Nagram/TMessagesProj/jni/webrtc/base/message_loop/message_pump_kqueue.cc

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2020-08-14 16:58:22 +00:00
// Copyright 2019 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "base/message_loop/message_pump_kqueue.h"
#include <sys/errno.h>
#include "base/auto_reset.h"
#include "base/logging.h"
#include "base/mac/mac_util.h"
#include "base/mac/mach_logging.h"
#include "base/mac/scoped_nsautorelease_pool.h"
#include "base/posix/eintr_wrapper.h"
namespace base {
namespace {
// Prior to macOS 10.12, a kqueue could not watch individual Mach ports, only
// port sets. MessagePumpKqueue will directly use Mach ports in the kqueue if
// it is possible.
bool KqueueNeedsPortSet() {
static bool kqueue_needs_port_set = mac::IsAtMostOS10_11();
return kqueue_needs_port_set;
}
int ChangeOneEvent(const ScopedFD& kqueue, kevent64_s* event) {
return HANDLE_EINTR(kevent64(kqueue.get(), event, 1, nullptr, 0, 0, nullptr));
}
} // namespace
MessagePumpKqueue::FdWatchController::FdWatchController(
const Location& from_here)
: FdWatchControllerInterface(from_here) {}
MessagePumpKqueue::FdWatchController::~FdWatchController() {
StopWatchingFileDescriptor();
}
bool MessagePumpKqueue::FdWatchController::StopWatchingFileDescriptor() {
if (!pump_)
return true;
return pump_->StopWatchingFileDescriptor(this);
}
void MessagePumpKqueue::FdWatchController::Init(WeakPtr<MessagePumpKqueue> pump,
int fd,
int mode,
FdWatcher* watcher) {
DCHECK_NE(fd, -1);
DCHECK(!watcher_);
DCHECK(watcher);
DCHECK(pump);
fd_ = fd;
mode_ = mode;
watcher_ = watcher;
pump_ = pump;
}
void MessagePumpKqueue::FdWatchController::Reset() {
fd_ = -1;
mode_ = 0;
watcher_ = nullptr;
pump_ = nullptr;
}
MessagePumpKqueue::MachPortWatchController::MachPortWatchController(
const Location& from_here)
: from_here_(from_here) {}
MessagePumpKqueue::MachPortWatchController::~MachPortWatchController() {
StopWatchingMachPort();
}
bool MessagePumpKqueue::MachPortWatchController::StopWatchingMachPort() {
if (!pump_)
return true;
return pump_->StopWatchingMachPort(this);
}
void MessagePumpKqueue::MachPortWatchController::Init(
WeakPtr<MessagePumpKqueue> pump,
mach_port_t port,
MachPortWatcher* watcher) {
DCHECK(!watcher_);
DCHECK(watcher);
DCHECK(pump);
port_ = port;
watcher_ = watcher;
pump_ = pump;
}
void MessagePumpKqueue::MachPortWatchController::Reset() {
port_ = MACH_PORT_NULL;
watcher_ = nullptr;
pump_ = nullptr;
}
MessagePumpKqueue::MessagePumpKqueue()
: kqueue_(kqueue()), weak_factory_(this) {
PCHECK(kqueue_.is_valid()) << "kqueue";
// Create a Mach port that will be used to wake up the pump by sending
// a message in response to ScheduleWork(). This is significantly faster than
// using an EVFILT_USER event, especially when triggered across threads.
kern_return_t kr = mach_port_allocate(
mach_task_self(), MACH_PORT_RIGHT_RECEIVE,
base::mac::ScopedMachReceiveRight::Receiver(wakeup_).get());
MACH_CHECK(kr == KERN_SUCCESS, kr) << "mach_port_allocate";
kevent64_s event{};
if (KqueueNeedsPortSet()) {
kr = mach_port_allocate(mach_task_self(), MACH_PORT_RIGHT_PORT_SET,
mac::ScopedMachPortSet::Receiver(port_set_).get());
MACH_CHECK(kr == KERN_SUCCESS, kr) << "mach_port_allocate PORT_SET";
kr = mach_port_insert_member(mach_task_self(), wakeup_.get(),
port_set_.get());
MACH_CHECK(kr == KERN_SUCCESS, kr) << "mach_port_insert_member";
event.ident = port_set_.get();
event.filter = EVFILT_MACHPORT;
event.flags = EV_ADD;
} else {
// When not using a port set, the wakeup port event can be specified to
// directly receive the Mach message as part of the kevent64() syscall.
// This is not done when using a port set, since that would potentially
// receive client MachPortWatchers' messages.
event.ident = wakeup_.get();
event.filter = EVFILT_MACHPORT;
event.flags = EV_ADD;
event.fflags = MACH_RCV_MSG;
event.ext[0] = reinterpret_cast<uint64_t>(&wakeup_buffer_);
event.ext[1] = sizeof(wakeup_buffer_);
}
int rv = ChangeOneEvent(kqueue_, &event);
PCHECK(rv == 0) << "kevent64";
}
MessagePumpKqueue::~MessagePumpKqueue() {}
void MessagePumpKqueue::Run(Delegate* delegate) {
AutoReset<bool> reset_keep_running(&keep_running_, true);
while (keep_running_) {
mac::ScopedNSAutoreleasePool pool;
bool do_more_work = DoInternalWork(nullptr);
if (!keep_running_)
break;
Delegate::NextWorkInfo next_work_info = delegate->DoSomeWork();
do_more_work |= next_work_info.is_immediate();
if (!keep_running_)
break;
if (do_more_work)
continue;
do_more_work |= delegate->DoIdleWork();
if (!keep_running_)
break;
if (do_more_work)
continue;
DoInternalWork(&next_work_info);
}
}
void MessagePumpKqueue::Quit() {
keep_running_ = false;
ScheduleWork();
}
void MessagePumpKqueue::ScheduleWork() {
mach_msg_empty_send_t message{};
message.header.msgh_size = sizeof(message);
message.header.msgh_bits =
MACH_MSGH_BITS_REMOTE(MACH_MSG_TYPE_MAKE_SEND_ONCE);
message.header.msgh_remote_port = wakeup_.get();
kern_return_t kr = mach_msg_send(&message.header);
if (kr != KERN_SUCCESS) {
// If ScheduleWork() is being called by other threads faster than the pump
// can dispatch work, the kernel message queue for the wakeup port can fill
// up (this happens under base_perftests, for example). The kernel does
// return a SEND_ONCE right in the case of failure, which must be destroyed
// to avoid leaking.
MACH_DLOG_IF(ERROR, (kr & ~MACH_MSG_IPC_SPACE) != MACH_SEND_NO_BUFFER, kr)
<< "mach_msg_send";
mach_msg_destroy(&message.header);
}
}
void MessagePumpKqueue::ScheduleDelayedWork(
const TimeTicks& delayed_work_time) {
// Nothing to do. This MessagePump uses DoSomeWork().
}
bool MessagePumpKqueue::WatchMachReceivePort(
mach_port_t port,
MachPortWatchController* controller,
MachPortWatcher* delegate) {
DCHECK(port != MACH_PORT_NULL);
DCHECK(controller);
DCHECK(delegate);
if (controller->port() != MACH_PORT_NULL) {
DLOG(ERROR)
<< "Cannot use the same MachPortWatchController while it is active";
return false;
}
if (KqueueNeedsPortSet()) {
kern_return_t kr =
mach_port_insert_member(mach_task_self(), port, port_set_.get());
if (kr != KERN_SUCCESS) {
MACH_LOG(ERROR, kr) << "mach_port_insert_member";
return false;
}
} else {
kevent64_s event{};
event.ident = port;
event.filter = EVFILT_MACHPORT;
event.flags = EV_ADD;
int rv = ChangeOneEvent(kqueue_, &event);
if (rv < 0) {
DPLOG(ERROR) << "kevent64";
return false;
}
++event_count_;
}
controller->Init(weak_factory_.GetWeakPtr(), port, delegate);
port_controllers_.AddWithID(controller, port);
return true;
}
bool MessagePumpKqueue::WatchFileDescriptor(int fd,
bool persistent,
int mode,
FdWatchController* controller,
FdWatcher* delegate) {
DCHECK_GE(fd, 0);
DCHECK(controller);
DCHECK(delegate);
DCHECK_NE(mode & Mode::WATCH_READ_WRITE, 0);
if (controller->fd() != -1 && controller->fd() != fd) {
DLOG(ERROR) << "Cannot use the same FdWatchController on two different FDs";
return false;
}
StopWatchingFileDescriptor(controller);
std::vector<kevent64_s> events;
kevent64_s base_event{};
base_event.ident = fd;
base_event.flags = EV_ADD | (!persistent ? EV_ONESHOT : 0);
if (mode & Mode::WATCH_READ) {
base_event.filter = EVFILT_READ;
base_event.udata = fd_controllers_.Add(controller);
events.push_back(base_event);
}
if (mode & Mode::WATCH_WRITE) {
base_event.filter = EVFILT_WRITE;
base_event.udata = fd_controllers_.Add(controller);
events.push_back(base_event);
}
int rv = HANDLE_EINTR(kevent64(kqueue_.get(), events.data(), events.size(),
nullptr, 0, 0, nullptr));
if (rv < 0) {
DPLOG(ERROR) << "WatchFileDescriptor kevent64";
return false;
}
event_count_ += events.size();
controller->Init(weak_factory_.GetWeakPtr(), fd, mode, delegate);
return true;
}
bool MessagePumpKqueue::StopWatchingMachPort(
MachPortWatchController* controller) {
mach_port_t port = controller->port();
controller->Reset();
port_controllers_.Remove(port);
if (KqueueNeedsPortSet()) {
kern_return_t kr =
mach_port_extract_member(mach_task_self(), port, port_set_.get());
if (kr != KERN_SUCCESS) {
MACH_LOG(ERROR, kr) << "mach_port_extract_member";
return false;
}
} else {
kevent64_s event{};
event.ident = port;
event.filter = EVFILT_MACHPORT;
event.flags = EV_DELETE;
--event_count_;
int rv = ChangeOneEvent(kqueue_, &event);
if (rv < 0) {
DPLOG(ERROR) << "kevent64";
return false;
}
}
return true;
}
bool MessagePumpKqueue::StopWatchingFileDescriptor(
FdWatchController* controller) {
int fd = controller->fd();
int mode = controller->mode();
controller->Reset();
if (fd == -1)
return true;
std::vector<kevent64_s> events;
kevent64_s base_event{};
base_event.ident = fd;
base_event.flags = EV_DELETE;
if (mode & Mode::WATCH_READ) {
base_event.filter = EVFILT_READ;
events.push_back(base_event);
}
if (mode & Mode::WATCH_WRITE) {
base_event.filter = EVFILT_WRITE;
events.push_back(base_event);
}
int rv = HANDLE_EINTR(kevent64(kqueue_.get(), events.data(), events.size(),
nullptr, 0, 0, nullptr));
DPLOG_IF(ERROR, rv < 0) << "StopWatchingFileDescriptor kevent64";
// The keys for the IDMap aren't recorded anywhere (they're attached to the
// kevent object in the kernel), so locate the entries by controller pointer.
for (auto it = IDMap<FdWatchController*>::iterator(&fd_controllers_);
!it.IsAtEnd(); it.Advance()) {
if (it.GetCurrentValue() == controller) {
fd_controllers_.Remove(it.GetCurrentKey());
}
}
event_count_ -= events.size();
return rv >= 0;
}
bool MessagePumpKqueue::DoInternalWork(Delegate::NextWorkInfo* next_work_info) {
if (events_.size() < event_count_) {
events_.resize(event_count_);
}
bool poll = next_work_info == nullptr;
int flags = poll ? KEVENT_FLAG_IMMEDIATE : 0;
bool indefinite =
next_work_info != nullptr && next_work_info->delayed_run_time.is_max();
int rv = 0;
do {
timespec timeout{};
if (!indefinite && !poll) {
if (rv != 0) {
// The wait was interrupted and made |next_work_info|'s view of
// TimeTicks::Now() stale. Refresh it before doing another wait.
next_work_info->recent_now = TimeTicks::Now();
}
timeout = next_work_info->remaining_delay().ToTimeSpec();
}
// This does not use HANDLE_EINTR, since retrying the syscall requires
// adjusting the timeout to account for time already waited.
rv = kevent64(kqueue_.get(), nullptr, 0, events_.data(), events_.size(),
flags, indefinite ? nullptr : &timeout);
} while (rv < 0 && errno == EINTR);
PCHECK(rv >= 0) << "kevent64";
return ProcessEvents(rv);
}
bool MessagePumpKqueue::ProcessEvents(int count) {
bool did_work = false;
for (int i = 0; i < count; ++i) {
auto* event = &events_[i];
if (event->filter == EVFILT_READ || event->filter == EVFILT_WRITE) {
did_work = true;
FdWatchController* controller = fd_controllers_.Lookup(event->udata);
if (!controller) {
// The controller was removed by some other work callout before
// this event could be processed.
continue;
}
FdWatcher* delegate = controller->watcher();
if (event->flags & EV_ONESHOT) {
// If this was a one-shot event, the Controller needs to stop tracking
// the descriptor, so it is not double-removed when it is told to stop
// watching.
controller->Reset();
fd_controllers_.Remove(event->udata);
--event_count_;
}
if (event->filter == EVFILT_READ) {
delegate->OnFileCanReadWithoutBlocking(event->ident);
} else if (event->filter == EVFILT_WRITE) {
delegate->OnFileCanWriteWithoutBlocking(event->ident);
}
} else if (event->filter == EVFILT_MACHPORT) {
mach_port_t port = KqueueNeedsPortSet() ? event->data : event->ident;
if (port == wakeup_.get()) {
// The wakeup event has been received, do not treat this as "doing
// work", this just wakes up the pump.
if (KqueueNeedsPortSet()) {
// When using the kqueue directly, the message can be received
// straight into a buffer that was created when adding the event.
// But when using a port set, the message must be drained manually.
wakeup_buffer_.header.msgh_local_port = port;
wakeup_buffer_.header.msgh_size = sizeof(wakeup_buffer_);
kern_return_t kr = mach_msg_receive(&wakeup_buffer_.header);
MACH_LOG_IF(ERROR, kr != KERN_SUCCESS, kr)
<< "mach_msg_receive wakeup";
}
continue;
}
did_work = true;
MachPortWatchController* controller = port_controllers_.Lookup(port);
// The controller could have been removed by some other work callout
// before this event could be processed.
if (controller) {
controller->watcher()->OnMachMessageReceived(port);
}
} else {
NOTREACHED() << "Unexpected event for filter " << event->filter;
}
}
return did_work;
}
} // namespace base