/*-*- Mode: C; c-basic-offset: 8 -*-*/ /*** This file is part of systemd. Copyright 2010 Lennart Poettering systemd is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. systemd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with systemd; If not, see . ***/ #include #include #include #include #include #include #include #include #include "unit.h" #include "strv.h" #include "conf-parser.h" #include "load-fragment.h" #include "log.h" #include "ioprio.h" #include "securebits.h" #include "missing.h" static int config_parse_deps( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { UnitDependency d = PTR_TO_UINT(data); Unit *u = userdata; char *w; size_t l; char *state; assert(filename); assert(lvalue); assert(rvalue); FOREACH_WORD(w, l, rvalue, state) { char *t; int r; if (!(t = strndup(w, l))) return -ENOMEM; r = unit_add_dependency_by_name(u, d, t); free(t); if (r < 0) return r; } return 0; } static int config_parse_names( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { Unit *u = userdata; char *w; size_t l; char *state; assert(filename); assert(lvalue); assert(rvalue); assert(data); FOREACH_WORD(w, l, rvalue, state) { char *t; int r; Unit *other; if (!(t = strndup(w, l))) return -ENOMEM; other = manager_get_unit(u->meta.manager, t); if (other) { if (other != u) { if (other->meta.load_state != UNIT_STUB) { free(t); return -EEXIST; } if ((r = unit_merge(u, other)) < 0) { free(t); return r; } } } else { if ((r = unit_add_name(u, t)) < 0) { free(t); return r; } } free(t); } return 0; } static int config_parse_listen( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { int r; SocketPort *p; Socket *s; assert(filename); assert(lvalue); assert(rvalue); assert(data); s = (Socket*) data; if (!(p = new0(SocketPort, 1))) return -ENOMEM; if (streq(lvalue, "ListenFIFO")) { p->type = SOCKET_FIFO; if (!(p->path = strdup(rvalue))) { free(p); return -ENOMEM; } } else { p->type = SOCKET_SOCKET; if ((r = socket_address_parse(&p->address, rvalue)) < 0) { log_error("[%s:%u] Failed to parse address value: %s", filename, line, rvalue); free(p); return r; } if (streq(lvalue, "ListenStream")) p->address.type = SOCK_STREAM; else if (streq(lvalue, "ListenDatagram")) p->address.type = SOCK_DGRAM; else { assert(streq(lvalue, "ListenSequentialPacket")); p->address.type = SOCK_SEQPACKET; } if (socket_address_family(&p->address) != AF_LOCAL && p->address.type == SOCK_SEQPACKET) { free(p); return -EPROTONOSUPPORT; } } p->fd = -1; LIST_PREPEND(SocketPort, port, s->ports, p); return 0; } static int config_parse_socket_bind( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { int r; Socket *s; assert(filename); assert(lvalue); assert(rvalue); assert(data); s = (Socket*) data; if ((r = parse_boolean(rvalue)) < 0) { log_error("[%s:%u] Failed to parse bind IPv6 only value: %s", filename, line, rvalue); return r; } s->bind_ipv6_only = r ? SOCKET_ADDRESS_IPV6_ONLY : SOCKET_ADDRESS_BOTH; return 0; } static int config_parse_nice( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; int priority, r; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((r = safe_atoi(rvalue, &priority)) < 0) { log_error("[%s:%u] Failed to parse nice priority: %s", filename, line, rvalue); return r; } if (priority < PRIO_MIN || priority >= PRIO_MAX) { log_error("[%s:%u] Nice priority out of range: %s", filename, line, rvalue); return -ERANGE; } c->nice = priority; c->nice_set = false; return 0; } static int config_parse_oom_adjust( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; int oa, r; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((r = safe_atoi(rvalue, &oa)) < 0) { log_error("[%s:%u] Failed to parse OOM adjust value: %s", filename, line, rvalue); return r; } if (oa < OOM_DISABLE || oa > OOM_ADJUST_MAX) { log_error("[%s:%u] OOM adjust value out of range: %s", filename, line, rvalue); return -ERANGE; } c->oom_adjust = oa; c->oom_adjust_set = true; return 0; } static int config_parse_mode( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { mode_t *m = data; long l; char *x = NULL; assert(filename); assert(lvalue); assert(rvalue); assert(data); errno = 0; l = strtol(rvalue, &x, 8); if (!x || *x || errno) { log_error("[%s:%u] Failed to parse mode value: %s", filename, line, rvalue); return errno ? -errno : -EINVAL; } if (l < 0000 || l > 07777) { log_error("[%s:%u] mode value out of range: %s", filename, line, rvalue); return -ERANGE; } *m = (mode_t) l; return 0; } static int config_parse_exec( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecCommand **e = data, *nce = NULL; char **n; char *w; unsigned k; size_t l; char *state; assert(filename); assert(lvalue); assert(rvalue); assert(data); k = 0; FOREACH_WORD_QUOTED(w, l, rvalue, state) k++; if (!(n = new(char*, k+1))) return -ENOMEM; k = 0; FOREACH_WORD_QUOTED(w, l, rvalue, state) if (!(n[k++] = strndup(w, l))) goto fail; n[k] = NULL; if (!n[0] || !path_is_absolute(n[0])) { log_error("[%s:%u] Invalid executable path in command line: %s", filename, line, rvalue); strv_free(n); return -EINVAL; } if (!(nce = new0(ExecCommand, 1))) goto fail; nce->argv = n; if (!(nce->path = strdup(n[0]))) goto fail; exec_command_append_list(e, nce); return 0; fail: for (; k > 0; k--) free(n[k-1]); free(n); free(nce); return -ENOMEM; } static int config_parse_usec( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { usec_t *usec = data; unsigned long long u; int r; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((r = safe_atollu(rvalue, &u)) < 0) { log_error("[%s:%u] Failed to parse time value: %s", filename, line, rvalue); return r; } /* We actually assume the user configures seconds. Later on we * might choose to support suffixes for time values, to * configure bigger or smaller units */ *usec = u * USEC_PER_SEC; return 0; } static int config_parse_service_type( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { Service *s = data; ServiceType x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = service_type_from_string(rvalue)) < 0) { log_error("[%s:%u] Failed to parse service type: %s", filename, line, rvalue); return -EBADMSG; } s->type = x; return 0; } static int config_parse_service_restart( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { Service *s = data; ServiceRestart x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = service_restart_from_string(rvalue)) < 0) { log_error("[%s:%u] Failed to parse service restart specifier: %s", filename, line, rvalue); return -EBADMSG; } s->restart = x; return 0; } static int config_parse_bindtodevice( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { Socket *s = data; char *n; assert(filename); assert(lvalue); assert(rvalue); assert(data); if (rvalue[0] && !streq(rvalue, "*")) { if (!(n = strdup(rvalue))) return -ENOMEM; } else n = NULL; free(s->bind_to_device); s->bind_to_device = n; return 0; } static int config_parse_output( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecOutput *o = data, x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = exec_output_from_string(rvalue)) < 0) { log_error("[%s:%u] Failed to parse output specifier: %s", filename, line, rvalue); return -EBADMSG; } *o = x; return 0; } static int config_parse_input( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecInput *i = data, x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = exec_input_from_string(rvalue)) < 0) { log_error("[%s:%u] Failed to parse input specifier: %s", filename, line, rvalue); return -EBADMSG; } *i = x; return 0; } static int config_parse_facility( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { int *o = data, x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = log_facility_from_string(rvalue)) < 0) /* Second try, let's see if this is a number. */ if (safe_atoi(rvalue, &x) < 0 || !log_facility_to_string(x)) { log_error("[%s:%u] Failed to parse log facility: %s", filename, line, rvalue); return -EBADMSG; } *o = LOG_MAKEPRI(x, LOG_PRI(*o)); return 0; } static int config_parse_level( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { int *o = data, x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = log_level_from_string(rvalue)) < 0) /* Second try, let's see if this is a number. */ if (safe_atoi(rvalue, &x) < 0 || !log_level_to_string(x)) { log_error("[%s:%u] Failed to parse log level: %s", filename, line, rvalue); return -EBADMSG; } *o = LOG_MAKEPRI(LOG_FAC(*o), x); return 0; } static int config_parse_io_class( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; int x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = ioprio_class_from_string(rvalue)) < 0) /* Second try, let's see if this is a number. */ if (safe_atoi(rvalue, &x) < 0 || !ioprio_class_to_string(x)) { log_error("[%s:%u] Failed to parse IO scheduling class: %s", filename, line, rvalue); return -EBADMSG; } c->ioprio = IOPRIO_PRIO_VALUE(x, IOPRIO_PRIO_DATA(c->ioprio)); c->ioprio_set = true; return 0; } static int config_parse_io_priority( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; int i; assert(filename); assert(lvalue); assert(rvalue); assert(data); if (safe_atoi(rvalue, &i) < 0 || i < 0 || i >= IOPRIO_BE_NR) { log_error("[%s:%u] Failed to parse io priority: %s", filename, line, rvalue); return -EBADMSG; } c->ioprio = IOPRIO_PRIO_VALUE(IOPRIO_PRIO_CLASS(c->ioprio), i); c->ioprio_set = true; return 0; } static int config_parse_cpu_sched_policy( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; int x; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((x = sched_policy_from_string(rvalue)) < 0) /* Second try, let's see if this is a number. */ if (safe_atoi(rvalue, &x) < 0 || !sched_policy_to_string(x)) { log_error("[%s:%u] Failed to parse CPU scheduling policy: %s", filename, line, rvalue); return -EBADMSG; } c->cpu_sched_policy = x; c->cpu_sched_set = true; return 0; } static int config_parse_cpu_sched_prio( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; int i; assert(filename); assert(lvalue); assert(rvalue); assert(data); /* On Linux RR/FIFO have the same range */ if (safe_atoi(rvalue, &i) < 0 || i < sched_get_priority_min(SCHED_RR) || i > sched_get_priority_max(SCHED_RR)) { log_error("[%s:%u] Failed to parse CPU scheduling priority: %s", filename, line, rvalue); return -EBADMSG; } c->cpu_sched_priority = i; c->cpu_sched_set = true; return 0; } static int config_parse_cpu_affinity( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; char *w; size_t l; char *state; assert(filename); assert(lvalue); assert(rvalue); assert(data); FOREACH_WORD(w, l, rvalue, state) { char *t; int r; unsigned cpu; if (!(t = strndup(w, l))) return -ENOMEM; r = safe_atou(t, &cpu); free(t); if (r < 0 || cpu >= CPU_SETSIZE) { log_error("[%s:%u] Failed to parse CPU affinity: %s", filename, line, rvalue); return -EBADMSG; } CPU_SET(cpu, &c->cpu_affinity); } c->cpu_affinity_set = true; return 0; } static int config_parse_capabilities( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; cap_t cap; assert(filename); assert(lvalue); assert(rvalue); assert(data); if (!(cap = cap_from_text(rvalue))) { if (errno == ENOMEM) return -ENOMEM; log_error("[%s:%u] Failed to parse capabilities: %s", filename, line, rvalue); return -EBADMSG; } if (c->capabilities) cap_free(c->capabilities); c->capabilities = cap; return 0; } static int config_parse_secure_bits( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; char *w; size_t l; char *state; assert(filename); assert(lvalue); assert(rvalue); assert(data); FOREACH_WORD(w, l, rvalue, state) { if (first_word(w, "keep-caps")) c->secure_bits |= SECURE_KEEP_CAPS; else if (first_word(w, "keep-caps-locked")) c->secure_bits |= SECURE_KEEP_CAPS_LOCKED; else if (first_word(w, "no-setuid-fixup")) c->secure_bits |= SECURE_NO_SETUID_FIXUP; else if (first_word(w, "no-setuid-fixup-locked")) c->secure_bits |= SECURE_NO_SETUID_FIXUP_LOCKED; else if (first_word(w, "noroot")) c->secure_bits |= SECURE_NOROOT; else if (first_word(w, "noroot-locked")) c->secure_bits |= SECURE_NOROOT_LOCKED; else { log_error("[%s:%u] Failed to parse secure bits: %s", filename, line, rvalue); return -EBADMSG; } } return 0; } static int config_parse_bounding_set( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; char *w; size_t l; char *state; assert(filename); assert(lvalue); assert(rvalue); assert(data); FOREACH_WORD(w, l, rvalue, state) { char *t; int r; cap_value_t cap; if (!(t = strndup(w, l))) return -ENOMEM; r = cap_from_name(t, &cap); free(t); if (r < 0) { log_error("[%s:%u] Failed to parse capability bounding set: %s", filename, line, rvalue); return -EBADMSG; } c->capability_bounding_set_drop |= 1 << cap; } return 0; } static int config_parse_timer_slack_ns( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { ExecContext *c = data; unsigned long u; int r; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((r = safe_atolu(rvalue, &u)) < 0) { log_error("[%s:%u] Failed to parse time slack value: %s", filename, line, rvalue); return r; } c->timer_slack_ns = u; return 0; } static int config_parse_limit( const char *filename, unsigned line, const char *section, const char *lvalue, const char *rvalue, void *data, void *userdata) { struct rlimit **rl = data; unsigned long long u; int r; assert(filename); assert(lvalue); assert(rvalue); assert(data); if ((r = safe_atollu(rvalue, &u)) < 0) { log_error("[%s:%u] Failed to parse resource value: %s", filename, line, rvalue); return r; } if (!*rl) if (!(*rl = new(struct rlimit, 1))) return -ENOMEM; (*rl)->rlim_cur = (*rl)->rlim_max = (rlim_t) u; return 0; } #define FOLLOW_MAX 8 static int open_follow(char **filename, FILE **_f, Set *names, char **_id) { unsigned c = 0; int fd, r; FILE *f; char *id = NULL; assert(filename); assert(*filename); assert(_f); assert(names); /* This will update the filename pointer if the loaded file is * reached by a symlink. The old string will be freed. */ for (;;) { char *target, *k, *name; if (c++ >= FOLLOW_MAX) return -ELOOP; path_kill_slashes(*filename); /* Add the file name we are currently looking at to * the names of this unit */ name = file_name_from_path(*filename); if (!(id = set_get(names, name))) { if (!(id = strdup(name))) return -ENOMEM; if ((r = set_put(names, id)) < 0) { free(id); return r; } } /* Try to open the file name, but don't if its a symlink */ if ((fd = open(*filename, O_RDONLY|O_CLOEXEC|O_NOCTTY|O_NOFOLLOW)) >= 0) break; if (errno != ELOOP) return -errno; /* Hmm, so this is a symlink. Let's read the name, and follow it manually */ if ((r = readlink_malloc(*filename, &target)) < 0) return r; k = file_in_same_dir(*filename, target); free(target); if (!k) return -ENOMEM; free(*filename); *filename = k; } if (!(f = fdopen(fd, "r"))) { r = -errno; assert(close_nointr(fd) == 0); return r; } *_f = f; *_id = id; return 0; } static int load_from_path(Unit *u, const char *path) { static const char* const section_table[_UNIT_TYPE_MAX] = { [UNIT_SERVICE] = "Service", [UNIT_TIMER] = "Timer", [UNIT_SOCKET] = "Socket", [UNIT_TARGET] = "Target", [UNIT_DEVICE] = "Device", [UNIT_MOUNT] = "Mount", [UNIT_AUTOMOUNT] = "Automount", [UNIT_SNAPSHOT] = "Snapshot" }; #define EXEC_CONTEXT_CONFIG_ITEMS(context, section) \ { "WorkingDirectory", config_parse_path, &(context).working_directory, section }, \ { "RootDirectory", config_parse_path, &(context).root_directory, section }, \ { "User", config_parse_string, &(context).user, section }, \ { "Group", config_parse_string, &(context).group, section }, \ { "SupplementaryGroups", config_parse_strv, &(context).supplementary_groups, section }, \ { "Nice", config_parse_nice, &(context), section }, \ { "OOMAdjust", config_parse_oom_adjust, &(context), section }, \ { "IOSchedulingClass", config_parse_io_class, &(context), section }, \ { "IOSchedulingPriority", config_parse_io_priority, &(context), section }, \ { "CPUSchedulingPolicy", config_parse_cpu_sched_policy,&(context), section }, \ { "CPUSchedulingPriority", config_parse_cpu_sched_prio, &(context), section }, \ { "CPUSchedulingResetOnFork", config_parse_bool, &(context).cpu_sched_reset_on_fork, section }, \ { "CPUAffinity", config_parse_cpu_affinity, &(context), section }, \ { "UMask", config_parse_mode, &(context).umask, section }, \ { "Environment", config_parse_strv, &(context).environment, section }, \ { "Output", config_parse_output, &(context).output, section }, \ { "Input", config_parse_input, &(context).input, section }, \ { "SyslogIdentifier", config_parse_string, &(context).syslog_identifier, section }, \ { "SyslogFacility", config_parse_facility, &(context).syslog_priority, section }, \ { "SyslogLevel", config_parse_level, &(context).syslog_priority, section }, \ { "Capabilities", config_parse_capabilities, &(context), section }, \ { "SecureBits", config_parse_secure_bits, &(context), section }, \ { "CapabilityBoundingSetDrop", config_parse_bounding_set, &(context), section }, \ { "TimerSlackNS", config_parse_timer_slack_ns, &(context), section }, \ { "LimitCPU", config_parse_limit, &(context).rlimit[RLIMIT_CPU], section }, \ { "LimitFSIZE", config_parse_limit, &(context).rlimit[RLIMIT_FSIZE], section }, \ { "LimitDATA", config_parse_limit, &(context).rlimit[RLIMIT_DATA], section }, \ { "LimitSTACK", config_parse_limit, &(context).rlimit[RLIMIT_STACK], section }, \ { "LimitCORE", config_parse_limit, &(context).rlimit[RLIMIT_CORE], section }, \ { "LimitRSS", config_parse_limit, &(context).rlimit[RLIMIT_RSS], section }, \ { "LimitNOFILE", config_parse_limit, &(context).rlimit[RLIMIT_NOFILE], section }, \ { "LimitAS", config_parse_limit, &(context).rlimit[RLIMIT_AS], section }, \ { "LimitNPROC", config_parse_limit, &(context).rlimit[RLIMIT_NPROC], section }, \ { "LimitMEMLOCK", config_parse_limit, &(context).rlimit[RLIMIT_MEMLOCK], section }, \ { "LimitLOCKS", config_parse_limit, &(context).rlimit[RLIMIT_LOCKS], section }, \ { "LimitSIGPENDING", config_parse_limit, &(context).rlimit[RLIMIT_SIGPENDING], section }, \ { "LimitMSGQUEUE", config_parse_limit, &(context).rlimit[RLIMIT_MSGQUEUE], section }, \ { "LimitNICE", config_parse_limit, &(context).rlimit[RLIMIT_NICE], section }, \ { "LimitRTPRIO", config_parse_limit, &(context).rlimit[RLIMIT_RTPRIO], section }, \ { "LimitRTTIME", config_parse_limit, &(context).rlimit[RLIMIT_RTTIME], section }, \ { "NonBlocking", config_parse_bool, &(context).non_blocking, section } const ConfigItem items[] = { { "Names", config_parse_names, u, "Meta" }, { "Description", config_parse_string, &u->meta.description, "Meta" }, { "Requires", config_parse_deps, UINT_TO_PTR(UNIT_REQUIRES), "Meta" }, { "SoftRequires", config_parse_deps, UINT_TO_PTR(UNIT_SOFT_REQUIRES), "Meta" }, { "Wants", config_parse_deps, UINT_TO_PTR(UNIT_WANTS), "Meta" }, { "Requisite", config_parse_deps, UINT_TO_PTR(UNIT_REQUISITE), "Meta" }, { "SoftRequisite", config_parse_deps, UINT_TO_PTR(UNIT_SOFT_REQUISITE), "Meta" }, { "Conflicts", config_parse_deps, UINT_TO_PTR(UNIT_CONFLICTS), "Meta" }, { "Before", config_parse_deps, UINT_TO_PTR(UNIT_BEFORE), "Meta" }, { "After", config_parse_deps, UINT_TO_PTR(UNIT_AFTER), "Meta" }, { "RecursiveStop", config_parse_bool, &u->meta.recursive_stop, "Meta" }, { "StopWhenUnneeded", config_parse_bool, &u->meta.stop_when_unneeded, "Meta" }, { "PIDFile", config_parse_path, &u->service.pid_file, "Service" }, { "ExecStartPre", config_parse_exec, u->service.exec_command+SERVICE_EXEC_START_PRE, "Service" }, { "ExecStart", config_parse_exec, u->service.exec_command+SERVICE_EXEC_START, "Service" }, { "ExecStartPost", config_parse_exec, u->service.exec_command+SERVICE_EXEC_START_POST, "Service" }, { "ExecReload", config_parse_exec, u->service.exec_command+SERVICE_EXEC_RELOAD, "Service" }, { "ExecStop", config_parse_exec, u->service.exec_command+SERVICE_EXEC_STOP, "Service" }, { "ExecStopPost", config_parse_exec, u->service.exec_command+SERVICE_EXEC_STOP_POST, "Service" }, { "RestartSec", config_parse_usec, &u->service.restart_usec, "Service" }, { "TimeoutSec", config_parse_usec, &u->service.timeout_usec, "Service" }, { "Type", config_parse_service_type, &u->service, "Service" }, { "Restart", config_parse_service_restart, &u->service, "Service" }, EXEC_CONTEXT_CONFIG_ITEMS(u->service.exec_context, "Service"), { "ListenStream", config_parse_listen, &u->socket, "Socket" }, { "ListenDatagram", config_parse_listen, &u->socket, "Socket" }, { "ListenSequentialPacket", config_parse_listen, &u->socket, "Socket" }, { "ListenFIFO", config_parse_listen, &u->socket, "Socket" }, { "BindIPv6Only", config_parse_socket_bind, &u->socket, "Socket" }, { "Backlog", config_parse_unsigned, &u->socket.backlog, "Socket" }, { "BindToDevice", config_parse_bindtodevice, &u->socket, "Socket" }, { "ExecStartPre", config_parse_exec, u->socket.exec_command+SOCKET_EXEC_START_PRE, "Socket" }, { "ExecStartPost", config_parse_exec, u->socket.exec_command+SOCKET_EXEC_START_POST, "Socket" }, { "ExecStopPre", config_parse_exec, u->socket.exec_command+SOCKET_EXEC_STOP_PRE, "Socket" }, { "ExecStopPost", config_parse_exec, u->socket.exec_command+SOCKET_EXEC_STOP_POST, "Socket" }, { "DirectoryMode", config_parse_mode, &u->socket.directory_mode, "Socket" }, { "SocketMode", config_parse_mode, &u->socket.socket_mode, "Socket" }, EXEC_CONTEXT_CONFIG_ITEMS(u->socket.exec_context, "Socket"), EXEC_CONTEXT_CONFIG_ITEMS(u->automount.exec_context, "Automount"), { NULL, NULL, NULL, NULL } }; #undef EXEC_CONTEXT_CONFIG_ITEMS const char *sections[3]; char *k; int r; Set *symlink_names; FILE *f; char *filename = NULL, *id; sections[0] = "Meta"; sections[1] = section_table[u->meta.type]; sections[2] = NULL; if (!(symlink_names = set_new(string_hash_func, string_compare_func))) return -ENOMEM; if (path_is_absolute(path)) { if (!(filename = strdup(path))) { r = -ENOMEM; goto finish; } if ((r = open_follow(&filename, &f, symlink_names, &id)) < 0) { free(filename); filename = NULL; if (r != -ENOENT) goto finish; } } else { char **p; STRV_FOREACH(p, u->meta.manager->unit_path) { /* Instead of opening the path right away, we manually * follow all symlinks and add their name to our unit * name set while doing so */ if (!(filename = path_make_absolute(path, *p))) { r = -ENOMEM; goto finish; } if ((r = open_follow(&filename, &f, symlink_names, &id)) < 0) { char *sn; free(filename); filename = NULL; if (r != -ENOENT) goto finish; /* Empty the symlink names for the next run */ while ((sn = set_steal_first(symlink_names))) free(sn); continue; } break; } } if (!filename) { r = 0; /* returning 0 means: no suitable config file found */ goto finish; } /* Now, parse the file contents */ r = config_parse(filename, f, sections, items, u); if (r < 0) goto finish; /* Let's try to add in all symlink names we found */ while ((k = set_steal_first(symlink_names))) { if ((r = unit_add_name(u, k)) < 0) goto finish; if (id == k) unit_choose_id(u, id); free(k); } free(u->meta.fragment_path); u->meta.fragment_path = filename; filename = NULL; r = 1; /* returning 1 means: suitable config file found and loaded */ finish: while ((k = set_steal_first(symlink_names))) free(k); set_free(symlink_names); free(filename); return r; } int unit_load_fragment(Unit *u) { int r = 0; ExecContext *c; assert(u); assert(u->meta.load_state == UNIT_STUB); if (u->meta.fragment_path) r = load_from_path(u, u->meta.fragment_path); else { Iterator i; char *t; /* Try to find a name we can load this with */ SET_FOREACH(t, u->meta.names, i) if ((r = load_from_path(u, t)) != 0) return r; } if (u->meta.type == UNIT_SOCKET) c = &u->socket.exec_context; else if (u->meta.type == UNIT_SERVICE) c = &u->service.exec_context; else c = NULL; if (r >= 0 && c && (c->output == EXEC_OUTPUT_KERNEL || c->output == EXEC_OUTPUT_SYSLOG)) { int k; /* If syslog or kernel logging is requested, make sure * our own logging daemon is run first. */ if ((k = unit_add_dependency_by_name(u, UNIT_AFTER, SPECIAL_LOGGER_SOCKET)) < 0) return k; if ((k = unit_add_dependency_by_name(u, UNIT_REQUIRES, SPECIAL_LOGGER_SOCKET)) < 0) return k; } return r; }