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// Copyright 2012 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Defined when linking against shared lib on Windows.
#if defined(USING_V8_SHARED) && !defined(V8_SHARED)
#define V8_SHARED
#endif
#ifdef COMPRESS_STARTUP_DATA_BZ2
#include <bzlib.h>
#endif
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <sys/stat.h>
#ifdef V8_SHARED
#include <assert.h>
#include "../include/v8-testing.h"
#endif // V8_SHARED
#include "d8.h"
#ifndef V8_SHARED
#include "api.h"
#include "checks.h"
#include "d8-debug.h"
#include "debug.h"
#include "natives.h"
#include "platform.h"
#include "v8.h"
#endif // V8_SHARED
#if !defined(_WIN32) && !defined(_WIN64)
#include <unistd.h> // NOLINT
#endif
#ifndef ASSERT
#define ASSERT(condition) assert(condition)
#endif
namespace v8 {
static Handle<Value> Throw(const char* message) {
return ThrowException(String::New(message));
}
// TODO(rossberg): should replace these by proper uses of HasInstance,
// once we figure out a good way to make the templates global.
const char kArrayBufferMarkerPropName[] = "d8::_is_array_buffer_";
const char kArrayMarkerPropName[] = "d8::_is_typed_array_";
#define FOR_EACH_SYMBOL(V) \
V(ArrayBuffer, "ArrayBuffer") \
V(ArrayBufferMarkerPropName, kArrayBufferMarkerPropName) \
V(ArrayMarkerPropName, kArrayMarkerPropName) \
V(buffer, "buffer") \
V(byteLength, "byteLength") \
V(byteOffset, "byteOffset") \
V(BYTES_PER_ELEMENT, "BYTES_PER_ELEMENT") \
V(length, "length")
class Symbols {
public:
explicit Symbols(Isolate* isolate) : isolate_(isolate) {
HandleScope scope(isolate);
#define INIT_SYMBOL(name, value) \
name##_ = Persistent<String>::New(isolate, String::NewSymbol(value));
FOR_EACH_SYMBOL(INIT_SYMBOL)
#undef INIT_SYMBOL
isolate->SetData(this);
}
~Symbols() {
#define DISPOSE_SYMBOL(name, value) name##_.Dispose(isolate_);
FOR_EACH_SYMBOL(DISPOSE_SYMBOL)
#undef DISPOSE_SYMBOL
isolate_->SetData(NULL); // Not really needed, just to be sure...
}
#define DEFINE_SYMBOL_GETTER(name, value) \
static Persistent<String> name(Isolate* isolate) { \
return reinterpret_cast<Symbols*>(isolate->GetData())->name##_; \
}
FOR_EACH_SYMBOL(DEFINE_SYMBOL_GETTER)
#undef DEFINE_SYMBOL_GETTER
private:
Isolate* isolate_;
#define DEFINE_MEMBER(name, value) Persistent<String> name##_;
FOR_EACH_SYMBOL(DEFINE_MEMBER)
#undef DEFINE_MEMBER
};
LineEditor *LineEditor::current_ = NULL;
LineEditor::LineEditor(Type type, const char* name)
: type_(type), name_(name) {
if (current_ == NULL || current_->type_ < type) current_ = this;
}
class DumbLineEditor: public LineEditor {
public:
explicit DumbLineEditor(Isolate* isolate)
: LineEditor(LineEditor::DUMB, "dumb"), isolate_(isolate) { }
virtual Handle<String> Prompt(const char* prompt);
private:
Isolate* isolate_;
};
Handle<String> DumbLineEditor::Prompt(const char* prompt) {
printf("%s", prompt);
return Shell::ReadFromStdin(isolate_);
}
#ifndef V8_SHARED
CounterMap* Shell::counter_map_;
i::OS::MemoryMappedFile* Shell::counters_file_ = NULL;
CounterCollection Shell::local_counters_;
CounterCollection* Shell::counters_ = &local_counters_;
i::Mutex* Shell::context_mutex_(i::OS::CreateMutex());
Persistent<Context> Shell::utility_context_;
#endif // V8_SHARED
Persistent<Context> Shell::evaluation_context_;
ShellOptions Shell::options;
const char* Shell::kPrompt = "d8> ";
const int MB = 1024 * 1024;
#ifndef V8_SHARED
bool CounterMap::Match(void* key1, void* key2) {
const char* name1 = reinterpret_cast<const char*>(key1);
const char* name2 = reinterpret_cast<const char*>(key2);
return strcmp(name1, name2) == 0;
}
#endif // V8_SHARED
// Converts a V8 value to a C string.
const char* Shell::ToCString(const v8::String::Utf8Value& value) {
return *value ? *value : "<string conversion failed>";
}
// Executes a string within the current v8 context.
bool Shell::ExecuteString(Isolate* isolate,
Handle<String> source,
Handle<Value> name,
bool print_result,
bool report_exceptions) {
#if !defined(V8_SHARED) && defined(ENABLE_DEBUGGER_SUPPORT)
bool FLAG_debugger = i::FLAG_debugger;
#else
bool FLAG_debugger = false;
#endif // !V8_SHARED && ENABLE_DEBUGGER_SUPPORT
HandleScope handle_scope(isolate);
TryCatch try_catch;
options.script_executed = true;
if (FLAG_debugger) {
// When debugging make exceptions appear to be uncaught.
try_catch.SetVerbose(true);
}
Handle<Script> script = Script::Compile(source, name);
if (script.IsEmpty()) {
// Print errors that happened during compilation.
if (report_exceptions && !FLAG_debugger)
ReportException(isolate, &try_catch);
return false;
} else {
Handle<Value> result = script->Run();
if (result.IsEmpty()) {
ASSERT(try_catch.HasCaught());
// Print errors that happened during execution.
if (report_exceptions && !FLAG_debugger)
ReportException(isolate, &try_catch);
return false;
} else {
ASSERT(!try_catch.HasCaught());
if (print_result) {
#if !defined(V8_SHARED)
if (options.test_shell) {
#endif
if (!result->IsUndefined()) {
// If all went well and the result wasn't undefined then print
// the returned value.
v8::String::Utf8Value str(result);
fwrite(*str, sizeof(**str), str.length(), stdout);
printf("\n");
}
#if !defined(V8_SHARED)
} else {
Context::Scope context_scope(utility_context_);
Handle<Object> global = utility_context_->Global();
Handle<Value> fun = global->Get(String::New("Stringify"));
Handle<Value> argv[1] = { result };
Handle<Value> s = Handle<Function>::Cast(fun)->Call(global, 1, argv);
v8::String::Utf8Value str(s);
fwrite(*str, sizeof(**str), str.length(), stdout);
printf("\n");
}
#endif
}
return true;
}
}
}
Handle<Value> Shell::Print(const Arguments& args) {
Handle<Value> val = Write(args);
printf("\n");
fflush(stdout);
return val;
}
Handle<Value> Shell::Write(const Arguments& args) {
for (int i = 0; i < args.Length(); i++) {
HandleScope handle_scope(args.GetIsolate());
if (i != 0) {
printf(" ");
}
// Explicitly catch potential exceptions in toString().
v8::TryCatch try_catch;
Handle<String> str_obj = args[i]->ToString();
if (try_catch.HasCaught()) return try_catch.ReThrow();
v8::String::Utf8Value str(str_obj);
int n = static_cast<int>(fwrite(*str, sizeof(**str), str.length(), stdout));
if (n != str.length()) {
printf("Error in fwrite\n");
Exit(1);
}
}
return Undefined(args.GetIsolate());
}
Handle<Value> Shell::EnableProfiler(const Arguments& args) {
V8::ResumeProfiler();
return Undefined(args.GetIsolate());
}
Handle<Value> Shell::DisableProfiler(const Arguments& args) {
V8::PauseProfiler();
return Undefined(args.GetIsolate());
}
Handle<Value> Shell::Read(const Arguments& args) {
String::Utf8Value file(args[0]);
if (*file == NULL) {
return Throw("Error loading file");
}
Handle<String> source = ReadFile(args.GetIsolate(), *file);
if (source.IsEmpty()) {
return Throw("Error loading file");
}
return source;
}
Handle<String> Shell::ReadFromStdin(Isolate* isolate) {
static const int kBufferSize = 256;
char buffer[kBufferSize];
Handle<String> accumulator = String::New("");
int length;
while (true) {
// Continue reading if the line ends with an escape '\\' or the line has
// not been fully read into the buffer yet (does not end with '\n').
// If fgets gets an error, just give up.
char* input = NULL;
{ // Release lock for blocking input.
Unlocker unlock(isolate);
input = fgets(buffer, kBufferSize, stdin);
}
if (input == NULL) return Handle<String>();
length = static_cast<int>(strlen(buffer));
if (length == 0) {
return accumulator;
} else if (buffer[length-1] != '\n') {
accumulator = String::Concat(accumulator, String::New(buffer, length));
} else if (length > 1 && buffer[length-2] == '\\') {
buffer[length-2] = '\n';
accumulator = String::Concat(accumulator, String::New(buffer, length-1));
} else {
return String::Concat(accumulator, String::New(buffer, length-1));
}
}
}
Handle<Value> Shell::Load(const Arguments& args) {
for (int i = 0; i < args.Length(); i++) {
HandleScope handle_scope(args.GetIsolate());
String::Utf8Value file(args[i]);
if (*file == NULL) {
return Throw("Error loading file");
}
Handle<String> source = ReadFile(args.GetIsolate(), *file);
if (source.IsEmpty()) {
return Throw("Error loading file");
}
if (!ExecuteString(args.GetIsolate(),
source,
String::New(*file),
false,
true)) {
return Throw("Error executing file");
}
}
return Undefined(args.GetIsolate());
}
static int32_t convertToInt(Local<Value> value_in, TryCatch* try_catch) {
if (value_in->IsInt32()) {
return value_in->Int32Value();
}
Local<Value> number = value_in->ToNumber();
if (try_catch->HasCaught()) return 0;
ASSERT(number->IsNumber());
Local<Int32> int32 = number->ToInt32();
if (try_catch->HasCaught() || int32.IsEmpty()) return 0;
int32_t value = int32->Int32Value();
if (try_catch->HasCaught()) return 0;
return value;
}
static int32_t convertToUint(Local<Value> value_in, TryCatch* try_catch) {
int32_t raw_value = convertToInt(value_in, try_catch);
if (try_catch->HasCaught()) return 0;
if (raw_value < 0) {
Throw("Array length must not be negative.");
return 0;
}
static const int kMaxLength = 0x3fffffff;
#ifndef V8_SHARED
ASSERT(kMaxLength == i::ExternalArray::kMaxLength);
#endif // V8_SHARED
if (raw_value > static_cast<int32_t>(kMaxLength)) {
Throw("Array length exceeds maximum length.");
}
return raw_value;
}
Handle<Value> Shell::CreateExternalArrayBuffer(Isolate* isolate,
Handle<Object> buffer,
int32_t length) {
static const int32_t kMaxSize = 0x7fffffff;
// Make sure the total size fits into a (signed) int.
if (length < 0 || length > kMaxSize) {
return Throw("ArrayBuffer exceeds maximum size (2G)");
}
uint8_t* data = new uint8_t[length];
if (data == NULL) {
return Throw("Memory allocation failed");
}
memset(data, 0, length);
buffer->SetHiddenValue(Symbols::ArrayBufferMarkerPropName(isolate), True());
Persistent<Object> persistent_array =
Persistent<Object>::New(isolate, buffer);
persistent_array.MakeWeak(isolate, data, ExternalArrayWeakCallback);
persistent_array.MarkIndependent(isolate);
isolate->AdjustAmountOfExternalAllocatedMemory(length);
buffer->SetIndexedPropertiesToExternalArrayData(
data, v8::kExternalByteArray, length);
buffer->Set(Symbols::byteLength(isolate),
Int32::New(length, isolate),
ReadOnly);
return buffer;
}
Handle<Value> Shell::ArrayBuffer(const Arguments& args) {
if (!args.IsConstructCall()) {
Handle<Value>* rec_args = new Handle<Value>[args.Length()];
for (int i = 0; i < args.Length(); ++i) rec_args[i] = args[i];
Handle<Value> result = args.Callee()->NewInstance(args.Length(), rec_args);
delete[] rec_args;
return result;
}
if (args.Length() == 0) {
return Throw("ArrayBuffer constructor must have one argument");
}
TryCatch try_catch;
int32_t length = convertToUint(args[0], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
return CreateExternalArrayBuffer(args.GetIsolate(), args.This(), length);
}
Handle<Object> Shell::CreateExternalArray(Isolate* isolate,
Handle<Object> array,
Handle<Object> buffer,
ExternalArrayType type,
int32_t length,
int32_t byteLength,
int32_t byteOffset,
int32_t element_size) {
ASSERT(element_size == 1 || element_size == 2 ||
element_size == 4 || element_size == 8);
ASSERT(byteLength == length * element_size);
void* data = buffer->GetIndexedPropertiesExternalArrayData();
ASSERT(data != NULL);
array->SetIndexedPropertiesToExternalArrayData(
static_cast<uint8_t*>(data) + byteOffset, type, length);
array->SetHiddenValue(Symbols::ArrayMarkerPropName(isolate),
Int32::New(type, isolate));
array->Set(Symbols::byteLength(isolate),
Int32::New(byteLength, isolate),
ReadOnly);
array->Set(Symbols::byteOffset(isolate),
Int32::New(byteOffset, isolate),
ReadOnly);
array->Set(Symbols::length(isolate),
Int32::New(length, isolate),
ReadOnly);
array->Set(Symbols::BYTES_PER_ELEMENT(isolate),
Int32::New(element_size, isolate));
array->Set(Symbols::buffer(isolate),
buffer,
ReadOnly);
return array;
}
Handle<Value> Shell::CreateExternalArray(const Arguments& args,
ExternalArrayType type,
int32_t element_size) {
Isolate* isolate = args.GetIsolate();
if (!args.IsConstructCall()) {
Handle<Value>* rec_args = new Handle<Value>[args.Length()];
for (int i = 0; i < args.Length(); ++i) rec_args[i] = args[i];
Handle<Value> result = args.Callee()->NewInstance(args.Length(), rec_args);
delete[] rec_args;
return result;
}
TryCatch try_catch;
ASSERT(element_size == 1 || element_size == 2 ||
element_size == 4 || element_size == 8);
// All of the following constructors are supported:
// TypedArray(unsigned long length)
// TypedArray(type[] array)
// TypedArray(TypedArray array)
// TypedArray(ArrayBuffer buffer,
// optional unsigned long byteOffset,
// optional unsigned long length)
Handle<Object> buffer;
int32_t length;
int32_t byteLength;
int32_t byteOffset;
bool init_from_array = false;
if (args.Length() == 0) {
return Throw("Array constructor must have at least one argument");
}
if (args[0]->IsObject() &&
!args[0]->ToObject()->GetHiddenValue(
Symbols::ArrayBufferMarkerPropName(isolate)).IsEmpty()) {
// Construct from ArrayBuffer.
buffer = args[0]->ToObject();
int32_t bufferLength =
convertToUint(buffer->Get(Symbols::byteLength(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (args.Length() < 2 || args[1]->IsUndefined()) {
byteOffset = 0;
} else {
byteOffset = convertToUint(args[1], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (byteOffset > bufferLength) {
return Throw("byteOffset out of bounds");
}
if (byteOffset % element_size != 0) {
return Throw("byteOffset must be multiple of element size");
}
}
if (args.Length() < 3 || args[2]->IsUndefined()) {
byteLength = bufferLength - byteOffset;
length = byteLength / element_size;
if (byteLength % element_size != 0) {
return Throw("buffer size must be multiple of element size");
}
} else {
length = convertToUint(args[2], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
byteLength = length * element_size;
if (byteOffset + byteLength > bufferLength) {
return Throw("length out of bounds");
}
}
} else {
if (args[0]->IsObject() &&
args[0]->ToObject()->Has(Symbols::length(isolate))) {
// Construct from array.
Local<Value> value = args[0]->ToObject()->Get(Symbols::length(isolate));
if (try_catch.HasCaught()) return try_catch.ReThrow();
length = convertToUint(value, &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
init_from_array = true;
} else {
// Construct from size.
length = convertToUint(args[0], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
}
byteLength = length * element_size;
byteOffset = 0;
Handle<Object> global = Context::GetCurrent()->Global();
Handle<Value> array_buffer = global->Get(Symbols::ArrayBuffer(isolate));
ASSERT(!try_catch.HasCaught() && array_buffer->IsFunction());
Handle<Value> buffer_args[] = { Uint32::New(byteLength, isolate) };
Handle<Value> result = Handle<Function>::Cast(array_buffer)->NewInstance(
1, buffer_args);
if (try_catch.HasCaught()) return result;
buffer = result->ToObject();
}
Handle<Object> array =
CreateExternalArray(isolate, args.This(), buffer, type, length,
byteLength, byteOffset, element_size);
if (init_from_array) {
Handle<Object> init = args[0]->ToObject();
for (int i = 0; i < length; ++i) {
Local<Value> value = init->Get(i);
if (try_catch.HasCaught()) return try_catch.ReThrow();
array->Set(i, value);
}
}
return array;
}
Handle<Value> Shell::ArrayBufferSlice(const Arguments& args) {
TryCatch try_catch;
if (!args.This()->IsObject()) {
return Throw("'slice' invoked on non-object receiver");
}
Isolate* isolate = args.GetIsolate();
Local<Object> self = args.This();
Local<Value> marker =
self->GetHiddenValue(Symbols::ArrayBufferMarkerPropName(isolate));
if (marker.IsEmpty()) {
return Throw("'slice' invoked on wrong receiver type");
}
int32_t length =
convertToUint(self->Get(Symbols::byteLength(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (args.Length() == 0) {
return Throw("'slice' must have at least one argument");
}
int32_t begin = convertToInt(args[0], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (begin < 0) begin += length;
if (begin < 0) begin = 0;
if (begin > length) begin = length;
int32_t end;
if (args.Length() < 2 || args[1]->IsUndefined()) {
end = length;
} else {
end = convertToInt(args[1], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (end < 0) end += length;
if (end < 0) end = 0;
if (end > length) end = length;
if (end < begin) end = begin;
}
Local<Function> constructor = Local<Function>::Cast(self->GetConstructor());
Handle<Value> new_args[] = { Uint32::New(end - begin, isolate) };
Handle<Value> result = constructor->NewInstance(1, new_args);
if (try_catch.HasCaught()) return result;
Handle<Object> buffer = result->ToObject();
uint8_t* dest =
static_cast<uint8_t*>(buffer->GetIndexedPropertiesExternalArrayData());
uint8_t* src = begin + static_cast<uint8_t*>(
self->GetIndexedPropertiesExternalArrayData());
memcpy(dest, src, end - begin);
return buffer;
}
Handle<Value> Shell::ArraySubArray(const Arguments& args) {
TryCatch try_catch;
if (!args.This()->IsObject()) {
return Throw("'subarray' invoked on non-object receiver");
}
Isolate* isolate = args.GetIsolate();
Local<Object> self = args.This();
Local<Value> marker =
self->GetHiddenValue(Symbols::ArrayMarkerPropName(isolate));
if (marker.IsEmpty()) {
return Throw("'subarray' invoked on wrong receiver type");
}
Handle<Object> buffer = self->Get(Symbols::buffer(isolate))->ToObject();
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t length =
convertToUint(self->Get(Symbols::length(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t byteOffset =
convertToUint(self->Get(Symbols::byteOffset(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t element_size =
convertToUint(self->Get(Symbols::BYTES_PER_ELEMENT(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (args.Length() == 0) {
return Throw("'subarray' must have at least one argument");
}
int32_t begin = convertToInt(args[0], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (begin < 0) begin += length;
if (begin < 0) begin = 0;
if (begin > length) begin = length;
int32_t end;
if (args.Length() < 2 || args[1]->IsUndefined()) {
end = length;
} else {
end = convertToInt(args[1], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (end < 0) end += length;
if (end < 0) end = 0;
if (end > length) end = length;
if (end < begin) end = begin;
}
length = end - begin;
byteOffset += begin * element_size;
Local<Function> constructor = Local<Function>::Cast(self->GetConstructor());
Handle<Value> construct_args[] = {
buffer, Uint32::New(byteOffset, isolate), Uint32::New(length, isolate)
};
return constructor->NewInstance(3, construct_args);
}
Handle<Value> Shell::ArraySet(const Arguments& args) {
TryCatch try_catch;
if (!args.This()->IsObject()) {
return Throw("'set' invoked on non-object receiver");
}
Isolate* isolate = args.GetIsolate();
Local<Object> self = args.This();
Local<Value> marker =
self->GetHiddenValue(Symbols::ArrayMarkerPropName(isolate));
if (marker.IsEmpty()) {
return Throw("'set' invoked on wrong receiver type");
}
int32_t length =
convertToUint(self->Get(Symbols::length(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t element_size =
convertToUint(self->Get(Symbols::BYTES_PER_ELEMENT(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (args.Length() == 0) {
return Throw("'set' must have at least one argument");
}
if (!args[0]->IsObject() ||
!args[0]->ToObject()->Has(Symbols::length(isolate))) {
return Throw("'set' invoked with non-array argument");
}
Handle<Object> source = args[0]->ToObject();
int32_t source_length =
convertToUint(source->Get(Symbols::length(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t offset;
if (args.Length() < 2 || args[1]->IsUndefined()) {
offset = 0;
} else {
offset = convertToUint(args[1], &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
}
if (offset + source_length > length) {
return Throw("offset or source length out of bounds");
}
int32_t source_element_size;
if (source->GetHiddenValue(Symbols::ArrayMarkerPropName(isolate)).IsEmpty()) {
source_element_size = 0;
} else {
source_element_size =
convertToUint(source->Get(Symbols::BYTES_PER_ELEMENT(isolate)),
&try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
}
if (element_size == source_element_size &&
self->GetConstructor()->StrictEquals(source->GetConstructor())) {
// Use memmove on the array buffers.
Handle<Object> buffer = self->Get(Symbols::buffer(isolate))->ToObject();
if (try_catch.HasCaught()) return try_catch.ReThrow();
Handle<Object> source_buffer =
source->Get(Symbols::buffer(isolate))->ToObject();
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t byteOffset =
convertToUint(self->Get(Symbols::byteOffset(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t source_byteOffset =
convertToUint(source->Get(Symbols::byteOffset(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
uint8_t* dest = byteOffset + offset * element_size + static_cast<uint8_t*>(
buffer->GetIndexedPropertiesExternalArrayData());
uint8_t* src = source_byteOffset + static_cast<uint8_t*>(
source_buffer->GetIndexedPropertiesExternalArrayData());
memmove(dest, src, source_length * element_size);
} else if (source_element_size == 0) {
// Source is not a typed array, copy element-wise sequentially.
for (int i = 0; i < source_length; ++i) {
self->Set(offset + i, source->Get(i));
if (try_catch.HasCaught()) return try_catch.ReThrow();
}
} else {
// Need to copy element-wise to make the right conversions.
Handle<Object> buffer = self->Get(Symbols::buffer(isolate))->ToObject();
if (try_catch.HasCaught()) return try_catch.ReThrow();
Handle<Object> source_buffer =
source->Get(Symbols::buffer(isolate))->ToObject();
if (try_catch.HasCaught()) return try_catch.ReThrow();
if (buffer->StrictEquals(source_buffer)) {
// Same backing store, need to handle overlap correctly.
// This gets a bit tricky in the case of different element sizes
// (which, of course, is extremely unlikely to ever occur in practice).
int32_t byteOffset =
convertToUint(self->Get(Symbols::byteOffset(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
int32_t source_byteOffset =
convertToUint(source->Get(Symbols::byteOffset(isolate)), &try_catch);
if (try_catch.HasCaught()) return try_catch.ReThrow();
// Copy as much as we can from left to right.
int i = 0;
int32_t next_dest_offset = byteOffset + (offset + 1) * element_size;
int32_t next_src_offset = source_byteOffset + source_element_size;
while (i < length && next_dest_offset <= next_src_offset) {
self->Set(offset + i, source->Get(i));
++i;
next_dest_offset += element_size;
next_src_offset += source_element_size;
}
// Of what's left, copy as much as we can from right to left.
int j = length - 1;
int32_t dest_offset = byteOffset + (offset + j) * element_size;
int32_t src_offset = source_byteOffset + j * source_element_size;
while (j >= i && dest_offset >= src_offset) {
self->Set(offset + j, source->Get(j));
--j;
dest_offset -= element_size;
src_offset -= source_element_size;
}
// There can be at most 8 entries left in the middle that need buffering
// (because the largest element_size is 8 times the smallest).
ASSERT(j+1 - i <= 8);
Handle<Value> temp[8];
for (int k = i; k <= j; ++k) {
temp[k - i] = source->Get(k);
}
for (int k = i; k <= j; ++k) {
self->Set(offset + k, temp[k - i]);
}
} else {
// Different backing stores, safe to copy element-wise sequentially.
for (int i = 0; i < source_length; ++i)
self->Set(offset + i, source->Get(i));
}
}
return Undefined(args.GetIsolate());
}
void Shell::ExternalArrayWeakCallback(v8::Isolate* isolate,
Persistent<Value> object,
void* data) {
HandleScope scope(isolate);
int32_t length =
object->ToObject()->Get(Symbols::byteLength(isolate))->Uint32Value();
isolate->AdjustAmountOfExternalAllocatedMemory(-length);
delete[] static_cast<uint8_t*>(data);
object.Dispose(isolate);
}
Handle<Value> Shell::Int8Array(const Arguments& args) {
return CreateExternalArray(args, v8::kExternalByteArray, sizeof(int8_t));
}
Handle<Value> Shell::Uint8Array(const Arguments& args) {
return CreateExternalArray(args, kExternalUnsignedByteArray, sizeof(uint8_t));
}
Handle<Value> Shell::Int16Array(const Arguments& args) {
return CreateExternalArray(args, kExternalShortArray, sizeof(int16_t));
}
Handle<Value> Shell::Uint16Array(const Arguments& args) {
return CreateExternalArray(
args, kExternalUnsignedShortArray, sizeof(uint16_t));
}
Handle<Value> Shell::Int32Array(const Arguments& args) {
return CreateExternalArray(args, kExternalIntArray, sizeof(int32_t));
}
Handle<Value> Shell::Uint32Array(const Arguments& args) {
return CreateExternalArray(args, kExternalUnsignedIntArray, sizeof(uint32_t));
}
Handle<Value> Shell::Float32Array(const Arguments& args) {
return CreateExternalArray(
args, kExternalFloatArray, sizeof(float)); // NOLINT
}
Handle<Value> Shell::Float64Array(const Arguments& args) {
return CreateExternalArray(
args, kExternalDoubleArray, sizeof(double)); // NOLINT
}
Handle<Value> Shell::Uint8ClampedArray(const Arguments& args) {
return CreateExternalArray(args, kExternalPixelArray, sizeof(uint8_t));
}
Handle<Value> Shell::Yield(const Arguments& args) {
v8::Unlocker unlocker(args.GetIsolate());
return Undefined(args.GetIsolate());
}
Handle<Value> Shell::Quit(const Arguments& args) {
int exit_code = args[0]->Int32Value();
OnExit();
exit(exit_code);
return Undefined(args.GetIsolate());
}
Handle<Value> Shell::Version(const Arguments& args) {
return String::New(V8::GetVersion());
}
void Shell::ReportException(Isolate* isolate, v8::TryCatch* try_catch) {
HandleScope handle_scope(isolate);
#if !defined(V8_SHARED) && defined(ENABLE_DEBUGGER_SUPPORT)
bool enter_context = !Context::InContext();
if (enter_context) utility_context_->Enter();
#endif // !V8_SHARED && ENABLE_DEBUGGER_SUPPORT
v8::String::Utf8Value exception(try_catch->Exception());
const char* exception_string = ToCString(exception);
Handle<Message> message = try_catch->Message();
if (message.IsEmpty()) {
// V8 didn't provide any extra information about this error; just
// print the exception.
printf("%s\n", exception_string);
} else {
// Print (filename):(line number): (message).
v8::String::Utf8Value filename(message->GetScriptResourceName());
const char* filename_string = ToCString(filename);
int linenum = message->GetLineNumber();
printf("%s:%i: %s\n", filename_string, linenum, exception_string);
// Print line of source code.
v8::String::Utf8Value sourceline(message->GetSourceLine());
const char* sourceline_string = ToCString(sourceline);
printf("%s\n", sourceline_string);
// Print wavy underline (GetUnderline is deprecated).
int start = message->GetStartColumn();
for (int i = 0; i < start; i++) {
printf(" ");
}
int end = message->GetEndColumn();
for (int i = start; i < end; i++) {
printf("^");
}
printf("\n");
v8::String::Utf8Value stack_trace(try_catch->StackTrace());
if (stack_trace.length() > 0) {
const char* stack_trace_string = ToCString(stack_trace);
printf("%s\n", stack_trace_string);
}
}
printf("\n");
#if !defined(V8_SHARED) && defined(ENABLE_DEBUGGER_SUPPORT)
if (enter_context) utility_context_->Exit();
#endif // !V8_SHARED && ENABLE_DEBUGGER_SUPPORT
}
#ifndef V8_SHARED
Handle<Array> Shell::GetCompletions(Isolate* isolate,
Handle<String> text,
Handle<String> full) {
HandleScope handle_scope(isolate);
Context::Scope context_scope(utility_context_);
Handle<Object> global = utility_context_->Global();
Handle<Value> fun = global->Get(String::New("GetCompletions"));
static const int kArgc = 3;
Handle<Value> argv[kArgc] = { evaluation_context_->Global(), text, full };
Handle<Value> val = Handle<Function>::Cast(fun)->Call(global, kArgc, argv);
return handle_scope.Close(Handle<Array>::Cast(val));
}
#ifdef ENABLE_DEBUGGER_SUPPORT
Handle<Object> Shell::DebugMessageDetails(Handle<String> message) {
Context::Scope context_scope(utility_context_);
Handle<Object> global = utility_context_->Global();
Handle<Value> fun = global->Get(String::New("DebugMessageDetails"));
static const int kArgc = 1;
Handle<Value> argv[kArgc] = { message };
Handle<Value> val = Handle<Function>::Cast(fun)->Call(global, kArgc, argv);
return Handle<Object>::Cast(val);
}
Handle<Value> Shell::DebugCommandToJSONRequest(Handle<String> command) {
Context::Scope context_scope(utility_context_);
Handle<Object> global = utility_context_->Global();
Handle<Value> fun = global->Get(String::New("DebugCommandToJSONRequest"));
static const int kArgc = 1;
Handle<Value> argv[kArgc] = { command };
Handle<Value> val = Handle<Function>::Cast(fun)->Call(global, kArgc, argv);
return val;
}
void Shell::DispatchDebugMessages() {
v8::Context::Scope scope(Shell::evaluation_context_);
v8::Debug::ProcessDebugMessages();
}
#endif // ENABLE_DEBUGGER_SUPPORT
#endif // V8_SHARED
#ifndef V8_SHARED
int32_t* Counter::Bind(const char* name, bool is_histogram) {
int i;
for (i = 0; i < kMaxNameSize - 1 && name[i]; i++)
name_[i] = static_cast<char>(name[i]);
name_[i] = '\0';
is_histogram_ = is_histogram;
return ptr();
}
void Counter::AddSample(int32_t sample) {
count_++;
sample_total_ += sample;
}
CounterCollection::CounterCollection() {
magic_number_ = 0xDEADFACE;
max_counters_ = kMaxCounters;
max_name_size_ = Counter::kMaxNameSize;
counters_in_use_ = 0;
}
Counter* CounterCollection::GetNextCounter() {
if (counters_in_use_ == kMaxCounters) return NULL;
return &counters_[counters_in_use_++];
}
void Shell::MapCounters(const char* name) {
counters_file_ = i::OS::MemoryMappedFile::create(
name, sizeof(CounterCollection), &local_counters_);
void* memory = (counters_file_ == NULL) ?
NULL : counters_file_->memory();
if (memory == NULL) {
printf("Could not map counters file %s\n", name);
Exit(1);
}
counters_ = static_cast<CounterCollection*>(memory);
V8::SetCounterFunction(LookupCounter);
V8::SetCreateHistogramFunction(CreateHistogram);
V8::SetAddHistogramSampleFunction(AddHistogramSample);
}
int CounterMap::Hash(const char* name) {
int h = 0;
int c;
while ((c = *name++) != 0) {
h += h << 5;
h += c;
}
return h;
}
Counter* Shell::GetCounter(const char* name, bool is_histogram) {
Counter* counter = counter_map_->Lookup(name);
if (counter == NULL) {
counter = counters_->GetNextCounter();
if (counter != NULL) {
counter_map_->Set(name, counter);
counter->Bind(name, is_histogram);
}
} else {
ASSERT(counter->is_histogram() == is_histogram);
}
return counter;
}
int* Shell::LookupCounter(const char* name) {
Counter* counter = GetCounter(name, false);
if (counter != NULL) {
return counter->ptr();
} else {
return NULL;
}
}
void* Shell::CreateHistogram(const char* name,
int min,
int max,
size_t buckets) {
return GetCounter(name, true);
}
void Shell::AddHistogramSample(void* histogram, int sample) {
Counter* counter = reinterpret_cast<Counter*>(histogram);
counter->AddSample(sample);
}
void Shell::InstallUtilityScript(Isolate* isolate) {
Locker lock(isolate);
HandleScope scope(isolate);
// If we use the utility context, we have to set the security tokens so that
// utility, evaluation and debug context can all access each other.
utility_context_->SetSecurityToken(Undefined(isolate));
evaluation_context_->SetSecurityToken(Undefined(isolate));
Context::Scope utility_scope(utility_context_);
#ifdef ENABLE_DEBUGGER_SUPPORT
if (i::FLAG_debugger) printf("JavaScript debugger enabled\n");
// Install the debugger object in the utility scope
i::Debug* debug = i::Isolate::Current()->debug();
debug->Load();
i::Handle<i::JSObject> js_debug
= i::Handle<i::JSObject>(debug->debug_context()->global_object());
utility_context_->Global()->Set(String::New("$debug"),
Utils::ToLocal(js_debug));
debug->debug_context()->set_security_token(HEAP->undefined_value());
#endif // ENABLE_DEBUGGER_SUPPORT
// Run the d8 shell utility script in the utility context
int source_index = i::NativesCollection<i::D8>::GetIndex("d8");
i::Vector<const char> shell_source =
i::NativesCollection<i::D8>::GetRawScriptSource(source_index);
i::Vector<const char> shell_source_name =
i::NativesCollection<i::D8>::GetScriptName(source_index);
Handle<String> source = String::New(shell_source.start(),
shell_source.length());
Handle<String> name = String::New(shell_source_name.start(),
shell_source_name.length());
Handle<Script> script = Script::Compile(source, name);
script->Run();
// Mark the d8 shell script as native to avoid it showing up as normal source
// in the debugger.
i::Handle<i::Object> compiled_script = Utils::OpenHandle(*script);
i::Handle<i::Script> script_object = compiled_script->IsJSFunction()
? i::Handle<i::Script>(i::Script::cast(
i::JSFunction::cast(*compiled_script)->shared()->script()))
: i::Handle<i::Script>(i::Script::cast(
i::SharedFunctionInfo::cast(*compiled_script)->script()));
script_object->set_type(i::Smi::FromInt(i::Script::TYPE_NATIVE));
#ifdef ENABLE_DEBUGGER_SUPPORT
// Start the in-process debugger if requested.
if (i::FLAG_debugger && !i::FLAG_debugger_agent) {
v8::Debug::SetDebugEventListener(HandleDebugEvent);
}
#endif // ENABLE_DEBUGGER_SUPPORT
}
#endif // V8_SHARED
#ifdef COMPRESS_STARTUP_DATA_BZ2
class BZip2Decompressor : public v8::StartupDataDecompressor {
public:
virtual ~BZip2Decompressor() { }
protected:
virtual int DecompressData(char* raw_data,
int* raw_data_size,
const char* compressed_data,
int compressed_data_size) {
ASSERT_EQ(v8::StartupData::kBZip2,
v8::V8::GetCompressedStartupDataAlgorithm());
unsigned int decompressed_size = *raw_data_size;
int result =
BZ2_bzBuffToBuffDecompress(raw_data,
&decompressed_size,
const_cast<char*>(compressed_data),
compressed_data_size,
0, 1);
if (result == BZ_OK) {
*raw_data_size = decompressed_size;
}
return result;
}
};
#endif
Handle<FunctionTemplate> Shell::CreateArrayBufferTemplate(
InvocationCallback fun) {
Handle<FunctionTemplate> buffer_template = FunctionTemplate::New(fun);
Local<Template> proto_template = buffer_template->PrototypeTemplate();
proto_template->Set(String::New("slice"),
FunctionTemplate::New(ArrayBufferSlice));
return buffer_template;
}
Handle<FunctionTemplate> Shell::CreateArrayTemplate(InvocationCallback fun) {
Handle<FunctionTemplate> array_template = FunctionTemplate::New(fun);
Local<Template> proto_template = array_template->PrototypeTemplate();
proto_template->Set(String::New("set"), FunctionTemplate::New(ArraySet));
proto_template->Set(String::New("subarray"),
FunctionTemplate::New(ArraySubArray));
return array_template;
}
Handle<ObjectTemplate> Shell::CreateGlobalTemplate(Isolate* isolate) {
Handle<ObjectTemplate> global_template = ObjectTemplate::New();
global_template->Set(String::New("print"), FunctionTemplate::New(Print));
global_template->Set(String::New("write"), FunctionTemplate::New(Write));
global_template->Set(String::New("read"), FunctionTemplate::New(Read));
global_template->Set(String::New("readbuffer"),
FunctionTemplate::New(ReadBuffer));
global_template->Set(String::New("readline"),
FunctionTemplate::New(ReadLine));
global_template->Set(String::New("load"), FunctionTemplate::New(Load));
global_template->Set(String::New("quit"), FunctionTemplate::New(Quit));
global_template->Set(String::New("version"), FunctionTemplate::New(Version));
global_template->Set(String::New("enableProfiler"),
FunctionTemplate::New(EnableProfiler));
global_template->Set(String::New("disableProfiler"),
FunctionTemplate::New(DisableProfiler));
// Bind the handlers for external arrays.
PropertyAttribute attr =
static_cast<PropertyAttribute>(ReadOnly | DontDelete);
global_template->Set(Symbols::ArrayBuffer(isolate),
CreateArrayBufferTemplate(ArrayBuffer), attr);
global_template->Set(String::New("Int8Array"),
CreateArrayTemplate(Int8Array), attr);
global_template->Set(String::New("Uint8Array"),
CreateArrayTemplate(Uint8Array), attr);
global_template->Set(String::New("Int16Array"),
CreateArrayTemplate(Int16Array), attr);
global_template->Set(String::New("Uint16Array"),
CreateArrayTemplate(Uint16Array), attr);
global_template->Set(String::New("Int32Array"),
CreateArrayTemplate(Int32Array), attr);
global_template->Set(String::New("Uint32Array"),
CreateArrayTemplate(Uint32Array), attr);
global_template->Set(String::New("Float32Array"),
CreateArrayTemplate(Float32Array), attr);
global_template->Set(String::New("Float64Array"),
CreateArrayTemplate(Float64Array), attr);
global_template->Set(String::New("Uint8ClampedArray"),
CreateArrayTemplate(Uint8ClampedArray), attr);
#if !defined(V8_SHARED) && !defined(_WIN32) && !defined(_WIN64)
Handle<ObjectTemplate> os_templ = ObjectTemplate::New();
AddOSMethods(os_templ);
global_template->Set(String::New("os"), os_templ);
#endif // V8_SHARED
return global_template;
}
void Shell::Initialize(Isolate* isolate) {
#ifdef COMPRESS_STARTUP_DATA_BZ2
BZip2Decompressor startup_data_decompressor;
int bz2_result = startup_data_decompressor.Decompress();
if (bz2_result != BZ_OK) {
fprintf(stderr, "bzip error code: %d\n", bz2_result);
Exit(1);
}
#endif
#ifndef V8_SHARED
Shell::counter_map_ = new CounterMap();
// Set up counters
if (i::StrLength(i::FLAG_map_counters) != 0)
MapCounters(i::FLAG_map_counters);
if (i::FLAG_dump_counters || i::FLAG_track_gc_object_stats) {
V8::SetCounterFunction(LookupCounter);
V8::SetCreateHistogramFunction(CreateHistogram);
V8::SetAddHistogramSampleFunction(AddHistogramSample);
}
#endif // V8_SHARED
}
void Shell::InitializeDebugger(Isolate* isolate) {
if (options.test_shell) return;
#ifndef V8_SHARED
Locker lock(isolate);
HandleScope scope(isolate);
Handle<ObjectTemplate> global_template = CreateGlobalTemplate(isolate);
utility_context_ = Context::New(NULL, global_template);
#ifdef ENABLE_DEBUGGER_SUPPORT
// Start the debugger agent if requested.
if (i::FLAG_debugger_agent) {
v8::Debug::EnableAgent("d8 shell", i::FLAG_debugger_port, true);
v8::Debug::SetDebugMessageDispatchHandler(DispatchDebugMessages, true);
}
#endif // ENABLE_DEBUGGER_SUPPORT
#endif // V8_SHARED
}
Persistent<Context> Shell::CreateEvaluationContext(Isolate* isolate) {
#ifndef V8_SHARED
// This needs to be a critical section since this is not thread-safe
i::ScopedLock lock(context_mutex_);
#endif // V8_SHARED
// Initialize the global objects
Handle<ObjectTemplate> global_template = CreateGlobalTemplate(isolate);
Persistent<Context> context = Context::New(NULL, global_template);
ASSERT(!context.IsEmpty());
Context::Scope scope(context);
#ifndef V8_SHARED
i::JSArguments js_args = i::FLAG_js_arguments;
i::Handle<i::FixedArray> arguments_array =
FACTORY->NewFixedArray(js_args.argc());
for (int j = 0; j < js_args.argc(); j++) {
i::Handle<i::String> arg =
FACTORY->NewStringFromUtf8(i::CStrVector(js_args[j]));
arguments_array->set(j, *arg);
}
i::Handle<i::JSArray> arguments_jsarray =
FACTORY->NewJSArrayWithElements(arguments_array);
context->Global()->Set(String::New("arguments"),
Utils::ToLocal(arguments_jsarray));
#endif // V8_SHARED
return context;
}
void Shell::Exit(int exit_code) {
// Use _exit instead of exit to avoid races between isolate
// threads and static destructors.
fflush(stdout);
fflush(stderr);
_exit(exit_code);
}
#ifndef V8_SHARED
struct CounterAndKey {
Counter* counter;
const char* key;
};
int CompareKeys(const void* a, const void* b) {
return strcmp(static_cast<const CounterAndKey*>(a)->key,
static_cast<const CounterAndKey*>(b)->key);
}
#endif // V8_SHARED
void Shell::OnExit() {
LineEditor* line_editor = LineEditor::Get();
if (line_editor) line_editor->Close();
#ifndef V8_SHARED
if (i::FLAG_dump_counters) {
int number_of_counters = 0;
for (CounterMap::Iterator i(counter_map_); i.More(); i.Next()) {
number_of_counters++;
}
CounterAndKey* counters = new CounterAndKey[number_of_counters];
int j = 0;
for (CounterMap::Iterator i(counter_map_); i.More(); i.Next(), j++) {
counters[j].counter = i.CurrentValue();
counters[j].key = i.CurrentKey();
}
qsort(counters, number_of_counters, sizeof(counters[0]), CompareKeys);
printf("+----------------------------------------------------------------+"
"-------------+\n");
printf("| Name |"
" Value |\n");
printf("+----------------------------------------------------------------+"
"-------------+\n");
for (j = 0; j < number_of_counters; j++) {
Counter* counter = counters[j].counter;
const char* key = counters[j].key;
if (counter->is_histogram()) {
printf("| c:%-60s | %11i |\n", key, counter->count());
printf("| t:%-60s | %11i |\n", key, counter->sample_total());
} else {
printf("| %-62s | %11i |\n", key, counter->count());
}
}
printf("+----------------------------------------------------------------+"
"-------------+\n");
delete [] counters;
}
delete context_mutex_;
delete counters_file_;
delete counter_map_;
#endif // V8_SHARED
}
static FILE* FOpen(const char* path, const char* mode) {
#if defined(_MSC_VER) && (defined(_WIN32) || defined(_WIN64))
FILE* result;
if (fopen_s(&result, path, mode) == 0) {
return result;
} else {
return NULL;
}
#else
FILE* file = fopen(path, mode);
if (file == NULL) return NULL;
struct stat file_stat;
if (fstat(fileno(file), &file_stat) != 0) return NULL;
bool is_regular_file = ((file_stat.st_mode & S_IFREG) != 0);
if (is_regular_file) return file;
fclose(file);
return NULL;
#endif
}
static char* ReadChars(Isolate* isolate, const char* name, int* size_out) {
// Release the V8 lock while reading files.
v8::Unlocker unlocker(isolate);
FILE* file = FOpen(name, "rb");
if (file == NULL) return NULL;
fseek(file, 0, SEEK_END);
int size = ftell(file);
rewind(file);
char* chars = new char[size + 1];
chars[size] = '\0';
for (int i = 0; i < size;) {
int read = static_cast<int>(fread(&chars[i], 1, size - i, file));
i += read;
}
fclose(file);
*size_out = size;
return chars;
}
Handle<Value> Shell::ReadBuffer(const Arguments& args) {
ASSERT(sizeof(char) == sizeof(uint8_t)); // NOLINT
String::Utf8Value filename(args[0]);
int length;
if (*filename == NULL) {
return Throw("Error loading file");
}
uint8_t* data = reinterpret_cast<uint8_t*>(
ReadChars(args.GetIsolate(), *filename, &length));
if (data == NULL) {
return Throw("Error reading file");
}
Isolate* isolate = args.GetIsolate();
Handle<Object> buffer = Object::New();
buffer->SetHiddenValue(Symbols::ArrayBufferMarkerPropName(isolate), True());
Persistent<Object> persistent_buffer =
Persistent<Object>::New(isolate, buffer);
persistent_buffer.MakeWeak(isolate, data, ExternalArrayWeakCallback);
persistent_buffer.MarkIndependent(isolate);
isolate->AdjustAmountOfExternalAllocatedMemory(length);
buffer->SetIndexedPropertiesToExternalArrayData(
data, kExternalUnsignedByteArray, length);
buffer->Set(Symbols::byteLength(isolate),
Int32::New(static_cast<int32_t>(length), isolate), ReadOnly);
return buffer;
}
#ifndef V8_SHARED
static char* ReadToken(char* data, char token) {
char* next = i::OS::StrChr(data, token);
if (next != NULL) {
*next = '\0';
return (next + 1);
}
return NULL;
}
static char* ReadLine(char* data) {
return ReadToken(data, '\n');
}
static char* ReadWord(char* data) {
return ReadToken(data, ' ');
}
#endif // V8_SHARED
// Reads a file into a v8 string.
Handle<String> Shell::ReadFile(Isolate* isolate, const char* name) {
int size = 0;
char* chars = ReadChars(isolate, name, &size);
if (chars == NULL) return Handle<String>();
Handle<String> result = String::New(chars, size);
delete[] chars;
return result;
}
void Shell::RunShell(Isolate* isolate) {
Locker locker(isolate);
Context::Scope context_scope(evaluation_context_);
HandleScope outer_scope(isolate);
Handle<String> name = String::New("(d8)");
LineEditor* console = LineEditor::Get();
printf("V8 version %s [console: %s]\n", V8::GetVersion(), console->name());
console->Open(isolate);
while (true) {
HandleScope inner_scope(isolate);
Handle<String> input = console->Prompt(Shell::kPrompt);
if (input.IsEmpty()) break;
ExecuteString(isolate, input, name, true, true);
}
printf("\n");
}
#ifndef V8_SHARED
class ShellThread : public i::Thread {
public:
// Takes ownership of the underlying char array of |files|.
ShellThread(Isolate* isolate, char* files)
: Thread("d8:ShellThread"),
isolate_(isolate), files_(files) { }
~ShellThread() {
delete[] files_;
}
virtual void Run();
private:
Isolate* isolate_;
char* files_;
};
void ShellThread::Run() {
char* ptr = files_;
while ((ptr != NULL) && (*ptr != '\0')) {
// For each newline-separated line.
char* next_line = ReadLine(ptr);
if (*ptr == '#') {
// Skip comment lines.
ptr = next_line;
continue;
}
// Prepare the context for this thread.
Locker locker(isolate_);
HandleScope outer_scope(isolate_);
Persistent<Context> thread_context =
Shell::CreateEvaluationContext(isolate_);
Context::Scope context_scope(thread_context);
while ((ptr != NULL) && (*ptr != '\0')) {
HandleScope inner_scope(isolate_);
char* filename = ptr;
ptr = ReadWord(ptr);
// Skip empty strings.
if (strlen(filename) == 0) {
continue;
}
Handle<String> str = Shell::ReadFile(isolate_, filename);
if (str.IsEmpty()) {
printf("File '%s' not found\n", filename);
Shell::Exit(1);
}
Shell::ExecuteString(isolate_, str, String::New(filename), false, false);
}
thread_context.Dispose(thread_context->GetIsolate());
ptr = next_line;
}
}
#endif // V8_SHARED
SourceGroup::~SourceGroup() {
#ifndef V8_SHARED
delete next_semaphore_;
next_semaphore_ = NULL;
delete done_semaphore_;
done_semaphore_ = NULL;
delete thread_;
thread_ = NULL;
#endif // V8_SHARED
}
void SourceGroup::Execute(Isolate* isolate) {
for (int i = begin_offset_; i < end_offset_; ++i) {
const char* arg = argv_[i];
if (strcmp(arg, "-e") == 0 && i + 1 < end_offset_) {
// Execute argument given to -e option directly.
HandleScope handle_scope(isolate);
Handle<String> file_name = String::New("unnamed");
Handle<String> source = String::New(argv_[i + 1]);
if (!Shell::ExecuteString(isolate, source, file_name, false, true)) {
Shell::Exit(1);
}
++i;
} else if (arg[0] == '-') {
// Ignore other options. They have been parsed already.
} else {
// Use all other arguments as names of files to load and run.
HandleScope handle_scope(isolate);
Handle<String> file_name = String::New(arg);
Handle<String> source = ReadFile(isolate, arg);
if (source.IsEmpty()) {
printf("Error reading '%s'\n", arg);
Shell::Exit(1);
}
if (!Shell::ExecuteString(isolate, source, file_name, false, true)) {
Shell::Exit(1);
}
}
}
}
Handle<String> SourceGroup::ReadFile(Isolate* isolate, const char* name) {
int size;
char* chars = ReadChars(isolate, name, &size);
if (chars == NULL) return Handle<String>();
Handle<String> result = String::New(chars, size);
delete[] chars;
return result;
}
#ifndef V8_SHARED
i::Thread::Options SourceGroup::GetThreadOptions() {
// On some systems (OSX 10.6) the stack size default is 0.5Mb or less
// which is not enough to parse the big literal expressions used in tests.
// The stack size should be at least StackGuard::kLimitSize + some
// OS-specific padding for thread startup code. 2Mbytes seems to be enough.
return i::Thread::Options("IsolateThread", 2 * MB);
}
void SourceGroup::ExecuteInThread() {
Isolate* isolate = Isolate::New();
do {
if (next_semaphore_ != NULL) next_semaphore_->Wait();
{
Isolate::Scope iscope(isolate);
Locker lock(isolate);
HandleScope scope(isolate);
Symbols symbols(isolate);
Persistent<Context> context = Shell::CreateEvaluationContext(isolate);
{
Context::Scope cscope(context);
Execute(isolate);
}
context.Dispose(isolate);
if (Shell::options.send_idle_notification) {
const int kLongIdlePauseInMs = 1000;
V8::ContextDisposedNotification();
V8::IdleNotification(kLongIdlePauseInMs);
}
}
if (done_semaphore_ != NULL) done_semaphore_->Signal();
} while (!Shell::options.last_run);
isolate->Dispose();
}
void SourceGroup::StartExecuteInThread() {
if (thread_ == NULL) {
thread_ = new IsolateThread(this);
thread_->Start();
}
next_semaphore_->Signal();
}
void SourceGroup::WaitForThread() {
if (thread_ == NULL) return;
if (Shell::options.last_run) {
thread_->Join();
} else {
done_semaphore_->Wait();
}
}
#endif // V8_SHARED
bool Shell::SetOptions(int argc, char* argv[]) {
for (int i = 0; i < argc; i++) {
if (strcmp(argv[i], "--stress-opt") == 0) {
options.stress_opt = true;
argv[i] = NULL;
} else if (strcmp(argv[i], "--stress-deopt") == 0) {
options.stress_deopt = true;
argv[i] = NULL;
} else if (strcmp(argv[i], "--noalways-opt") == 0) {
// No support for stressing if we can't use --always-opt.
options.stress_opt = false;
options.stress_deopt = false;
} else if (strcmp(argv[i], "--shell") == 0) {
options.interactive_shell = true;
argv[i] = NULL;
} else if (strcmp(argv[i], "--test") == 0) {
options.test_shell = true;
argv[i] = NULL;
} else if (strcmp(argv[i], "--send-idle-notification") == 0) {
options.send_idle_notification = true;
argv[i] = NULL;
} else if (strcmp(argv[i], "--preemption") == 0) {
#ifdef V8_SHARED
printf("D8 with shared library does not support multi-threading\n");
return false;
#else
options.use_preemption = true;
argv[i] = NULL;
#endif // V8_SHARED
} else if (strcmp(argv[i], "--nopreemption") == 0) {
#ifdef V8_SHARED
printf("D8 with shared library does not support multi-threading\n");
return false;
#else
options.use_preemption = false;
argv[i] = NULL;
#endif // V8_SHARED
} else if (strcmp(argv[i], "--preemption-interval") == 0) {
#ifdef V8_SHARED
printf("D8 with shared library does not support multi-threading\n");
return false;
#else
if (++i < argc) {
argv[i-1] = NULL;
char* end = NULL;
options.preemption_interval = strtol(argv[i], &end, 10); // NOLINT
if (options.preemption_interval <= 0
|| *end != '\0'
|| errno == ERANGE) {
printf("Invalid value for --preemption-interval '%s'\n", argv[i]);
return false;
}
argv[i] = NULL;
} else {
printf("Missing value for --preemption-interval\n");
return false;
}
#endif // V8_SHARED
} else if (strcmp(argv[i], "-f") == 0) {
// Ignore any -f flags for compatibility with other stand-alone
// JavaScript engines.
continue;
} else if (strcmp(argv[i], "--isolate") == 0) {
#ifdef V8_SHARED
printf("D8 with shared library does not support multi-threading\n");
return false;
#endif // V8_SHARED
options.num_isolates++;
} else if (strcmp(argv[i], "-p") == 0) {
#ifdef V8_SHARED
printf("D8 with shared library does not support multi-threading\n");
return false;
#else
options.num_parallel_files++;
#endif // V8_SHARED
}
#ifdef V8_SHARED
else if (strcmp(argv[i], "--dump-counters") == 0) {
printf("D8 with shared library does not include counters\n");
return false;
} else if (strcmp(argv[i], "--debugger") == 0) {
printf("Javascript debugger not included\n");
return false;
}
#endif // V8_SHARED
}
#ifndef V8_SHARED
// Run parallel threads if we are not using --isolate
options.parallel_files = new char*[options.num_parallel_files];
int parallel_files_set = 0;
for (int i = 1; i < argc; i++) {
if (argv[i] == NULL) continue;
if (strcmp(argv[i], "-p") == 0 && i + 1 < argc) {
if (options.num_isolates > 1) {
printf("-p is not compatible with --isolate\n");
return false;
}
argv[i] = NULL;
i++;
options.parallel_files[parallel_files_set] = argv[i];
parallel_files_set++;
argv[i] = NULL;
}
}
if (parallel_files_set != options.num_parallel_files) {
printf("-p requires a file containing a list of files as parameter\n");
return false;
}
#endif // V8_SHARED
v8::V8::SetFlagsFromCommandLine(&argc, argv, true);
// Set up isolated source groups.
options.isolate_sources = new SourceGroup[options.num_isolates];
SourceGroup* current = options.isolate_sources;
current->Begin(argv, 1);
for (int i = 1; i < argc; i++) {
const char* str = argv[i];
if (strcmp(str, "--isolate") == 0) {
current->End(i);
current++;
current->Begin(argv, i + 1);
} else if (strncmp(argv[i], "--", 2) == 0) {
printf("Warning: unknown flag %s.\nTry --help for options\n", argv[i]);
}
}
current->End(argc);
return true;
}
int Shell::RunMain(Isolate* isolate, int argc, char* argv[]) {
#ifndef V8_SHARED
i::List<i::Thread*> threads(1);
if (options.parallel_files != NULL) {
for (int i = 0; i < options.num_parallel_files; i++) {
char* files = NULL;
{ Locker lock(isolate);
int size = 0;
files = ReadChars(isolate, options.parallel_files[i], &size);
}
if (files == NULL) {
printf("File list '%s' not found\n", options.parallel_files[i]);
Exit(1);
}
ShellThread* thread = new ShellThread(isolate, files);
thread->Start();
threads.Add(thread);
}
}
for (int i = 1; i < options.num_isolates; ++i) {
options.isolate_sources[i].StartExecuteInThread();
}
#endif // V8_SHARED
{ // NOLINT
Locker lock(isolate);
HandleScope scope(isolate);
Persistent<Context> context = CreateEvaluationContext(isolate);
if (options.last_run) {
// Keep using the same context in the interactive shell.
evaluation_context_ = context;
#if !defined(V8_SHARED) && defined(ENABLE_DEBUGGER_SUPPORT)
// If the interactive debugger is enabled make sure to activate
// it before running the files passed on the command line.
if (i::FLAG_debugger) {
InstallUtilityScript(isolate);
}
#endif // !V8_SHARED && ENABLE_DEBUGGER_SUPPORT
}
{
Context::Scope cscope(context);
options.isolate_sources[0].Execute(isolate);
}
if (!options.last_run) {
context.Dispose(isolate);
if (options.send_idle_notification) {
const int kLongIdlePauseInMs = 1000;
V8::ContextDisposedNotification();
V8::IdleNotification(kLongIdlePauseInMs);
}
}
#ifndef V8_SHARED
// Start preemption if threads have been created and preemption is enabled.
if (threads.length() > 0
&& options.use_preemption) {
Locker::StartPreemption(options.preemption_interval);
}
#endif // V8_SHARED
}
#ifndef V8_SHARED
for (int i = 1; i < options.num_isolates; ++i) {
options.isolate_sources[i].WaitForThread();
}
for (int i = 0; i < threads.length(); i++) {
i::Thread* thread = threads[i];
thread->Join();
delete thread;
}
if (threads.length() > 0 && options.use_preemption) {
Locker lock(isolate);
Locker::StopPreemption();
}
#endif // V8_SHARED
return 0;
}
int Shell::Main(int argc, char* argv[]) {
if (!SetOptions(argc, argv)) return 1;
int result = 0;
Isolate* isolate = Isolate::GetCurrent();
DumbLineEditor dumb_line_editor(isolate);
{
Initialize(isolate);
Symbols symbols(isolate);
InitializeDebugger(isolate);
if (options.stress_opt || options.stress_deopt) {
Testing::SetStressRunType(options.stress_opt
? Testing::kStressTypeOpt
: Testing::kStressTypeDeopt);
int stress_runs = Testing::GetStressRuns();
for (int i = 0; i < stress_runs && result == 0; i++) {
printf("============ Stress %d/%d ============\n", i + 1, stress_runs);
Testing::PrepareStressRun(i);
options.last_run = (i == stress_runs - 1);
result = RunMain(isolate, argc, argv);
}
printf("======== Full Deoptimization =======\n");
Testing::DeoptimizeAll();
#if !defined(V8_SHARED)
} else if (i::FLAG_stress_runs > 0) {
int stress_runs = i::FLAG_stress_runs;
for (int i = 0; i < stress_runs && result == 0; i++) {
printf("============ Run %d/%d ============\n", i + 1, stress_runs);
options.last_run = (i == stress_runs - 1);
result = RunMain(isolate, argc, argv);
}
#endif
} else {
result = RunMain(isolate, argc, argv);
}
#if !defined(V8_SHARED) && defined(ENABLE_DEBUGGER_SUPPORT)
// Run remote debugger if requested, but never on --test
if (i::FLAG_remote_debugger && !options.test_shell) {
InstallUtilityScript(isolate);
RunRemoteDebugger(isolate, i::FLAG_debugger_port);
return 0;
}
#endif // !V8_SHARED && ENABLE_DEBUGGER_SUPPORT
// Run interactive shell if explicitly requested or if no script has been
// executed, but never on --test
if (( options.interactive_shell || !options.script_executed )
&& !options.test_shell ) {
#if !defined(V8_SHARED) && defined(ENABLE_DEBUGGER_SUPPORT)
if (!i::FLAG_debugger) {
InstallUtilityScript(isolate);
}
#endif // !V8_SHARED && ENABLE_DEBUGGER_SUPPORT
RunShell(isolate);
}
}
V8::Dispose();
OnExit();
return result;
}
} // namespace v8
#ifndef GOOGLE3
int main(int argc, char* argv[]) {
return v8::Shell::Main(argc, argv);
}
#endif