/* SPDX-License-Identifier: MPL-2.0 */ #include "precompiled.hpp" #include "kqueue.hpp" #if defined ZMQ_IOTHREAD_POLLER_USE_KQUEUE #include #include #include #include #include #include #include #include "macros.hpp" #include "kqueue.hpp" #include "err.hpp" #include "config.hpp" #include "i_poll_events.hpp" #include "likely.hpp" // NetBSD up to version 9 defines (struct kevent).udata as intptr_t, // everyone else as void *. #if defined ZMQ_HAVE_NETBSD && defined(ZMQ_NETBSD_KEVENT_UDATA_INTPTR_T) #define kevent_udata_t intptr_t #else #define kevent_udata_t void * #endif zmq::kqueue_t::kqueue_t (const zmq::thread_ctx_t &ctx_) : worker_poller_base_t (ctx_) { // Create event queue kqueue_fd = kqueue (); errno_assert (kqueue_fd != -1); #ifdef HAVE_FORK pid = getpid (); #endif } zmq::kqueue_t::~kqueue_t () { stop_worker (); close (kqueue_fd); } void zmq::kqueue_t::kevent_add (fd_t fd_, short filter_, void *udata_) { check_thread (); struct kevent ev; EV_SET (&ev, fd_, filter_, EV_ADD, 0, 0, (kevent_udata_t) udata_); int rc = kevent (kqueue_fd, &ev, 1, NULL, 0, NULL); errno_assert (rc != -1); } void zmq::kqueue_t::kevent_delete (fd_t fd_, short filter_) { struct kevent ev; EV_SET (&ev, fd_, filter_, EV_DELETE, 0, 0, 0); int rc = kevent (kqueue_fd, &ev, 1, NULL, 0, NULL); errno_assert (rc != -1); } zmq::kqueue_t::handle_t zmq::kqueue_t::add_fd (fd_t fd_, i_poll_events *reactor_) { check_thread (); poll_entry_t *pe = new (std::nothrow) poll_entry_t; alloc_assert (pe); pe->fd = fd_; pe->flag_pollin = 0; pe->flag_pollout = 0; pe->reactor = reactor_; adjust_load (1); return pe; } void zmq::kqueue_t::rm_fd (handle_t handle_) { check_thread (); poll_entry_t *pe = (poll_entry_t *) handle_; if (pe->flag_pollin) kevent_delete (pe->fd, EVFILT_READ); if (pe->flag_pollout) kevent_delete (pe->fd, EVFILT_WRITE); pe->fd = retired_fd; retired.push_back (pe); adjust_load (-1); } void zmq::kqueue_t::set_pollin (handle_t handle_) { check_thread (); poll_entry_t *pe = (poll_entry_t *) handle_; if (likely (!pe->flag_pollin)) { pe->flag_pollin = true; kevent_add (pe->fd, EVFILT_READ, pe); } } void zmq::kqueue_t::reset_pollin (handle_t handle_) { check_thread (); poll_entry_t *pe = (poll_entry_t *) handle_; if (likely (pe->flag_pollin)) { pe->flag_pollin = false; kevent_delete (pe->fd, EVFILT_READ); } } void zmq::kqueue_t::set_pollout (handle_t handle_) { check_thread (); poll_entry_t *pe = (poll_entry_t *) handle_; if (likely (!pe->flag_pollout)) { pe->flag_pollout = true; kevent_add (pe->fd, EVFILT_WRITE, pe); } } void zmq::kqueue_t::reset_pollout (handle_t handle_) { check_thread (); poll_entry_t *pe = (poll_entry_t *) handle_; if (likely (pe->flag_pollout)) { pe->flag_pollout = false; kevent_delete (pe->fd, EVFILT_WRITE); } } void zmq::kqueue_t::stop () { } int zmq::kqueue_t::max_fds () { return -1; } void zmq::kqueue_t::loop () { while (true) { // Execute any due timers. int timeout = (int) execute_timers (); if (get_load () == 0) { if (timeout == 0) break; // TODO sleep for timeout continue; } // Wait for events. struct kevent ev_buf[max_io_events]; timespec ts = {timeout / 1000, (timeout % 1000) * 1000000}; int n = kevent (kqueue_fd, NULL, 0, &ev_buf[0], max_io_events, timeout ? &ts : NULL); #ifdef HAVE_FORK if (unlikely (pid != getpid ())) { //printf("zmq::kqueue_t::loop aborting on forked child %d\n", (int)getpid()); // simply exit the loop in a forked process. return; } #endif if (n == -1) { errno_assert (errno == EINTR); continue; } for (int i = 0; i < n; i++) { poll_entry_t *pe = (poll_entry_t *) ev_buf[i].udata; if (pe->fd == retired_fd) continue; if (ev_buf[i].flags & EV_EOF) pe->reactor->in_event (); if (pe->fd == retired_fd) continue; if (ev_buf[i].filter == EVFILT_WRITE) pe->reactor->out_event (); if (pe->fd == retired_fd) continue; if (ev_buf[i].filter == EVFILT_READ) pe->reactor->in_event (); } // Destroy retired event sources. for (retired_t::iterator it = retired.begin (); it != retired.end (); ++it) { LIBZMQ_DELETE (*it); } retired.clear (); } } #endif