/* SPDX-License-Identifier: LGPL-2.1-or-later */ #include #include "af-list.h" #include "bus-error.h" #include "bus-locator.h" #include "bus-map-properties.h" #include "bus-print-properties.h" #include "bus-unit-procs.h" #include "cgroup-show.h" #include "cpu-set-util.h" #include "errno-util.h" #include "exec-util.h" #include "exit-status.h" #include "fd-util.h" #include "format-util.h" #include "hexdecoct.h" #include "hostname-util.h" #include "in-addr-util.h" #include "ip-protocol-list.h" #include "journal-file.h" #include "list.h" #include "locale-util.h" #include "memory-util.h" #include "numa-util.h" #include "open-file.h" #include "parse-util.h" #include "path-util.h" #include "pretty-print.h" #include "process-util.h" #include "signal-util.h" #include "sort-util.h" #include "special.h" #include "string-table.h" #include "systemctl-list-machines.h" #include "systemctl-list-units.h" #include "systemctl-show.h" #include "systemctl-sysv-compat.h" #include "systemctl-util.h" #include "systemctl.h" #include "terminal-util.h" #include "utf8.h" static OutputFlags get_output_flags(void) { return FLAGS_SET(arg_print_flags, BUS_PRINT_PROPERTY_SHOW_EMPTY) * OUTPUT_SHOW_ALL | (arg_full || !on_tty() || pager_have()) * OUTPUT_FULL_WIDTH | colors_enabled() * OUTPUT_COLOR | !arg_quiet * OUTPUT_WARN_CUTOFF; } typedef struct ExecStatusInfo { char *name; char *path; char **argv; bool ignore; usec_t start_timestamp; usec_t exit_timestamp; pid_t pid; int code; int status; ExecCommandFlags flags; LIST_FIELDS(struct ExecStatusInfo, exec_status_info_list); } ExecStatusInfo; static void exec_status_info_free(ExecStatusInfo *i) { assert(i); free(i->name); free(i->path); strv_free(i->argv); free(i); } static int exec_status_info_deserialize(sd_bus_message *m, ExecStatusInfo *i, bool is_ex_prop) { _cleanup_strv_free_ char **ex_opts = NULL; uint64_t start_timestamp, exit_timestamp, start_timestamp_monotonic, exit_timestamp_monotonic; const char *path; uint32_t pid; int32_t code, status; int ignore, r; assert(m); assert(i); r = sd_bus_message_enter_container(m, SD_BUS_TYPE_STRUCT, is_ex_prop ? "sasasttttuii" : "sasbttttuii"); if (r < 0) return bus_log_parse_error(r); if (r == 0) return 0; r = sd_bus_message_read(m, "s", &path); if (r < 0) return bus_log_parse_error(r); i->path = strdup(path); if (!i->path) return log_oom(); r = sd_bus_message_read_strv(m, &i->argv); if (r < 0) return bus_log_parse_error(r); r = is_ex_prop ? sd_bus_message_read_strv(m, &ex_opts) : sd_bus_message_read(m, "b", &ignore); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read(m, "ttttuii", &start_timestamp, &start_timestamp_monotonic, &exit_timestamp, &exit_timestamp_monotonic, &pid, &code, &status); if (r < 0) return bus_log_parse_error(r); if (is_ex_prop) { r = exec_command_flags_from_strv(ex_opts, &i->flags); if (r < 0) return log_error_errno(r, "Failed to convert strv to ExecCommandFlags: %m"); i->ignore = FLAGS_SET(i->flags, EXEC_COMMAND_IGNORE_FAILURE); } else i->ignore = ignore; i->start_timestamp = (usec_t) start_timestamp; i->exit_timestamp = (usec_t) exit_timestamp; i->pid = (pid_t) pid; i->code = code; i->status = status; r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } typedef struct UnitCondition { char *name; char *param; bool trigger; bool negate; int tristate; LIST_FIELDS(struct UnitCondition, conditions); } UnitCondition; static UnitCondition* unit_condition_free(UnitCondition *c) { if (!c) return NULL; free(c->name); free(c->param); return mfree(c); } DEFINE_TRIVIAL_CLEANUP_FUNC(UnitCondition*, unit_condition_free); typedef struct UnitStatusInfo { const char *id; const char *load_state; const char *active_state; const char *freezer_state; const char *sub_state; const char *unit_file_state; const char *unit_file_preset; const char *description; const char *following; char **documentation; const char *fragment_path; const char *source_path; const char *control_group; char **dropin_paths; char **triggered_by; char **triggers; const char *load_error; const char *result; usec_t inactive_exit_timestamp; usec_t inactive_exit_timestamp_monotonic; usec_t active_enter_timestamp; usec_t active_exit_timestamp; usec_t inactive_enter_timestamp; uint64_t runtime_max_sec; sd_id128_t invocation_id; bool need_daemon_reload; bool transient; /* Service */ pid_t main_pid; pid_t control_pid; const char *status_text; const char *pid_file; bool running; int status_errno; uint32_t fd_store_max; uint32_t n_fd_store; usec_t start_timestamp; usec_t exit_timestamp; int exit_code, exit_status; const char *log_namespace; usec_t condition_timestamp; bool condition_result; LIST_HEAD(UnitCondition, conditions); usec_t assert_timestamp; bool assert_result; bool failed_assert_trigger; bool failed_assert_negate; const char *failed_assert; const char *failed_assert_parameter; usec_t next_elapse_real; usec_t next_elapse_monotonic; /* Socket */ unsigned n_accepted; unsigned n_connections; unsigned n_refused; bool accept; /* Pairs of type, path */ char **listen; /* Device */ const char *sysfs_path; /* Mount, Automount */ const char *where; /* Swap */ const char *what; /* CGroup */ uint64_t memory_current; uint64_t memory_peak; uint64_t memory_swap_current; uint64_t memory_swap_peak; uint64_t memory_zswap_current; uint64_t memory_min; uint64_t memory_low; uint64_t startup_memory_low; uint64_t memory_high; uint64_t startup_memory_high; uint64_t memory_max; uint64_t startup_memory_max; uint64_t memory_swap_max; uint64_t startup_memory_swap_max; uint64_t memory_zswap_max; uint64_t startup_memory_zswap_max; uint64_t memory_limit; uint64_t memory_available; uint64_t cpu_usage_nsec; uint64_t tasks_current; uint64_t tasks_max; uint64_t ip_ingress_bytes; uint64_t ip_egress_bytes; uint64_t io_read_bytes; uint64_t io_write_bytes; uint64_t default_memory_min; uint64_t default_memory_low; uint64_t default_startup_memory_low; LIST_HEAD(ExecStatusInfo, exec_status_info_list); } UnitStatusInfo; static void unit_status_info_done(UnitStatusInfo *info) { strv_free(info->documentation); strv_free(info->dropin_paths); strv_free(info->triggered_by); strv_free(info->triggers); strv_free(info->listen); LIST_CLEAR(conditions, info->conditions, unit_condition_free); LIST_CLEAR(exec_status_info_list, info->exec_status_info_list, exec_status_info_free); } static void format_active_state(const char *active_state, const char **active_on, const char **active_off) { if (streq_ptr(active_state, "failed")) { *active_on = ansi_highlight_red(); *active_off = ansi_normal(); } else if (STRPTR_IN_SET(active_state, "active", "reloading")) { *active_on = ansi_highlight_green(); *active_off = ansi_normal(); } else *active_on = *active_off = ""; } static void format_enable_state(const char *enable_state, const char **enable_on, const char **enable_off) { assert(enable_on); assert(enable_off); if (streq_ptr(enable_state, "disabled")) { *enable_on = ansi_highlight_yellow(); *enable_off = ansi_normal(); } else if (streq_ptr(enable_state, "enabled")) { *enable_on = ansi_highlight_green(); *enable_off = ansi_normal(); } else *enable_on = *enable_off = ""; } static void print_status_info( sd_bus *bus, UnitStatusInfo *i, bool *ellipsized) { const char *active_on, *active_off, *on, *off, *ss, *fs; const char *enable_on, *enable_off, *preset_on, *preset_off; _cleanup_free_ char *formatted_path = NULL; usec_t timestamp; const char *path; int r; assert(i); /* This shows pretty information about a unit. See print_property() for a low-level property * printer */ format_active_state(i->active_state, &active_on, &active_off); format_enable_state(i->unit_file_state, &enable_on, &enable_off); format_enable_state(i->unit_file_preset, &preset_on, &preset_off); const SpecialGlyph glyph = unit_active_state_to_glyph(unit_active_state_from_string(i->active_state)); printf("%s%s%s %s", active_on, special_glyph(glyph), active_off, strna(i->id)); if (i->description && !streq_ptr(i->id, i->description)) printf(" - %s", i->description); printf("\n"); if (i->following) printf(" Follows: unit currently follows state of %s\n", i->following); if (STRPTR_IN_SET(i->load_state, "error", "not-found", "bad-setting")) { on = ansi_highlight_red(); off = ansi_normal(); } else on = off = ""; path = i->source_path ?: i->fragment_path; if (path && terminal_urlify_path(path, NULL, &formatted_path) >= 0) path = formatted_path; if (!isempty(i->load_error)) printf(" Loaded: %s%s%s (Reason: %s)\n", on, strna(i->load_state), off, i->load_error); else if (path && !isempty(i->unit_file_state)) { bool show_preset = !isempty(i->unit_file_preset) && show_preset_for_state(unit_file_state_from_string(i->unit_file_state)); printf(" Loaded: %s%s%s (%s; %s%s%s%s%s%s%s)\n", on, strna(i->load_state), off, path, enable_on, i->unit_file_state, enable_off, show_preset ? "; preset: " : "", preset_on, show_preset ? i->unit_file_preset : "", preset_off); } else if (path) printf(" Loaded: %s%s%s (%s)\n", on, strna(i->load_state), off, path); else printf(" Loaded: %s%s%s\n", on, strna(i->load_state), off); if (i->transient) printf(" Transient: yes\n"); if (!strv_isempty(i->dropin_paths)) { _cleanup_free_ char *dir = NULL; bool last = false; STRV_FOREACH(dropin, i->dropin_paths) { _cleanup_free_ char *dropin_formatted = NULL; const char *df; if (!dir || last) { printf(dir ? " " : " Drop-In: "); dir = mfree(dir); r = path_extract_directory(*dropin, &dir); if (r < 0) { log_error_errno(r, "Failed to extract directory of '%s': %m", *dropin); break; } printf("%s\n" " %s", dir, special_glyph(SPECIAL_GLYPH_TREE_RIGHT)); } last = ! (*(dropin + 1) && startswith(*(dropin + 1), dir)); if (terminal_urlify_path(*dropin, basename(*dropin), &dropin_formatted) >= 0) df = dropin_formatted; else df = *dropin; printf("%s%s", df, last ? "\n" : ", "); } } ss = streq_ptr(i->active_state, i->sub_state) ? NULL : i->sub_state; if (ss) printf(" Active: %s%s (%s)%s", active_on, strna(i->active_state), ss, active_off); else printf(" Active: %s%s%s", active_on, strna(i->active_state), active_off); fs = !isempty(i->freezer_state) && !streq(i->freezer_state, "running") ? i->freezer_state : NULL; if (fs) printf(" %s(%s)%s", ansi_highlight_yellow(), fs, ansi_normal()); if (!isempty(i->result) && !streq(i->result, "success")) printf(" (Result: %s)", i->result); timestamp = STRPTR_IN_SET(i->active_state, "active", "reloading") ? i->active_enter_timestamp : STRPTR_IN_SET(i->active_state, "inactive", "failed") ? i->inactive_enter_timestamp : STRPTR_IN_SET(i->active_state, "activating") ? i->inactive_exit_timestamp : i->active_exit_timestamp; if (timestamp_is_set(timestamp)) { printf(" since %s; %s\n", FORMAT_TIMESTAMP_STYLE(timestamp, arg_timestamp_style), FORMAT_TIMESTAMP_RELATIVE(timestamp)); if (streq_ptr(i->active_state, "active") && i->runtime_max_sec < USEC_INFINITY) { usec_t until_timestamp; until_timestamp = usec_add(timestamp, i->runtime_max_sec); printf(" Until: %s; %s\n", FORMAT_TIMESTAMP_STYLE(until_timestamp, arg_timestamp_style), FORMAT_TIMESTAMP_RELATIVE(until_timestamp)); } if (!endswith(i->id, ".target") && STRPTR_IN_SET(i->active_state, "inactive", "failed") && timestamp_is_set(i->active_enter_timestamp) && timestamp_is_set(i->active_exit_timestamp) && i->active_exit_timestamp >= i->active_enter_timestamp) { usec_t duration; duration = i->active_exit_timestamp - i->active_enter_timestamp; printf(" Duration: %s\n", FORMAT_TIMESPAN(duration, MSEC_PER_SEC)); } } else printf("\n"); if (!sd_id128_is_null(i->invocation_id)) printf(" Invocation: " SD_ID128_FORMAT_STR "\n", SD_ID128_FORMAT_VAL(i->invocation_id)); STRV_FOREACH(t, i->triggered_by) { UnitActiveState state = _UNIT_ACTIVE_STATE_INVALID; (void) get_state_one_unit(bus, *t, &state); format_active_state(unit_active_state_to_string(state), &on, &off); printf("%s %s%s%s %s\n", t == i->triggered_by ? "TriggeredBy:" : " ", on, special_glyph(unit_active_state_to_glyph(state)), off, *t); } if (endswith(i->id, ".timer")) { dual_timestamp nw, next = {i->next_elapse_real, i->next_elapse_monotonic}; usec_t next_elapse; dual_timestamp_now(&nw); next_elapse = calc_next_elapse(&nw, &next); if (timestamp_is_set(next_elapse)) printf(" Trigger: %s; %s\n", FORMAT_TIMESTAMP_STYLE(next_elapse, arg_timestamp_style), FORMAT_TIMESTAMP_RELATIVE(next_elapse)); else printf(" Trigger: n/a\n"); } STRV_FOREACH(t, i->triggers) { UnitActiveState state = _UNIT_ACTIVE_STATE_INVALID; (void) get_state_one_unit(bus, *t, &state); format_active_state(unit_active_state_to_string(state), &on, &off); printf("%s %s%s%s %s\n", t == i->triggers ? " Triggers:" : " ", on, special_glyph(SPECIAL_GLYPH_BLACK_CIRCLE), off, *t); } if (!i->condition_result && i->condition_timestamp > 0) { int n = 0; printf(" Condition: start %scondition unmet%s at %s; %s\n", ansi_highlight_yellow(), ansi_normal(), FORMAT_TIMESTAMP_STYLE(i->condition_timestamp, arg_timestamp_style), FORMAT_TIMESTAMP_RELATIVE(i->condition_timestamp)); LIST_FOREACH(conditions, c, i->conditions) if (c->tristate < 0) n++; LIST_FOREACH(conditions, c, i->conditions) if (c->tristate < 0) printf(" %s %s=%s%s%s was not met\n", --n ? special_glyph(SPECIAL_GLYPH_TREE_BRANCH) : special_glyph(SPECIAL_GLYPH_TREE_RIGHT), c->name, c->trigger ? "|" : "", c->negate ? "!" : "", c->param); } if (!i->assert_result && i->assert_timestamp > 0) { printf(" Assert: start %sassertion failed%s at %s; %s\n", ansi_highlight_red(), ansi_normal(), FORMAT_TIMESTAMP_STYLE(i->assert_timestamp, arg_timestamp_style), FORMAT_TIMESTAMP_RELATIVE(i->assert_timestamp)); if (i->failed_assert_trigger) printf(" none of the trigger assertions were met\n"); else if (i->failed_assert) printf(" %s=%s%s was not met\n", i->failed_assert, i->failed_assert_negate ? "!" : "", i->failed_assert_parameter); } if (i->sysfs_path) printf(" Device: %s\n", i->sysfs_path); if (i->where) printf(" Where: %s\n", i->where); if (i->what) printf(" What: %s\n", i->what); STRV_FOREACH(t, i->documentation) { _cleanup_free_ char *formatted = NULL; const char *q; if (terminal_urlify(*t, NULL, &formatted) >= 0) q = formatted; else q = *t; printf(" %*s %s\n", 9, t == i->documentation ? "Docs:" : "", q); } STRV_FOREACH_PAIR(t, t2, i->listen) printf(" %*s %s (%s)\n", 9, t == i->listen ? "Listen:" : "", *t2, *t); if (i->accept) { printf(" Accepted: %u; Connected: %u;", i->n_accepted, i->n_connections); if (i->n_refused) printf(" Refused: %u", i->n_refused); printf("\n"); } LIST_FOREACH(exec_status_info_list, p, i->exec_status_info_list) { _cleanup_free_ char *argv = NULL; bool good; /* Only show exited processes here */ if (p->code == 0) continue; /* Don't print ExecXYZEx= properties here since it will appear as a * duplicate of the non-Ex= variant. */ if (endswith(p->name, "Ex")) continue; argv = strv_join(p->argv, " "); printf(" Process: "PID_FMT" %s=%s ", p->pid, p->name, strna(argv)); good = is_clean_exit(p->code, p->status, EXIT_CLEAN_DAEMON, NULL); if (!good) { on = p->ignore ? ansi_highlight_yellow() : ansi_highlight_red(); off = ansi_normal(); } else on = off = ""; printf("%s(code=%s, ", on, sigchld_code_to_string(p->code)); if (p->code == CLD_EXITED) { const char *c; printf("status=%i", p->status); c = exit_status_to_string(p->status, EXIT_STATUS_LIBC | EXIT_STATUS_SYSTEMD); if (c) printf("/%s", c); } else printf("signal=%s", signal_to_string(p->status)); printf(")%s\n", off); if (i->main_pid == p->pid && i->start_timestamp == p->start_timestamp && i->exit_timestamp == p->start_timestamp) /* Let's not show this twice */ i->main_pid = 0; if (p->pid == i->control_pid) i->control_pid = 0; } if (i->main_pid > 0 || i->control_pid > 0) { if (i->main_pid > 0) { printf(" Main PID: "PID_FMT, i->main_pid); if (i->running) { if (arg_transport == BUS_TRANSPORT_LOCAL) { _cleanup_free_ char *comm = NULL; (void) pid_get_comm(i->main_pid, &comm); if (comm) printf(" (%s)", comm); } } else if (i->exit_code > 0) { printf(" (code=%s, ", sigchld_code_to_string(i->exit_code)); if (i->exit_code == CLD_EXITED) { const char *c; printf("status=%i", i->exit_status); c = exit_status_to_string(i->exit_status, EXIT_STATUS_LIBC | EXIT_STATUS_SYSTEMD); if (c) printf("/%s", c); } else printf("signal=%s", signal_to_string(i->exit_status)); printf(")"); } } if (i->control_pid > 0) { _cleanup_free_ char *c = NULL; if (i->main_pid > 0) fputs("; Control PID: ", stdout); else fputs(" Cntrl PID: ", stdout); /* if first in column, abbreviated so it fits alignment */ printf(PID_FMT, i->control_pid); if (arg_transport == BUS_TRANSPORT_LOCAL) { (void) pid_get_comm(i->control_pid, &c); if (c) printf(" (%s)", c); } } printf("\n"); } if (i->status_text) printf(" Status: \"%s%s%s\"\n", ansi_highlight_cyan(), i->status_text, ansi_normal()); if (i->status_errno > 0) { errno = i->status_errno; printf(" Error: %i (%m)\n", i->status_errno); } if (i->ip_ingress_bytes != UINT64_MAX && i->ip_egress_bytes != UINT64_MAX) printf(" IP: %s in, %s out\n", FORMAT_BYTES(i->ip_ingress_bytes), FORMAT_BYTES(i->ip_egress_bytes)); if (i->io_read_bytes != UINT64_MAX && i->io_write_bytes != UINT64_MAX) printf(" IO: %s read, %s written\n", FORMAT_BYTES(i->io_read_bytes), FORMAT_BYTES(i->io_write_bytes)); if (i->tasks_current != UINT64_MAX) { printf(" Tasks: %" PRIu64, i->tasks_current); if (i->tasks_max != UINT64_MAX) printf(" (limit: %" PRIu64 ")\n", i->tasks_max); else printf("\n"); } if (i->n_fd_store > 0 || i->fd_store_max > 0) printf(" FD Store: %u%s (limit: %u)%s\n", i->n_fd_store, ansi_grey(), i->fd_store_max, ansi_normal()); bool show_memory_peak = i->memory_peak != CGROUP_LIMIT_MAX, show_memory_swap_peak = !IN_SET(i->memory_swap_peak, 0, CGROUP_LIMIT_MAX); if (i->memory_current != UINT64_MAX) { printf(" Memory: %s", FORMAT_BYTES(i->memory_current)); /* Only show current swap if it ever was non-zero or is currently non-zero. In both cases memory_swap_peak will be non-zero (and not CGROUP_LIMIT_MAX). Only show the available memory if it was artificially limited. */ bool show_memory_zswap_current = !IN_SET(i->memory_zswap_current, 0, CGROUP_LIMIT_MAX), show_memory_available = i->memory_high != CGROUP_LIMIT_MAX || i->memory_max != CGROUP_LIMIT_MAX; if (show_memory_peak || show_memory_swap_peak || show_memory_zswap_current || show_memory_available || i->memory_min > 0 || i->memory_low > 0 || i->startup_memory_low > 0 || i->memory_high != CGROUP_LIMIT_MAX || i->startup_memory_high != CGROUP_LIMIT_MAX || i->memory_max != CGROUP_LIMIT_MAX || i->startup_memory_max != CGROUP_LIMIT_MAX || i->memory_swap_max != CGROUP_LIMIT_MAX || i->startup_memory_swap_max != CGROUP_LIMIT_MAX || i->memory_zswap_max != CGROUP_LIMIT_MAX || i->startup_memory_zswap_max != CGROUP_LIMIT_MAX || i->memory_available != CGROUP_LIMIT_MAX || i->memory_limit != CGROUP_LIMIT_MAX) { const char *prefix = ""; printf(" ("); if (i->memory_min > 0) { printf("%smin: %s", prefix, FORMAT_BYTES_CGROUP_PROTECTION(i->memory_min)); prefix = " "; } if (i->memory_low > 0) { printf("%slow: %s", prefix, FORMAT_BYTES_CGROUP_PROTECTION(i->memory_low)); prefix = " "; } if (i->startup_memory_low > 0) { printf("%slow (startup): %s", prefix, FORMAT_BYTES_CGROUP_PROTECTION(i->startup_memory_low)); prefix = " "; } if (i->memory_high != CGROUP_LIMIT_MAX) { printf("%shigh: %s", prefix, FORMAT_BYTES(i->memory_high)); prefix = " "; } if (i->startup_memory_high != CGROUP_LIMIT_MAX) { printf("%shigh (startup): %s", prefix, FORMAT_BYTES(i->startup_memory_high)); prefix = " "; } if (i->memory_max != CGROUP_LIMIT_MAX) { printf("%smax: %s", prefix, FORMAT_BYTES(i->memory_max)); prefix = " "; } if (i->startup_memory_max != CGROUP_LIMIT_MAX) { printf("%smax (startup): %s", prefix, FORMAT_BYTES(i->startup_memory_max)); prefix = " "; } if (i->memory_swap_max != CGROUP_LIMIT_MAX) { printf("%sswap max: %s", prefix, FORMAT_BYTES(i->memory_swap_max)); prefix = " "; } if (i->startup_memory_swap_max != CGROUP_LIMIT_MAX) { printf("%sswap max (startup): %s", prefix, FORMAT_BYTES(i->startup_memory_swap_max)); prefix = " "; } if (i->memory_zswap_max != CGROUP_LIMIT_MAX) { printf("%szswap max: %s", prefix, FORMAT_BYTES(i->memory_zswap_max)); prefix = " "; } if (i->startup_memory_zswap_max != CGROUP_LIMIT_MAX) { printf("%szswap max (startup): %s", prefix, FORMAT_BYTES(i->startup_memory_zswap_max)); prefix = " "; } if (i->memory_limit != CGROUP_LIMIT_MAX) { printf("%slimit: %s", prefix, FORMAT_BYTES(i->memory_limit)); prefix = " "; } if (show_memory_available) { printf("%savailable: %s", prefix, FORMAT_BYTES(i->memory_available)); prefix = " "; } if (show_memory_peak) { printf("%speak: %s", prefix, FORMAT_BYTES(i->memory_peak)); prefix = " "; } if (show_memory_swap_peak) { printf("%sswap: %s swap peak: %s", prefix, FORMAT_BYTES(i->memory_swap_current), FORMAT_BYTES(i->memory_swap_peak)); prefix = " "; } if (show_memory_zswap_current) { printf("%szswap: %s", prefix, FORMAT_BYTES(i->memory_zswap_current)); prefix = " "; } printf(")"); } printf("\n"); } else if (show_memory_peak) { printf(" Mem peak: %s", FORMAT_BYTES(i->memory_peak)); if (show_memory_swap_peak) printf(" (swap: %s)", FORMAT_BYTES(i->memory_swap_peak)); putchar('\n'); } if (i->cpu_usage_nsec != UINT64_MAX) printf(" CPU: %s\n", FORMAT_TIMESPAN(i->cpu_usage_nsec / NSEC_PER_USEC, USEC_PER_MSEC)); if (i->control_group) { _cleanup_(sd_bus_error_free) sd_bus_error error = SD_BUS_ERROR_NULL; static const char prefix[] = " "; unsigned c; printf(" CGroup: %s\n", i->control_group); c = LESS_BY(columns(), strlen(prefix)); r = unit_show_processes(bus, i->id, i->control_group, prefix, c, get_output_flags(), &error); if (r == -EBADR && arg_transport == BUS_TRANSPORT_LOCAL) { unsigned k = 0; pid_t extra[2]; /* Fallback for older systemd versions where the GetUnitProcesses() call is not yet available */ if (i->main_pid > 0) extra[k++] = i->main_pid; if (i->control_pid > 0) extra[k++] = i->control_pid; show_cgroup_and_extra(SYSTEMD_CGROUP_CONTROLLER, i->control_group, prefix, c, extra, k, get_output_flags()); } else if (r < 0) log_warning_errno(r, "Failed to dump process list for '%s', ignoring: %s", i->id, bus_error_message(&error, r)); } if (i->id && arg_transport == BUS_TRANSPORT_LOCAL) show_journal_by_unit( stdout, i->id, i->log_namespace, arg_output, 0, i->inactive_exit_timestamp_monotonic, arg_lines, getuid(), get_output_flags() | OUTPUT_BEGIN_NEWLINE, SD_JOURNAL_LOCAL_ONLY, arg_runtime_scope == RUNTIME_SCOPE_SYSTEM, ellipsized); if (i->need_daemon_reload) warn_unit_file_changed(i->id); } static void show_unit_help(UnitStatusInfo *i) { bool previous_man_page = false; assert(i); if (!i->documentation) { log_info("Documentation for %s not known.", i->id); return; } STRV_FOREACH(doc, i->documentation) { const char *p; p = startswith(*doc, "man:"); if (p ? doc != i->documentation : previous_man_page) { puts(""); fflush(stdout); } previous_man_page = p; if (p) show_man_page(p, /* null_stdio= */ false); else { _cleanup_free_ char *t = NULL; if ((p = startswith(*doc, "file://"))) (void) terminal_urlify_path(p, NULL, &t); printf("Additional documentation: %s\n", t ?: p ?: *doc); } } } static int map_main_pid(sd_bus *bus, const char *member, sd_bus_message *m, sd_bus_error *error, void *userdata) { UnitStatusInfo *i = userdata; uint32_t u; int r; r = sd_bus_message_read(m, "u", &u); if (r < 0) return r; i->main_pid = (pid_t) u; i->running = u > 0; return 0; } static int map_load_error(sd_bus *bus, const char *member, sd_bus_message *m, sd_bus_error *error, void *userdata) { const char *message, **p = userdata; int r; r = sd_bus_message_read(m, "(ss)", NULL, &message); if (r < 0) return r; if (!isempty(message)) *p = message; return 0; } static int map_listen(sd_bus *bus, const char *member, sd_bus_message *m, sd_bus_error *error, void *userdata) { const char *type, *path; char ***p = userdata; int r; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ss)"); if (r < 0) return r; while ((r = sd_bus_message_read(m, "(ss)", &type, &path)) > 0) { r = strv_extend_many(p, type, path); if (r < 0) return r; } if (r < 0) return r; r = sd_bus_message_exit_container(m); if (r < 0) return r; return 0; } static int map_conditions(sd_bus *bus, const char *member, sd_bus_message *m, sd_bus_error *error, void *userdata) { UnitStatusInfo *i = userdata; const char *cond, *param; int trigger, negate; int32_t state; int r; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sbbsi)"); if (r < 0) return r; while ((r = sd_bus_message_read(m, "(sbbsi)", &cond, &trigger, &negate, ¶m, &state)) > 0) { _cleanup_(unit_condition_freep) UnitCondition *c = NULL; c = new(UnitCondition, 1); if (!c) return -ENOMEM; *c = (UnitCondition) { .name = strdup(cond), .param = strdup(param), .trigger = trigger, .negate = negate, .tristate = state, }; if (!c->name || !c->param) return -ENOMEM; LIST_PREPEND(conditions, i->conditions, TAKE_PTR(c)); } if (r < 0) return r; r = sd_bus_message_exit_container(m); if (r < 0) return r; return 0; } static int map_asserts(sd_bus *bus, const char *member, sd_bus_message *m, sd_bus_error *error, void *userdata) { UnitStatusInfo *i = userdata; const char *cond, *param; int trigger, negate; int32_t state; int r; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sbbsi)"); if (r < 0) return r; while ((r = sd_bus_message_read(m, "(sbbsi)", &cond, &trigger, &negate, ¶m, &state)) > 0) { if (state < 0 && (!trigger || !i->failed_assert)) { i->failed_assert = cond; i->failed_assert_trigger = trigger; i->failed_assert_negate = negate; i->failed_assert_parameter = param; } } if (r < 0) return r; r = sd_bus_message_exit_container(m); if (r < 0) return r; return 0; } static int map_exec(sd_bus *bus, const char *member, sd_bus_message *m, sd_bus_error *error, void *userdata) { _cleanup_free_ ExecStatusInfo *info = NULL; ExecStatusInfo *last; UnitStatusInfo *i = userdata; bool is_ex_prop = endswith(member, "Ex"); int r; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, is_ex_prop ? "(sasasttttuii)" : "(sasbttttuii)"); if (r < 0) return r; info = new0(ExecStatusInfo, 1); if (!info) return -ENOMEM; last = LIST_FIND_TAIL(exec_status_info_list, i->exec_status_info_list); while ((r = exec_status_info_deserialize(m, info, is_ex_prop)) > 0) { info->name = strdup(member); if (!info->name) return -ENOMEM; LIST_INSERT_AFTER(exec_status_info_list, i->exec_status_info_list, last, info); last = info; info = new0(ExecStatusInfo, 1); if (!info) return -ENOMEM; } if (r < 0) return r; r = sd_bus_message_exit_container(m); if (r < 0) return r; return 0; } static int print_property(const char *name, const char *expected_value, sd_bus_message *m, BusPrintPropertyFlags flags) { char bus_type; const char *contents; int r; assert(name); assert(m); /* This is a low-level property printer, see print_status_info() for the nicer output */ r = sd_bus_message_peek_type(m, &bus_type, &contents); if (r < 0) return r; switch (bus_type) { case SD_BUS_TYPE_INT32: if (endswith(name, "ActionExitStatus")) { int32_t i; r = sd_bus_message_read_basic(m, bus_type, &i); if (r < 0) return r; if (i >= 0 && i <= 255) bus_print_property_valuef(name, expected_value, flags, "%"PRIi32, i); else if (FLAGS_SET(flags, BUS_PRINT_PROPERTY_SHOW_EMPTY)) bus_print_property_value(name, expected_value, flags, "[not set]"); return 1; } else if (streq(name, "NUMAPolicy")) { int32_t i; r = sd_bus_message_read_basic(m, bus_type, &i); if (r < 0) return r; bus_print_property_valuef(name, expected_value, flags, "%s", strna(mpol_to_string(i))); return 1; } break; case SD_BUS_TYPE_UINT64: if (endswith(name, "Timestamp")) { uint64_t timestamp; r = sd_bus_message_read_basic(m, bus_type, ×tamp); if (r < 0) return r; bus_print_property_value(name, expected_value, flags, FORMAT_TIMESTAMP_STYLE(timestamp, arg_timestamp_style)); return 1; } break; case SD_BUS_TYPE_STRUCT: if (contents[0] == SD_BUS_TYPE_UINT32 && streq(name, "Job")) { uint32_t u; r = sd_bus_message_read(m, "(uo)", &u, NULL); if (r < 0) return bus_log_parse_error(r); if (u > 0) bus_print_property_valuef(name, expected_value, flags, "%"PRIu32, u); else bus_print_property_value(name, expected_value, flags, NULL); return 1; } else if (contents[0] == SD_BUS_TYPE_STRING && streq(name, "Unit")) { const char *s; r = sd_bus_message_read(m, "(so)", &s, NULL); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, s); return 1; } else if (contents[0] == SD_BUS_TYPE_STRING && streq(name, "LoadError")) { const char *a = NULL, *b = NULL; r = sd_bus_message_read(m, "(ss)", &a, &b); if (r < 0) return bus_log_parse_error(r); if (!isempty(a) || !isempty(b)) bus_print_property_valuef(name, expected_value, flags, "%s \"%s\"", strempty(a), strempty(b)); else bus_print_property_value(name, expected_value, flags, NULL); return 1; } else if (STR_IN_SET(name, "SystemCallFilter", "SystemCallLog", "RestrictAddressFamilies", "RestrictNetworkInterfaces", "RestrictFileSystems")) { _cleanup_strv_free_ char **l = NULL; int allow_list; r = sd_bus_message_enter_container(m, 'r', "bas"); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read(m, "b", &allow_list); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read_strv(m, &l); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); if (FLAGS_SET(flags, BUS_PRINT_PROPERTY_SHOW_EMPTY) || allow_list || !strv_isempty(l)) { bool first = true; if (!FLAGS_SET(flags, BUS_PRINT_PROPERTY_ONLY_VALUE)) { fputs(name, stdout); fputc('=', stdout); } if (!allow_list) fputc('~', stdout); STRV_FOREACH(i, l) { if (first) first = false; else fputc(' ', stdout); fputs(*i, stdout); } fputc('\n', stdout); } return 1; } else if (STR_IN_SET(name, "SELinuxContext", "AppArmorProfile", "SmackProcessLabel")) { int ignore; const char *s; r = sd_bus_message_read(m, "(bs)", &ignore, &s); if (r < 0) return bus_log_parse_error(r); if (!isempty(s)) bus_print_property_valuef(name, expected_value, flags, "%s%s", ignore ? "-" : "", s); else bus_print_property_value(name, expected_value, flags, NULL); return 1; } else if (endswith(name, "ExitStatus") && streq(contents, "aiai")) { const int32_t *status, *signal; size_t n_status, n_signal; r = sd_bus_message_enter_container(m, 'r', "aiai"); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read_array(m, 'i', (const void **) &status, &n_status); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read_array(m, 'i', (const void **) &signal, &n_signal); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); n_status /= sizeof(int32_t); n_signal /= sizeof(int32_t); if (FLAGS_SET(flags, BUS_PRINT_PROPERTY_SHOW_EMPTY) || n_status > 0 || n_signal > 0) { bool first = true; if (!FLAGS_SET(flags, BUS_PRINT_PROPERTY_ONLY_VALUE)) { fputs(name, stdout); fputc('=', stdout); } for (size_t i = 0; i < n_status; i++) { if (first) first = false; else fputc(' ', stdout); printf("%"PRIi32, status[i]); } for (size_t i = 0; i < n_signal; i++) { const char *str; str = signal_to_string((int) signal[i]); if (first) first = false; else fputc(' ', stdout); if (str) fputs(str, stdout); else printf("%"PRIi32, status[i]); } fputc('\n', stdout); } return 1; } break; case SD_BUS_TYPE_ARRAY: if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "EnvironmentFiles")) { const char *path; int ignore; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sb)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(sb)", &path, &ignore)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s (ignore_errors=%s)", path, yes_no(ignore)); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "Paths")) { const char *type, *path; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &type, &path)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s (%s)", path, type); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "Listen")) { const char *type, *path; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &type, &path)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s (%s)", path, type); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "TimersMonotonic")) { const char *base; uint64_t v, next_elapse; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(stt)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(stt)", &base, &v, &next_elapse)) > 0) bus_print_property_valuef(name, expected_value, flags, "{ %s=%s ; next_elapse=%s }", base, strna(FORMAT_TIMESPAN(v, 0)), strna(FORMAT_TIMESPAN(next_elapse, 0))); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "TimersCalendar")) { const char *base, *spec; uint64_t next_elapse; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sst)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(sst)", &base, &spec, &next_elapse)) > 0) bus_print_property_valuef(name, expected_value, flags, "{ %s=%s ; next_elapse=%s }", base, spec, FORMAT_TIMESTAMP_STYLE(next_elapse, arg_timestamp_style)); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && startswith(name, "Exec")) { ExecStatusInfo info = {}; bool is_ex_prop = endswith(name, "Ex"); r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, is_ex_prop ? "(sasasttttuii)" : "(sasbttttuii)"); if (r < 0) return bus_log_parse_error(r); while ((r = exec_status_info_deserialize(m, &info, is_ex_prop)) > 0) { _cleanup_strv_free_ char **optv = NULL; _cleanup_free_ char *tt = NULL, *o = NULL; tt = strv_join(info.argv, " "); if (is_ex_prop) { r = exec_command_flags_to_strv(info.flags, &optv); if (r < 0) return log_error_errno(r, "Failed to convert ExecCommandFlags to strv: %m"); o = strv_join(optv, " "); bus_print_property_valuef(name, expected_value, flags, "{ path=%s ; argv[]=%s ; flags=%s ; start_time=[%s] ; stop_time=[%s] ; pid="PID_FMT" ; code=%s ; status=%i%s%s }", strna(info.path), strna(tt), strna(o), strna(FORMAT_TIMESTAMP_STYLE(info.start_timestamp, arg_timestamp_style)), strna(FORMAT_TIMESTAMP_STYLE(info.exit_timestamp, arg_timestamp_style)), info.pid, sigchld_code_to_string(info.code), info.status, info.code == CLD_EXITED ? "" : "/", strempty(info.code == CLD_EXITED ? NULL : signal_to_string(info.status))); } else bus_print_property_valuef(name, expected_value, flags, "{ path=%s ; argv[]=%s ; ignore_errors=%s ; start_time=[%s] ; stop_time=[%s] ; pid="PID_FMT" ; code=%s ; status=%i%s%s }", strna(info.path), strna(tt), yes_no(info.ignore), strna(FORMAT_TIMESTAMP_STYLE(info.start_timestamp, arg_timestamp_style)), strna(FORMAT_TIMESTAMP_STYLE(info.exit_timestamp, arg_timestamp_style)), info.pid, sigchld_code_to_string(info.code), info.status, info.code == CLD_EXITED ? "" : "/", strempty(info.code == CLD_EXITED ? NULL : signal_to_string(info.status))); free(info.path); strv_free(info.argv); zero(info); } r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "DeviceAllow")) { const char *path, *rwm; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &path, &rwm)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s %s", strna(path), strna(rwm)); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && STR_IN_SET(name, "IODeviceWeight", "BlockIODeviceWeight")) { const char *path; uint64_t weight; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(st)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(st)", &path, &weight)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s %"PRIu64, strna(path), weight); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && (cgroup_io_limit_type_from_string(name) >= 0 || STR_IN_SET(name, "BlockIOReadBandwidth", "BlockIOWriteBandwidth"))) { const char *path; uint64_t bandwidth; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(st)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(st)", &path, &bandwidth)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s %"PRIu64, strna(path), bandwidth); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "IODeviceLatencyTargetUSec")) { const char *path; uint64_t target; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(st)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(st)", &path, &target)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s %s", strna(path), FORMAT_TIMESPAN(target, 1)); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_BYTE && STR_IN_SET(name, "StandardInputData", "RootHashSignature")) { _cleanup_free_ char *h = NULL; const void *p; size_t sz; ssize_t n; r = sd_bus_message_read_array(m, 'y', &p, &sz); if (r < 0) return bus_log_parse_error(r); n = base64mem(p, sz, &h); if (n < 0) return log_oom(); bus_print_property_value(name, expected_value, flags, h); return 1; } else if (STR_IN_SET(name, "IPAddressAllow", "IPAddressDeny")) { _cleanup_free_ char *addresses = NULL; r = sd_bus_message_enter_container(m, 'a', "(iayu)"); if (r < 0) return bus_log_parse_error(r); for (;;) { uint32_t prefixlen; int32_t family; const void *ap; size_t an; r = sd_bus_message_enter_container(m, 'r', "iayu"); if (r < 0) return bus_log_parse_error(r); if (r == 0) break; r = sd_bus_message_read(m, "i", &family); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read_array(m, 'y', &ap, &an); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_read(m, "u", &prefixlen); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); if (!IN_SET(family, AF_INET, AF_INET6)) continue; if (an != FAMILY_ADDRESS_SIZE(family)) continue; if (prefixlen > FAMILY_ADDRESS_SIZE(family) * 8) continue; if (!strextend_with_separator(&addresses, " ", IN_ADDR_PREFIX_TO_STRING(family, ap, prefixlen))) return log_oom(); } r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, addresses); return 1; } else if (STR_IN_SET(name, "BindPaths", "BindReadOnlyPaths")) { _cleanup_free_ char *paths = NULL; const char *source, *dest; int ignore_enoent; uint64_t rbind; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ssbt)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ssbt)", &source, &dest, &ignore_enoent, &rbind)) > 0) { _cleanup_free_ char *str = NULL; if (isempty(source)) continue; if (asprintf(&str, "%s%s%s%s%s", ignore_enoent ? "-" : "", source, isempty(dest) ? "" : ":", strempty(dest), rbind == MS_REC ? ":rbind" : "") < 0) return log_oom(); if (!strextend_with_separator(&paths, " ", str)) return log_oom(); } if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, paths); return 1; } else if (streq(name, "TemporaryFileSystem")) { _cleanup_free_ char *paths = NULL; const char *target, *option; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &target, &option)) > 0) { _cleanup_free_ char *str = NULL; if (isempty(target)) continue; if (asprintf(&str, "%s%s%s", target, isempty(option) ? "" : ":", strempty(option)) < 0) return log_oom(); if (!strextend_with_separator(&paths, " ", str)) return log_oom(); } if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, paths); return 1; } else if (streq(name, "LogExtraFields")) { _cleanup_free_ char *fields = NULL; const void *p; size_t sz; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "ay"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read_array(m, 'y', &p, &sz)) > 0) { _cleanup_free_ char *str = NULL; const char *eq; if (memchr(p, 0, sz)) continue; eq = memchr(p, '=', sz); if (!eq) continue; if (!journal_field_valid(p, eq - (const char*) p, false)) continue; str = malloc(sz + 1); if (!str) return log_oom(); memcpy(str, p, sz); str[sz] = '\0'; if (!utf8_is_valid(str)) continue; if (!strextend_with_separator(&fields, " ", str)) return log_oom(); } if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, fields); return 1; } else if (contents[0] == SD_BUS_TYPE_BYTE && STR_IN_SET(name, "CPUAffinity", "NUMAMask", "AllowedCPUs", "AllowedMemoryNodes", "EffectiveCPUs", "EffectiveMemoryNodes")) { _cleanup_free_ char *affinity = NULL; _cleanup_(cpu_set_reset) CPUSet set = {}; const void *a; size_t n; r = sd_bus_message_read_array(m, 'y', &a, &n); if (r < 0) return bus_log_parse_error(r); r = cpu_set_from_dbus(a, n, &set); if (r < 0) return log_error_errno(r, "Failed to deserialize %s: %m", name); affinity = cpu_set_to_range_string(&set); if (!affinity) return log_oom(); bus_print_property_value(name, expected_value, flags, affinity); return 1; } else if (streq(name, "LogFilterPatterns")) { int is_allowlist; const char *pattern; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(bs)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(bs)", &is_allowlist, &pattern)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s%s", is_allowlist ? "" : "~", pattern); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (streq(name, "MountImages")) { _cleanup_free_ char *paths = NULL; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ssba(ss))"); if (r < 0) return bus_log_parse_error(r); for (;;) { _cleanup_free_ char *str = NULL; const char *source, *destination, *partition, *mount_options; int ignore_enoent; r = sd_bus_message_enter_container(m, 'r', "ssba(ss)"); if (r < 0) return bus_log_parse_error(r); if (r == 0) break; r = sd_bus_message_read(m, "ssb", &source, &destination, &ignore_enoent); if (r < 0) return bus_log_parse_error(r); str = strjoin(ignore_enoent ? "-" : "", source, ":", destination); if (!str) return log_oom(); r = sd_bus_message_enter_container(m, 'a', "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &partition, &mount_options)) > 0) if (!strextend_with_separator(&str, ":", partition, mount_options)) return log_oom(); if (r < 0) return bus_log_parse_error(r); if (!strextend_with_separator(&paths, " ", str)) return log_oom(); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); } r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, paths); return 1; } else if (streq(name, "ExtensionImages")) { _cleanup_free_ char *paths = NULL; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sba(ss))"); if (r < 0) return bus_log_parse_error(r); for (;;) { _cleanup_free_ char *str = NULL; const char *source, *partition, *mount_options; int ignore_enoent; r = sd_bus_message_enter_container(m, 'r', "sba(ss)"); if (r < 0) return bus_log_parse_error(r); if (r == 0) break; r = sd_bus_message_read(m, "sb", &source, &ignore_enoent); if (r < 0) return bus_log_parse_error(r); str = strjoin(ignore_enoent ? "-" : "", source); if (!str) return log_oom(); r = sd_bus_message_enter_container(m, 'a', "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &partition, &mount_options)) > 0) if (!strextend_with_separator(&str, ":", partition, mount_options)) return log_oom(); if (r < 0) return bus_log_parse_error(r); if (!strextend_with_separator(&paths, " ", str)) return log_oom(); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); } r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); bus_print_property_value(name, expected_value, flags, paths); return 1; } else if (streq(name, "BPFProgram")) { const char *a, *p; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(ss)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(ss)", &a, &p)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s:%s", a, p); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (STR_IN_SET(name, "SocketBindAllow", "SocketBindDeny")) { uint16_t nr_ports, port_min; int32_t af, ip_protocol; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(iiqq)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(iiqq)", &af, &ip_protocol, &nr_ports, &port_min)) > 0) { const char *family, *colon1, *protocol = "", *colon2 = ""; family = strempty(af_to_ipv4_ipv6(af)); colon1 = isempty(family) ? "" : ":"; if (ip_protocol != 0) { protocol = ip_protocol_to_tcp_udp(ip_protocol); colon2 = ""; } if (nr_ports == 0) bus_print_property_valuef(name, expected_value, flags, "%s%s%s%sany", family, colon1, protocol, colon2); else if (nr_ports == 1) bus_print_property_valuef( name, expected_value, flags, "%s%s%s%s%hu", family, colon1, protocol, colon2, port_min); else bus_print_property_valuef( name, expected_value, flags, "%s%s%s%s%hu-%hu", family, colon1, protocol, colon2, port_min, (uint16_t) (port_min + nr_ports - 1)); } if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (STR_IN_SET(name, "StateDirectorySymlink", "RuntimeDirectorySymlink", "CacheDirectorySymlink", "LogsDirectorySymlink")) { const char *a, *p; uint64_t symlink_flags; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sst)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(sst)", &a, &p, &symlink_flags)) > 0) bus_print_property_valuef(name, expected_value, flags, "%s:%s", a, p); if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } else if (contents[0] == SD_BUS_TYPE_STRUCT_BEGIN && streq(name, "OpenFile")) { char *path, *fdname; uint64_t offlags; r = sd_bus_message_enter_container(m, SD_BUS_TYPE_ARRAY, "(sst)"); if (r < 0) return bus_log_parse_error(r); while ((r = sd_bus_message_read(m, "(sst)", &path, &fdname, &offlags)) > 0) { _cleanup_free_ char *ofs = NULL; r = open_file_to_string( &(OpenFile){ .path = path, .fdname = fdname, .flags = offlags, }, &ofs); if (r < 0) return log_error_errno( r, "Failed to convert OpenFile= value to string: %m"); bus_print_property_value(name, expected_value, flags, ofs); } if (r < 0) return bus_log_parse_error(r); r = sd_bus_message_exit_container(m); if (r < 0) return bus_log_parse_error(r); return 1; } break; } return 0; } typedef enum SystemctlShowMode{ SYSTEMCTL_SHOW_PROPERTIES, SYSTEMCTL_SHOW_STATUS, SYSTEMCTL_SHOW_HELP, _SYSTEMCTL_SHOW_MODE_MAX, _SYSTEMCTL_SHOW_MODE_INVALID = -EINVAL, } SystemctlShowMode; static const char* const systemctl_show_mode_table[_SYSTEMCTL_SHOW_MODE_MAX] = { [SYSTEMCTL_SHOW_PROPERTIES] = "show", [SYSTEMCTL_SHOW_STATUS] = "status", [SYSTEMCTL_SHOW_HELP] = "help", }; DEFINE_PRIVATE_STRING_TABLE_LOOKUP_FROM_STRING(systemctl_show_mode, SystemctlShowMode); static int show_one( sd_bus *bus, const char *path, const char *unit, SystemctlShowMode show_mode, bool *new_line, bool *ellipsized) { static const struct bus_properties_map property_map[] = { { "Id", "s", NULL, offsetof(UnitStatusInfo, id) }, { "LoadState", "s", NULL, offsetof(UnitStatusInfo, load_state) }, { "ActiveState", "s", NULL, offsetof(UnitStatusInfo, active_state) }, { "FreezerState", "s", NULL, offsetof(UnitStatusInfo, freezer_state) }, { "Documentation", "as", NULL, offsetof(UnitStatusInfo, documentation) }, {} }, status_map[] = { { "Id", "s", NULL, offsetof(UnitStatusInfo, id) }, { "LoadState", "s", NULL, offsetof(UnitStatusInfo, load_state) }, { "ActiveState", "s", NULL, offsetof(UnitStatusInfo, active_state) }, { "FreezerState", "s", NULL, offsetof(UnitStatusInfo, freezer_state) }, { "SubState", "s", NULL, offsetof(UnitStatusInfo, sub_state) }, { "UnitFileState", "s", NULL, offsetof(UnitStatusInfo, unit_file_state) }, { "UnitFilePreset", "s", NULL, offsetof(UnitStatusInfo, unit_file_preset) }, { "Description", "s", NULL, offsetof(UnitStatusInfo, description) }, { "Following", "s", NULL, offsetof(UnitStatusInfo, following) }, { "Documentation", "as", NULL, offsetof(UnitStatusInfo, documentation) }, { "FragmentPath", "s", NULL, offsetof(UnitStatusInfo, fragment_path) }, { "SourcePath", "s", NULL, offsetof(UnitStatusInfo, source_path) }, { "ControlGroup", "s", NULL, offsetof(UnitStatusInfo, control_group) }, { "DropInPaths", "as", NULL, offsetof(UnitStatusInfo, dropin_paths) }, { "LoadError", "(ss)", map_load_error, offsetof(UnitStatusInfo, load_error) }, { "Result", "s", NULL, offsetof(UnitStatusInfo, result) }, { "TriggeredBy", "as", NULL, offsetof(UnitStatusInfo, triggered_by) }, { "Triggers", "as", NULL, offsetof(UnitStatusInfo, triggers) }, { "InactiveExitTimestamp", "t", NULL, offsetof(UnitStatusInfo, inactive_exit_timestamp) }, { "InactiveExitTimestampMonotonic", "t", NULL, offsetof(UnitStatusInfo, inactive_exit_timestamp_monotonic) }, { "ActiveEnterTimestamp", "t", NULL, offsetof(UnitStatusInfo, active_enter_timestamp) }, { "ActiveExitTimestamp", "t", NULL, offsetof(UnitStatusInfo, active_exit_timestamp) }, { "InactiveEnterTimestamp", "t", NULL, offsetof(UnitStatusInfo, inactive_enter_timestamp) }, { "RuntimeMaxUSec", "t", NULL, offsetof(UnitStatusInfo, runtime_max_sec) }, { "InvocationID", "s", bus_map_id128, offsetof(UnitStatusInfo, invocation_id) }, { "NeedDaemonReload", "b", NULL, offsetof(UnitStatusInfo, need_daemon_reload) }, { "Transient", "b", NULL, offsetof(UnitStatusInfo, transient) }, { "ExecMainPID", "u", NULL, offsetof(UnitStatusInfo, main_pid) }, { "MainPID", "u", map_main_pid, 0 }, { "ControlPID", "u", NULL, offsetof(UnitStatusInfo, control_pid) }, { "StatusText", "s", NULL, offsetof(UnitStatusInfo, status_text) }, { "PIDFile", "s", NULL, offsetof(UnitStatusInfo, pid_file) }, { "StatusErrno", "i", NULL, offsetof(UnitStatusInfo, status_errno) }, { "FileDescriptorStoreMax", "u", NULL, offsetof(UnitStatusInfo, fd_store_max) }, { "NFileDescriptorStore", "u", NULL, offsetof(UnitStatusInfo, n_fd_store) }, { "ExecMainStartTimestamp", "t", NULL, offsetof(UnitStatusInfo, start_timestamp) }, { "ExecMainExitTimestamp", "t", NULL, offsetof(UnitStatusInfo, exit_timestamp) }, { "ExecMainCode", "i", NULL, offsetof(UnitStatusInfo, exit_code) }, { "ExecMainStatus", "i", NULL, offsetof(UnitStatusInfo, exit_status) }, { "LogNamespace", "s", NULL, offsetof(UnitStatusInfo, log_namespace) }, { "ConditionTimestamp", "t", NULL, offsetof(UnitStatusInfo, condition_timestamp) }, { "ConditionResult", "b", NULL, offsetof(UnitStatusInfo, condition_result) }, { "Conditions", "a(sbbsi)", map_conditions, 0 }, { "AssertTimestamp", "t", NULL, offsetof(UnitStatusInfo, assert_timestamp) }, { "AssertResult", "b", NULL, offsetof(UnitStatusInfo, assert_result) }, { "Asserts", "a(sbbsi)", map_asserts, 0 }, { "NextElapseUSecRealtime", "t", NULL, offsetof(UnitStatusInfo, next_elapse_real) }, { "NextElapseUSecMonotonic", "t", NULL, offsetof(UnitStatusInfo, next_elapse_monotonic) }, { "NAccepted", "u", NULL, offsetof(UnitStatusInfo, n_accepted) }, { "NConnections", "u", NULL, offsetof(UnitStatusInfo, n_connections) }, { "NRefused", "u", NULL, offsetof(UnitStatusInfo, n_refused) }, { "Accept", "b", NULL, offsetof(UnitStatusInfo, accept) }, { "Listen", "a(ss)", map_listen, offsetof(UnitStatusInfo, listen) }, { "SysFSPath", "s", NULL, offsetof(UnitStatusInfo, sysfs_path) }, { "Where", "s", NULL, offsetof(UnitStatusInfo, where) }, { "What", "s", NULL, offsetof(UnitStatusInfo, what) }, { "MemoryCurrent", "t", NULL, offsetof(UnitStatusInfo, memory_current) }, { "MemoryPeak", "t", NULL, offsetof(UnitStatusInfo, memory_peak) }, { "MemorySwapCurrent", "t", NULL, offsetof(UnitStatusInfo, memory_swap_current) }, { "MemorySwapPeak", "t", NULL, offsetof(UnitStatusInfo, memory_swap_peak) }, { "MemoryZSwapCurrent", "t", NULL, offsetof(UnitStatusInfo, memory_zswap_current) }, { "MemoryAvailable", "t", NULL, offsetof(UnitStatusInfo, memory_available) }, { "DefaultMemoryMin", "t", NULL, offsetof(UnitStatusInfo, default_memory_min) }, { "DefaultMemoryLow", "t", NULL, offsetof(UnitStatusInfo, default_memory_low) }, { "DefaultStartupMemoryLow", "t", NULL, offsetof(UnitStatusInfo, default_startup_memory_low) }, { "MemoryMin", "t", NULL, offsetof(UnitStatusInfo, memory_min) }, { "MemoryLow", "t", NULL, offsetof(UnitStatusInfo, memory_low) }, { "StartupMemoryLow", "t", NULL, offsetof(UnitStatusInfo, startup_memory_low) }, { "MemoryHigh", "t", NULL, offsetof(UnitStatusInfo, memory_high) }, { "StartupMemoryHigh", "t", NULL, offsetof(UnitStatusInfo, startup_memory_high) }, { "MemoryMax", "t", NULL, offsetof(UnitStatusInfo, memory_max) }, { "StartupMemoryMax", "t", NULL, offsetof(UnitStatusInfo, startup_memory_max) }, { "MemorySwapMax", "t", NULL, offsetof(UnitStatusInfo, memory_swap_max) }, { "StartupMemorySwapMax", "t", NULL, offsetof(UnitStatusInfo, startup_memory_swap_max) }, { "MemoryZSwapMax", "t", NULL, offsetof(UnitStatusInfo, memory_zswap_max) }, { "StartupMemoryZSwapMax", "t", NULL, offsetof(UnitStatusInfo, startup_memory_zswap_max) }, { "MemoryLimit", "t", NULL, offsetof(UnitStatusInfo, memory_limit) }, { "CPUUsageNSec", "t", NULL, offsetof(UnitStatusInfo, cpu_usage_nsec) }, { "TasksCurrent", "t", NULL, offsetof(UnitStatusInfo, tasks_current) }, { "TasksMax", "t", NULL, offsetof(UnitStatusInfo, tasks_max) }, { "IPIngressBytes", "t", NULL, offsetof(UnitStatusInfo, ip_ingress_bytes) }, { "IPEgressBytes", "t", NULL, offsetof(UnitStatusInfo, ip_egress_bytes) }, { "IOReadBytes", "t", NULL, offsetof(UnitStatusInfo, io_read_bytes) }, { "IOWriteBytes", "t", NULL, offsetof(UnitStatusInfo, io_write_bytes) }, { "ExecCondition", "a(sasbttttuii)", map_exec, 0 }, { "ExecConditionEx", "a(sasasttttuii)", map_exec, 0 }, { "ExecStartPre", "a(sasbttttuii)", map_exec, 0 }, { "ExecStartPreEx", "a(sasasttttuii)", map_exec, 0 }, { "ExecStart", "a(sasbttttuii)", map_exec, 0 }, { "ExecStartEx", "a(sasasttttuii)", map_exec, 0 }, { "ExecStartPost", "a(sasbttttuii)", map_exec, 0 }, { "ExecStartPostEx", "a(sasasttttuii)", map_exec, 0 }, { "ExecReload", "a(sasbttttuii)", map_exec, 0 }, { "ExecReloadEx", "a(sasasttttuii)", map_exec, 0 }, { "ExecStopPre", "a(sasbttttuii)", map_exec, 0 }, { "ExecStop", "a(sasbttttuii)", map_exec, 0 }, { "ExecStopEx", "a(sasasttttuii)", map_exec, 0 }, { "ExecStopPost", "a(sasbttttuii)", map_exec, 0 }, { "ExecStopPostEx", "a(sasasttttuii)", map_exec, 0 }, {} }; _cleanup_(sd_bus_message_unrefp) sd_bus_message *reply = NULL; _cleanup_(sd_bus_error_free) sd_bus_error error = SD_BUS_ERROR_NULL; _cleanup_set_free_ Set *found_properties = NULL; _cleanup_(unit_status_info_done) UnitStatusInfo info = { .runtime_max_sec = USEC_INFINITY, .memory_current = UINT64_MAX, .memory_high = CGROUP_LIMIT_MAX, .startup_memory_high = CGROUP_LIMIT_MAX, .memory_max = CGROUP_LIMIT_MAX, .startup_memory_max = CGROUP_LIMIT_MAX, .memory_swap_max = CGROUP_LIMIT_MAX, .startup_memory_swap_max = CGROUP_LIMIT_MAX, .memory_zswap_max = CGROUP_LIMIT_MAX, .startup_memory_zswap_max = CGROUP_LIMIT_MAX, .memory_limit = CGROUP_LIMIT_MAX, .memory_peak = CGROUP_LIMIT_MAX, .memory_swap_current = CGROUP_LIMIT_MAX, .memory_swap_peak = CGROUP_LIMIT_MAX, .memory_zswap_current = CGROUP_LIMIT_MAX, .memory_available = CGROUP_LIMIT_MAX, .cpu_usage_nsec = UINT64_MAX, .tasks_current = UINT64_MAX, .tasks_max = UINT64_MAX, .ip_ingress_bytes = UINT64_MAX, .ip_egress_bytes = UINT64_MAX, .io_read_bytes = UINT64_MAX, .io_write_bytes = UINT64_MAX, }; int r; assert(path); assert(new_line); log_debug("Showing one %s", path); r = bus_map_all_properties( bus, "org.freedesktop.systemd1", path, show_mode == SYSTEMCTL_SHOW_STATUS ? status_map : property_map, BUS_MAP_BOOLEAN_AS_BOOL, &error, &reply, &info); if (r < 0) return log_error_errno(r, "Failed to get properties: %s", bus_error_message(&error, r)); if (unit && streq_ptr(info.load_state, "not-found") && streq_ptr(info.active_state, "inactive")) { log_full(show_mode == SYSTEMCTL_SHOW_PROPERTIES ? LOG_DEBUG : LOG_ERR, "Unit %s could not be found.", unit); if (show_mode == SYSTEMCTL_SHOW_STATUS) return EXIT_PROGRAM_OR_SERVICES_STATUS_UNKNOWN; if (show_mode == SYSTEMCTL_SHOW_HELP) return -ENOENT; } if (*new_line) printf("\n"); *new_line = true; if (show_mode == SYSTEMCTL_SHOW_STATUS) { print_status_info(bus, &info, ellipsized); if (info.active_state && !STR_IN_SET(info.active_state, "active", "reloading")) return EXIT_PROGRAM_NOT_RUNNING; return EXIT_PROGRAM_RUNNING_OR_SERVICE_OK; } else if (show_mode == SYSTEMCTL_SHOW_HELP) { show_unit_help(&info); return 0; } r = sd_bus_message_rewind(reply, true); if (r < 0) return log_error_errno(r, "Failed to rewind: %s", bus_error_message(&error, r)); r = bus_message_print_all_properties(reply, print_property, arg_properties, arg_print_flags, &found_properties); if (r < 0) return bus_log_parse_error(r); STRV_FOREACH(pp, arg_properties) if (!set_contains(found_properties, *pp)) log_debug("Property %s does not exist.", *pp); return 0; } static int show_all( sd_bus *bus, SystemctlShowMode show_mode, bool *new_line, bool *ellipsized) { _cleanup_(sd_bus_message_unrefp) sd_bus_message *reply = NULL; _cleanup_free_ UnitInfo *unit_infos = NULL; unsigned c; int r, ret = 0; r = get_unit_list(bus, NULL, NULL, &unit_infos, 0, &reply); if (r < 0) return r; pager_open(arg_pager_flags); c = (unsigned) r; typesafe_qsort(unit_infos, c, unit_info_compare); for (const UnitInfo *u = unit_infos; u < unit_infos + c; u++) { _cleanup_free_ char *p = NULL; p = unit_dbus_path_from_name(u->id); if (!p) return log_oom(); r = show_one(bus, p, u->id, show_mode, new_line, ellipsized); if (r < 0) return r; if (r > 0 && ret == 0) ret = r; } return ret; } static int show_system_status(sd_bus *bus) { _cleanup_(sd_bus_error_free) sd_bus_error error = SD_BUS_ERROR_NULL; _cleanup_(machine_info_clear) struct machine_info mi = {}; static const char prefix[] = " "; _cleanup_free_ char *hn = NULL; const char *on, *off; unsigned c; int r; hn = gethostname_malloc(); if (!hn) return log_oom(); r = bus_map_all_properties( bus, "org.freedesktop.systemd1", "/org/freedesktop/systemd1", machine_info_property_map, BUS_MAP_STRDUP, &error, NULL, &mi); if (r < 0) return log_error_errno(r, "Failed to read server status: %s", bus_error_message(&error, r)); if (streq_ptr(mi.state, "degraded")) { on = ansi_highlight_red(); off = ansi_normal(); } else if (streq_ptr(mi.state, "running")) { on = ansi_highlight_green(); off = ansi_normal(); } else { on = ansi_highlight_yellow(); off = ansi_normal(); } printf("%s%s%s %s\n", on, special_glyph(SPECIAL_GLYPH_BLACK_CIRCLE), off, arg_host ?: hn); printf(" State: %s%s%s\n", on, strna(mi.state), off); printf(" Units: %" PRIu32 " loaded (incl. loaded aliases)\n", mi.n_names); printf(" Jobs: %" PRIu32 " queued\n", mi.n_jobs); printf(" Failed: %" PRIu32 " units\n", mi.n_failed_units); printf(" Since: %s; %s\n", FORMAT_TIMESTAMP_STYLE(mi.timestamp, arg_timestamp_style), FORMAT_TIMESTAMP_RELATIVE(mi.timestamp)); printf(" systemd: %s\n", mi.version); if (!isempty(mi.tainted)) printf(" Tainted: %s%s%s\n", ansi_highlight_yellow(), mi.tainted, ansi_normal()); printf(" CGroup: %s\n", empty_to_root(mi.control_group)); c = LESS_BY(columns(), strlen(prefix)); r = unit_show_processes(bus, SPECIAL_ROOT_SLICE, mi.control_group, prefix, c, get_output_flags(), &error); if (r == -EBADR && arg_transport == BUS_TRANSPORT_LOCAL) /* Compatibility for really old systemd versions */ show_cgroup(SYSTEMD_CGROUP_CONTROLLER, strempty(mi.control_group), prefix, c, get_output_flags()); else if (r < 0) log_warning_errno(r, "Failed to dump process list for '%s', ignoring: %s", arg_host ?: hn, bus_error_message(&error, r)); return 0; } int verb_show(int argc, char *argv[], void *userdata) { bool new_line = false, ellipsized = false; SystemctlShowMode show_mode; int r, ret = 0; sd_bus *bus; assert(argv); show_mode = systemctl_show_mode_from_string(argv[0]); if (show_mode < 0) return log_error_errno(show_mode, "Invalid argument '%s'.", argv[0]); if (show_mode == SYSTEMCTL_SHOW_HELP && argc <= 1) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "'help' command expects one or more unit names.\n" "(Alternatively, help for systemctl itself may be shown with --help)"); r = acquire_bus(BUS_MANAGER, &bus); if (r < 0) return r; pager_open(arg_pager_flags); if (argc <= 1) { /* If no argument or filter is specified inspect the manager itself: * systemctl status → we show status of the manager * systemctl status --all → status of the manager + status of all units * systemctl status --state=… → status of units in listed states * systemctl status --type=… → status of units of listed types * systemctl status --failed → status of failed units, mirroring systemctl list-units --failed */ if (!arg_states && !arg_types) { if (show_mode == SYSTEMCTL_SHOW_PROPERTIES) /* systemctl show --all → show properties of the manager */ return show_one(bus, "/org/freedesktop/systemd1", NULL, show_mode, &new_line, &ellipsized); r = show_system_status(bus); if (r < 0) return r; new_line = true; } if (arg_all || arg_states || arg_types) ret = show_all(bus, show_mode, &new_line, &ellipsized); } else { _cleanup_free_ char **patterns = NULL; STRV_FOREACH(name, strv_skip(argv, 1)) { _cleanup_free_ char *path = NULL, *unit = NULL; uint32_t id; if (safe_atou32(*name, &id) < 0) { if (strv_push(&patterns, *name) < 0) return log_oom(); continue; } else if (show_mode == SYSTEMCTL_SHOW_PROPERTIES) { /* Interpret as job id */ if (asprintf(&path, "/org/freedesktop/systemd1/job/%u", id) < 0) return log_oom(); } else { /* Interpret as PID */ r = lookup_unit_by_pidref(bus, (pid_t) id, &unit, &path); if (r < 0) { RET_GATHER(ret, r); continue; } } r = show_one(bus, path, unit, show_mode, &new_line, &ellipsized); if (r < 0) return r; if (r > 0 && ret == 0) ret = r; } if (!strv_isempty(patterns)) { _cleanup_strv_free_ char **names = NULL; r = expand_unit_names(bus, patterns, NULL, &names, NULL); if (r < 0) return log_error_errno(r, "Failed to expand names: %m"); r = maybe_extend_with_unit_dependencies(bus, &names); if (r < 0) return r; STRV_FOREACH(name, names) { _cleanup_free_ char *path = NULL; path = unit_dbus_path_from_name(*name); if (!path) return log_oom(); r = show_one(bus, path, *name, show_mode, &new_line, &ellipsized); if (r < 0) return r; if (r > 0 && ret == 0) ret = r; } } } if (ellipsized && !arg_quiet) printf("Hint: Some lines were ellipsized, use -l to show in full.\n"); return ret; }