/* * lsns(8) - list system namespaces * * Copyright (C) 2015 Karel Zak * * This program 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. * * This program is distributed in the hope that it would 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 this program; if not, write to the Free Software Foundation, * Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include #include #include #include #include #include #include #include #include #include #include #include #ifdef HAVE_LINUX_NET_NAMESPACE_H #include #include #include #include #include #endif #include "pathnames.h" #include "nls.h" #include "xalloc.h" #include "c.h" #include "list.h" #include "closestream.h" #include "optutils.h" #include "procutils.h" #include "strutils.h" #include "namespace.h" #include "idcache.h" #include "debug.h" static UL_DEBUG_DEFINE_MASK(lsns); UL_DEBUG_DEFINE_MASKNAMES(lsns) = UL_DEBUG_EMPTY_MASKNAMES; #define LSNS_DEBUG_INIT (1 << 1) #define LSNS_DEBUG_PROC (1 << 2) #define LSNS_DEBUG_NS (1 << 3) #define LSNS_DEBUG_ALL 0xFFFF #define LSNS_NETNS_UNUSABLE -2 #define DBG(m, x) __UL_DBG(lsns, LSNS_DEBUG_, m, x) #define ON_DBG(m, x) __UL_DBG_CALL(lsns, LSNS_DEBUG_, m, x) #define UL_DEBUG_CURRENT_MASK UL_DEBUG_MASK(lsns) #include "debugobj.h" static struct idcache *uid_cache = NULL; /* column IDs */ enum { COL_NS = 0, COL_TYPE, COL_PATH, COL_NPROCS, COL_PID, COL_PPID, COL_COMMAND, COL_UID, COL_USER, COL_NETNSID, COL_NSFS, }; /* column names */ struct colinfo { const char *name; /* header */ double whint; /* width hint (N < 1 is in percent of termwidth) */ int flags; /* SCOLS_FL_* */ const char *help; int json_type; }; /* columns descriptions */ static const struct colinfo infos[] = { [COL_NS] = { "NS", 10, SCOLS_FL_RIGHT, N_("namespace identifier (inode number)"), SCOLS_JSON_NUMBER }, [COL_TYPE] = { "TYPE", 5, 0, N_("kind of namespace") }, [COL_PATH] = { "PATH", 0, 0, N_("path to the namespace")}, [COL_NPROCS] = { "NPROCS", 5, SCOLS_FL_RIGHT, N_("number of processes in the namespace"), SCOLS_JSON_NUMBER }, [COL_PID] = { "PID", 5, SCOLS_FL_RIGHT, N_("lowest PID in the namespace"), SCOLS_JSON_NUMBER }, [COL_PPID] = { "PPID", 5, SCOLS_FL_RIGHT, N_("PPID of the PID"), SCOLS_JSON_NUMBER }, [COL_COMMAND] = { "COMMAND", 0, SCOLS_FL_TRUNC, N_("command line of the PID")}, [COL_UID] = { "UID", 0, SCOLS_FL_RIGHT, N_("UID of the PID"), SCOLS_JSON_NUMBER}, [COL_USER] = { "USER", 0, 0, N_("username of the PID")}, [COL_NETNSID] = { "NETNSID", 0, SCOLS_FL_RIGHT, N_("namespace ID as used by network subsystem")}, [COL_NSFS] = { "NSFS", 0, SCOLS_FL_WRAP, N_("nsfs mountpoint (usually used network subsystem)")} }; static int columns[ARRAY_SIZE(infos) * 2]; static size_t ncolumns; enum { LSNS_ID_MNT = 0, LSNS_ID_NET, LSNS_ID_PID, LSNS_ID_UTS, LSNS_ID_IPC, LSNS_ID_USER, LSNS_ID_CGROUP }; static char *ns_names[] = { [LSNS_ID_MNT] = "mnt", [LSNS_ID_NET] = "net", [LSNS_ID_PID] = "pid", [LSNS_ID_UTS] = "uts", [LSNS_ID_IPC] = "ipc", [LSNS_ID_USER] = "user", [LSNS_ID_CGROUP] = "cgroup" }; struct lsns_namespace { ino_t id; int type; /* LSNS_* */ int nprocs; int netnsid; struct lsns_process *proc; struct list_head namespaces; /* lsns->processes member */ struct list_head processes; /* head of lsns_process *siblings */ }; struct lsns_process { pid_t pid; /* process PID */ pid_t ppid; /* parent's PID */ pid_t tpid; /* thread group */ char state; uid_t uid; ino_t ns_ids[ARRAY_SIZE(ns_names)]; struct list_head ns_siblings[ARRAY_SIZE(ns_names)]; struct list_head processes; /* list of processes */ struct libscols_line *outline; struct lsns_process *parent; int netnsid; }; struct lsns { struct list_head processes; struct list_head namespaces; pid_t fltr_pid; /* filter out by PID */ ino_t fltr_ns; /* filter out by namespace */ int fltr_types[ARRAY_SIZE(ns_names)]; int fltr_ntypes; unsigned int raw : 1, json : 1, tree : 1, list : 1, no_trunc : 1, no_headings: 1, no_wrap : 1; struct libmnt_table *tab; }; struct netnsid_cache { ino_t ino; int id; struct list_head netnsids; }; static struct list_head netnsids_cache; static int netlink_fd = -1; static void lsns_init_debug(void) { __UL_INIT_DEBUG_FROM_ENV(lsns, LSNS_DEBUG_, 0, LSNS_DEBUG); } static int ns_name2type(const char *name) { size_t i; for (i = 0; i < ARRAY_SIZE(ns_names); i++) { if (strcmp(ns_names[i], name) == 0) return i; } return -1; } static int column_name_to_id(const char *name, size_t namesz) { size_t i; assert(name); for (i = 0; i < ARRAY_SIZE(infos); i++) { const char *cn = infos[i].name; if (!strncasecmp(name, cn, namesz) && !*(cn + namesz)) return i; } warnx(_("unknown column: %s"), name); return -1; } static int has_column(int id) { size_t i; for (i = 0; i < ncolumns; i++) { if (columns[i] == id) return 1; } return 0; } static inline int get_column_id(int num) { assert(num >= 0); assert((size_t) num < ncolumns); assert(columns[num] < (int) ARRAY_SIZE(infos)); return columns[num]; } static inline const struct colinfo *get_column_info(unsigned num) { return &infos[ get_column_id(num) ]; } static int get_ns_ino(int dir, const char *nsname, ino_t *ino) { struct stat st; char path[16]; snprintf(path, sizeof(path), "ns/%s", nsname); if (fstatat(dir, path, &st, 0) != 0) return -errno; *ino = st.st_ino; return 0; } static int parse_proc_stat(FILE *fp, pid_t *pid, char *state, pid_t *ppid) { char *line = NULL, *p; size_t len = 0; int rc; if (getline(&line, &len, fp) < 0) { rc = -errno; goto error; } p = strrchr(line, ')'); if (p == NULL || sscanf(line, "%d (", pid) != 1 || sscanf(p, ") %c %d*[^\n]", state, ppid) != 2) { rc = -EINVAL; goto error; } rc = 0; error: free(line); return rc; } #ifdef HAVE_LINUX_NET_NAMESPACE_H static int netnsid_cache_find(ino_t netino, int *netnsid) { struct list_head *p; list_for_each(p, &netnsids_cache) { struct netnsid_cache *e = list_entry(p, struct netnsid_cache, netnsids); if (e->ino == netino) { *netnsid = e->id; return 1; } } return 0; } static void netnsid_cache_add(ino_t netino, int netnsid) { struct netnsid_cache *e; e = xcalloc(1, sizeof(*e)); e->ino = netino; e->id = netnsid; INIT_LIST_HEAD(&e->netnsids); list_add(&e->netnsids, &netnsids_cache); } static int get_netnsid_via_netlink_send_request(int target_fd) { unsigned char req[NLMSG_SPACE(sizeof(struct rtgenmsg)) + RTA_SPACE(sizeof(int32_t))]; struct nlmsghdr *nlh = (struct nlmsghdr *)req; struct rtgenmsg *rt = NLMSG_DATA(req); struct rtattr *rta = (struct rtattr *) (req + NLMSG_SPACE(sizeof(struct rtgenmsg))); int32_t *fd = RTA_DATA(rta); nlh->nlmsg_len = sizeof(req); nlh->nlmsg_flags = NLM_F_REQUEST; nlh->nlmsg_type = RTM_GETNSID; rt->rtgen_family = AF_UNSPEC; rta->rta_type = NETNSA_FD; rta->rta_len = RTA_SPACE(sizeof(int32_t)); *fd = target_fd; if (send(netlink_fd, req, sizeof(req), 0) < 0) return -1; return 0; } static int get_netnsid_via_netlink_recv_response(int *netnsid) { unsigned char res[NLMSG_SPACE(sizeof(struct rtgenmsg)) + ((RTA_SPACE(sizeof(int32_t)) < RTA_SPACE(sizeof(struct nlmsgerr))) ? RTA_SPACE(sizeof(struct nlmsgerr)) : RTA_SPACE(sizeof(int32_t)))]; int rtalen; ssize_t reslen; struct nlmsghdr *nlh; struct rtattr *rta; reslen = recv(netlink_fd, res, sizeof(res), 0); if (reslen < 0) return -1; nlh = (struct nlmsghdr *)res; if (!(NLMSG_OK(nlh, (size_t)reslen) && nlh->nlmsg_type == RTM_NEWNSID)) return -1; rtalen = NLMSG_PAYLOAD(nlh, sizeof(struct rtgenmsg)); rta = (struct rtattr *)(res + NLMSG_SPACE(sizeof(struct rtgenmsg))); if (!(RTA_OK(rta, rtalen) && rta->rta_type == NETNSA_NSID)) return -1; *netnsid = *(int *)RTA_DATA(rta); return 0; } static int get_netnsid_via_netlink(int dir, const char *path) { int netnsid; int target_fd; if (netlink_fd < 0) return LSNS_NETNS_UNUSABLE; target_fd = openat(dir, path, O_RDONLY); if (target_fd < 0) return LSNS_NETNS_UNUSABLE; if (get_netnsid_via_netlink_send_request(target_fd) < 0) { netnsid = LSNS_NETNS_UNUSABLE; goto out; } if (get_netnsid_via_netlink_recv_response(&netnsid) < 0) { netnsid = LSNS_NETNS_UNUSABLE; goto out; } out: close(target_fd); return netnsid; } static int get_netnsid(int dir, ino_t netino) { int netnsid; if (!netnsid_cache_find(netino, &netnsid)) { netnsid = get_netnsid_via_netlink(dir, "ns/net"); netnsid_cache_add(netino, netnsid); } return netnsid; } #else static int get_netnsid(int dir __attribute__((__unused__)), ino_t netino __attribute__((__unused__))) { return LSNS_NETNS_UNUSABLE; } #endif /* HAVE_LINUX_NET_NAMESPACE_H */ static int read_process(struct lsns *ls, pid_t pid) { struct lsns_process *p = NULL; char buf[BUFSIZ]; DIR *dir; int rc = 0, fd; FILE *f = NULL; size_t i; struct stat st; DBG(PROC, ul_debug("reading %d", (int) pid)); snprintf(buf, sizeof(buf), "/proc/%d", pid); dir = opendir(buf); if (!dir) return -errno; p = xcalloc(1, sizeof(*p)); p->netnsid = LSNS_NETNS_UNUSABLE; if (fstat(dirfd(dir), &st) == 0) { p->uid = st.st_uid; add_uid(uid_cache, st.st_uid); } fd = openat(dirfd(dir), "stat", O_RDONLY); if (fd < 0) { rc = -errno; goto done; } if (!(f = fdopen(fd, "r"))) { rc = -errno; goto done; } rc = parse_proc_stat(f, &p->pid, &p->state, &p->ppid); if (rc < 0) goto done; rc = 0; for (i = 0; i < ARRAY_SIZE(p->ns_ids); i++) { INIT_LIST_HEAD(&p->ns_siblings[i]); if (!ls->fltr_types[i]) continue; rc = get_ns_ino(dirfd(dir), ns_names[i], &p->ns_ids[i]); if (rc && rc != -EACCES && rc != -ENOENT) goto done; if (i == LSNS_ID_NET) p->netnsid = get_netnsid(dirfd(dir), p->ns_ids[i]); rc = 0; } INIT_LIST_HEAD(&p->processes); DBG(PROC, ul_debugobj(p, "new pid=%d", p->pid)); list_add_tail(&p->processes, &ls->processes); done: if (f) fclose(f); closedir(dir); if (rc) free(p); return rc; } static int read_processes(struct lsns *ls) { struct proc_processes *proc = NULL; pid_t pid; int rc = 0; DBG(PROC, ul_debug("opening /proc")); if (!(proc = proc_open_processes())) { rc = -errno; goto done; } while (proc_next_pid(proc, &pid) == 0) { rc = read_process(ls, pid); if (rc && rc != -EACCES && rc != -ENOENT) break; rc = 0; } done: DBG(PROC, ul_debug("closing /proc")); proc_close_processes(proc); return rc; } static struct lsns_namespace *get_namespace(struct lsns *ls, ino_t ino) { struct list_head *p; list_for_each(p, &ls->namespaces) { struct lsns_namespace *ns = list_entry(p, struct lsns_namespace, namespaces); if (ns->id == ino) return ns; } return NULL; } static int namespace_has_process(struct lsns_namespace *ns, pid_t pid) { struct list_head *p; list_for_each(p, &ns->processes) { struct lsns_process *proc = list_entry(p, struct lsns_process, ns_siblings[ns->type]); if (proc->pid == pid) return 1; } return 0; } static struct lsns_namespace *add_namespace(struct lsns *ls, int type, ino_t ino) { struct lsns_namespace *ns = xcalloc(1, sizeof(*ns)); if (!ns) return NULL; DBG(NS, ul_debugobj(ns, "new %s[%ju]", ns_names[type], (uintmax_t)ino)); INIT_LIST_HEAD(&ns->processes); INIT_LIST_HEAD(&ns->namespaces); ns->type = type; ns->id = ino; list_add_tail(&ns->namespaces, &ls->namespaces); return ns; } static int add_process_to_namespace(struct lsns *ls, struct lsns_namespace *ns, struct lsns_process *proc) { struct list_head *p; DBG(NS, ul_debugobj(ns, "add process [%p] pid=%d to %s[%ju]", proc, proc->pid, ns_names[ns->type], (uintmax_t)ns->id)); list_for_each(p, &ls->processes) { struct lsns_process *xproc = list_entry(p, struct lsns_process, processes); if (xproc->pid == proc->ppid) /* my parent */ proc->parent = xproc; else if (xproc->ppid == proc->pid) /* my child */ xproc->parent = proc; } list_add_tail(&proc->ns_siblings[ns->type], &ns->processes); ns->nprocs++; if (!ns->proc || ns->proc->pid > proc->pid) ns->proc = proc; return 0; } static int cmp_namespaces(struct list_head *a, struct list_head *b, __attribute__((__unused__)) void *data) { struct lsns_namespace *xa = list_entry(a, struct lsns_namespace, namespaces), *xb = list_entry(b, struct lsns_namespace, namespaces); return cmp_numbers(xa->id, xb->id); } static int netnsid_xasputs(char **str, int netnsid) { if (netnsid >= 0) return xasprintf(str, "%d", netnsid); #ifdef NETNSA_NSID_NOT_ASSIGNED else if (netnsid == NETNSA_NSID_NOT_ASSIGNED) return xasprintf(str, "%s", "unassigned"); #endif else return 0; } static int read_namespaces(struct lsns *ls) { struct list_head *p; DBG(NS, ul_debug("reading namespace")); list_for_each(p, &ls->processes) { size_t i; struct lsns_namespace *ns; struct lsns_process *proc = list_entry(p, struct lsns_process, processes); for (i = 0; i < ARRAY_SIZE(proc->ns_ids); i++) { if (proc->ns_ids[i] == 0) continue; if (!(ns = get_namespace(ls, proc->ns_ids[i]))) { ns = add_namespace(ls, i, proc->ns_ids[i]); if (!ns) return -ENOMEM; } add_process_to_namespace(ls, ns, proc); } } list_sort(&ls->namespaces, cmp_namespaces, NULL); return 0; } static int is_nsfs_root(struct libmnt_fs *fs, void *data) { if (!mnt_fs_match_fstype(fs, "nsfs") || !mnt_fs_get_root(fs)) return 0; return (strcmp(mnt_fs_get_root(fs), (char *)data) == 0); } static int is_path_included(const char *path_set, const char *elt, const char sep) { size_t elt_len; size_t path_set_len; char *tmp; tmp = strstr(path_set, elt); if (!tmp) return 0; elt_len = strlen(elt); path_set_len = strlen(path_set); /* path_set includes only elt or * path_set includes elt as the first element. */ if (tmp == path_set && ((path_set_len == elt_len) || (path_set[elt_len] == sep))) return 1; /* path_set includes elt at the middle * or as the last element. */ if ((*(tmp - 1) == sep) && ((*(tmp + elt_len) == sep) || (*(tmp + elt_len) == '\0'))) return 1; return 0; } static int nsfs_xasputs(char **str, struct lsns_namespace *ns, struct libmnt_table *tab, char sep) { struct libmnt_iter *itr = mnt_new_iter(MNT_ITER_FORWARD); char *expected_root; struct libmnt_fs *fs = NULL; xasprintf(&expected_root, "%s:[%ju]", ns_names[ns->type], (uintmax_t)ns->id); *str = NULL; while (mnt_table_find_next_fs(tab, itr, is_nsfs_root, expected_root, &fs) == 0) { const char *tgt = mnt_fs_get_target(fs); if (!*str) xasprintf(str, "%s", tgt); else if (!is_path_included(*str, tgt, sep)) { char *tmp = NULL; xasprintf(&tmp, "%s%c%s", *str, sep, tgt); free(*str); *str = tmp; } } free(expected_root); mnt_free_iter(itr); return 1; } static void add_scols_line(struct lsns *ls, struct libscols_table *table, struct lsns_namespace *ns, struct lsns_process *proc) { size_t i; struct libscols_line *line; assert(ns); assert(table); line = scols_table_new_line(table, ls->tree && proc->parent ? proc->parent->outline : NULL); if (!line) { warn(_("failed to add line to output")); return; } for (i = 0; i < ncolumns; i++) { char *str = NULL; switch (get_column_id(i)) { case COL_NS: xasprintf(&str, "%ju", (uintmax_t)ns->id); break; case COL_PID: xasprintf(&str, "%d", (int) proc->pid); break; case COL_PPID: xasprintf(&str, "%d", (int) proc->ppid); break; case COL_TYPE: xasprintf(&str, "%s", ns_names[ns->type]); break; case COL_NPROCS: xasprintf(&str, "%d", ns->nprocs); break; case COL_COMMAND: str = proc_get_command(proc->pid); if (!str) str = proc_get_command_name(proc->pid); break; case COL_PATH: xasprintf(&str, "/proc/%d/ns/%s", (int) proc->pid, ns_names[ns->type]); break; case COL_UID: xasprintf(&str, "%d", (int) proc->uid); break; case COL_USER: xasprintf(&str, "%s", get_id(uid_cache, proc->uid)->name); break; case COL_NETNSID: if (ns->type == LSNS_ID_NET) netnsid_xasputs(&str, proc->netnsid); break; case COL_NSFS: nsfs_xasputs(&str, ns, ls->tab, ls->no_wrap ? ',' : '\n'); break; default: break; } if (str && scols_line_refer_data(line, i, str) != 0) err_oom(); } proc->outline = line; } static struct libscols_table *init_scols_table(struct lsns *ls) { struct libscols_table *tab; size_t i; tab = scols_new_table(); if (!tab) { warn(_("failed to initialize output table")); return NULL; } scols_table_enable_raw(tab, ls->raw); scols_table_enable_json(tab, ls->json); scols_table_enable_noheadings(tab, ls->no_headings); if (ls->json) scols_table_set_name(tab, "namespaces"); for (i = 0; i < ncolumns; i++) { const struct colinfo *col = get_column_info(i); int flags = col->flags; struct libscols_column *cl; if (ls->no_trunc) flags &= ~SCOLS_FL_TRUNC; if (ls->tree && get_column_id(i) == COL_COMMAND) flags |= SCOLS_FL_TREE; if (ls->no_wrap) flags &= ~SCOLS_FL_WRAP; cl = scols_table_new_column(tab, col->name, col->whint, flags); if (cl == NULL) { warnx(_("failed to initialize output column")); goto err; } if (ls->json) scols_column_set_json_type(cl, col->json_type); if (!ls->no_wrap && get_column_id(i) == COL_NSFS) { scols_column_set_wrapfunc(cl, scols_wrapnl_chunksize, scols_wrapnl_nextchunk, NULL); scols_column_set_safechars(cl, "\n"); } } return tab; err: scols_unref_table(tab); return NULL; } static int show_namespaces(struct lsns *ls) { struct libscols_table *tab; struct list_head *p; int rc = 0; tab = init_scols_table(ls); if (!tab) return -ENOMEM; list_for_each(p, &ls->namespaces) { struct lsns_namespace *ns = list_entry(p, struct lsns_namespace, namespaces); if (ls->fltr_pid != 0 && !namespace_has_process(ns, ls->fltr_pid)) continue; add_scols_line(ls, tab, ns, ns->proc); } scols_print_table(tab); scols_unref_table(tab); return rc; } static void show_process(struct lsns *ls, struct libscols_table *tab, struct lsns_process *proc, struct lsns_namespace *ns) { /* * create a tree from parent->child relation, but only if the parent is * within the same namespace */ if (ls->tree && proc->parent && !proc->parent->outline && proc->parent->ns_ids[ns->type] == proc->ns_ids[ns->type]) show_process(ls, tab, proc->parent, ns); add_scols_line(ls, tab, ns, proc); } static int show_namespace_processes(struct lsns *ls, struct lsns_namespace *ns) { struct libscols_table *tab; struct list_head *p; tab = init_scols_table(ls); if (!tab) return -ENOMEM; list_for_each(p, &ns->processes) { struct lsns_process *proc = list_entry(p, struct lsns_process, ns_siblings[ns->type]); if (!proc->outline) show_process(ls, tab, proc, ns); } scols_print_table(tab); scols_unref_table(tab); return 0; } static void __attribute__((__noreturn__)) usage(void) { FILE *out = stdout; size_t i; fputs(USAGE_HEADER, out); fprintf(out, _(" %s [options] []\n"), program_invocation_short_name); fputs(USAGE_SEPARATOR, out); fputs(_("List system namespaces.\n"), out); fputs(USAGE_OPTIONS, out); fputs(_(" -J, --json use JSON output format\n"), out); fputs(_(" -l, --list use list format output\n"), out); fputs(_(" -n, --noheadings don't print headings\n"), out); fputs(_(" -o, --output define which output columns to use\n"), out); fputs(_(" --output-all output all columns\n"), out); fputs(_(" -p, --task print process namespaces\n"), out); fputs(_(" -r, --raw use the raw output format\n"), out); fputs(_(" -u, --notruncate don't truncate text in columns\n"), out); fputs(_(" -W, --nowrap don't use multi-line representation\n"), out); fputs(_(" -t, --type namespace type (mnt, net, ipc, user, pid, uts, cgroup)\n"), out); fputs(USAGE_SEPARATOR, out); printf(USAGE_HELP_OPTIONS(24)); fputs(USAGE_COLUMNS, out); for (i = 0; i < ARRAY_SIZE(infos); i++) fprintf(out, " %11s %s\n", infos[i].name, _(infos[i].help)); printf(USAGE_MAN_TAIL("lsns(8)")); exit(EXIT_SUCCESS); } int main(int argc, char *argv[]) { struct lsns ls; int c; int r = 0; char *outarg = NULL; enum { OPT_OUTPUT_ALL = CHAR_MAX + 1 }; static const struct option long_opts[] = { { "json", no_argument, NULL, 'J' }, { "task", required_argument, NULL, 'p' }, { "help", no_argument, NULL, 'h' }, { "output", required_argument, NULL, 'o' }, { "output-all", no_argument, NULL, OPT_OUTPUT_ALL }, { "notruncate", no_argument, NULL, 'u' }, { "version", no_argument, NULL, 'V' }, { "noheadings", no_argument, NULL, 'n' }, { "nowrap", no_argument, NULL, 'W' }, { "list", no_argument, NULL, 'l' }, { "raw", no_argument, NULL, 'r' }, { "type", required_argument, NULL, 't' }, { NULL, 0, NULL, 0 } }; static const ul_excl_t excl[] = { /* rows and cols in ASCII order */ { 'J','r' }, { 0 } }; int excl_st[ARRAY_SIZE(excl)] = UL_EXCL_STATUS_INIT; int is_net = 0; setlocale(LC_ALL, ""); bindtextdomain(PACKAGE, LOCALEDIR); textdomain(PACKAGE); close_stdout_atexit(); lsns_init_debug(); memset(&ls, 0, sizeof(ls)); INIT_LIST_HEAD(&ls.processes); INIT_LIST_HEAD(&ls.namespaces); INIT_LIST_HEAD(&netnsids_cache); while ((c = getopt_long(argc, argv, "Jlp:o:nruhVt:W", long_opts, NULL)) != -1) { err_exclusive_options(c, long_opts, excl, excl_st); switch(c) { case 'J': ls.json = 1; break; case 'l': ls.list = 1; break; case 'o': outarg = optarg; break; case OPT_OUTPUT_ALL: for (ncolumns = 0; ncolumns < ARRAY_SIZE(infos); ncolumns++) columns[ncolumns] = ncolumns; break; case 'p': ls.fltr_pid = strtos32_or_err(optarg, _("invalid PID argument")); break; case 'n': ls.no_headings = 1; break; case 'r': ls.no_wrap = ls.raw = 1; break; case 'u': ls.no_trunc = 1; break; case 't': { int type = ns_name2type(optarg); if (type < 0) errx(EXIT_FAILURE, _("unknown namespace type: %s"), optarg); ls.fltr_types[type] = 1; ls.fltr_ntypes++; if (type == LSNS_ID_NET) is_net = 1; break; } case 'W': ls.no_wrap = 1; break; case 'h': usage(); case 'V': print_version(EXIT_SUCCESS); default: errtryhelp(EXIT_FAILURE); } } if (!ls.fltr_ntypes) { size_t i; for (i = 0; i < ARRAY_SIZE(ns_names); i++) ls.fltr_types[i] = 1; } if (optind < argc) { if (ls.fltr_pid) errx(EXIT_FAILURE, _("--task is mutually exclusive with ")); ls.fltr_ns = strtou64_or_err(argv[optind], _("invalid namespace argument")); ls.tree = ls.list ? 0 : 1; if (!ncolumns) { columns[ncolumns++] = COL_PID; columns[ncolumns++] = COL_PPID; columns[ncolumns++] = COL_USER; columns[ncolumns++] = COL_COMMAND; } } if (!ncolumns) { columns[ncolumns++] = COL_NS; columns[ncolumns++] = COL_TYPE; columns[ncolumns++] = COL_NPROCS; columns[ncolumns++] = COL_PID; columns[ncolumns++] = COL_USER; if (is_net) { columns[ncolumns++] = COL_NETNSID; columns[ncolumns++] = COL_NSFS; } columns[ncolumns++] = COL_COMMAND; } if (outarg && string_add_to_idarray(outarg, columns, ARRAY_SIZE(columns), &ncolumns, column_name_to_id) < 0) return EXIT_FAILURE; scols_init_debug(0); uid_cache = new_idcache(); if (!uid_cache) err(EXIT_FAILURE, _("failed to allocate UID cache")); #ifdef HAVE_LINUX_NET_NAMESPACE_H if (has_column(COL_NETNSID)) netlink_fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_ROUTE); #endif if (has_column(COL_NSFS)) { ls.tab = mnt_new_table_from_file(_PATH_PROC_MOUNTINFO); if (!ls.tab) err(MNT_EX_FAIL, _("failed to parse %s"), _PATH_PROC_MOUNTINFO); } r = read_processes(&ls); if (!r) r = read_namespaces(&ls); if (!r) { if (ls.fltr_ns) { struct lsns_namespace *ns = get_namespace(&ls, ls.fltr_ns); if (!ns) errx(EXIT_FAILURE, _("not found namespace: %ju"), (uintmax_t) ls.fltr_ns); r = show_namespace_processes(&ls, ns); } else r = show_namespaces(&ls); } mnt_free_table(ls.tab); if (netlink_fd >= 0) close(netlink_fd); free_idcache(uid_cache); return r == 0 ? EXIT_SUCCESS : EXIT_FAILURE; }