicit ExternalFloatElementsAccessor(const char* name) 970 : ExternalElementsAccessor<ExternalFloatElementsAccessor, 971 EXTERNAL_FLOAT_ELEMENTS>(name) {} 972 }; 973 974 975 class ExternalDoubleElementsAccessor 976 : public ExternalElementsAccessor<ExternalDoubleElementsAccessor, 977 EXTERNAL_DOUBLE_ELEMENTS> { 978 public: 979 explicit ExternalDoubleElementsAccessor(const char* name) 980 : ExternalElementsAccessor<ExternalDoubleElementsAccessor, 981 EXTERNAL_DOUBLE_ELEMENTS>(name) {} 982 }; 983 984 985 class PixelElementsAccessor 986 : public ExternalElementsAccessor<PixelElementsAccessor, 987 EXTERNAL_PIXEL_ELEMENTS> { 988 public: 989 explicit PixelElementsAccessor(const char* name) 990 : ExternalElementsAccessor<PixelElementsAccessor, 991 EXTERNAL_PIXEL_ELEMENTS>(name) {} 992 }; 993 994 995 class DictionaryElementsAccessor 996 : public ElementsAccessorBase<DictionaryElementsAccessor, 997 ElementsKindTraits<DICTIONARY_ELEMENTS> > { 998 public: 999 explicit DictionaryElementsAccessor(const char* name) 1000 : ElementsAccessorBase<DictionaryElementsAccessor, 1001 ElementsKindTraits<DICTIONARY_ELEMENTS> >(name) {} 1002 1003 // Adjusts the length of the dictionary backing store and returns the new 1004 // length according to ES5 section 15.4.5.2 behavior. 1005 static MaybeObject* SetLengthWithoutNormalize(SeededNumberDictionary* dict, 1006 JSArray* array, 1007 Object* length_object, 1008 uint32_t length) { 1009 if (length == 0) { 1010 // If the length of a slow array is reset to zero, we clear 1011 // the array and flush backing storage. This has the added 1012 // benefit that the array returns to fast mode. 1013 Object* obj; 1014 MaybeObject* maybe_obj = array->ResetElements(); 1015 if (!maybe_obj->ToObject(&obj)) return maybe_obj; 1016 } else { 1017 uint32_t new_length = length; 1018 uint32_t old_length = static_cast<uint32_t>(array->length()->Number()); 1019 if (new_length < old_length) { 1020 // Find last non-deletable element in range of elements to be 1021 // deleted and adjust range accordingly. 1022 Heap* heap = array->GetHeap(); 1023 int capacity = dict->Capacity(); 1024 for (int i = 0; i < capacity; i++) { 1025 Object* key = dict->KeyAt(i); 1026 if (key->IsNumber()) { 1027 uint32_t number = static_cast<uint32_t>(key->Number()); 1028 if (new_length <= number && number < old_length) { 1029 PropertyDetails details = dict->DetailsAt(i); 1030 if (details.IsDontDelete()) new_length = number + 1; 1031 } 1032 } 1033 } 1034 if (new_length != length) { 1035 MaybeObject* maybe_object = heap->NumberFromUint32(new_length); 1036 if (!maybe_object->To(&length_object)) return maybe_object; 1037 } 1038 1039 // Remove elements that should be deleted. 1040 int removed_entries = 0; 1041 Object* the_hole_value = heap->the_hole_value(); 1042 for (int i = 0; i < capacity; i++) { 1043 Object* key = dict->KeyAt(i); 1044 if (key->IsNumber()) { 1045 uint32_t number = static_cast<uint32_t>(key->Number()); 1046 if (new_length <= number && number < old_length) { 1047 dict->SetEntry(i, the_hole_value, the_hole_value); 1048 removed_entries++; 1049 } 1050 } 1051 } 1052 1053 // Update the number of elements. 1054 dict->ElementsRemoved(removed_entries); 1055 } 1056 } 1057 return length_object; 1058 } 1059 1060 static MaybeObject* DeleteCommon(JSObject* obj, 1061 uint32_t key, 1062 JSReceiver::DeleteMode mode) { 1063 Isolate* isolate = obj->GetIsolate(); 1064 Heap* heap = isolate->heap(); 1065 FixedArray* backing_store = FixedArray::cast(obj->elements()); 1066 bool is_arguments = 1067 (obj->GetElementsKind() == NON_STRICT_ARGUMENTS_ELEMENTS); 1068 if (is_arguments) { 1069 backing_store = FixedArray::cast(backing_store->get(1)); 1070 } 1071 SeededNumberDictionary* dictionary = 1072 SeededNumberDictionary::cast(backing_store); 1073 int entry = dictionary->FindEntry(key); 1074 if (entry != SeededNumberDictionary::kNotFound) { 1075 Object* result = dictionary->DeleteProperty(entry, mode); 1076 if (result == heap->true_value()) { 1077 MaybeObject* maybe_elements = dictionary->Shrink(key); 1078 FixedArray* new_elements = NULL; 1079 if (!maybe_elements->To(&new_elements)) { 1080 return maybe_elements; 1081 } 1082 if (is_arguments) { 1083 FixedArray::cast(obj->elements())->set(1, new_elements); 1084 } else { 1085 obj->set_elements(new_elements); 1086 } 1087 } 1088 if (mode == JSObject::STRICT_DELETION && 1089 result == heap->false_value()) { 1090 // In strict mode, attempting to delete a non-configurable property 1091 // throws an exception. 1092 HandleScope scope(isolate); 1093 Handle<Object> holder(obj); 1094 Handle<Object> name = isolate->factory()->NewNumberFromUint(key); 1095 Handle<Object> args[2] = { name, holder }; 1096 Handle<Object> error = 1097 isolate->factory()->NewTypeError("strict_delete_property", 1098 HandleVector(args, 2)); 1099 return isolate->Throw(*error); 1100 } 1101 } 1102 return heap->true_value(); 1103 } 1104 1105 static MaybeObject* CopyElementsImpl(FixedArrayBase* from, 1106 uint32_t from_start, 1107 FixedArrayBase* to, 1108 ElementsKind to_kind, 1109 uint32_t to_start, 1110 int copy_size) { 1111 switch (to_kind) { 1112 case FAST_SMI_ONLY_ELEMENTS: 1113 case FAST_ELEMENTS: 1114 CopyDictionaryToObjectElements( 1115 SeededNumberDictionary::cast(from), from_start, 1116 FixedArray::cast(to), to_kind, to_start, copy_size); 1117 return from; 1118 case FAST_DOUBLE_ELEMENTS: 1119 CopyDictionaryToDoubleElements( 1120 SeededNumberDictionary::cast(from), from_start, 1121 FixedDoubleArray::cast(to), to_start, copy_size); 1122 return from; 1123 default: 1124 UNREACHABLE(); 1125 } 1126 return to->GetHeap()->undefined_value(); 1127 } 1128 1129 1130 protected: 1131 friend class ElementsAccessorBase<DictionaryElementsAccessor, 1132 ElementsKindTraits<DICTIONARY_ELEMENTS> >; 1133 1134 virtual MaybeObject* Delete(JSObject* obj, 1135 uint32_t key, 1136 JSReceiver::DeleteMode mode) { 1137 return DeleteCommon(obj, key, mode); 1138 } 1139 1140 static MaybeObject* GetImpl(Object* receiver, 1141 JSObject* obj, 1142 uint32_t key, 1143 SeededNumberDictionary* backing_store) { 1144 int entry = backing_store->FindEntry(key); 1145 if (entry != SeededNumberDictionary::kNotFound) { 1146 Object* element = backing_store->ValueAt(entry); 1147 PropertyDetails details = backing_store->DetailsAt(entry); 1148 if (details.type() == CALLBACKS) { 1149 return obj->GetElementWithCallback(receiver, 1150 element, 1151 key, 1152 obj); 1153 } else { 1154 return element; 1155 } 1156 } 1157 return obj->GetHeap()->the_hole_value(); 1158 } 1159 1160 static bool HasElementImpl(Object* receiver, 1161 JSObject* holder, 1162 uint32_t key, 1163 SeededNumberDictionary* backing_store) { 1164 return backing_store->FindEntry(key) != 1165 SeededNumberDictionary::kNotFound; 1166 } 1167 1168 static uint32_t GetKeyForIndexImpl(SeededNumberDictionary* dict, 1169 uint32_t index) { 1170 Object* key = dict->KeyAt(index); 1171 return Smi::cast(key)->value(); 1172 } 1173 }; 1174 1175 1176 class NonStrictArgumentsElementsAccessor : public ElementsAccessorBase< 1177 NonStrictArgumentsElementsAccessor, 1178 ElementsKindTraits<NON_STRICT_ARGUMENTS_ELEMENTS> > { 1179 public: 1180 explicit NonStrictArgumentsElementsAccessor(const char* name) 1181 : ElementsAccessorBase< 1182 NonStrictArgumentsElementsAccessor, 1183 ElementsKindTraits<NON_STRICT_ARGUMENTS_ELEMENTS> >(name) {} 1184 protected: 1185 friend class ElementsAccessorBase< 1186 NonStrictArgumentsElementsAccessor, 1187 ElementsKindTraits<NON_STRICT_ARGUMENTS_ELEMENTS> >; 1188 1189 static MaybeObject* GetImpl(Object* receiver, 1190 JSObject* obj, 1191 uint32_t key, 1192 FixedArray* parameter_map) { 1193 Object* probe = GetParameterMapArg(obj, parameter_map, key); 1194 if (!probe->IsTheHole()) { 1195 Context* context = Context::cast(parameter_map->get(0)); 1196 int context_index = Smi::cast(probe)->value(); 1197 ASSERT(!context->get(context_index)->IsTheHole()); 1198 return context->get(context_index); 1199 } else { 1200 // Object is not mapped, defer to the arguments. 1201 FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); 1202 MaybeObject* maybe_result = ElementsAccessor::ForArray(arguments)->Get( 1203 receiver, obj, key, arguments); 1204 Object* result; 1205 if (!maybe_result->ToObject(&result)) return maybe_result; 1206 // Elements of the arguments object in slow mode might be slow aliases. 1207 if (result->IsAliasedArgumentsEntry()) { 1208 AliasedArgumentsEntry* entry = AliasedArgumentsEntry::cast(result); 1209 Context* context = Context::cast(parameter_map->get(0)); 1210 int context_index = entry->aliased_context_slot(); 1211 ASSERT(!context->get(context_index)->IsTheHole()); 1212 return context->get(context_index); 1213 } else { 1214 return result; 1215 } 1216 } 1217 } 1218 1219 static MaybeObject* SetLengthImpl(JSObject* obj, 1220 Object* length, 1221 FixedArray* parameter_map) { 1222 // TODO(mstarzinger): This was never implemented but will be used once we 1223 // correctly implement [[DefineOwnProperty]] on arrays. 1224 UNIMPLEMENTED(); 1225 return obj; 1226 } 1227 1228 virtual MaybeObject* Delete(JSObject* obj, 1229 uint32_t key, 1230 JSReceiver::DeleteMode mode) { 1231 FixedArray* parameter_map = FixedArray::cast(obj->elements()); 1232 Object* probe = GetParameterMapArg(obj, parameter_map, key); 1233 if (!probe->IsTheHole()) { 1234 // TODO(kmillikin): We could check if this was the last aliased 1235 // parameter, and revert to normal elements in that case. That 1236 // would enable GC of the context. 1237 parameter_map->set_the_hole(key + 2); 1238 } else { 1239 FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); 1240 if (arguments->IsDictionary()) { 1241 return DictionaryElementsAccessor::DeleteCommon(obj, key, mode); 1242 } else { 1243 return FastObjectElementsAccessor::DeleteCommon(obj, key); 1244 } 1245 } 1246 return obj->GetHeap()->true_value(); 1247 } 1248 1249 static MaybeObject* CopyElementsImpl(FixedArrayBase* from, 1250 uint32_t from_start, 1251 FixedArrayBase* to, 1252 ElementsKind to_kind, 1253 uint32_t to_start, 1254 int copy_size) { 1255 FixedArray* parameter_map = FixedArray::cast(from); 1256 FixedArray* arguments = FixedArray::cast(parameter_map->get(1)); 1257 ElementsAccessor* accessor = ElementsAccessor::ForArray(arguments); 1258 return accessor->CopyElements(NULL, from_start, to, to_kind, 1259 to_start, copy_size, arguments); 1260 } 1261 1262 static uint32_t GetCapacityImpl(FixedArray* parameter_map) { 1263 FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); 1264 return Max(static_cast<uint32_t>(parameter_map->length() - 2), 1265 ForArray(arguments)->GetCapacity(arguments)); 1266 } 1267 1268 static uint32_t GetKeyForIndexImpl(FixedArray* dict, 1269 uint32_t index) { 1270 return index; 1271 } 1272 1273 static bool HasElementImpl(Object* receiver, 1274 JSObject* holder, 1275 uint32_t key, 1276 FixedArray* parameter_map) { 1277 Object* probe = GetParameterMapArg(holder, parameter_map, key); 1278 if (!probe->IsTheHole()) { 1279 return true; 1280 } else { 1281 FixedArrayBase* arguments = FixedArrayBase::cast(parameter_map->get(1)); 1282 ElementsAccessor* accessor = ElementsAccessor::ForArray(arguments); 1283 return !accessor->Get(receiver, holder, key, arguments)->IsTheHole(); 1284 } 1285 } 1286 1287 private: 1288 static Object* GetParameterMapArg(JSObject* holder, 1289 FixedArray* parameter_map, 1290 uint32_t key) { 1291 uint32_t length = holder->IsJSArray() 1292 ? Smi::cast(JSArray::cast(holder)->length())->value() 1293 : parameter_map->length(); 1294 return key < (length - 2 ) 1295 ? parameter_map->get(key + 2) 1296 : parameter_map->GetHeap()->the_hole_value(); 1297 } 1298 }; 1299 1300 1301 ElementsAccessor* ElementsAccessor::ForArray(FixedArrayBase* array) { 1302 switch (array->map()->instance_type()) { 1303 case FIXED_ARRAY_TYPE: 1304 if (array->IsDictionary()) { 1305 return elements_accessors_[DICTIONARY_ELEMENTS]; 1306 } else { 1307 return elements_accessors_[FAST_ELEMENTS]; 1308 } 1309 case EXTERNAL_BYTE_ARRAY_TYPE: 1310 return elements_accessors_[EXTERNAL_BYTE_ELEMENTS]; 1311 case EXTERNAL_UNSIGNED_BYTE_ARRAY_TYPE: 1312 return elements_accessors_[EXTERNAL_UNSIGNED_BYTE_ELEMENTS]; 1313 case EXTERNAL_SHORT_ARRAY_TYPE: 1314 return elements_accessors_[EXTERNAL_SHORT_ELEMENTS]; 1315 case EXTERNAL_UNSIGNED_SHORT_ARRAY_TYPE: 1316 return elements_accessors_[EXTERNAL_UNSIGNED_SHORT_ELEMENTS]; 1317 case EXTERNAL_INT_ARRAY_TYPE: 1318 return elements_accessors_[EXTERNAL_INT_ELEMENTS]; 1319 case EXTERNAL_UNSIGNED_INT_ARRAY_TYPE: 1320 return elements_accessors_[EXTERNAL_UNSIGNED_INT_ELEMENTS]; 1321 case EXTERNAL_FLOAT_ARRAY_TYPE: 1322 return elements_accessors_[EXTERNAL_FLOAT_ELEMENTS]; 1323 case EXTERNAL_DOUBLE_ARRAY_TYPE: 1324 return elements_accessors_[EXTERNAL_DOUBLE_ELEMENTS]; 1325 case EXTERNAL_PIXEL_ARRAY_TYPE: 1326 return elements_accessors_[EXTERNAL_PIXEL_ELEMENTS]; 1327 default: 1328 UNREACHABLE(); 1329 return NULL; 1330 } 1331 } 1332 1333 1334 void ElementsAccessor::InitializeOncePerProcess() { 1335 static struct ConcreteElementsAccessors { 1336 #define ACCESSOR_STRUCT(Class, Kind, Store) Class* Kind##_handler; 1337 ELEMENTS_LIST(ACCESSOR_STRUCT) 1338 #undef ACCESSOR_STRUCT 1339 } element_accessors = { 1340 #define ACCESSOR_INIT(Class, Kind, Store) new Class(#Kind), 1341 ELEMENTS_LIST(ACCESSOR_INIT) 1342 #undef ACCESSOR_INIT 1343 }; 1344 1345 static ElementsAccessor* accessor_array[] = { 1346 #define ACCESSOR_ARRAY(Class, Kind, Store) element_accessors.Kind##_handler, 1347 ELEMENTS_LIST(ACCESSOR_ARRAY) 1348 #undef ACCESSOR_ARRAY 1349 }; 1350 1351 STATIC_ASSERT((sizeof(accessor_array) / sizeof(*accessor_array)) == 1352 kElementsKindCount); 1353 1354 elements_accessors_ = accessor_array; 1355 } 1356 1357 1358 template <typename ElementsAccessorSubclass, typename ElementsKindTraits> 1359 MaybeObject* ElementsAccessorBase<ElementsAccessorSubclass, 1360 ElementsKindTraits>:: 1361 SetLengthImpl(JSObject* obj, 1362 Object* length, 1363 typename ElementsKindTraits::BackingStore* backing_store) { 1364 JSArray* array = JSArray::cast(obj); 1365 1366 // Fast case: The new length fits into a Smi. 1367 MaybeObject* maybe_smi_length = length->ToSmi(); 1368 Object* smi_length = Smi::FromInt(0); 1369 if (maybe_smi_length->ToObject(&smi_length) && smi_length->IsSmi()) { 1370 const int value = Smi::cast(smi_length)->value(); 1371 if (value >= 0) { 1372 Object* new_length; 1373 MaybeObject* result = ElementsAccessorSubclass:: 1374 SetLengthWithoutNormalize(backing_store, array, smi_length, value); 1375 if (!result->ToObject(&new_length)) return result; 1376 ASSERT(new_length->IsSmi() || new_length->IsUndefined()); 1377 if (new_length->IsSmi()) { 1378 array->set_length(Smi::cast(new_length)); 1379 return array; 1380 } 1381 } else { 1382 return ThrowArrayLengthRangeError(array->GetHeap()); 1383 } 1384 } 1385 1386 // Slow case: The new length does not fit into a Smi or conversion 1387 // to slow elements is needed for other reasons. 1388 if (length->IsNumber()) { 1389 uint32_t value; 1390 if (length->ToArrayIndex(&value)) { 1391 SeededNumberDictionary* dictionary; 1392 MaybeObject* maybe_object = array->NormalizeElements(); 1393 if (!maybe_object->To(&dictionary)) return maybe_object; 1394 Object* new_length; 1395 MaybeObject* result = DictionaryElementsAccessor:: 1396 SetLengthWithoutNormalize(dictionary, array, length, value); 1397 if (!result->ToObject(&new_length)) return result; 1398 ASSERT(new_length->IsNumber()); 1399 array->set_length(new_length); 1400 return array; 1401 } else { 1402 return ThrowArrayLengthRangeError(array->GetHeap()); 1403 } 1404 } 1405 1406 // Fall-back case: The new length is not a number so make the array 1407 // size one and set only element to length. 1408 FixedArray* new_backing_store; 1409 MaybeObject* maybe_obj = array->GetHeap()->AllocateFixedArray(1); 1410 if (!maybe_obj->To(&new_backing_store)) return maybe_obj; 1411 new_backing_store->set(0, length); 1412 { MaybeObject* result = array->SetContent(new_backing_store); 1413 if (result->IsFailure()) return result; 1414 } 1415 return array; 1416 } 1417 1418 1419 } } // namespace v8::internal 1420