/* SPDX-License-Identifier: LGPL-2.1+ */ #include #include #include #include #include #include #include #include #include #include #include #include "sd-resolve.h" #include "alloc-util.h" #include "dns-domain.h" #include "fd-util.h" #include "io-util.h" #include "list.h" #include "missing.h" #include "socket-util.h" #include "util.h" #include "process-util.h" #define WORKERS_MIN 1U #define WORKERS_MAX 16U #define QUERIES_MAX 256U #define BUFSIZE 10240U typedef enum { REQUEST_ADDRINFO, RESPONSE_ADDRINFO, REQUEST_NAMEINFO, RESPONSE_NAMEINFO, REQUEST_TERMINATE, RESPONSE_DIED } QueryType; enum { REQUEST_RECV_FD, REQUEST_SEND_FD, RESPONSE_RECV_FD, RESPONSE_SEND_FD, _FD_MAX }; struct sd_resolve { unsigned n_ref; bool dead:1; pid_t original_pid; int fds[_FD_MAX]; pthread_t workers[WORKERS_MAX]; unsigned n_valid_workers; unsigned current_id; sd_resolve_query* query_array[QUERIES_MAX]; unsigned n_queries, n_done, n_outstanding; sd_event_source *event_source; sd_event *event; sd_resolve_query *current; sd_resolve **default_resolve_ptr; pid_t tid; LIST_HEAD(sd_resolve_query, queries); }; struct sd_resolve_query { unsigned n_ref; sd_resolve *resolve; QueryType type:4; bool done:1; bool floating:1; unsigned id; int ret; int _errno; int _h_errno; struct addrinfo *addrinfo; char *serv, *host; union { sd_resolve_getaddrinfo_handler_t getaddrinfo_handler; sd_resolve_getnameinfo_handler_t getnameinfo_handler; }; void *userdata; sd_resolve_destroy_t destroy_callback; LIST_FIELDS(sd_resolve_query, queries); }; typedef struct RHeader { QueryType type; unsigned id; size_t length; } RHeader; typedef struct AddrInfoRequest { struct RHeader header; bool hints_valid; int ai_flags; int ai_family; int ai_socktype; int ai_protocol; size_t node_len, service_len; } AddrInfoRequest; typedef struct AddrInfoResponse { struct RHeader header; int ret; int _errno; int _h_errno; /* followed by addrinfo_serialization[] */ } AddrInfoResponse; typedef struct AddrInfoSerialization { int ai_flags; int ai_family; int ai_socktype; int ai_protocol; size_t ai_addrlen; size_t canonname_len; /* Followed by ai_addr amd ai_canonname with variable lengths */ } AddrInfoSerialization; typedef struct NameInfoRequest { struct RHeader header; int flags; socklen_t sockaddr_len; bool gethost:1, getserv:1; } NameInfoRequest; typedef struct NameInfoResponse { struct RHeader header; size_t hostlen, servlen; int ret; int _errno; int _h_errno; } NameInfoResponse; typedef union Packet { RHeader rheader; AddrInfoRequest addrinfo_request; AddrInfoResponse addrinfo_response; NameInfoRequest nameinfo_request; NameInfoResponse nameinfo_response; } Packet; static int getaddrinfo_done(sd_resolve_query* q); static int getnameinfo_done(sd_resolve_query *q); static void resolve_query_disconnect(sd_resolve_query *q); #define RESOLVE_DONT_DESTROY(resolve) \ _cleanup_(sd_resolve_unrefp) _unused_ sd_resolve *_dont_destroy_##resolve = sd_resolve_ref(resolve) static void query_assign_errno(sd_resolve_query *q, int ret, int error, int h_error) { assert(q); q->ret = ret; q->_errno = abs(error); q->_h_errno = h_error; } static int send_died(int out_fd) { RHeader rh = { .type = RESPONSE_DIED, .length = sizeof(RHeader), }; assert(out_fd >= 0); if (send(out_fd, &rh, rh.length, MSG_NOSIGNAL) < 0) return -errno; return 0; } static void *serialize_addrinfo(void *p, const struct addrinfo *ai, size_t *length, size_t maxlength) { AddrInfoSerialization s; size_t cnl, l; assert(p); assert(ai); assert(length); assert(*length <= maxlength); cnl = ai->ai_canonname ? strlen(ai->ai_canonname)+1 : 0; l = sizeof(AddrInfoSerialization) + ai->ai_addrlen + cnl; if (*length + l > maxlength) return NULL; s = (AddrInfoSerialization) { .ai_flags = ai->ai_flags, .ai_family = ai->ai_family, .ai_socktype = ai->ai_socktype, .ai_protocol = ai->ai_protocol, .ai_addrlen = ai->ai_addrlen, .canonname_len = cnl, }; memcpy((uint8_t*) p, &s, sizeof(AddrInfoSerialization)); memcpy((uint8_t*) p + sizeof(AddrInfoSerialization), ai->ai_addr, ai->ai_addrlen); memcpy_safe((char*) p + sizeof(AddrInfoSerialization) + ai->ai_addrlen, ai->ai_canonname, cnl); *length += l; return (uint8_t*) p + l; } static int send_addrinfo_reply( int out_fd, unsigned id, int ret, struct addrinfo *ai, int _errno, int _h_errno) { AddrInfoResponse resp = {}; union { AddrInfoSerialization ais; uint8_t space[BUFSIZE]; } buffer; struct iovec iov[2]; struct msghdr mh; assert(out_fd >= 0); resp = (AddrInfoResponse) { .header.type = RESPONSE_ADDRINFO, .header.id = id, .header.length = sizeof(AddrInfoResponse), .ret = ret, ._errno = _errno, ._h_errno = _h_errno, }; if (ret == 0 && ai) { void *p = &buffer; struct addrinfo *k; for (k = ai; k; k = k->ai_next) { p = serialize_addrinfo(p, k, &resp.header.length, (uint8_t*) &buffer + BUFSIZE - (uint8_t*) p); if (!p) { freeaddrinfo(ai); return -ENOBUFS; } } } if (ai) freeaddrinfo(ai); iov[0] = IOVEC_MAKE(&resp, sizeof(AddrInfoResponse)); iov[1] = IOVEC_MAKE(&buffer, resp.header.length - sizeof(AddrInfoResponse)); mh = (struct msghdr) { .msg_iov = iov, .msg_iovlen = ELEMENTSOF(iov) }; if (sendmsg(out_fd, &mh, MSG_NOSIGNAL) < 0) return -errno; return 0; } static int send_nameinfo_reply( int out_fd, unsigned id, int ret, const char *host, const char *serv, int _errno, int _h_errno) { NameInfoResponse resp = {}; struct iovec iov[3]; struct msghdr mh; size_t hl, sl; assert(out_fd >= 0); sl = serv ? strlen(serv)+1 : 0; hl = host ? strlen(host)+1 : 0; resp = (NameInfoResponse) { .header.type = RESPONSE_NAMEINFO, .header.id = id, .header.length = sizeof(NameInfoResponse) + hl + sl, .hostlen = hl, .servlen = sl, .ret = ret, ._errno = _errno, ._h_errno = _h_errno, }; iov[0] = IOVEC_MAKE(&resp, sizeof(NameInfoResponse)); iov[1] = IOVEC_MAKE((void*) host, hl); iov[2] = IOVEC_MAKE((void*) serv, sl); mh = (struct msghdr) { .msg_iov = iov, .msg_iovlen = ELEMENTSOF(iov) }; if (sendmsg(out_fd, &mh, MSG_NOSIGNAL) < 0) return -errno; return 0; } static int handle_request(int out_fd, const Packet *packet, size_t length) { const RHeader *req; assert(out_fd >= 0); assert(packet); req = &packet->rheader; assert_return(length >= sizeof(RHeader), -EIO); assert_return(length == req->length, -EIO); switch (req->type) { case REQUEST_ADDRINFO: { const AddrInfoRequest *ai_req = &packet->addrinfo_request; struct addrinfo hints, *result = NULL; const char *node, *service; int ret; assert_return(length >= sizeof(AddrInfoRequest), -EBADMSG); assert_return(length == sizeof(AddrInfoRequest) + ai_req->node_len + ai_req->service_len, -EBADMSG); hints = (struct addrinfo) { .ai_flags = ai_req->ai_flags, .ai_family = ai_req->ai_family, .ai_socktype = ai_req->ai_socktype, .ai_protocol = ai_req->ai_protocol, }; node = ai_req->node_len ? (const char*) ai_req + sizeof(AddrInfoRequest) : NULL; service = ai_req->service_len ? (const char*) ai_req + sizeof(AddrInfoRequest) + ai_req->node_len : NULL; ret = getaddrinfo(node, service, ai_req->hints_valid ? &hints : NULL, &result); /* send_addrinfo_reply() frees result */ return send_addrinfo_reply(out_fd, req->id, ret, result, errno, h_errno); } case REQUEST_NAMEINFO: { const NameInfoRequest *ni_req = &packet->nameinfo_request; char hostbuf[NI_MAXHOST], servbuf[NI_MAXSERV]; union sockaddr_union sa; int ret; assert_return(length >= sizeof(NameInfoRequest), -EBADMSG); assert_return(length == sizeof(NameInfoRequest) + ni_req->sockaddr_len, -EBADMSG); assert_return(ni_req->sockaddr_len <= sizeof(sa), -EBADMSG); memcpy(&sa, (const uint8_t *) ni_req + sizeof(NameInfoRequest), ni_req->sockaddr_len); ret = getnameinfo(&sa.sa, ni_req->sockaddr_len, ni_req->gethost ? hostbuf : NULL, ni_req->gethost ? sizeof(hostbuf) : 0, ni_req->getserv ? servbuf : NULL, ni_req->getserv ? sizeof(servbuf) : 0, ni_req->flags); return send_nameinfo_reply(out_fd, req->id, ret, ret == 0 && ni_req->gethost ? hostbuf : NULL, ret == 0 && ni_req->getserv ? servbuf : NULL, errno, h_errno); } case REQUEST_TERMINATE: /* Quit */ return -ECONNRESET; default: assert_not_reached("Unknown request"); } return 0; } static void* thread_worker(void *p) { sd_resolve *resolve = p; /* Assign a pretty name to this thread */ (void) pthread_setname_np(pthread_self(), "sd-resolve"); while (!resolve->dead) { union { Packet packet; uint8_t space[BUFSIZE]; } buf; ssize_t length; length = recv(resolve->fds[REQUEST_RECV_FD], &buf, sizeof buf, 0); if (length < 0) { if (errno == EINTR) continue; break; } if (length == 0) break; if (handle_request(resolve->fds[RESPONSE_SEND_FD], &buf.packet, (size_t) length) < 0) break; } send_died(resolve->fds[RESPONSE_SEND_FD]); return NULL; } static int start_threads(sd_resolve *resolve, unsigned extra) { sigset_t ss, saved_ss; unsigned n; int r, k; if (sigfillset(&ss) < 0) return -errno; /* No signals in forked off threads please. We set the mask before forking, so that the threads never exist * with a different mask than a fully blocked one */ r = pthread_sigmask(SIG_BLOCK, &ss, &saved_ss); if (r > 0) return -r; n = resolve->n_outstanding + extra; n = CLAMP(n, WORKERS_MIN, WORKERS_MAX); while (resolve->n_valid_workers < n) { r = pthread_create(&resolve->workers[resolve->n_valid_workers], NULL, thread_worker, resolve); if (r > 0) { r = -r; goto finish; } resolve->n_valid_workers++; } r = 0; finish: k = pthread_sigmask(SIG_SETMASK, &saved_ss, NULL); if (k > 0 && r >= 0) r = -k; return r; } static bool resolve_pid_changed(sd_resolve *r) { assert(r); /* We don't support people creating a resolver and keeping it * around after fork(). Let's complain. */ return r->original_pid != getpid_cached(); } _public_ int sd_resolve_new(sd_resolve **ret) { _cleanup_(sd_resolve_unrefp) sd_resolve *resolve = NULL; int i; assert_return(ret, -EINVAL); resolve = new0(sd_resolve, 1); if (!resolve) return -ENOMEM; resolve->n_ref = 1; resolve->original_pid = getpid_cached(); for (i = 0; i < _FD_MAX; i++) resolve->fds[i] = -1; if (socketpair(PF_UNIX, SOCK_DGRAM|SOCK_CLOEXEC, 0, resolve->fds + REQUEST_RECV_FD) < 0) return -errno; if (socketpair(PF_UNIX, SOCK_DGRAM|SOCK_CLOEXEC, 0, resolve->fds + RESPONSE_RECV_FD) < 0) return -errno; for (i = 0; i < _FD_MAX; i++) resolve->fds[i] = fd_move_above_stdio(resolve->fds[i]); (void) fd_inc_sndbuf(resolve->fds[REQUEST_SEND_FD], QUERIES_MAX * BUFSIZE); (void) fd_inc_rcvbuf(resolve->fds[REQUEST_RECV_FD], QUERIES_MAX * BUFSIZE); (void) fd_inc_sndbuf(resolve->fds[RESPONSE_SEND_FD], QUERIES_MAX * BUFSIZE); (void) fd_inc_rcvbuf(resolve->fds[RESPONSE_RECV_FD], QUERIES_MAX * BUFSIZE); (void) fd_nonblock(resolve->fds[RESPONSE_RECV_FD], true); *ret = TAKE_PTR(resolve); return 0; } _public_ int sd_resolve_default(sd_resolve **ret) { static thread_local sd_resolve *default_resolve = NULL; sd_resolve *e = NULL; int r; if (!ret) return !!default_resolve; if (default_resolve) { *ret = sd_resolve_ref(default_resolve); return 0; } r = sd_resolve_new(&e); if (r < 0) return r; e->default_resolve_ptr = &default_resolve; e->tid = gettid(); default_resolve = e; *ret = e; return 1; } _public_ int sd_resolve_get_tid(sd_resolve *resolve, pid_t *tid) { assert_return(resolve, -EINVAL); assert_return(tid, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); if (resolve->tid != 0) { *tid = resolve->tid; return 0; } if (resolve->event) return sd_event_get_tid(resolve->event, tid); return -ENXIO; } static sd_resolve *resolve_free(sd_resolve *resolve) { PROTECT_ERRNO; sd_resolve_query *q; unsigned i; assert(resolve); while ((q = resolve->queries)) { assert(q->floating); resolve_query_disconnect(q); sd_resolve_query_unref(q); } if (resolve->default_resolve_ptr) *(resolve->default_resolve_ptr) = NULL; resolve->dead = true; sd_resolve_detach_event(resolve); if (resolve->fds[REQUEST_SEND_FD] >= 0) { RHeader req = { .type = REQUEST_TERMINATE, .length = sizeof req, }; /* Send one termination packet for each worker */ for (i = 0; i < resolve->n_valid_workers; i++) (void) send(resolve->fds[REQUEST_SEND_FD], &req, req.length, MSG_NOSIGNAL); } /* Now terminate them and wait until they are gone. If we get an error than most likely the thread already exited. */ for (i = 0; i < resolve->n_valid_workers; i++) (void) pthread_join(resolve->workers[i], NULL); /* Close all communication channels */ close_many(resolve->fds, _FD_MAX); return mfree(resolve); } DEFINE_PUBLIC_TRIVIAL_REF_UNREF_FUNC(sd_resolve, sd_resolve, resolve_free); _public_ int sd_resolve_get_fd(sd_resolve *resolve) { assert_return(resolve, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); return resolve->fds[RESPONSE_RECV_FD]; } _public_ int sd_resolve_get_events(sd_resolve *resolve) { assert_return(resolve, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); return resolve->n_queries > resolve->n_done ? POLLIN : 0; } _public_ int sd_resolve_get_timeout(sd_resolve *resolve, uint64_t *usec) { assert_return(resolve, -EINVAL); assert_return(usec, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); *usec = (uint64_t) -1; return 0; } static sd_resolve_query *lookup_query(sd_resolve *resolve, unsigned id) { sd_resolve_query *q; assert(resolve); q = resolve->query_array[id % QUERIES_MAX]; if (q) if (q->id == id) return q; return NULL; } static int complete_query(sd_resolve *resolve, sd_resolve_query *q) { int r; assert(q); assert(!q->done); assert(q->resolve == resolve); q->done = true; resolve->n_done++; resolve->current = sd_resolve_query_ref(q); switch (q->type) { case REQUEST_ADDRINFO: r = getaddrinfo_done(q); break; case REQUEST_NAMEINFO: r = getnameinfo_done(q); break; default: assert_not_reached("Cannot complete unknown query type"); } resolve->current = NULL; if (q->floating) { resolve_query_disconnect(q); sd_resolve_query_unref(q); } sd_resolve_query_unref(q); return r; } static int unserialize_addrinfo(const void **p, size_t *length, struct addrinfo **ret_ai) { AddrInfoSerialization s; struct addrinfo *ai; size_t l; assert(p); assert(*p); assert(ret_ai); assert(length); if (*length < sizeof(AddrInfoSerialization)) return -EBADMSG; memcpy(&s, *p, sizeof(s)); l = sizeof(AddrInfoSerialization) + s.ai_addrlen + s.canonname_len; if (*length < l) return -EBADMSG; ai = new(struct addrinfo, 1); if (!ai) return -ENOMEM; *ai = (struct addrinfo) { .ai_flags = s.ai_flags, .ai_family = s.ai_family, .ai_socktype = s.ai_socktype, .ai_protocol = s.ai_protocol, .ai_addrlen = s.ai_addrlen, }; if (s.ai_addrlen > 0) { ai->ai_addr = memdup((const uint8_t*) *p + sizeof(AddrInfoSerialization), s.ai_addrlen); if (!ai->ai_addr) { free(ai); return -ENOMEM; } } if (s.canonname_len > 0) { ai->ai_canonname = memdup((const uint8_t*) *p + sizeof(AddrInfoSerialization) + s.ai_addrlen, s.canonname_len); if (!ai->ai_canonname) { free(ai->ai_addr); free(ai); return -ENOMEM; } } *length -= l; *ret_ai = ai; *p = ((const uint8_t*) *p) + l; return 0; } static int handle_response(sd_resolve *resolve, const Packet *packet, size_t length) { const RHeader *resp; sd_resolve_query *q; int r; assert(resolve); assert(packet); resp = &packet->rheader; assert_return(length >= sizeof(RHeader), -EIO); assert_return(length == resp->length, -EIO); if (resp->type == RESPONSE_DIED) { resolve->dead = true; return 0; } assert(resolve->n_outstanding > 0); resolve->n_outstanding--; q = lookup_query(resolve, resp->id); if (!q) return 0; switch (resp->type) { case RESPONSE_ADDRINFO: { const AddrInfoResponse *ai_resp = &packet->addrinfo_response; const void *p; size_t l; struct addrinfo *prev = NULL; assert_return(length >= sizeof(AddrInfoResponse), -EBADMSG); assert_return(q->type == REQUEST_ADDRINFO, -EBADMSG); query_assign_errno(q, ai_resp->ret, ai_resp->_errno, ai_resp->_h_errno); l = length - sizeof(AddrInfoResponse); p = (const uint8_t*) resp + sizeof(AddrInfoResponse); while (l > 0 && p) { struct addrinfo *ai = NULL; r = unserialize_addrinfo(&p, &l, &ai); if (r < 0) { query_assign_errno(q, EAI_SYSTEM, r, 0); freeaddrinfo(q->addrinfo); q->addrinfo = NULL; break; } if (prev) prev->ai_next = ai; else q->addrinfo = ai; prev = ai; } return complete_query(resolve, q); } case RESPONSE_NAMEINFO: { const NameInfoResponse *ni_resp = &packet->nameinfo_response; assert_return(length >= sizeof(NameInfoResponse), -EBADMSG); assert_return(q->type == REQUEST_NAMEINFO, -EBADMSG); if (ni_resp->hostlen > DNS_HOSTNAME_MAX || ni_resp->servlen > DNS_HOSTNAME_MAX || sizeof(NameInfoResponse) + ni_resp->hostlen + ni_resp->servlen > length) query_assign_errno(q, EAI_SYSTEM, EIO, 0); else { query_assign_errno(q, ni_resp->ret, ni_resp->_errno, ni_resp->_h_errno); if (ni_resp->hostlen > 0) { q->host = strndup((const char*) ni_resp + sizeof(NameInfoResponse), ni_resp->hostlen-1); if (!q->host) query_assign_errno(q, EAI_MEMORY, ENOMEM, 0); } if (ni_resp->servlen > 0) { q->serv = strndup((const char*) ni_resp + sizeof(NameInfoResponse) + ni_resp->hostlen, ni_resp->servlen-1); if (!q->serv) query_assign_errno(q, EAI_MEMORY, ENOMEM, 0); } } return complete_query(resolve, q); } default: return 0; } } _public_ int sd_resolve_process(sd_resolve *resolve) { RESOLVE_DONT_DESTROY(resolve); union { Packet packet; uint8_t space[BUFSIZE]; } buf; ssize_t l; int r; assert_return(resolve, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); /* We don't allow recursively invoking sd_resolve_process(). */ assert_return(!resolve->current, -EBUSY); l = recv(resolve->fds[RESPONSE_RECV_FD], &buf, sizeof buf, 0); if (l < 0) { if (errno == EAGAIN) return 0; return -errno; } if (l == 0) return -ECONNREFUSED; r = handle_response(resolve, &buf.packet, (size_t) l); if (r < 0) return r; return 1; } _public_ int sd_resolve_wait(sd_resolve *resolve, uint64_t timeout_usec) { int r; assert_return(resolve, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); if (resolve->n_done >= resolve->n_queries) return 0; do { r = fd_wait_for_event(resolve->fds[RESPONSE_RECV_FD], POLLIN, timeout_usec); } while (r == -EINTR); if (r < 0) return r; if (r == 0) return -ETIMEDOUT; return sd_resolve_process(resolve); } static int alloc_query(sd_resolve *resolve, bool floating, sd_resolve_query **_q) { sd_resolve_query *q; int r; assert(resolve); assert(_q); if (resolve->n_queries >= QUERIES_MAX) return -ENOBUFS; r = start_threads(resolve, 1); if (r < 0) return r; while (resolve->query_array[resolve->current_id % QUERIES_MAX]) resolve->current_id++; q = resolve->query_array[resolve->current_id % QUERIES_MAX] = new0(sd_resolve_query, 1); if (!q) return -ENOMEM; q->n_ref = 1; q->resolve = resolve; q->floating = floating; q->id = resolve->current_id++; if (!floating) sd_resolve_ref(resolve); LIST_PREPEND(queries, resolve->queries, q); resolve->n_queries++; *_q = q; return 0; } _public_ int sd_resolve_getaddrinfo( sd_resolve *resolve, sd_resolve_query **_q, const char *node, const char *service, const struct addrinfo *hints, sd_resolve_getaddrinfo_handler_t callback, void *userdata) { _cleanup_(sd_resolve_query_unrefp) sd_resolve_query *q = NULL; AddrInfoRequest req = {}; struct iovec iov[3]; struct msghdr mh = {}; int r; size_t node_len, service_len; assert_return(resolve, -EINVAL); assert_return(node || service, -EINVAL); assert_return(callback, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); r = alloc_query(resolve, !_q, &q); if (r < 0) return r; q->type = REQUEST_ADDRINFO; q->getaddrinfo_handler = callback; q->userdata = userdata; node_len = node ? strlen(node) + 1 : 0; service_len = service ? strlen(service) + 1 : 0; req = (AddrInfoRequest) { .node_len = node_len, .service_len = service_len, .header.id = q->id, .header.type = REQUEST_ADDRINFO, .header.length = sizeof(AddrInfoRequest) + node_len + service_len, .hints_valid = hints, .ai_flags = hints ? hints->ai_flags : 0, .ai_family = hints ? hints->ai_family : 0, .ai_socktype = hints ? hints->ai_socktype : 0, .ai_protocol = hints ? hints->ai_protocol : 0, }; iov[mh.msg_iovlen++] = IOVEC_MAKE(&req, sizeof(AddrInfoRequest)); if (node) iov[mh.msg_iovlen++] = IOVEC_MAKE((void*) node, req.node_len); if (service) iov[mh.msg_iovlen++] = IOVEC_MAKE((void*) service, req.service_len); mh.msg_iov = iov; if (sendmsg(resolve->fds[REQUEST_SEND_FD], &mh, MSG_NOSIGNAL) < 0) return -errno; resolve->n_outstanding++; if (_q) *_q = q; TAKE_PTR(q); return 0; } static int getaddrinfo_done(sd_resolve_query* q) { assert(q); assert(q->done); assert(q->getaddrinfo_handler); errno = q->_errno; h_errno = q->_h_errno; return q->getaddrinfo_handler(q, q->ret, q->addrinfo, q->userdata); } _public_ int sd_resolve_getnameinfo( sd_resolve *resolve, sd_resolve_query**_q, const struct sockaddr *sa, socklen_t salen, int flags, uint64_t get, sd_resolve_getnameinfo_handler_t callback, void *userdata) { _cleanup_(sd_resolve_query_unrefp) sd_resolve_query *q = NULL; NameInfoRequest req = {}; struct iovec iov[2]; struct msghdr mh; int r; assert_return(resolve, -EINVAL); assert_return(sa, -EINVAL); assert_return(salen >= sizeof(struct sockaddr), -EINVAL); assert_return(salen <= sizeof(union sockaddr_union), -EINVAL); assert_return((get & ~SD_RESOLVE_GET_BOTH) == 0, -EINVAL); assert_return(callback, -EINVAL); assert_return(!resolve_pid_changed(resolve), -ECHILD); r = alloc_query(resolve, !_q, &q); if (r < 0) return r; q->type = REQUEST_NAMEINFO; q->getnameinfo_handler = callback; q->userdata = userdata; req = (NameInfoRequest) { .header.id = q->id, .header.type = REQUEST_NAMEINFO, .header.length = sizeof(NameInfoRequest) + salen, .flags = flags, .sockaddr_len = salen, .gethost = !!(get & SD_RESOLVE_GET_HOST), .getserv = !!(get & SD_RESOLVE_GET_SERVICE), }; iov[0] = IOVEC_MAKE(&req, sizeof(NameInfoRequest)); iov[1] = IOVEC_MAKE((void*) sa, salen); mh = (struct msghdr) { .msg_iov = iov, .msg_iovlen = ELEMENTSOF(iov) }; if (sendmsg(resolve->fds[REQUEST_SEND_FD], &mh, MSG_NOSIGNAL) < 0) return -errno; if (_q) *_q = q; resolve->n_outstanding++; TAKE_PTR(q); return 0; } static int getnameinfo_done(sd_resolve_query *q) { assert(q); assert(q->done); assert(q->getnameinfo_handler); errno = q->_errno; h_errno = q->_h_errno; return q->getnameinfo_handler(q, q->ret, q->host, q->serv, q->userdata); } static void resolve_freeaddrinfo(struct addrinfo *ai) { while (ai) { struct addrinfo *next = ai->ai_next; free(ai->ai_addr); free(ai->ai_canonname); free(ai); ai = next; } } static void resolve_query_disconnect(sd_resolve_query *q) { sd_resolve *resolve; unsigned i; assert(q); if (!q->resolve) return; resolve = q->resolve; assert(resolve->n_queries > 0); if (q->done) { assert(resolve->n_done > 0); resolve->n_done--; } i = q->id % QUERIES_MAX; assert(resolve->query_array[i] == q); resolve->query_array[i] = NULL; LIST_REMOVE(queries, resolve->queries, q); resolve->n_queries--; q->resolve = NULL; if (!q->floating) sd_resolve_unref(resolve); } static sd_resolve_query *resolve_query_free(sd_resolve_query *q) { assert(q); resolve_query_disconnect(q); if (q->destroy_callback) q->destroy_callback(q->userdata); resolve_freeaddrinfo(q->addrinfo); free(q->host); free(q->serv); return mfree(q); } DEFINE_PUBLIC_TRIVIAL_REF_UNREF_FUNC(sd_resolve_query, sd_resolve_query, resolve_query_free); _public_ int sd_resolve_query_is_done(sd_resolve_query *q) { assert_return(q, -EINVAL); assert_return(!resolve_pid_changed(q->resolve), -ECHILD); return q->done; } _public_ void* sd_resolve_query_set_userdata(sd_resolve_query *q, void *userdata) { void *ret; assert_return(q, NULL); assert_return(!resolve_pid_changed(q->resolve), NULL); ret = q->userdata; q->userdata = userdata; return ret; } _public_ void* sd_resolve_query_get_userdata(sd_resolve_query *q) { assert_return(q, NULL); assert_return(!resolve_pid_changed(q->resolve), NULL); return q->userdata; } _public_ sd_resolve *sd_resolve_query_get_resolve(sd_resolve_query *q) { assert_return(q, NULL); assert_return(!resolve_pid_changed(q->resolve), NULL); return q->resolve; } _public_ int sd_resolve_query_get_destroy_callback(sd_resolve_query *q, sd_resolve_destroy_t *destroy_callback) { assert_return(q, -EINVAL); if (destroy_callback) *destroy_callback = q->destroy_callback; return !!q->destroy_callback; } _public_ int sd_resolve_query_set_destroy_callback(sd_resolve_query *q, sd_resolve_destroy_t destroy_callback) { assert_return(q, -EINVAL); q->destroy_callback = destroy_callback; return 0; } _public_ int sd_resolve_query_get_floating(sd_resolve_query *q) { assert_return(q, -EINVAL); return q->floating; } _public_ int sd_resolve_query_set_floating(sd_resolve_query *q, int b) { assert_return(q, -EINVAL); if (q->floating == !!b) return 0; if (!q->resolve) /* Already disconnected */ return -ESTALE; q->floating = b; if (b) { sd_resolve_query_ref(q); sd_resolve_unref(q->resolve); } else { sd_resolve_ref(q->resolve); sd_resolve_query_unref(q); } return 1; } static int io_callback(sd_event_source *s, int fd, uint32_t revents, void *userdata) { sd_resolve *resolve = userdata; int r; assert(resolve); r = sd_resolve_process(resolve); if (r < 0) return r; return 1; } _public_ int sd_resolve_attach_event(sd_resolve *resolve, sd_event *event, int64_t priority) { int r; assert_return(resolve, -EINVAL); assert_return(!resolve->event, -EBUSY); assert(!resolve->event_source); if (event) resolve->event = sd_event_ref(event); else { r = sd_event_default(&resolve->event); if (r < 0) return r; } r = sd_event_add_io(resolve->event, &resolve->event_source, resolve->fds[RESPONSE_RECV_FD], POLLIN, io_callback, resolve); if (r < 0) goto fail; r = sd_event_source_set_priority(resolve->event_source, priority); if (r < 0) goto fail; return 0; fail: sd_resolve_detach_event(resolve); return r; } _public_ int sd_resolve_detach_event(sd_resolve *resolve) { assert_return(resolve, -EINVAL); if (!resolve->event) return 0; if (resolve->event_source) { sd_event_source_set_enabled(resolve->event_source, SD_EVENT_OFF); resolve->event_source = sd_event_source_unref(resolve->event_source); } resolve->event = sd_event_unref(resolve->event); return 1; } _public_ sd_event *sd_resolve_get_event(sd_resolve *resolve) { assert_return(resolve, NULL); return resolve->event; }