// Copyright (C) 2021 The Qt Company Ltd. // Copyright (C) 2019 Luxoft Sweden AB // Copyright (C) 2018 Pelagicore AG // SPDX-License-Identifier: LicenseRef-Qt-Commercial OR GPL-3.0-only #include "unixsignalhandler.h" #include "logging.h" #include #include #include #if defined(Q_OS_WIN) # include # include #else # include #endif QT_BEGIN_NAMESPACE_AM // sigmask() is not available on Windows UnixSignalHandler::am_sigmask_t UnixSignalHandler::am_sigmask(int sig) { return ((am_sigmask_t(1)) << (((sig) - 1) % int(8 * sizeof(am_sigmask_t)))); } UnixSignalHandler *UnixSignalHandler::s_instance = nullptr; UnixSignalHandler::UnixSignalHandler() { #if defined(Q_OS_UNIX) && !defined(Q_OS_QNX) // Setup alternate signal stack (to get backtrace for stack overflow) // Canonical size might not be suffcient to get QML backtrace, so we double it size_t stackSize = SIGSTKSZ * 2; stack_t sigstack; // ASAN and valgrind would report malloc() as a leak. In addition, we avoid the // signal stack being close to a possibly corrupted heap this way. sigstack.ss_sp = mmap(nullptr, stackSize, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, 0); if (sigstack.ss_sp != MAP_FAILED) { sigstack.ss_size = stackSize; sigstack.ss_flags = 0; sigaltstack(&sigstack, nullptr); } else { // this code runs before all other static constructors qWarning("WARNING: UnixSignalHandler failed to allocate memory for an alternate signal stack."); } #endif } UnixSignalHandler *UnixSignalHandler::instance() { if (Q_UNLIKELY(!s_instance)) s_instance = new UnixSignalHandler(); return s_instance; } const char *UnixSignalHandler::signalName(int sig) { #if defined(Q_OS_UNIX) #if __GLIBC__ >= 2 && __GLIBC_MINOR__ >= 32 return sigdescr_np(sig); #else return strsignal(sig); // not async-signal-safe #endif #else Q_UNUSED(sig) return ""; #endif } void UnixSignalHandler::resetToDefault(int sig) { auto sigs = { sig }; resetToDefault(sigs); } void UnixSignalHandler::resetToDefault(const std::initializer_list &sigs) { for (int sig : sigs) { m_resetSignalMask |= am_sigmask(sig); signal(sig, SIG_DFL); } } bool UnixSignalHandler::install(Type handlerType, int sig, const std::function &handler) { auto sigs = { sig }; return install(handlerType, sigs, handler); } bool UnixSignalHandler::install(Type handlerType, const std::initializer_list &sigs, const std::function &handler) { auto sigHandler = [](int sig) { // this lambda is the low-level signal handler multiplexer auto that = UnixSignalHandler::instance(); that->m_currentSignal = sig; for (const auto &h : std::as_const(that->m_handlers)) { if ((h.m_signal == sig) && !h.m_disabled) { if (!h.m_qt) { h.m_handler(sig); } else { #if defined(Q_OS_UNIX) auto dummy = write(that->m_pipe[1], &sig, sizeof(int)); Q_UNUSED(dummy) #elif defined(Q_OS_WIN) // we're running in a separate thread now that->m_winLock.lock(); that->m_signalsForEventLoop << sig; that->m_winLock.unlock(); PulseEvent(that->m_winEvent->handle()); #endif } } } if (that->m_resetSignalMask) { // Someone called resetToDefault - now's a good time to handle it. // We can not remove the entries in the list, because that would (a) allocate and (b) // step on code that might be iterating over the list in the "Forwarded" handler. for (const auto &h : std::as_const(that->m_handlers)) { if (that->m_resetSignalMask & am_sigmask(h.m_signal)) h.m_disabled = true; } that->m_resetSignalMask = 0; } that->m_currentSignal = 0; }; if (m_currentSignal) { // installing a signal handler from within a signal handler shouldn't be necessary return false; } if (handlerType == ForwardedToEventLoopHandler) { #if defined(Q_OS_UNIX) if ((m_pipe[0] == -1) && qApp) { auto dummy = pipe(m_pipe); Q_UNUSED(dummy) auto sn = new QSocketNotifier(m_pipe[0], QSocketNotifier::Read, this); connect(sn, &QSocketNotifier::activated, qApp, [this]() { // this lambda is the "signal handler" multiplexer within the Qt event loop int sig = 0; if (read(m_pipe[0], &sig, sizeof(int)) != sizeof(int)) { qCWarning(LogSystem) << "Error reading from signal handler:" << strerror(errno);; return; } for (const auto &h : std::as_const(m_handlers)) { if (h.m_qt && (h.m_signal == sig) && !h.m_disabled) h.m_handler(sig); } }); } #elif defined(Q_OS_WIN) if (!m_winEvent) { m_winEvent = new QWinEventNotifier(CreateEventW(nullptr, false, false, nullptr), this); connect(m_winEvent, &QWinEventNotifier::activated, qApp, [this]() { // this lambda is the "signal handler" multiplexer within the Qt event loop m_winLock.lock(); for (const int &sig : std::as_const(m_signalsForEventLoop)) { for (const auto &h : std::as_const(m_handlers)) { if (h.m_qt && (h.m_signal == sig) && !h.m_disabled) h.m_handler(sig); } } m_signalsForEventLoop.clear(); m_winLock.unlock(); }); } #else qCWarning(LogSystem) << "Unix signal handling via 'ForwardedToEventLoopHandler' is not " "supported on this platform"; return false; #endif } // This is UB! We cannot guarantee that the signal handler is not currently executing and // iterating over this list. In practice, this is a none-issue in the AM however, because all // install() calls are done right at startup time. // To do it right, we would need a lock-free list structure for m_handlers. for (int sig : sigs) m_handlers.emplace_back(sig, handlerType == ForwardedToEventLoopHandler, handler); #if defined(Q_OS_UNIX) && !defined(Q_OS_QNX) struct sigaction sigact; sigact.sa_flags = SA_ONSTACK; sigact.sa_handler = sigHandler; sigemptyset(&sigact.sa_mask); sigset_t unblockSet; sigemptyset(&unblockSet); for (int sig : sigs) { sigaddset(&unblockSet, sig); sigaction(sig, &sigact, nullptr); m_resetSignalMask &= ~am_sigmask(sig); // cancel unfinished reset } sigprocmask(SIG_UNBLOCK, &unblockSet, nullptr); #else for (int sig : sigs) signal(sig, sigHandler); #endif return true; } UnixSignalHandler::SigHandler::SigHandler(int signal, bool qt, const std::function &handler) : m_signal(signal), m_qt(qt), m_handler(handler) { } QT_END_NAMESPACE_AM #include "moc_unixsignalhandler.cpp"