Rocket.Chat.ReactNative/ios/Pods/Flipper-Folly/folly/io/async/AsyncServerSocket.cpp

1188 lines
36 KiB
C++

/*
* Copyright (c) Facebook, Inc. and its affiliates.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef __STDC_FORMAT_MACROS
#define __STDC_FORMAT_MACROS
#endif
#include <folly/io/async/AsyncServerSocket.h>
#include <folly/FileUtil.h>
#include <folly/Portability.h>
#include <folly/SocketAddress.h>
#include <folly/String.h>
#include <folly/detail/SocketFastOpen.h>
#include <folly/io/async/EventBase.h>
#include <folly/io/async/NotificationQueue.h>
#include <folly/portability/Fcntl.h>
#include <folly/portability/Sockets.h>
#include <folly/portability/Unistd.h>
#include <sys/types.h>
#include <cerrno>
#include <cstring>
namespace folly {
#ifndef TCP_SAVE_SYN
#define TCP_SAVE_SYN 27
#endif
#ifndef TCP_SAVED_SYN
#define TCP_SAVED_SYN 28
#endif
static constexpr bool msgErrQueueSupported =
#ifdef FOLLY_HAVE_MSG_ERRQUEUE
true;
#else
false;
#endif // FOLLY_HAVE_MSG_ERRQUEUE
const uint32_t AsyncServerSocket::kDefaultMaxAcceptAtOnce;
const uint32_t AsyncServerSocket::kDefaultCallbackAcceptAtOnce;
const uint32_t AsyncServerSocket::kDefaultMaxMessagesInQueue;
void AsyncServerSocket::RemoteAcceptor::start(
EventBase* eventBase,
uint32_t maxAtOnce,
uint32_t maxInQueue) {
setMaxReadAtOnce(maxAtOnce);
queue_.setMaxQueueSize(maxInQueue);
eventBase->runInEventBaseThread([=]() {
callback_->acceptStarted();
this->startConsuming(eventBase, &queue_);
});
}
void AsyncServerSocket::RemoteAcceptor::stop(
EventBase* eventBase,
AcceptCallback* callback) {
eventBase->runInEventBaseThread([=]() {
callback->acceptStopped();
delete this;
});
}
void AsyncServerSocket::RemoteAcceptor::messageAvailable(
QueueMessage&& msg) noexcept {
switch (msg.type) {
case MessageType::MSG_NEW_CONN: {
if (connectionEventCallback_) {
connectionEventCallback_->onConnectionDequeuedByAcceptorCallback(
msg.fd, msg.address);
}
callback_->connectionAccepted(msg.fd, msg.address);
break;
}
case MessageType::MSG_ERROR: {
std::runtime_error ex(msg.msg);
callback_->acceptError(ex);
break;
}
default: {
LOG(ERROR) << "invalid accept notification message type "
<< int(msg.type);
std::runtime_error ex(
"received invalid accept notification message type");
callback_->acceptError(ex);
}
}
}
/*
* AsyncServerSocket::BackoffTimeout
*/
class AsyncServerSocket::BackoffTimeout : public AsyncTimeout {
public:
// Disallow copy, move, and default constructors.
BackoffTimeout(BackoffTimeout&&) = delete;
explicit BackoffTimeout(AsyncServerSocket* socket)
: AsyncTimeout(socket->getEventBase()), socket_(socket) {}
void timeoutExpired() noexcept override {
socket_->backoffTimeoutExpired();
}
private:
AsyncServerSocket* socket_;
};
/*
* AsyncServerSocket methods
*/
AsyncServerSocket::AsyncServerSocket(EventBase* eventBase)
: eventBase_(eventBase),
accepting_(false),
maxAcceptAtOnce_(kDefaultMaxAcceptAtOnce),
maxNumMsgsInQueue_(kDefaultMaxMessagesInQueue),
acceptRateAdjustSpeed_(0),
acceptRate_(1),
lastAccepTimestamp_(std::chrono::steady_clock::now()),
numDroppedConnections_(0),
callbackIndex_(0),
backoffTimeout_(nullptr),
callbacks_(),
keepAliveEnabled_(true),
closeOnExec_(true) {
disableTransparentTls();
}
void AsyncServerSocket::setShutdownSocketSet(
const std::weak_ptr<ShutdownSocketSet>& wNewSS) {
const auto newSS = wNewSS.lock();
const auto shutdownSocketSet = wShutdownSocketSet_.lock();
if (shutdownSocketSet == newSS) {
return;
}
if (shutdownSocketSet) {
for (auto& h : sockets_) {
shutdownSocketSet->remove(h.socket_);
}
}
if (newSS) {
for (auto& h : sockets_) {
newSS->add(h.socket_);
}
}
wShutdownSocketSet_ = wNewSS;
}
AsyncServerSocket::~AsyncServerSocket() {
assert(callbacks_.empty());
}
int AsyncServerSocket::stopAccepting(int shutdownFlags) {
int result = 0;
for (auto& handler : sockets_) {
VLOG(10) << "AsyncServerSocket::stopAccepting " << this << handler.socket_;
}
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
// When destroy is called, unregister and close the socket immediately.
accepting_ = false;
// Close the sockets in reverse order as they were opened to avoid
// the condition where another process concurrently tries to open
// the same port, succeed to bind the first socket but fails on the
// second because it hasn't been closed yet.
for (; !sockets_.empty(); sockets_.pop_back()) {
auto& handler = sockets_.back();
handler.unregisterHandler();
if (const auto shutdownSocketSet = wShutdownSocketSet_.lock()) {
shutdownSocketSet->close(handler.socket_);
} else if (shutdownFlags >= 0) {
result = shutdownNoInt(handler.socket_, shutdownFlags);
pendingCloseSockets_.push_back(handler.socket_);
} else {
closeNoInt(handler.socket_);
}
}
// Destroy the backoff timout. This will cancel it if it is running.
delete backoffTimeout_;
backoffTimeout_ = nullptr;
// Close all of the callback queues to notify them that they are being
// destroyed. No one should access the AsyncServerSocket any more once
// destroy() is called. However, clear out callbacks_ before invoking the
// accept callbacks just in case. This will potentially help us detect the
// bug if one of the callbacks calls addAcceptCallback() or
// removeAcceptCallback().
std::vector<CallbackInfo> callbacksCopy;
callbacks_.swap(callbacksCopy);
for (const auto& callback : callbacksCopy) {
// consumer may not be set if we are running in primary event base
if (callback.consumer) {
DCHECK(callback.eventBase);
callback.consumer->stop(callback.eventBase, callback.callback);
} else {
DCHECK(callback.callback);
callback.callback->acceptStopped();
}
}
return result;
}
void AsyncServerSocket::destroy() {
stopAccepting();
for (auto s : pendingCloseSockets_) {
closeNoInt(s);
}
// Then call DelayedDestruction::destroy() to take care of
// whether or not we need immediate or delayed destruction
DelayedDestruction::destroy();
}
void AsyncServerSocket::attachEventBase(EventBase* eventBase) {
assert(eventBase_ == nullptr);
eventBase->dcheckIsInEventBaseThread();
eventBase_ = eventBase;
for (auto& handler : sockets_) {
handler.attachEventBase(eventBase);
}
}
void AsyncServerSocket::detachEventBase() {
assert(eventBase_ != nullptr);
eventBase_->dcheckIsInEventBaseThread();
assert(!accepting_);
eventBase_ = nullptr;
for (auto& handler : sockets_) {
handler.detachEventBase();
}
}
void AsyncServerSocket::useExistingSockets(
const std::vector<NetworkSocket>& fds) {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
if (!sockets_.empty()) {
throw std::invalid_argument(
"cannot call useExistingSocket() on a "
"AsyncServerSocket that already has a socket");
}
for (auto fd : fds) {
// Set addressFamily_ from this socket.
// Note that the socket may not have been bound yet, but
// setFromLocalAddress() will still work and get the correct address family.
// We will update addressFamily_ again anyway if bind() is called later.
SocketAddress address;
address.setFromLocalAddress(fd);
#if defined(__linux__)
if (noTransparentTls_) {
// Ignore return value, errors are ok
netops::setsockopt(fd, SOL_SOCKET, SO_NO_TRANSPARENT_TLS, nullptr, 0);
}
#endif
setupSocket(fd, address.getFamily());
sockets_.emplace_back(eventBase_, fd, this, address.getFamily());
sockets_.back().changeHandlerFD(fd);
}
}
void AsyncServerSocket::useExistingSocket(NetworkSocket fd) {
useExistingSockets({fd});
}
void AsyncServerSocket::bindSocket(
NetworkSocket fd,
const SocketAddress& address,
bool isExistingSocket) {
sockaddr_storage addrStorage;
address.getAddress(&addrStorage);
auto saddr = reinterpret_cast<sockaddr*>(&addrStorage);
if (netops::bind(fd, saddr, address.getActualSize()) != 0) {
if (errno != EINPROGRESS) {
// Get a copy of errno so that it is not overwritten by subsequent calls.
auto errnoCopy = errno;
if (!isExistingSocket) {
closeNoInt(fd);
}
folly::throwSystemErrorExplicit(
errnoCopy,
"failed to bind to async server socket: " + address.describe());
}
}
#if defined(__linux__)
if (noTransparentTls_) {
// Ignore return value, errors are ok
netops::setsockopt(fd, SOL_SOCKET, SO_NO_TRANSPARENT_TLS, nullptr, 0);
}
#endif
// If we just created this socket, update the EventHandler and set socket_
if (!isExistingSocket) {
sockets_.emplace_back(eventBase_, fd, this, address.getFamily());
}
}
bool AsyncServerSocket::setZeroCopy(bool enable) {
if (msgErrQueueSupported) {
// save the enable flag here
zeroCopyVal_ = enable;
int val = enable ? 1 : 0;
size_t num = 0;
for (auto& s : sockets_) {
int ret = netops::setsockopt(
s.socket_, SOL_SOCKET, SO_ZEROCOPY, &val, sizeof(val));
num += (0 == ret) ? 1 : 0;
}
return num != 0;
}
return false;
}
void AsyncServerSocket::bind(const SocketAddress& address) {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
// useExistingSocket() may have been called to initialize socket_ already.
// However, in the normal case we need to create a new socket now.
// Don't set socket_ yet, so that socket_ will remain uninitialized if an
// error occurs.
NetworkSocket fd;
if (sockets_.empty()) {
fd = createSocket(address.getFamily());
} else if (sockets_.size() == 1) {
if (address.getFamily() != sockets_[0].addressFamily_) {
throw std::invalid_argument(
"Attempted to bind address to socket with "
"different address family");
}
fd = sockets_[0].socket_;
} else {
throw std::invalid_argument("Attempted to bind to multiple fds");
}
bindSocket(fd, address, !sockets_.empty());
}
void AsyncServerSocket::bind(
const std::vector<IPAddress>& ipAddresses,
uint16_t port) {
if (ipAddresses.empty()) {
throw std::invalid_argument("No ip addresses were provided");
}
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
for (const IPAddress& ipAddress : ipAddresses) {
SocketAddress address(ipAddress.toFullyQualified(), port);
auto fd = createSocket(address.getFamily());
bindSocket(fd, address, false);
}
if (sockets_.empty()) {
throw std::runtime_error(
"did not bind any async server socket for port and addresses");
}
}
void AsyncServerSocket::bind(uint16_t port) {
struct addrinfo hints, *res0;
char sport[sizeof("65536")];
memset(&hints, 0, sizeof(hints));
hints.ai_family = AF_UNSPEC;
hints.ai_socktype = SOCK_STREAM;
hints.ai_flags = AI_PASSIVE | AI_NUMERICSERV;
snprintf(sport, sizeof(sport), "%u", port);
// On Windows the value we need to pass to bind to all available
// addresses is an empty string. Everywhere else, it's nullptr.
constexpr const char* kWildcardNode = kIsWindows ? "" : nullptr;
if (getaddrinfo(kWildcardNode, sport, &hints, &res0)) {
throw std::invalid_argument(
"Attempted to bind address to socket with "
"bad getaddrinfo");
}
SCOPE_EXIT {
freeaddrinfo(res0);
};
auto setupAddress = [&](struct addrinfo* res) {
auto s = netops::socket(res->ai_family, res->ai_socktype, res->ai_protocol);
// IPv6/IPv4 may not be supported by the kernel
if (s == NetworkSocket() && errno == EAFNOSUPPORT) {
return;
}
CHECK_NE(s, NetworkSocket());
try {
setupSocket(s, res->ai_family);
} catch (...) {
closeNoInt(s);
throw;
}
if (res->ai_family == AF_INET6) {
int v6only = 1;
CHECK(
0 ==
netops::setsockopt(
s, IPPROTO_IPV6, IPV6_V6ONLY, &v6only, sizeof(v6only)));
}
// Bind to the socket
if (netops::bind(s, res->ai_addr, socklen_t(res->ai_addrlen)) != 0) {
folly::throwSystemError(
errno,
"failed to bind to async server socket for port ",
SocketAddress::getPortFrom(res->ai_addr),
" family ",
SocketAddress::getFamilyNameFrom(res->ai_addr, "<unknown>"));
}
#if defined(__linux__)
if (noTransparentTls_) {
// Ignore return value, errors are ok
netops::setsockopt(s, SOL_SOCKET, SO_NO_TRANSPARENT_TLS, nullptr, 0);
}
#endif
SocketAddress address;
address.setFromLocalAddress(s);
sockets_.emplace_back(eventBase_, s, this, address.getFamily());
};
const int kNumTries = 25;
for (int tries = 1; true; tries++) {
// Prefer AF_INET6 addresses. RFC 3484 mandates that getaddrinfo
// should return IPv6 first and then IPv4 addresses, but glibc's
// getaddrinfo(nullptr) with AI_PASSIVE returns:
// - 0.0.0.0 (IPv4-only)
// - :: (IPv6+IPv4) in this order
// See: https://sourceware.org/bugzilla/show_bug.cgi?id=9981
for (struct addrinfo* res = res0; res; res = res->ai_next) {
if (res->ai_family == AF_INET6) {
setupAddress(res);
}
}
// If port == 0, then we should try to bind to the same port on ipv4 and
// ipv6. So if we did bind to ipv6, figure out that port and use it.
if (sockets_.size() == 1 && port == 0) {
SocketAddress address;
address.setFromLocalAddress(sockets_.back().socket_);
snprintf(sport, sizeof(sport), "%u", address.getPort());
freeaddrinfo(res0);
CHECK_EQ(0, getaddrinfo(nullptr, sport, &hints, &res0));
}
try {
for (struct addrinfo* res = res0; res; res = res->ai_next) {
if (res->ai_family != AF_INET6) {
setupAddress(res);
}
}
} catch (const std::system_error&) {
// If we can't bind to the same port on ipv4 as ipv6 when using
// port=0 then we will retry again before giving up after
// kNumTries attempts. We do this by closing the sockets that
// were opened, then restarting from scratch.
if (port == 0 && !sockets_.empty() && tries != kNumTries) {
for (const auto& socket : sockets_) {
if (socket.socket_ == NetworkSocket()) {
continue;
} else if (
const auto shutdownSocketSet = wShutdownSocketSet_.lock()) {
shutdownSocketSet->close(socket.socket_);
} else {
closeNoInt(socket.socket_);
}
}
sockets_.clear();
snprintf(sport, sizeof(sport), "%u", port);
freeaddrinfo(res0);
CHECK_EQ(0, getaddrinfo(nullptr, sport, &hints, &res0));
continue;
}
throw;
}
break;
}
if (sockets_.empty()) {
throw std::runtime_error("did not bind any async server socket for port");
}
}
void AsyncServerSocket::listen(int backlog) {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
// Start listening
for (auto& handler : sockets_) {
if (netops::listen(handler.socket_, backlog) == -1) {
folly::throwSystemError(errno, "failed to listen on async server socket");
}
}
}
void AsyncServerSocket::getAddress(SocketAddress* addressReturn) const {
CHECK(!sockets_.empty());
VLOG_IF(2, sockets_.size() > 1)
<< "Warning: getAddress() called and multiple addresses available ("
<< sockets_.size() << "). Returning only the first one.";
addressReturn->setFromLocalAddress(sockets_[0].socket_);
}
std::vector<SocketAddress> AsyncServerSocket::getAddresses() const {
CHECK(!sockets_.empty());
auto tsaVec = std::vector<SocketAddress>(sockets_.size());
auto tsaIter = tsaVec.begin();
for (const auto& socket : sockets_) {
(tsaIter++)->setFromLocalAddress(socket.socket_);
};
return tsaVec;
}
void AsyncServerSocket::addAcceptCallback(
AcceptCallback* callback,
EventBase* eventBase,
uint32_t maxAtOnce) {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
// If this is the first accept callback and we are supposed to be accepting,
// start accepting once the callback is installed.
bool runStartAccepting = accepting_ && callbacks_.empty();
callbacks_.emplace_back(callback, eventBase);
SCOPE_SUCCESS {
// If this is the first accept callback and we are supposed to be accepting,
// start accepting.
if (runStartAccepting) {
startAccepting();
}
};
if (!eventBase) {
// Run in AsyncServerSocket's eventbase; notify that we are
// starting to accept connections
callback->acceptStarted();
return;
}
// Start the remote acceptor.
//
// It would be nice if we could avoid starting the remote acceptor if
// eventBase == eventBase_. However, that would cause issues if
// detachEventBase() and attachEventBase() were ever used to change the
// primary EventBase for the server socket. Therefore we require the caller
// to specify a nullptr EventBase if they want to ensure that the callback is
// always invoked in the primary EventBase, and to be able to invoke that
// callback more efficiently without having to use a notification queue.
RemoteAcceptor* acceptor = nullptr;
try {
acceptor = new RemoteAcceptor(callback, connectionEventCallback_);
acceptor->start(eventBase, maxAtOnce, maxNumMsgsInQueue_);
} catch (...) {
callbacks_.pop_back();
delete acceptor;
throw;
}
callbacks_.back().consumer = acceptor;
}
void AsyncServerSocket::removeAcceptCallback(
AcceptCallback* callback,
EventBase* eventBase) {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
// Find the matching AcceptCallback.
// We just do a simple linear search; we don't expect removeAcceptCallback()
// to be called frequently, and we expect there to only be a small number of
// callbacks anyway.
auto it = callbacks_.begin();
uint32_t n = 0;
while (true) {
if (it == callbacks_.end()) {
throw std::runtime_error(
"AsyncServerSocket::removeAcceptCallback(): "
"accept callback not found");
}
if (it->callback == callback &&
(it->eventBase == eventBase || eventBase == nullptr)) {
break;
}
++it;
++n;
}
// Remove this callback from callbacks_.
//
// Do this before invoking the acceptStopped() callback, in case
// acceptStopped() invokes one of our methods that examines callbacks_.
//
// Save a copy of the CallbackInfo first.
CallbackInfo info(*it);
callbacks_.erase(it);
if (n < callbackIndex_) {
// We removed an element before callbackIndex_. Move callbackIndex_ back
// one step, since things after n have been shifted back by 1.
--callbackIndex_;
} else {
// We removed something at or after callbackIndex_.
// If we removed the last element and callbackIndex_ was pointing at it,
// we need to reset callbackIndex_ to 0.
if (callbackIndex_ >= callbacks_.size()) {
callbackIndex_ = 0;
}
}
if (info.consumer) {
// consumer could be nullptr is we run callbacks in primary event
// base
DCHECK(info.eventBase);
info.consumer->stop(info.eventBase, info.callback);
} else {
// callback invoked in the primary event base, just call directly
DCHECK(info.callback);
callback->acceptStopped();
}
// If we are supposed to be accepting but the last accept callback
// was removed, unregister for events until a callback is added.
if (accepting_ && callbacks_.empty()) {
for (auto& handler : sockets_) {
handler.unregisterHandler();
}
}
}
void AsyncServerSocket::startAccepting() {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
accepting_ = true;
if (callbacks_.empty()) {
// We can't actually begin accepting if no callbacks are defined.
// Wait until a callback is added to start accepting.
return;
}
for (auto& handler : sockets_) {
if (!handler.registerHandler(EventHandler::READ | EventHandler::PERSIST)) {
throw std::runtime_error("failed to register for accept events");
}
}
}
void AsyncServerSocket::pauseAccepting() {
if (eventBase_) {
eventBase_->dcheckIsInEventBaseThread();
}
accepting_ = false;
for (auto& handler : sockets_) {
handler.unregisterHandler();
}
// If we were in the accept backoff state, disable the backoff timeout
if (backoffTimeout_) {
backoffTimeout_->cancelTimeout();
}
}
NetworkSocket AsyncServerSocket::createSocket(int family) {
auto fd = netops::socket(family, SOCK_STREAM, 0);
if (fd == NetworkSocket()) {
folly::throwSystemError(errno, "error creating async server socket");
}
try {
setupSocket(fd, family);
} catch (...) {
closeNoInt(fd);
throw;
}
return fd;
}
/**
* Enable/Disable TOS reflection for the server socket
* If enabled, the 'accepted' connections will reflect the
* TOS derived from the client's connect request
*/
void AsyncServerSocket::setTosReflect(bool enable) {
if (!kIsLinux || !enable) {
tosReflect_ = false;
return;
}
for (auto& handler : sockets_) {
if (handler.socket_ == NetworkSocket()) {
continue;
}
int val = (enable) ? 1 : 0;
int ret = netops::setsockopt(
handler.socket_, IPPROTO_TCP, TCP_SAVE_SYN, &val, sizeof(val));
if (ret == 0) {
VLOG(10) << "Enabled SYN save for socket " << handler.socket_;
} else {
folly::throwSystemError(errno, "failed to enable TOS reflect");
}
}
tosReflect_ = true;
}
void AsyncServerSocket::setupSocket(NetworkSocket fd, int family) {
// Put the socket in non-blocking mode
if (netops::set_socket_non_blocking(fd) != 0) {
folly::throwSystemError(errno, "failed to put socket in non-blocking mode");
}
// Set reuseaddr to avoid 2MSL delay on server restart
int one = 1;
if (netops::setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one)) !=
0) {
auto errnoCopy = errno;
// This isn't a fatal error; just log an error message and continue
LOG(ERROR) << "failed to set SO_REUSEADDR on async server socket "
<< errnoCopy;
}
// Set reuseport to support multiple accept threads
int zero = 0;
if (reusePortEnabled_ &&
netops::setsockopt(fd, SOL_SOCKET, SO_REUSEPORT, &one, sizeof(int)) !=
0) {
auto errnoCopy = errno;
LOG(ERROR) << "failed to set SO_REUSEPORT on async server socket "
<< errnoStr(errnoCopy);
#ifdef WIN32
folly::throwSystemErrorExplicit(
errnoCopy, "failed to set SO_REUSEPORT on async server socket");
#else
SocketAddress address;
address.setFromLocalAddress(fd);
folly::throwSystemErrorExplicit(
errnoCopy,
"failed to set SO_REUSEPORT on async server socket: " +
address.describe());
#endif
}
// Set keepalive as desired
if (netops::setsockopt(
fd,
SOL_SOCKET,
SO_KEEPALIVE,
(keepAliveEnabled_) ? &one : &zero,
sizeof(int)) != 0) {
auto errnoCopy = errno;
LOG(ERROR) << "failed to set SO_KEEPALIVE on async server socket: "
<< errnoStr(errnoCopy);
}
// Setup FD_CLOEXEC flag
if (closeOnExec_ && (-1 == netops::set_socket_close_on_exec(fd))) {
auto errnoCopy = errno;
LOG(ERROR) << "failed to set FD_CLOEXEC on async server socket: "
<< errnoStr(errnoCopy);
}
// Set TCP nodelay if available, MAC OS X Hack
// See http://lists.danga.com/pipermail/memcached/2005-March/001240.html
#ifndef TCP_NOPUSH
if (family != AF_UNIX) {
if (netops::setsockopt(fd, IPPROTO_TCP, TCP_NODELAY, &one, sizeof(one)) !=
0) {
auto errnoCopy = errno;
// This isn't a fatal error; just log an error message and continue
LOG(ERROR) << "failed to set TCP_NODELAY on async server socket: "
<< errnoStr(errnoCopy);
}
}
#else
(void)family; // to avoid unused parameter warning
#endif
#if FOLLY_ALLOW_TFO
if (tfo_ && detail::tfo_enable(fd, tfoMaxQueueSize_) != 0) {
auto errnoCopy = errno;
// This isn't a fatal error; just log an error message and continue
LOG(WARNING) << "failed to set TCP_FASTOPEN on async server socket: "
<< folly::errnoStr(errnoCopy);
}
#endif
if (zeroCopyVal_) {
int val = 1;
int ret =
netops::setsockopt(fd, SOL_SOCKET, SO_ZEROCOPY, &val, sizeof(val));
if (ret) {
auto errnoCopy = errno;
LOG(WARNING) << "failed to set SO_ZEROCOPY on async server socket: "
<< folly::errnoStr(errnoCopy);
}
}
if (const auto shutdownSocketSet = wShutdownSocketSet_.lock()) {
shutdownSocketSet->add(fd);
}
}
void AsyncServerSocket::handlerReady(
uint16_t /* events */,
NetworkSocket fd,
sa_family_t addressFamily) noexcept {
assert(!callbacks_.empty());
DestructorGuard dg(this);
// Only accept up to maxAcceptAtOnce_ connections at a time,
// to avoid starving other I/O handlers using this EventBase.
for (uint32_t n = 0; n < maxAcceptAtOnce_; ++n) {
SocketAddress address;
sockaddr_storage addrStorage = {};
socklen_t addrLen = sizeof(addrStorage);
auto saddr = reinterpret_cast<sockaddr*>(&addrStorage);
// In some cases, accept() doesn't seem to update these correctly.
saddr->sa_family = addressFamily;
if (addressFamily == AF_UNIX) {
addrLen = sizeof(struct sockaddr_un);
}
// Accept a new client socket
#if FOLLY_HAVE_ACCEPT4
auto clientSocket = NetworkSocket::fromFd(
accept4(fd.toFd(), saddr, &addrLen, SOCK_NONBLOCK));
#else
auto clientSocket = netops::accept(fd, saddr, &addrLen);
#endif
address.setFromSockaddr(saddr, addrLen);
if (clientSocket != NetworkSocket() && connectionEventCallback_) {
connectionEventCallback_->onConnectionAccepted(clientSocket, address);
}
// Connection accepted, get the SYN packet from the client if
// TOS reflect is enabled
if (kIsLinux && clientSocket != NetworkSocket() && tosReflect_) {
std::array<uint32_t, 64> buffer;
socklen_t len = sizeof(buffer);
int ret = netops::getsockopt(
clientSocket, IPPROTO_TCP, TCP_SAVED_SYN, &buffer, &len);
if (ret == 0) {
uint32_t tosWord = folly::Endian::big(buffer[0]);
if (addressFamily == AF_INET6) {
tosWord = (tosWord & 0x0FC00000) >> 20;
// Set the TOS on the return socket only if it is non-zero
if (tosWord) {
ret = netops::setsockopt(
clientSocket,
IPPROTO_IPV6,
IPV6_TCLASS,
&tosWord,
sizeof(tosWord));
}
} else if (addressFamily == AF_INET) {
tosWord = (tosWord & 0x00FC0000) >> 16;
if (tosWord) {
ret = netops::setsockopt(
clientSocket, IPPROTO_IP, IP_TOS, &tosWord, sizeof(tosWord));
}
}
if (ret != 0) {
LOG(ERROR) << "Unable to set TOS for accepted socket "
<< clientSocket;
}
} else {
LOG(ERROR) << "Unable to get SYN packet for accepted socket "
<< clientSocket;
}
}
std::chrono::time_point<std::chrono::steady_clock> nowMs =
std::chrono::steady_clock::now();
auto timeSinceLastAccept = std::max<int64_t>(
0,
nowMs.time_since_epoch().count() -
lastAccepTimestamp_.time_since_epoch().count());
lastAccepTimestamp_ = nowMs;
if (acceptRate_ < 1) {
acceptRate_ *= 1 + acceptRateAdjustSpeed_ * timeSinceLastAccept;
if (acceptRate_ >= 1) {
acceptRate_ = 1;
} else if (rand() > acceptRate_ * RAND_MAX) {
++numDroppedConnections_;
if (clientSocket != NetworkSocket()) {
closeNoInt(clientSocket);
if (connectionEventCallback_) {
connectionEventCallback_->onConnectionDropped(
clientSocket, address);
}
}
continue;
}
}
if (clientSocket == NetworkSocket()) {
if (errno == EAGAIN) {
// No more sockets to accept right now.
// Check for this code first, since it's the most common.
return;
} else if (errno == EMFILE || errno == ENFILE) {
// We're out of file descriptors. Perhaps we're accepting connections
// too quickly. Pause accepting briefly to back off and give the server
// a chance to recover.
LOG(ERROR) << "accept failed: out of file descriptors; entering accept "
"back-off state";
enterBackoff();
// Dispatch the error message
dispatchError("accept() failed", errno);
} else {
dispatchError("accept() failed", errno);
}
if (connectionEventCallback_) {
connectionEventCallback_->onConnectionAcceptError(errno);
}
return;
}
#if !FOLLY_HAVE_ACCEPT4
// Explicitly set the new connection to non-blocking mode
if (netops::set_socket_non_blocking(clientSocket) != 0) {
closeNoInt(clientSocket);
dispatchError(
"failed to set accepted socket to non-blocking mode", errno);
if (connectionEventCallback_) {
connectionEventCallback_->onConnectionDropped(clientSocket, address);
}
return;
}
#endif
// Inform the callback about the new connection
dispatchSocket(clientSocket, std::move(address));
// If we aren't accepting any more, break out of the loop
if (!accepting_ || callbacks_.empty()) {
break;
}
}
}
void AsyncServerSocket::dispatchSocket(
NetworkSocket socket,
SocketAddress&& address) {
uint32_t startingIndex = callbackIndex_;
// Short circuit if the callback is in the primary EventBase thread
CallbackInfo* info = nextCallback();
if (info->eventBase == nullptr || info->eventBase == this->eventBase_) {
info->callback->connectionAccepted(socket, address);
return;
}
const SocketAddress addr(address);
// Create a message to send over the notification queue
QueueMessage msg;
msg.type = MessageType::MSG_NEW_CONN;
msg.address = std::move(address);
msg.fd = socket;
// Loop until we find a free queue to write to
while (true) {
if (info->consumer->getQueue()->tryPutMessageNoThrow(std::move(msg))) {
if (connectionEventCallback_) {
connectionEventCallback_->onConnectionEnqueuedForAcceptorCallback(
socket, addr);
}
// Success! return.
return;
}
// We couldn't add to queue. Fall through to below
++numDroppedConnections_;
if (acceptRateAdjustSpeed_ > 0) {
// aggressively decrease accept rate when in trouble
static const double kAcceptRateDecreaseSpeed = 0.1;
acceptRate_ *= 1 - kAcceptRateDecreaseSpeed;
}
if (callbackIndex_ == startingIndex) {
// The notification queue was full
// We can't really do anything at this point other than close the socket.
//
// This should only happen if a user's service is behaving extremely
// badly and none of the EventBase threads are looping fast enough to
// process the incoming connections. If the service is overloaded, it
// should use pauseAccepting() to temporarily back off accepting new
// connections, before they reach the point where their threads can't
// even accept new messages.
LOG_EVERY_N(ERROR, 100) << "failed to dispatch newly accepted socket:"
<< " all accept callback queues are full";
closeNoInt(socket);
if (connectionEventCallback_) {
connectionEventCallback_->onConnectionDropped(socket, addr);
}
return;
}
info = nextCallback();
}
}
void AsyncServerSocket::dispatchError(const char* msgstr, int errnoValue) {
uint32_t startingIndex = callbackIndex_;
CallbackInfo* info = nextCallback();
// Create a message to send over the notification queue
QueueMessage msg;
msg.type = MessageType::MSG_ERROR;
msg.err = errnoValue;
msg.msg = msgstr;
while (true) {
// Short circuit if the callback is in the primary EventBase thread
if (info->eventBase == nullptr || info->eventBase == this->eventBase_) {
std::runtime_error ex(
std::string(msgstr) + folly::to<std::string>(errnoValue));
info->callback->acceptError(ex);
return;
}
if (info->consumer->getQueue()->tryPutMessageNoThrow(std::move(msg))) {
return;
}
// Fall through and try another callback
if (callbackIndex_ == startingIndex) {
// The notification queues for all of the callbacks were full.
// We can't really do anything at this point.
LOG_EVERY_N(ERROR, 100)
<< "failed to dispatch accept error: all accept"
<< " callback queues are full: error msg: " << msg.msg << ": "
<< errnoValue;
return;
}
info = nextCallback();
}
}
void AsyncServerSocket::enterBackoff() {
// If this is the first time we have entered the backoff state,
// allocate backoffTimeout_.
if (backoffTimeout_ == nullptr) {
try {
backoffTimeout_ = new BackoffTimeout(this);
} catch (const std::bad_alloc&) {
// Man, we couldn't even allocate the timer to re-enable accepts.
// We must be in pretty bad shape. Don't pause accepting for now,
// since we won't be able to re-enable ourselves later.
LOG(ERROR) << "failed to allocate AsyncServerSocket backoff"
<< " timer; unable to temporarly pause accepting";
if (connectionEventCallback_) {
connectionEventCallback_->onBackoffError();
}
return;
}
}
// For now, we simply pause accepting for 1 second.
//
// We could add some smarter backoff calculation here in the future. (e.g.,
// start sleeping for longer if we keep hitting the backoff frequently.)
// Typically the user needs to figure out why the server is overloaded and
// fix it in some other way, though. The backoff timer is just a simple
// mechanism to try and give the connection processing code a little bit of
// breathing room to catch up, and to avoid just spinning and failing to
// accept over and over again.
const uint32_t timeoutMS = 1000;
if (!backoffTimeout_->scheduleTimeout(timeoutMS)) {
LOG(ERROR) << "failed to schedule AsyncServerSocket backoff timer;"
<< "unable to temporarly pause accepting";
if (connectionEventCallback_) {
connectionEventCallback_->onBackoffError();
}
return;
}
// The backoff timer is scheduled to re-enable accepts.
// Go ahead and disable accepts for now. We leave accepting_ set to true,
// since that tracks the desired state requested by the user.
for (auto& handler : sockets_) {
handler.unregisterHandler();
}
if (connectionEventCallback_) {
connectionEventCallback_->onBackoffStarted();
}
}
void AsyncServerSocket::backoffTimeoutExpired() {
// accepting_ should still be true.
// If pauseAccepting() was called while in the backoff state it will cancel
// the backoff timeout.
assert(accepting_);
// We can't be detached from the EventBase without being paused
assert(eventBase_ != nullptr);
eventBase_->dcheckIsInEventBaseThread();
// If all of the callbacks were removed, we shouldn't re-enable accepts
if (callbacks_.empty()) {
if (connectionEventCallback_) {
connectionEventCallback_->onBackoffEnded();
}
return;
}
// Register the handler.
for (auto& handler : sockets_) {
if (!handler.registerHandler(EventHandler::READ | EventHandler::PERSIST)) {
// We're hosed. We could just re-schedule backoffTimeout_ to
// re-try again after a little bit. However, we don't want to
// loop retrying forever if we can't re-enable accepts. Just
// abort the entire program in this state; things are really bad
// and restarting the entire server is probably the best remedy.
LOG(ERROR)
<< "failed to re-enable AsyncServerSocket accepts after backoff; "
<< "crashing now";
abort();
}
}
if (connectionEventCallback_) {
connectionEventCallback_->onBackoffEnded();
}
}
} // namespace folly