1 // Copyright 2012 the V8 project authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style license that can be 3 // found in the LICENSE file. 4 5 #ifndef V8_ISOLATE_H_ 6 #define V8_ISOLATE_H_ 7 8 #include <cstddef> 9 #include <memory> 10 #include <queue> 11 #include <unordered_map> 12 #include <vector> 13 14 #include "include/v8-inspector.h" 15 #include "include/v8.h" 16 #include "src/allocation.h" 17 #include "src/base/atomicops.h" 18 #include "src/base/macros.h" 19 #include "src/builtins/builtins.h" 20 #include "src/contexts.h" 21 #include "src/date.h" 22 #include "src/debug/debug-interface.h" 23 #include "src/execution.h" 24 #include "src/futex-emulation.h" 25 #include "src/globals.h" 26 #include "src/handles.h" 27 #include "src/heap/factory.h" 28 #include "src/heap/heap.h" 29 #include "src/messages.h" 30 #include "src/objects/code.h" 31 #include "src/objects/debug-objects.h" 32 #include "src/runtime/runtime.h" 33 #include "src/unicode.h" 34 35 #ifdef V8_INTL_SUPPORT 36 #include "unicode/uversion.h" // Define U_ICU_NAMESPACE. 37 // 'icu' does not work. Use U_ICU_NAMESPACE. 38 namespace U_ICU_NAMESPACE { 39 40 class RegexMatcher; 41 42 } // namespace U_ICU_NAMESPACE 43 #endif // V8_INTL_SUPPORT 44 45 namespace v8 { 46 47 namespace base { 48 class RandomNumberGenerator; 49 } 50 51 namespace debug { 52 class ConsoleDelegate; 53 } 54 55 namespace internal { 56 57 namespace heap { 58 class HeapTester; 59 } // namespace heap 60 61 class AccessCompilerData; 62 class AddressToIndexHashMap; 63 class AstStringConstants; 64 class Bootstrapper; 65 class BuiltinsConstantsTableBuilder; 66 class CancelableTaskManager; 67 class CodeEventDispatcher; 68 class ExternalCodeEventListener; 69 class CodeGenerator; 70 class CodeRange; 71 class CodeStubDescriptor; 72 class CodeTracer; 73 class CompilationCache; 74 class CompilationStatistics; 75 class CompilerDispatcher; 76 class ContextSlotCache; 77 class Counters; 78 class CpuFeatures; 79 class Debug; 80 class DeoptimizerData; 81 class DescriptorLookupCache; 82 class EmptyStatement; 83 class EternalHandles; 84 class ExternalCallbackScope; 85 class HandleScopeImplementer; 86 class HeapObjectToIndexHashMap; 87 class HeapProfiler; 88 class InlineRuntimeFunctionsTable; 89 class InnerPointerToCodeCache; 90 class InstructionStream; 91 class Logger; 92 class MaterializedObjectStore; 93 class Microtask; 94 class OptimizingCompileDispatcher; 95 class PromiseOnStack; 96 class Redirection; 97 class RegExpStack; 98 class RootVisitor; 99 class RuntimeProfiler; 100 class SaveContext; 101 class SetupIsolateDelegate; 102 class Simulator; 103 class StartupDeserializer; 104 class StandardFrame; 105 class StatsTable; 106 class StringTracker; 107 class StubCache; 108 class SweeperThread; 109 class ThreadManager; 110 class ThreadState; 111 class ThreadVisitor; // Defined in v8threads.h 112 class TracingCpuProfilerImpl; 113 class UnicodeCache; 114 struct ManagedPtrDestructor; 115 116 template <StateTag Tag> class VMState; 117 118 namespace interpreter { 119 class Interpreter; 120 } 121 122 namespace wasm { 123 class WasmEngine; 124 } 125 126 #define RETURN_FAILURE_IF_SCHEDULED_EXCEPTION(isolate) \ 127 do { \ 128 Isolate* __isolate__ = (isolate); \ 129 DCHECK(!__isolate__->has_pending_exception()); \ 130 if (__isolate__->has_scheduled_exception()) { \ 131 return __isolate__->PromoteScheduledException(); \ 132 } \ 133 } while (false) 134 135 // Macros for MaybeHandle. 136 137 #define RETURN_VALUE_IF_SCHEDULED_EXCEPTION(isolate, value) \ 138 do { \ 139 Isolate* __isolate__ = (isolate); \ 140 DCHECK(!__isolate__->has_pending_exception()); \ 141 if (__isolate__->has_scheduled_exception()) { \ 142 __isolate__->PromoteScheduledException(); \ 143 return value; \ 144 } \ 145 } while (false) 146 147 #define RETURN_EXCEPTION_IF_SCHEDULED_EXCEPTION(isolate, T) \ 148 RETURN_VALUE_IF_SCHEDULED_EXCEPTION(isolate, MaybeHandle<T>()) 149 150 #define ASSIGN_RETURN_ON_SCHEDULED_EXCEPTION_VALUE(isolate, dst, call, value) \ 151 do { \ 152 Isolate* __isolate__ = (isolate); \ 153 if (!(call).ToLocal(&dst)) { \ 154 DCHECK(__isolate__->has_scheduled_exception()); \ 155 __isolate__->PromoteScheduledException(); \ 156 return value; \ 157 } \ 158 } while (false) 159 160 #define RETURN_ON_SCHEDULED_EXCEPTION_VALUE(isolate, call, value) \ 161 do { \ 162 Isolate* __isolate__ = (isolate); \ 163 if ((call).IsNothing()) { \ 164 DCHECK(__isolate__->has_scheduled_exception()); \ 165 __isolate__->PromoteScheduledException(); \ 166 return value; \ 167 } \ 168 } while (false) 169 170 /** 171 * RETURN_RESULT_OR_FAILURE is used in functions with return type Object* (such 172 * as "RUNTIME_FUNCTION(...) {...}" or "BUILTIN(...) {...}" ) to return either 173 * the contents of a MaybeHandle<X>, or the "exception" sentinel value. 174 * Example usage: 175 * 176 * RUNTIME_FUNCTION(Runtime_Func) { 177 * ... 178 * RETURN_RESULT_OR_FAILURE( 179 * isolate, 180 * FunctionWithReturnTypeMaybeHandleX(...)); 181 * } 182 * 183 * If inside a function with return type MaybeHandle<X> use RETURN_ON_EXCEPTION 184 * instead. 185 * If inside a function with return type Handle<X>, or Maybe<X> use 186 * RETURN_ON_EXCEPTION_VALUE instead. 187 */ 188 #define RETURN_RESULT_OR_FAILURE(isolate, call) \ 189 do { \ 190 Handle<Object> __result__; \ 191 Isolate* __isolate__ = (isolate); \ 192 if (!(call).ToHandle(&__result__)) { \ 193 DCHECK(__isolate__->has_pending_exception()); \ 194 return ReadOnlyRoots(__isolate__).exception(); \ 195 } \ 196 DCHECK(!__isolate__->has_pending_exception()); \ 197 return *__result__; \ 198 } while (false) 199 200 #define ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, dst, call, value) \ 201 do { \ 202 if (!(call).ToHandle(&dst)) { \ 203 DCHECK((isolate)->has_pending_exception()); \ 204 return value; \ 205 } \ 206 } while (false) 207 208 #define ASSIGN_RETURN_FAILURE_ON_EXCEPTION(isolate, dst, call) \ 209 do { \ 210 Isolate* __isolate__ = (isolate); \ 211 ASSIGN_RETURN_ON_EXCEPTION_VALUE(__isolate__, dst, call, \ 212 ReadOnlyRoots(__isolate__).exception()); \ 213 } while (false) 214 215 #define ASSIGN_RETURN_ON_EXCEPTION(isolate, dst, call, T) \ 216 ASSIGN_RETURN_ON_EXCEPTION_VALUE(isolate, dst, call, MaybeHandle<T>()) 217 218 #define THROW_NEW_ERROR(isolate, call, T) \ 219 do { \ 220 Isolate* __isolate__ = (isolate); \ 221 return __isolate__->Throw<T>(__isolate__->factory()->call); \ 222 } while (false) 223 224 #define THROW_NEW_ERROR_RETURN_FAILURE(isolate, call) \ 225 do { \ 226 Isolate* __isolate__ = (isolate); \ 227 return __isolate__->Throw(*__isolate__->factory()->call); \ 228 } while (false) 229 230 #define THROW_NEW_ERROR_RETURN_VALUE(isolate, call, value) \ 231 do { \ 232 Isolate* __isolate__ = (isolate); \ 233 __isolate__->Throw(*__isolate__->factory()->call); \ 234 return value; \ 235 } while (false) 236 237 /** 238 * RETURN_ON_EXCEPTION_VALUE conditionally returns the given value when the 239 * given MaybeHandle is empty. It is typically used in functions with return 240 * type Maybe<X> or Handle<X>. Example usage: 241 * 242 * Handle<X> Func() { 243 * ... 244 * RETURN_ON_EXCEPTION_VALUE( 245 * isolate, 246 * FunctionWithReturnTypeMaybeHandleX(...), 247 * Handle<X>()); 248 * // code to handle non exception 249 * ... 250 * } 251 * 252 * Maybe<bool> Func() { 253 * .. 254 * RETURN_ON_EXCEPTION_VALUE( 255 * isolate, 256 * FunctionWithReturnTypeMaybeHandleX(...), 257 * Nothing<bool>); 258 * // code to handle non exception 259 * return Just(true); 260 * } 261 * 262 * If inside a function with return type MaybeHandle<X>, use RETURN_ON_EXCEPTION 263 * instead. 264 * If inside a function with return type Object*, use 265 * RETURN_FAILURE_ON_EXCEPTION instead. 266 */ 267 #define RETURN_ON_EXCEPTION_VALUE(isolate, call, value) \ 268 do { \ 269 if ((call).is_null()) { \ 270 DCHECK((isolate)->has_pending_exception()); \ 271 return value; \ 272 } \ 273 } while (false) 274 275 /** 276 * RETURN_FAILURE_ON_EXCEPTION conditionally returns the "exception" sentinel if 277 * the given MaybeHandle is empty; so it can only be used in functions with 278 * return type Object*, such as RUNTIME_FUNCTION(...) {...} or BUILTIN(...) 279 * {...}. Example usage: 280 * 281 * RUNTIME_FUNCTION(Runtime_Func) { 282 * ... 283 * RETURN_FAILURE_ON_EXCEPTION( 284 * isolate, 285 * FunctionWithReturnTypeMaybeHandleX(...)); 286 * // code to handle non exception 287 * ... 288 * } 289 * 290 * If inside a function with return type MaybeHandle<X>, use RETURN_ON_EXCEPTION 291 * instead. 292 * If inside a function with return type Maybe<X> or Handle<X>, use 293 * RETURN_ON_EXCEPTION_VALUE instead. 294 */ 295 #define RETURN_FAILURE_ON_EXCEPTION(isolate, call) \ 296 do { \ 297 Isolate* __isolate__ = (isolate); \ 298 RETURN_ON_EXCEPTION_VALUE(__isolate__, call, \ 299 ReadOnlyRoots(__isolate__).exception()); \ 300 } while (false); 301 302 /** 303 * RETURN_ON_EXCEPTION conditionally returns an empty MaybeHandle<T> if the 304 * given MaybeHandle is empty. Use it to return immediately from a function with 305 * return type MaybeHandle when an exception was thrown. Example usage: 306 * 307 * MaybeHandle<X> Func() { 308 * ... 309 * RETURN_ON_EXCEPTION( 310 * isolate, 311 * FunctionWithReturnTypeMaybeHandleY(...), 312 * X); 313 * // code to handle non exception 314 * ... 315 * } 316 * 317 * If inside a function with return type Object*, use 318 * RETURN_FAILURE_ON_EXCEPTION instead. 319 * If inside a function with return type 320 * Maybe<X> or Handle<X>, use RETURN_ON_EXCEPTION_VALUE instead. 321 */ 322 #define RETURN_ON_EXCEPTION(isolate, call, T) \ 323 RETURN_ON_EXCEPTION_VALUE(isolate, call, MaybeHandle<T>()) 324 325 326 #define FOR_WITH_HANDLE_SCOPE(isolate, loop_var_type, init, loop_var, \ 327 limit_check, increment, body) \ 328 do { \ 329 loop_var_type init; \ 330 loop_var_type for_with_handle_limit = loop_var; \ 331 Isolate* for_with_handle_isolate = isolate; \ 332 while (limit_check) { \ 333 for_with_handle_limit += 1024; \ 334 HandleScope loop_scope(for_with_handle_isolate); \ 335 for (; limit_check && loop_var < for_with_handle_limit; increment) { \ 336 body \ 337 } \ 338 } \ 339 } while (false) 340 341 // Platform-independent, reliable thread identifier. 342 class ThreadId { 343 public: 344 // Creates an invalid ThreadId. ThreadId()345 ThreadId() { base::Relaxed_Store(&id_, kInvalidId); } 346 347 ThreadId& operator=(const ThreadId& other) { 348 base::Relaxed_Store(&id_, base::Relaxed_Load(&other.id_)); 349 return *this; 350 } 351 352 bool operator==(const ThreadId& other) const { return Equals(other); } 353 354 // Returns ThreadId for current thread. Current()355 static ThreadId Current() { return ThreadId(GetCurrentThreadId()); } 356 357 // Returns invalid ThreadId (guaranteed not to be equal to any thread). Invalid()358 static ThreadId Invalid() { return ThreadId(kInvalidId); } 359 360 // Compares ThreadIds for equality. Equals(const ThreadId & other)361 V8_INLINE bool Equals(const ThreadId& other) const { 362 return base::Relaxed_Load(&id_) == base::Relaxed_Load(&other.id_); 363 } 364 365 // Checks whether this ThreadId refers to any thread. IsValid()366 V8_INLINE bool IsValid() const { 367 return base::Relaxed_Load(&id_) != kInvalidId; 368 } 369 370 // Converts ThreadId to an integer representation 371 // (required for public API: V8::V8::GetCurrentThreadId). ToInteger()372 int ToInteger() const { return static_cast<int>(base::Relaxed_Load(&id_)); } 373 374 // Converts ThreadId to an integer representation 375 // (required for public API: V8::V8::TerminateExecution). FromInteger(int id)376 static ThreadId FromInteger(int id) { return ThreadId(id); } 377 378 private: 379 static const int kInvalidId = -1; 380 ThreadId(int id)381 explicit ThreadId(int id) { base::Relaxed_Store(&id_, id); } 382 383 static int AllocateThreadId(); 384 385 V8_EXPORT_PRIVATE static int GetCurrentThreadId(); 386 387 base::Atomic32 id_; 388 389 static base::Atomic32 highest_thread_id_; 390 391 friend class Isolate; 392 }; 393 394 #define FIELD_ACCESSOR(type, name) \ 395 inline void set_##name(type v) { name##_ = v; } \ 396 inline type name() const { return name##_; } 397 398 399 class ThreadLocalTop BASE_EMBEDDED { 400 public: 401 // Does early low-level initialization that does not depend on the 402 // isolate being present. 403 ThreadLocalTop() = default; 404 405 // Initialize the thread data. 406 void Initialize(Isolate*); 407 408 // Get the top C++ try catch handler or nullptr if none are registered. 409 // 410 // This method is not guaranteed to return an address that can be 411 // used for comparison with addresses into the JS stack. If such an 412 // address is needed, use try_catch_handler_address. FIELD_ACCESSOR(v8::TryCatch *,try_catch_handler)413 FIELD_ACCESSOR(v8::TryCatch*, try_catch_handler) 414 415 // Get the address of the top C++ try catch handler or nullptr if 416 // none are registered. 417 // 418 // This method always returns an address that can be compared to 419 // pointers into the JavaScript stack. When running on actual 420 // hardware, try_catch_handler_address and TryCatchHandler return 421 // the same pointer. When running on a simulator with a separate JS 422 // stack, try_catch_handler_address returns a JS stack address that 423 // corresponds to the place on the JS stack where the C++ handler 424 // would have been if the stack were not separate. 425 Address try_catch_handler_address() { 426 return reinterpret_cast<Address>( 427 v8::TryCatch::JSStackComparableAddress(try_catch_handler())); 428 } 429 430 void Free(); 431 432 Isolate* isolate_ = nullptr; 433 // The context where the current execution method is created and for variable 434 // lookups. 435 Context* context_ = nullptr; 436 ThreadId thread_id_ = ThreadId::Invalid(); 437 Object* pending_exception_ = nullptr; 438 // TODO(kschimpf): Change this to a stack of caught exceptions (rather than 439 // just innermost catching try block). 440 Object* wasm_caught_exception_ = nullptr; 441 442 // Communication channel between Isolate::FindHandler and the CEntry. 443 Context* pending_handler_context_ = nullptr; 444 Address pending_handler_entrypoint_ = kNullAddress; 445 Address pending_handler_constant_pool_ = kNullAddress; 446 Address pending_handler_fp_ = kNullAddress; 447 Address pending_handler_sp_ = kNullAddress; 448 449 // Communication channel between Isolate::Throw and message consumers. 450 bool rethrowing_message_ = false; 451 Object* pending_message_obj_ = nullptr; 452 453 // Use a separate value for scheduled exceptions to preserve the 454 // invariants that hold about pending_exception. We may want to 455 // unify them later. 456 Object* scheduled_exception_ = nullptr; 457 bool external_caught_exception_ = false; 458 SaveContext* save_context_ = nullptr; 459 460 // Stack. 461 // The frame pointer of the top c entry frame. 462 Address c_entry_fp_ = kNullAddress; 463 // Try-blocks are chained through the stack. 464 Address handler_ = kNullAddress; 465 // C function that was called at c entry. 466 Address c_function_ = kNullAddress; 467 468 // Throwing an exception may cause a Promise rejection. For this purpose 469 // we keep track of a stack of nested promises and the corresponding 470 // try-catch handlers. 471 PromiseOnStack* promise_on_stack_ = nullptr; 472 473 #ifdef USE_SIMULATOR 474 Simulator* simulator_ = nullptr; 475 #endif 476 477 // The stack pointer of the bottom JS entry frame. 478 Address js_entry_sp_ = kNullAddress; 479 // The external callback we're currently in. 480 ExternalCallbackScope* external_callback_scope_ = nullptr; 481 StateTag current_vm_state_ = EXTERNAL; 482 483 // Call back function to report unsafe JS accesses. 484 v8::FailedAccessCheckCallback failed_access_check_callback_ = nullptr; 485 486 // Address of the thread-local "thread in wasm" flag. 487 Address thread_in_wasm_flag_address_ = kNullAddress; 488 489 private: 490 v8::TryCatch* try_catch_handler_ = nullptr; 491 }; 492 493 #ifdef DEBUG 494 495 #define ISOLATE_INIT_DEBUG_ARRAY_LIST(V) \ 496 V(CommentStatistic, paged_space_comments_statistics, \ 497 CommentStatistic::kMaxComments + 1) \ 498 V(int, code_kind_statistics, AbstractCode::NUMBER_OF_KINDS) 499 #else 500 501 #define ISOLATE_INIT_DEBUG_ARRAY_LIST(V) 502 503 #endif 504 505 #define ISOLATE_INIT_ARRAY_LIST(V) \ 506 /* SerializerDeserializer state. */ \ 507 V(int32_t, jsregexp_static_offsets_vector, kJSRegexpStaticOffsetsVectorSize) \ 508 V(int, bad_char_shift_table, kUC16AlphabetSize) \ 509 V(int, good_suffix_shift_table, (kBMMaxShift + 1)) \ 510 V(int, suffix_table, (kBMMaxShift + 1)) \ 511 ISOLATE_INIT_DEBUG_ARRAY_LIST(V) 512 513 typedef std::vector<HeapObject*> DebugObjectCache; 514 515 #define ISOLATE_INIT_LIST(V) \ 516 /* Assembler state. */ \ 517 V(FatalErrorCallback, exception_behavior, nullptr) \ 518 V(OOMErrorCallback, oom_behavior, nullptr) \ 519 V(LogEventCallback, event_logger, nullptr) \ 520 V(AllowCodeGenerationFromStringsCallback, allow_code_gen_callback, nullptr) \ 521 V(AllowWasmCodeGenerationCallback, allow_wasm_code_gen_callback, nullptr) \ 522 V(ExtensionCallback, wasm_module_callback, &NoExtension) \ 523 V(ExtensionCallback, wasm_instance_callback, &NoExtension) \ 524 V(ApiImplementationCallback, wasm_compile_streaming_callback, nullptr) \ 525 V(WasmStreamingCallback, wasm_streaming_callback, nullptr) \ 526 V(WasmThreadsEnabledCallback, wasm_threads_enabled_callback, nullptr) \ 527 /* State for Relocatable. */ \ 528 V(Relocatable*, relocatable_top, nullptr) \ 529 V(DebugObjectCache*, string_stream_debug_object_cache, nullptr) \ 530 V(Object*, string_stream_current_security_token, nullptr) \ 531 V(const intptr_t*, api_external_references, nullptr) \ 532 V(AddressToIndexHashMap*, external_reference_map, nullptr) \ 533 V(HeapObjectToIndexHashMap*, root_index_map, nullptr) \ 534 V(int, pending_microtask_count, 0) \ 535 V(CompilationStatistics*, turbo_statistics, nullptr) \ 536 V(CodeTracer*, code_tracer, nullptr) \ 537 V(uint32_t, per_isolate_assert_data, 0xFFFFFFFFu) \ 538 V(PromiseRejectCallback, promise_reject_callback, nullptr) \ 539 V(const v8::StartupData*, snapshot_blob, nullptr) \ 540 V(int, code_and_metadata_size, 0) \ 541 V(int, bytecode_and_metadata_size, 0) \ 542 V(int, external_script_source_size, 0) \ 543 /* true if being profiled. Causes collection of extra compile info. */ \ 544 V(bool, is_profiling, false) \ 545 /* true if a trace is being formatted through Error.prepareStackTrace. */ \ 546 V(bool, formatting_stack_trace, false) \ 547 /* Perform side effect checks on function call and API callbacks. */ \ 548 V(DebugInfo::ExecutionMode, debug_execution_mode, DebugInfo::kBreakpoints) \ 549 /* Current code coverage mode */ \ 550 V(debug::Coverage::Mode, code_coverage_mode, debug::Coverage::kBestEffort) \ 551 V(debug::TypeProfile::Mode, type_profile_mode, debug::TypeProfile::kNone) \ 552 V(int, last_stack_frame_info_id, 0) \ 553 V(int, last_console_context_id, 0) \ 554 V(v8_inspector::V8Inspector*, inspector, nullptr) \ 555 V(bool, next_v8_call_is_safe_for_termination, false) \ 556 V(bool, only_terminate_in_safe_scope, false) 557 558 #define THREAD_LOCAL_TOP_ACCESSOR(type, name) \ 559 inline void set_##name(type v) { thread_local_top_.name##_ = v; } \ 560 inline type name() const { return thread_local_top_.name##_; } 561 562 #define THREAD_LOCAL_TOP_ADDRESS(type, name) \ 563 type* name##_address() { return &thread_local_top_.name##_; } 564 565 // HiddenFactory exists so Isolate can privately inherit from it without making 566 // Factory's members available to Isolate directly. 567 class V8_EXPORT_PRIVATE HiddenFactory : private Factory {}; 568 569 class Isolate : private HiddenFactory { 570 // These forward declarations are required to make the friend declarations in 571 // PerIsolateThreadData work on some older versions of gcc. 572 class ThreadDataTable; 573 class EntryStackItem; 574 public: 575 ~Isolate(); 576 577 // A thread has a PerIsolateThreadData instance for each isolate that it has 578 // entered. That instance is allocated when the isolate is initially entered 579 // and reused on subsequent entries. 580 class PerIsolateThreadData { 581 public: PerIsolateThreadData(Isolate * isolate,ThreadId thread_id)582 PerIsolateThreadData(Isolate* isolate, ThreadId thread_id) 583 : isolate_(isolate), 584 thread_id_(thread_id), 585 stack_limit_(0), 586 thread_state_(nullptr), 587 #if USE_SIMULATOR 588 simulator_(nullptr), 589 #endif 590 next_(nullptr), 591 prev_(nullptr) { 592 } 593 ~PerIsolateThreadData(); isolate()594 Isolate* isolate() const { return isolate_; } thread_id()595 ThreadId thread_id() const { return thread_id_; } 596 FIELD_ACCESSOR(uintptr_t,stack_limit)597 FIELD_ACCESSOR(uintptr_t, stack_limit) 598 FIELD_ACCESSOR(ThreadState*, thread_state) 599 600 #if USE_SIMULATOR 601 FIELD_ACCESSOR(Simulator*, simulator) 602 #endif 603 604 bool Matches(Isolate* isolate, ThreadId thread_id) const { 605 return isolate_ == isolate && thread_id_.Equals(thread_id); 606 } 607 608 private: 609 Isolate* isolate_; 610 ThreadId thread_id_; 611 uintptr_t stack_limit_; 612 ThreadState* thread_state_; 613 614 #if USE_SIMULATOR 615 Simulator* simulator_; 616 #endif 617 618 PerIsolateThreadData* next_; 619 PerIsolateThreadData* prev_; 620 621 friend class Isolate; 622 friend class ThreadDataTable; 623 friend class EntryStackItem; 624 625 DISALLOW_COPY_AND_ASSIGN(PerIsolateThreadData); 626 }; 627 628 static void InitializeOncePerProcess(); 629 630 // Returns the PerIsolateThreadData for the current thread (or nullptr if one 631 // is not currently set). CurrentPerIsolateThreadData()632 static PerIsolateThreadData* CurrentPerIsolateThreadData() { 633 return reinterpret_cast<PerIsolateThreadData*>( 634 base::Thread::GetThreadLocal(per_isolate_thread_data_key_)); 635 } 636 637 // Returns the isolate inside which the current thread is running. Current()638 V8_INLINE static Isolate* Current() { 639 DCHECK_EQ(base::Relaxed_Load(&isolate_key_created_), 1); 640 Isolate* isolate = reinterpret_cast<Isolate*>( 641 base::Thread::GetExistingThreadLocal(isolate_key_)); 642 DCHECK_NOT_NULL(isolate); 643 return isolate; 644 } 645 646 // Get the isolate that the given HeapObject lives in, returning true on 647 // success. If the object is not writable (i.e. lives in read-only space), 648 // return false. 649 inline static bool FromWritableHeapObject(HeapObject* obj, Isolate** isolate); 650 651 // Usually called by Init(), but can be called early e.g. to allow 652 // testing components that require logging but not the whole 653 // isolate. 654 // 655 // Safe to call more than once. 656 void InitializeLoggingAndCounters(); 657 bool InitializeCounters(); // Returns false if already initialized. 658 659 bool Init(StartupDeserializer* des); 660 661 // True if at least one thread Enter'ed this isolate. IsInUse()662 bool IsInUse() { return entry_stack_ != nullptr; } 663 664 // Destroys the non-default isolates. 665 // Sets default isolate into "has_been_disposed" state rather then destroying, 666 // for legacy API reasons. 667 void TearDown(); 668 669 void ReleaseSharedPtrs(); 670 671 void ClearSerializerData(); 672 673 // Find the PerThread for this particular (isolate, thread) combination 674 // If one does not yet exist, return null. 675 PerIsolateThreadData* FindPerThreadDataForThisThread(); 676 677 // Find the PerThread for given (isolate, thread) combination 678 // If one does not yet exist, return null. 679 PerIsolateThreadData* FindPerThreadDataForThread(ThreadId thread_id); 680 681 // Discard the PerThread for this particular (isolate, thread) combination 682 // If one does not yet exist, no-op. 683 void DiscardPerThreadDataForThisThread(); 684 685 // Returns the key used to store the pointer to the current isolate. 686 // Used internally for V8 threads that do not execute JavaScript but still 687 // are part of the domain of an isolate (like the context switcher). isolate_key()688 static base::Thread::LocalStorageKey isolate_key() { 689 return isolate_key_; 690 } 691 692 // Returns the key used to store process-wide thread IDs. thread_id_key()693 static base::Thread::LocalStorageKey thread_id_key() { 694 return thread_id_key_; 695 } 696 697 static base::Thread::LocalStorageKey per_isolate_thread_data_key(); 698 699 // Mutex for serializing access to break control structures. break_access()700 base::RecursiveMutex* break_access() { return &break_access_; } 701 702 Address get_address_from_id(IsolateAddressId id); 703 704 // Access to top context (where the current function object was created). context()705 Context* context() { return thread_local_top_.context_; } 706 inline void set_context(Context* context); context_address()707 Context** context_address() { return &thread_local_top_.context_; } 708 709 THREAD_LOCAL_TOP_ACCESSOR(SaveContext*, save_context) 710 711 // Access to current thread id. 712 THREAD_LOCAL_TOP_ACCESSOR(ThreadId, thread_id) 713 714 // Interface to pending exception. 715 inline Object* pending_exception(); 716 inline void set_pending_exception(Object* exception_obj); 717 inline void clear_pending_exception(); 718 719 // Interface to wasm caught exception. 720 inline Object* get_wasm_caught_exception(); 721 inline void set_wasm_caught_exception(Object* exception); 722 inline void clear_wasm_caught_exception(); 723 724 bool AreWasmThreadsEnabled(Handle<Context> context); 725 726 THREAD_LOCAL_TOP_ADDRESS(Object*, pending_exception) 727 728 inline bool has_pending_exception(); 729 THREAD_LOCAL_TOP_ADDRESS(Context *,pending_handler_context)730 THREAD_LOCAL_TOP_ADDRESS(Context*, pending_handler_context) 731 THREAD_LOCAL_TOP_ADDRESS(Address, pending_handler_entrypoint) 732 THREAD_LOCAL_TOP_ADDRESS(Address, pending_handler_constant_pool) 733 THREAD_LOCAL_TOP_ADDRESS(Address, pending_handler_fp) 734 THREAD_LOCAL_TOP_ADDRESS(Address, pending_handler_sp) 735 736 THREAD_LOCAL_TOP_ACCESSOR(bool, external_caught_exception) 737 738 v8::TryCatch* try_catch_handler() { 739 return thread_local_top_.try_catch_handler(); 740 } external_caught_exception_address()741 bool* external_caught_exception_address() { 742 return &thread_local_top_.external_caught_exception_; 743 } 744 745 THREAD_LOCAL_TOP_ADDRESS(Object*, scheduled_exception) 746 747 inline void clear_pending_message(); pending_message_obj_address()748 Address pending_message_obj_address() { 749 return reinterpret_cast<Address>(&thread_local_top_.pending_message_obj_); 750 } 751 752 inline Object* scheduled_exception(); 753 inline bool has_scheduled_exception(); 754 inline void clear_scheduled_exception(); 755 756 bool IsJavaScriptHandlerOnTop(Object* exception); 757 bool IsExternalHandlerOnTop(Object* exception); 758 759 inline bool is_catchable_by_javascript(Object* exception); 760 bool is_catchable_by_wasm(Object* exception); 761 762 // JS execution stack (see frames.h). c_entry_fp(ThreadLocalTop * thread)763 static Address c_entry_fp(ThreadLocalTop* thread) { 764 return thread->c_entry_fp_; 765 } handler(ThreadLocalTop * thread)766 static Address handler(ThreadLocalTop* thread) { return thread->handler_; } c_function()767 Address c_function() { return thread_local_top_.c_function_; } 768 c_entry_fp_address()769 inline Address* c_entry_fp_address() { 770 return &thread_local_top_.c_entry_fp_; 771 } handler_address()772 inline Address* handler_address() { return &thread_local_top_.handler_; } c_function_address()773 inline Address* c_function_address() { 774 return &thread_local_top_.c_function_; 775 } 776 777 // Bottom JS entry. js_entry_sp()778 Address js_entry_sp() { 779 return thread_local_top_.js_entry_sp_; 780 } js_entry_sp_address()781 inline Address* js_entry_sp_address() { 782 return &thread_local_top_.js_entry_sp_; 783 } 784 785 // Returns the global object of the current context. It could be 786 // a builtin object, or a JS global object. 787 inline Handle<JSGlobalObject> global_object(); 788 789 // Returns the global proxy object of the current context. 790 inline Handle<JSObject> global_proxy(); 791 ArchiveSpacePerThread()792 static int ArchiveSpacePerThread() { return sizeof(ThreadLocalTop); } FreeThreadResources()793 void FreeThreadResources() { thread_local_top_.Free(); } 794 795 // This method is called by the api after operations that may throw 796 // exceptions. If an exception was thrown and not handled by an external 797 // handler the exception is scheduled to be rethrown when we return to running 798 // JavaScript code. If an exception is scheduled true is returned. 799 V8_EXPORT_PRIVATE bool OptionalRescheduleException(bool is_bottom_call); 800 801 // Push and pop a promise and the current try-catch handler. 802 void PushPromise(Handle<JSObject> promise); 803 void PopPromise(); 804 805 // Return the relevant Promise that a throw/rejection pertains to, based 806 // on the contents of the Promise stack 807 Handle<Object> GetPromiseOnStackOnThrow(); 808 809 // Heuristically guess whether a Promise is handled by user catch handler 810 bool PromiseHasUserDefinedRejectHandler(Handle<Object> promise); 811 812 class ExceptionScope { 813 public: 814 // Scope currently can only be used for regular exceptions, 815 // not termination exception. 816 inline explicit ExceptionScope(Isolate* isolate); 817 inline ~ExceptionScope(); 818 819 private: 820 Isolate* isolate_; 821 Handle<Object> pending_exception_; 822 }; 823 824 void SetCaptureStackTraceForUncaughtExceptions( 825 bool capture, 826 int frame_limit, 827 StackTrace::StackTraceOptions options); 828 829 void SetAbortOnUncaughtExceptionCallback( 830 v8::Isolate::AbortOnUncaughtExceptionCallback callback); 831 832 enum PrintStackMode { kPrintStackConcise, kPrintStackVerbose }; 833 void PrintCurrentStackTrace(FILE* out); 834 void PrintStack(StringStream* accumulator, 835 PrintStackMode mode = kPrintStackVerbose); 836 V8_EXPORT_PRIVATE void PrintStack(FILE* out, 837 PrintStackMode mode = kPrintStackVerbose); 838 Handle<String> StackTraceString(); 839 // Stores a stack trace in a stack-allocated temporary buffer which will 840 // end up in the minidump for debugging purposes. 841 V8_NOINLINE void PushStackTraceAndDie(void* ptr1 = nullptr, 842 void* ptr2 = nullptr, 843 void* ptr3 = nullptr, 844 void* ptr4 = nullptr); 845 Handle<FixedArray> CaptureCurrentStackTrace( 846 int frame_limit, StackTrace::StackTraceOptions options); 847 Handle<Object> CaptureSimpleStackTrace(Handle<JSReceiver> error_object, 848 FrameSkipMode mode, 849 Handle<Object> caller); 850 MaybeHandle<JSReceiver> CaptureAndSetDetailedStackTrace( 851 Handle<JSReceiver> error_object); 852 MaybeHandle<JSReceiver> CaptureAndSetSimpleStackTrace( 853 Handle<JSReceiver> error_object, FrameSkipMode mode, 854 Handle<Object> caller); 855 Handle<FixedArray> GetDetailedStackTrace(Handle<JSObject> error_object); 856 857 Address GetAbstractPC(int* line, int* column); 858 859 // Returns if the given context may access the given global object. If 860 // the result is false, the pending exception is guaranteed to be 861 // set. 862 bool MayAccess(Handle<Context> accessing_context, Handle<JSObject> receiver); 863 864 void SetFailedAccessCheckCallback(v8::FailedAccessCheckCallback callback); 865 void ReportFailedAccessCheck(Handle<JSObject> receiver); 866 867 // Exception throwing support. The caller should use the result 868 // of Throw() as its return value. 869 Object* Throw(Object* exception, MessageLocation* location = nullptr); 870 Object* ThrowIllegalOperation(); 871 872 template <typename T> 873 V8_WARN_UNUSED_RESULT MaybeHandle<T> Throw( 874 Handle<Object> exception, MessageLocation* location = nullptr) { 875 Throw(*exception, location); 876 return MaybeHandle<T>(); 877 } 878 set_console_delegate(debug::ConsoleDelegate * delegate)879 void set_console_delegate(debug::ConsoleDelegate* delegate) { 880 console_delegate_ = delegate; 881 } console_delegate()882 debug::ConsoleDelegate* console_delegate() { return console_delegate_; } 883 set_async_event_delegate(debug::AsyncEventDelegate * delegate)884 void set_async_event_delegate(debug::AsyncEventDelegate* delegate) { 885 async_event_delegate_ = delegate; 886 PromiseHookStateUpdated(); 887 } 888 void OnAsyncFunctionStateChanged(Handle<JSPromise> promise, 889 debug::DebugAsyncActionType); 890 891 // Re-throw an exception. This involves no error reporting since error 892 // reporting was handled when the exception was thrown originally. 893 Object* ReThrow(Object* exception); 894 895 // Find the correct handler for the current pending exception. This also 896 // clears and returns the current pending exception. 897 Object* UnwindAndFindHandler(); 898 899 // Tries to predict whether an exception will be caught. Note that this can 900 // only produce an estimate, because it is undecidable whether a finally 901 // clause will consume or re-throw an exception. 902 enum CatchType { 903 NOT_CAUGHT, 904 CAUGHT_BY_JAVASCRIPT, 905 CAUGHT_BY_EXTERNAL, 906 CAUGHT_BY_DESUGARING, 907 CAUGHT_BY_PROMISE, 908 CAUGHT_BY_ASYNC_AWAIT 909 }; 910 CatchType PredictExceptionCatcher(); 911 912 V8_EXPORT_PRIVATE void ScheduleThrow(Object* exception); 913 // Re-set pending message, script and positions reported to the TryCatch 914 // back to the TLS for re-use when rethrowing. 915 void RestorePendingMessageFromTryCatch(v8::TryCatch* handler); 916 // Un-schedule an exception that was caught by a TryCatch handler. 917 void CancelScheduledExceptionFromTryCatch(v8::TryCatch* handler); 918 void ReportPendingMessages(); 919 void ReportPendingMessagesFromJavaScript(); 920 921 // Implements code shared between the two above methods 922 void ReportPendingMessagesImpl(bool report_externally); 923 924 // Return pending location if any or unfilled structure. 925 MessageLocation GetMessageLocation(); 926 927 // Promote a scheduled exception to pending. Asserts has_scheduled_exception. 928 Object* PromoteScheduledException(); 929 930 // Attempts to compute the current source location, storing the 931 // result in the target out parameter. The source location is attached to a 932 // Message object as the location which should be shown to the user. It's 933 // typically the top-most meaningful location on the stack. 934 bool ComputeLocation(MessageLocation* target); 935 bool ComputeLocationFromException(MessageLocation* target, 936 Handle<Object> exception); 937 bool ComputeLocationFromStackTrace(MessageLocation* target, 938 Handle<Object> exception); 939 940 Handle<JSMessageObject> CreateMessage(Handle<Object> exception, 941 MessageLocation* location); 942 943 // Out of resource exception helpers. 944 Object* StackOverflow(); 945 Object* TerminateExecution(); 946 void CancelTerminateExecution(); 947 948 void RequestInterrupt(InterruptCallback callback, void* data); 949 void InvokeApiInterruptCallbacks(); 950 951 // Administration 952 void Iterate(RootVisitor* v); 953 void Iterate(RootVisitor* v, ThreadLocalTop* t); 954 char* Iterate(RootVisitor* v, char* t); 955 void IterateThread(ThreadVisitor* v, char* t); 956 957 // Returns the current native context. 958 inline Handle<NativeContext> native_context(); 959 inline NativeContext* raw_native_context(); 960 961 Handle<Context> GetIncumbentContext(); 962 963 void RegisterTryCatchHandler(v8::TryCatch* that); 964 void UnregisterTryCatchHandler(v8::TryCatch* that); 965 966 char* ArchiveThread(char* to); 967 char* RestoreThread(char* from); 968 969 static const int kUC16AlphabetSize = 256; // See StringSearchBase. 970 static const int kBMMaxShift = 250; // See StringSearchBase. 971 972 // Accessors. 973 #define GLOBAL_ACCESSOR(type, name, initialvalue) \ 974 inline type name() const { \ 975 DCHECK(OFFSET_OF(Isolate, name##_) == name##_debug_offset_); \ 976 return name##_; \ 977 } \ 978 inline void set_##name(type value) { \ 979 DCHECK(OFFSET_OF(Isolate, name##_) == name##_debug_offset_); \ 980 name##_ = value; \ 981 } 982 ISOLATE_INIT_LIST(GLOBAL_ACCESSOR) 983 #undef GLOBAL_ACCESSOR 984 985 #define GLOBAL_ARRAY_ACCESSOR(type, name, length) \ 986 inline type* name() { \ 987 DCHECK(OFFSET_OF(Isolate, name##_) == name##_debug_offset_); \ 988 return &(name##_)[0]; \ 989 } ISOLATE_INIT_ARRAY_LIST(GLOBAL_ARRAY_ACCESSOR)990 ISOLATE_INIT_ARRAY_LIST(GLOBAL_ARRAY_ACCESSOR) 991 #undef GLOBAL_ARRAY_ACCESSOR 992 993 #define NATIVE_CONTEXT_FIELD_ACCESSOR(index, type, name) \ 994 inline Handle<type> name(); \ 995 inline bool is_##name(type* value); 996 NATIVE_CONTEXT_FIELDS(NATIVE_CONTEXT_FIELD_ACCESSOR) 997 #undef NATIVE_CONTEXT_FIELD_ACCESSOR 998 999 Bootstrapper* bootstrapper() { return bootstrapper_; } 1000 // Use for updating counters on a foreground thread. counters()1001 Counters* counters() { return async_counters().get(); } 1002 // Use for updating counters on a background thread. async_counters()1003 const std::shared_ptr<Counters>& async_counters() { 1004 // Make sure InitializeCounters() has been called. 1005 DCHECK_NOT_NULL(async_counters_.get()); 1006 return async_counters_; 1007 } runtime_profiler()1008 RuntimeProfiler* runtime_profiler() { return runtime_profiler_; } compilation_cache()1009 CompilationCache* compilation_cache() { return compilation_cache_; } logger()1010 Logger* logger() { 1011 // Call InitializeLoggingAndCounters() if logging is needed before 1012 // the isolate is fully initialized. 1013 DCHECK_NOT_NULL(logger_); 1014 return logger_; 1015 } stack_guard()1016 StackGuard* stack_guard() { return &stack_guard_; } heap()1017 Heap* heap() { return &heap_; } load_stub_cache()1018 StubCache* load_stub_cache() { return load_stub_cache_; } store_stub_cache()1019 StubCache* store_stub_cache() { return store_stub_cache_; } deoptimizer_data()1020 DeoptimizerData* deoptimizer_data() { return deoptimizer_data_; } deoptimizer_lazy_throw()1021 bool deoptimizer_lazy_throw() const { return deoptimizer_lazy_throw_; } set_deoptimizer_lazy_throw(bool value)1022 void set_deoptimizer_lazy_throw(bool value) { 1023 deoptimizer_lazy_throw_ = value; 1024 } thread_local_top()1025 ThreadLocalTop* thread_local_top() { return &thread_local_top_; } materialized_object_store()1026 MaterializedObjectStore* materialized_object_store() { 1027 return materialized_object_store_; 1028 } 1029 context_slot_cache()1030 ContextSlotCache* context_slot_cache() { 1031 return context_slot_cache_; 1032 } 1033 descriptor_lookup_cache()1034 DescriptorLookupCache* descriptor_lookup_cache() { 1035 return descriptor_lookup_cache_; 1036 } 1037 handle_scope_data()1038 HandleScopeData* handle_scope_data() { return &handle_scope_data_; } 1039 handle_scope_implementer()1040 HandleScopeImplementer* handle_scope_implementer() { 1041 DCHECK(handle_scope_implementer_); 1042 return handle_scope_implementer_; 1043 } 1044 unicode_cache()1045 UnicodeCache* unicode_cache() { 1046 return unicode_cache_; 1047 } 1048 inner_pointer_to_code_cache()1049 InnerPointerToCodeCache* inner_pointer_to_code_cache() { 1050 return inner_pointer_to_code_cache_; 1051 } 1052 global_handles()1053 GlobalHandles* global_handles() { return global_handles_; } 1054 eternal_handles()1055 EternalHandles* eternal_handles() { return eternal_handles_; } 1056 thread_manager()1057 ThreadManager* thread_manager() { return thread_manager_; } 1058 jsregexp_uncanonicalize()1059 unibrow::Mapping<unibrow::Ecma262UnCanonicalize>* jsregexp_uncanonicalize() { 1060 return &jsregexp_uncanonicalize_; 1061 } 1062 jsregexp_canonrange()1063 unibrow::Mapping<unibrow::CanonicalizationRange>* jsregexp_canonrange() { 1064 return &jsregexp_canonrange_; 1065 } 1066 runtime_state()1067 RuntimeState* runtime_state() { return &runtime_state_; } 1068 builtins()1069 Builtins* builtins() { return &builtins_; } 1070 1071 unibrow::Mapping<unibrow::Ecma262Canonicalize>* regexp_macro_assembler_canonicalize()1072 regexp_macro_assembler_canonicalize() { 1073 return ®exp_macro_assembler_canonicalize_; 1074 } 1075 regexp_stack()1076 RegExpStack* regexp_stack() { return regexp_stack_; } 1077 total_regexp_code_generated()1078 size_t total_regexp_code_generated() { return total_regexp_code_generated_; } IncreaseTotalRegexpCodeGenerated(int size)1079 void IncreaseTotalRegexpCodeGenerated(int size) { 1080 total_regexp_code_generated_ += size; 1081 } 1082 regexp_indices()1083 std::vector<int>* regexp_indices() { return ®exp_indices_; } 1084 1085 unibrow::Mapping<unibrow::Ecma262Canonicalize>* interp_canonicalize_mapping()1086 interp_canonicalize_mapping() { 1087 return ®exp_macro_assembler_canonicalize_; 1088 } 1089 debug()1090 Debug* debug() { return debug_; } 1091 is_profiling_address()1092 bool* is_profiling_address() { return &is_profiling_; } code_event_dispatcher()1093 CodeEventDispatcher* code_event_dispatcher() const { 1094 return code_event_dispatcher_.get(); 1095 } heap_profiler()1096 HeapProfiler* heap_profiler() const { return heap_profiler_; } 1097 1098 #ifdef DEBUG non_disposed_isolates()1099 static size_t non_disposed_isolates() { return non_disposed_isolates_; } 1100 #endif 1101 factory()1102 v8::internal::Factory* factory() { 1103 // Upcast to the privately inherited base-class using c-style casts to avoid 1104 // undefined behavior (as static_cast cannot cast across private bases). 1105 return (v8::internal::Factory*)this; // NOLINT(readability/casting) 1106 } 1107 1108 static const int kJSRegexpStaticOffsetsVectorSize = 128; 1109 THREAD_LOCAL_TOP_ACCESSOR(ExternalCallbackScope *,external_callback_scope)1110 THREAD_LOCAL_TOP_ACCESSOR(ExternalCallbackScope*, external_callback_scope) 1111 1112 THREAD_LOCAL_TOP_ACCESSOR(StateTag, current_vm_state) 1113 1114 void SetData(uint32_t slot, void* data) { 1115 DCHECK_LT(slot, Internals::kNumIsolateDataSlots); 1116 embedder_data_[slot] = data; 1117 } GetData(uint32_t slot)1118 void* GetData(uint32_t slot) { 1119 DCHECK_LT(slot, Internals::kNumIsolateDataSlots); 1120 return embedder_data_[slot]; 1121 } 1122 serializer_enabled()1123 bool serializer_enabled() const { return serializer_enabled_; } 1124 enable_serializer()1125 void enable_serializer() { serializer_enabled_ = true; } 1126 snapshot_available()1127 bool snapshot_available() const { 1128 return snapshot_blob_ != nullptr && snapshot_blob_->raw_size != 0; 1129 } 1130 IsDead()1131 bool IsDead() { return has_fatal_error_; } SignalFatalError()1132 void SignalFatalError() { has_fatal_error_ = true; } 1133 1134 bool use_optimizer(); 1135 initialized_from_snapshot()1136 bool initialized_from_snapshot() { return initialized_from_snapshot_; } 1137 1138 bool NeedsSourcePositionsForProfiling() const; 1139 1140 bool NeedsDetailedOptimizedCodeLineInfo() const; 1141 is_best_effort_code_coverage()1142 bool is_best_effort_code_coverage() const { 1143 return code_coverage_mode() == debug::Coverage::kBestEffort; 1144 } 1145 is_precise_count_code_coverage()1146 bool is_precise_count_code_coverage() const { 1147 return code_coverage_mode() == debug::Coverage::kPreciseCount; 1148 } 1149 is_precise_binary_code_coverage()1150 bool is_precise_binary_code_coverage() const { 1151 return code_coverage_mode() == debug::Coverage::kPreciseBinary; 1152 } 1153 is_block_count_code_coverage()1154 bool is_block_count_code_coverage() const { 1155 return code_coverage_mode() == debug::Coverage::kBlockCount; 1156 } 1157 is_block_binary_code_coverage()1158 bool is_block_binary_code_coverage() const { 1159 return code_coverage_mode() == debug::Coverage::kBlockBinary; 1160 } 1161 is_block_code_coverage()1162 bool is_block_code_coverage() const { 1163 return is_block_count_code_coverage() || is_block_binary_code_coverage(); 1164 } 1165 is_collecting_type_profile()1166 bool is_collecting_type_profile() const { 1167 return type_profile_mode() == debug::TypeProfile::kCollect; 1168 } 1169 1170 // Collect feedback vectors with data for code coverage or type profile. 1171 // Reset the list, when both code coverage and type profile are not 1172 // needed anymore. This keeps many feedback vectors alive, but code 1173 // coverage or type profile are used for debugging only and increase in 1174 // memory usage is expected. 1175 void SetFeedbackVectorsForProfilingTools(Object* value); 1176 1177 void MaybeInitializeVectorListFromHeap(); 1178 time_millis_since_init()1179 double time_millis_since_init() { 1180 return heap_.MonotonicallyIncreasingTimeInMs() - time_millis_at_init_; 1181 } 1182 date_cache()1183 DateCache* date_cache() { 1184 return date_cache_; 1185 } 1186 set_date_cache(DateCache * date_cache)1187 void set_date_cache(DateCache* date_cache) { 1188 if (date_cache != date_cache_) { 1189 delete date_cache_; 1190 } 1191 date_cache_ = date_cache; 1192 } 1193 1194 #ifdef V8_INTL_SUPPORT language_singleton_regexp_matcher()1195 icu::RegexMatcher* language_singleton_regexp_matcher() { 1196 return language_singleton_regexp_matcher_; 1197 } 1198 language_tag_regexp_matcher()1199 icu::RegexMatcher* language_tag_regexp_matcher() { 1200 return language_tag_regexp_matcher_; 1201 } 1202 language_variant_regexp_matcher()1203 icu::RegexMatcher* language_variant_regexp_matcher() { 1204 return language_variant_regexp_matcher_; 1205 } 1206 default_locale()1207 const std::string& default_locale() { return default_locale_; } 1208 set_default_locale(const std::string & locale)1209 void set_default_locale(const std::string& locale) { 1210 DCHECK_EQ(default_locale_.length(), 0); 1211 default_locale_ = locale; 1212 } 1213 set_language_tag_regexp_matchers(icu::RegexMatcher * language_singleton_regexp_matcher,icu::RegexMatcher * language_tag_regexp_matcher,icu::RegexMatcher * language_variant_regexp_matcher)1214 void set_language_tag_regexp_matchers( 1215 icu::RegexMatcher* language_singleton_regexp_matcher, 1216 icu::RegexMatcher* language_tag_regexp_matcher, 1217 icu::RegexMatcher* language_variant_regexp_matcher) { 1218 DCHECK_NULL(language_singleton_regexp_matcher_); 1219 DCHECK_NULL(language_tag_regexp_matcher_); 1220 DCHECK_NULL(language_variant_regexp_matcher_); 1221 language_singleton_regexp_matcher_ = language_singleton_regexp_matcher; 1222 language_tag_regexp_matcher_ = language_tag_regexp_matcher; 1223 language_variant_regexp_matcher_ = language_variant_regexp_matcher; 1224 } 1225 #endif // V8_INTL_SUPPORT 1226 1227 static const int kProtectorValid = 1; 1228 static const int kProtectorInvalid = 0; 1229 1230 inline bool IsArrayConstructorIntact(); 1231 1232 // The version with an explicit context parameter can be used when 1233 // Isolate::context is not set up, e.g. when calling directly into C++ from 1234 // CSA. 1235 bool IsNoElementsProtectorIntact(Context* context); 1236 bool IsNoElementsProtectorIntact(); 1237 1238 inline bool IsArraySpeciesLookupChainIntact(); 1239 inline bool IsTypedArraySpeciesLookupChainIntact(); 1240 inline bool IsPromiseSpeciesLookupChainIntact(); 1241 bool IsIsConcatSpreadableLookupChainIntact(); 1242 bool IsIsConcatSpreadableLookupChainIntact(JSReceiver* receiver); 1243 inline bool IsStringLengthOverflowIntact(); 1244 inline bool IsArrayIteratorLookupChainIntact(); 1245 1246 // Make sure we do check for neutered array buffers. 1247 inline bool IsArrayBufferNeuteringIntact(); 1248 1249 // Disable promise optimizations if promise (debug) hooks have ever been 1250 // active. 1251 bool IsPromiseHookProtectorIntact(); 1252 1253 // Make sure a lookup of "resolve" on the %Promise% intrinsic object 1254 // yeidls the initial Promise.resolve method. 1255 bool IsPromiseResolveLookupChainIntact(); 1256 1257 // Make sure a lookup of "then" on any JSPromise whose [[Prototype]] is the 1258 // initial %PromisePrototype% yields the initial method. In addition this 1259 // protector also guards the negative lookup of "then" on the intrinsic 1260 // %ObjectPrototype%, meaning that such lookups are guaranteed to yield 1261 // undefined without triggering any side-effects. 1262 bool IsPromiseThenLookupChainIntact(); 1263 bool IsPromiseThenLookupChainIntact(Handle<JSReceiver> receiver); 1264 1265 // On intent to set an element in object, make sure that appropriate 1266 // notifications occur if the set is on the elements of the array or 1267 // object prototype. Also ensure that changes to prototype chain between 1268 // Array and Object fire notifications. 1269 void UpdateNoElementsProtectorOnSetElement(Handle<JSObject> object); UpdateNoElementsProtectorOnSetLength(Handle<JSObject> object)1270 void UpdateNoElementsProtectorOnSetLength(Handle<JSObject> object) { 1271 UpdateNoElementsProtectorOnSetElement(object); 1272 } UpdateNoElementsProtectorOnSetPrototype(Handle<JSObject> object)1273 void UpdateNoElementsProtectorOnSetPrototype(Handle<JSObject> object) { 1274 UpdateNoElementsProtectorOnSetElement(object); 1275 } UpdateNoElementsProtectorOnNormalizeElements(Handle<JSObject> object)1276 void UpdateNoElementsProtectorOnNormalizeElements(Handle<JSObject> object) { 1277 UpdateNoElementsProtectorOnSetElement(object); 1278 } 1279 void InvalidateArrayConstructorProtector(); 1280 void InvalidateArraySpeciesProtector(); 1281 void InvalidateTypedArraySpeciesProtector(); 1282 void InvalidatePromiseSpeciesProtector(); 1283 void InvalidateIsConcatSpreadableProtector(); 1284 void InvalidateStringLengthOverflowProtector(); 1285 void InvalidateArrayIteratorProtector(); 1286 void InvalidateArrayBufferNeuteringProtector(); 1287 V8_EXPORT_PRIVATE void InvalidatePromiseHookProtector(); 1288 void InvalidatePromiseResolveProtector(); 1289 void InvalidatePromiseThenProtector(); 1290 1291 // Returns true if array is the initial array prototype in any native context. 1292 bool IsAnyInitialArrayPrototype(Handle<JSArray> array); 1293 1294 void IterateDeferredHandles(RootVisitor* visitor); 1295 void LinkDeferredHandles(DeferredHandles* deferred_handles); 1296 void UnlinkDeferredHandles(DeferredHandles* deferred_handles); 1297 1298 #ifdef DEBUG 1299 bool IsDeferredHandle(Object** location); 1300 #endif // DEBUG 1301 concurrent_recompilation_enabled()1302 bool concurrent_recompilation_enabled() { 1303 // Thread is only available with flag enabled. 1304 DCHECK(optimizing_compile_dispatcher_ == nullptr || 1305 FLAG_concurrent_recompilation); 1306 return optimizing_compile_dispatcher_ != nullptr; 1307 } 1308 optimizing_compile_dispatcher()1309 OptimizingCompileDispatcher* optimizing_compile_dispatcher() { 1310 return optimizing_compile_dispatcher_; 1311 } 1312 // Flushes all pending concurrent optimzation jobs from the optimizing 1313 // compile dispatcher's queue. 1314 void AbortConcurrentOptimization(BlockingBehavior blocking_behavior); 1315 id()1316 int id() const { return static_cast<int>(id_); } 1317 1318 CompilationStatistics* GetTurboStatistics(); 1319 CodeTracer* GetCodeTracer(); 1320 1321 void DumpAndResetStats(); 1322 function_entry_hook()1323 FunctionEntryHook function_entry_hook() { return function_entry_hook_; } set_function_entry_hook(FunctionEntryHook function_entry_hook)1324 void set_function_entry_hook(FunctionEntryHook function_entry_hook) { 1325 function_entry_hook_ = function_entry_hook; 1326 } 1327 stress_deopt_count_address()1328 void* stress_deopt_count_address() { return &stress_deopt_count_; } 1329 set_force_slow_path(bool v)1330 void set_force_slow_path(bool v) { force_slow_path_ = v; } force_slow_path()1331 bool force_slow_path() const { return force_slow_path_; } force_slow_path_address()1332 bool* force_slow_path_address() { return &force_slow_path_; } 1333 1334 V8_EXPORT_PRIVATE base::RandomNumberGenerator* random_number_generator(); 1335 1336 V8_EXPORT_PRIVATE base::RandomNumberGenerator* fuzzer_rng(); 1337 1338 // Generates a random number that is non-zero when masked 1339 // with the provided mask. 1340 int GenerateIdentityHash(uint32_t mask); 1341 1342 // Given an address occupied by a live code object, return that object. 1343 Code* FindCodeObject(Address a); 1344 NextOptimizationId()1345 int NextOptimizationId() { 1346 int id = next_optimization_id_++; 1347 if (!Smi::IsValid(next_optimization_id_)) { 1348 next_optimization_id_ = 0; 1349 } 1350 return id; 1351 } 1352 1353 void AddNearHeapLimitCallback(v8::NearHeapLimitCallback, void* data); 1354 void RemoveNearHeapLimitCallback(v8::NearHeapLimitCallback callback, 1355 size_t heap_limit); 1356 void AddCallCompletedCallback(CallCompletedCallback callback); 1357 void RemoveCallCompletedCallback(CallCompletedCallback callback); 1358 void FireCallCompletedCallback(); 1359 1360 void AddBeforeCallEnteredCallback(BeforeCallEnteredCallback callback); 1361 void RemoveBeforeCallEnteredCallback(BeforeCallEnteredCallback callback); 1362 inline void FireBeforeCallEnteredCallback(); 1363 1364 void AddMicrotasksCompletedCallback(MicrotasksCompletedCallback callback); 1365 void RemoveMicrotasksCompletedCallback(MicrotasksCompletedCallback callback); 1366 inline void FireMicrotasksCompletedCallback(); 1367 1368 void SetPromiseRejectCallback(PromiseRejectCallback callback); 1369 void ReportPromiseReject(Handle<JSPromise> promise, Handle<Object> value, 1370 v8::PromiseRejectEvent event); 1371 1372 void EnqueueMicrotask(Handle<Microtask> microtask); 1373 void RunMicrotasks(); IsRunningMicrotasks()1374 bool IsRunningMicrotasks() const { return is_running_microtasks_; } 1375 1376 Handle<Symbol> SymbolFor(Heap::RootListIndex dictionary_index, 1377 Handle<String> name, bool private_symbol); 1378 1379 void SetUseCounterCallback(v8::Isolate::UseCounterCallback callback); 1380 void CountUsage(v8::Isolate::UseCounterFeature feature); 1381 1382 std::string GetTurboCfgFileName(); 1383 1384 #if V8_SFI_HAS_UNIQUE_ID GetNextUniqueSharedFunctionInfoId()1385 int GetNextUniqueSharedFunctionInfoId() { return next_unique_sfi_id_++; } 1386 #endif 1387 promise_hook_address()1388 Address promise_hook_address() { 1389 return reinterpret_cast<Address>(&promise_hook_); 1390 } 1391 async_event_delegate_address()1392 Address async_event_delegate_address() { 1393 return reinterpret_cast<Address>(&async_event_delegate_); 1394 } 1395 promise_hook_or_async_event_delegate_address()1396 Address promise_hook_or_async_event_delegate_address() { 1397 return reinterpret_cast<Address>(&promise_hook_or_async_event_delegate_); 1398 } 1399 pending_microtask_count_address()1400 Address pending_microtask_count_address() { 1401 return reinterpret_cast<Address>(&pending_microtask_count_); 1402 } 1403 handle_scope_implementer_address()1404 Address handle_scope_implementer_address() { 1405 return reinterpret_cast<Address>(&handle_scope_implementer_); 1406 } 1407 1408 void SetAtomicsWaitCallback(v8::Isolate::AtomicsWaitCallback callback, 1409 void* data); 1410 void RunAtomicsWaitCallback(v8::Isolate::AtomicsWaitEvent event, 1411 Handle<JSArrayBuffer> array_buffer, 1412 size_t offset_in_bytes, int32_t value, 1413 double timeout_in_ms, 1414 AtomicsWaitWakeHandle* stop_handle); 1415 1416 void SetPromiseHook(PromiseHook hook); 1417 void RunPromiseHook(PromiseHookType type, Handle<JSPromise> promise, 1418 Handle<Object> parent); 1419 1420 void AddDetachedContext(Handle<Context> context); 1421 void CheckDetachedContextsAfterGC(); 1422 partial_snapshot_cache()1423 std::vector<Object*>* partial_snapshot_cache() { 1424 return &partial_snapshot_cache_; 1425 } 1426 1427 // Off-heap builtins cannot embed constants within the code object itself, 1428 // and thus need to load them from the root list. ShouldLoadConstantsFromRootList()1429 bool ShouldLoadConstantsFromRootList() const { 1430 if (FLAG_embedded_builtins) { 1431 return (serializer_enabled() && 1432 builtins_constants_table_builder() != nullptr); 1433 } else { 1434 return false; 1435 } 1436 } 1437 1438 // Called only prior to serialization. 1439 // This function copies off-heap-safe builtins off the heap, creates off-heap 1440 // trampolines, and sets up this isolate's embedded blob. 1441 void PrepareEmbeddedBlobForSerialization(); 1442 builtins_constants_table_builder()1443 BuiltinsConstantsTableBuilder* builtins_constants_table_builder() const { 1444 return builtins_constants_table_builder_; 1445 } 1446 1447 static const uint8_t* CurrentEmbeddedBlob(); 1448 static uint32_t CurrentEmbeddedBlobSize(); 1449 1450 // These always return the same result as static methods above, but don't 1451 // access the global atomic variable (and thus *might be* slightly faster). 1452 const uint8_t* embedded_blob() const; 1453 uint32_t embedded_blob_size() const; 1454 set_array_buffer_allocator(v8::ArrayBuffer::Allocator * allocator)1455 void set_array_buffer_allocator(v8::ArrayBuffer::Allocator* allocator) { 1456 array_buffer_allocator_ = allocator; 1457 } array_buffer_allocator()1458 v8::ArrayBuffer::Allocator* array_buffer_allocator() const { 1459 return array_buffer_allocator_; 1460 } 1461 futex_wait_list_node()1462 FutexWaitListNode* futex_wait_list_node() { return &futex_wait_list_node_; } 1463 cancelable_task_manager()1464 CancelableTaskManager* cancelable_task_manager() { 1465 return cancelable_task_manager_; 1466 } 1467 ast_string_constants()1468 const AstStringConstants* ast_string_constants() const { 1469 return ast_string_constants_; 1470 } 1471 interpreter()1472 interpreter::Interpreter* interpreter() const { return interpreter_; } 1473 allocator()1474 AccountingAllocator* allocator() { return allocator_; } 1475 compiler_dispatcher()1476 CompilerDispatcher* compiler_dispatcher() const { 1477 return compiler_dispatcher_; 1478 } 1479 1480 bool IsInAnyContext(Object* object, uint32_t index); 1481 1482 void SetHostImportModuleDynamicallyCallback( 1483 HostImportModuleDynamicallyCallback callback); 1484 MaybeHandle<JSPromise> RunHostImportModuleDynamicallyCallback( 1485 Handle<Script> referrer, Handle<Object> specifier); 1486 1487 void SetHostInitializeImportMetaObjectCallback( 1488 HostInitializeImportMetaObjectCallback callback); 1489 Handle<JSObject> RunHostInitializeImportMetaObjectCallback( 1490 Handle<Module> module); 1491 1492 void SetRAILMode(RAILMode rail_mode); 1493 rail_mode()1494 RAILMode rail_mode() { return rail_mode_.Value(); } 1495 1496 double LoadStartTimeMs(); 1497 1498 void IsolateInForegroundNotification(); 1499 1500 void IsolateInBackgroundNotification(); 1501 IsIsolateInBackground()1502 bool IsIsolateInBackground() { return is_isolate_in_background_; } 1503 EnableMemorySavingsMode()1504 void EnableMemorySavingsMode() { memory_savings_mode_active_ = true; } 1505 DisableMemorySavingsMode()1506 void DisableMemorySavingsMode() { memory_savings_mode_active_ = false; } 1507 IsMemorySavingsModeActive()1508 bool IsMemorySavingsModeActive() { return memory_savings_mode_active_; } 1509 1510 PRINTF_FORMAT(2, 3) void PrintWithTimestamp(const char* format, ...); 1511 set_allow_atomics_wait(bool set)1512 void set_allow_atomics_wait(bool set) { allow_atomics_wait_ = set; } allow_atomics_wait()1513 bool allow_atomics_wait() { return allow_atomics_wait_; } 1514 1515 // Register a finalizer to be called at isolate teardown. 1516 void RegisterManagedPtrDestructor(ManagedPtrDestructor* finalizer); 1517 1518 // Removes a previously-registered shared object finalizer. 1519 void UnregisterManagedPtrDestructor(ManagedPtrDestructor* finalizer); 1520 elements_deletion_counter()1521 size_t elements_deletion_counter() { return elements_deletion_counter_; } set_elements_deletion_counter(size_t value)1522 void set_elements_deletion_counter(size_t value) { 1523 elements_deletion_counter_ = value; 1524 } 1525 wasm_engine()1526 wasm::WasmEngine* wasm_engine() const { return wasm_engine_.get(); } set_wasm_engine(std::shared_ptr<wasm::WasmEngine> engine)1527 void set_wasm_engine(std::shared_ptr<wasm::WasmEngine> engine) { 1528 DCHECK_NULL(wasm_engine_); // Only call once before {Init}. 1529 wasm_engine_ = std::move(engine); 1530 } 1531 top_backup_incumbent_scope()1532 const v8::Context::BackupIncumbentScope* top_backup_incumbent_scope() const { 1533 return top_backup_incumbent_scope_; 1534 } set_top_backup_incumbent_scope(const v8::Context::BackupIncumbentScope * top_backup_incumbent_scope)1535 void set_top_backup_incumbent_scope( 1536 const v8::Context::BackupIncumbentScope* top_backup_incumbent_scope) { 1537 top_backup_incumbent_scope_ = top_backup_incumbent_scope; 1538 } 1539 1540 void SetIdle(bool is_idle); 1541 1542 protected: 1543 Isolate(); 1544 bool IsArrayOrObjectOrStringPrototype(Object* object); 1545 1546 private: 1547 friend struct GlobalState; 1548 friend struct InitializeGlobalState; 1549 1550 // These fields are accessed through the API, offsets must be kept in sync 1551 // with v8::internal::Internals (in include/v8.h) constants. This is also 1552 // verified in Isolate::Init() using runtime checks. 1553 void* embedder_data_[Internals::kNumIsolateDataSlots]; 1554 Heap heap_; 1555 1556 class ThreadDataTable { 1557 public: 1558 ThreadDataTable(); 1559 ~ThreadDataTable(); 1560 1561 PerIsolateThreadData* Lookup(ThreadId thread_id); 1562 void Insert(PerIsolateThreadData* data); 1563 void Remove(PerIsolateThreadData* data); 1564 void RemoveAllThreads(); 1565 1566 private: 1567 struct Hasher { operatorHasher1568 std::size_t operator()(const ThreadId& t) const { 1569 return std::hash<int>()(t.ToInteger()); 1570 } 1571 }; 1572 1573 std::unordered_map<ThreadId, PerIsolateThreadData*, Hasher> table_; 1574 }; 1575 1576 // These items form a stack synchronously with threads Enter'ing and Exit'ing 1577 // the Isolate. The top of the stack points to a thread which is currently 1578 // running the Isolate. When the stack is empty, the Isolate is considered 1579 // not entered by any thread and can be Disposed. 1580 // If the same thread enters the Isolate more than once, the entry_count_ 1581 // is incremented rather then a new item pushed to the stack. 1582 class EntryStackItem { 1583 public: EntryStackItem(PerIsolateThreadData * previous_thread_data,Isolate * previous_isolate,EntryStackItem * previous_item)1584 EntryStackItem(PerIsolateThreadData* previous_thread_data, 1585 Isolate* previous_isolate, 1586 EntryStackItem* previous_item) 1587 : entry_count(1), 1588 previous_thread_data(previous_thread_data), 1589 previous_isolate(previous_isolate), 1590 previous_item(previous_item) { } 1591 1592 int entry_count; 1593 PerIsolateThreadData* previous_thread_data; 1594 Isolate* previous_isolate; 1595 EntryStackItem* previous_item; 1596 1597 private: 1598 DISALLOW_COPY_AND_ASSIGN(EntryStackItem); 1599 }; 1600 1601 static base::Thread::LocalStorageKey per_isolate_thread_data_key_; 1602 static base::Thread::LocalStorageKey isolate_key_; 1603 static base::Thread::LocalStorageKey thread_id_key_; 1604 1605 // A global counter for all generated Isolates, might overflow. 1606 static base::Atomic32 isolate_counter_; 1607 1608 #if DEBUG 1609 static base::Atomic32 isolate_key_created_; 1610 #endif 1611 1612 void Deinit(); 1613 1614 static void SetIsolateThreadLocals(Isolate* isolate, 1615 PerIsolateThreadData* data); 1616 1617 // Find the PerThread for this particular (isolate, thread) combination. 1618 // If one does not yet exist, allocate a new one. 1619 PerIsolateThreadData* FindOrAllocatePerThreadDataForThisThread(); 1620 1621 // Initializes the current thread to run this Isolate. 1622 // Not thread-safe. Multiple threads should not Enter/Exit the same isolate 1623 // at the same time, this should be prevented using external locking. 1624 void Enter(); 1625 1626 // Exits the current thread. The previosuly entered Isolate is restored 1627 // for the thread. 1628 // Not thread-safe. Multiple threads should not Enter/Exit the same isolate 1629 // at the same time, this should be prevented using external locking. 1630 void Exit(); 1631 1632 void InitializeThreadLocal(); 1633 1634 void MarkCompactPrologue(bool is_compacting, 1635 ThreadLocalTop* archived_thread_data); 1636 void MarkCompactEpilogue(bool is_compacting, 1637 ThreadLocalTop* archived_thread_data); 1638 1639 void FillCache(); 1640 1641 // Propagate pending exception message to the v8::TryCatch. 1642 // If there is no external try-catch or message was successfully propagated, 1643 // then return true. 1644 bool PropagatePendingExceptionToExternalTryCatch(); 1645 1646 void SetTerminationOnExternalTryCatch(); 1647 1648 void PromiseHookStateUpdated(); 1649 void RunPromiseHookForAsyncEventDelegate(PromiseHookType type, 1650 Handle<JSPromise> promise); 1651 RAILModeName(RAILMode rail_mode)1652 const char* RAILModeName(RAILMode rail_mode) const { 1653 switch (rail_mode) { 1654 case PERFORMANCE_RESPONSE: 1655 return "RESPONSE"; 1656 case PERFORMANCE_ANIMATION: 1657 return "ANIMATION"; 1658 case PERFORMANCE_IDLE: 1659 return "IDLE"; 1660 case PERFORMANCE_LOAD: 1661 return "LOAD"; 1662 } 1663 return ""; 1664 } 1665 1666 base::Atomic32 id_; 1667 EntryStackItem* entry_stack_; 1668 int stack_trace_nesting_level_; 1669 StringStream* incomplete_message_; 1670 Address isolate_addresses_[kIsolateAddressCount + 1]; // NOLINT 1671 Bootstrapper* bootstrapper_; 1672 RuntimeProfiler* runtime_profiler_; 1673 CompilationCache* compilation_cache_; 1674 std::shared_ptr<Counters> async_counters_; 1675 base::RecursiveMutex break_access_; 1676 Logger* logger_; 1677 StackGuard stack_guard_; 1678 StubCache* load_stub_cache_; 1679 StubCache* store_stub_cache_; 1680 DeoptimizerData* deoptimizer_data_; 1681 bool deoptimizer_lazy_throw_; 1682 MaterializedObjectStore* materialized_object_store_; 1683 ThreadLocalTop thread_local_top_; 1684 bool capture_stack_trace_for_uncaught_exceptions_; 1685 int stack_trace_for_uncaught_exceptions_frame_limit_; 1686 StackTrace::StackTraceOptions stack_trace_for_uncaught_exceptions_options_; 1687 ContextSlotCache* context_slot_cache_; 1688 DescriptorLookupCache* descriptor_lookup_cache_; 1689 HandleScopeData handle_scope_data_; 1690 HandleScopeImplementer* handle_scope_implementer_; 1691 UnicodeCache* unicode_cache_; 1692 AccountingAllocator* allocator_; 1693 InnerPointerToCodeCache* inner_pointer_to_code_cache_; 1694 GlobalHandles* global_handles_; 1695 EternalHandles* eternal_handles_; 1696 ThreadManager* thread_manager_; 1697 RuntimeState runtime_state_; 1698 Builtins builtins_; 1699 SetupIsolateDelegate* setup_delegate_; 1700 unibrow::Mapping<unibrow::Ecma262UnCanonicalize> jsregexp_uncanonicalize_; 1701 unibrow::Mapping<unibrow::CanonicalizationRange> jsregexp_canonrange_; 1702 unibrow::Mapping<unibrow::Ecma262Canonicalize> 1703 regexp_macro_assembler_canonicalize_; 1704 RegExpStack* regexp_stack_; 1705 std::vector<int> regexp_indices_; 1706 DateCache* date_cache_; 1707 base::RandomNumberGenerator* random_number_generator_; 1708 base::RandomNumberGenerator* fuzzer_rng_; 1709 base::AtomicValue<RAILMode> rail_mode_; 1710 v8::Isolate::AtomicsWaitCallback atomics_wait_callback_; 1711 void* atomics_wait_callback_data_; 1712 PromiseHook promise_hook_; 1713 HostImportModuleDynamicallyCallback host_import_module_dynamically_callback_; 1714 HostInitializeImportMetaObjectCallback 1715 host_initialize_import_meta_object_callback_; 1716 base::Mutex rail_mutex_; 1717 double load_start_time_ms_; 1718 1719 #ifdef V8_INTL_SUPPORT 1720 icu::RegexMatcher* language_singleton_regexp_matcher_; 1721 icu::RegexMatcher* language_tag_regexp_matcher_; 1722 icu::RegexMatcher* language_variant_regexp_matcher_; 1723 std::string default_locale_; 1724 #endif // V8_INTL_SUPPORT 1725 1726 // Whether the isolate has been created for snapshotting. 1727 bool serializer_enabled_; 1728 1729 // True if fatal error has been signaled for this isolate. 1730 bool has_fatal_error_; 1731 1732 // True if this isolate was initialized from a snapshot. 1733 bool initialized_from_snapshot_; 1734 1735 // True if ES2015 tail call elimination feature is enabled. 1736 bool is_tail_call_elimination_enabled_; 1737 1738 // True if the isolate is in background. This flag is used 1739 // to prioritize between memory usage and latency. 1740 bool is_isolate_in_background_; 1741 1742 // True if the isolate is in memory savings mode. This flag is used to 1743 // favor memory over runtime performance. 1744 bool memory_savings_mode_active_; 1745 1746 // Time stamp at initialization. 1747 double time_millis_at_init_; 1748 1749 #ifdef DEBUG 1750 static std::atomic<size_t> non_disposed_isolates_; 1751 1752 JSObject::SpillInformation js_spill_information_; 1753 #endif 1754 1755 Debug* debug_; 1756 HeapProfiler* heap_profiler_; 1757 std::unique_ptr<CodeEventDispatcher> code_event_dispatcher_; 1758 FunctionEntryHook function_entry_hook_; 1759 1760 const AstStringConstants* ast_string_constants_; 1761 1762 interpreter::Interpreter* interpreter_; 1763 1764 CompilerDispatcher* compiler_dispatcher_; 1765 1766 typedef std::pair<InterruptCallback, void*> InterruptEntry; 1767 std::queue<InterruptEntry> api_interrupts_queue_; 1768 1769 #define GLOBAL_BACKING_STORE(type, name, initialvalue) \ 1770 type name##_; 1771 ISOLATE_INIT_LIST(GLOBAL_BACKING_STORE) 1772 #undef GLOBAL_BACKING_STORE 1773 1774 #define GLOBAL_ARRAY_BACKING_STORE(type, name, length) \ 1775 type name##_[length]; 1776 ISOLATE_INIT_ARRAY_LIST(GLOBAL_ARRAY_BACKING_STORE) 1777 #undef GLOBAL_ARRAY_BACKING_STORE 1778 1779 #ifdef DEBUG 1780 // This class is huge and has a number of fields controlled by 1781 // preprocessor defines. Make sure the offsets of these fields agree 1782 // between compilation units. 1783 #define ISOLATE_FIELD_OFFSET(type, name, ignored) \ 1784 static const intptr_t name##_debug_offset_; 1785 ISOLATE_INIT_LIST(ISOLATE_FIELD_OFFSET) 1786 ISOLATE_INIT_ARRAY_LIST(ISOLATE_FIELD_OFFSET) 1787 #undef ISOLATE_FIELD_OFFSET 1788 #endif 1789 1790 DeferredHandles* deferred_handles_head_; 1791 OptimizingCompileDispatcher* optimizing_compile_dispatcher_; 1792 1793 // Counts deopt points if deopt_every_n_times is enabled. 1794 unsigned int stress_deopt_count_; 1795 1796 bool force_slow_path_; 1797 1798 int next_optimization_id_; 1799 1800 #if V8_SFI_HAS_UNIQUE_ID 1801 int next_unique_sfi_id_; 1802 #endif 1803 1804 // Vector of callbacks before a Call starts execution. 1805 std::vector<BeforeCallEnteredCallback> before_call_entered_callbacks_; 1806 1807 // Vector of callbacks when a Call completes. 1808 std::vector<CallCompletedCallback> call_completed_callbacks_; 1809 1810 // Vector of callbacks after microtasks were run. 1811 std::vector<MicrotasksCompletedCallback> microtasks_completed_callbacks_; 1812 bool is_running_microtasks_; 1813 1814 v8::Isolate::UseCounterCallback use_counter_callback_; 1815 1816 std::vector<Object*> partial_snapshot_cache_; 1817 1818 // Used during builtins compilation to build the builtins constants table, 1819 // which is stored on the root list prior to serialization. 1820 BuiltinsConstantsTableBuilder* builtins_constants_table_builder_ = nullptr; 1821 1822 void SetEmbeddedBlob(const uint8_t* blob, uint32_t blob_size); 1823 1824 const uint8_t* embedded_blob_ = nullptr; 1825 uint32_t embedded_blob_size_ = 0; 1826 1827 v8::ArrayBuffer::Allocator* array_buffer_allocator_; 1828 1829 FutexWaitListNode futex_wait_list_node_; 1830 1831 CancelableTaskManager* cancelable_task_manager_; 1832 1833 debug::ConsoleDelegate* console_delegate_ = nullptr; 1834 1835 debug::AsyncEventDelegate* async_event_delegate_ = nullptr; 1836 bool promise_hook_or_async_event_delegate_ = false; 1837 int async_task_count_ = 0; 1838 1839 v8::Isolate::AbortOnUncaughtExceptionCallback 1840 abort_on_uncaught_exception_callback_; 1841 1842 bool allow_atomics_wait_; 1843 1844 ManagedPtrDestructor* managed_ptr_destructors_head_ = nullptr; 1845 1846 size_t total_regexp_code_generated_; 1847 1848 size_t elements_deletion_counter_ = 0; 1849 1850 std::shared_ptr<wasm::WasmEngine> wasm_engine_; 1851 1852 std::unique_ptr<TracingCpuProfilerImpl> tracing_cpu_profiler_; 1853 1854 // The top entry of the v8::Context::BackupIncumbentScope stack. 1855 const v8::Context::BackupIncumbentScope* top_backup_incumbent_scope_ = 1856 nullptr; 1857 1858 // TODO(kenton@cloudflare.com): This mutex can be removed if 1859 // thread_data_table_ is always accessed under the isolate lock. I do not 1860 // know if this is the case, so I'm preserving it for now. 1861 base::Mutex thread_data_table_mutex_; 1862 ThreadDataTable thread_data_table_; 1863 1864 friend class ExecutionAccess; 1865 friend class HandleScopeImplementer; 1866 friend class heap::HeapTester; 1867 friend class OptimizingCompileDispatcher; 1868 friend class Simulator; 1869 friend class StackGuard; 1870 friend class SweeperThread; 1871 friend class TestIsolate; 1872 friend class ThreadId; 1873 friend class ThreadManager; 1874 friend class v8::Isolate; 1875 friend class v8::Locker; 1876 friend class v8::SnapshotCreator; 1877 friend class v8::Unlocker; 1878 1879 DISALLOW_COPY_AND_ASSIGN(Isolate); 1880 }; 1881 1882 1883 #undef FIELD_ACCESSOR 1884 #undef THREAD_LOCAL_TOP_ACCESSOR 1885 1886 1887 class PromiseOnStack { 1888 public: PromiseOnStack(Handle<JSObject> promise,PromiseOnStack * prev)1889 PromiseOnStack(Handle<JSObject> promise, PromiseOnStack* prev) 1890 : promise_(promise), prev_(prev) {} promise()1891 Handle<JSObject> promise() { return promise_; } prev()1892 PromiseOnStack* prev() { return prev_; } 1893 1894 private: 1895 Handle<JSObject> promise_; 1896 PromiseOnStack* prev_; 1897 }; 1898 1899 1900 // If the GCC version is 4.1.x or 4.2.x an additional field is added to the 1901 // class as a work around for a bug in the generated code found with these 1902 // versions of GCC. See V8 issue 122 for details. 1903 class SaveContext BASE_EMBEDDED { 1904 public: 1905 explicit SaveContext(Isolate* isolate); 1906 ~SaveContext(); 1907 context()1908 Handle<Context> context() { return context_; } prev()1909 SaveContext* prev() { return prev_; } 1910 1911 // Returns true if this save context is below a given JavaScript frame. 1912 bool IsBelowFrame(StandardFrame* frame); 1913 1914 private: 1915 Isolate* const isolate_; 1916 Handle<Context> context_; 1917 SaveContext* const prev_; 1918 Address c_entry_fp_; 1919 }; 1920 1921 1922 class AssertNoContextChange BASE_EMBEDDED { 1923 #ifdef DEBUG 1924 public: 1925 explicit AssertNoContextChange(Isolate* isolate); ~AssertNoContextChange()1926 ~AssertNoContextChange() { 1927 DCHECK(isolate_->context() == *context_); 1928 } 1929 1930 private: 1931 Isolate* isolate_; 1932 Handle<Context> context_; 1933 #else 1934 public: 1935 explicit AssertNoContextChange(Isolate* isolate) { } 1936 #endif 1937 }; 1938 1939 1940 class ExecutionAccess BASE_EMBEDDED { 1941 public: ExecutionAccess(Isolate * isolate)1942 explicit ExecutionAccess(Isolate* isolate) : isolate_(isolate) { 1943 Lock(isolate); 1944 } ~ExecutionAccess()1945 ~ExecutionAccess() { Unlock(isolate_); } 1946 Lock(Isolate * isolate)1947 static void Lock(Isolate* isolate) { isolate->break_access()->Lock(); } Unlock(Isolate * isolate)1948 static void Unlock(Isolate* isolate) { isolate->break_access()->Unlock(); } 1949 TryLock(Isolate * isolate)1950 static bool TryLock(Isolate* isolate) { 1951 return isolate->break_access()->TryLock(); 1952 } 1953 1954 private: 1955 Isolate* isolate_; 1956 }; 1957 1958 1959 // Support for checking for stack-overflows. 1960 class StackLimitCheck BASE_EMBEDDED { 1961 public: StackLimitCheck(Isolate * isolate)1962 explicit StackLimitCheck(Isolate* isolate) : isolate_(isolate) { } 1963 1964 // Use this to check for stack-overflows in C++ code. HasOverflowed()1965 bool HasOverflowed() const { 1966 StackGuard* stack_guard = isolate_->stack_guard(); 1967 return GetCurrentStackPosition() < stack_guard->real_climit(); 1968 } 1969 1970 // Use this to check for interrupt request in C++ code. InterruptRequested()1971 bool InterruptRequested() { 1972 StackGuard* stack_guard = isolate_->stack_guard(); 1973 return GetCurrentStackPosition() < stack_guard->climit(); 1974 } 1975 1976 // Use this to check for stack-overflow when entering runtime from JS code. 1977 bool JsHasOverflowed(uintptr_t gap = 0) const; 1978 1979 private: 1980 Isolate* isolate_; 1981 }; 1982 1983 #define STACK_CHECK(isolate, result_value) \ 1984 do { \ 1985 StackLimitCheck stack_check(isolate); \ 1986 if (stack_check.HasOverflowed()) { \ 1987 isolate->StackOverflow(); \ 1988 return result_value; \ 1989 } \ 1990 } while (false) 1991 1992 // Scope intercepts only interrupt which is part of its interrupt_mask and does 1993 // not affect other interrupts. 1994 class InterruptsScope { 1995 public: 1996 enum Mode { kPostponeInterrupts, kRunInterrupts, kNoop }; 1997 ~InterruptsScope()1998 virtual ~InterruptsScope() { 1999 if (mode_ != kNoop) stack_guard_->PopInterruptsScope(); 2000 } 2001 2002 // Find the scope that intercepts this interrupt. 2003 // It may be outermost PostponeInterruptsScope or innermost 2004 // SafeForInterruptsScope if any. 2005 // Return whether the interrupt has been intercepted. 2006 bool Intercept(StackGuard::InterruptFlag flag); 2007 InterruptsScope(Isolate * isolate,int intercept_mask,Mode mode)2008 InterruptsScope(Isolate* isolate, int intercept_mask, Mode mode) 2009 : stack_guard_(isolate->stack_guard()), 2010 intercept_mask_(intercept_mask), 2011 intercepted_flags_(0), 2012 mode_(mode) { 2013 if (mode_ != kNoop) stack_guard_->PushInterruptsScope(this); 2014 } 2015 2016 private: 2017 StackGuard* stack_guard_; 2018 int intercept_mask_; 2019 int intercepted_flags_; 2020 Mode mode_; 2021 InterruptsScope* prev_; 2022 2023 friend class StackGuard; 2024 }; 2025 2026 // Support for temporarily postponing interrupts. When the outermost 2027 // postpone scope is left the interrupts will be re-enabled and any 2028 // interrupts that occurred while in the scope will be taken into 2029 // account. 2030 class PostponeInterruptsScope : public InterruptsScope { 2031 public: 2032 PostponeInterruptsScope(Isolate* isolate, 2033 int intercept_mask = StackGuard::ALL_INTERRUPTS) InterruptsScope(isolate,intercept_mask,InterruptsScope::kPostponeInterrupts)2034 : InterruptsScope(isolate, intercept_mask, 2035 InterruptsScope::kPostponeInterrupts) {} 2036 virtual ~PostponeInterruptsScope() = default; 2037 }; 2038 2039 // Support for overriding PostponeInterruptsScope. Interrupt is not ignored if 2040 // innermost scope is SafeForInterruptsScope ignoring any outer 2041 // PostponeInterruptsScopes. 2042 class SafeForInterruptsScope : public InterruptsScope { 2043 public: 2044 SafeForInterruptsScope(Isolate* isolate, 2045 int intercept_mask = StackGuard::ALL_INTERRUPTS) InterruptsScope(isolate,intercept_mask,InterruptsScope::kRunInterrupts)2046 : InterruptsScope(isolate, intercept_mask, 2047 InterruptsScope::kRunInterrupts) {} 2048 virtual ~SafeForInterruptsScope() = default; 2049 }; 2050 2051 class StackTraceFailureMessage { 2052 public: 2053 explicit StackTraceFailureMessage(Isolate* isolate, void* ptr1 = nullptr, 2054 void* ptr2 = nullptr, void* ptr3 = nullptr, 2055 void* ptr4 = nullptr); 2056 2057 V8_NOINLINE void Print() volatile; 2058 2059 static const uintptr_t kStartMarker = 0xdecade30; 2060 static const uintptr_t kEndMarker = 0xdecade31; 2061 static const int kStacktraceBufferSize = 32 * KB; 2062 2063 uintptr_t start_marker_ = kStartMarker; 2064 void* isolate_; 2065 void* ptr1_; 2066 void* ptr2_; 2067 void* ptr3_; 2068 void* ptr4_; 2069 void* code_objects_[4]; 2070 char js_stack_trace_[kStacktraceBufferSize]; 2071 uintptr_t end_marker_ = kEndMarker; 2072 }; 2073 2074 } // namespace internal 2075 } // namespace v8 2076 2077 #endif // V8_ISOLATE_H_ 2078