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#include "env.h"
#include "async_wrap.h"
#include "node_buffer.h"
#include "node_context_data.h"
#include "node_errors.h"
#include "node_file.h"
#include "node_internals.h"
#include "node_native_module.h"
#include "node_options-inl.h"
#include "node_platform.h"
#include "node_process.h"
#include "node_v8_platform-inl.h"
#include "node_worker.h"
#include "tracing/agent.h"
#include "tracing/traced_value.h"
#include "v8-profiler.h"
#include <algorithm>
#include <atomic>
#include <cstdio>
#include <memory>
namespace node {
using errors::TryCatchScope;
using v8::ArrayBuffer;
using v8::Boolean;
using v8::Context;
using v8::EmbedderGraph;
using v8::Function;
using v8::FunctionTemplate;
using v8::HandleScope;
using v8::Integer;
using v8::Isolate;
using v8::Local;
using v8::Message;
using v8::NewStringType;
using v8::Number;
using v8::Object;
using v8::Private;
using v8::StackFrame;
using v8::StackTrace;
using v8::String;
using v8::Symbol;
using v8::TracingController;
using v8::Undefined;
using v8::Value;
using worker::Worker;
int const Environment::kNodeContextTag = 0x6e6f64;
void* const Environment::kNodeContextTagPtr = const_cast<void*>(
static_cast<const void*>(&Environment::kNodeContextTag));
IsolateData::IsolateData(Isolate* isolate,
uv_loop_t* event_loop,
MultiIsolatePlatform* platform,
ArrayBufferAllocator* node_allocator)
: isolate_(isolate),
event_loop_(event_loop),
allocator_(isolate->GetArrayBufferAllocator()),
node_allocator_(node_allocator == nullptr ?
nullptr : node_allocator->GetImpl()),
uses_node_allocator_(allocator_ == node_allocator_),
platform_(platform) {
CHECK_NOT_NULL(allocator_);
options_.reset(
new PerIsolateOptions(*(per_process::cli_options->per_isolate)));
// Create string and private symbol properties as internalized one byte
// strings after the platform is properly initialized.
//
// Internalized because it makes property lookups a little faster and
// because the string is created in the old space straight away. It's going
// to end up in the old space sooner or later anyway but now it doesn't go
// through v8::Eternal's new space handling first.
//
// One byte because our strings are ASCII and we can safely skip V8's UTF-8
// decoding step.
#define V(PropertyName, StringValue) \
PropertyName ## _.Set( \
isolate, \
Private::New( \
isolate, \
String::NewFromOneByte( \
isolate, \
reinterpret_cast<const uint8_t*>(StringValue), \
NewStringType::kInternalized, \
sizeof(StringValue) - 1).ToLocalChecked()));
PER_ISOLATE_PRIVATE_SYMBOL_PROPERTIES(V)
#undef V
#define V(PropertyName, StringValue) \
PropertyName ## _.Set( \
isolate, \
Symbol::New( \
isolate, \
String::NewFromOneByte( \
isolate, \
reinterpret_cast<const uint8_t*>(StringValue), \
NewStringType::kInternalized, \
sizeof(StringValue) - 1).ToLocalChecked()));
PER_ISOLATE_SYMBOL_PROPERTIES(V)
#undef V
#define V(PropertyName, StringValue) \
PropertyName ## _.Set( \
isolate, \
String::NewFromOneByte( \
isolate, \
reinterpret_cast<const uint8_t*>(StringValue), \
NewStringType::kInternalized, \
sizeof(StringValue) - 1).ToLocalChecked());
PER_ISOLATE_STRING_PROPERTIES(V)
#undef V
}
void InitThreadLocalOnce() {
CHECK_EQ(0, uv_key_create(&Environment::thread_local_env));
}
void Environment::TrackingTraceStateObserver::UpdateTraceCategoryState() {
if (!env_->owns_process_state()) {
// Ideally, we’d have a consistent story that treats all threads/Environment
// instances equally here. However, tracing is essentially global, and this
// callback is called from whichever thread calls `StartTracing()` or
// `StopTracing()`. The only way to do this in a threadsafe fashion
// seems to be only tracking this from the main thread, and only allowing
// these state modifications from the main thread.
return;
}
bool async_hooks_enabled = (*(TRACE_EVENT_API_GET_CATEGORY_GROUP_ENABLED(
TRACING_CATEGORY_NODE1(async_hooks)))) != 0;
Isolate* isolate = env_->isolate();
HandleScope handle_scope(isolate);
Local<Function> cb = env_->trace_category_state_function();
if (cb.IsEmpty())
return;
TryCatchScope try_catch(env_);
try_catch.SetVerbose(true);
Local<Value> args[] = {Boolean::New(isolate, async_hooks_enabled)};
cb->Call(env_->context(), Undefined(isolate), arraysize(args), args)
.ToLocalChecked();
}
static std::atomic<uint64_t> next_thread_id{0};
uint64_t Environment::AllocateThreadId() {
return next_thread_id++;
}
Environment::Environment(IsolateData* isolate_data,
Local<Context> context,
Flags flags,
uint64_t thread_id)
: isolate_(context->GetIsolate()),
isolate_data_(isolate_data),
immediate_info_(context->GetIsolate()),
tick_info_(context->GetIsolate()),
timer_base_(uv_now(isolate_data->event_loop())),
should_abort_on_uncaught_toggle_(isolate_, 1),
stream_base_state_(isolate_, StreamBase::kNumStreamBaseStateFields),
flags_(flags),
thread_id_(thread_id == kNoThreadId ? AllocateThreadId() : thread_id),
fs_stats_field_array_(isolate_, kFsStatsBufferLength),
fs_stats_field_bigint_array_(isolate_, kFsStatsBufferLength),
context_(context->GetIsolate(), context) {
// We'll be creating new objects so make sure we've entered the context.
HandleScope handle_scope(isolate());
Context::Scope context_scope(context);
{
Local<FunctionTemplate> templ = FunctionTemplate::New(isolate());
templ->InstanceTemplate()->SetInternalFieldCount(1);
Local<Object> obj =
templ->GetFunction(context).ToLocalChecked()->NewInstance(
context).ToLocalChecked();
obj->SetAlignedPointerInInternalField(0, this);
set_as_callback_data(obj);
set_as_callback_data_template(templ);
}
// We create new copies of the per-Environment option sets, so that it is
// easier to modify them after Environment creation. The defaults are
// part of the per-Isolate option set, for which in turn the defaults are
// part of the per-process option set.
options_.reset(new EnvironmentOptions(*isolate_data->options()->per_env));
inspector_host_port_.reset(new HostPort(options_->debug_options().host_port));
#if HAVE_INSPECTOR
// We can only create the inspector agent after having cloned the options.
inspector_agent_ = std::make_unique<inspector::Agent>(this);
#endif
AssignToContext(context, ContextInfo(""));
if (tracing::AgentWriterHandle* writer = GetTracingAgentWriter()) {
trace_state_observer_ = std::make_unique<TrackingTraceStateObserver>(this);
TracingController* tracing_controller = writer->GetTracingController();
tracing_controller->AddTraceStateObserver(trace_state_observer_.get());
}
destroy_async_id_list_.reserve(512);
BeforeExit(
[](void* arg) {
Environment* env = static_cast<Environment*>(arg);
if (!env->destroy_async_id_list()->empty())
AsyncWrap::DestroyAsyncIdsCallback(env, nullptr);
},
this);
performance_state_ =
std::make_unique<performance::performance_state>(isolate());
performance_state_->Mark(
performance::NODE_PERFORMANCE_MILESTONE_ENVIRONMENT);
performance_state_->Mark(performance::NODE_PERFORMANCE_MILESTONE_NODE_START,
per_process::node_start_time);
performance_state_->Mark(
performance::NODE_PERFORMANCE_MILESTONE_V8_START,
performance::performance_v8_start);
// By default, always abort when --abort-on-uncaught-exception was passed.
should_abort_on_uncaught_toggle_[0] = 1;
std::string debug_cats;
credentials::SafeGetenv("NODE_DEBUG_NATIVE", &debug_cats);
set_debug_categories(debug_cats, true);
isolate()->GetHeapProfiler()->AddBuildEmbedderGraphCallback(
BuildEmbedderGraph, this);
if (options_->no_force_async_hooks_checks) {
async_hooks_.no_force_checks();
}
}
CompileFnEntry::CompileFnEntry(Environment* env, uint32_t id)
: env(env), id(id) {
env->compile_fn_entries.insert(this);
}
Environment::~Environment() {
isolate()->GetHeapProfiler()->RemoveBuildEmbedderGraphCallback(
BuildEmbedderGraph, this);
// Make sure there are no re-used libuv wrapper objects.
// CleanupHandles() should have removed all of them.
CHECK(file_handle_read_wrap_freelist_.empty());
// dispose the Persistent references to the compileFunction
// wrappers used in the dynamic import callback
for (auto& entry : compile_fn_entries) {
delete entry;
}
HandleScope handle_scope(isolate());
#if HAVE_INSPECTOR
// Destroy inspector agent before erasing the context. The inspector
// destructor depends on the context still being accessible.
inspector_agent_.reset();
#endif
context()->SetAlignedPointerInEmbedderData(
ContextEmbedderIndex::kEnvironment, nullptr);
if (trace_state_observer_) {
tracing::AgentWriterHandle* writer = GetTracingAgentWriter();
CHECK_NOT_NULL(writer);
TracingController* tracing_controller = writer->GetTracingController();
tracing_controller->RemoveTraceStateObserver(trace_state_observer_.get());
}
delete[] heap_statistics_buffer_;
delete[] heap_space_statistics_buffer_;
delete[] http_parser_buffer_;
TRACE_EVENT_NESTABLE_ASYNC_END0(
TRACING_CATEGORY_NODE1(environment), "Environment", this);
// Do not unload addons on the main thread. Some addons need to retain memory
// beyond the Environment's lifetime, and unloading them early would break
// them; with Worker threads, we have the opportunity to be stricter.
// Also, since the main thread usually stops just before the process exits,
// this is far less relevant here.
if (!is_main_thread()) {
// Dereference all addons that were loaded into this environment.
for (binding::DLib& addon : loaded_addons_) {
addon.Close();
}
}
}
void Environment::InitializeLibuv(bool start_profiler_idle_notifier) {
HandleScope handle_scope(isolate());
Context::Scope context_scope(context());
CHECK_EQ(0, uv_timer_init(event_loop(), timer_handle()));
uv_unref(reinterpret_cast<uv_handle_t*>(timer_handle()));
uv_check_init(event_loop(), immediate_check_handle());
uv_unref(reinterpret_cast<uv_handle_t*>(immediate_check_handle()));
uv_idle_init(event_loop(), immediate_idle_handle());
uv_check_start(immediate_check_handle(), CheckImmediate);
// Inform V8's CPU profiler when we're idle. The profiler is sampling-based
// but not all samples are created equal; mark the wall clock time spent in
// epoll_wait() and friends so profiling tools can filter it out. The samples
// still end up in v8.log but with state=IDLE rather than state=EXTERNAL.
// TODO(bnoordhuis) Depends on a libuv implementation detail that we should
// probably fortify in the API contract, namely that the last started prepare
// or check watcher runs first. It's not 100% foolproof; if an add-on starts
// a prepare or check watcher after us, any samples attributed to its callback
// will be recorded with state=IDLE.
uv_prepare_init(event_loop(), &idle_prepare_handle_);
uv_check_init(event_loop(), &idle_check_handle_);
uv_unref(reinterpret_cast<uv_handle_t*>(&idle_prepare_handle_));
uv_unref(reinterpret_cast<uv_handle_t*>(&idle_check_handle_));
thread_stopper()->Install(
this, static_cast<void*>(this), [](uv_async_t* handle) {
Environment* env = static_cast<Environment*>(handle->data);
uv_stop(env->event_loop());
});
thread_stopper()->set_stopped(false);
uv_unref(reinterpret_cast<uv_handle_t*>(thread_stopper()->GetHandle()));
// Register clean-up cb to be called to clean up the handles
// when the environment is freed, note that they are not cleaned in
// the one environment per process setup, but will be called in
// FreeEnvironment.
RegisterHandleCleanups();
if (start_profiler_idle_notifier) {
StartProfilerIdleNotifier();
}
static uv_once_t init_once = UV_ONCE_INIT;
uv_once(&init_once, InitThreadLocalOnce);
uv_key_set(&thread_local_env, this);
}
void Environment::ExitEnv() {
set_can_call_into_js(false);
thread_stopper()->Stop();
isolate_->TerminateExecution();
}
MaybeLocal<Object> Environment::ProcessCliArgs(
const std::vector<std::string>& args,
const std::vector<std::string>& exec_args) {
if (args.size() > 1) {
std::string first_arg = args[1];
if (first_arg == "inspect") {
execution_mode_ = ExecutionMode::kInspect;
} else if (first_arg == "debug") {
execution_mode_ = ExecutionMode::kDebug;
} else if (first_arg != "-") {
execution_mode_ = ExecutionMode::kRunMainModule;
}
}
if (*TRACE_EVENT_API_GET_CATEGORY_GROUP_ENABLED(
TRACING_CATEGORY_NODE1(environment)) != 0) {
auto traced_value = tracing::TracedValue::Create();
traced_value->BeginArray("args");
for (const std::string& arg : args) traced_value->AppendString(arg);
traced_value->EndArray();
traced_value->BeginArray("exec_args");
for (const std::string& arg : exec_args) traced_value->AppendString(arg);
traced_value->EndArray();
TRACE_EVENT_NESTABLE_ASYNC_BEGIN1(TRACING_CATEGORY_NODE1(environment),
"Environment",
this,
"args",
std::move(traced_value));
}
exec_argv_ = exec_args;
Local<Object> process_object =
node::CreateProcessObject(this, args, exec_args)
.FromMaybe(Local<Object>());
set_process_object(process_object);
return process_object;
}
void Environment::RegisterHandleCleanups() {
HandleCleanupCb close_and_finish = [](Environment* env, uv_handle_t* handle,
void* arg) {
handle->data = env;
env->CloseHandle(handle, [](uv_handle_t* handle) {
#ifdef DEBUG
memset(handle, 0xab, uv_handle_size(handle->type));
#endif
});
};
RegisterHandleCleanup(
reinterpret_cast<uv_handle_t*>(timer_handle()),
close_and_finish,
nullptr);
RegisterHandleCleanup(
reinterpret_cast<uv_handle_t*>(immediate_check_handle()),
close_and_finish,
nullptr);
RegisterHandleCleanup(
reinterpret_cast<uv_handle_t*>(immediate_idle_handle()),
close_and_finish,
nullptr);
RegisterHandleCleanup(
reinterpret_cast<uv_handle_t*>(&idle_prepare_handle_),
close_and_finish,
nullptr);
RegisterHandleCleanup(
reinterpret_cast<uv_handle_t*>(&idle_check_handle_),
close_and_finish,
nullptr);
}
void Environment::CleanupHandles() {
for (ReqWrapBase* request : req_wrap_queue_)
request->Cancel();
for (HandleWrap* handle : handle_wrap_queue_)
handle->Close();
for (HandleCleanup& hc : handle_cleanup_queue_)
hc.cb_(this, hc.handle_, hc.arg_);
handle_cleanup_queue_.clear();
while (handle_cleanup_waiting_ != 0 ||
request_waiting_ != 0 ||
!handle_wrap_queue_.IsEmpty()) {
uv_run(event_loop(), UV_RUN_ONCE);
}
file_handle_read_wrap_freelist_.clear();
}
void Environment::StartProfilerIdleNotifier() {
if (profiler_idle_notifier_started_)
return;
profiler_idle_notifier_started_ = true;
uv_prepare_start(&idle_prepare_handle_, [](uv_prepare_t* handle) {
Environment* env = ContainerOf(&Environment::idle_prepare_handle_, handle);
env->isolate()->SetIdle(true);
});
uv_check_start(&idle_check_handle_, [](uv_check_t* handle) {
Environment* env = ContainerOf(&Environment::idle_check_handle_, handle);
env->isolate()->SetIdle(false);
});
}
void Environment::StopProfilerIdleNotifier() {
profiler_idle_notifier_started_ = false;
uv_prepare_stop(&idle_prepare_handle_);
uv_check_stop(&idle_check_handle_);
}
void Environment::PrintSyncTrace() const {
if (!options_->trace_sync_io)
return;
HandleScope handle_scope(isolate());
Local<StackTrace> stack =
StackTrace::CurrentStackTrace(isolate(), 10, StackTrace::kDetailed);
fprintf(stderr, "(node:%d) WARNING: Detected use of sync API\n",
uv_os_getpid());
for (int i = 0; i < stack->GetFrameCount() - 1; i++) {
Local<StackFrame> stack_frame = stack->GetFrame(isolate(), i);
node::Utf8Value fn_name_s(isolate(), stack_frame->GetFunctionName());
node::Utf8Value script_name(isolate(), stack_frame->GetScriptName());
const int line_number = stack_frame->GetLineNumber();
const int column = stack_frame->GetColumn();
if (stack_frame->IsEval()) {
if (stack_frame->GetScriptId() == Message::kNoScriptIdInfo) {
fprintf(stderr, " at [eval]:%i:%i\n", line_number, column);
} else {
fprintf(stderr,
" at [eval] (%s:%i:%i)\n",
*script_name,
line_number,
column);
}
break;
}
if (fn_name_s.length() == 0) {
fprintf(stderr, " at %s:%i:%i\n", *script_name, line_number, column);
} else {
fprintf(stderr,
" at %s (%s:%i:%i)\n",
*fn_name_s,
*script_name,
line_number,
column);
}
}
fflush(stderr);
}
void Environment::RunCleanup() {
started_cleanup_ = true;
TraceEventScope trace_scope(TRACING_CATEGORY_NODE1(environment),
"RunCleanup", this);
thread_stopper()->Uninstall();
CleanupHandles();
while (!cleanup_hooks_.empty()) {
// Copy into a vector, since we can't sort an unordered_set in-place.
std::vector<CleanupHookCallback> callbacks(
cleanup_hooks_.begin(), cleanup_hooks_.end());
// We can't erase the copied elements from `cleanup_hooks_` yet, because we
// need to be able to check whether they were un-scheduled by another hook.
std::sort(callbacks.begin(), callbacks.end(),
[](const CleanupHookCallback& a, const CleanupHookCallback& b) {
// Sort in descending order so that the most recently inserted callbacks
// are run first.
return a.insertion_order_counter_ > b.insertion_order_counter_;
});
for (const CleanupHookCallback& cb : callbacks) {
if (cleanup_hooks_.count(cb) == 0) {
// This hook was removed from the `cleanup_hooks_` set during another
// hook that was run earlier. Nothing to do here.
continue;
}
cb.fn_(cb.arg_);
cleanup_hooks_.erase(cb);
}
CleanupHandles();
}
}
void Environment::RunBeforeExitCallbacks() {
TraceEventScope trace_scope(TRACING_CATEGORY_NODE1(environment),
"BeforeExit", this);
for (ExitCallback before_exit : before_exit_functions_) {
before_exit.cb_(before_exit.arg_);
}
before_exit_functions_.clear();
}
void Environment::BeforeExit(void (*cb)(void* arg), void* arg) {
before_exit_functions_.push_back(ExitCallback{cb, arg});
}
void Environment::RunAtExitCallbacks() {
TraceEventScope trace_scope(TRACING_CATEGORY_NODE1(environment),
"AtExit", this);
for (ExitCallback at_exit : at_exit_functions_) {
at_exit.cb_(at_exit.arg_);
}
at_exit_functions_.clear();
}
void Environment::AtExit(void (*cb)(void* arg), void* arg) {
at_exit_functions_.push_back(ExitCallback{cb, arg});
}
void Environment::RunAndClearNativeImmediates() {
TraceEventScope trace_scope(TRACING_CATEGORY_NODE1(environment),
"RunAndClearNativeImmediates", this);
size_t count = native_immediate_callbacks_.size();
if (count > 0) {
size_t ref_count = 0;
std::vector<NativeImmediateCallback> list;
native_immediate_callbacks_.swap(list);
auto drain_list = [&]() {
TryCatchScope try_catch(this);
for (auto it = list.begin(); it != list.end(); ++it) {
DebugSealHandleScope seal_handle_scope(isolate());
it->cb_(this, it->data_);
if (it->refed_)
ref_count++;
if (UNLIKELY(try_catch.HasCaught())) {
if (!try_catch.HasTerminated())
FatalException(isolate(), try_catch);
// Bail out, remove the already executed callbacks from list
// and set up a new TryCatch for the other pending callbacks.
std::move_backward(it, list.end(), list.begin() + (list.end() - it));
list.resize(list.end() - it);
return true;
}
}
return false;
};
while (drain_list()) {}
DCHECK_GE(immediate_info()->count(), count);
immediate_info()->count_dec(count);
immediate_info()->ref_count_dec(ref_count);
}
}
void Environment::ScheduleTimer(int64_t duration_ms) {
if (started_cleanup_) return;
uv_timer_start(timer_handle(), RunTimers, duration_ms, 0);
}
void Environment::ToggleTimerRef(bool ref) {
if (started_cleanup_) return;
if (ref) {
uv_ref(reinterpret_cast<uv_handle_t*>(timer_handle()));
} else {
uv_unref(reinterpret_cast<uv_handle_t*>(timer_handle()));
}
}
void Environment::RunTimers(uv_timer_t* handle) {
Environment* env = Environment::from_timer_handle(handle);
TraceEventScope trace_scope(TRACING_CATEGORY_NODE1(environment),
"RunTimers", env);
if (!env->can_call_into_js())
return;
HandleScope handle_scope(env->isolate());
Context::Scope context_scope(env->context());
Local<Object> process = env->process_object();
InternalCallbackScope scope(env, process, {0, 0});
Local<Function> cb = env->timers_callback_function();
MaybeLocal<Value> ret;
Local<Value> arg = env->GetNow();
// This code will loop until all currently due timers will process. It is
// impossible for us to end up in an infinite loop due to how the JS-side
// is structured.
do {
TryCatchScope try_catch(env);
try_catch.SetVerbose(true);
ret = cb->Call(env->context(), process, 1, &arg);
} while (ret.IsEmpty() && env->can_call_into_js());
// NOTE(apapirovski): If it ever becomes possible that `call_into_js` above
// is reset back to `true` after being previously set to `false` then this
// code becomes invalid and needs to be rewritten. Otherwise catastrophic
// timers corruption will occur and all timers behaviour will become
// entirely unpredictable.
if (ret.IsEmpty())
return;
// To allow for less JS-C++ boundary crossing, the value returned from JS
// serves a few purposes:
// 1. If it's 0, no more timers exist and the handle should be unrefed
// 2. If it's > 0, the value represents the next timer's expiry and there
// is at least one timer remaining that is refed.
// 3. If it's < 0, the absolute value represents the next timer's expiry
// and there are no timers that are refed.
int64_t expiry_ms =
ret.ToLocalChecked()->IntegerValue(env->context()).FromJust();
uv_handle_t* h = reinterpret_cast<uv_handle_t*>(handle);
if (expiry_ms != 0) {
int64_t duration_ms =
llabs(expiry_ms) - (uv_now(env->event_loop()) - env->timer_base());
env->ScheduleTimer(duration_ms > 0 ? duration_ms : 1);
if (expiry_ms > 0)
uv_ref(h);
else
uv_unref(h);
} else {
uv_unref(h);
}
}
void Environment::CheckImmediate(uv_check_t* handle) {
Environment* env = Environment::from_immediate_check_handle(handle);
TraceEventScope trace_scope(TRACING_CATEGORY_NODE1(environment),
"CheckImmediate", env);
if (env->immediate_info()->count() == 0)
return;
HandleScope scope(env->isolate());
Context::Scope context_scope(env->context());
env->RunAndClearNativeImmediates();
if (!env->can_call_into_js())
return;
do {
MakeCallback(env->isolate(),
env->process_object(),
env->immediate_callback_function(),
0,
nullptr,
{0, 0}).ToLocalChecked();
} while (env->immediate_info()->has_outstanding() && env->can_call_into_js());
if (env->immediate_info()->ref_count() == 0)
env->ToggleImmediateRef(false);
}
void Environment::ToggleImmediateRef(bool ref) {
if (started_cleanup_) return;
if (ref) {
// Idle handle is needed only to stop the event loop from blocking in poll.
uv_idle_start(immediate_idle_handle(), [](uv_idle_t*){ });
} else {
uv_idle_stop(immediate_idle_handle());
}
}
Local<Value> Environment::GetNow() {
uv_update_time(event_loop());
uint64_t now = uv_now(event_loop());
CHECK_GE(now, timer_base());
now -= timer_base();
if (now <= 0xffffffff)
return Integer::NewFromUnsigned(isolate(), static_cast<uint32_t>(now));
else
return Number::New(isolate(), static_cast<double>(now));
}
void Environment::set_debug_categories(const std::string& cats, bool enabled) {
std::string debug_categories = cats;
while (!debug_categories.empty()) {
std::string::size_type comma_pos = debug_categories.find(',');
std::string wanted = ToLower(debug_categories.substr(0, comma_pos));
#define V(name) \
{ \
static const std::string available_category = ToLower(#name); \
if (available_category.find(wanted) != std::string::npos) \
set_debug_enabled(DebugCategory::name, enabled); \
}
DEBUG_CATEGORY_NAMES(V)
if (comma_pos == std::string::npos)
break;
// Use everything after the `,` as the list for the next iteration.
debug_categories = debug_categories.substr(comma_pos + 1);
}
}
void CollectExceptionInfo(Environment* env,
Local<Object> obj,
int errorno,
const char* err_string,
const char* syscall,
const char* message,
const char* path,
const char* dest) {
obj->Set(env->context(),
env->errno_string(),
Integer::New(env->isolate(), errorno)).FromJust();
obj->Set(env->context(), env->code_string(),
OneByteString(env->isolate(), err_string)).FromJust();
if (message != nullptr) {
obj->Set(env->context(), env->message_string(),
OneByteString(env->isolate(), message)).FromJust();
}
Local<Value> path_buffer;
if (path != nullptr) {
path_buffer =
Buffer::Copy(env->isolate(), path, strlen(path)).ToLocalChecked();
obj->Set(env->context(), env->path_string(), path_buffer).FromJust();
}
Local<Value> dest_buffer;
if (dest != nullptr) {
dest_buffer =
Buffer::Copy(env->isolate(), dest, strlen(dest)).ToLocalChecked();
obj->Set(env->context(), env->dest_string(), dest_buffer).FromJust();
}
if (syscall != nullptr) {
obj->Set(env->context(), env->syscall_string(),
OneByteString(env->isolate(), syscall)).FromJust();
}
}
void Environment::CollectUVExceptionInfo(Local<Value> object,
int errorno,
const char* syscall,
const char* message,
const char* path,
const char* dest) {
if (!object->IsObject() || errorno == 0)
return;
Local<Object> obj = object.As<Object>();
const char* err_string = uv_err_name(errorno);
if (message == nullptr || message[0] == '\0') {
message = uv_strerror(errorno);
}
node::CollectExceptionInfo(this, obj, errorno, err_string,
syscall, message, path, dest);
}
void Environment::AsyncHooks::grow_async_ids_stack() {
async_ids_stack_.reserve(async_ids_stack_.Length() * 3);
env()->async_hooks_binding()->Set(
env()->context(),
env()->async_ids_stack_string(),
async_ids_stack_.GetJSArray()).FromJust();
}
uv_key_t Environment::thread_local_env = {};
void Environment::Exit(int exit_code) {
if (is_main_thread()) {
stop_sub_worker_contexts();
DisposePlatform();
exit(exit_code);
} else {
worker_context_->Exit(exit_code);
}
}
void Environment::stop_sub_worker_contexts() {
while (!sub_worker_contexts_.empty()) {
Worker* w = *sub_worker_contexts_.begin();
remove_sub_worker_context(w);
w->Exit(1);
w->JoinThread();
}
}
void Environment::BuildEmbedderGraph(Isolate* isolate,
EmbedderGraph* graph,
void* data) {
MemoryTracker tracker(isolate, graph);
static_cast<Environment*>(data)->ForEachBaseObject([&](BaseObject* obj) {
tracker.Track(obj);
});
}
char* Environment::Reallocate(char* data, size_t old_size, size_t size) {
if (old_size == size) return data;
// If we know that the allocator is our ArrayBufferAllocator, we can let
// if reallocate directly.
if (isolate_data()->uses_node_allocator()) {
return static_cast<char*>(
isolate_data()->node_allocator()->Reallocate(data, old_size, size));
}
// Generic allocators do not provide a reallocation method; we need to
// allocate a new chunk of memory and copy the data over.
char* new_data = AllocateUnchecked(size);
if (new_data == nullptr) return nullptr;
memcpy(new_data, data, std::min(size, old_size));
if (size > old_size)
memset(new_data + old_size, 0, size - old_size);
Free(data, old_size);
return new_data;
}
void AsyncRequest::Install(Environment* env, void* data, uv_async_cb target) {
CHECK_NULL(async_);
env_ = env;
async_ = new uv_async_t;
async_->data = data;
CHECK_EQ(uv_async_init(env_->event_loop(), async_, target), 0);
}
void AsyncRequest::Uninstall() {
if (async_ != nullptr) {
env_->CloseHandle(async_, [](uv_async_t* async) { delete async; });
async_ = nullptr;
}
}
void AsyncRequest::Stop() {
set_stopped(true);
if (async_ != nullptr) uv_async_send(async_);
}
uv_async_t* AsyncRequest::GetHandle() {
return async_;
}
void AsyncRequest::MemoryInfo(MemoryTracker* tracker) const {
if (async_ != nullptr) tracker->TrackField("async_request", *async_);
}
AsyncRequest::~AsyncRequest() {
CHECK_NULL(async_);
}
// Not really any better place than env.cc at this moment.
void BaseObject::DeleteMe(void* data) {
BaseObject* self = static_cast<BaseObject*>(data);
delete self;
}
Local<Object> BaseObject::WrappedObject() const {
return object();
}
bool BaseObject::IsRootNode() const {
return !persistent_handle_.IsWeak();
}
} // namespace node
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