/* $NetBSD: socket.c,v 1.1.2.2 2024/02/24 13:07:30 martin Exp $ */ /* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * SPDX-License-Identifier: MPL-2.0 * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, you can obtain one at https://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ /*! \file */ #include #include #include #include #include #include #if defined(HAVE_SYS_SYSCTL_H) && !defined(__linux__) #include #endif /* if defined(HAVE_SYS_SYSCTL_H) && !defined(__linux__) */ #include #include #if defined(HAVE_LINUX_NETLINK_H) && defined(HAVE_LINUX_RTNETLINK_H) #include #include #endif /* if defined(HAVE_LINUX_NETLINK_H) && defined(HAVE_LINUX_RTNETLINK_H) \ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef ISC_PLATFORM_HAVESYSUNH #include #endif /* ifdef ISC_PLATFORM_HAVESYSUNH */ #ifdef HAVE_KQUEUE #include #endif /* ifdef HAVE_KQUEUE */ #ifdef HAVE_EPOLL_CREATE1 #include #endif /* ifdef HAVE_EPOLL_CREATE1 */ #if defined(HAVE_SYS_DEVPOLL_H) #include #elif defined(HAVE_DEVPOLL_H) #include #endif /* if defined(HAVE_SYS_DEVPOLL_H) */ #include #include "errno2result.h" #ifdef ENABLE_TCP_FASTOPEN #include #endif /* ifdef ENABLE_TCP_FASTOPEN */ #ifdef HAVE_JSON_C #include #endif /* HAVE_JSON_C */ #ifdef HAVE_LIBXML2 #include #define ISC_XMLCHAR (const xmlChar *) #endif /* HAVE_LIBXML2 */ /*% * Choose the most preferable multiplex method. */ #if defined(HAVE_KQUEUE) #define USE_KQUEUE #elif defined(HAVE_EPOLL_CREATE1) #define USE_EPOLL #elif defined(HAVE_SYS_DEVPOLL_H) || defined(HAVE_DEVPOLL_H) #define USE_DEVPOLL typedef struct { unsigned int want_read : 1, want_write : 1; } pollinfo_t; #else /* if defined(HAVE_KQUEUE) */ #define USE_SELECT #endif /* HAVE_KQUEUE */ /* * Set by the -T dscp option on the command line. If set to a value * other than -1, we check to make sure DSCP values match it, and * assert if not. */ int isc_dscp_check_value = -1; /*% * Maximum number of allowable open sockets. This is also the maximum * allowable socket file descriptor. * * Care should be taken before modifying this value for select(): * The API standard doesn't ensure select() accept more than (the system default * of) FD_SETSIZE descriptors, and the default size should in fact be fine in * the vast majority of cases. This constant should therefore be increased only * when absolutely necessary and possible, i.e., the server is exhausting all * available file descriptors (up to FD_SETSIZE) and the select() function * and FD_xxx macros support larger values than FD_SETSIZE (which may not * always by true, but we keep using some of them to ensure as much * portability as possible). Note also that overall server performance * may be rather worsened with a larger value of this constant due to * inherent scalability problems of select(). * * As a special note, this value shouldn't have to be touched if * this is a build for an authoritative only DNS server. */ #ifndef ISC_SOCKET_MAXSOCKETS #if defined(USE_KQUEUE) || defined(USE_EPOLL) || defined(USE_DEVPOLL) #ifdef TUNE_LARGE #define ISC_SOCKET_MAXSOCKETS 21000 #else /* ifdef TUNE_LARGE */ #define ISC_SOCKET_MAXSOCKETS 4096 #endif /* TUNE_LARGE */ #elif defined(USE_SELECT) #define ISC_SOCKET_MAXSOCKETS FD_SETSIZE #endif /* USE_KQUEUE... */ #endif /* ISC_SOCKET_MAXSOCKETS */ #ifdef USE_SELECT /*% * Mac OS X needs a special definition to support larger values in select(). * We always define this because a larger value can be specified run-time. */ #ifdef __APPLE__ #define _DARWIN_UNLIMITED_SELECT #endif /* __APPLE__ */ #endif /* USE_SELECT */ #ifdef ISC_SOCKET_USE_POLLWATCH /*% * If this macro is defined, enable workaround for a Solaris /dev/poll kernel * bug: DP_POLL ioctl could keep sleeping even if socket I/O is possible for * some of the specified FD. The idea is based on the observation that it's * likely for a busy server to keep receiving packets. It specifically works * as follows: the socket watcher is first initialized with the state of * "poll_idle". While it's in the idle state it keeps sleeping until a socket * event occurs. When it wakes up for a socket I/O event, it moves to the * poll_active state, and sets the poll timeout to a short period * (ISC_SOCKET_POLLWATCH_TIMEOUT msec). If timeout occurs in this state, the * watcher goes to the poll_checking state with the same timeout period. * In this state, the watcher tries to detect whether this is a break * during intermittent events or the kernel bug is triggered. If the next * polling reports an event within the short period, the previous timeout is * likely to be a kernel bug, and so the watcher goes back to the active state. * Otherwise, it moves to the idle state again. * * It's not clear whether this is a thread-related bug, but since we've only * seen this with threads, this workaround is used only when enabling threads. */ typedef enum { poll_idle, poll_active, poll_checking } pollstate_t; #ifndef ISC_SOCKET_POLLWATCH_TIMEOUT #define ISC_SOCKET_POLLWATCH_TIMEOUT 10 #endif /* ISC_SOCKET_POLLWATCH_TIMEOUT */ #endif /* ISC_SOCKET_USE_POLLWATCH */ /*% * Per-FD lock buckets, we shuffle them around a bit as FDs come in herds. */ #define FDLOCK_BITS 10 #define FDLOCK_COUNT (1 << FDLOCK_BITS) #define FDLOCK_ID(fd) \ (((fd) % (FDLOCK_COUNT) >> (FDLOCK_BITS / 2)) | \ (((fd) << (FDLOCK_BITS / 2)) % (FDLOCK_COUNT))) /*% * Maximum number of events communicated with the kernel. There should normally * be no need for having a large number. */ #if defined(USE_KQUEUE) || defined(USE_EPOLL) || defined(USE_DEVPOLL) #ifndef ISC_SOCKET_MAXEVENTS #ifdef TUNE_LARGE #define ISC_SOCKET_MAXEVENTS 2048 #else /* ifdef TUNE_LARGE */ #define ISC_SOCKET_MAXEVENTS 64 #endif /* TUNE_LARGE */ #endif /* ifndef ISC_SOCKET_MAXEVENTS */ #endif /* if defined(USE_KQUEUE) || defined(USE_EPOLL) || defined(USE_DEVPOLL) \ * */ /*% * Some systems define the socket length argument as an int, some as size_t, * some as socklen_t. This is here so it can be easily changed if needed. */ #ifndef socklen_t #define socklen_t unsigned int #endif /* ifndef socklen_t */ /*% * Define what the possible "soft" errors can be. These are non-fatal returns * of various network related functions, like recv() and so on. * * For some reason, BSDI (and perhaps others) will sometimes return <0 * from recv() but will have errno==0. This is broken, but we have to * work around it here. */ #define SOFT_ERROR(e) \ ((e) == EAGAIN || (e) == EWOULDBLOCK || (e) == ENOBUFS || \ (e) == EINTR || (e) == 0) #define DLVL(x) ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_DEBUG(x) /*!< * DLVL(90) -- Function entry/exit and other tracing. * DLVL(70) -- Socket "correctness" -- including returning of events, etc. * DLVL(60) -- Socket data send/receive * DLVL(50) -- Event tracing, including receiving/sending completion events. * DLVL(20) -- Socket creation/destruction. */ #define TRACE_LEVEL 90 #define CORRECTNESS_LEVEL 70 #define IOEVENT_LEVEL 60 #define EVENT_LEVEL 50 #define CREATION_LEVEL 20 #define TRACE DLVL(TRACE_LEVEL) #define CORRECTNESS DLVL(CORRECTNESS_LEVEL) #define IOEVENT DLVL(IOEVENT_LEVEL) #define EVENT DLVL(EVENT_LEVEL) #define CREATION DLVL(CREATION_LEVEL) typedef isc_event_t intev_t; #define SOCKET_MAGIC ISC_MAGIC('I', 'O', 'i', 'o') #define VALID_SOCKET(s) ISC_MAGIC_VALID(s, SOCKET_MAGIC) /*! * IPv6 control information. If the socket is an IPv6 socket we want * to collect the destination address and interface so the client can * set them on outgoing packets. */ #ifndef USE_CMSG #define USE_CMSG 1 #endif /* ifndef USE_CMSG */ /*% * NetBSD and FreeBSD can timestamp packets. XXXMLG Should we have * a setsockopt() like interface to request timestamps, and if the OS * doesn't do it for us, call gettimeofday() on every UDP receive? */ #ifdef SO_TIMESTAMP #ifndef USE_CMSG #define USE_CMSG 1 #endif /* ifndef USE_CMSG */ #endif /* ifdef SO_TIMESTAMP */ #if defined(SO_RCVBUF) && defined(ISC_RECV_BUFFER_SIZE) #define SET_RCVBUF #endif #if defined(SO_SNDBUF) && defined(ISC_SEND_BUFFER_SIZE) #define SET_SNDBUF #endif /*% * Instead of calculating the cmsgbuf lengths every time we take * a rule of thumb approach - sizes are taken from x86_64 linux, * multiplied by 2, everything should fit. Those sizes are not * large enough to cause any concern. */ #if defined(USE_CMSG) #define CMSG_SP_IN6PKT 40 #else /* if defined(USE_CMSG) */ #define CMSG_SP_IN6PKT 0 #endif /* if defined(USE_CMSG) */ #if defined(USE_CMSG) && defined(SO_TIMESTAMP) #define CMSG_SP_TIMESTAMP 32 #else /* if defined(USE_CMSG) && defined(SO_TIMESTAMP) */ #define CMSG_SP_TIMESTAMP 0 #endif /* if defined(USE_CMSG) && defined(SO_TIMESTAMP) */ #if defined(USE_CMSG) && (defined(IPV6_TCLASS) || defined(IP_TOS)) #define CMSG_SP_TCTOS 24 #else /* if defined(USE_CMSG) && (defined(IPV6_TCLASS) || defined(IP_TOS)) */ #define CMSG_SP_TCTOS 0 #endif /* if defined(USE_CMSG) && (defined(IPV6_TCLASS) || defined(IP_TOS)) */ #define CMSG_SP_INT 24 /* Align cmsg buffers to be safe on SPARC etc. */ #define RECVCMSGBUFLEN \ ISC_ALIGN(2 * (CMSG_SP_IN6PKT + CMSG_SP_TIMESTAMP + CMSG_SP_TCTOS) + \ 1, \ sizeof(void *)) #define SENDCMSGBUFLEN \ ISC_ALIGN(2 * (CMSG_SP_IN6PKT + CMSG_SP_INT + CMSG_SP_TCTOS) + 1, \ sizeof(void *)) /*% * The number of times a send operation is repeated if the result is EINTR. */ #define NRETRIES 10 typedef struct isc__socketthread isc__socketthread_t; #define NEWCONNSOCK(ev) ((ev)->newsocket) struct isc_socket { /* Not locked. */ unsigned int magic; isc_socketmgr_t *manager; isc_mutex_t lock; isc_sockettype_t type; const isc_statscounter_t *statsindex; isc_refcount_t references; /* Locked by socket lock. */ ISC_LINK(isc_socket_t) link; int fd; int pf; int threadid; char name[16]; void *tag; ISC_LIST(isc_socketevent_t) send_list; ISC_LIST(isc_socketevent_t) recv_list; ISC_LIST(isc_socket_newconnev_t) accept_list; ISC_LIST(isc_socket_connev_t) connect_list; isc_sockaddr_t peer_address; /* remote address */ unsigned int listener : 1, /* listener socket */ connected : 1, connecting : 1, /* connect pending * */ bound : 1, /* bound to local addr */ dupped : 1, active : 1, /* currently active */ pktdscp : 1; /* per packet dscp */ #ifdef ISC_PLATFORM_RECVOVERFLOW unsigned char overflow; /* used for MSG_TRUNC fake */ #endif /* ifdef ISC_PLATFORM_RECVOVERFLOW */ void *fdwatcharg; isc_sockfdwatch_t fdwatchcb; int fdwatchflags; isc_task_t *fdwatchtask; unsigned int dscp; }; #define SOCKET_MANAGER_MAGIC ISC_MAGIC('I', 'O', 'm', 'g') #define VALID_MANAGER(m) ISC_MAGIC_VALID(m, SOCKET_MANAGER_MAGIC) struct isc_socketmgr { /* Not locked. */ unsigned int magic; isc_mem_t *mctx; isc_mutex_t lock; isc_stats_t *stats; int nthreads; isc__socketthread_t *threads; unsigned int maxsocks; /* Locked by manager lock. */ ISC_LIST(isc_socket_t) socklist; int reserved; /* unlocked */ isc_condition_t shutdown_ok; size_t maxudp; }; struct isc__socketthread { isc_socketmgr_t *manager; int threadid; isc_thread_t thread; int pipe_fds[2]; isc_mutex_t *fdlock; /* Locked by fdlock. */ isc_socket_t **fds; int *fdstate; #ifdef USE_KQUEUE int kqueue_fd; int nevents; struct kevent *events; #endif /* USE_KQUEUE */ #ifdef USE_EPOLL int epoll_fd; int nevents; struct epoll_event *events; uint32_t *epoll_events; #endif /* USE_EPOLL */ #ifdef USE_DEVPOLL int devpoll_fd; isc_resourcevalue_t open_max; unsigned int calls; int nevents; struct pollfd *events; pollinfo_t *fdpollinfo; #endif /* USE_DEVPOLL */ #ifdef USE_SELECT int fd_bufsize; fd_set *read_fds; fd_set *read_fds_copy; fd_set *write_fds; fd_set *write_fds_copy; int maxfd; #endif /* USE_SELECT */ }; #define CLOSED 0 /* this one must be zero */ #define MANAGED 1 #define CLOSE_PENDING 2 /* * send() and recv() iovec counts */ #define MAXSCATTERGATHER_SEND (ISC_SOCKET_MAXSCATTERGATHER) #ifdef ISC_PLATFORM_RECVOVERFLOW #define MAXSCATTERGATHER_RECV (ISC_SOCKET_MAXSCATTERGATHER + 1) #else /* ifdef ISC_PLATFORM_RECVOVERFLOW */ #define MAXSCATTERGATHER_RECV (ISC_SOCKET_MAXSCATTERGATHER) #endif /* ifdef ISC_PLATFORM_RECVOVERFLOW */ static isc_result_t socket_create(isc_socketmgr_t *manager0, int pf, isc_sockettype_t type, isc_socket_t **socketp, isc_socket_t *dup_socket); static void send_recvdone_event(isc_socket_t *, isc_socketevent_t **); static void send_senddone_event(isc_socket_t *, isc_socketevent_t **); static void send_connectdone_event(isc_socket_t *, isc_socket_connev_t **); static void free_socket(isc_socket_t **); static isc_result_t allocate_socket(isc_socketmgr_t *, isc_sockettype_t, isc_socket_t **); static void destroy(isc_socket_t **); static void internal_accept(isc_socket_t *); static void internal_connect(isc_socket_t *); static void internal_recv(isc_socket_t *); static void internal_send(isc_socket_t *); static void process_cmsg(isc_socket_t *, struct msghdr *, isc_socketevent_t *); static void build_msghdr_send(isc_socket_t *, char *, isc_socketevent_t *, struct msghdr *, struct iovec *, size_t *); static void build_msghdr_recv(isc_socket_t *, char *, isc_socketevent_t *, struct msghdr *, struct iovec *, size_t *); static bool process_ctlfd(isc__socketthread_t *thread); static void setdscp(isc_socket_t *sock, isc_dscp_t dscp); static void dispatch_recv(isc_socket_t *sock); static void dispatch_send(isc_socket_t *sock); static void internal_fdwatch_read(isc_socket_t *sock); static void internal_fdwatch_write(isc_socket_t *sock); #define SELECT_POKE_SHUTDOWN (-1) #define SELECT_POKE_NOTHING (-2) #define SELECT_POKE_READ (-3) #define SELECT_POKE_ACCEPT (-3) /*%< Same as _READ */ #define SELECT_POKE_WRITE (-4) #define SELECT_POKE_CONNECT (-4) /*%< Same as _WRITE */ #define SELECT_POKE_CLOSE (-5) /*% * Shortcut index arrays to get access to statistics counters. */ enum { STATID_OPEN = 0, STATID_OPENFAIL = 1, STATID_CLOSE = 2, STATID_BINDFAIL = 3, STATID_CONNECTFAIL = 4, STATID_CONNECT = 5, STATID_ACCEPTFAIL = 6, STATID_ACCEPT = 7, STATID_SENDFAIL = 8, STATID_RECVFAIL = 9, STATID_ACTIVE = 10 }; static const isc_statscounter_t udp4statsindex[] = { isc_sockstatscounter_udp4open, isc_sockstatscounter_udp4openfail, isc_sockstatscounter_udp4close, isc_sockstatscounter_udp4bindfail, isc_sockstatscounter_udp4connectfail, isc_sockstatscounter_udp4connect, -1, -1, isc_sockstatscounter_udp4sendfail, isc_sockstatscounter_udp4recvfail, isc_sockstatscounter_udp4active }; static const isc_statscounter_t udp6statsindex[] = { isc_sockstatscounter_udp6open, isc_sockstatscounter_udp6openfail, isc_sockstatscounter_udp6close, isc_sockstatscounter_udp6bindfail, isc_sockstatscounter_udp6connectfail, isc_sockstatscounter_udp6connect, -1, -1, isc_sockstatscounter_udp6sendfail, isc_sockstatscounter_udp6recvfail, isc_sockstatscounter_udp6active }; static const isc_statscounter_t tcp4statsindex[] = { isc_sockstatscounter_tcp4open, isc_sockstatscounter_tcp4openfail, isc_sockstatscounter_tcp4close, isc_sockstatscounter_tcp4bindfail, isc_sockstatscounter_tcp4connectfail, isc_sockstatscounter_tcp4connect, isc_sockstatscounter_tcp4acceptfail, isc_sockstatscounter_tcp4accept, isc_sockstatscounter_tcp4sendfail, isc_sockstatscounter_tcp4recvfail, isc_sockstatscounter_tcp4active }; static const isc_statscounter_t tcp6statsindex[] = { isc_sockstatscounter_tcp6open, isc_sockstatscounter_tcp6openfail, isc_sockstatscounter_tcp6close, isc_sockstatscounter_tcp6bindfail, isc_sockstatscounter_tcp6connectfail, isc_sockstatscounter_tcp6connect, isc_sockstatscounter_tcp6acceptfail, isc_sockstatscounter_tcp6accept, isc_sockstatscounter_tcp6sendfail, isc_sockstatscounter_tcp6recvfail, isc_sockstatscounter_tcp6active }; static const isc_statscounter_t unixstatsindex[] = { isc_sockstatscounter_unixopen, isc_sockstatscounter_unixopenfail, isc_sockstatscounter_unixclose, isc_sockstatscounter_unixbindfail, isc_sockstatscounter_unixconnectfail, isc_sockstatscounter_unixconnect, isc_sockstatscounter_unixacceptfail, isc_sockstatscounter_unixaccept, isc_sockstatscounter_unixsendfail, isc_sockstatscounter_unixrecvfail, isc_sockstatscounter_unixactive }; static const isc_statscounter_t rawstatsindex[] = { isc_sockstatscounter_rawopen, isc_sockstatscounter_rawopenfail, isc_sockstatscounter_rawclose, -1, -1, -1, -1, -1, -1, isc_sockstatscounter_rawrecvfail, isc_sockstatscounter_rawactive }; static int gen_threadid(isc_socket_t *sock); static int gen_threadid(isc_socket_t *sock) { return (sock->fd % sock->manager->nthreads); } static void manager_log(isc_socketmgr_t *sockmgr, isc_logcategory_t *category, isc_logmodule_t *module, int level, const char *fmt, ...) ISC_FORMAT_PRINTF(5, 6); static void manager_log(isc_socketmgr_t *sockmgr, isc_logcategory_t *category, isc_logmodule_t *module, int level, const char *fmt, ...) { char msgbuf[2048]; va_list ap; if (!isc_log_wouldlog(isc_lctx, level)) { return; } va_start(ap, fmt); vsnprintf(msgbuf, sizeof(msgbuf), fmt, ap); va_end(ap); isc_log_write(isc_lctx, category, module, level, "sockmgr %p: %s", sockmgr, msgbuf); } static void thread_log(isc__socketthread_t *thread, isc_logcategory_t *category, isc_logmodule_t *module, int level, const char *fmt, ...) ISC_FORMAT_PRINTF(5, 6); static void thread_log(isc__socketthread_t *thread, isc_logcategory_t *category, isc_logmodule_t *module, int level, const char *fmt, ...) { char msgbuf[2048]; va_list ap; if (!isc_log_wouldlog(isc_lctx, level)) { return; } va_start(ap, fmt); vsnprintf(msgbuf, sizeof(msgbuf), fmt, ap); va_end(ap); isc_log_write(isc_lctx, category, module, level, "sockmgr %p thread %d: %s", thread->manager, thread->threadid, msgbuf); } static void socket_log(isc_socket_t *sock, const isc_sockaddr_t *address, isc_logcategory_t *category, isc_logmodule_t *module, int level, const char *fmt, ...) ISC_FORMAT_PRINTF(6, 7); static void socket_log(isc_socket_t *sock, const isc_sockaddr_t *address, isc_logcategory_t *category, isc_logmodule_t *module, int level, const char *fmt, ...) { char msgbuf[2048]; char peerbuf[ISC_SOCKADDR_FORMATSIZE]; va_list ap; if (!isc_log_wouldlog(isc_lctx, level)) { return; } va_start(ap, fmt); vsnprintf(msgbuf, sizeof(msgbuf), fmt, ap); va_end(ap); if (address == NULL) { isc_log_write(isc_lctx, category, module, level, "socket %p: %s", sock, msgbuf); } else { isc_sockaddr_format(address, peerbuf, sizeof(peerbuf)); isc_log_write(isc_lctx, category, module, level, "socket %p %s: %s", sock, peerbuf, msgbuf); } } /*% * Increment socket-related statistics counters. */ static void inc_stats(isc_stats_t *stats, isc_statscounter_t counterid) { REQUIRE(counterid != -1); if (stats != NULL) { isc_stats_increment(stats, counterid); } } /*% * Decrement socket-related statistics counters. */ static void dec_stats(isc_stats_t *stats, isc_statscounter_t counterid) { REQUIRE(counterid != -1); if (stats != NULL) { isc_stats_decrement(stats, counterid); } } static isc_result_t watch_fd(isc__socketthread_t *thread, int fd, int msg) { isc_result_t result = ISC_R_SUCCESS; #ifdef USE_KQUEUE struct kevent evchange; memset(&evchange, 0, sizeof(evchange)); if (msg == SELECT_POKE_READ) { evchange.filter = EVFILT_READ; } else { evchange.filter = EVFILT_WRITE; } evchange.flags = EV_ADD; evchange.ident = fd; if (kevent(thread->kqueue_fd, &evchange, 1, NULL, 0, NULL) != 0) { result = isc__errno2result(errno); } return (result); #elif defined(USE_EPOLL) struct epoll_event event; uint32_t oldevents; int ret; int op; oldevents = thread->epoll_events[fd]; if (msg == SELECT_POKE_READ) { thread->epoll_events[fd] |= EPOLLIN; } else { thread->epoll_events[fd] |= EPOLLOUT; } event.events = thread->epoll_events[fd]; memset(&event.data, 0, sizeof(event.data)); event.data.fd = fd; op = (oldevents == 0U) ? EPOLL_CTL_ADD : EPOLL_CTL_MOD; if (thread->fds[fd] != NULL) { LOCK(&thread->fds[fd]->lock); } ret = epoll_ctl(thread->epoll_fd, op, fd, &event); if (thread->fds[fd] != NULL) { UNLOCK(&thread->fds[fd]->lock); } if (ret == -1) { if (errno == EEXIST) { UNEXPECTED_ERROR(__FILE__, __LINE__, "epoll_ctl(ADD/MOD) returned " "EEXIST for fd %d", fd); } result = isc__errno2result(errno); } return (result); #elif defined(USE_DEVPOLL) struct pollfd pfd; memset(&pfd, 0, sizeof(pfd)); if (msg == SELECT_POKE_READ) { pfd.events = POLLIN; } else { pfd.events = POLLOUT; } pfd.fd = fd; pfd.revents = 0; if (write(thread->devpoll_fd, &pfd, sizeof(pfd)) == -1) { result = isc__errno2result(errno); } else { if (msg == SELECT_POKE_READ) { thread->fdpollinfo[fd].want_read = 1; } else { thread->fdpollinfo[fd].want_write = 1; } } return (result); #elif defined(USE_SELECT) LOCK(&thread->manager->lock); if (msg == SELECT_POKE_READ) { FD_SET(fd, thread->read_fds); } if (msg == SELECT_POKE_WRITE) { FD_SET(fd, thread->write_fds); } UNLOCK(&thread->manager->lock); return (result); #endif /* ifdef USE_KQUEUE */ } static isc_result_t unwatch_fd(isc__socketthread_t *thread, int fd, int msg) { isc_result_t result = ISC_R_SUCCESS; #ifdef USE_KQUEUE struct kevent evchange; memset(&evchange, 0, sizeof(evchange)); if (msg == SELECT_POKE_READ) { evchange.filter = EVFILT_READ; } else { evchange.filter = EVFILT_WRITE; } evchange.flags = EV_DELETE; evchange.ident = fd; if (kevent(thread->kqueue_fd, &evchange, 1, NULL, 0, NULL) != 0) { result = isc__errno2result(errno); } return (result); #elif defined(USE_EPOLL) struct epoll_event event; int ret; int op; if (msg == SELECT_POKE_READ) { thread->epoll_events[fd] &= ~(EPOLLIN); } else { thread->epoll_events[fd] &= ~(EPOLLOUT); } event.events = thread->epoll_events[fd]; memset(&event.data, 0, sizeof(event.data)); event.data.fd = fd; op = (event.events == 0U) ? EPOLL_CTL_DEL : EPOLL_CTL_MOD; ret = epoll_ctl(thread->epoll_fd, op, fd, &event); if (ret == -1 && errno != ENOENT) { char strbuf[ISC_STRERRORSIZE]; strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "epoll_ctl(DEL), %d: %s", fd, strbuf); result = ISC_R_UNEXPECTED; } return (result); #elif defined(USE_DEVPOLL) struct pollfd pfds[2]; size_t writelen = sizeof(pfds[0]); memset(pfds, 0, sizeof(pfds)); pfds[0].events = POLLREMOVE; pfds[0].fd = fd; /* * Canceling read or write polling via /dev/poll is tricky. Since it * only provides a way of canceling per FD, we may need to re-poll the * socket for the other operation. */ if (msg == SELECT_POKE_READ && thread->fdpollinfo[fd].want_write == 1) { pfds[1].events = POLLOUT; pfds[1].fd = fd; writelen += sizeof(pfds[1]); } if (msg == SELECT_POKE_WRITE && thread->fdpollinfo[fd].want_read == 1) { pfds[1].events = POLLIN; pfds[1].fd = fd; writelen += sizeof(pfds[1]); } if (write(thread->devpoll_fd, pfds, writelen) == -1) { result = isc__errno2result(errno); } else { if (msg == SELECT_POKE_READ) { thread->fdpollinfo[fd].want_read = 0; } else { thread->fdpollinfo[fd].want_write = 0; } } return (result); #elif defined(USE_SELECT) LOCK(&thread->manager->lock); if (msg == SELECT_POKE_READ) { FD_CLR(fd, thread->read_fds); } else if (msg == SELECT_POKE_WRITE) { FD_CLR(fd, thread->write_fds); } UNLOCK(&thread->manager->lock); return (result); #endif /* ifdef USE_KQUEUE */ } /* * A poke message was received, perform a proper watch/unwatch * on a fd provided */ static void wakeup_socket(isc__socketthread_t *thread, int fd, int msg) { isc_result_t result; int lockid = FDLOCK_ID(fd); /* * This is a wakeup on a socket. If the socket is not in the * process of being closed, start watching it for either reads * or writes. */ INSIST(fd >= 0 && fd < (int)thread->manager->maxsocks); if (msg == SELECT_POKE_CLOSE) { LOCK(&thread->fdlock[lockid]); INSIST(thread->fdstate[fd] == CLOSE_PENDING); thread->fdstate[fd] = CLOSED; (void)unwatch_fd(thread, fd, SELECT_POKE_READ); (void)unwatch_fd(thread, fd, SELECT_POKE_WRITE); (void)close(fd); UNLOCK(&thread->fdlock[lockid]); return; } LOCK(&thread->fdlock[lockid]); if (thread->fdstate[fd] == CLOSE_PENDING) { /* * We accept (and ignore) any error from unwatch_fd() as we are * closing the socket, hoping it doesn't leave dangling state in * the kernel. * Note that unwatch_fd() must be called after releasing the * fdlock; otherwise it could cause deadlock due to a lock order * reversal. */ (void)unwatch_fd(thread, fd, SELECT_POKE_READ); (void)unwatch_fd(thread, fd, SELECT_POKE_WRITE); UNLOCK(&thread->fdlock[lockid]); return; } if (thread->fdstate[fd] != MANAGED) { UNLOCK(&thread->fdlock[lockid]); return; } /* * Set requested bit. */ result = watch_fd(thread, fd, msg); if (result != ISC_R_SUCCESS) { /* * XXXJT: what should we do? Ignoring the failure of watching * a socket will make the application dysfunctional, but there * seems to be no reasonable recovery process. */ isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "failed to start watching FD (%d): %s", fd, isc_result_totext(result)); } UNLOCK(&thread->fdlock[lockid]); } /* * Poke the select loop when there is something for us to do. * The write is required (by POSIX) to complete. That is, we * will not get partial writes. */ static void select_poke(isc_socketmgr_t *mgr, int threadid, int fd, int msg) { int cc; int buf[2]; char strbuf[ISC_STRERRORSIZE]; buf[0] = fd; buf[1] = msg; do { cc = write(mgr->threads[threadid].pipe_fds[1], buf, sizeof(buf)); #ifdef ENOSR /* * Treat ENOSR as EAGAIN but loop slowly as it is * unlikely to clear fast. */ if (cc < 0 && errno == ENOSR) { sleep(1); errno = EAGAIN; } #endif /* ifdef ENOSR */ } while (cc < 0 && SOFT_ERROR(errno)); if (cc < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); FATAL_ERROR(__FILE__, __LINE__, "write() failed during watcher poke: %s", strbuf); } INSIST(cc == sizeof(buf)); } /* * Read a message on the internal fd. */ static void select_readmsg(isc__socketthread_t *thread, int *fd, int *msg) { int buf[2]; int cc; char strbuf[ISC_STRERRORSIZE]; cc = read(thread->pipe_fds[0], buf, sizeof(buf)); if (cc < 0) { *msg = SELECT_POKE_NOTHING; *fd = -1; /* Silence compiler. */ if (SOFT_ERROR(errno)) { return; } strerror_r(errno, strbuf, sizeof(strbuf)); FATAL_ERROR(__FILE__, __LINE__, "read() failed during watcher poke: %s", strbuf); } INSIST(cc == sizeof(buf)); *fd = buf[0]; *msg = buf[1]; } /* * Make a fd non-blocking. */ static isc_result_t make_nonblock(int fd) { int ret; char strbuf[ISC_STRERRORSIZE]; #ifdef USE_FIONBIO_IOCTL int on = 1; #else /* ifdef USE_FIONBIO_IOCTL */ int flags; #endif /* ifdef USE_FIONBIO_IOCTL */ #ifdef USE_FIONBIO_IOCTL ret = ioctl(fd, FIONBIO, (char *)&on); #else /* ifdef USE_FIONBIO_IOCTL */ flags = fcntl(fd, F_GETFL, 0); flags |= PORT_NONBLOCK; ret = fcntl(fd, F_SETFL, flags); #endif /* ifdef USE_FIONBIO_IOCTL */ if (ret == -1) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, #ifdef USE_FIONBIO_IOCTL "ioctl(%d, FIONBIO, &on): %s", fd, #else /* ifdef USE_FIONBIO_IOCTL */ "fcntl(%d, F_SETFL, %d): %s", fd, flags, #endif /* ifdef USE_FIONBIO_IOCTL */ strbuf); return (ISC_R_UNEXPECTED); } return (ISC_R_SUCCESS); } #ifdef USE_CMSG /* * Not all OSes support advanced CMSG macros: CMSG_LEN and CMSG_SPACE. * In order to ensure as much portability as possible, we provide wrapper * functions of these macros. * Note that cmsg_space() could run slow on OSes that do not have * CMSG_SPACE. */ static socklen_t cmsg_len(socklen_t len) { #ifdef CMSG_LEN return (CMSG_LEN(len)); #else /* ifdef CMSG_LEN */ socklen_t hdrlen; /* * Cast NULL so that any pointer arithmetic performed by CMSG_DATA * is correct. */ hdrlen = (socklen_t)CMSG_DATA(((struct cmsghdr *)NULL)); return (hdrlen + len); #endif /* ifdef CMSG_LEN */ } static socklen_t cmsg_space(socklen_t len) { #ifdef CMSG_SPACE return (CMSG_SPACE(len)); #else /* ifdef CMSG_SPACE */ struct msghdr msg; struct cmsghdr *cmsgp; /* * XXX: The buffer length is an ad-hoc value, but should be enough * in a practical sense. */ char dummybuf[sizeof(struct cmsghdr) + 1024]; memset(&msg, 0, sizeof(msg)); msg.msg_control = dummybuf; msg.msg_controllen = sizeof(dummybuf); cmsgp = (struct cmsghdr *)dummybuf; cmsgp->cmsg_len = cmsg_len(len); cmsgp = CMSG_NXTHDR(&msg, cmsgp); if (cmsgp != NULL) { return ((char *)cmsgp - (char *)msg.msg_control); } else { return (0); } #endif /* ifdef CMSG_SPACE */ } #endif /* USE_CMSG */ /* * Process control messages received on a socket. */ static void process_cmsg(isc_socket_t *sock, struct msghdr *msg, isc_socketevent_t *dev) { #ifdef USE_CMSG struct cmsghdr *cmsgp; struct in6_pktinfo *pktinfop; #ifdef SO_TIMESTAMP void *timevalp; #endif /* ifdef SO_TIMESTAMP */ #endif /* ifdef USE_CMSG */ /* * sock is used only when ISC_NET_BSD44MSGHDR and USE_CMSG are defined. * msg and dev are used only when ISC_NET_BSD44MSGHDR is defined. * They are all here, outside of the CPP tests, because it is * more consistent with the usual ISC coding style. */ UNUSED(sock); UNUSED(msg); UNUSED(dev); #ifdef MSG_TRUNC if ((msg->msg_flags & MSG_TRUNC) != 0) { dev->attributes |= ISC_SOCKEVENTATTR_TRUNC; } #endif /* ifdef MSG_TRUNC */ #ifdef MSG_CTRUNC if ((msg->msg_flags & MSG_CTRUNC) != 0) { dev->attributes |= ISC_SOCKEVENTATTR_CTRUNC; } #endif /* ifdef MSG_CTRUNC */ #ifndef USE_CMSG return; #else /* ifndef USE_CMSG */ if (msg->msg_controllen == 0U || msg->msg_control == NULL) { return; } #ifdef SO_TIMESTAMP timevalp = NULL; #endif /* ifdef SO_TIMESTAMP */ pktinfop = NULL; cmsgp = CMSG_FIRSTHDR(msg); while (cmsgp != NULL) { socket_log(sock, NULL, TRACE, "processing cmsg %p", cmsgp); if (cmsgp->cmsg_level == IPPROTO_IPV6 && cmsgp->cmsg_type == IPV6_PKTINFO) { pktinfop = (struct in6_pktinfo *)CMSG_DATA(cmsgp); memmove(&dev->pktinfo, pktinfop, sizeof(struct in6_pktinfo)); dev->attributes |= ISC_SOCKEVENTATTR_PKTINFO; socket_log(sock, NULL, TRACE, "interface received on ifindex %u", dev->pktinfo.ipi6_ifindex); if (IN6_IS_ADDR_MULTICAST(&pktinfop->ipi6_addr)) { dev->attributes |= ISC_SOCKEVENTATTR_MULTICAST; } goto next; } #ifdef SO_TIMESTAMP if (cmsgp->cmsg_level == SOL_SOCKET && cmsgp->cmsg_type == SCM_TIMESTAMP) { struct timeval tv; timevalp = CMSG_DATA(cmsgp); memmove(&tv, timevalp, sizeof(tv)); dev->timestamp.seconds = tv.tv_sec; dev->timestamp.nanoseconds = tv.tv_usec * 1000; dev->attributes |= ISC_SOCKEVENTATTR_TIMESTAMP; goto next; } #endif /* ifdef SO_TIMESTAMP */ #ifdef IPV6_TCLASS if (cmsgp->cmsg_level == IPPROTO_IPV6 && cmsgp->cmsg_type == IPV6_TCLASS) { dev->dscp = *(int *)CMSG_DATA(cmsgp); dev->dscp >>= 2; dev->attributes |= ISC_SOCKEVENTATTR_DSCP; goto next; } #endif /* ifdef IPV6_TCLASS */ #ifdef IP_TOS if (cmsgp->cmsg_level == IPPROTO_IP && (cmsgp->cmsg_type == IP_TOS #ifdef IP_RECVTOS || cmsgp->cmsg_type == IP_RECVTOS #endif /* ifdef IP_RECVTOS */ )) { dev->dscp = (int)*(unsigned char *)CMSG_DATA(cmsgp); dev->dscp >>= 2; dev->attributes |= ISC_SOCKEVENTATTR_DSCP; goto next; } #endif /* ifdef IP_TOS */ next: cmsgp = CMSG_NXTHDR(msg, cmsgp); } #endif /* USE_CMSG */ } /* * Construct an iov array and attach it to the msghdr passed in. This is * the SEND constructor, which will use the used region of the buffer * (if using a buffer list) or will use the internal region (if a single * buffer I/O is requested). * * Nothing can be NULL, and the done event must list at least one buffer * on the buffer linked list for this function to be meaningful. * * If write_countp != NULL, *write_countp will hold the number of bytes * this transaction can send. */ static void build_msghdr_send(isc_socket_t *sock, char *cmsgbuf, isc_socketevent_t *dev, struct msghdr *msg, struct iovec *iov, size_t *write_countp) { unsigned int iovcount; size_t write_count; struct cmsghdr *cmsgp; memset(msg, 0, sizeof(*msg)); if (!sock->connected) { msg->msg_name = (void *)&dev->address.type.sa; msg->msg_namelen = dev->address.length; } else { msg->msg_name = NULL; msg->msg_namelen = 0; } write_count = dev->region.length - dev->n; iov[0].iov_base = (void *)(dev->region.base + dev->n); iov[0].iov_len = write_count; iovcount = 1; msg->msg_iov = iov; msg->msg_iovlen = iovcount; msg->msg_control = NULL; msg->msg_controllen = 0; msg->msg_flags = 0; #if defined(USE_CMSG) if ((sock->type == isc_sockettype_udp) && ((dev->attributes & ISC_SOCKEVENTATTR_PKTINFO) != 0)) { struct in6_pktinfo *pktinfop; socket_log(sock, NULL, TRACE, "sendto pktinfo data, ifindex %u", dev->pktinfo.ipi6_ifindex); msg->msg_control = (void *)cmsgbuf; msg->msg_controllen = cmsg_space(sizeof(struct in6_pktinfo)); INSIST(msg->msg_controllen <= SENDCMSGBUFLEN); cmsgp = (struct cmsghdr *)cmsgbuf; cmsgp->cmsg_level = IPPROTO_IPV6; cmsgp->cmsg_type = IPV6_PKTINFO; cmsgp->cmsg_len = cmsg_len(sizeof(struct in6_pktinfo)); pktinfop = (struct in6_pktinfo *)CMSG_DATA(cmsgp); memmove(pktinfop, &dev->pktinfo, sizeof(struct in6_pktinfo)); } #if defined(IPV6_USE_MIN_MTU) if ((sock->type == isc_sockettype_udp) && (sock->pf == AF_INET6) && ((dev->attributes & ISC_SOCKEVENTATTR_USEMINMTU) != 0)) { int use_min_mtu = 1; /* -1, 0, 1 */ cmsgp = (struct cmsghdr *)(cmsgbuf + msg->msg_controllen); msg->msg_control = (void *)cmsgbuf; msg->msg_controllen += cmsg_space(sizeof(use_min_mtu)); INSIST(msg->msg_controllen <= SENDCMSGBUFLEN); cmsgp->cmsg_level = IPPROTO_IPV6; cmsgp->cmsg_type = IPV6_USE_MIN_MTU; cmsgp->cmsg_len = cmsg_len(sizeof(use_min_mtu)); memmove(CMSG_DATA(cmsgp), &use_min_mtu, sizeof(use_min_mtu)); } #endif /* if defined(IPV6_USE_MIN_MTU) */ if (isc_dscp_check_value > -1) { if (sock->type == isc_sockettype_udp) { INSIST((int)dev->dscp == isc_dscp_check_value); } else if (sock->type == isc_sockettype_tcp) { INSIST((int)sock->dscp == isc_dscp_check_value); } } #if defined(IP_TOS) || (defined(IPPROTO_IPV6) && defined(IPV6_TCLASS)) if ((sock->type == isc_sockettype_udp) && ((dev->attributes & ISC_SOCKEVENTATTR_DSCP) != 0)) { int dscp = (dev->dscp << 2) & 0xff; INSIST(dev->dscp < 0x40); #ifdef IP_TOS if (sock->pf == AF_INET && sock->pktdscp) { cmsgp = (struct cmsghdr *)(cmsgbuf + msg->msg_controllen); msg->msg_control = (void *)cmsgbuf; msg->msg_controllen += cmsg_space(sizeof(dscp)); INSIST(msg->msg_controllen <= SENDCMSGBUFLEN); cmsgp->cmsg_level = IPPROTO_IP; cmsgp->cmsg_type = IP_TOS; cmsgp->cmsg_len = cmsg_len(sizeof(char)); *(unsigned char *)CMSG_DATA(cmsgp) = dscp; } else if (sock->pf == AF_INET && sock->dscp != dev->dscp) { if (setsockopt(sock->fd, IPPROTO_IP, IP_TOS, (void *)&dscp, sizeof(int)) < 0) { char strbuf[ISC_STRERRORSIZE]; strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IP_TOS, %.02x)" " failed: %s", sock->fd, dscp >> 2, strbuf); } else { sock->dscp = dscp; } } #endif /* ifdef IP_TOS */ #if defined(IPPROTO_IPV6) && defined(IPV6_TCLASS) if (sock->pf == AF_INET6 && sock->pktdscp) { cmsgp = (struct cmsghdr *)(cmsgbuf + msg->msg_controllen); msg->msg_control = (void *)cmsgbuf; msg->msg_controllen += cmsg_space(sizeof(dscp)); INSIST(msg->msg_controllen <= SENDCMSGBUFLEN); cmsgp->cmsg_level = IPPROTO_IPV6; cmsgp->cmsg_type = IPV6_TCLASS; cmsgp->cmsg_len = cmsg_len(sizeof(dscp)); memmove(CMSG_DATA(cmsgp), &dscp, sizeof(dscp)); } else if (sock->pf == AF_INET6 && sock->dscp != dev->dscp) { if (setsockopt(sock->fd, IPPROTO_IPV6, IPV6_TCLASS, (void *)&dscp, sizeof(int)) < 0) { char strbuf[ISC_STRERRORSIZE]; strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IPV6_TCLASS, " "%.02x) failed: %s", sock->fd, dscp >> 2, strbuf); } else { sock->dscp = dscp; } } #endif /* if defined(IPPROTO_IPV6) && defined(IPV6_TCLASS) */ if (msg->msg_controllen != 0 && msg->msg_controllen < SENDCMSGBUFLEN) { memset(cmsgbuf + msg->msg_controllen, 0, SENDCMSGBUFLEN - msg->msg_controllen); } } #endif /* if defined(IP_TOS) || (defined(IPPROTO_IPV6) && \ * defined(IPV6_TCLASS)) \ * */ #endif /* USE_CMSG */ if (write_countp != NULL) { *write_countp = write_count; } } /* * Construct an iov array and attach it to the msghdr passed in. This is * the RECV constructor, which will use the available region of the buffer * (if using a buffer list) or will use the internal region (if a single * buffer I/O is requested). * * Nothing can be NULL, and the done event must list at least one buffer * on the buffer linked list for this function to be meaningful. * * If read_countp != NULL, *read_countp will hold the number of bytes * this transaction can receive. */ static void build_msghdr_recv(isc_socket_t *sock, char *cmsgbuf, isc_socketevent_t *dev, struct msghdr *msg, struct iovec *iov, size_t *read_countp) { unsigned int iovcount; size_t read_count; memset(msg, 0, sizeof(struct msghdr)); if (sock->type == isc_sockettype_udp) { memset(&dev->address, 0, sizeof(dev->address)); msg->msg_name = (void *)&dev->address.type.sa; msg->msg_namelen = sizeof(dev->address.type); } else { /* TCP */ msg->msg_name = NULL; msg->msg_namelen = 0; dev->address = sock->peer_address; } read_count = dev->region.length - dev->n; iov[0].iov_base = (void *)(dev->region.base + dev->n); iov[0].iov_len = read_count; iovcount = 1; /* * If needed, set up to receive that one extra byte. */ #ifdef ISC_PLATFORM_RECVOVERFLOW if (sock->type == isc_sockettype_udp) { INSIST(iovcount < MAXSCATTERGATHER_RECV); iov[iovcount].iov_base = (void *)(&sock->overflow); iov[iovcount].iov_len = 1; iovcount++; } #endif /* ifdef ISC_PLATFORM_RECVOVERFLOW */ msg->msg_iov = iov; msg->msg_iovlen = iovcount; #if defined(USE_CMSG) msg->msg_control = cmsgbuf; msg->msg_controllen = RECVCMSGBUFLEN; #else /* if defined(USE_CMSG) */ msg->msg_control = NULL; msg->msg_controllen = 0; #endif /* USE_CMSG */ msg->msg_flags = 0; if (read_countp != NULL) { *read_countp = read_count; } } static void set_dev_address(const isc_sockaddr_t *address, isc_socket_t *sock, isc_socketevent_t *dev) { if (sock->type == isc_sockettype_udp) { if (address != NULL) { dev->address = *address; } else { dev->address = sock->peer_address; } } else if (sock->type == isc_sockettype_tcp) { INSIST(address == NULL); dev->address = sock->peer_address; } } static void destroy_socketevent(isc_event_t *event) { isc_socketevent_t *ev = (isc_socketevent_t *)event; (ev->destroy)(event); } static isc_socketevent_t * allocate_socketevent(isc_mem_t *mctx, void *sender, isc_eventtype_t eventtype, isc_taskaction_t action, void *arg) { isc_socketevent_t *ev; ev = (isc_socketevent_t *)isc_event_allocate(mctx, sender, eventtype, action, arg, sizeof(*ev)); ev->result = ISC_R_UNSET; ISC_LINK_INIT(ev, ev_link); ev->region.base = NULL; ev->n = 0; ev->offset = 0; ev->attributes = 0; ev->destroy = ev->ev_destroy; ev->ev_destroy = destroy_socketevent; ev->dscp = 0; return (ev); } #if defined(ISC_SOCKET_DEBUG) static void dump_msg(struct msghdr *msg) { unsigned int i; printf("MSGHDR %p\n", msg); printf("\tname %p, namelen %ld\n", msg->msg_name, (long)msg->msg_namelen); printf("\tiov %p, iovlen %ld\n", msg->msg_iov, (long)msg->msg_iovlen); for (i = 0; i < (unsigned int)msg->msg_iovlen; i++) { printf("\t\t%u\tbase %p, len %ld\n", i, msg->msg_iov[i].iov_base, (long)msg->msg_iov[i].iov_len); } printf("\tcontrol %p, controllen %ld\n", msg->msg_control, (long)msg->msg_controllen); } #endif /* if defined(ISC_SOCKET_DEBUG) */ #define DOIO_SUCCESS 0 /* i/o ok, event sent */ #define DOIO_SOFT 1 /* i/o ok, soft error, no event sent */ #define DOIO_HARD 2 /* i/o error, event sent */ #define DOIO_EOF 3 /* EOF, no event sent */ static int doio_recv(isc_socket_t *sock, isc_socketevent_t *dev) { int cc; struct iovec iov[MAXSCATTERGATHER_RECV]; size_t read_count; struct msghdr msghdr; int recv_errno; char strbuf[ISC_STRERRORSIZE]; char cmsgbuf[RECVCMSGBUFLEN] = { 0 }; build_msghdr_recv(sock, cmsgbuf, dev, &msghdr, iov, &read_count); #if defined(ISC_SOCKET_DEBUG) dump_msg(&msghdr); #endif /* if defined(ISC_SOCKET_DEBUG) */ cc = recvmsg(sock->fd, &msghdr, 0); recv_errno = errno; #if defined(ISC_SOCKET_DEBUG) dump_msg(&msghdr); #endif /* if defined(ISC_SOCKET_DEBUG) */ if (cc < 0) { if (SOFT_ERROR(recv_errno)) { return (DOIO_SOFT); } if (isc_log_wouldlog(isc_lctx, IOEVENT_LEVEL)) { strerror_r(recv_errno, strbuf, sizeof(strbuf)); socket_log(sock, NULL, IOEVENT, "doio_recv: recvmsg(%d) %d bytes, err %d/%s", sock->fd, cc, recv_errno, strbuf); } #define SOFT_OR_HARD(_system, _isc) \ if (recv_errno == _system) { \ if (sock->connected) { \ dev->result = _isc; \ inc_stats(sock->manager->stats, \ sock->statsindex[STATID_RECVFAIL]); \ return (DOIO_HARD); \ } \ return (DOIO_SOFT); \ } #define ALWAYS_HARD(_system, _isc) \ if (recv_errno == _system) { \ dev->result = _isc; \ inc_stats(sock->manager->stats, \ sock->statsindex[STATID_RECVFAIL]); \ return (DOIO_HARD); \ } SOFT_OR_HARD(ECONNREFUSED, ISC_R_CONNREFUSED); SOFT_OR_HARD(ENETUNREACH, ISC_R_NETUNREACH); SOFT_OR_HARD(EHOSTUNREACH, ISC_R_HOSTUNREACH); SOFT_OR_HARD(EHOSTDOWN, ISC_R_HOSTDOWN); SOFT_OR_HARD(ENOBUFS, ISC_R_NORESOURCES); /* * Older operating systems may still return EPROTO in some * situations, for example when receiving ICMP/ICMPv6 errors. * A real life scenario is when ICMPv6 returns code 5 or 6. * These codes are introduced in RFC 4443 from March 2006, * and the document obsoletes RFC 1885. But unfortunately not * all operating systems have caught up with the new standard * (in 2020) and thus a generic protocol error is returned. */ SOFT_OR_HARD(EPROTO, ISC_R_HOSTUNREACH); /* Should never get this one but it was seen. */ #ifdef ENOPROTOOPT SOFT_OR_HARD(ENOPROTOOPT, ISC_R_HOSTUNREACH); #endif /* ifdef ENOPROTOOPT */ SOFT_OR_HARD(EINVAL, ISC_R_HOSTUNREACH); #undef SOFT_OR_HARD #undef ALWAYS_HARD dev->result = isc__errno2result(recv_errno); inc_stats(sock->manager->stats, sock->statsindex[STATID_RECVFAIL]); return (DOIO_HARD); } /* * On TCP and UNIX sockets, zero length reads indicate EOF, * while on UDP sockets, zero length reads are perfectly valid, * although strange. */ switch (sock->type) { case isc_sockettype_tcp: case isc_sockettype_unix: if (cc == 0) { return (DOIO_EOF); } break; case isc_sockettype_udp: case isc_sockettype_raw: break; case isc_sockettype_fdwatch: default: UNREACHABLE(); } if (sock->type == isc_sockettype_udp) { dev->address.length = msghdr.msg_namelen; if (isc_sockaddr_getport(&dev->address) == 0) { if (isc_log_wouldlog(isc_lctx, IOEVENT_LEVEL)) { socket_log(sock, &dev->address, IOEVENT, "dropping source port zero packet"); } return (DOIO_SOFT); } /* * Simulate a firewall blocking UDP responses bigger than * 'maxudp' bytes. */ if (sock->manager->maxudp != 0 && cc > (int)sock->manager->maxudp) { return (DOIO_SOFT); } } socket_log(sock, &dev->address, IOEVENT, "packet received correctly"); /* * Overflow bit detection. If we received MORE bytes than we should, * this indicates an overflow situation. Set the flag in the * dev entry and adjust how much we read by one. */ #ifdef ISC_PLATFORM_RECVOVERFLOW if ((sock->type == isc_sockettype_udp) && ((size_t)cc > read_count)) { dev->attributes |= ISC_SOCKEVENTATTR_TRUNC; cc--; } #endif /* ifdef ISC_PLATFORM_RECVOVERFLOW */ /* * If there are control messages attached, run through them and pull * out the interesting bits. */ process_cmsg(sock, &msghdr, dev); /* * update the buffers (if any) and the i/o count */ dev->n += cc; /* * If we read less than we expected, update counters, * and let the upper layer poke the descriptor. */ if (((size_t)cc != read_count) && (dev->n < dev->minimum)) { return (DOIO_SOFT); } /* * Full reads are posted, or partials if partials are ok. */ dev->result = ISC_R_SUCCESS; return (DOIO_SUCCESS); } /* * Returns: * DOIO_SUCCESS The operation succeeded. dev->result contains * ISC_R_SUCCESS. * * DOIO_HARD A hard or unexpected I/O error was encountered. * dev->result contains the appropriate error. * * DOIO_SOFT A soft I/O error was encountered. No senddone * event was sent. The operation should be retried. * * No other return values are possible. */ static int doio_send(isc_socket_t *sock, isc_socketevent_t *dev) { int cc; struct iovec iov[MAXSCATTERGATHER_SEND]; size_t write_count; struct msghdr msghdr; char addrbuf[ISC_SOCKADDR_FORMATSIZE]; int attempts = 0; int send_errno; char strbuf[ISC_STRERRORSIZE]; char cmsgbuf[SENDCMSGBUFLEN] = { 0 }; build_msghdr_send(sock, cmsgbuf, dev, &msghdr, iov, &write_count); resend: if (sock->type == isc_sockettype_udp && sock->manager->maxudp != 0 && write_count > sock->manager->maxudp) { cc = write_count; } else { cc = sendmsg(sock->fd, &msghdr, 0); } send_errno = errno; /* * Check for error or block condition. */ if (cc < 0) { if (send_errno == EINTR && ++attempts < NRETRIES) { goto resend; } if (SOFT_ERROR(send_errno)) { if (errno == EWOULDBLOCK || errno == EAGAIN) { dev->result = ISC_R_WOULDBLOCK; } return (DOIO_SOFT); } #define SOFT_OR_HARD(_system, _isc) \ if (send_errno == _system) { \ if (sock->connected) { \ dev->result = _isc; \ inc_stats(sock->manager->stats, \ sock->statsindex[STATID_SENDFAIL]); \ return (DOIO_HARD); \ } \ return (DOIO_SOFT); \ } #define ALWAYS_HARD(_system, _isc) \ if (send_errno == _system) { \ dev->result = _isc; \ inc_stats(sock->manager->stats, \ sock->statsindex[STATID_SENDFAIL]); \ return (DOIO_HARD); \ } SOFT_OR_HARD(ECONNREFUSED, ISC_R_CONNREFUSED); ALWAYS_HARD(EACCES, ISC_R_NOPERM); ALWAYS_HARD(EAFNOSUPPORT, ISC_R_ADDRNOTAVAIL); ALWAYS_HARD(EADDRNOTAVAIL, ISC_R_ADDRNOTAVAIL); ALWAYS_HARD(EHOSTUNREACH, ISC_R_HOSTUNREACH); #ifdef EHOSTDOWN ALWAYS_HARD(EHOSTDOWN, ISC_R_HOSTUNREACH); #endif /* ifdef EHOSTDOWN */ ALWAYS_HARD(ENETUNREACH, ISC_R_NETUNREACH); SOFT_OR_HARD(ENOBUFS, ISC_R_NORESOURCES); ALWAYS_HARD(EPERM, ISC_R_HOSTUNREACH); ALWAYS_HARD(EPIPE, ISC_R_NOTCONNECTED); ALWAYS_HARD(ECONNRESET, ISC_R_CONNECTIONRESET); #undef SOFT_OR_HARD #undef ALWAYS_HARD /* * The other error types depend on whether or not the * socket is UDP or TCP. If it is UDP, some errors * that we expect to be fatal under TCP are merely * annoying, and are really soft errors. * * However, these soft errors are still returned as * a status. */ isc_sockaddr_format(&dev->address, addrbuf, sizeof(addrbuf)); strerror_r(send_errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "internal_send: %s: %s", addrbuf, strbuf); dev->result = isc__errno2result(send_errno); inc_stats(sock->manager->stats, sock->statsindex[STATID_SENDFAIL]); return (DOIO_HARD); } if (cc == 0) { inc_stats(sock->manager->stats, sock->statsindex[STATID_SENDFAIL]); UNEXPECTED_ERROR(__FILE__, __LINE__, "doio_send: send() returned 0"); } /* * If we write less than we expected, update counters, poke. */ dev->n += cc; if ((size_t)cc != write_count) { return (DOIO_SOFT); } /* * Exactly what we wanted to write. We're done with this * entry. Post its completion event. */ dev->result = ISC_R_SUCCESS; return (DOIO_SUCCESS); } /* * Kill. * * Caller must ensure that the socket is not locked and no external * references exist. */ static void socketclose(isc__socketthread_t *thread, isc_socket_t *sock, int fd) { int lockid = FDLOCK_ID(fd); /* * No one has this socket open, so the watcher doesn't have to be * poked, and the socket doesn't have to be locked. */ LOCK(&thread->fdlock[lockid]); thread->fds[fd] = NULL; if (sock->type == isc_sockettype_fdwatch) thread->fdstate[fd] = CLOSED; else thread->fdstate[fd] = CLOSE_PENDING; UNLOCK(&thread->fdlock[lockid]); if (sock->type == isc_sockettype_fdwatch) { /* * The caller may close the socket once this function returns, * and `fd' may be reassigned for a new socket. So we do * unwatch_fd() here, rather than defer it via select_poke(). * Note: this may complicate data protection among threads and * may reduce performance due to additional locks. One way to * solve this would be to dup() the watched descriptor, but we * take a simpler approach at this moment. */ (void)unwatch_fd(thread, fd, SELECT_POKE_READ); (void)unwatch_fd(thread, fd, SELECT_POKE_WRITE); } else select_poke(thread->manager, thread->threadid, fd, SELECT_POKE_CLOSE); inc_stats(thread->manager->stats, sock->statsindex[STATID_CLOSE]); LOCK(&sock->lock); if (sock->active == 1) { dec_stats(thread->manager->stats, sock->statsindex[STATID_ACTIVE]); sock->active = 0; } UNLOCK(&sock->lock); /* * update manager->maxfd here (XXX: this should be implemented more * efficiently) */ #ifdef USE_SELECT LOCK(&thread->manager->lock); if (thread->maxfd == fd) { int i; thread->maxfd = 0; for (i = fd - 1; i >= 0; i--) { lockid = FDLOCK_ID(i); LOCK(&thread->fdlock[lockid]); if (thread->fdstate[i] == MANAGED) { thread->maxfd = i; UNLOCK(&thread->fdlock[lockid]); break; } UNLOCK(&thread->fdlock[lockid]); } if (thread->maxfd < thread->pipe_fds[0]) { thread->maxfd = thread->pipe_fds[0]; } } UNLOCK(&thread->manager->lock); #endif /* USE_SELECT */ } static void destroy(isc_socket_t **sockp) { int fd = 0; isc_socket_t *sock = *sockp; isc_socketmgr_t *manager = sock->manager; isc__socketthread_t *thread = NULL; socket_log(sock, NULL, CREATION, "destroying"); isc_refcount_destroy(&sock->references); LOCK(&sock->lock); INSIST(ISC_LIST_EMPTY(sock->connect_list)); INSIST(ISC_LIST_EMPTY(sock->accept_list)); INSIST(ISC_LIST_EMPTY(sock->recv_list)); INSIST(ISC_LIST_EMPTY(sock->send_list)); INSIST(sock->fd >= -1 && sock->fd < (int)manager->maxsocks); if (sock->fd >= 0) { fd = sock->fd; thread = &manager->threads[sock->threadid]; sock->fd = -1; sock->threadid = -1; } UNLOCK(&sock->lock); if (fd > 0) { socketclose(thread, sock, fd); } LOCK(&manager->lock); ISC_LIST_UNLINK(manager->socklist, sock, link); if (ISC_LIST_EMPTY(manager->socklist)) { SIGNAL(&manager->shutdown_ok); } /* can't unlock manager as its memory context is still used */ free_socket(sockp); UNLOCK(&manager->lock); } static isc_result_t allocate_socket(isc_socketmgr_t *manager, isc_sockettype_t type, isc_socket_t **socketp) { isc_socket_t *sock; sock = isc_mem_get(manager->mctx, sizeof(*sock)); sock->magic = 0; isc_refcount_init(&sock->references, 0); sock->manager = manager; sock->type = type; sock->fd = -1; sock->threadid = -1; sock->dscp = 0; /* TOS/TCLASS is zero until set. */ sock->dupped = 0; sock->statsindex = NULL; sock->active = 0; ISC_LINK_INIT(sock, link); memset(sock->name, 0, sizeof(sock->name)); sock->tag = NULL; /* * Set up list of readers and writers to be initially empty. */ ISC_LIST_INIT(sock->recv_list); ISC_LIST_INIT(sock->send_list); ISC_LIST_INIT(sock->accept_list); ISC_LIST_INIT(sock->connect_list); sock->listener = 0; sock->connected = 0; sock->connecting = 0; sock->bound = 0; sock->pktdscp = 0; /* * Initialize the lock. */ isc_mutex_init(&sock->lock); sock->magic = SOCKET_MAGIC; *socketp = sock; return (ISC_R_SUCCESS); } /* * This event requires that the various lists be empty, that the reference * count be 1, and that the magic number is valid. The other socket bits, * like the lock, must be initialized as well. The fd associated must be * marked as closed, by setting it to -1 on close, or this routine will * also close the socket. */ static void free_socket(isc_socket_t **socketp) { isc_socket_t *sock = *socketp; *socketp = NULL; INSIST(VALID_SOCKET(sock)); isc_refcount_destroy(&sock->references); LOCK(&sock->lock); INSIST(!sock->connecting); INSIST(ISC_LIST_EMPTY(sock->recv_list)); INSIST(ISC_LIST_EMPTY(sock->send_list)); INSIST(ISC_LIST_EMPTY(sock->accept_list)); INSIST(ISC_LIST_EMPTY(sock->connect_list)); INSIST(!ISC_LINK_LINKED(sock, link)); UNLOCK(&sock->lock); sock->magic = 0; isc_mutex_destroy(&sock->lock); isc_mem_put(sock->manager->mctx, sock, sizeof(*sock)); } #if defined(SET_RCVBUF) static isc_once_t rcvbuf_once = ISC_ONCE_INIT; static int rcvbuf = ISC_RECV_BUFFER_SIZE; static void set_rcvbuf(void) { int fd; int max = rcvbuf, min; socklen_t len; fd = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); if (fd == -1) { switch (errno) { case EPROTONOSUPPORT: case EPFNOSUPPORT: case EAFNOSUPPORT: /* * Linux 2.2 (and maybe others) return EINVAL instead of * EAFNOSUPPORT. */ case EINVAL: fd = socket(AF_INET6, SOCK_DGRAM, IPPROTO_UDP); break; } } if (fd == -1) { return; } len = sizeof(min); if (getsockopt(fd, SOL_SOCKET, SO_RCVBUF, (void *)&min, &len) == 0 && min < rcvbuf) { again: if (setsockopt(fd, SOL_SOCKET, SO_RCVBUF, (void *)&rcvbuf, sizeof(rcvbuf)) == -1) { if (errno == ENOBUFS && rcvbuf > min) { max = rcvbuf - 1; rcvbuf = (rcvbuf + min) / 2; goto again; } else { rcvbuf = min; goto cleanup; } } else { min = rcvbuf; } if (min != max) { rcvbuf = max; goto again; } } cleanup: close(fd); } #endif /* ifdef SO_RCVBUF */ #if defined(SET_SNDBUF) static isc_once_t sndbuf_once = ISC_ONCE_INIT; static int sndbuf = ISC_SEND_BUFFER_SIZE; static void set_sndbuf(void) { int fd; int max = sndbuf, min; socklen_t len; fd = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP); if (fd == -1) { switch (errno) { case EPROTONOSUPPORT: case EPFNOSUPPORT: case EAFNOSUPPORT: /* * Linux 2.2 (and maybe others) return EINVAL instead of * EAFNOSUPPORT. */ case EINVAL: fd = socket(AF_INET6, SOCK_DGRAM, IPPROTO_UDP); break; } } if (fd == -1) { return; } len = sizeof(min); if (getsockopt(fd, SOL_SOCKET, SO_SNDBUF, (void *)&min, &len) == 0 && min < sndbuf) { again: if (setsockopt(fd, SOL_SOCKET, SO_SNDBUF, (void *)&sndbuf, sizeof(sndbuf)) == -1) { if (errno == ENOBUFS && sndbuf > min) { max = sndbuf - 1; sndbuf = (sndbuf + min) / 2; goto again; } else { sndbuf = min; goto cleanup; } } else { min = sndbuf; } if (min != max) { sndbuf = max; goto again; } } cleanup: close(fd); } #endif /* ifdef SO_SNDBUF */ static void use_min_mtu(isc_socket_t *sock) { #if !defined(IPV6_USE_MIN_MTU) && !defined(IPV6_MTU) UNUSED(sock); #endif /* if !defined(IPV6_USE_MIN_MTU) && !defined(IPV6_MTU) */ #ifdef IPV6_USE_MIN_MTU /* use minimum MTU */ if (sock->pf == AF_INET6) { int on = 1; (void)setsockopt(sock->fd, IPPROTO_IPV6, IPV6_USE_MIN_MTU, (void *)&on, sizeof(on)); } #endif /* ifdef IPV6_USE_MIN_MTU */ #if defined(IPV6_MTU) /* * Use minimum MTU on IPv6 sockets. */ if (sock->pf == AF_INET6) { int mtu = 1280; (void)setsockopt(sock->fd, IPPROTO_IPV6, IPV6_MTU, &mtu, sizeof(mtu)); } #endif /* if defined(IPV6_MTU) */ } static void set_tcp_maxseg(isc_socket_t *sock, int size) { #ifdef TCP_MAXSEG if (sock->type == isc_sockettype_tcp) { (void)setsockopt(sock->fd, IPPROTO_TCP, TCP_MAXSEG, (void *)&size, sizeof(size)); } #endif /* ifdef TCP_MAXSEG */ } static void set_ip_disable_pmtud(isc_socket_t *sock) { /* * Disable Path MTU Discover on IP packets */ if (sock->pf == AF_INET6) { #if defined(IPV6_DONTFRAG) (void)setsockopt(sock->fd, IPPROTO_IPV6, IPV6_DONTFRAG, &(int){ 0 }, sizeof(int)); #endif #if defined(IPV6_MTU_DISCOVER) && defined(IP_PMTUDISC_OMIT) (void)setsockopt(sock->fd, IPPROTO_IPV6, IPV6_MTU_DISCOVER, &(int){ IP_PMTUDISC_OMIT }, sizeof(int)); #endif } else if (sock->pf == AF_INET) { #if defined(IP_DONTFRAG) (void)setsockopt(sock->fd, IPPROTO_IP, IP_DONTFRAG, &(int){ 0 }, sizeof(int)); #endif #if defined(IP_MTU_DISCOVER) && defined(IP_PMTUDISC_OMIT) (void)setsockopt(sock->fd, IPPROTO_IP, IP_MTU_DISCOVER, &(int){ IP_PMTUDISC_OMIT }, sizeof(int)); #endif } } static isc_result_t opensocket(isc_socketmgr_t *manager, isc_socket_t *sock, isc_socket_t *dup_socket) { isc_result_t result; char strbuf[ISC_STRERRORSIZE]; const char *err = "socket"; int tries = 0; #if defined(USE_CMSG) || defined(SO_NOSIGPIPE) int on = 1; #endif /* if defined(USE_CMSG) || defined(SO_NOSIGPIPE) */ #if defined(SET_RCVBUF) || defined(SET_SNDBUF) socklen_t optlen; int size = 0; #endif again: if (dup_socket == NULL) { switch (sock->type) { case isc_sockettype_udp: sock->fd = socket(sock->pf, SOCK_DGRAM, IPPROTO_UDP); break; case isc_sockettype_tcp: sock->fd = socket(sock->pf, SOCK_STREAM, IPPROTO_TCP); break; case isc_sockettype_unix: sock->fd = socket(sock->pf, SOCK_STREAM, 0); break; case isc_sockettype_raw: errno = EPFNOSUPPORT; /* * PF_ROUTE is a alias for PF_NETLINK on linux. */ #if defined(PF_ROUTE) if (sock->fd == -1 && sock->pf == PF_ROUTE) { #ifdef NETLINK_ROUTE sock->fd = socket(sock->pf, SOCK_RAW, NETLINK_ROUTE); #else /* ifdef NETLINK_ROUTE */ sock->fd = socket(sock->pf, SOCK_RAW, 0); #endif /* ifdef NETLINK_ROUTE */ if (sock->fd != -1) { #ifdef NETLINK_ROUTE struct sockaddr_nl sa; int n; /* * Do an implicit bind. */ memset(&sa, 0, sizeof(sa)); sa.nl_family = AF_NETLINK; sa.nl_groups = RTMGRP_IPV4_IFADDR | RTMGRP_IPV6_IFADDR; n = bind(sock->fd, (struct sockaddr *)&sa, sizeof(sa)); if (n < 0) { close(sock->fd); sock->fd = -1; } #endif /* ifdef NETLINK_ROUTE */ sock->bound = 1; } } #endif /* if defined(PF_ROUTE) */ break; case isc_sockettype_fdwatch: /* * We should not be called for isc_sockettype_fdwatch * sockets. */ INSIST(0); break; } } else { sock->fd = dup(dup_socket->fd); sock->dupped = 1; sock->bound = dup_socket->bound; } if (sock->fd == -1 && errno == EINTR && tries++ < 42) { goto again; } #ifdef F_DUPFD /* * Leave a space for stdio and TCP to work in. */ if (manager->reserved != 0 && sock->type == isc_sockettype_udp && sock->fd >= 0 && sock->fd < manager->reserved) { int newfd, tmp; newfd = fcntl(sock->fd, F_DUPFD, manager->reserved); tmp = errno; (void)close(sock->fd); errno = tmp; sock->fd = newfd; err = "isc_socket_create: fcntl/reserved"; } else if (sock->fd >= 0 && sock->fd < 20) { int newfd, tmp; newfd = fcntl(sock->fd, F_DUPFD, 20); tmp = errno; (void)close(sock->fd); errno = tmp; sock->fd = newfd; err = "isc_socket_create: fcntl"; } #endif /* ifdef F_DUPFD */ if (sock->fd >= (int)manager->maxsocks) { (void)close(sock->fd); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "socket: file descriptor exceeds limit (%d/%u)", sock->fd, manager->maxsocks); inc_stats(manager->stats, sock->statsindex[STATID_OPENFAIL]); return (ISC_R_NORESOURCES); } if (sock->fd < 0) { switch (errno) { case EMFILE: case ENFILE: strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "%s: %s", err, strbuf); FALLTHROUGH; case ENOBUFS: inc_stats(manager->stats, sock->statsindex[STATID_OPENFAIL]); return (ISC_R_NORESOURCES); case EPROTONOSUPPORT: case EPFNOSUPPORT: case EAFNOSUPPORT: /* * Linux 2.2 (and maybe others) return EINVAL instead of * EAFNOSUPPORT. */ case EINVAL: inc_stats(manager->stats, sock->statsindex[STATID_OPENFAIL]); return (ISC_R_FAMILYNOSUPPORT); default: strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "%s() failed: %s", err, strbuf); inc_stats(manager->stats, sock->statsindex[STATID_OPENFAIL]); return (ISC_R_UNEXPECTED); } } if (dup_socket != NULL) { goto setup_done; } result = make_nonblock(sock->fd); if (result != ISC_R_SUCCESS) { (void)close(sock->fd); inc_stats(manager->stats, sock->statsindex[STATID_OPENFAIL]); return (result); } #ifdef SO_NOSIGPIPE if (setsockopt(sock->fd, SOL_SOCKET, SO_NOSIGPIPE, (void *)&on, sizeof(on)) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, SO_NOSIGPIPE) failed: %s", sock->fd, strbuf); /* Press on... */ } #endif /* ifdef SO_NOSIGPIPE */ /* * Use minimum mtu if possible. */ if (sock->type == isc_sockettype_tcp && sock->pf == AF_INET6) { use_min_mtu(sock); set_tcp_maxseg(sock, 1280 - 20 - 40); /* 1280 - TCP - IPV6 */ } #if defined(USE_CMSG) || defined(SET_RCVBUF) || defined(SET_SNDBUF) if (sock->type == isc_sockettype_udp) { #if defined(USE_CMSG) #if defined(SO_TIMESTAMP) if (setsockopt(sock->fd, SOL_SOCKET, SO_TIMESTAMP, (void *)&on, sizeof(on)) < 0 && errno != ENOPROTOOPT) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, SO_TIMESTAMP) failed: " "%s", sock->fd, strbuf); /* Press on... */ } #endif /* SO_TIMESTAMP */ #ifdef IPV6_RECVPKTINFO /* RFC 3542 */ if ((sock->pf == AF_INET6) && (setsockopt(sock->fd, IPPROTO_IPV6, IPV6_RECVPKTINFO, (void *)&on, sizeof(on)) < 0)) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IPV6_RECVPKTINFO) " "failed: %s", sock->fd, strbuf); } #else /* ifdef IPV6_RECVPKTINFO */ /* RFC 2292 */ if ((sock->pf == AF_INET6) && (setsockopt(sock->fd, IPPROTO_IPV6, IPV6_PKTINFO, (void *)&on, sizeof(on)) < 0)) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IPV6_PKTINFO) failed: " "%s", sock->fd, strbuf); } #endif /* IPV6_RECVPKTINFO */ #endif /* defined(USE_CMSG) */ #if defined(SET_RCVBUF) optlen = sizeof(size); if (getsockopt(sock->fd, SOL_SOCKET, SO_RCVBUF, (void *)&size, &optlen) == 0 && size < rcvbuf) { RUNTIME_CHECK(isc_once_do(&rcvbuf_once, set_rcvbuf) == ISC_R_SUCCESS); if (setsockopt(sock->fd, SOL_SOCKET, SO_RCVBUF, (void *)&rcvbuf, sizeof(rcvbuf)) == -1) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, SO_RCVBUF, " "%d) failed: %s", sock->fd, rcvbuf, strbuf); } } #endif /* if defined(SET_RCVBUF) */ #if defined(SET_SNDBUF) optlen = sizeof(size); if (getsockopt(sock->fd, SOL_SOCKET, SO_SNDBUF, (void *)&size, &optlen) == 0 && size < sndbuf) { RUNTIME_CHECK(isc_once_do(&sndbuf_once, set_sndbuf) == ISC_R_SUCCESS); if (setsockopt(sock->fd, SOL_SOCKET, SO_SNDBUF, (void *)&sndbuf, sizeof(sndbuf)) == -1) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, SO_SNDBUF, " "%d) failed: %s", sock->fd, sndbuf, strbuf); } } #endif /* if defined(SO_SNDBUF) */ } #ifdef IPV6_RECVTCLASS if ((sock->pf == AF_INET6) && (setsockopt(sock->fd, IPPROTO_IPV6, IPV6_RECVTCLASS, (void *)&on, sizeof(on)) < 0)) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IPV6_RECVTCLASS) " "failed: %s", sock->fd, strbuf); } #endif /* ifdef IPV6_RECVTCLASS */ #ifdef IP_RECVTOS if ((sock->pf == AF_INET) && (setsockopt(sock->fd, IPPROTO_IP, IP_RECVTOS, (void *)&on, sizeof(on)) < 0)) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IP_RECVTOS) " "failed: %s", sock->fd, strbuf); } #endif /* ifdef IP_RECVTOS */ #endif /* defined(USE_CMSG) || defined(SET_RCVBUF) || defined(SET_SNDBUF) */ set_ip_disable_pmtud(sock); setup_done: inc_stats(manager->stats, sock->statsindex[STATID_OPEN]); if (sock->active == 0) { inc_stats(manager->stats, sock->statsindex[STATID_ACTIVE]); sock->active = 1; } return (ISC_R_SUCCESS); } /* * Create a 'type' socket or duplicate an existing socket, managed * by 'manager'. Events will be posted to 'task' and when dispatched * 'action' will be called with 'arg' as the arg value. The new * socket is returned in 'socketp'. */ static isc_result_t socket_create(isc_socketmgr_t *manager, int pf, isc_sockettype_t type, isc_socket_t **socketp, isc_socket_t *dup_socket) { isc_socket_t *sock = NULL; isc__socketthread_t *thread; isc_result_t result; int lockid; REQUIRE(VALID_MANAGER(manager)); REQUIRE(socketp != NULL && *socketp == NULL); REQUIRE(type != isc_sockettype_fdwatch); result = allocate_socket(manager, type, &sock); if (result != ISC_R_SUCCESS) { return (result); } switch (sock->type) { case isc_sockettype_udp: sock->statsindex = (pf == AF_INET) ? udp4statsindex : udp6statsindex; #define DCSPPKT(pf) ((pf == AF_INET) ? ISC_NET_DSCPPKTV4 : ISC_NET_DSCPPKTV6) sock->pktdscp = (isc_net_probedscp() & DCSPPKT(pf)) != 0; break; case isc_sockettype_tcp: sock->statsindex = (pf == AF_INET) ? tcp4statsindex : tcp6statsindex; break; case isc_sockettype_unix: sock->statsindex = unixstatsindex; break; case isc_sockettype_raw: sock->statsindex = rawstatsindex; break; default: UNREACHABLE(); } sock->pf = pf; result = opensocket(manager, sock, dup_socket); if (result != ISC_R_SUCCESS) { free_socket(&sock); return (result); } if (sock->fd == -1) { abort(); } sock->threadid = gen_threadid(sock); isc_refcount_increment0(&sock->references); thread = &manager->threads[sock->threadid]; *socketp = sock; /* * Note we don't have to lock the socket like we normally would because * there are no external references to it yet. */ lockid = FDLOCK_ID(sock->fd); LOCK(&thread->fdlock[lockid]); thread->fds[sock->fd] = sock; thread->fdstate[sock->fd] = MANAGED; #if defined(USE_EPOLL) thread->epoll_events[sock->fd] = 0; #endif /* if defined(USE_EPOLL) */ #ifdef USE_DEVPOLL INSIST(thread->fdpollinfo[sock->fd].want_read == 0 && thread->fdpollinfo[sock->fd].want_write == 0); #endif /* ifdef USE_DEVPOLL */ UNLOCK(&thread->fdlock[lockid]); LOCK(&manager->lock); ISC_LIST_APPEND(manager->socklist, sock, link); #ifdef USE_SELECT if (thread->maxfd < sock->fd) { thread->maxfd = sock->fd; } #endif /* ifdef USE_SELECT */ UNLOCK(&manager->lock); socket_log(sock, NULL, CREATION, dup_socket != NULL ? "dupped" : "created"); return (ISC_R_SUCCESS); } /*% * Create a new 'type' socket managed by 'manager'. Events * will be posted to 'task' and when dispatched 'action' will be * called with 'arg' as the arg value. The new socket is returned * in 'socketp'. */ isc_result_t isc_socket_create(isc_socketmgr_t *manager0, int pf, isc_sockettype_t type, isc_socket_t **socketp) { return (socket_create(manager0, pf, type, socketp, NULL)); } /*% * Duplicate an existing socket. The new socket is returned * in 'socketp'. */ isc_result_t isc_socket_dup(isc_socket_t *sock, isc_socket_t **socketp) { REQUIRE(VALID_SOCKET(sock)); REQUIRE(socketp != NULL && *socketp == NULL); return (socket_create(sock->manager, sock->pf, sock->type, socketp, sock)); } isc_result_t isc_socket_open(isc_socket_t *sock) { isc_result_t result; isc__socketthread_t *thread; REQUIRE(VALID_SOCKET(sock)); LOCK(&sock->lock); REQUIRE(isc_refcount_current(&sock->references) >= 1); REQUIRE(sock->fd == -1); REQUIRE(sock->threadid == -1); REQUIRE(sock->type != isc_sockettype_fdwatch); result = opensocket(sock->manager, sock, NULL); UNLOCK(&sock->lock); if (result != ISC_R_SUCCESS) { sock->fd = -1; } else { sock->threadid = gen_threadid(sock); thread = &sock->manager->threads[sock->threadid]; int lockid = FDLOCK_ID(sock->fd); LOCK(&thread->fdlock[lockid]); thread->fds[sock->fd] = sock; thread->fdstate[sock->fd] = MANAGED; #if defined(USE_EPOLL) thread->epoll_events[sock->fd] = 0; #endif /* if defined(USE_EPOLL) */ #ifdef USE_DEVPOLL INSIST(thread->fdpollinfo[sock->fd].want_read == 0 && thread->fdpollinfo[sock->fd].want_write == 0); #endif /* ifdef USE_DEVPOLL */ UNLOCK(&thread->fdlock[lockid]); #ifdef USE_SELECT LOCK(&sock->manager->lock); if (thread->maxfd < sock->fd) { thread->maxfd = sock->fd; } UNLOCK(&sock->manager->lock); #endif /* ifdef USE_SELECT */ } return (result); } /* * Attach to a socket. Caller must explicitly detach when it is done. */ void isc_socket_attach(isc_socket_t *sock, isc_socket_t **socketp) { REQUIRE(VALID_SOCKET(sock)); REQUIRE(socketp != NULL && *socketp == NULL); int old_refs = isc_refcount_increment(&sock->references); REQUIRE(old_refs > 0); *socketp = sock; } /* * Dereference a socket. If this is the last reference to it, clean things * up by destroying the socket. */ void isc_socket_detach(isc_socket_t **socketp) { isc_socket_t *sock; REQUIRE(socketp != NULL); sock = *socketp; REQUIRE(VALID_SOCKET(sock)); if (isc_refcount_decrement(&sock->references) == 1) { destroy(&sock); } *socketp = NULL; } isc_result_t isc_socket_close(isc_socket_t *sock) { int fd; isc_socketmgr_t *manager; isc__socketthread_t *thread; fflush(stdout); REQUIRE(VALID_SOCKET(sock)); LOCK(&sock->lock); REQUIRE(sock->type != isc_sockettype_fdwatch); REQUIRE(sock->fd >= 0 && sock->fd < (int)sock->manager->maxsocks); INSIST(!sock->connecting); INSIST(ISC_LIST_EMPTY(sock->recv_list)); INSIST(ISC_LIST_EMPTY(sock->send_list)); INSIST(ISC_LIST_EMPTY(sock->accept_list)); INSIST(ISC_LIST_EMPTY(sock->connect_list)); manager = sock->manager; thread = &manager->threads[sock->threadid]; fd = sock->fd; sock->fd = -1; sock->threadid = -1; sock->dupped = 0; memset(sock->name, 0, sizeof(sock->name)); sock->tag = NULL; sock->listener = 0; sock->connected = 0; sock->connecting = 0; sock->bound = 0; isc_sockaddr_any(&sock->peer_address); UNLOCK(&sock->lock); socketclose(thread, sock, fd); return (ISC_R_SUCCESS); } static void dispatch_recv(isc_socket_t *sock) { if (sock->type != isc_sockettype_fdwatch) { internal_recv(sock); } else { internal_fdwatch_read(sock); } } static void dispatch_send(isc_socket_t *sock) { if (sock->type != isc_sockettype_fdwatch) { internal_send(sock); } else { internal_fdwatch_write(sock); } } /* * Dequeue an item off the given socket's read queue, set the result code * in the done event to the one provided, and send it to the task it was * destined for. * * If the event to be sent is on a list, remove it before sending. If * asked to, send and detach from the socket as well. * * Caller must have the socket locked if the event is attached to the socket. */ static void send_recvdone_event(isc_socket_t *sock, isc_socketevent_t **dev) { isc_task_t *task; task = (*dev)->ev_sender; (*dev)->ev_sender = sock; if (ISC_LINK_LINKED(*dev, ev_link)) { ISC_LIST_DEQUEUE(sock->recv_list, *dev, ev_link); } if (((*dev)->attributes & ISC_SOCKEVENTATTR_ATTACHED) != 0) { isc_task_sendtoanddetach(&task, (isc_event_t **)dev, sock->threadid); } else { isc_task_sendto(task, (isc_event_t **)dev, sock->threadid); } } /* * See comments for send_recvdone_event() above. * * Caller must have the socket locked if the event is attached to the socket. */ static void send_senddone_event(isc_socket_t *sock, isc_socketevent_t **dev) { isc_task_t *task; INSIST(dev != NULL && *dev != NULL); task = (*dev)->ev_sender; (*dev)->ev_sender = sock; if (ISC_LINK_LINKED(*dev, ev_link)) { ISC_LIST_DEQUEUE(sock->send_list, *dev, ev_link); } if (((*dev)->attributes & ISC_SOCKEVENTATTR_ATTACHED) != 0) { isc_task_sendtoanddetach(&task, (isc_event_t **)dev, sock->threadid); } else { isc_task_sendto(task, (isc_event_t **)dev, sock->threadid); } } /* * See comments for send_recvdone_event() above. * * Caller must have the socket locked if the event is attached to the socket. */ static void send_connectdone_event(isc_socket_t *sock, isc_socket_connev_t **dev) { isc_task_t *task; INSIST(dev != NULL && *dev != NULL); task = (*dev)->ev_sender; (*dev)->ev_sender = sock; if (ISC_LINK_LINKED(*dev, ev_link)) { ISC_LIST_DEQUEUE(sock->connect_list, *dev, ev_link); } isc_task_sendtoanddetach(&task, (isc_event_t **)dev, sock->threadid); } /* * Call accept() on a socket, to get the new file descriptor. The listen * socket is used as a prototype to create a new isc_socket_t. The new * socket has one outstanding reference. The task receiving the event * will be detached from just after the event is delivered. * * On entry to this function, the event delivered is the internal * readable event, and the first item on the accept_list should be * the done event we want to send. If the list is empty, this is a no-op, * so just unlock and return. */ static void internal_accept(isc_socket_t *sock) { isc_socketmgr_t *manager; isc__socketthread_t *thread, *nthread; isc_socket_newconnev_t *dev; isc_task_t *task; socklen_t addrlen; int fd; isc_result_t result = ISC_R_SUCCESS; char strbuf[ISC_STRERRORSIZE]; const char *err = "accept"; INSIST(VALID_SOCKET(sock)); REQUIRE(sock->fd >= 0); socket_log(sock, NULL, TRACE, "internal_accept called, locked socket"); manager = sock->manager; INSIST(VALID_MANAGER(manager)); thread = &manager->threads[sock->threadid]; INSIST(sock->listener); /* * Get the first item off the accept list. * If it is empty, unlock the socket and return. */ dev = ISC_LIST_HEAD(sock->accept_list); if (dev == NULL) { unwatch_fd(thread, sock->fd, SELECT_POKE_ACCEPT); UNLOCK(&sock->lock); return; } /* * Try to accept the new connection. If the accept fails with * EAGAIN or EINTR, simply poke the watcher to watch this socket * again. Also ignore ECONNRESET, which has been reported to * be spuriously returned on Linux 2.2.19 although it is not * a documented error for accept(). ECONNABORTED has been * reported for Solaris 8. The rest are thrown in not because * we have seen them but because they are ignored by other * daemons such as BIND 8 and Apache. */ addrlen = sizeof(NEWCONNSOCK(dev)->peer_address.type); memset(&NEWCONNSOCK(dev)->peer_address.type, 0, addrlen); fd = accept(sock->fd, &NEWCONNSOCK(dev)->peer_address.type.sa, (void *)&addrlen); #ifdef F_DUPFD /* * Leave a space for stdio to work in. */ if (fd >= 0 && fd < 20) { int newfd, tmp; newfd = fcntl(fd, F_DUPFD, 20); tmp = errno; (void)close(fd); errno = tmp; fd = newfd; err = "accept/fcntl"; } #endif /* ifdef F_DUPFD */ if (fd < 0) { if (SOFT_ERROR(errno)) { goto soft_error; } switch (errno) { case ENFILE: case EMFILE: isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "%s: too many open file descriptors", err); goto soft_error; case ENOBUFS: case ENOMEM: case ECONNRESET: case ECONNABORTED: case EHOSTUNREACH: case EHOSTDOWN: case ENETUNREACH: case ENETDOWN: case ECONNREFUSED: #ifdef EPROTO case EPROTO: #endif /* ifdef EPROTO */ #ifdef ENONET case ENONET: #endif /* ifdef ENONET */ goto soft_error; default: break; } strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "internal_accept: %s() failed: %s", err, strbuf); fd = -1; result = ISC_R_UNEXPECTED; } else { if (addrlen == 0U) { UNEXPECTED_ERROR(__FILE__, __LINE__, "internal_accept(): " "accept() failed to return " "remote address"); (void)close(fd); goto soft_error; } else if (NEWCONNSOCK(dev)->peer_address.type.sa.sa_family != sock->pf) { UNEXPECTED_ERROR( __FILE__, __LINE__, "internal_accept(): " "accept() returned peer address " "family %u (expected %u)", NEWCONNSOCK(dev)->peer_address.type.sa.sa_family, sock->pf); (void)close(fd); goto soft_error; } else if (fd >= (int)manager->maxsocks) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "accept: file descriptor exceeds limit " "(%d/%u)", fd, manager->maxsocks); (void)close(fd); goto soft_error; } } if (fd != -1) { NEWCONNSOCK(dev)->peer_address.length = addrlen; NEWCONNSOCK(dev)->pf = sock->pf; } /* * Pull off the done event. */ ISC_LIST_UNLINK(sock->accept_list, dev, ev_link); /* * Poke watcher if there are more pending accepts. */ if (ISC_LIST_EMPTY(sock->accept_list)) { unwatch_fd(thread, sock->fd, SELECT_POKE_ACCEPT); } if (fd != -1) { result = make_nonblock(fd); if (result != ISC_R_SUCCESS) { (void)close(fd); fd = -1; } } /* * We need to unlock sock->lock now to be able to lock manager->lock * without risking a deadlock with xmlstats. */ UNLOCK(&sock->lock); /* * -1 means the new socket didn't happen. */ if (fd != -1) { int lockid = FDLOCK_ID(fd); NEWCONNSOCK(dev)->fd = fd; NEWCONNSOCK(dev)->threadid = gen_threadid(NEWCONNSOCK(dev)); NEWCONNSOCK(dev)->bound = 1; NEWCONNSOCK(dev)->connected = 1; nthread = &manager->threads[NEWCONNSOCK(dev)->threadid]; /* * We already hold a lock on one fdlock in accepting thread, * we need to make sure that we don't double lock. */ bool same_bucket = (sock->threadid == NEWCONNSOCK(dev)->threadid) && (FDLOCK_ID(sock->fd) == lockid); /* * Use minimum mtu if possible. */ use_min_mtu(NEWCONNSOCK(dev)); set_tcp_maxseg(NEWCONNSOCK(dev), 1280 - 20 - 40); /* * Ensure DSCP settings are inherited across accept. */ setdscp(NEWCONNSOCK(dev), sock->dscp); /* * Save away the remote address */ dev->address = NEWCONNSOCK(dev)->peer_address; if (NEWCONNSOCK(dev)->active == 0) { inc_stats(manager->stats, NEWCONNSOCK(dev)->statsindex[STATID_ACTIVE]); NEWCONNSOCK(dev)->active = 1; } if (!same_bucket) { LOCK(&nthread->fdlock[lockid]); } nthread->fds[fd] = NEWCONNSOCK(dev); nthread->fdstate[fd] = MANAGED; #if defined(USE_EPOLL) nthread->epoll_events[fd] = 0; #endif /* if defined(USE_EPOLL) */ if (!same_bucket) { UNLOCK(&nthread->fdlock[lockid]); } LOCK(&manager->lock); #ifdef USE_SELECT if (nthread->maxfd < fd) { nthread->maxfd = fd; } #endif /* ifdef USE_SELECT */ socket_log(sock, &NEWCONNSOCK(dev)->peer_address, CREATION, "accepted connection, new socket %p", dev->newsocket); ISC_LIST_APPEND(manager->socklist, NEWCONNSOCK(dev), link); UNLOCK(&manager->lock); inc_stats(manager->stats, sock->statsindex[STATID_ACCEPT]); } else { inc_stats(manager->stats, sock->statsindex[STATID_ACCEPTFAIL]); isc_refcount_decrementz(&NEWCONNSOCK(dev)->references); free_socket((isc_socket_t **)&dev->newsocket); } /* * Fill in the done event details and send it off. */ dev->result = result; task = dev->ev_sender; dev->ev_sender = sock; isc_task_sendtoanddetach(&task, ISC_EVENT_PTR(&dev), sock->threadid); return; soft_error: watch_fd(thread, sock->fd, SELECT_POKE_ACCEPT); UNLOCK(&sock->lock); inc_stats(manager->stats, sock->statsindex[STATID_ACCEPTFAIL]); return; } static void internal_recv(isc_socket_t *sock) { isc_socketevent_t *dev; INSIST(VALID_SOCKET(sock)); REQUIRE(sock->fd >= 0); dev = ISC_LIST_HEAD(sock->recv_list); if (dev == NULL) { goto finish; } socket_log(sock, NULL, IOEVENT, "internal_recv: event %p -> task %p", dev, dev->ev_sender); /* * Try to do as much I/O as possible on this socket. There are no * limits here, currently. */ while (dev != NULL) { switch (doio_recv(sock, dev)) { case DOIO_SOFT: goto finish; case DOIO_EOF: /* * read of 0 means the remote end was closed. * Run through the event queue and dispatch all * the events with an EOF result code. */ do { dev->result = ISC_R_EOF; send_recvdone_event(sock, &dev); dev = ISC_LIST_HEAD(sock->recv_list); } while (dev != NULL); goto finish; case DOIO_SUCCESS: case DOIO_HARD: send_recvdone_event(sock, &dev); break; } dev = ISC_LIST_HEAD(sock->recv_list); } finish: if (ISC_LIST_EMPTY(sock->recv_list)) { unwatch_fd(&sock->manager->threads[sock->threadid], sock->fd, SELECT_POKE_READ); } } static void internal_send(isc_socket_t *sock) { isc_socketevent_t *dev; INSIST(VALID_SOCKET(sock)); REQUIRE(sock->fd >= 0); dev = ISC_LIST_HEAD(sock->send_list); if (dev == NULL) { goto finish; } socket_log(sock, NULL, EVENT, "internal_send: event %p -> task %p", dev, dev->ev_sender); /* * Try to do as much I/O as possible on this socket. There are no * limits here, currently. */ while (dev != NULL) { switch (doio_send(sock, dev)) { case DOIO_SOFT: goto finish; case DOIO_HARD: case DOIO_SUCCESS: send_senddone_event(sock, &dev); break; } dev = ISC_LIST_HEAD(sock->send_list); } finish: if (ISC_LIST_EMPTY(sock->send_list)) { unwatch_fd(&sock->manager->threads[sock->threadid], sock->fd, SELECT_POKE_WRITE); } } static void internal_fdwatch_write(isc_socket_t *sock) { int more_data; INSIST(VALID_SOCKET(sock)); isc_refcount_increment(&sock->references); UNLOCK(&sock->lock); more_data = (sock->fdwatchcb)(sock->fdwatchtask, (isc_socket_t *)sock, sock->fdwatcharg, ISC_SOCKFDWATCH_WRITE); LOCK(&sock->lock); if (isc_refcount_decrement(&sock->references) == 0) { UNLOCK(&sock->lock); destroy(&sock); return; } if (more_data) select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_WRITE); } static void internal_fdwatch_read(isc_socket_t *sock) { int more_data; INSIST(VALID_SOCKET(sock)); isc_refcount_increment(&sock->references); UNLOCK(&sock->lock); more_data = (sock->fdwatchcb)(sock->fdwatchtask, (isc_socket_t *)sock, sock->fdwatcharg, ISC_SOCKFDWATCH_READ); LOCK(&sock->lock); if (isc_refcount_decrement(&sock->references) == 0) { UNLOCK(&sock->lock); destroy(&sock); return; } if (more_data) select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_READ); } /* * Process read/writes on each fd here. Avoid locking * and unlocking twice if both reads and writes are possible. */ static void process_fd(isc__socketthread_t *thread, int fd, bool readable, bool writeable) { isc_socket_t *sock; int lockid = FDLOCK_ID(fd); /* * If the socket is going to be closed, don't do more I/O. */ LOCK(&thread->fdlock[lockid]); if (thread->fdstate[fd] == CLOSE_PENDING) { UNLOCK(&thread->fdlock[lockid]); (void)unwatch_fd(thread, fd, SELECT_POKE_READ); (void)unwatch_fd(thread, fd, SELECT_POKE_WRITE); return; } sock = thread->fds[fd]; if (sock == NULL) { UNLOCK(&thread->fdlock[lockid]); return; } LOCK(&sock->lock); if (sock->fd < 0) { /* * Sock is being closed - the final external reference * is gone but it was not yet removed from event loop * and fdstate[]/fds[] as destroy() is waiting on * thread->fdlock[lockid] or sock->lock that we're holding. * Just release the locks and bail. */ UNLOCK(&sock->lock); UNLOCK(&thread->fdlock[lockid]); return; } REQUIRE(readable || writeable); if (writeable) { if (sock->connecting) { internal_connect(sock); } else { dispatch_send(sock); } } if (readable) { if (sock->listener) { internal_accept(sock); /* unlocks sock */ } else { dispatch_recv(sock); UNLOCK(&sock->lock); } } else { UNLOCK(&sock->lock); } UNLOCK(&thread->fdlock[lockid]); /* * Socket destruction might be pending, it will resume * after releasing fdlock and sock->lock. */ } /* * process_fds is different for different event loops * it takes the events from event loops and for each FD * launches process_fd */ #ifdef USE_KQUEUE static bool process_fds(isc__socketthread_t *thread, struct kevent *events, int nevents) { int i; bool readable, writable; bool done = false; bool have_ctlevent = false; if (nevents == thread->nevents) { /* * This is not an error, but something unexpected. If this * happens, it may indicate the need for increasing * ISC_SOCKET_MAXEVENTS. */ thread_log(thread, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_INFO, "maximum number of FD events (%d) received", nevents); } for (i = 0; i < nevents; i++) { REQUIRE(events[i].ident < thread->manager->maxsocks); if (events[i].ident == (uintptr_t)thread->pipe_fds[0]) { have_ctlevent = true; continue; } readable = (events[i].filter == EVFILT_READ); writable = (events[i].filter == EVFILT_WRITE); process_fd(thread, events[i].ident, readable, writable); } if (have_ctlevent) { done = process_ctlfd(thread); } return (done); } #elif defined(USE_EPOLL) static bool process_fds(isc__socketthread_t *thread, struct epoll_event *events, int nevents) { int i; bool done = false; bool have_ctlevent = false; if (nevents == thread->nevents) { thread_log(thread, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_INFO, "maximum number of FD events (%d) received", nevents); } for (i = 0; i < nevents; i++) { REQUIRE(events[i].data.fd < (int)thread->manager->maxsocks); if (events[i].data.fd == thread->pipe_fds[0]) { have_ctlevent = true; continue; } if ((events[i].events & EPOLLERR) != 0 || (events[i].events & EPOLLHUP) != 0) { /* * epoll does not set IN/OUT bits on an erroneous * condition, so we need to try both anyway. This is a * bit inefficient, but should be okay for such rare * events. Note also that the read or write attempt * won't block because we use non-blocking sockets. */ int fd = events[i].data.fd; events[i].events |= thread->epoll_events[fd]; } process_fd(thread, events[i].data.fd, (events[i].events & EPOLLIN) != 0, (events[i].events & EPOLLOUT) != 0); } if (have_ctlevent) { done = process_ctlfd(thread); } return (done); } #elif defined(USE_DEVPOLL) static bool process_fds(isc__socketthread_t *thread, struct pollfd *events, int nevents) { int i; bool done = false; bool have_ctlevent = false; if (nevents == thread->nevents) { thread_log(thread, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_INFO, "maximum number of FD events (%d) received", nevents); } for (i = 0; i < nevents; i++) { REQUIRE(events[i].fd < (int)thread->manager->maxsocks); if (events[i].fd == thread->pipe_fds[0]) { have_ctlevent = true; continue; } process_fd(thread, events[i].fd, (events[i].events & POLLIN) != 0, (events[i].events & POLLOUT) != 0); } if (have_ctlevent) { done = process_ctlfd(thread); } return (done); } #elif defined(USE_SELECT) static void process_fds(isc__socketthread_t *thread, int maxfd, fd_set *readfds, fd_set *writefds) { int i; REQUIRE(maxfd <= (int)thread->manager->maxsocks); for (i = 0; i < maxfd; i++) { if (i == thread->pipe_fds[0] || i == thread->pipe_fds[1]) { continue; } process_fd(thread, i, FD_ISSET(i, readfds), FD_ISSET(i, writefds)); } } #endif /* ifdef USE_KQUEUE */ static bool process_ctlfd(isc__socketthread_t *thread) { int msg, fd; for (;;) { select_readmsg(thread, &fd, &msg); thread_log(thread, IOEVENT, "watcher got message %d for socket %d", msg, fd); /* * Nothing to read? */ if (msg == SELECT_POKE_NOTHING) { break; } /* * Handle shutdown message. We really should * jump out of this loop right away, but * it doesn't matter if we have to do a little * more work first. */ if (msg == SELECT_POKE_SHUTDOWN) { return (true); } /* * This is a wakeup on a socket. Look * at the event queue for both read and write, * and decide if we need to watch on it now * or not. */ wakeup_socket(thread, fd, msg); } return (false); } /* * This is the thread that will loop forever, always in a select or poll * call. * * When select returns something to do, do whatever's necessary and post * an event to the task that was requesting the action. */ static isc_threadresult_t netthread(void *uap) { isc__socketthread_t *thread = uap; isc_socketmgr_t *manager = thread->manager; (void)manager; bool done; int cc; #ifdef USE_KQUEUE const char *fnname = "kevent()"; #elif defined(USE_EPOLL) const char *fnname = "epoll_wait()"; #elif defined(USE_DEVPOLL) isc_result_t result; const char *fnname = "ioctl(DP_POLL)"; struct dvpoll dvp; int pass; #if defined(ISC_SOCKET_USE_POLLWATCH) pollstate_t pollstate = poll_idle; #endif /* if defined(ISC_SOCKET_USE_POLLWATCH) */ #elif defined(USE_SELECT) const char *fnname = "select()"; int maxfd; int ctlfd; #endif /* ifdef USE_KQUEUE */ char strbuf[ISC_STRERRORSIZE]; #if defined(USE_SELECT) /* * Get the control fd here. This will never change. */ ctlfd = thread->pipe_fds[0]; #endif /* if defined(USE_SELECT) */ done = false; while (!done) { do { #ifdef USE_KQUEUE cc = kevent(thread->kqueue_fd, NULL, 0, thread->events, thread->nevents, NULL); #elif defined(USE_EPOLL) cc = epoll_wait(thread->epoll_fd, thread->events, thread->nevents, -1); #elif defined(USE_DEVPOLL) /* * Re-probe every thousand calls. */ if (thread->calls++ > 1000U) { result = isc_resource_getcurlimit( isc_resource_openfiles, &thread->open_max); if (result != ISC_R_SUCCESS) { thread->open_max = 64; } thread->calls = 0; } for (pass = 0; pass < 2; pass++) { dvp.dp_fds = thread->events; dvp.dp_nfds = thread->nevents; if (dvp.dp_nfds >= thread->open_max) { dvp.dp_nfds = thread->open_max - 1; } #ifndef ISC_SOCKET_USE_POLLWATCH dvp.dp_timeout = -1; #else /* ifndef ISC_SOCKET_USE_POLLWATCH */ if (pollstate == poll_idle) { dvp.dp_timeout = -1; } else { dvp.dp_timeout = ISC_SOCKET_POLLWATCH_TIMEOUT; } #endif /* ISC_SOCKET_USE_POLLWATCH */ cc = ioctl(thread->devpoll_fd, DP_POLL, &dvp); if (cc == -1 && errno == EINVAL) { /* * {OPEN_MAX} may have dropped. Look * up the current value and try again. */ result = isc_resource_getcurlimit( isc_resource_openfiles, &thread->open_max); if (result != ISC_R_SUCCESS) { thread->open_max = 64; } } else { break; } } #elif defined(USE_SELECT) /* * We will have only one thread anyway, we can lock * manager lock and don't care */ LOCK(&manager->lock); memmove(thread->read_fds_copy, thread->read_fds, thread->fd_bufsize); memmove(thread->write_fds_copy, thread->write_fds, thread->fd_bufsize); maxfd = thread->maxfd + 1; UNLOCK(&manager->lock); cc = select(maxfd, thread->read_fds_copy, thread->write_fds_copy, NULL, NULL); #endif /* USE_KQUEUE */ if (cc < 0 && !SOFT_ERROR(errno)) { strerror_r(errno, strbuf, sizeof(strbuf)); FATAL_ERROR(__FILE__, __LINE__, "%s failed: %s", fnname, strbuf); } #if defined(USE_DEVPOLL) && defined(ISC_SOCKET_USE_POLLWATCH) if (cc == 0) { if (pollstate == poll_active) { pollstate = poll_checking; } else if (pollstate == poll_checking) { pollstate = poll_idle; } } else if (cc > 0) { if (pollstate == poll_checking) { /* * XXX: We'd like to use a more * verbose log level as it's actually an * unexpected event, but the kernel bug * reportedly happens pretty frequently * (and it can also be a false positive) * so it would be just too noisy. */ thread_log(thread, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_DEBUG(1), "unexpected POLL timeout"); } pollstate = poll_active; } #endif /* if defined(USE_DEVPOLL) && defined(ISC_SOCKET_USE_POLLWATCH) */ } while (cc < 0); #if defined(USE_KQUEUE) || defined(USE_EPOLL) || defined(USE_DEVPOLL) done = process_fds(thread, thread->events, cc); #elif defined(USE_SELECT) process_fds(thread, maxfd, thread->read_fds_copy, thread->write_fds_copy); /* * Process reads on internal, control fd. */ if (FD_ISSET(ctlfd, thread->read_fds_copy)) { done = process_ctlfd(thread); } #endif /* if defined(USE_KQUEUE) || defined(USE_EPOLL) || defined(USE_DEVPOLL) \ * */ } thread_log(thread, TRACE, "watcher exiting"); return ((isc_threadresult_t)0); } void isc_socketmgr_setreserved(isc_socketmgr_t *manager, uint32_t reserved) { REQUIRE(VALID_MANAGER(manager)); manager->reserved = reserved; } void isc_socketmgr_maxudp(isc_socketmgr_t *manager, unsigned int maxudp) { REQUIRE(VALID_MANAGER(manager)); manager->maxudp = maxudp; } /* * Setup socket thread, thread->manager and thread->threadid must be filled. */ static isc_result_t setup_thread(isc__socketthread_t *thread) { isc_result_t result = ISC_R_SUCCESS; int i; char strbuf[ISC_STRERRORSIZE]; REQUIRE(thread != NULL); REQUIRE(VALID_MANAGER(thread->manager)); REQUIRE(thread->threadid >= 0 && thread->threadid < thread->manager->nthreads); thread->fds = isc_mem_get(thread->manager->mctx, thread->manager->maxsocks * sizeof(isc_socket_t *)); memset(thread->fds, 0, thread->manager->maxsocks * sizeof(isc_socket_t *)); thread->fdstate = isc_mem_get(thread->manager->mctx, thread->manager->maxsocks * sizeof(int)); memset(thread->fdstate, 0, thread->manager->maxsocks * sizeof(int)); thread->fdlock = isc_mem_get(thread->manager->mctx, FDLOCK_COUNT * sizeof(isc_mutex_t)); for (i = 0; i < FDLOCK_COUNT; i++) { isc_mutex_init(&thread->fdlock[i]); } if (pipe(thread->pipe_fds) != 0) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "pipe() failed: %s", strbuf); return (ISC_R_UNEXPECTED); } RUNTIME_CHECK(make_nonblock(thread->pipe_fds[0]) == ISC_R_SUCCESS); #ifdef USE_KQUEUE thread->nevents = ISC_SOCKET_MAXEVENTS; thread->events = isc_mem_get(thread->manager->mctx, sizeof(struct kevent) * thread->nevents); thread->kqueue_fd = kqueue(); if (thread->kqueue_fd == -1) { result = isc__errno2result(errno); strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "kqueue failed: %s", strbuf); isc_mem_put(thread->manager->mctx, thread->events, sizeof(struct kevent) * thread->nevents); return (result); } result = watch_fd(thread, thread->pipe_fds[0], SELECT_POKE_READ); if (result != ISC_R_SUCCESS) { close(thread->kqueue_fd); isc_mem_put(thread->manager->mctx, thread->events, sizeof(struct kevent) * thread->nevents); } return (result); #elif defined(USE_EPOLL) thread->nevents = ISC_SOCKET_MAXEVENTS; thread->epoll_events = isc_mem_get(thread->manager->mctx, (thread->manager->maxsocks * sizeof(uint32_t))); memset(thread->epoll_events, 0, thread->manager->maxsocks * sizeof(uint32_t)); thread->events = isc_mem_get(thread->manager->mctx, sizeof(struct epoll_event) * thread->nevents); thread->epoll_fd = epoll_create(thread->nevents); if (thread->epoll_fd == -1) { result = isc__errno2result(errno); strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "epoll_create failed: %s", strbuf); return (result); } result = watch_fd(thread, thread->pipe_fds[0], SELECT_POKE_READ); return (result); #elif defined(USE_DEVPOLL) thread->nevents = ISC_SOCKET_MAXEVENTS; result = isc_resource_getcurlimit(isc_resource_openfiles, &thread->open_max); if (result != ISC_R_SUCCESS) { thread->open_max = 64; } thread->calls = 0; thread->events = isc_mem_get(thread->manager->mctx, sizeof(struct pollfd) * thread->nevents); /* * Note: fdpollinfo should be able to support all possible FDs, so * it must have maxsocks entries (not nevents). */ thread->fdpollinfo = isc_mem_get(thread->manager->mctx, sizeof(pollinfo_t) * thread->manager->maxsocks); memset(thread->fdpollinfo, 0, sizeof(pollinfo_t) * thread->manager->maxsocks); thread->devpoll_fd = open("/dev/poll", O_RDWR); if (thread->devpoll_fd == -1) { result = isc__errno2result(errno); strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "open(/dev/poll) failed: %s", strbuf); isc_mem_put(thread->manager->mctx, thread->events, sizeof(struct pollfd) * thread->nevents); isc_mem_put(thread->manager->mctx, thread->fdpollinfo, sizeof(pollinfo_t) * thread->manager->maxsocks); return (result); } result = watch_fd(thread, thread->pipe_fds[0], SELECT_POKE_READ); if (result != ISC_R_SUCCESS) { close(thread->devpoll_fd); isc_mem_put(thread->manager->mctx, thread->events, sizeof(struct pollfd) * thread->nevents); isc_mem_put(thread->manager->mctx, thread->fdpollinfo, sizeof(pollinfo_t) * thread->manager->maxsocks); return (result); } return (ISC_R_SUCCESS); #elif defined(USE_SELECT) UNUSED(result); #if ISC_SOCKET_MAXSOCKETS > FD_SETSIZE /* * Note: this code should also cover the case of MAXSOCKETS <= * FD_SETSIZE, but we separate the cases to avoid possible portability * issues regarding howmany() and the actual representation of fd_set. */ thread->fd_bufsize = howmany(manager->maxsocks, NFDBITS) * sizeof(fd_mask); #else /* if ISC_SOCKET_MAXSOCKETS > FD_SETSIZE */ thread->fd_bufsize = sizeof(fd_set); #endif /* if ISC_SOCKET_MAXSOCKETS > FD_SETSIZE */ thread->read_fds = isc_mem_get(thread->manager->mctx, thread->fd_bufsize); thread->read_fds_copy = isc_mem_get(thread->manager->mctx, thread->fd_bufsize); thread->write_fds = isc_mem_get(thread->manager->mctx, thread->fd_bufsize); thread->write_fds_copy = isc_mem_get(thread->manager->mctx, thread->fd_bufsize); memset(thread->read_fds, 0, thread->fd_bufsize); memset(thread->write_fds, 0, thread->fd_bufsize); (void)watch_fd(thread, thread->pipe_fds[0], SELECT_POKE_READ); thread->maxfd = thread->pipe_fds[0]; return (ISC_R_SUCCESS); #endif /* USE_KQUEUE */ } static void cleanup_thread(isc_mem_t *mctx, isc__socketthread_t *thread) { isc_result_t result; int i; result = unwatch_fd(thread, thread->pipe_fds[0], SELECT_POKE_READ); if (result != ISC_R_SUCCESS) { UNEXPECTED_ERROR(__FILE__, __LINE__, "epoll_ctl(DEL) failed"); } #ifdef USE_KQUEUE close(thread->kqueue_fd); isc_mem_put(mctx, thread->events, sizeof(struct kevent) * thread->nevents); #elif defined(USE_EPOLL) close(thread->epoll_fd); isc_mem_put(mctx, thread->events, sizeof(struct epoll_event) * thread->nevents); #elif defined(USE_DEVPOLL) close(thread->devpoll_fd); isc_mem_put(mctx, thread->events, sizeof(struct pollfd) * thread->nevents); isc_mem_put(mctx, thread->fdpollinfo, sizeof(pollinfo_t) * thread->manager->maxsocks); #elif defined(USE_SELECT) if (thread->read_fds != NULL) { isc_mem_put(mctx, thread->read_fds, thread->fd_bufsize); } if (thread->read_fds_copy != NULL) { isc_mem_put(mctx, thread->read_fds_copy, thread->fd_bufsize); } if (thread->write_fds != NULL) { isc_mem_put(mctx, thread->write_fds, thread->fd_bufsize); } if (thread->write_fds_copy != NULL) { isc_mem_put(mctx, thread->write_fds_copy, thread->fd_bufsize); } #endif /* USE_KQUEUE */ for (i = 0; i < (int)thread->manager->maxsocks; i++) { if (thread->fdstate[i] == CLOSE_PENDING) { /* no need to lock */ (void)close(i); } } #if defined(USE_EPOLL) isc_mem_put(thread->manager->mctx, thread->epoll_events, thread->manager->maxsocks * sizeof(uint32_t)); #endif /* if defined(USE_EPOLL) */ isc_mem_put(thread->manager->mctx, thread->fds, thread->manager->maxsocks * sizeof(isc_socket_t *)); isc_mem_put(thread->manager->mctx, thread->fdstate, thread->manager->maxsocks * sizeof(int)); for (i = 0; i < FDLOCK_COUNT; i++) { isc_mutex_destroy(&thread->fdlock[i]); } isc_mem_put(thread->manager->mctx, thread->fdlock, FDLOCK_COUNT * sizeof(isc_mutex_t)); } isc_result_t isc_socketmgr_create(isc_mem_t *mctx, isc_socketmgr_t **managerp) { return (isc_socketmgr_create2(mctx, managerp, 0, 1)); } isc_result_t isc_socketmgr_create2(isc_mem_t *mctx, isc_socketmgr_t **managerp, unsigned int maxsocks, int nthreads) { int i; isc_socketmgr_t *manager; REQUIRE(managerp != NULL && *managerp == NULL); if (maxsocks == 0) { maxsocks = ISC_SOCKET_MAXSOCKETS; } manager = isc_mem_get(mctx, sizeof(*manager)); /* zero-clear so that necessary cleanup on failure will be easy */ memset(manager, 0, sizeof(*manager)); manager->maxsocks = maxsocks; manager->reserved = 0; manager->maxudp = 0; manager->nthreads = nthreads; manager->stats = NULL; manager->magic = SOCKET_MANAGER_MAGIC; manager->mctx = NULL; ISC_LIST_INIT(manager->socklist); isc_mutex_init(&manager->lock); isc_condition_init(&manager->shutdown_ok); /* * Start up the select/poll thread. */ manager->threads = isc_mem_get(mctx, sizeof(isc__socketthread_t) * manager->nthreads); isc_mem_attach(mctx, &manager->mctx); for (i = 0; i < manager->nthreads; i++) { manager->threads[i].manager = manager; manager->threads[i].threadid = i; setup_thread(&manager->threads[i]); isc_thread_create(netthread, &manager->threads[i], &manager->threads[i].thread); char tname[1024]; sprintf(tname, "sock-%d", i); isc_thread_setname(manager->threads[i].thread, tname); } *managerp = manager; return (ISC_R_SUCCESS); } isc_result_t isc_socketmgr_getmaxsockets(isc_socketmgr_t *manager, unsigned int *nsockp) { REQUIRE(VALID_MANAGER(manager)); REQUIRE(nsockp != NULL); *nsockp = manager->maxsocks; return (ISC_R_SUCCESS); } void isc_socketmgr_setstats(isc_socketmgr_t *manager, isc_stats_t *stats) { REQUIRE(VALID_MANAGER(manager)); REQUIRE(ISC_LIST_EMPTY(manager->socklist)); REQUIRE(manager->stats == NULL); REQUIRE(isc_stats_ncounters(stats) == isc_sockstatscounter_max); isc_stats_attach(stats, &manager->stats); } void isc_socketmgr_destroy(isc_socketmgr_t **managerp) { isc_socketmgr_t *manager; /* * Destroy a socket manager. */ REQUIRE(managerp != NULL); manager = *managerp; REQUIRE(VALID_MANAGER(manager)); LOCK(&manager->lock); /* * Wait for all sockets to be destroyed. */ while (!ISC_LIST_EMPTY(manager->socklist)) { manager_log(manager, CREATION, "sockets exist"); WAIT(&manager->shutdown_ok, &manager->lock); } UNLOCK(&manager->lock); /* * Here, poke our select/poll thread. Do this by closing the write * half of the pipe, which will send EOF to the read half. * This is currently a no-op in the non-threaded case. */ for (int i = 0; i < manager->nthreads; i++) { select_poke(manager, i, 0, SELECT_POKE_SHUTDOWN); } /* * Wait for thread to exit. */ for (int i = 0; i < manager->nthreads; i++) { isc_thread_join(manager->threads[i].thread, NULL); cleanup_thread(manager->mctx, &manager->threads[i]); } /* * Clean up. */ isc_mem_put(manager->mctx, manager->threads, sizeof(isc__socketthread_t) * manager->nthreads); (void)isc_condition_destroy(&manager->shutdown_ok); if (manager->stats != NULL) { isc_stats_detach(&manager->stats); } isc_mutex_destroy(&manager->lock); manager->magic = 0; isc_mem_putanddetach(&manager->mctx, manager, sizeof(*manager)); *managerp = NULL; } static isc_result_t socket_recv(isc_socket_t *sock, isc_socketevent_t *dev, isc_task_t *task, unsigned int flags) { int io_state; bool have_lock = false; isc_task_t *ntask = NULL; isc_result_t result = ISC_R_SUCCESS; dev->ev_sender = task; if (sock->type == isc_sockettype_udp) { io_state = doio_recv(sock, dev); } else { LOCK(&sock->lock); have_lock = true; if (ISC_LIST_EMPTY(sock->recv_list)) { io_state = doio_recv(sock, dev); } else { io_state = DOIO_SOFT; } } switch (io_state) { case DOIO_SOFT: /* * We couldn't read all or part of the request right now, so * queue it. * * Attach to socket and to task */ isc_task_attach(task, &ntask); dev->attributes |= ISC_SOCKEVENTATTR_ATTACHED; if (!have_lock) { LOCK(&sock->lock); have_lock = true; } /* * Enqueue the request. If the socket was previously not being * watched, poke the watcher to start paying attention to it. */ bool do_poke = ISC_LIST_EMPTY(sock->recv_list); ISC_LIST_ENQUEUE(sock->recv_list, dev, ev_link); if (do_poke) { select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_READ); } socket_log(sock, NULL, EVENT, "socket_recv: event %p -> task %p", dev, ntask); if ((flags & ISC_SOCKFLAG_IMMEDIATE) != 0) { result = ISC_R_INPROGRESS; } break; case DOIO_EOF: dev->result = ISC_R_EOF; FALLTHROUGH; case DOIO_HARD: case DOIO_SUCCESS: if ((flags & ISC_SOCKFLAG_IMMEDIATE) == 0) { send_recvdone_event(sock, &dev); } break; } if (have_lock) { UNLOCK(&sock->lock); } return (result); } isc_result_t isc_socket_recv(isc_socket_t *sock, isc_region_t *region, unsigned int minimum, isc_task_t *task, isc_taskaction_t action, void *arg) { isc_socketevent_t *dev; isc_socketmgr_t *manager; REQUIRE(VALID_SOCKET(sock)); REQUIRE(action != NULL); manager = sock->manager; REQUIRE(VALID_MANAGER(manager)); INSIST(sock->bound); dev = allocate_socketevent(manager->mctx, sock, ISC_SOCKEVENT_RECVDONE, action, arg); if (dev == NULL) { return (ISC_R_NOMEMORY); } return (isc_socket_recv2(sock, region, minimum, task, dev, 0)); } isc_result_t isc_socket_recv2(isc_socket_t *sock, isc_region_t *region, unsigned int minimum, isc_task_t *task, isc_socketevent_t *event, unsigned int flags) { event->ev_sender = sock; event->result = ISC_R_UNSET; event->region = *region; event->n = 0; event->offset = 0; event->attributes = 0; /* * UDP sockets are always partial read. */ if (sock->type == isc_sockettype_udp) { event->minimum = 1; } else { if (minimum == 0) { event->minimum = region->length; } else { event->minimum = minimum; } } return (socket_recv(sock, event, task, flags)); } static isc_result_t socket_send(isc_socket_t *sock, isc_socketevent_t *dev, isc_task_t *task, const isc_sockaddr_t *address, struct in6_pktinfo *pktinfo, unsigned int flags) { int io_state; bool have_lock = false; isc_task_t *ntask = NULL; isc_result_t result = ISC_R_SUCCESS; dev->ev_sender = task; set_dev_address(address, sock, dev); if (pktinfo != NULL) { dev->attributes |= ISC_SOCKEVENTATTR_PKTINFO; dev->pktinfo = *pktinfo; if (!isc_sockaddr_issitelocal(&dev->address) && !isc_sockaddr_islinklocal(&dev->address)) { socket_log(sock, NULL, TRACE, "pktinfo structure provided, ifindex %u " "(set to 0)", pktinfo->ipi6_ifindex); /* * Set the pktinfo index to 0 here, to let the * kernel decide what interface it should send on. */ dev->pktinfo.ipi6_ifindex = 0; } } if (sock->type == isc_sockettype_udp) { io_state = doio_send(sock, dev); } else { LOCK(&sock->lock); have_lock = true; if (ISC_LIST_EMPTY(sock->send_list)) { io_state = doio_send(sock, dev); } else { io_state = DOIO_SOFT; } } switch (io_state) { case DOIO_SOFT: /* * We couldn't send all or part of the request right now, so * queue it unless ISC_SOCKFLAG_NORETRY is set. */ if ((flags & ISC_SOCKFLAG_NORETRY) == 0) { isc_task_attach(task, &ntask); dev->attributes |= ISC_SOCKEVENTATTR_ATTACHED; if (!have_lock) { LOCK(&sock->lock); have_lock = true; } /* * Enqueue the request. If the socket was previously * not being watched, poke the watcher to start * paying attention to it. */ bool do_poke = ISC_LIST_EMPTY(sock->send_list); ISC_LIST_ENQUEUE(sock->send_list, dev, ev_link); if (do_poke) { select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_WRITE); } socket_log(sock, NULL, EVENT, "socket_send: event %p -> task %p", dev, ntask); if ((flags & ISC_SOCKFLAG_IMMEDIATE) != 0) { result = ISC_R_INPROGRESS; } break; } FALLTHROUGH; case DOIO_HARD: case DOIO_SUCCESS: if (!have_lock) { LOCK(&sock->lock); have_lock = true; } if ((flags & ISC_SOCKFLAG_IMMEDIATE) == 0) { send_senddone_event(sock, &dev); } break; } if (have_lock) { UNLOCK(&sock->lock); } return (result); } isc_result_t isc_socket_send(isc_socket_t *sock, isc_region_t *region, isc_task_t *task, isc_taskaction_t action, void *arg) { /* * REQUIRE() checking is performed in isc_socket_sendto(). */ return (isc_socket_sendto(sock, region, task, action, arg, NULL, NULL)); } isc_result_t isc_socket_sendto(isc_socket_t *sock, isc_region_t *region, isc_task_t *task, isc_taskaction_t action, void *arg, const isc_sockaddr_t *address, struct in6_pktinfo *pktinfo) { isc_socketevent_t *dev; isc_socketmgr_t *manager; REQUIRE(VALID_SOCKET(sock)); REQUIRE(region != NULL); REQUIRE(task != NULL); REQUIRE(action != NULL); manager = sock->manager; REQUIRE(VALID_MANAGER(manager)); INSIST(sock->bound); dev = allocate_socketevent(manager->mctx, sock, ISC_SOCKEVENT_SENDDONE, action, arg); if (dev == NULL) { return (ISC_R_NOMEMORY); } dev->region = *region; return (socket_send(sock, dev, task, address, pktinfo, 0)); } isc_result_t isc_socket_sendto2(isc_socket_t *sock, isc_region_t *region, isc_task_t *task, const isc_sockaddr_t *address, struct in6_pktinfo *pktinfo, isc_socketevent_t *event, unsigned int flags) { REQUIRE(VALID_SOCKET(sock)); REQUIRE((flags & ~(ISC_SOCKFLAG_IMMEDIATE | ISC_SOCKFLAG_NORETRY)) == 0); if ((flags & ISC_SOCKFLAG_NORETRY) != 0) { REQUIRE(sock->type == isc_sockettype_udp); } event->ev_sender = sock; event->result = ISC_R_UNSET; event->region = *region; event->n = 0; event->offset = 0; event->attributes &= ~ISC_SOCKEVENTATTR_ATTACHED; return (socket_send(sock, event, task, address, pktinfo, flags)); } void isc_socket_cleanunix(const isc_sockaddr_t *sockaddr, bool active) { #ifdef ISC_PLATFORM_HAVESYSUNH int s; struct stat sb; char strbuf[ISC_STRERRORSIZE]; if (sockaddr->type.sa.sa_family != AF_UNIX) { return; } #ifndef S_ISSOCK #if defined(S_IFMT) && defined(S_IFSOCK) #define S_ISSOCK(mode) ((mode & S_IFMT) == S_IFSOCK) #elif defined(_S_IFMT) && defined(S_IFSOCK) #define S_ISSOCK(mode) ((mode & _S_IFMT) == S_IFSOCK) #endif /* if defined(S_IFMT) && defined(S_IFSOCK) */ #endif /* ifndef S_ISSOCK */ #ifndef S_ISFIFO #if defined(S_IFMT) && defined(S_IFIFO) #define S_ISFIFO(mode) ((mode & S_IFMT) == S_IFIFO) #elif defined(_S_IFMT) && defined(S_IFIFO) #define S_ISFIFO(mode) ((mode & _S_IFMT) == S_IFIFO) #endif /* if defined(S_IFMT) && defined(S_IFIFO) */ #endif /* ifndef S_ISFIFO */ #if !defined(S_ISFIFO) && !defined(S_ISSOCK) /* cppcheck-suppress preprocessorErrorDirective */ #error \ You need to define S_ISFIFO and S_ISSOCK as appropriate for your platform. See . #endif /* if !defined(S_ISFIFO) && !defined(S_ISSOCK) */ #ifndef S_ISFIFO #define S_ISFIFO(mode) 0 #endif /* ifndef S_ISFIFO */ #ifndef S_ISSOCK #define S_ISSOCK(mode) 0 #endif /* ifndef S_ISSOCK */ if (stat(sockaddr->type.sunix.sun_path, &sb) < 0) { switch (errno) { case ENOENT: if (active) { /* We exited cleanly last time */ break; } FALLTHROUGH; default: strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, active ? ISC_LOG_ERROR : ISC_LOG_WARNING, "isc_socket_cleanunix: stat(%s): %s", sockaddr->type.sunix.sun_path, strbuf); return; } } else { if (!(S_ISSOCK(sb.st_mode) || S_ISFIFO(sb.st_mode))) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, active ? ISC_LOG_ERROR : ISC_LOG_WARNING, "isc_socket_cleanunix: %s: not a socket", sockaddr->type.sunix.sun_path); return; } } if (active) { if (unlink(sockaddr->type.sunix.sun_path) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "isc_socket_cleanunix: unlink(%s): %s", sockaddr->type.sunix.sun_path, strbuf); } return; } s = socket(AF_UNIX, SOCK_STREAM, 0); if (s < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_WARNING, "isc_socket_cleanunix: socket(%s): %s", sockaddr->type.sunix.sun_path, strbuf); return; } if (connect(s, (const struct sockaddr *)&sockaddr->type.sunix, sizeof(sockaddr->type.sunix)) < 0) { switch (errno) { case ECONNREFUSED: case ECONNRESET: if (unlink(sockaddr->type.sunix.sun_path) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write( isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_WARNING, "isc_socket_cleanunix: " "unlink(%s): %s", sockaddr->type.sunix.sun_path, strbuf); } break; default: strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_WARNING, "isc_socket_cleanunix: connect(%s): %s", sockaddr->type.sunix.sun_path, strbuf); break; } } close(s); #else /* ifdef ISC_PLATFORM_HAVESYSUNH */ UNUSED(sockaddr); UNUSED(active); #endif /* ifdef ISC_PLATFORM_HAVESYSUNH */ } isc_result_t isc_socket_permunix(const isc_sockaddr_t *sockaddr, uint32_t perm, uint32_t owner, uint32_t group) { #ifdef ISC_PLATFORM_HAVESYSUNH isc_result_t result = ISC_R_SUCCESS; char strbuf[ISC_STRERRORSIZE]; char path[sizeof(sockaddr->type.sunix.sun_path)]; #ifdef NEED_SECURE_DIRECTORY char *slash; #endif /* ifdef NEED_SECURE_DIRECTORY */ REQUIRE(sockaddr->type.sa.sa_family == AF_UNIX); INSIST(strlen(sockaddr->type.sunix.sun_path) < sizeof(path)); strlcpy(path, sockaddr->type.sunix.sun_path, sizeof(path)); #ifdef NEED_SECURE_DIRECTORY slash = strrchr(path, '/'); if (slash != NULL) { if (slash != path) { *slash = '\0'; } else { strlcpy(path, "/", sizeof(path)); } } else { strlcpy(path, ".", sizeof(path)); } #endif /* ifdef NEED_SECURE_DIRECTORY */ if (chmod(path, perm) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "isc_socket_permunix: chmod(%s, %d): %s", path, perm, strbuf); result = ISC_R_FAILURE; } if (chown(path, owner, group) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_ERROR, "isc_socket_permunix: chown(%s, %d, %d): %s", path, owner, group, strbuf); result = ISC_R_FAILURE; } return (result); #else /* ifdef ISC_PLATFORM_HAVESYSUNH */ UNUSED(sockaddr); UNUSED(perm); UNUSED(owner); UNUSED(group); return (ISC_R_NOTIMPLEMENTED); #endif /* ifdef ISC_PLATFORM_HAVESYSUNH */ } isc_result_t isc_socket_bind(isc_socket_t *sock, const isc_sockaddr_t *sockaddr, isc_socket_options_t options) { char strbuf[ISC_STRERRORSIZE]; int on = 1; REQUIRE(VALID_SOCKET(sock)); LOCK(&sock->lock); INSIST(!sock->bound); INSIST(!sock->dupped); if (sock->pf != sockaddr->type.sa.sa_family) { UNLOCK(&sock->lock); return (ISC_R_FAMILYMISMATCH); } /* * Only set SO_REUSEADDR when we want a specific port. */ #ifdef AF_UNIX if (sock->pf == AF_UNIX) { goto bind_socket; } #endif /* ifdef AF_UNIX */ if ((options & ISC_SOCKET_REUSEADDRESS) != 0 && isc_sockaddr_getport(sockaddr) != (in_port_t)0) { if (setsockopt(sock->fd, SOL_SOCKET, SO_REUSEADDR, (void *)&on, sizeof(on)) < 0) { UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d) failed", sock->fd); } #if defined(__FreeBSD_kernel__) && defined(SO_REUSEPORT_LB) if (setsockopt(sock->fd, SOL_SOCKET, SO_REUSEPORT_LB, (void *)&on, sizeof(on)) < 0) { UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d) failed", sock->fd); } #elif defined(__linux__) && defined(SO_REUSEPORT) if (setsockopt(sock->fd, SOL_SOCKET, SO_REUSEPORT, (void *)&on, sizeof(on)) < 0) { UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d) failed", sock->fd); } #endif /* if defined(__FreeBSD_kernel__) && defined(SO_REUSEPORT_LB) */ /* Press on... */ } #ifdef AF_UNIX bind_socket: #endif /* ifdef AF_UNIX */ if (bind(sock->fd, &sockaddr->type.sa, sockaddr->length) < 0) { inc_stats(sock->manager->stats, sock->statsindex[STATID_BINDFAIL]); UNLOCK(&sock->lock); switch (errno) { case EACCES: return (ISC_R_NOPERM); case EADDRNOTAVAIL: return (ISC_R_ADDRNOTAVAIL); case EADDRINUSE: return (ISC_R_ADDRINUSE); case EINVAL: return (ISC_R_BOUND); default: strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "bind: %s", strbuf); return (ISC_R_UNEXPECTED); } } socket_log(sock, sockaddr, TRACE, "bound"); sock->bound = 1; UNLOCK(&sock->lock); return (ISC_R_SUCCESS); } /* * Enable this only for specific OS versions, and only when they have repaired * their problems with it. Until then, this is is broken and needs to be * disabled by default. See RT22589 for details. */ #undef ENABLE_ACCEPTFILTER isc_result_t isc_socket_filter(isc_socket_t *sock, const char *filter) { #if defined(SO_ACCEPTFILTER) && defined(ENABLE_ACCEPTFILTER) char strbuf[ISC_STRERRORSIZE]; struct accept_filter_arg afa; #else /* if defined(SO_ACCEPTFILTER) && defined(ENABLE_ACCEPTFILTER) */ UNUSED(sock); UNUSED(filter); #endif /* if defined(SO_ACCEPTFILTER) && defined(ENABLE_ACCEPTFILTER) */ REQUIRE(VALID_SOCKET(sock)); #if defined(SO_ACCEPTFILTER) && defined(ENABLE_ACCEPTFILTER) bzero(&afa, sizeof(afa)); strlcpy(afa.af_name, filter, sizeof(afa.af_name)); if (setsockopt(sock->fd, SOL_SOCKET, SO_ACCEPTFILTER, &afa, sizeof(afa)) == -1) { strerror_r(errno, strbuf, sizeof(strbuf)); socket_log(sock, NULL, CREATION, "setsockopt(SO_ACCEPTFILTER): %s", strbuf); return (ISC_R_FAILURE); } return (ISC_R_SUCCESS); #else /* if defined(SO_ACCEPTFILTER) && defined(ENABLE_ACCEPTFILTER) */ return (ISC_R_NOTIMPLEMENTED); #endif /* if defined(SO_ACCEPTFILTER) && defined(ENABLE_ACCEPTFILTER) */ } /* * Try enabling TCP Fast Open for a given socket if the OS supports it. */ static void set_tcp_fastopen(isc_socket_t *sock, unsigned int backlog) { #if defined(ENABLE_TCP_FASTOPEN) && defined(TCP_FASTOPEN) char strbuf[ISC_STRERRORSIZE]; /* * FreeBSD, as of versions 10.3 and 11.0, defines TCP_FASTOPEN while also * shipping a default kernel without TFO support, so we special-case it by * performing an additional runtime check for TFO support using sysctl to * prevent setsockopt() errors from being logged. */ #if defined(__FreeBSD__) && defined(HAVE_SYSCTLBYNAME) #define SYSCTL_TFO "net.inet.tcp.fastopen.enabled" unsigned int enabled; size_t enabledlen = sizeof(enabled); static bool tfo_notice_logged = false; if (sysctlbyname(SYSCTL_TFO, &enabled, &enabledlen, NULL, 0) < 0) { /* * This kernel does not support TCP Fast Open. There is * nothing more we can do. */ return; } else if (enabled == 0) { /* * This kernel does support TCP Fast Open, but it is disabled * by sysctl. Notify the user, but do not nag. */ if (!tfo_notice_logged) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_SOCKET, ISC_LOG_NOTICE, "TCP_FASTOPEN support is disabled by " "sysctl (" SYSCTL_TFO " = 0)"); tfo_notice_logged = true; } return; } #endif /* if defined(__FreeBSD__) && defined(HAVE_SYSCTLBYNAME) */ #ifdef __APPLE__ backlog = 1; #else /* ifdef __APPLE__ */ backlog = backlog / 2; if (backlog == 0) { backlog = 1; } #endif /* ifdef __APPLE__ */ if (setsockopt(sock->fd, IPPROTO_TCP, TCP_FASTOPEN, (void *)&backlog, sizeof(backlog)) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, TCP_FASTOPEN) failed with %s", sock->fd, strbuf); /* TCP_FASTOPEN is experimental so ignore failures */ } #else /* if defined(ENABLE_TCP_FASTOPEN) && defined(TCP_FASTOPEN) */ UNUSED(sock); UNUSED(backlog); #endif /* if defined(ENABLE_TCP_FASTOPEN) && defined(TCP_FASTOPEN) */ } /* * Set up to listen on a given socket. We do this by creating an internal * event that will be dispatched when the socket has read activity. The * watcher will send the internal event to the task when there is a new * connection. * * Unlike in read, we don't preallocate a done event here. Every time there * is a new connection we'll have to allocate a new one anyway, so we might * as well keep things simple rather than having to track them. */ isc_result_t isc_socket_listen(isc_socket_t *sock, unsigned int backlog) { char strbuf[ISC_STRERRORSIZE]; REQUIRE(VALID_SOCKET(sock)); LOCK(&sock->lock); REQUIRE(!sock->listener); REQUIRE(sock->bound); REQUIRE(sock->type == isc_sockettype_tcp || sock->type == isc_sockettype_unix); if (backlog == 0) { backlog = SOMAXCONN; } if (listen(sock->fd, (int)backlog) < 0) { UNLOCK(&sock->lock); strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "listen: %s", strbuf); return (ISC_R_UNEXPECTED); } set_tcp_fastopen(sock, backlog); sock->listener = 1; UNLOCK(&sock->lock); return (ISC_R_SUCCESS); } /* * This should try to do aggressive accept() XXXMLG */ isc_result_t isc_socket_accept(isc_socket_t *sock, isc_task_t *task, isc_taskaction_t action, void *arg) { isc_socket_newconnev_t *dev; isc_socketmgr_t *manager; isc_task_t *ntask = NULL; isc_socket_t *nsock; isc_result_t result; bool do_poke = false; REQUIRE(VALID_SOCKET(sock)); manager = sock->manager; REQUIRE(VALID_MANAGER(manager)); LOCK(&sock->lock); REQUIRE(sock->listener); /* * Sender field is overloaded here with the task we will be sending * this event to. Just before the actual event is delivered the * actual ev_sender will be touched up to be the socket. */ dev = (isc_socket_newconnev_t *)isc_event_allocate( manager->mctx, task, ISC_SOCKEVENT_NEWCONN, action, arg, sizeof(*dev)); ISC_LINK_INIT(dev, ev_link); result = allocate_socket(manager, sock->type, &nsock); if (result != ISC_R_SUCCESS) { isc_event_free(ISC_EVENT_PTR(&dev)); UNLOCK(&sock->lock); return (result); } /* * Attach to socket and to task. */ isc_task_attach(task, &ntask); if (isc_task_exiting(ntask)) { free_socket(&nsock); isc_task_detach(&ntask); isc_event_free(ISC_EVENT_PTR(&dev)); UNLOCK(&sock->lock); return (ISC_R_SHUTTINGDOWN); } isc_refcount_increment0(&nsock->references); nsock->statsindex = sock->statsindex; dev->ev_sender = ntask; dev->newsocket = nsock; /* * Poke watcher here. We still have the socket locked, so there * is no race condition. We will keep the lock for such a short * bit of time waking it up now or later won't matter all that much. */ do_poke = ISC_LIST_EMPTY(sock->accept_list); ISC_LIST_ENQUEUE(sock->accept_list, dev, ev_link); if (do_poke) { select_poke(manager, sock->threadid, sock->fd, SELECT_POKE_ACCEPT); } UNLOCK(&sock->lock); return (ISC_R_SUCCESS); } isc_result_t isc_socket_connect(isc_socket_t *sock, const isc_sockaddr_t *addr, isc_task_t *task, isc_taskaction_t action, void *arg) { isc_socket_connev_t *dev; isc_task_t *ntask = NULL; isc_socketmgr_t *manager; int cc; char strbuf[ISC_STRERRORSIZE]; char addrbuf[ISC_SOCKADDR_FORMATSIZE]; REQUIRE(VALID_SOCKET(sock)); REQUIRE(addr != NULL); REQUIRE(task != NULL); REQUIRE(action != NULL); manager = sock->manager; REQUIRE(VALID_MANAGER(manager)); REQUIRE(addr != NULL); if (isc_sockaddr_ismulticast(addr)) { return (ISC_R_MULTICAST); } LOCK(&sock->lock); dev = (isc_socket_connev_t *)isc_event_allocate( manager->mctx, sock, ISC_SOCKEVENT_CONNECT, action, arg, sizeof(*dev)); ISC_LINK_INIT(dev, ev_link); if (sock->connecting) { INSIST(isc_sockaddr_equal(&sock->peer_address, addr)); goto queue; } if (sock->connected) { INSIST(isc_sockaddr_equal(&sock->peer_address, addr)); dev->result = ISC_R_SUCCESS; isc_task_sendto(task, ISC_EVENT_PTR(&dev), sock->threadid); UNLOCK(&sock->lock); return (ISC_R_SUCCESS); } /* * Try to do the connect right away, as there can be only one * outstanding, and it might happen to complete. */ sock->peer_address = *addr; cc = connect(sock->fd, &addr->type.sa, addr->length); if (cc < 0) { /* * The socket is nonblocking and the connection cannot be * completed immediately. It is possible to select(2) or * poll(2) for completion by selecting the socket for writing. * After select(2) indicates writability, use getsockopt(2) to * read the SO_ERROR option at level SOL_SOCKET to determine * whether connect() completed successfully (SO_ERROR is zero) * or unsuccessfully (SO_ERROR is one of the usual error codes * listed here, explaining the reason for the failure). */ if (sock->type == isc_sockettype_udp && errno == EINPROGRESS) { cc = 0; goto success; } if (SOFT_ERROR(errno) || errno == EINPROGRESS) { goto queue; } switch (errno) { #define ERROR_MATCH(a, b) \ case a: \ dev->result = b; \ goto err_exit; ERROR_MATCH(EACCES, ISC_R_NOPERM); ERROR_MATCH(EADDRNOTAVAIL, ISC_R_ADDRNOTAVAIL); ERROR_MATCH(EAFNOSUPPORT, ISC_R_ADDRNOTAVAIL); ERROR_MATCH(ECONNREFUSED, ISC_R_CONNREFUSED); ERROR_MATCH(EHOSTUNREACH, ISC_R_HOSTUNREACH); #ifdef EHOSTDOWN ERROR_MATCH(EHOSTDOWN, ISC_R_HOSTUNREACH); #endif /* ifdef EHOSTDOWN */ ERROR_MATCH(ENETUNREACH, ISC_R_NETUNREACH); ERROR_MATCH(ENOBUFS, ISC_R_NORESOURCES); ERROR_MATCH(EPERM, ISC_R_HOSTUNREACH); ERROR_MATCH(EPIPE, ISC_R_NOTCONNECTED); ERROR_MATCH(ETIMEDOUT, ISC_R_TIMEDOUT); ERROR_MATCH(ECONNRESET, ISC_R_CONNECTIONRESET); #undef ERROR_MATCH } sock->connected = 0; strerror_r(errno, strbuf, sizeof(strbuf)); isc_sockaddr_format(addr, addrbuf, sizeof(addrbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "connect(%s) %d/%s", addrbuf, errno, strbuf); UNLOCK(&sock->lock); inc_stats(sock->manager->stats, sock->statsindex[STATID_CONNECTFAIL]); isc_event_free(ISC_EVENT_PTR(&dev)); return (ISC_R_UNEXPECTED); err_exit: sock->connected = 0; isc_task_sendto(task, ISC_EVENT_PTR(&dev), sock->threadid); UNLOCK(&sock->lock); inc_stats(sock->manager->stats, sock->statsindex[STATID_CONNECTFAIL]); return (ISC_R_SUCCESS); } /* * If connect completed, fire off the done event. */ success: if (cc == 0) { sock->connected = 1; sock->bound = 1; dev->result = ISC_R_SUCCESS; isc_task_sendto(task, ISC_EVENT_PTR(&dev), sock->threadid); UNLOCK(&sock->lock); inc_stats(sock->manager->stats, sock->statsindex[STATID_CONNECT]); return (ISC_R_SUCCESS); } queue: /* * Attach to task. */ isc_task_attach(task, &ntask); dev->ev_sender = ntask; /* * Poke watcher here. We still have the socket locked, so there * is no race condition. We will keep the lock for such a short * bit of time waking it up now or later won't matter all that much. */ bool do_poke = ISC_LIST_EMPTY(sock->connect_list); ISC_LIST_ENQUEUE(sock->connect_list, dev, ev_link); if (do_poke && !sock->connecting) { sock->connecting = 1; select_poke(manager, sock->threadid, sock->fd, SELECT_POKE_CONNECT); } UNLOCK(&sock->lock); return (ISC_R_SUCCESS); } /* * Called when a socket with a pending connect() finishes. */ static void internal_connect(isc_socket_t *sock) { isc_socket_connev_t *dev; int cc; isc_result_t result; socklen_t optlen; char strbuf[ISC_STRERRORSIZE]; char peerbuf[ISC_SOCKADDR_FORMATSIZE]; INSIST(VALID_SOCKET(sock)); REQUIRE(sock->fd >= 0); /* * Get the first item off the connect list. * If it is empty, unlock the socket and return. */ dev = ISC_LIST_HEAD(sock->connect_list); if (dev == NULL) { INSIST(!sock->connecting); goto finish; } INSIST(sock->connecting); sock->connecting = 0; /* * Get any possible error status here. */ optlen = sizeof(cc); if (getsockopt(sock->fd, SOL_SOCKET, SO_ERROR, (void *)&cc, (void *)&optlen) != 0) { cc = errno; } else { errno = cc; } if (errno != 0) { /* * If the error is EAGAIN, just re-select on this * fd and pretend nothing strange happened. */ if (SOFT_ERROR(errno) || errno == EINPROGRESS) { sock->connecting = 1; return; } inc_stats(sock->manager->stats, sock->statsindex[STATID_CONNECTFAIL]); /* * Translate other errors into ISC_R_* flavors. */ switch (errno) { #define ERROR_MATCH(a, b) \ case a: \ result = b; \ break; ERROR_MATCH(EACCES, ISC_R_NOPERM); ERROR_MATCH(EADDRNOTAVAIL, ISC_R_ADDRNOTAVAIL); ERROR_MATCH(EAFNOSUPPORT, ISC_R_ADDRNOTAVAIL); ERROR_MATCH(ECONNREFUSED, ISC_R_CONNREFUSED); ERROR_MATCH(EHOSTUNREACH, ISC_R_HOSTUNREACH); #ifdef EHOSTDOWN ERROR_MATCH(EHOSTDOWN, ISC_R_HOSTUNREACH); #endif /* ifdef EHOSTDOWN */ ERROR_MATCH(ENETUNREACH, ISC_R_NETUNREACH); ERROR_MATCH(ENOBUFS, ISC_R_NORESOURCES); ERROR_MATCH(EPERM, ISC_R_HOSTUNREACH); ERROR_MATCH(EPIPE, ISC_R_NOTCONNECTED); ERROR_MATCH(ETIMEDOUT, ISC_R_TIMEDOUT); ERROR_MATCH(ECONNRESET, ISC_R_CONNECTIONRESET); #undef ERROR_MATCH default: result = ISC_R_UNEXPECTED; isc_sockaddr_format(&sock->peer_address, peerbuf, sizeof(peerbuf)); strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "internal_connect: connect(%s) %s", peerbuf, strbuf); } } else { inc_stats(sock->manager->stats, sock->statsindex[STATID_CONNECT]); result = ISC_R_SUCCESS; sock->connected = 1; sock->bound = 1; } do { dev->result = result; send_connectdone_event(sock, &dev); dev = ISC_LIST_HEAD(sock->connect_list); } while (dev != NULL); finish: unwatch_fd(&sock->manager->threads[sock->threadid], sock->fd, SELECT_POKE_CONNECT); } isc_result_t isc_socket_getpeername(isc_socket_t *sock, isc_sockaddr_t *addressp) { isc_result_t result; REQUIRE(VALID_SOCKET(sock)); REQUIRE(addressp != NULL); LOCK(&sock->lock); if (sock->connected) { *addressp = sock->peer_address; result = ISC_R_SUCCESS; } else { result = ISC_R_NOTCONNECTED; } UNLOCK(&sock->lock); return (result); } isc_result_t isc_socket_getsockname(isc_socket_t *sock, isc_sockaddr_t *addressp) { socklen_t len; isc_result_t result; char strbuf[ISC_STRERRORSIZE]; REQUIRE(VALID_SOCKET(sock)); REQUIRE(addressp != NULL); LOCK(&sock->lock); if (!sock->bound) { result = ISC_R_NOTBOUND; goto out; } result = ISC_R_SUCCESS; len = sizeof(addressp->type); if (getsockname(sock->fd, &addressp->type.sa, (void *)&len) < 0) { strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "getsockname: %s", strbuf); result = ISC_R_UNEXPECTED; goto out; } addressp->length = (unsigned int)len; out: UNLOCK(&sock->lock); return (result); } /* * Run through the list of events on this socket, and cancel the ones * queued for task "task" of type "how". "how" is a bitmask. */ void isc_socket_cancel(isc_socket_t *sock, isc_task_t *task, unsigned int how) { REQUIRE(VALID_SOCKET(sock)); /* * Quick exit if there is nothing to do. Don't even bother locking * in this case. */ if (how == 0) { return; } LOCK(&sock->lock); /* * All of these do the same thing, more or less. * Each will: * o If the internal event is marked as "posted" try to * remove it from the task's queue. If this fails, mark it * as canceled instead, and let the task clean it up later. * o For each I/O request for that task of that type, post * its done event with status of "ISC_R_CANCELED". * o Reset any state needed. */ if (((how & ISC_SOCKCANCEL_RECV) != 0) && !ISC_LIST_EMPTY(sock->recv_list)) { isc_socketevent_t *dev; isc_socketevent_t *next; isc_task_t *current_task; dev = ISC_LIST_HEAD(sock->recv_list); while (dev != NULL) { current_task = dev->ev_sender; next = ISC_LIST_NEXT(dev, ev_link); if ((task == NULL) || (task == current_task)) { dev->result = ISC_R_CANCELED; send_recvdone_event(sock, &dev); } dev = next; } } if (((how & ISC_SOCKCANCEL_SEND) != 0) && !ISC_LIST_EMPTY(sock->send_list)) { isc_socketevent_t *dev; isc_socketevent_t *next; isc_task_t *current_task; dev = ISC_LIST_HEAD(sock->send_list); while (dev != NULL) { current_task = dev->ev_sender; next = ISC_LIST_NEXT(dev, ev_link); if ((task == NULL) || (task == current_task)) { dev->result = ISC_R_CANCELED; send_senddone_event(sock, &dev); } dev = next; } } if (((how & ISC_SOCKCANCEL_ACCEPT) != 0) && !ISC_LIST_EMPTY(sock->accept_list)) { isc_socket_newconnev_t *dev; isc_socket_newconnev_t *next; isc_task_t *current_task; dev = ISC_LIST_HEAD(sock->accept_list); while (dev != NULL) { current_task = dev->ev_sender; next = ISC_LIST_NEXT(dev, ev_link); if ((task == NULL) || (task == current_task)) { ISC_LIST_UNLINK(sock->accept_list, dev, ev_link); isc_refcount_decrementz( &NEWCONNSOCK(dev)->references); free_socket((isc_socket_t **)&dev->newsocket); dev->result = ISC_R_CANCELED; dev->ev_sender = sock; isc_task_sendtoanddetach(¤t_task, ISC_EVENT_PTR(&dev), sock->threadid); } dev = next; } } if (((how & ISC_SOCKCANCEL_CONNECT) != 0) && !ISC_LIST_EMPTY(sock->connect_list)) { isc_socket_connev_t *dev; isc_socket_connev_t *next; isc_task_t *current_task; INSIST(sock->connecting); sock->connecting = 0; dev = ISC_LIST_HEAD(sock->connect_list); while (dev != NULL) { current_task = dev->ev_sender; next = ISC_LIST_NEXT(dev, ev_link); if ((task == NULL) || (task == current_task)) { dev->result = ISC_R_CANCELED; send_connectdone_event(sock, &dev); } dev = next; } } UNLOCK(&sock->lock); } isc_sockettype_t isc_socket_gettype(isc_socket_t *sock) { REQUIRE(VALID_SOCKET(sock)); return (sock->type); } void isc_socket_ipv6only(isc_socket_t *sock, bool yes) { #if defined(IPV6_V6ONLY) && !defined(__OpenBSD__) int onoff = yes ? 1 : 0; #else /* if defined(IPV6_V6ONLY) */ UNUSED(yes); UNUSED(sock); #endif /* if defined(IPV6_V6ONLY) */ REQUIRE(VALID_SOCKET(sock)); INSIST(!sock->dupped); #if defined(IPV6_V6ONLY) && !defined(__OpenBSD__) if (sock->pf == AF_INET6) { if (setsockopt(sock->fd, IPPROTO_IPV6, IPV6_V6ONLY, (void *)&onoff, sizeof(int)) < 0) { char strbuf[ISC_STRERRORSIZE]; strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IPV6_V6ONLY) failed: " "%s", sock->fd, strbuf); } } #endif /* ifdef IPV6_V6ONLY */ } static void setdscp(isc_socket_t *sock, isc_dscp_t dscp) { #if defined(IP_TOS) || defined(IPV6_TCLASS) int value = dscp << 2; #endif /* if defined(IP_TOS) || defined(IPV6_TCLASS) */ sock->dscp = dscp; #ifdef IP_TOS if (sock->pf == AF_INET) { if (setsockopt(sock->fd, IPPROTO_IP, IP_TOS, (void *)&value, sizeof(value)) < 0) { char strbuf[ISC_STRERRORSIZE]; strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IP_TOS, %.02x) " "failed: %s", sock->fd, value >> 2, strbuf); } } #endif /* ifdef IP_TOS */ #ifdef IPV6_TCLASS if (sock->pf == AF_INET6) { if (setsockopt(sock->fd, IPPROTO_IPV6, IPV6_TCLASS, (void *)&value, sizeof(value)) < 0) { char strbuf[ISC_STRERRORSIZE]; strerror_r(errno, strbuf, sizeof(strbuf)); UNEXPECTED_ERROR(__FILE__, __LINE__, "setsockopt(%d, IPV6_TCLASS, %.02x) " "failed: %s", sock->fd, dscp >> 2, strbuf); } } #endif /* ifdef IPV6_TCLASS */ } void isc_socket_dscp(isc_socket_t *sock, isc_dscp_t dscp) { REQUIRE(VALID_SOCKET(sock)); REQUIRE(dscp < 0x40); #if !defined(IP_TOS) && !defined(IPV6_TCLASS) UNUSED(dscp); #else /* if !defined(IP_TOS) && !defined(IPV6_TCLASS) */ if (dscp < 0) { return; } /* The DSCP value must not be changed once it has been set. */ if (isc_dscp_check_value != -1) { INSIST(dscp == isc_dscp_check_value); } #endif /* if !defined(IP_TOS) && !defined(IPV6_TCLASS) */ #ifdef notyet REQUIRE(!sock->dupped); #endif /* ifdef notyet */ setdscp(sock, dscp); } isc_socketevent_t * isc_socket_socketevent(isc_mem_t *mctx, void *sender, isc_eventtype_t eventtype, isc_taskaction_t action, void *arg) { return (allocate_socketevent(mctx, sender, eventtype, action, arg)); } void isc_socket_setname(isc_socket_t *sock, const char *name, void *tag) { /* * Name 'sock'. */ REQUIRE(VALID_SOCKET(sock)); LOCK(&sock->lock); strlcpy(sock->name, name, sizeof(sock->name)); sock->tag = tag; UNLOCK(&sock->lock); } const char * isc_socket_getname(isc_socket_t *sock) { return (sock->name); } void * isc_socket_gettag(isc_socket_t *sock) { return (sock->tag); } int isc_socket_getfd(isc_socket_t *sock) { return ((short)sock->fd); } static isc_once_t hasreuseport_once = ISC_ONCE_INIT; static bool hasreuseport = false; static void init_hasreuseport(void) { /* * SO_REUSEPORT works very differently on *BSD and on Linux (because why not). * We only want to use it on Linux, if it's available. On BSD we want to dup() * sockets instead of re-binding them. */ #if (defined(SO_REUSEPORT) && defined(__linux__)) || \ (defined(SO_REUSEPORT_LB) && defined(__FreeBSD_kernel__)) int sock, yes = 1; sock = socket(AF_INET, SOCK_DGRAM, 0); if (sock < 0) { sock = socket(AF_INET6, SOCK_DGRAM, 0); if (sock < 0) { return; } } if (setsockopt(sock, SOL_SOCKET, SO_REUSEADDR, (void *)&yes, sizeof(yes)) < 0) { close(sock); return; #if defined(__FreeBSD_kernel__) } else if (setsockopt(sock, SOL_SOCKET, SO_REUSEPORT_LB, (void *)&yes, sizeof(yes)) < 0) #else /* if defined(__FreeBSD_kernel__) */ } else if (setsockopt(sock, SOL_SOCKET, SO_REUSEPORT, (void *)&yes, sizeof(yes)) < 0) #endif /* if defined(__FreeBSD_kernel__) */ { close(sock); return; } hasreuseport = true; close(sock); #endif /* if (defined(SO_REUSEPORT) && defined(__linux__)) || \ * (defined(SO_REUSEPORT_LB) && defined(__FreeBSD_kernel__)) */ } bool isc_socket_hasreuseport() { RUNTIME_CHECK(isc_once_do(&hasreuseport_once, init_hasreuseport) == ISC_R_SUCCESS); return (hasreuseport); } #if defined(HAVE_LIBXML2) || defined(HAVE_JSON_C) static const char * _socktype(isc_sockettype_t type) { switch (type) { case isc_sockettype_udp: return ("udp"); case isc_sockettype_tcp: return ("tcp"); case isc_sockettype_unix: return ("unix"); case isc_sockettype_fdwatch: return ("fdwatch"); default: return ("not-initialized"); } } #endif /* if defined(HAVE_LIBXML2) || defined(HAVE_JSON_C) */ #ifdef HAVE_LIBXML2 #define TRY0(a) \ do { \ xmlrc = (a); \ if (xmlrc < 0) \ goto error; \ } while (0) int isc_socketmgr_renderxml(isc_socketmgr_t *mgr, void *writer0) { isc_socket_t *sock = NULL; char peerbuf[ISC_SOCKADDR_FORMATSIZE]; isc_sockaddr_t addr; socklen_t len; int xmlrc; xmlTextWriterPtr writer = (xmlTextWriterPtr)writer0; LOCK(&mgr->lock); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "sockets")); sock = ISC_LIST_HEAD(mgr->socklist); while (sock != NULL) { LOCK(&sock->lock); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "socket")); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "id")); TRY0(xmlTextWriterWriteFormatString(writer, "%p", sock)); TRY0(xmlTextWriterEndElement(writer)); if (sock->name[0] != 0) { TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "name")); TRY0(xmlTextWriterWriteFormatString(writer, "%s", sock->name)); TRY0(xmlTextWriterEndElement(writer)); /* name */ } TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "references")); TRY0(xmlTextWriterWriteFormatString( writer, "%d", (int)isc_refcount_current(&sock->references))); TRY0(xmlTextWriterEndElement(writer)); TRY0(xmlTextWriterWriteElement( writer, ISC_XMLCHAR "type", ISC_XMLCHAR _socktype(sock->type))); if (sock->connected) { isc_sockaddr_format(&sock->peer_address, peerbuf, sizeof(peerbuf)); TRY0(xmlTextWriterWriteElement( writer, ISC_XMLCHAR "peer-address", ISC_XMLCHAR peerbuf)); } len = sizeof(addr); if (getsockname(sock->fd, &addr.type.sa, (void *)&len) == 0) { isc_sockaddr_format(&addr, peerbuf, sizeof(peerbuf)); TRY0(xmlTextWriterWriteElement( writer, ISC_XMLCHAR "local-address", ISC_XMLCHAR peerbuf)); } TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "states")); if (sock->listener) { TRY0(xmlTextWriterWriteElement(writer, ISC_XMLCHAR "state", ISC_XMLCHAR "listener")); } if (sock->connected) { TRY0(xmlTextWriterWriteElement( writer, ISC_XMLCHAR "state", ISC_XMLCHAR "connected")); } if (sock->connecting) { TRY0(xmlTextWriterWriteElement( writer, ISC_XMLCHAR "state", ISC_XMLCHAR "connecting")); } if (sock->bound) { TRY0(xmlTextWriterWriteElement(writer, ISC_XMLCHAR "state", ISC_XMLCHAR "bound")); } TRY0(xmlTextWriterEndElement(writer)); /* states */ TRY0(xmlTextWriterEndElement(writer)); /* socket */ UNLOCK(&sock->lock); sock = ISC_LIST_NEXT(sock, link); } TRY0(xmlTextWriterEndElement(writer)); /* sockets */ error: if (sock != NULL) { UNLOCK(&sock->lock); } UNLOCK(&mgr->lock); return (xmlrc); } #endif /* HAVE_LIBXML2 */ #ifdef HAVE_JSON_C #define CHECKMEM(m) \ do { \ if (m == NULL) { \ result = ISC_R_NOMEMORY; \ goto error; \ } \ } while (0) isc_result_t isc_socketmgr_renderjson(isc_socketmgr_t *mgr, void *stats0) { isc_result_t result = ISC_R_SUCCESS; isc_socket_t *sock = NULL; char peerbuf[ISC_SOCKADDR_FORMATSIZE]; isc_sockaddr_t addr; socklen_t len; json_object *obj, *array = json_object_new_array(); json_object *stats = (json_object *)stats0; CHECKMEM(array); LOCK(&mgr->lock); sock = ISC_LIST_HEAD(mgr->socklist); while (sock != NULL) { json_object *states, *entry = json_object_new_object(); char buf[255]; CHECKMEM(entry); json_object_array_add(array, entry); LOCK(&sock->lock); snprintf(buf, sizeof(buf), "%p", sock); obj = json_object_new_string(buf); CHECKMEM(obj); json_object_object_add(entry, "id", obj); if (sock->name[0] != 0) { obj = json_object_new_string(sock->name); CHECKMEM(obj); json_object_object_add(entry, "name", obj); } obj = json_object_new_int( (int)isc_refcount_current(&sock->references)); CHECKMEM(obj); json_object_object_add(entry, "references", obj); obj = json_object_new_string(_socktype(sock->type)); CHECKMEM(obj); json_object_object_add(entry, "type", obj); if (sock->connected) { isc_sockaddr_format(&sock->peer_address, peerbuf, sizeof(peerbuf)); obj = json_object_new_string(peerbuf); CHECKMEM(obj); json_object_object_add(entry, "peer-address", obj); } len = sizeof(addr); if (getsockname(sock->fd, &addr.type.sa, (void *)&len) == 0) { isc_sockaddr_format(&addr, peerbuf, sizeof(peerbuf)); obj = json_object_new_string(peerbuf); CHECKMEM(obj); json_object_object_add(entry, "local-address", obj); } states = json_object_new_array(); CHECKMEM(states); json_object_object_add(entry, "states", states); if (sock->listener) { obj = json_object_new_string("listener"); CHECKMEM(obj); json_object_array_add(states, obj); } if (sock->connected) { obj = json_object_new_string("connected"); CHECKMEM(obj); json_object_array_add(states, obj); } if (sock->connecting) { obj = json_object_new_string("connecting"); CHECKMEM(obj); json_object_array_add(states, obj); } if (sock->bound) { obj = json_object_new_string("bound"); CHECKMEM(obj); json_object_array_add(states, obj); } UNLOCK(&sock->lock); sock = ISC_LIST_NEXT(sock, link); } json_object_object_add(stats, "sockets", array); array = NULL; result = ISC_R_SUCCESS; error: if (array != NULL) { json_object_put(array); } if (sock != NULL) { UNLOCK(&sock->lock); } UNLOCK(&mgr->lock); return (result); } #endif /* HAVE_JSON_C */ /* * Create a new 'type' socket managed by 'manager'. Events * will be posted to 'task' and when dispatched 'action' will be * called with 'arg' as the arg value. The new socket is returned * in 'socketp'. */ isc_result_t isc_socket_fdwatchcreate(isc_socketmgr_t *manager, int fd, int flags, isc_sockfdwatch_t callback, void *cbarg, isc_task_t *task, isc_socket_t **socketp) { isc_socket_t *sock = NULL; isc__socketthread_t *thread; isc_result_t result; int lockid; REQUIRE(VALID_MANAGER(manager)); REQUIRE(socketp != NULL && *socketp == NULL); if (fd < 0 || (unsigned int)fd >= manager->maxsocks) return (ISC_R_RANGE); result = allocate_socket(manager, isc_sockettype_fdwatch, &sock); if (result != ISC_R_SUCCESS) return (result); sock->fd = fd; sock->fdwatcharg = cbarg; sock->fdwatchcb = callback; sock->fdwatchflags = flags; sock->fdwatchtask = task; sock->threadid = gen_threadid(sock); isc_refcount_init(&sock->references, 1); thread = &manager->threads[sock->threadid]; *socketp = (isc_socket_t *)sock; /* * Note we don't have to lock the socket like we normally would because * there are no external references to it yet. */ lockid = FDLOCK_ID(sock->fd); LOCK(&thread->fdlock[lockid]); thread->fds[sock->fd] = sock; thread->fdstate[sock->fd] = MANAGED; #if defined(USE_EPOLL) manager->epoll_events[sock->fd] = 0; #endif #ifdef USE_DEVPOLL INSIST(thread->fdpollinfo[sock->fd].want_read == 0 && thread->fdpollinfo[sock->fd].want_write == 0); #endif /* ifdef USE_DEVPOLL */ UNLOCK(&thread->fdlock[lockid]); LOCK(&manager->lock); ISC_LIST_APPEND(manager->socklist, sock, link); #ifdef USE_SELECT if (thread->maxfd < sock->fd) thread->maxfd = sock->fd; #endif UNLOCK(&manager->lock); sock->active = 1; if (flags & ISC_SOCKFDWATCH_READ) select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_READ); if (flags & ISC_SOCKFDWATCH_WRITE) select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_WRITE); socket_log(sock, NULL, CREATION, "fdwatch-created"); return (ISC_R_SUCCESS); } /* * Indicate to the manager that it should watch the socket again. * This can be used to restart watching if the previous event handler * didn't indicate there was more data to be processed. Primarily * it is for writing but could be used for reading if desired */ isc_result_t isc_socket_fdwatchpoke(isc_socket_t *sock, int flags) { REQUIRE(VALID_SOCKET(sock)); /* * We check both flags first to allow us to get the lock * once but only if we need it. */ if ((flags & (ISC_SOCKFDWATCH_READ | ISC_SOCKFDWATCH_WRITE)) != 0) { LOCK(&sock->lock); if ((flags & ISC_SOCKFDWATCH_READ) != 0) select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_READ); if ((flags & ISC_SOCKFDWATCH_WRITE) != 0) select_poke(sock->manager, sock->threadid, sock->fd, SELECT_POKE_WRITE); UNLOCK(&sock->lock); } socket_log(sock, NULL, TRACE, "fdwatch-poked flags: %d", flags); return (ISC_R_SUCCESS); }