1 // Copyright 2018 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_OBJECTS_JS_ARRAY_BUFFER_INL_H_
6 #define V8_OBJECTS_JS_ARRAY_BUFFER_INL_H_
7
8 #include "src/objects/js-array-buffer.h"
9
10 #include "src/objects-inl.h" // Needed for write barriers
11 #include "src/wasm/wasm-engine.h"
12
13 // Has to be the last include (doesn't have include guards):
14 #include "src/objects/object-macros.h"
15
16 namespace v8 {
17 namespace internal {
18
19 CAST_ACCESSOR(JSArrayBuffer)
CAST_ACCESSOR(JSArrayBufferView)20 CAST_ACCESSOR(JSArrayBufferView)
21 CAST_ACCESSOR(JSTypedArray)
22
23 void* JSArrayBuffer::backing_store() const {
24 intptr_t ptr = READ_INTPTR_FIELD(this, kBackingStoreOffset);
25 return reinterpret_cast<void*>(ptr);
26 }
27
set_backing_store(void * value,WriteBarrierMode mode)28 void JSArrayBuffer::set_backing_store(void* value, WriteBarrierMode mode) {
29 intptr_t ptr = reinterpret_cast<intptr_t>(value);
30 WRITE_INTPTR_FIELD(this, kBackingStoreOffset, ptr);
31 }
32
ACCESSORS(JSArrayBuffer,byte_length,Object,kByteLengthOffset)33 ACCESSORS(JSArrayBuffer, byte_length, Object, kByteLengthOffset)
34
35 size_t JSArrayBuffer::allocation_length() const {
36 if (backing_store() == nullptr) {
37 return 0;
38 }
39 // If this buffer is managed by the WasmMemoryTracker
40 if (is_wasm_memory()) {
41 const auto* data =
42 GetIsolate()->wasm_engine()->memory_tracker()->FindAllocationData(
43 backing_store());
44 DCHECK_NOT_NULL(data);
45 return data->allocation_length;
46 }
47 return byte_length()->Number();
48 }
49
allocation_base()50 void* JSArrayBuffer::allocation_base() const {
51 if (backing_store() == nullptr) {
52 return nullptr;
53 }
54 // If this buffer is managed by the WasmMemoryTracker
55 if (is_wasm_memory()) {
56 const auto* data =
57 GetIsolate()->wasm_engine()->memory_tracker()->FindAllocationData(
58 backing_store());
59 DCHECK_NOT_NULL(data);
60 return data->allocation_base;
61 }
62 return backing_store();
63 }
64
is_wasm_memory()65 bool JSArrayBuffer::is_wasm_memory() const {
66 bool const is_wasm_memory = IsWasmMemory::decode(bit_field());
67 DCHECK_EQ(is_wasm_memory,
68 GetIsolate()->wasm_engine()->memory_tracker()->IsWasmMemory(
69 backing_store()));
70 return is_wasm_memory;
71 }
72
set_bit_field(uint32_t bits)73 void JSArrayBuffer::set_bit_field(uint32_t bits) {
74 if (kInt32Size != kPointerSize) {
75 #if V8_TARGET_LITTLE_ENDIAN
76 WRITE_UINT32_FIELD(this, kBitFieldSlot + kInt32Size, 0);
77 #else
78 WRITE_UINT32_FIELD(this, kBitFieldSlot, 0);
79 #endif
80 }
81 WRITE_UINT32_FIELD(this, kBitFieldOffset, bits);
82 }
83
bit_field()84 uint32_t JSArrayBuffer::bit_field() const {
85 return READ_UINT32_FIELD(this, kBitFieldOffset);
86 }
87
is_external()88 bool JSArrayBuffer::is_external() { return IsExternal::decode(bit_field()); }
89
set_is_external(bool value)90 void JSArrayBuffer::set_is_external(bool value) {
91 set_bit_field(IsExternal::update(bit_field(), value));
92 }
93
is_neuterable()94 bool JSArrayBuffer::is_neuterable() {
95 return IsNeuterable::decode(bit_field());
96 }
97
set_is_neuterable(bool value)98 void JSArrayBuffer::set_is_neuterable(bool value) {
99 set_bit_field(IsNeuterable::update(bit_field(), value));
100 }
101
was_neutered()102 bool JSArrayBuffer::was_neutered() { return WasNeutered::decode(bit_field()); }
103
set_was_neutered(bool value)104 void JSArrayBuffer::set_was_neutered(bool value) {
105 set_bit_field(WasNeutered::update(bit_field(), value));
106 }
107
is_shared()108 bool JSArrayBuffer::is_shared() { return IsShared::decode(bit_field()); }
109
set_is_shared(bool value)110 void JSArrayBuffer::set_is_shared(bool value) {
111 set_bit_field(IsShared::update(bit_field(), value));
112 }
113
is_growable()114 bool JSArrayBuffer::is_growable() { return IsGrowable::decode(bit_field()); }
115
set_is_growable(bool value)116 void JSArrayBuffer::set_is_growable(bool value) {
117 set_bit_field(IsGrowable::update(bit_field(), value));
118 }
119
byte_offset()120 Object* JSArrayBufferView::byte_offset() const {
121 if (WasNeutered()) return Smi::kZero;
122 return Object::cast(READ_FIELD(this, kByteOffsetOffset));
123 }
124
set_byte_offset(Object * value,WriteBarrierMode mode)125 void JSArrayBufferView::set_byte_offset(Object* value, WriteBarrierMode mode) {
126 WRITE_FIELD(this, kByteOffsetOffset, value);
127 CONDITIONAL_WRITE_BARRIER(this, kByteOffsetOffset, value, mode);
128 }
129
byte_length()130 Object* JSArrayBufferView::byte_length() const {
131 if (WasNeutered()) return Smi::kZero;
132 return Object::cast(READ_FIELD(this, kByteLengthOffset));
133 }
134
set_byte_length(Object * value,WriteBarrierMode mode)135 void JSArrayBufferView::set_byte_length(Object* value, WriteBarrierMode mode) {
136 WRITE_FIELD(this, kByteLengthOffset, value);
137 CONDITIONAL_WRITE_BARRIER(this, kByteLengthOffset, value, mode);
138 }
139
ACCESSORS(JSArrayBufferView,buffer,Object,kBufferOffset)140 ACCESSORS(JSArrayBufferView, buffer, Object, kBufferOffset)
141 #ifdef VERIFY_HEAP
142 ACCESSORS(JSArrayBufferView, raw_byte_offset, Object, kByteOffsetOffset)
143 ACCESSORS(JSArrayBufferView, raw_byte_length, Object, kByteLengthOffset)
144 #endif
145
146 bool JSArrayBufferView::WasNeutered() const {
147 return JSArrayBuffer::cast(buffer())->was_neutered();
148 }
149
length()150 Object* JSTypedArray::length() const {
151 if (WasNeutered()) return Smi::kZero;
152 return Object::cast(READ_FIELD(this, kLengthOffset));
153 }
154
length_value()155 size_t JSTypedArray::length_value() const {
156 if (WasNeutered()) return 0;
157 double val = Object::cast(READ_FIELD(this, kLengthOffset))->Number();
158 DCHECK_LE(val, kMaxSafeInteger); // 2^53-1
159 DCHECK_GE(val, -kMaxSafeInteger); // -2^53+1
160 DCHECK_LE(val, std::numeric_limits<size_t>::max());
161 DCHECK_GE(val, std::numeric_limits<size_t>::min());
162 return static_cast<size_t>(val);
163 }
164
set_length(Object * value,WriteBarrierMode mode)165 void JSTypedArray::set_length(Object* value, WriteBarrierMode mode) {
166 WRITE_FIELD(this, kLengthOffset, value);
167 CONDITIONAL_WRITE_BARRIER(this, kLengthOffset, value, mode);
168 }
169
is_on_heap()170 bool JSTypedArray::is_on_heap() const {
171 DisallowHeapAllocation no_gc;
172 // Checking that buffer()->backing_store() is not nullptr is not sufficient;
173 // it will be nullptr when byte_length is 0 as well.
174 FixedTypedArrayBase* fta(FixedTypedArrayBase::cast(elements()));
175 return fta->base_pointer() == fta;
176 }
177
178 // static
Validate(Isolate * isolate,Handle<Object> receiver,const char * method_name)179 MaybeHandle<JSTypedArray> JSTypedArray::Validate(Isolate* isolate,
180 Handle<Object> receiver,
181 const char* method_name) {
182 if (V8_UNLIKELY(!receiver->IsJSTypedArray())) {
183 const MessageTemplate::Template message = MessageTemplate::kNotTypedArray;
184 THROW_NEW_ERROR(isolate, NewTypeError(message), JSTypedArray);
185 }
186
187 Handle<JSTypedArray> array = Handle<JSTypedArray>::cast(receiver);
188 if (V8_UNLIKELY(array->WasNeutered())) {
189 const MessageTemplate::Template message =
190 MessageTemplate::kDetachedOperation;
191 Handle<String> operation =
192 isolate->factory()->NewStringFromAsciiChecked(method_name);
193 THROW_NEW_ERROR(isolate, NewTypeError(message, operation), JSTypedArray);
194 }
195
196 // spec describes to return `buffer`, but it may disrupt current
197 // implementations, and it's much useful to return array for now.
198 return array;
199 }
200
201 #ifdef VERIFY_HEAP
202 ACCESSORS(JSTypedArray, raw_length, Object, kLengthOffset)
203 #endif
204
205 } // namespace internal
206 } // namespace v8
207
208 #include "src/objects/object-macros-undef.h"
209
210 #endif // V8_OBJECTS_JS_ARRAY_BUFFER_INL_H_
211