// Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. #include "node_buffer.h" #include "node.h" #include "node_blob.h" #include "node_debug.h" #include "node_errors.h" #include "node_external_reference.h" #include "node_i18n.h" #include "node_internals.h" #include "env-inl.h" #include "simdutf.h" #include "string_bytes.h" #include "util-inl.h" #include "v8-fast-api-calls.h" #include "v8.h" #include #include #include #include "nbytes.h" #define THROW_AND_RETURN_UNLESS_BUFFER(env, obj) \ THROW_AND_RETURN_IF_NOT_BUFFER(env, obj, "argument") \ #define THROW_AND_RETURN_IF_OOB(r) \ do { \ Maybe m = (r); \ if (m.IsNothing()) return; \ if (!m.FromJust()) \ return node::THROW_ERR_OUT_OF_RANGE(env, "Index out of range"); \ } while (0) \ namespace node { namespace Buffer { using v8::ArrayBuffer; using v8::ArrayBufferView; using v8::BackingStore; using v8::BackingStoreInitializationMode; using v8::BackingStoreOnFailureMode; using v8::CFunction; using v8::Context; using v8::EscapableHandleScope; using v8::FastApiCallbackOptions; using v8::FastOneByteString; using v8::FunctionCallbackInfo; using v8::Global; using v8::HandleScope; using v8::Int32; using v8::Integer; using v8::Isolate; using v8::Just; using v8::Local; using v8::Maybe; using v8::MaybeLocal; using v8::Nothing; using v8::Number; using v8::Object; using v8::SharedArrayBuffer; using v8::String; using v8::Uint32; using v8::Uint8Array; using v8::Value; namespace { class CallbackInfo : public Cleanable { public: static inline Local CreateTrackedArrayBuffer( Environment* env, char* data, size_t length, FreeCallback callback, void* hint); CallbackInfo(const CallbackInfo&) = delete; CallbackInfo& operator=(const CallbackInfo&) = delete; private: void Clean() override; inline void OnBackingStoreFree(); inline void CallAndResetCallback(); inline CallbackInfo(Environment* env, FreeCallback callback, char* data, void* hint); Global persistent_; Mutex mutex_; // Protects callback_. FreeCallback callback_; char* const data_; void* const hint_; Environment* const env_; }; Local CallbackInfo::CreateTrackedArrayBuffer( Environment* env, char* data, size_t length, FreeCallback callback, void* hint) { CHECK_NOT_NULL(callback); CHECK_IMPLIES(data == nullptr, length == 0); CallbackInfo* self = new CallbackInfo(env, callback, data, hint); std::unique_ptr bs = ArrayBuffer::NewBackingStore(data, length, [](void*, size_t, void* arg) { static_cast(arg)->OnBackingStoreFree(); }, self); Local ab = ArrayBuffer::New(env->isolate(), std::move(bs)); // V8 simply ignores the BackingStore deleter callback if data == nullptr, // but our API contract requires it being called. if (data == nullptr) { ab->Detach(Local()).Check(); self->OnBackingStoreFree(); // This calls `callback` asynchronously. } else { // Store the ArrayBuffer so that we can detach it later. self->persistent_.Reset(env->isolate(), ab); self->persistent_.SetWeak(); } return ab; } CallbackInfo::CallbackInfo(Environment* env, FreeCallback callback, char* data, void* hint) : callback_(callback), data_(data), hint_(hint), env_(env) { env->cleanable_queue()->PushFront(this); env->external_memory_accounter()->Increase(env->isolate(), sizeof(*this)); } void CallbackInfo::Clean() { { HandleScope handle_scope(env_->isolate()); Local ab = persistent_.Get(env_->isolate()); if (!ab.IsEmpty() && ab->IsDetachable()) { ab->Detach(Local()).Check(); persistent_.Reset(); } } // Call the callback in this case, but don't delete `this` yet because the // BackingStore deleter callback will do so later. CallAndResetCallback(); } void CallbackInfo::CallAndResetCallback() { FreeCallback callback; { Mutex::ScopedLock lock(mutex_); callback = callback_; callback_ = nullptr; } if (callback != nullptr) { // Clean up all Environment-related state and run the callback. cleanable_queue_.Remove(); env_->external_memory_accounter()->Decrease(env_->isolate(), sizeof(*this)); callback(data_, hint_); } } void CallbackInfo::OnBackingStoreFree() { // This method should always release the memory for `this`. std::unique_ptr self { this }; Mutex::ScopedLock lock(mutex_); // If callback_ == nullptr, that means that the callback has already run from // the cleanup hook, and there is nothing left to do here besides to clean // up the memory involved. In particular, the underlying `Environment` may // be gone at this point, so don’t attempt to call SetImmediateThreadsafe(). if (callback_ == nullptr) return; env_->SetImmediateThreadsafe([self = std::move(self)](Environment* env) { CHECK_EQ(self->env_, env); // Consistency check. self->CallAndResetCallback(); }); } // Parse index for external array data. An empty Maybe indicates // a pending exception. `false` indicates that the index is out-of-bounds. inline MUST_USE_RESULT Maybe ParseArrayIndex(Environment* env, Local arg, size_t def, size_t* ret) { if (arg->IsUndefined()) { *ret = def; return Just(true); } int64_t tmp_i; if (!arg->IntegerValue(env->context()).To(&tmp_i)) return Nothing(); if (tmp_i < 0) return Just(false); // Check that the result fits in a size_t. // coverity[pointless_expression] if (static_cast(tmp_i) > std::numeric_limits::max()) return Just(false); *ret = static_cast(tmp_i); return Just(true); } } // anonymous namespace // Buffer methods bool HasInstance(Local val) { return val->IsArrayBufferView(); } bool HasInstance(Local obj) { return obj->IsArrayBufferView(); } char* Data(Local val) { CHECK(val->IsArrayBufferView()); Local ui = val.As(); return static_cast(ui->Buffer()->Data()) + ui->ByteOffset(); } char* Data(Local obj) { return Data(obj.As()); } size_t Length(Local val) { CHECK(val->IsArrayBufferView()); Local ui = val.As(); return ui->ByteLength(); } size_t Length(Local obj) { CHECK(obj->IsArrayBufferView()); Local ui = obj.As(); return ui->ByteLength(); } MaybeLocal New(Environment* env, Local ab, size_t byte_offset, size_t length) { CHECK(!env->buffer_prototype_object().IsEmpty()); Local ui = Uint8Array::New(ab, byte_offset, length); if (ui->SetPrototypeV2(env->context(), env->buffer_prototype_object()) .IsNothing()) { return MaybeLocal(); } return ui; } MaybeLocal New(Isolate* isolate, Local ab, size_t byte_offset, size_t length) { Environment* env = Environment::GetCurrent(isolate); if (env == nullptr) { THROW_ERR_BUFFER_CONTEXT_NOT_AVAILABLE(isolate); return MaybeLocal(); } return New(env, ab, byte_offset, length); } MaybeLocal New(Isolate* isolate, Local string, enum encoding enc) { EscapableHandleScope scope(isolate); size_t length; if (!StringBytes::Size(isolate, string, enc).To(&length)) return {}; size_t actual = 0; std::unique_ptr store; if (length > 0) { store = ArrayBuffer::NewBackingStore( isolate, length, BackingStoreInitializationMode::kZeroInitialized, BackingStoreOnFailureMode::kReturnNull); if (!store) [[unlikely]] { THROW_ERR_MEMORY_ALLOCATION_FAILED(isolate); return {}; } actual = StringBytes::Write( isolate, static_cast(store->Data()), length, string, enc); CHECK(actual <= length); if (actual > 0) [[likely]] { if (actual < length) { std::unique_ptr old_store = std::move(store); store = ArrayBuffer::NewBackingStore( isolate, actual, BackingStoreInitializationMode::kUninitialized, BackingStoreOnFailureMode::kReturnNull); if (!store) [[unlikely]] { THROW_ERR_MEMORY_ALLOCATION_FAILED(isolate); return {}; } memcpy(store->Data(), old_store->Data(), actual); } Local buf = ArrayBuffer::New(isolate, std::move(store)); Local obj; if (!New(isolate, buf, 0, actual).ToLocal(&obj)) [[unlikely]] { return {}; } return scope.Escape(obj); } } return scope.EscapeMaybe(New(isolate, 0)); } MaybeLocal New(Isolate* isolate, size_t length) { EscapableHandleScope handle_scope(isolate); Local obj; Environment* env = Environment::GetCurrent(isolate); if (env == nullptr) { THROW_ERR_BUFFER_CONTEXT_NOT_AVAILABLE(isolate); return MaybeLocal(); } if (Buffer::New(env, length).ToLocal(&obj)) return handle_scope.Escape(obj); return Local(); } MaybeLocal New(Environment* env, size_t length) { Isolate* isolate(env->isolate()); EscapableHandleScope scope(isolate); // V8 currently only allows a maximum Typed Array index of max Smi. if (length > kMaxLength) { isolate->ThrowException(ERR_BUFFER_TOO_LARGE(isolate)); return Local(); } Local ab; { std::unique_ptr bs = ArrayBuffer::NewBackingStore( isolate, length, BackingStoreInitializationMode::kUninitialized, BackingStoreOnFailureMode::kReturnNull); if (!bs) [[unlikely]] { THROW_ERR_MEMORY_ALLOCATION_FAILED(isolate); return {}; } CHECK(bs); ab = ArrayBuffer::New(isolate, std::move(bs)); } MaybeLocal obj = New(env, ab, 0, ab->ByteLength()) .FromMaybe(Local()); return scope.EscapeMaybe(obj); } MaybeLocal Copy(Isolate* isolate, const char* data, size_t length) { EscapableHandleScope handle_scope(isolate); Environment* env = Environment::GetCurrent(isolate); if (env == nullptr) { THROW_ERR_BUFFER_CONTEXT_NOT_AVAILABLE(isolate); return MaybeLocal(); } Local obj; if (Buffer::Copy(env, data, length).ToLocal(&obj)) return handle_scope.Escape(obj); return Local(); } MaybeLocal Copy(Environment* env, const char* data, size_t length) { Isolate* isolate(env->isolate()); EscapableHandleScope scope(isolate); // V8 currently only allows a maximum Typed Array index of max Smi. if (length > kMaxLength) { isolate->ThrowException(ERR_BUFFER_TOO_LARGE(isolate)); return Local(); } std::unique_ptr bs = ArrayBuffer::NewBackingStore( isolate, length, BackingStoreInitializationMode::kUninitialized, BackingStoreOnFailureMode::kReturnNull); if (!bs) [[unlikely]] { THROW_ERR_MEMORY_ALLOCATION_FAILED(isolate); return {}; } if (length > 0) memcpy(bs->Data(), data, length); Local ab = ArrayBuffer::New(isolate, std::move(bs)); MaybeLocal obj = New(env, ab, 0, ab->ByteLength()) .FromMaybe(Local()); return scope.EscapeMaybe(obj); } MaybeLocal New(Isolate* isolate, char* data, size_t length, FreeCallback callback, void* hint) { EscapableHandleScope handle_scope(isolate); Environment* env = Environment::GetCurrent(isolate); if (env == nullptr) { callback(data, hint); THROW_ERR_BUFFER_CONTEXT_NOT_AVAILABLE(isolate); return MaybeLocal(); } return handle_scope.EscapeMaybe( Buffer::New(env, data, length, callback, hint)); } MaybeLocal New(Environment* env, char* data, size_t length, FreeCallback callback, void* hint) { EscapableHandleScope scope(env->isolate()); if (length > kMaxLength) { env->isolate()->ThrowException(ERR_BUFFER_TOO_LARGE(env->isolate())); callback(data, hint); return Local(); } Local ab = CallbackInfo::CreateTrackedArrayBuffer(env, data, length, callback, hint); if (ab->SetPrivate(env->context(), env->untransferable_object_private_symbol(), True(env->isolate())).IsNothing()) { return Local(); } MaybeLocal maybe_ui = Buffer::New(env, ab, 0, length); Local ui; if (!maybe_ui.ToLocal(&ui)) return MaybeLocal(); return scope.Escape(ui); } // Warning: This function needs `data` to be allocated with malloc() and not // necessarily isolate's ArrayBuffer::Allocator. MaybeLocal New(Isolate* isolate, char* data, size_t length) { EscapableHandleScope handle_scope(isolate); Environment* env = Environment::GetCurrent(isolate); if (env == nullptr) { free(data); THROW_ERR_BUFFER_CONTEXT_NOT_AVAILABLE(isolate); return MaybeLocal(); } Local obj; if (Buffer::New(env, data, length).ToLocal(&obj)) return handle_scope.Escape(obj); return Local(); } // The contract for this function is that `data` is allocated with malloc() // and not necessarily isolate's ArrayBuffer::Allocator. MaybeLocal New(Environment* env, char* data, size_t length) { if (length > 0) { CHECK_NOT_NULL(data); // V8 currently only allows a maximum Typed Array index of max Smi. if (length > kMaxLength) { Isolate* isolate(env->isolate()); isolate->ThrowException(ERR_BUFFER_TOO_LARGE(isolate)); free(data); return Local(); } } #if defined(V8_ENABLE_SANDBOX) // When v8 sandbox is enabled, external backing stores are not supported // since all arraybuffer allocations are expected to be done by the isolate. // Since this violates the contract of this function, let's free the data and // throw an error. free(data); THROW_ERR_OPERATION_FAILED( env->isolate(), "Wrapping external data is not supported when the v8 sandbox is enabled"); return MaybeLocal(); #else EscapableHandleScope handle_scope(env->isolate()); auto free_callback = [](void* data, size_t length, void* deleter_data) { free(data); }; std::unique_ptr bs = ArrayBuffer::NewBackingStore(data, length, free_callback, nullptr); Local ab = ArrayBuffer::New(env->isolate(), std::move(bs)); Local obj; if (Buffer::New(env, ab, 0, length).ToLocal(&obj)) return handle_scope.Escape(obj); return Local(); #endif } namespace { template void StringSlice(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); Isolate* isolate = env->isolate(); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); ArrayBufferViewContents buffer(args[0]); if (buffer.length() == 0) return args.GetReturnValue().SetEmptyString(); size_t start = 0; size_t end = 0; THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[1], 0, &start)); THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[2], buffer.length(), &end)); if (end < start) end = start; THROW_AND_RETURN_IF_OOB(Just(end <= buffer.length())); size_t length = end - start; Local ret; if (StringBytes::Encode(isolate, buffer.data() + start, length, encoding) .ToLocal(&ret)) { args.GetReturnValue().Set(ret); } } void CopyImpl(Local source_obj, Local target_obj, const uint32_t target_start, const uint32_t source_start, const uint32_t to_copy) { ArrayBufferViewContents source(source_obj); SPREAD_BUFFER_ARG(target_obj, target); memmove(target_data + target_start, source.data() + source_start, to_copy); } // Assume caller has properly validated args. void SlowCopy(const FunctionCallbackInfo& args) { Local source_obj = args[0]; Local target_obj = args[1]; const uint32_t target_start = args[2].As()->Value(); const uint32_t source_start = args[3].As()->Value(); const uint32_t to_copy = args[4].As()->Value(); CopyImpl(source_obj, target_obj, target_start, source_start, to_copy); args.GetReturnValue().Set(to_copy); } // Assume caller has properly validated args. uint32_t FastCopy(Local receiver, Local source_obj, Local target_obj, uint32_t target_start, uint32_t source_start, uint32_t to_copy, // NOLINTNEXTLINE(runtime/references) FastApiCallbackOptions& options) { HandleScope scope(options.isolate); CopyImpl(source_obj, target_obj, target_start, source_start, to_copy); return to_copy; } static CFunction fast_copy(CFunction::Make(FastCopy)); void Fill(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); Local ctx = env->context(); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); SPREAD_BUFFER_ARG(args[0], ts_obj); size_t start = 0; THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[2], 0, &start)); size_t end; THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[3], 0, &end)); size_t fill_length = end - start; Local str_obj; size_t str_length; enum encoding enc; // OOB Check. Throw the error in JS. if (start > end || fill_length + start > ts_obj_length) return args.GetReturnValue().Set(-2); // First check if Buffer has been passed. if (Buffer::HasInstance(args[1])) { SPREAD_BUFFER_ARG(args[1], fill_obj); str_length = fill_obj_length; memcpy( ts_obj_data + start, fill_obj_data, std::min(str_length, fill_length)); goto start_fill; } // Then coerce everything that's not a string. if (!args[1]->IsString()) { uint32_t val; if (!args[1]->Uint32Value(ctx).To(&val)) return; int value = val & 255; memset(ts_obj_data + start, value, fill_length); return; } if (!args[1]->ToString(env->context()).ToLocal(&str_obj)) { return; } enc = ParseEncoding(env->isolate(), args[4], UTF8); // Can't use StringBytes::Write() in all cases. For example if attempting // to write a two byte character into a one byte Buffer. if (enc == UTF8) { str_length = str_obj->Utf8LengthV2(env->isolate()); node::Utf8Value str(env->isolate(), args[1]); memcpy(ts_obj_data + start, *str, std::min(str_length, fill_length)); } else if (enc == UCS2) { str_length = str_obj->Length() * sizeof(uint16_t); node::TwoByteValue str(env->isolate(), args[1]); if constexpr (IsBigEndian()) CHECK(nbytes::SwapBytes16(reinterpret_cast(&str[0]), str_length)); memcpy(ts_obj_data + start, *str, std::min(str_length, fill_length)); } else { // Write initial String to Buffer, then use that memory to copy remainder // of string. Correct the string length for cases like HEX where less than // the total string length is written. str_length = StringBytes::Write( env->isolate(), ts_obj_data + start, fill_length, str_obj, enc); } start_fill: if (str_length >= fill_length) return; // If str_length is zero, then either an empty buffer was provided, or Write() // indicated that no bytes could be written. If no bytes could be written, // then return -1 because the fill value is invalid. This will trigger a throw // in JavaScript. Silently failing should be avoided because it can lead to // buffers with unexpected contents. if (str_length == 0) return args.GetReturnValue().Set(-1); size_t in_there = str_length; char* ptr = ts_obj_data + start + str_length; while (in_there < fill_length - in_there) { memcpy(ptr, ts_obj_data + start, in_there); ptr += in_there; in_there *= 2; } if (in_there < fill_length) { memcpy(ptr, ts_obj_data + start, fill_length - in_there); } } template void StringWrite(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); SPREAD_BUFFER_ARG(args[0], ts_obj); THROW_AND_RETURN_IF_NOT_STRING(env, args[1], "argument"); Local str; if (!args[1]->ToString(env->context()).ToLocal(&str)) { return; } size_t offset = 0; size_t max_length = 0; THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[2], 0, &offset)); if (offset > ts_obj_length) { return node::THROW_ERR_BUFFER_OUT_OF_BOUNDS( env, "\"offset\" is outside of buffer bounds"); } THROW_AND_RETURN_IF_OOB( ParseArrayIndex(env, args[3], ts_obj_length - offset, &max_length)); max_length = std::min(ts_obj_length - offset, max_length); if (max_length == 0) return args.GetReturnValue().Set(0); uint32_t written = StringBytes::Write( env->isolate(), ts_obj_data + offset, max_length, str, encoding); args.GetReturnValue().Set(written); } void SlowByteLengthUtf8(const FunctionCallbackInfo& args) { CHECK(args[0]->IsString()); // Fast case: avoid StringBytes on UTF8 string. Jump to v8. size_t result = args[0].As()->Utf8LengthV2(args.GetIsolate()); args.GetReturnValue().Set(static_cast(result)); } uint32_t FastByteLengthUtf8( Local receiver, Local sourceValue, FastApiCallbackOptions& options) { // NOLINT(runtime/references) TRACK_V8_FAST_API_CALL("Buffer::FastByteLengthUtf8"); auto isolate = options.isolate; HandleScope handleScope(isolate); CHECK(sourceValue->IsString()); Local sourceStr = sourceValue.As(); if (!sourceStr->IsExternalOneByte()) { return sourceStr->Utf8LengthV2(isolate); } auto source = sourceStr->GetExternalOneByteStringResource(); // For short inputs, the function call overhead to simdutf is maybe // not worth it, reserve simdutf for long strings. if (source->length() > 128) { return simdutf::utf8_length_from_latin1(source->data(), source->length()); } uint32_t length = source->length(); const auto input = reinterpret_cast(source->data()); uint32_t answer = length; uint32_t i = 0; auto pop = [](uint64_t v) { return static_cast(((v >> 7) & UINT64_C(0x0101010101010101)) * UINT64_C(0x0101010101010101) >> 56); }; for (; i + 32 <= length; i += 32) { uint64_t v; memcpy(&v, input + i, 8); answer += pop(v); memcpy(&v, input + i + 8, 8); answer += pop(v); memcpy(&v, input + i + 16, 8); answer += pop(v); memcpy(&v, input + i + 24, 8); answer += pop(v); } for (; i + 8 <= length; i += 8) { uint64_t v; memcpy(&v, input + i, 8); answer += pop(v); } for (; i + 1 <= length; i += 1) { answer += input[i] >> 7; } return answer; } static CFunction fast_byte_length_utf8(CFunction::Make(FastByteLengthUtf8)); // Normalize val to be an integer in the range of [1, -1] since // implementations of memcmp() can vary by platform. static int normalizeCompareVal(int val, size_t a_length, size_t b_length) { if (val == 0) { if (a_length > b_length) return 1; else if (a_length < b_length) return -1; } else { if (val > 0) return 1; else return -1; } return val; } void CompareOffset(const FunctionCallbackInfo &args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); THROW_AND_RETURN_UNLESS_BUFFER(env, args[1]); ArrayBufferViewContents source(args[0]); ArrayBufferViewContents target(args[1]); size_t target_start = 0; size_t source_start = 0; size_t source_end = 0; size_t target_end = 0; THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[2], 0, &target_start)); THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[3], 0, &source_start)); THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[4], target.length(), &target_end)); THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[5], source.length(), &source_end)); if (source_start > source.length()) return THROW_ERR_OUT_OF_RANGE( env, "The value of \"sourceStart\" is out of range."); if (target_start > target.length()) return THROW_ERR_OUT_OF_RANGE( env, "The value of \"targetStart\" is out of range."); CHECK_LE(source_start, source_end); CHECK_LE(target_start, target_end); size_t to_cmp = std::min(std::min(source_end - source_start, target_end - target_start), source.length() - source_start); int val = normalizeCompareVal(to_cmp > 0 ? memcmp(source.data() + source_start, target.data() + target_start, to_cmp) : 0, source_end - source_start, target_end - target_start); args.GetReturnValue().Set(val); } int32_t CompareImpl(Local a_obj, Local b_obj) { ArrayBufferViewContents a(a_obj); ArrayBufferViewContents b(b_obj); size_t cmp_length = std::min(a.length(), b.length()); return normalizeCompareVal( cmp_length > 0 ? memcmp(a.data(), b.data(), cmp_length) : 0, a.length(), b.length()); } void Compare(const FunctionCallbackInfo &args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); THROW_AND_RETURN_UNLESS_BUFFER(env, args[1]); int val = CompareImpl(args[0], args[1]); args.GetReturnValue().Set(val); } int32_t FastCompare(Local, Local a_obj, Local b_obj, // NOLINTNEXTLINE(runtime/references) FastApiCallbackOptions& options) { HandleScope scope(options.isolate); return CompareImpl(a_obj, b_obj); } static CFunction fast_compare(CFunction::Make(FastCompare)); // Computes the offset for starting an indexOf or lastIndexOf search. // Returns either a valid offset in [0...], ie inside the Buffer, // or -1 to signal that there is no possible match. int64_t IndexOfOffset(size_t length, int64_t offset_i64, int64_t needle_length, bool is_forward) { int64_t length_i64 = static_cast(length); if (offset_i64 < 0) { if (offset_i64 + length_i64 >= 0) { // Negative offsets count backwards from the end of the buffer. return length_i64 + offset_i64; } else if (is_forward || needle_length == 0) { // indexOf from before the start of the buffer: search the whole buffer. return 0; } else { // lastIndexOf from before the start of the buffer: no match. return -1; } } else { if (offset_i64 + needle_length <= length_i64) { // Valid positive offset. return offset_i64; } else if (needle_length == 0) { // Out of buffer bounds, but empty needle: point to end of buffer. return length_i64; } else if (is_forward) { // indexOf from past the end of the buffer: no match. return -1; } else { // lastIndexOf from past the end of the buffer: search the whole buffer. return length_i64 - 1; } } } void IndexOfString(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); Isolate* isolate = env->isolate(); CHECK(args[1]->IsString()); CHECK(args[2]->IsNumber()); CHECK(args[3]->IsInt32()); CHECK(args[4]->IsBoolean()); enum encoding enc = static_cast(args[3].As()->Value()); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); ArrayBufferViewContents buffer(args[0]); Local needle = args[1].As(); int64_t offset_i64 = args[2].As()->Value(); bool is_forward = args[4]->IsTrue(); const char* haystack = buffer.data(); // Round down to the nearest multiple of 2 in case of UCS2. const size_t haystack_length = (enc == UCS2) ? buffer.length() &~ 1 : buffer.length(); // NOLINT(whitespace/operators) size_t needle_length; if (!StringBytes::Size(isolate, needle, enc).To(&needle_length)) return; int64_t opt_offset = IndexOfOffset(haystack_length, offset_i64, needle_length, is_forward); if (needle_length == 0) { // Match String#indexOf() and String#lastIndexOf() behavior. args.GetReturnValue().Set(static_cast(opt_offset)); return; } if (haystack_length == 0) { return args.GetReturnValue().Set(-1); } if (opt_offset <= -1) { return args.GetReturnValue().Set(-1); } size_t offset = static_cast(opt_offset); CHECK_LT(offset, haystack_length); if ((is_forward && needle_length + offset > haystack_length) || needle_length > haystack_length) { return args.GetReturnValue().Set(-1); } size_t result = haystack_length; if (enc == UCS2) { TwoByteValue needle_value(isolate, needle); if (haystack_length < 2 || needle_value.length() < 1) { return args.GetReturnValue().Set(-1); } if constexpr (IsBigEndian()) { StringBytes::InlineDecoder decoder; if (decoder.Decode(env, needle, enc).IsNothing()) return; const uint16_t* decoded_string = reinterpret_cast(decoder.out()); if (decoded_string == nullptr) return args.GetReturnValue().Set(-1); result = nbytes::SearchString(reinterpret_cast(haystack), haystack_length / 2, decoded_string, decoder.size() / 2, offset / 2, is_forward); } else { result = nbytes::SearchString(reinterpret_cast(haystack), haystack_length / 2, needle_value.out(), needle_value.length(), offset / 2, is_forward); } result *= 2; } else if (enc == UTF8) { Utf8Value needle_value(isolate, needle); if (*needle_value == nullptr) return args.GetReturnValue().Set(-1); CHECK_GE(needle_length, needle_value.length()); result = nbytes::SearchString( reinterpret_cast(haystack), haystack_length, reinterpret_cast(needle_value.out()), needle_length, offset, is_forward); } else if (enc == LATIN1) { uint8_t* needle_data = node::UncheckedMalloc(needle_length); if (needle_data == nullptr) { return args.GetReturnValue().Set(-1); } StringBytes::Write(isolate, reinterpret_cast(needle_data), needle_length, needle, enc); result = nbytes::SearchString(reinterpret_cast(haystack), haystack_length, needle_data, needle_length, offset, is_forward); free(needle_data); } args.GetReturnValue().Set( result == haystack_length ? -1 : static_cast(result)); } void IndexOfBuffer(const FunctionCallbackInfo& args) { CHECK(args[1]->IsObject()); CHECK(args[2]->IsNumber()); CHECK(args[3]->IsInt32()); CHECK(args[4]->IsBoolean()); enum encoding enc = static_cast(args[3].As()->Value()); Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); THROW_AND_RETURN_UNLESS_BUFFER(env, args[1]); ArrayBufferViewContents haystack_contents(args[0]); ArrayBufferViewContents needle_contents(args[1]); int64_t offset_i64 = args[2].As()->Value(); bool is_forward = args[4]->IsTrue(); const char* haystack = haystack_contents.data(); const size_t haystack_length = haystack_contents.length(); const char* needle = needle_contents.data(); const size_t needle_length = needle_contents.length(); int64_t opt_offset = IndexOfOffset(haystack_length, offset_i64, needle_length, is_forward); if (needle_length == 0) { // Match String#indexOf() and String#lastIndexOf() behavior. args.GetReturnValue().Set(static_cast(opt_offset)); return; } if (haystack_length == 0) { return args.GetReturnValue().Set(-1); } if (opt_offset <= -1) { return args.GetReturnValue().Set(-1); } size_t offset = static_cast(opt_offset); CHECK_LT(offset, haystack_length); if ((is_forward && needle_length + offset > haystack_length) || needle_length > haystack_length) { return args.GetReturnValue().Set(-1); } size_t result = haystack_length; if (enc == UCS2) { if (haystack_length < 2 || needle_length < 2) { return args.GetReturnValue().Set(-1); } result = nbytes::SearchString(reinterpret_cast(haystack), haystack_length / 2, reinterpret_cast(needle), needle_length / 2, offset / 2, is_forward); result *= 2; } else { result = nbytes::SearchString(reinterpret_cast(haystack), haystack_length, reinterpret_cast(needle), needle_length, offset, is_forward); } args.GetReturnValue().Set( result == haystack_length ? -1 : static_cast(result)); } int32_t IndexOfNumberImpl(Local buffer_obj, const uint32_t needle, const int64_t offset_i64, const bool is_forward) { ArrayBufferViewContents buffer(buffer_obj); const uint8_t* buffer_data = buffer.data(); const size_t buffer_length = buffer.length(); int64_t opt_offset = IndexOfOffset(buffer_length, offset_i64, 1, is_forward); if (opt_offset <= -1 || buffer_length == 0) { return -1; } size_t offset = static_cast(opt_offset); CHECK_LT(offset, buffer_length); const void* ptr; if (is_forward) { ptr = memchr(buffer_data + offset, needle, buffer_length - offset); } else { ptr = nbytes::stringsearch::MemrchrFill(buffer_data, needle, offset + 1); } const uint8_t* ptr_uint8 = static_cast(ptr); return ptr != nullptr ? static_cast(ptr_uint8 - buffer_data) : -1; } void SlowIndexOfNumber(const FunctionCallbackInfo& args) { CHECK(args[1]->IsUint32()); CHECK(args[2]->IsNumber()); CHECK(args[3]->IsBoolean()); THROW_AND_RETURN_UNLESS_BUFFER(Environment::GetCurrent(args), args[0]); Local buffer_obj = args[0]; uint32_t needle = args[1].As()->Value(); int64_t offset_i64 = args[2].As()->Value(); bool is_forward = args[3]->IsTrue(); args.GetReturnValue().Set( IndexOfNumberImpl(buffer_obj, needle, offset_i64, is_forward)); } int32_t FastIndexOfNumber(Local, Local buffer_obj, uint32_t needle, int64_t offset_i64, bool is_forward, // NOLINTNEXTLINE(runtime/references) FastApiCallbackOptions& options) { HandleScope scope(options.isolate); return IndexOfNumberImpl(buffer_obj, needle, offset_i64, is_forward); } static CFunction fast_index_of_number(CFunction::Make(FastIndexOfNumber)); void Swap16(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); SPREAD_BUFFER_ARG(args[0], ts_obj); CHECK(nbytes::SwapBytes16(ts_obj_data, ts_obj_length)); args.GetReturnValue().Set(args[0]); } void Swap32(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); SPREAD_BUFFER_ARG(args[0], ts_obj); CHECK(nbytes::SwapBytes32(ts_obj_data, ts_obj_length)); args.GetReturnValue().Set(args[0]); } void Swap64(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); SPREAD_BUFFER_ARG(args[0], ts_obj); CHECK(nbytes::SwapBytes64(ts_obj_data, ts_obj_length)); args.GetReturnValue().Set(args[0]); } static void IsUtf8(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); CHECK_EQ(args.Length(), 1); CHECK(args[0]->IsTypedArray() || args[0]->IsArrayBuffer() || args[0]->IsSharedArrayBuffer()); ArrayBufferViewContents abv(args[0]); if (abv.WasDetached()) { return node::THROW_ERR_INVALID_STATE( env, "Cannot validate on a detached buffer"); } args.GetReturnValue().Set(simdutf::validate_utf8(abv.data(), abv.length())); } static void IsAscii(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); CHECK_EQ(args.Length(), 1); CHECK(args[0]->IsTypedArray() || args[0]->IsArrayBuffer() || args[0]->IsSharedArrayBuffer()); ArrayBufferViewContents abv(args[0]); if (abv.WasDetached()) { return node::THROW_ERR_INVALID_STATE( env, "Cannot validate on a detached buffer"); } args.GetReturnValue().Set( !simdutf::validate_ascii_with_errors(abv.data(), abv.length()).error); } void SetBufferPrototype(const FunctionCallbackInfo& args) { Realm* realm = Realm::GetCurrent(args); // TODO(legendecas): Remove this check once the binding supports sub-realms. CHECK_EQ(realm->kind(), Realm::Kind::kPrincipal); CHECK(args[0]->IsObject()); Local proto = args[0].As(); realm->set_buffer_prototype_object(proto); } static void Btoa(const FunctionCallbackInfo& args) { CHECK_EQ(args.Length(), 1); Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_IF_NOT_STRING(env, args[0], "argument"); Local input = args[0].As(); MaybeStackBuffer buffer; size_t written; if (input->IsExternalOneByte()) { // 8-bit case auto ext = input->GetExternalOneByteStringResource(); size_t expected_length = simdutf::base64_length_from_binary(ext->length()); buffer.AllocateSufficientStorage(expected_length + 1); buffer.SetLengthAndZeroTerminate(expected_length); written = simdutf::binary_to_base64(ext->data(), ext->length(), buffer.out()); } else if (input->IsOneByte()) { MaybeStackBuffer stack_buf(input->Length()); input->WriteOneByteV2(env->isolate(), 0, input->Length(), stack_buf.out()); size_t expected_length = simdutf::base64_length_from_binary(input->Length()); buffer.AllocateSufficientStorage(expected_length + 1); buffer.SetLengthAndZeroTerminate(expected_length); written = simdutf::binary_to_base64(reinterpret_cast(*stack_buf), input->Length(), buffer.out()); } else { TwoByteValue value(env->isolate(), input); MaybeStackBuffer stack_buf(value.length()); size_t out_len = simdutf::convert_utf16_to_latin1( reinterpret_cast(value.out()), value.length(), stack_buf.out()); if (out_len == 0) { // error return args.GetReturnValue().Set(-1); } size_t expected_length = simdutf::base64_length_from_binary(out_len); buffer.AllocateSufficientStorage(expected_length + 1); buffer.SetLengthAndZeroTerminate(expected_length); written = simdutf::binary_to_base64(*stack_buf, out_len, buffer.out()); } auto value = OneByteString( env->isolate(), reinterpret_cast(buffer.out()), written); return args.GetReturnValue().Set(value); } // In case of success, the decoded string is returned. // In case of error, a negative value is returned: // * -1 indicates a single character remained, // * -2 indicates an invalid character, // * -3 indicates a possible overflow (i.e., more than 2 GB output). static void Atob(const FunctionCallbackInfo& args) { CHECK_EQ(args.Length(), 1); Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_IF_NOT_STRING(env, args[0], "argument"); Local input = args[0].As(); MaybeStackBuffer buffer; simdutf::result result; if (input->IsExternalOneByte()) { // 8-bit case auto ext = input->GetExternalOneByteStringResource(); size_t expected_length = simdutf::maximal_binary_length_from_base64(ext->data(), ext->length()); buffer.AllocateSufficientStorage(expected_length); buffer.SetLength(expected_length); result = simdutf::base64_to_binary( ext->data(), ext->length(), buffer.out(), simdutf::base64_default); } else if (input->IsOneByte()) { MaybeStackBuffer stack_buf(input->Length()); input->WriteOneByteV2( args.GetIsolate(), 0, input->Length(), stack_buf.out()); const char* data = reinterpret_cast(*stack_buf); size_t expected_length = simdutf::maximal_binary_length_from_base64(data, input->Length()); buffer.AllocateSufficientStorage(expected_length); buffer.SetLength(expected_length); result = simdutf::base64_to_binary(data, input->Length(), buffer.out()); } else { // 16-bit case TwoByteValue value(env->isolate(), input); auto data = reinterpret_cast(value.out()); size_t expected_length = simdutf::maximal_binary_length_from_base64(data, value.length()); buffer.AllocateSufficientStorage(expected_length); buffer.SetLength(expected_length); result = simdutf::base64_to_binary(data, value.length(), buffer.out()); } if (result.error == simdutf::error_code::SUCCESS) { auto value = OneByteString(env->isolate(), reinterpret_cast(buffer.out()), result.count); return args.GetReturnValue().Set(value); } // Default value is: "possible overflow" int32_t error_code = -3; if (result.error == simdutf::error_code::INVALID_BASE64_CHARACTER) { error_code = -2; } else if (result.error == simdutf::error_code::BASE64_INPUT_REMAINDER) { error_code = -1; } args.GetReturnValue().Set(error_code); } static void SetDetachKey(const FunctionCallbackInfo& args) { CHECK_EQ(args.Length(), 2); CHECK(args[0]->IsArrayBuffer()); Local ab = args[0].As(); Local key = args[1]; ab->SetDetachKey(key); } namespace { std::pair DecomposeBufferToParts(Local buffer) { void* pointer; size_t byte_length; if (buffer->IsArrayBuffer()) { Local ab = buffer.As(); pointer = ab->Data(); byte_length = ab->ByteLength(); } else if (buffer->IsSharedArrayBuffer()) { Local ab = buffer.As(); pointer = ab->Data(); byte_length = ab->ByteLength(); } else { UNREACHABLE(); // Caller must validate. } return {pointer, byte_length}; } } // namespace void CopyArrayBuffer(const FunctionCallbackInfo& args) { // args[0] == Destination ArrayBuffer // args[1] == Destination ArrayBuffer Offset // args[2] == Source ArrayBuffer // args[3] == Source ArrayBuffer Offset // args[4] == bytesToCopy CHECK(args[0]->IsArrayBuffer() || args[0]->IsSharedArrayBuffer()); CHECK(args[1]->IsUint32()); CHECK(args[2]->IsArrayBuffer() || args[2]->IsSharedArrayBuffer()); CHECK(args[3]->IsUint32()); CHECK(args[4]->IsUint32()); void* destination; size_t destination_byte_length; std::tie(destination, destination_byte_length) = DecomposeBufferToParts(args[0]); void* source; size_t source_byte_length; std::tie(source, source_byte_length) = DecomposeBufferToParts(args[2]); uint32_t destination_offset = args[1].As()->Value(); uint32_t source_offset = args[3].As()->Value(); size_t bytes_to_copy = args[4].As()->Value(); CHECK_GE(destination_byte_length - destination_offset, bytes_to_copy); CHECK_GE(source_byte_length - source_offset, bytes_to_copy); uint8_t* dest = static_cast(destination) + destination_offset; uint8_t* src = static_cast(source) + source_offset; memcpy(dest, src, bytes_to_copy); } // Converts a number parameter to size_t suitable for ArrayBuffer sizes // Could be larger than uint32_t // See v8::internal::TryNumberToSize and v8::internal::NumberToSize inline size_t CheckNumberToSize(Local number) { CHECK(number->IsNumber()); double value = number.As()->Value(); // See v8::internal::TryNumberToSize on this (and on < comparison) double maxSize = static_cast(std::numeric_limits::max()); CHECK(value >= 0 && value < maxSize); size_t size = static_cast(value); #ifdef V8_ENABLE_SANDBOX CHECK_LE(size, kMaxSafeBufferSizeForSandbox); #endif return size; } void CreateUnsafeArrayBuffer(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); if (args.Length() != 1) { env->ThrowRangeError("Invalid array buffer length"); return; } size_t size = CheckNumberToSize(args[0]); Isolate* isolate = env->isolate(); Local buf; // 0-length, or zero-fill flag is set, or building snapshot if (size == 0 || per_process::cli_options->zero_fill_all_buffers || env->isolate_data()->is_building_snapshot()) { buf = ArrayBuffer::New(isolate, size); } else { std::unique_ptr store = ArrayBuffer::NewBackingStore( isolate, size, BackingStoreInitializationMode::kUninitialized, v8::BackingStoreOnFailureMode::kReturnNull); if (!store) [[unlikely]] { THROW_ERR_MEMORY_ALLOCATION_FAILED(env); return; } buf = ArrayBuffer::New(isolate, std::move(store)); } args.GetReturnValue().Set(buf); } template uint32_t WriteOneByteString(const char* src, uint32_t src_len, char* dst, uint32_t dst_len) { if (dst_len == 0) { return 0; } if constexpr (encoding == UTF8) { return simdutf::convert_latin1_to_utf8_safe(src, src_len, dst, dst_len); } else if constexpr (encoding == LATIN1 || encoding == ASCII) { const auto size = std::min(src_len, dst_len); memcpy(dst, src, size); return size; } else { // TODO(ronag): Add support for more encoding. UNREACHABLE(); } } template void SlowWriteString(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); THROW_AND_RETURN_UNLESS_BUFFER(env, args[0]); SPREAD_BUFFER_ARG(args[0], ts_obj); THROW_AND_RETURN_IF_NOT_STRING(env, args[1], "argument"); Local str; if (!args[1]->ToString(env->context()).ToLocal(&str)) { return; } size_t offset = 0; size_t max_length = 0; THROW_AND_RETURN_IF_OOB(ParseArrayIndex(env, args[2], 0, &offset)); THROW_AND_RETURN_IF_OOB( ParseArrayIndex(env, args[3], ts_obj_length - offset, &max_length)); max_length = std::min(ts_obj_length - offset, max_length); if (max_length == 0) return args.GetReturnValue().Set(0); uint32_t written = 0; if ((encoding == UTF8 || encoding == LATIN1 || encoding == ASCII) && str->IsExternalOneByte()) { const auto src = str->GetExternalOneByteStringResource(); written = WriteOneByteString( src->data(), src->length(), ts_obj_data + offset, max_length); } else { written = StringBytes::Write( env->isolate(), ts_obj_data + offset, max_length, str, encoding); } args.GetReturnValue().Set(written); } template uint32_t FastWriteString(Local receiver, Local dst_obj, const FastOneByteString& src, uint32_t offset, uint32_t max_length, // NOLINTNEXTLINE(runtime/references) FastApiCallbackOptions& options) { // Just a heads up... this is a v8 fast api function. The use of // FastOneByteString has some caveats. Specifically, a GC occurring // between the time the FastOneByteString is created and the time // we use it below can cause the FastOneByteString to become invalid // and produce garbage data. This is not a problem here because we // are not performing any allocations or other operations that would // trigger a GC before the FastOneByteString is used. Take care when // modifying this code to ensure that no operations would trigger a GC. HandleScope handle_scope(options.isolate); SPREAD_BUFFER_ARG(dst_obj, dst); CHECK(offset <= dst_length); CHECK(dst_length - offset <= std::numeric_limits::max()); TRACK_V8_FAST_API_CALL("buffer.writeString"); return WriteOneByteString( src.data, src.length, reinterpret_cast(dst_data + offset), std::min(dst_length - offset, max_length)); } static const CFunction fast_write_string_ascii( CFunction::Make(FastWriteString)); static const CFunction fast_write_string_latin1( CFunction::Make(FastWriteString)); static const CFunction fast_write_string_utf8( CFunction::Make(FastWriteString)); void Initialize(Local target, Local unused, Local context, void* priv) { Environment* env = Environment::GetCurrent(context); Isolate* isolate = env->isolate(); SetMethodNoSideEffect(context, target, "atob", Atob); SetMethodNoSideEffect(context, target, "btoa", Btoa); SetMethod(context, target, "setBufferPrototype", SetBufferPrototype); SetFastMethodNoSideEffect(context, target, "byteLengthUtf8", SlowByteLengthUtf8, &fast_byte_length_utf8); SetFastMethod(context, target, "copy", SlowCopy, &fast_copy); SetFastMethodNoSideEffect(context, target, "compare", Compare, &fast_compare); SetMethodNoSideEffect(context, target, "compareOffset", CompareOffset); SetMethod(context, target, "fill", Fill); SetMethodNoSideEffect(context, target, "indexOfBuffer", IndexOfBuffer); SetFastMethodNoSideEffect(context, target, "indexOfNumber", SlowIndexOfNumber, &fast_index_of_number); SetMethodNoSideEffect(context, target, "indexOfString", IndexOfString); SetMethod(context, target, "copyArrayBuffer", CopyArrayBuffer); SetMethodNoSideEffect( context, target, "createUnsafeArrayBuffer", CreateUnsafeArrayBuffer); SetMethod(context, target, "swap16", Swap16); SetMethod(context, target, "swap32", Swap32); SetMethod(context, target, "swap64", Swap64); SetMethodNoSideEffect(context, target, "isUtf8", IsUtf8); SetMethodNoSideEffect(context, target, "isAscii", IsAscii); target ->Set(context, FIXED_ONE_BYTE_STRING(isolate, "kMaxLength"), Number::New(isolate, kMaxLength)) .Check(); target ->Set(context, FIXED_ONE_BYTE_STRING(isolate, "kStringMaxLength"), Integer::New(isolate, String::kMaxLength)) .Check(); SetMethodNoSideEffect(context, target, "asciiSlice", StringSlice); SetMethodNoSideEffect(context, target, "base64Slice", StringSlice); SetMethodNoSideEffect( context, target, "base64urlSlice", StringSlice); SetMethodNoSideEffect(context, target, "latin1Slice", StringSlice); SetMethodNoSideEffect(context, target, "hexSlice", StringSlice); SetMethodNoSideEffect(context, target, "ucs2Slice", StringSlice); SetMethodNoSideEffect(context, target, "utf8Slice", StringSlice); SetMethod(context, target, "base64Write", StringWrite); SetMethod(context, target, "base64urlWrite", StringWrite); SetMethod(context, target, "hexWrite", StringWrite); SetMethod(context, target, "ucs2Write", StringWrite); SetFastMethod(context, target, "asciiWriteStatic", SlowWriteString, &fast_write_string_ascii); SetFastMethod(context, target, "latin1WriteStatic", SlowWriteString, &fast_write_string_latin1); SetFastMethod(context, target, "utf8WriteStatic", SlowWriteString, &fast_write_string_utf8); SetMethod(context, target, "setDetachKey", SetDetachKey); } } // anonymous namespace void RegisterExternalReferences(ExternalReferenceRegistry* registry) { registry->Register(SetBufferPrototype); registry->Register(SlowByteLengthUtf8); registry->Register(fast_byte_length_utf8); registry->Register(SlowCopy); registry->Register(fast_copy); registry->Register(Compare); registry->Register(fast_compare); registry->Register(CompareOffset); registry->Register(Fill); registry->Register(IndexOfBuffer); registry->Register(SlowIndexOfNumber); registry->Register(fast_index_of_number); registry->Register(IndexOfString); registry->Register(Swap16); registry->Register(Swap32); registry->Register(Swap64); registry->Register(IsUtf8); registry->Register(IsAscii); registry->Register(StringSlice); registry->Register(StringSlice); registry->Register(StringSlice); registry->Register(StringSlice); registry->Register(StringSlice); registry->Register(StringSlice); registry->Register(StringSlice); registry->Register(SlowWriteString); registry->Register(SlowWriteString); registry->Register(SlowWriteString); registry->Register(fast_write_string_ascii); registry->Register(fast_write_string_latin1); registry->Register(fast_write_string_utf8); registry->Register(StringWrite); registry->Register(StringWrite); registry->Register(StringWrite); registry->Register(StringWrite); registry->Register(StringWrite); registry->Register(StringWrite); registry->Register(StringWrite); registry->Register(CopyArrayBuffer); registry->Register(CreateUnsafeArrayBuffer); registry->Register(Atob); registry->Register(Btoa); registry->Register(SetDetachKey); } } // namespace Buffer } // namespace node NODE_BINDING_CONTEXT_AWARE_INTERNAL(buffer, node::Buffer::Initialize) NODE_BINDING_EXTERNAL_REFERENCE(buffer, node::Buffer::RegisterExternalReferences)