/*** 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 Lesser General Public License as published by the Free Software Foundation; either version 2.1 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with systemd; If not, see . ***/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "alloc-util.h" #include "cgroup-util.h" #include "def.h" #include "dirent-util.h" #include "extract-word.h" #include "fd-util.h" #include "fileio.h" #include "format-util.h" #include "fs-util.h" #include "log.h" #include "login-util.h" #include "macro.h" #include "missing.h" #include "mkdir.h" #include "parse-util.h" #include "path-util.h" #include "proc-cmdline.h" #include "process-util.h" #include "set.h" #include "special.h" #include "stat-util.h" #include "stdio-util.h" #include "string-table.h" #include "string-util.h" #include "unit-name.h" #include "user-util.h" int cg_enumerate_processes(const char *controller, const char *path, FILE **_f) { _cleanup_free_ char *fs = NULL; FILE *f; int r; assert(_f); r = cg_get_path(controller, path, "cgroup.procs", &fs); if (r < 0) return r; f = fopen(fs, "re"); if (!f) return -errno; *_f = f; return 0; } int cg_read_pid(FILE *f, pid_t *_pid) { unsigned long ul; /* Note that the cgroup.procs might contain duplicates! See * cgroups.txt for details. */ assert(f); assert(_pid); errno = 0; if (fscanf(f, "%lu", &ul) != 1) { if (feof(f)) return 0; return errno > 0 ? -errno : -EIO; } if (ul <= 0) return -EIO; *_pid = (pid_t) ul; return 1; } int cg_read_event(const char *controller, const char *path, const char *event, char **val) { _cleanup_free_ char *events = NULL, *content = NULL; char *p, *line; int r; r = cg_get_path(controller, path, "cgroup.events", &events); if (r < 0) return r; r = read_full_file(events, &content, NULL); if (r < 0) return r; p = content; while ((line = strsep(&p, "\n"))) { char *key; key = strsep(&line, " "); if (!key || !line) return -EINVAL; if (strcmp(key, event)) continue; *val = strdup(line); return 0; } return -ENOENT; } bool cg_ns_supported(void) { static thread_local int enabled = -1; if (enabled >= 0) return enabled; if (access("/proc/self/ns/cgroup", F_OK) == 0) enabled = 1; else enabled = 0; return enabled; } int cg_enumerate_subgroups(const char *controller, const char *path, DIR **_d) { _cleanup_free_ char *fs = NULL; int r; DIR *d; assert(_d); /* This is not recursive! */ r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; d = opendir(fs); if (!d) return -errno; *_d = d; return 0; } int cg_read_subgroup(DIR *d, char **fn) { struct dirent *de; assert(d); assert(fn); FOREACH_DIRENT_ALL(de, d, return -errno) { char *b; if (de->d_type != DT_DIR) continue; if (dot_or_dot_dot(de->d_name)) continue; b = strdup(de->d_name); if (!b) return -ENOMEM; *fn = b; return 1; } return 0; } int cg_rmdir(const char *controller, const char *path) { _cleanup_free_ char *p = NULL; int r; r = cg_get_path(controller, path, NULL, &p); if (r < 0) return r; r = rmdir(p); if (r < 0 && errno != ENOENT) return -errno; r = cg_hybrid_unified(); if (r < 0) return r; if (r == 0) return 0; if (streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { r = cg_rmdir(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path); if (r < 0) log_warning_errno(r, "Failed to remove compat systemd cgroup %s: %m", path); } return 0; } int cg_kill( const char *controller, const char *path, int sig, CGroupFlags flags, Set *s, cg_kill_log_func_t log_kill, void *userdata) { _cleanup_set_free_ Set *allocated_set = NULL; bool done = false; int r, ret = 0; pid_t my_pid; assert(sig >= 0); /* Don't send SIGCONT twice. Also, SIGKILL always works even when process is suspended, hence don't send * SIGCONT on SIGKILL. */ if (IN_SET(sig, SIGCONT, SIGKILL)) flags &= ~CGROUP_SIGCONT; /* This goes through the tasks list and kills them all. This * is repeated until no further processes are added to the * tasks list, to properly handle forking processes */ if (!s) { s = allocated_set = set_new(NULL); if (!s) return -ENOMEM; } my_pid = getpid(); do { _cleanup_fclose_ FILE *f = NULL; pid_t pid = 0; done = true; r = cg_enumerate_processes(controller, path, &f); if (r < 0) { if (ret >= 0 && r != -ENOENT) return r; return ret; } while ((r = cg_read_pid(f, &pid)) > 0) { if ((flags & CGROUP_IGNORE_SELF) && pid == my_pid) continue; if (set_get(s, PID_TO_PTR(pid)) == PID_TO_PTR(pid)) continue; if (log_kill) log_kill(pid, sig, userdata); /* If we haven't killed this process yet, kill * it */ if (kill(pid, sig) < 0) { if (ret >= 0 && errno != ESRCH) ret = -errno; } else { if (flags & CGROUP_SIGCONT) (void) kill(pid, SIGCONT); if (ret == 0) ret = 1; } done = false; r = set_put(s, PID_TO_PTR(pid)); if (r < 0) { if (ret >= 0) return r; return ret; } } if (r < 0) { if (ret >= 0) return r; return ret; } /* To avoid racing against processes which fork * quicker than we can kill them we repeat this until * no new pids need to be killed. */ } while (!done); return ret; } int cg_kill_recursive( const char *controller, const char *path, int sig, CGroupFlags flags, Set *s, cg_kill_log_func_t log_kill, void *userdata) { _cleanup_set_free_ Set *allocated_set = NULL; _cleanup_closedir_ DIR *d = NULL; int r, ret; char *fn; assert(path); assert(sig >= 0); if (!s) { s = allocated_set = set_new(NULL); if (!s) return -ENOMEM; } ret = cg_kill(controller, path, sig, flags, s, log_kill, userdata); r = cg_enumerate_subgroups(controller, path, &d); if (r < 0) { if (ret >= 0 && r != -ENOENT) return r; return ret; } while ((r = cg_read_subgroup(d, &fn)) > 0) { _cleanup_free_ char *p = NULL; p = strjoin(path, "/", fn); free(fn); if (!p) return -ENOMEM; r = cg_kill_recursive(controller, p, sig, flags, s, log_kill, userdata); if (r != 0 && ret >= 0) ret = r; } if (ret >= 0 && r < 0) ret = r; if (flags & CGROUP_REMOVE) { r = cg_rmdir(controller, path); if (r < 0 && ret >= 0 && r != -ENOENT && r != -EBUSY) return r; } return ret; } int cg_migrate( const char *cfrom, const char *pfrom, const char *cto, const char *pto, CGroupFlags flags) { bool done = false; _cleanup_set_free_ Set *s = NULL; int r, ret = 0; pid_t my_pid; assert(cfrom); assert(pfrom); assert(cto); assert(pto); s = set_new(NULL); if (!s) return -ENOMEM; my_pid = getpid(); do { _cleanup_fclose_ FILE *f = NULL; pid_t pid = 0; done = true; r = cg_enumerate_processes(cfrom, pfrom, &f); if (r < 0) { if (ret >= 0 && r != -ENOENT) return r; return ret; } while ((r = cg_read_pid(f, &pid)) > 0) { /* This might do weird stuff if we aren't a * single-threaded program. However, we * luckily know we are not */ if ((flags & CGROUP_IGNORE_SELF) && pid == my_pid) continue; if (set_get(s, PID_TO_PTR(pid)) == PID_TO_PTR(pid)) continue; /* Ignore kernel threads. Since they can only * exist in the root cgroup, we only check for * them there. */ if (cfrom && (isempty(pfrom) || path_equal(pfrom, "/")) && is_kernel_thread(pid) > 0) continue; r = cg_attach(cto, pto, pid); if (r < 0) { if (ret >= 0 && r != -ESRCH) ret = r; } else if (ret == 0) ret = 1; done = false; r = set_put(s, PID_TO_PTR(pid)); if (r < 0) { if (ret >= 0) return r; return ret; } } if (r < 0) { if (ret >= 0) return r; return ret; } } while (!done); return ret; } int cg_migrate_recursive( const char *cfrom, const char *pfrom, const char *cto, const char *pto, CGroupFlags flags) { _cleanup_closedir_ DIR *d = NULL; int r, ret = 0; char *fn; assert(cfrom); assert(pfrom); assert(cto); assert(pto); ret = cg_migrate(cfrom, pfrom, cto, pto, flags); r = cg_enumerate_subgroups(cfrom, pfrom, &d); if (r < 0) { if (ret >= 0 && r != -ENOENT) return r; return ret; } while ((r = cg_read_subgroup(d, &fn)) > 0) { _cleanup_free_ char *p = NULL; p = strjoin(pfrom, "/", fn); free(fn); if (!p) return -ENOMEM; r = cg_migrate_recursive(cfrom, p, cto, pto, flags); if (r != 0 && ret >= 0) ret = r; } if (r < 0 && ret >= 0) ret = r; if (flags & CGROUP_REMOVE) { r = cg_rmdir(cfrom, pfrom); if (r < 0 && ret >= 0 && r != -ENOENT && r != -EBUSY) return r; } return ret; } int cg_migrate_recursive_fallback( const char *cfrom, const char *pfrom, const char *cto, const char *pto, CGroupFlags flags) { int r; assert(cfrom); assert(pfrom); assert(cto); assert(pto); r = cg_migrate_recursive(cfrom, pfrom, cto, pto, flags); if (r < 0) { char prefix[strlen(pto) + 1]; /* This didn't work? Then let's try all prefixes of the destination */ PATH_FOREACH_PREFIX(prefix, pto) { int q; q = cg_migrate_recursive(cfrom, pfrom, cto, prefix, flags); if (q >= 0) return q; } } return r; } static const char *controller_to_dirname(const char *controller) { const char *e; assert(controller); /* Converts a controller name to the directory name below * /sys/fs/cgroup/ we want to mount it to. Effectively, this * just cuts off the name= prefixed used for named * hierarchies, if it is specified. */ if (streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { if (cg_hybrid_unified() > 0) controller = SYSTEMD_CGROUP_CONTROLLER_HYBRID; else controller = SYSTEMD_CGROUP_CONTROLLER_LEGACY; } e = startswith(controller, "name="); if (e) return e; return controller; } static int join_path_legacy(const char *controller, const char *path, const char *suffix, char **fs) { const char *dn; char *t = NULL; assert(fs); assert(controller); dn = controller_to_dirname(controller); if (isempty(path) && isempty(suffix)) t = strappend("/sys/fs/cgroup/", dn); else if (isempty(path)) t = strjoin("/sys/fs/cgroup/", dn, "/", suffix); else if (isempty(suffix)) t = strjoin("/sys/fs/cgroup/", dn, "/", path); else t = strjoin("/sys/fs/cgroup/", dn, "/", path, "/", suffix); if (!t) return -ENOMEM; *fs = t; return 0; } static int join_path_unified(const char *path, const char *suffix, char **fs) { char *t; assert(fs); if (isempty(path) && isempty(suffix)) t = strdup("/sys/fs/cgroup"); else if (isempty(path)) t = strappend("/sys/fs/cgroup/", suffix); else if (isempty(suffix)) t = strappend("/sys/fs/cgroup/", path); else t = strjoin("/sys/fs/cgroup/", path, "/", suffix); if (!t) return -ENOMEM; *fs = t; return 0; } int cg_get_path(const char *controller, const char *path, const char *suffix, char **fs) { int r; assert(fs); if (!controller) { char *t; /* If no controller is specified, we return the path * *below* the controllers, without any prefix. */ if (!path && !suffix) return -EINVAL; if (!suffix) t = strdup(path); else if (!path) t = strdup(suffix); else t = strjoin(path, "/", suffix); if (!t) return -ENOMEM; *fs = path_kill_slashes(t); return 0; } if (!cg_controller_is_valid(controller)) return -EINVAL; r = cg_all_unified(); if (r < 0) return r; if (r > 0) r = join_path_unified(path, suffix, fs); else r = join_path_legacy(controller, path, suffix, fs); if (r < 0) return r; path_kill_slashes(*fs); return 0; } static int controller_is_accessible(const char *controller) { int r; assert(controller); /* Checks whether a specific controller is accessible, * i.e. its hierarchy mounted. In the unified hierarchy all * controllers are considered accessible, except for the named * hierarchies */ if (!cg_controller_is_valid(controller)) return -EINVAL; r = cg_all_unified(); if (r < 0) return r; if (r > 0) { /* We don't support named hierarchies if we are using * the unified hierarchy. */ if (streq(controller, SYSTEMD_CGROUP_CONTROLLER)) return 0; if (startswith(controller, "name=")) return -EOPNOTSUPP; } else { const char *cc, *dn; dn = controller_to_dirname(controller); cc = strjoina("/sys/fs/cgroup/", dn); if (laccess(cc, F_OK) < 0) return -errno; } return 0; } int cg_get_path_and_check(const char *controller, const char *path, const char *suffix, char **fs) { int r; assert(controller); assert(fs); /* Check if the specified controller is actually accessible */ r = controller_is_accessible(controller); if (r < 0) return r; return cg_get_path(controller, path, suffix, fs); } static int trim_cb(const char *path, const struct stat *sb, int typeflag, struct FTW *ftwbuf) { assert(path); assert(sb); assert(ftwbuf); if (typeflag != FTW_DP) return 0; if (ftwbuf->level < 1) return 0; (void) rmdir(path); return 0; } int cg_trim(const char *controller, const char *path, bool delete_root) { _cleanup_free_ char *fs = NULL; int r = 0, q; assert(path); r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; errno = 0; if (nftw(fs, trim_cb, 64, FTW_DEPTH|FTW_MOUNT|FTW_PHYS) != 0) { if (errno == ENOENT) r = 0; else if (errno > 0) r = -errno; else r = -EIO; } if (delete_root) { if (rmdir(fs) < 0 && errno != ENOENT) return -errno; } q = cg_hybrid_unified(); if (q < 0) return q; if (q > 0 && streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { q = cg_trim(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path, delete_root); if (q < 0) log_warning_errno(q, "Failed to trim compat systemd cgroup %s: %m", path); } return r; } int cg_create(const char *controller, const char *path) { _cleanup_free_ char *fs = NULL; int r; r = cg_get_path_and_check(controller, path, NULL, &fs); if (r < 0) return r; r = mkdir_parents(fs, 0755); if (r < 0) return r; if (mkdir(fs, 0755) < 0) { if (errno == EEXIST) return 0; return -errno; } r = cg_hybrid_unified(); if (r < 0) return r; if (r > 0 && streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { r = cg_create(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path); if (r < 0) log_warning_errno(r, "Failed to create compat systemd cgroup %s: %m", path); } return 1; } int cg_create_and_attach(const char *controller, const char *path, pid_t pid) { int r, q; assert(pid >= 0); r = cg_create(controller, path); if (r < 0) return r; q = cg_attach(controller, path, pid); if (q < 0) return q; /* This does not remove the cgroup on failure */ return r; } int cg_attach(const char *controller, const char *path, pid_t pid) { _cleanup_free_ char *fs = NULL; char c[DECIMAL_STR_MAX(pid_t) + 2]; int r; assert(path); assert(pid >= 0); r = cg_get_path_and_check(controller, path, "cgroup.procs", &fs); if (r < 0) return r; if (pid == 0) pid = getpid(); xsprintf(c, PID_FMT "\n", pid); r = write_string_file(fs, c, 0); if (r < 0) return r; r = cg_hybrid_unified(); if (r < 0) return r; if (r > 0 && streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { r = cg_attach(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path, pid); if (r < 0) log_warning_errno(r, "Failed to attach %d to compat systemd cgroup %s: %m", pid, path); } return 0; } int cg_attach_fallback(const char *controller, const char *path, pid_t pid) { int r; assert(controller); assert(path); assert(pid >= 0); r = cg_attach(controller, path, pid); if (r < 0) { char prefix[strlen(path) + 1]; /* This didn't work? Then let's try all prefixes of * the destination */ PATH_FOREACH_PREFIX(prefix, path) { int q; q = cg_attach(controller, prefix, pid); if (q >= 0) return q; } } return r; } int cg_set_group_access( const char *controller, const char *path, mode_t mode, uid_t uid, gid_t gid) { _cleanup_free_ char *fs = NULL; int r; if (mode == MODE_INVALID && uid == UID_INVALID && gid == GID_INVALID) return 0; if (mode != MODE_INVALID) mode &= 0777; r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; r = chmod_and_chown(fs, mode, uid, gid); if (r < 0) return r; r = cg_hybrid_unified(); if (r < 0) return r; if (r > 0 && streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { r = cg_set_group_access(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path, mode, uid, gid); if (r < 0) log_warning_errno(r, "Failed to set group access on compat systemd cgroup %s: %m", path); } return 0; } int cg_set_task_access( const char *controller, const char *path, mode_t mode, uid_t uid, gid_t gid) { _cleanup_free_ char *fs = NULL, *procs = NULL; int r; assert(path); if (mode == MODE_INVALID && uid == UID_INVALID && gid == GID_INVALID) return 0; if (mode != MODE_INVALID) mode &= 0666; r = cg_get_path(controller, path, "cgroup.procs", &fs); if (r < 0) return r; r = chmod_and_chown(fs, mode, uid, gid); if (r < 0) return r; r = cg_unified_controller(controller); if (r < 0) return r; if (r == 0) { /* Compatibility, Always keep values for "tasks" in sync with * "cgroup.procs" */ if (cg_get_path(controller, path, "tasks", &procs) >= 0) (void) chmod_and_chown(procs, mode, uid, gid); } r = cg_hybrid_unified(); if (r < 0) return r; if (r > 0 && streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { r = cg_set_task_access(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path, mode, uid, gid); if (r < 0) log_warning_errno(r, "Failed to set task access on compat systemd cgroup %s: %m", path); } return 0; } int cg_set_xattr(const char *controller, const char *path, const char *name, const void *value, size_t size, int flags) { _cleanup_free_ char *fs = NULL; int r; assert(path); assert(name); assert(value || size <= 0); r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; if (setxattr(fs, name, value, size, flags) < 0) return -errno; return 0; } int cg_get_xattr(const char *controller, const char *path, const char *name, void *value, size_t size) { _cleanup_free_ char *fs = NULL; ssize_t n; int r; assert(path); assert(name); r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; n = getxattr(fs, name, value, size); if (n < 0) return -errno; return (int) n; } int cg_pid_get_path(const char *controller, pid_t pid, char **path) { _cleanup_fclose_ FILE *f = NULL; char line[LINE_MAX]; const char *fs, *controller_str; size_t cs = 0; int unified; assert(path); assert(pid >= 0); if (controller) { if (!cg_controller_is_valid(controller)) return -EINVAL; } else controller = SYSTEMD_CGROUP_CONTROLLER; unified = cg_unified_controller(controller); if (unified < 0) return unified; if (unified == 0) { if (streq(controller, SYSTEMD_CGROUP_CONTROLLER)) controller_str = SYSTEMD_CGROUP_CONTROLLER_LEGACY; else controller_str = controller; cs = strlen(controller_str); } fs = procfs_file_alloca(pid, "cgroup"); f = fopen(fs, "re"); if (!f) return errno == ENOENT ? -ESRCH : -errno; FOREACH_LINE(line, f, return -errno) { char *e, *p; truncate_nl(line); if (unified) { e = startswith(line, "0:"); if (!e) continue; e = strchr(e, ':'); if (!e) continue; } else { char *l; size_t k; const char *word, *state; bool found = false; l = strchr(line, ':'); if (!l) continue; l++; e = strchr(l, ':'); if (!e) continue; *e = 0; FOREACH_WORD_SEPARATOR(word, k, l, ",", state) { if (k == cs && memcmp(word, controller_str, cs) == 0) { found = true; break; } } if (!found) continue; } p = strdup(e + 1); if (!p) return -ENOMEM; *path = p; return 0; } return -ENODATA; } int cg_install_release_agent(const char *controller, const char *agent) { _cleanup_free_ char *fs = NULL, *contents = NULL; const char *sc; int r; assert(agent); r = cg_unified_controller(controller); if (r < 0) return r; if (r > 0) /* doesn't apply to unified hierarchy */ return -EOPNOTSUPP; r = cg_get_path(controller, NULL, "release_agent", &fs); if (r < 0) return r; r = read_one_line_file(fs, &contents); if (r < 0) return r; sc = strstrip(contents); if (isempty(sc)) { r = write_string_file(fs, agent, 0); if (r < 0) return r; } else if (!path_equal(sc, agent)) return -EEXIST; fs = mfree(fs); r = cg_get_path(controller, NULL, "notify_on_release", &fs); if (r < 0) return r; contents = mfree(contents); r = read_one_line_file(fs, &contents); if (r < 0) return r; sc = strstrip(contents); if (streq(sc, "0")) { r = write_string_file(fs, "1", 0); if (r < 0) return r; return 1; } if (!streq(sc, "1")) return -EIO; return 0; } int cg_uninstall_release_agent(const char *controller) { _cleanup_free_ char *fs = NULL; int r; r = cg_unified_controller(controller); if (r < 0) return r; if (r > 0) /* Doesn't apply to unified hierarchy */ return -EOPNOTSUPP; r = cg_get_path(controller, NULL, "notify_on_release", &fs); if (r < 0) return r; r = write_string_file(fs, "0", 0); if (r < 0) return r; fs = mfree(fs); r = cg_get_path(controller, NULL, "release_agent", &fs); if (r < 0) return r; r = write_string_file(fs, "", 0); if (r < 0) return r; return 0; } int cg_is_empty(const char *controller, const char *path) { _cleanup_fclose_ FILE *f = NULL; pid_t pid; int r; assert(path); r = cg_enumerate_processes(controller, path, &f); if (r == -ENOENT) return 1; if (r < 0) return r; r = cg_read_pid(f, &pid); if (r < 0) return r; return r == 0; } int cg_is_empty_recursive(const char *controller, const char *path) { int r; assert(path); /* The root cgroup is always populated */ if (controller && (isempty(path) || path_equal(path, "/"))) return false; r = cg_unified_controller(controller); if (r < 0) return r; if (r > 0) { _cleanup_free_ char *t = NULL; /* On the unified hierarchy we can check empty state * via the "populated" attribute of "cgroup.events". */ r = cg_read_event(controller, path, "populated", &t); if (r < 0) return r; return streq(t, "0"); } else { _cleanup_closedir_ DIR *d = NULL; char *fn; r = cg_is_empty(controller, path); if (r <= 0) return r; r = cg_enumerate_subgroups(controller, path, &d); if (r == -ENOENT) return 1; if (r < 0) return r; while ((r = cg_read_subgroup(d, &fn)) > 0) { _cleanup_free_ char *p = NULL; p = strjoin(path, "/", fn); free(fn); if (!p) return -ENOMEM; r = cg_is_empty_recursive(controller, p); if (r <= 0) return r; } if (r < 0) return r; return true; } } int cg_split_spec(const char *spec, char **controller, char **path) { char *t = NULL, *u = NULL; const char *e; assert(spec); if (*spec == '/') { if (!path_is_safe(spec)) return -EINVAL; if (path) { t = strdup(spec); if (!t) return -ENOMEM; *path = path_kill_slashes(t); } if (controller) *controller = NULL; return 0; } e = strchr(spec, ':'); if (!e) { if (!cg_controller_is_valid(spec)) return -EINVAL; if (controller) { t = strdup(spec); if (!t) return -ENOMEM; *controller = t; } if (path) *path = NULL; return 0; } t = strndup(spec, e-spec); if (!t) return -ENOMEM; if (!cg_controller_is_valid(t)) { free(t); return -EINVAL; } if (isempty(e+1)) u = NULL; else { u = strdup(e+1); if (!u) { free(t); return -ENOMEM; } if (!path_is_safe(u) || !path_is_absolute(u)) { free(t); free(u); return -EINVAL; } path_kill_slashes(u); } if (controller) *controller = t; else free(t); if (path) *path = u; else free(u); return 0; } int cg_mangle_path(const char *path, char **result) { _cleanup_free_ char *c = NULL, *p = NULL; char *t; int r; assert(path); assert(result); /* First, check if it already is a filesystem path */ if (path_startswith(path, "/sys/fs/cgroup")) { t = strdup(path); if (!t) return -ENOMEM; *result = path_kill_slashes(t); return 0; } /* Otherwise, treat it as cg spec */ r = cg_split_spec(path, &c, &p); if (r < 0) return r; return cg_get_path(c ?: SYSTEMD_CGROUP_CONTROLLER, p ?: "/", NULL, result); } int cg_get_root_path(char **path) { char *p, *e; int r; assert(path); r = cg_pid_get_path(SYSTEMD_CGROUP_CONTROLLER, 1, &p); if (r < 0) return r; e = endswith(p, "/" SPECIAL_INIT_SCOPE); if (!e) e = endswith(p, "/" SPECIAL_SYSTEM_SLICE); /* legacy */ if (!e) e = endswith(p, "/system"); /* even more legacy */ if (e) *e = 0; *path = p; return 0; } int cg_shift_path(const char *cgroup, const char *root, const char **shifted) { _cleanup_free_ char *rt = NULL; char *p; int r; assert(cgroup); assert(shifted); if (!root) { /* If the root was specified let's use that, otherwise * let's determine it from PID 1 */ r = cg_get_root_path(&rt); if (r < 0) return r; root = rt; } p = path_startswith(cgroup, root); if (p && p > cgroup) *shifted = p - 1; else *shifted = cgroup; return 0; } int cg_pid_get_path_shifted(pid_t pid, const char *root, char **cgroup) { _cleanup_free_ char *raw = NULL; const char *c; int r; assert(pid >= 0); assert(cgroup); r = cg_pid_get_path(SYSTEMD_CGROUP_CONTROLLER, pid, &raw); if (r < 0) return r; r = cg_shift_path(raw, root, &c); if (r < 0) return r; if (c == raw) { *cgroup = raw; raw = NULL; } else { char *n; n = strdup(c); if (!n) return -ENOMEM; *cgroup = n; } return 0; } int cg_path_decode_unit(const char *cgroup, char **unit) { char *c, *s; size_t n; assert(cgroup); assert(unit); n = strcspn(cgroup, "/"); if (n < 3) return -ENXIO; c = strndupa(cgroup, n); c = cg_unescape(c); if (!unit_name_is_valid(c, UNIT_NAME_PLAIN|UNIT_NAME_INSTANCE)) return -ENXIO; s = strdup(c); if (!s) return -ENOMEM; *unit = s; return 0; } static bool valid_slice_name(const char *p, size_t n) { if (!p) return false; if (n < strlen("x.slice")) return false; if (memcmp(p + n - 6, ".slice", 6) == 0) { char buf[n+1], *c; memcpy(buf, p, n); buf[n] = 0; c = cg_unescape(buf); return unit_name_is_valid(c, UNIT_NAME_PLAIN); } return false; } static const char *skip_slices(const char *p) { assert(p); /* Skips over all slice assignments */ for (;;) { size_t n; p += strspn(p, "/"); n = strcspn(p, "/"); if (!valid_slice_name(p, n)) return p; p += n; } } int cg_path_get_unit(const char *path, char **ret) { const char *e; char *unit; int r; assert(path); assert(ret); e = skip_slices(path); r = cg_path_decode_unit(e, &unit); if (r < 0) return r; /* We skipped over the slices, don't accept any now */ if (endswith(unit, ".slice")) { free(unit); return -ENXIO; } *ret = unit; return 0; } int cg_pid_get_unit(pid_t pid, char **unit) { _cleanup_free_ char *cgroup = NULL; int r; assert(unit); r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_unit(cgroup, unit); } /** * Skip session-*.scope, but require it to be there. */ static const char *skip_session(const char *p) { size_t n; if (isempty(p)) return NULL; p += strspn(p, "/"); n = strcspn(p, "/"); if (n < strlen("session-x.scope")) return NULL; if (memcmp(p, "session-", 8) == 0 && memcmp(p + n - 6, ".scope", 6) == 0) { char buf[n - 8 - 6 + 1]; memcpy(buf, p + 8, n - 8 - 6); buf[n - 8 - 6] = 0; /* Note that session scopes never need unescaping, * since they cannot conflict with the kernel's own * names, hence we don't need to call cg_unescape() * here. */ if (!session_id_valid(buf)) return false; p += n; p += strspn(p, "/"); return p; } return NULL; } /** * Skip user@*.service, but require it to be there. */ static const char *skip_user_manager(const char *p) { size_t n; if (isempty(p)) return NULL; p += strspn(p, "/"); n = strcspn(p, "/"); if (n < strlen("user@x.service")) return NULL; if (memcmp(p, "user@", 5) == 0 && memcmp(p + n - 8, ".service", 8) == 0) { char buf[n - 5 - 8 + 1]; memcpy(buf, p + 5, n - 5 - 8); buf[n - 5 - 8] = 0; /* Note that user manager services never need unescaping, * since they cannot conflict with the kernel's own * names, hence we don't need to call cg_unescape() * here. */ if (parse_uid(buf, NULL) < 0) return NULL; p += n; p += strspn(p, "/"); return p; } return NULL; } static const char *skip_user_prefix(const char *path) { const char *e, *t; assert(path); /* Skip slices, if there are any */ e = skip_slices(path); /* Skip the user manager, if it's in the path now... */ t = skip_user_manager(e); if (t) return t; /* Alternatively skip the user session if it is in the path... */ return skip_session(e); } int cg_path_get_user_unit(const char *path, char **ret) { const char *t; assert(path); assert(ret); t = skip_user_prefix(path); if (!t) return -ENXIO; /* And from here on it looks pretty much the same as for a * system unit, hence let's use the same parser from here * on. */ return cg_path_get_unit(t, ret); } int cg_pid_get_user_unit(pid_t pid, char **unit) { _cleanup_free_ char *cgroup = NULL; int r; assert(unit); r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_user_unit(cgroup, unit); } int cg_path_get_machine_name(const char *path, char **machine) { _cleanup_free_ char *u = NULL; const char *sl; int r; r = cg_path_get_unit(path, &u); if (r < 0) return r; sl = strjoina("/run/systemd/machines/unit:", u); return readlink_malloc(sl, machine); } int cg_pid_get_machine_name(pid_t pid, char **machine) { _cleanup_free_ char *cgroup = NULL; int r; assert(machine); r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_machine_name(cgroup, machine); } int cg_path_get_session(const char *path, char **session) { _cleanup_free_ char *unit = NULL; char *start, *end; int r; assert(path); r = cg_path_get_unit(path, &unit); if (r < 0) return r; start = startswith(unit, "session-"); if (!start) return -ENXIO; end = endswith(start, ".scope"); if (!end) return -ENXIO; *end = 0; if (!session_id_valid(start)) return -ENXIO; if (session) { char *rr; rr = strdup(start); if (!rr) return -ENOMEM; *session = rr; } return 0; } int cg_pid_get_session(pid_t pid, char **session) { _cleanup_free_ char *cgroup = NULL; int r; r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_session(cgroup, session); } int cg_path_get_owner_uid(const char *path, uid_t *uid) { _cleanup_free_ char *slice = NULL; char *start, *end; int r; assert(path); r = cg_path_get_slice(path, &slice); if (r < 0) return r; start = startswith(slice, "user-"); if (!start) return -ENXIO; end = endswith(start, ".slice"); if (!end) return -ENXIO; *end = 0; if (parse_uid(start, uid) < 0) return -ENXIO; return 0; } int cg_pid_get_owner_uid(pid_t pid, uid_t *uid) { _cleanup_free_ char *cgroup = NULL; int r; r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_owner_uid(cgroup, uid); } int cg_path_get_slice(const char *p, char **slice) { const char *e = NULL; assert(p); assert(slice); /* Finds the right-most slice unit from the beginning, but * stops before we come to the first non-slice unit. */ for (;;) { size_t n; p += strspn(p, "/"); n = strcspn(p, "/"); if (!valid_slice_name(p, n)) { if (!e) { char *s; s = strdup(SPECIAL_ROOT_SLICE); if (!s) return -ENOMEM; *slice = s; return 0; } return cg_path_decode_unit(e, slice); } e = p; p += n; } } int cg_pid_get_slice(pid_t pid, char **slice) { _cleanup_free_ char *cgroup = NULL; int r; assert(slice); r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_slice(cgroup, slice); } int cg_path_get_user_slice(const char *p, char **slice) { const char *t; assert(p); assert(slice); t = skip_user_prefix(p); if (!t) return -ENXIO; /* And now it looks pretty much the same as for a system * slice, so let's just use the same parser from here on. */ return cg_path_get_slice(t, slice); } int cg_pid_get_user_slice(pid_t pid, char **slice) { _cleanup_free_ char *cgroup = NULL; int r; assert(slice); r = cg_pid_get_path_shifted(pid, NULL, &cgroup); if (r < 0) return r; return cg_path_get_user_slice(cgroup, slice); } char *cg_escape(const char *p) { bool need_prefix = false; /* This implements very minimal escaping for names to be used * as file names in the cgroup tree: any name which might * conflict with a kernel name or is prefixed with '_' is * prefixed with a '_'. That way, when reading cgroup names it * is sufficient to remove a single prefixing underscore if * there is one. */ /* The return value of this function (unlike cg_unescape()) * needs free()! */ if (p[0] == 0 || p[0] == '_' || p[0] == '.' || streq(p, "notify_on_release") || streq(p, "release_agent") || streq(p, "tasks") || startswith(p, "cgroup.")) need_prefix = true; else { const char *dot; dot = strrchr(p, '.'); if (dot) { CGroupController c; size_t l = dot - p; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { const char *n; n = cgroup_controller_to_string(c); if (l != strlen(n)) continue; if (memcmp(p, n, l) != 0) continue; need_prefix = true; break; } } } if (need_prefix) return strappend("_", p); return strdup(p); } char *cg_unescape(const char *p) { assert(p); /* The return value of this function (unlike cg_escape()) * doesn't need free()! */ if (p[0] == '_') return (char*) p+1; return (char*) p; } #define CONTROLLER_VALID \ DIGITS LETTERS \ "_" bool cg_controller_is_valid(const char *p) { const char *t, *s; if (!p) return false; if (streq(p, SYSTEMD_CGROUP_CONTROLLER)) return true; s = startswith(p, "name="); if (s) p = s; if (*p == 0 || *p == '_') return false; for (t = p; *t; t++) if (!strchr(CONTROLLER_VALID, *t)) return false; if (t - p > FILENAME_MAX) return false; return true; } int cg_slice_to_path(const char *unit, char **ret) { _cleanup_free_ char *p = NULL, *s = NULL, *e = NULL; const char *dash; int r; assert(unit); assert(ret); if (streq(unit, SPECIAL_ROOT_SLICE)) { char *x; x = strdup(""); if (!x) return -ENOMEM; *ret = x; return 0; } if (!unit_name_is_valid(unit, UNIT_NAME_PLAIN)) return -EINVAL; if (!endswith(unit, ".slice")) return -EINVAL; r = unit_name_to_prefix(unit, &p); if (r < 0) return r; dash = strchr(p, '-'); /* Don't allow initial dashes */ if (dash == p) return -EINVAL; while (dash) { _cleanup_free_ char *escaped = NULL; char n[dash - p + sizeof(".slice")]; /* Don't allow trailing or double dashes */ if (dash[1] == 0 || dash[1] == '-') return -EINVAL; strcpy(stpncpy(n, p, dash - p), ".slice"); if (!unit_name_is_valid(n, UNIT_NAME_PLAIN)) return -EINVAL; escaped = cg_escape(n); if (!escaped) return -ENOMEM; if (!strextend(&s, escaped, "/", NULL)) return -ENOMEM; dash = strchr(dash+1, '-'); } e = cg_escape(unit); if (!e) return -ENOMEM; if (!strextend(&s, e, NULL)) return -ENOMEM; *ret = s; s = NULL; return 0; } int cg_set_attribute(const char *controller, const char *path, const char *attribute, const char *value) { _cleanup_free_ char *p = NULL; int r; r = cg_get_path(controller, path, attribute, &p); if (r < 0) return r; return write_string_file(p, value, 0); } int cg_get_attribute(const char *controller, const char *path, const char *attribute, char **ret) { _cleanup_free_ char *p = NULL; int r; r = cg_get_path(controller, path, attribute, &p); if (r < 0) return r; return read_one_line_file(p, ret); } int cg_get_keyed_attribute(const char *controller, const char *path, const char *attribute, const char **keys, char **values) { _cleanup_free_ char *filename = NULL, *content = NULL; char *line, *p; int i, r; for (i = 0; keys[i]; i++) values[i] = NULL; r = cg_get_path(controller, path, attribute, &filename); if (r < 0) return r; r = read_full_file(filename, &content, NULL); if (r < 0) return r; p = content; while ((line = strsep(&p, "\n"))) { char *key; key = strsep(&line, " "); for (i = 0; keys[i]; i++) { if (streq(key, keys[i])) { values[i] = strdup(line); break; } } } for (i = 0; keys[i]; i++) { if (!values[i]) { for (i = 0; keys[i]; i++) { free(values[i]); values[i] = NULL; } return -ENOENT; } } return 0; } int cg_create_everywhere(CGroupMask supported, CGroupMask mask, const char *path) { CGroupController c; int r; /* This one will create a cgroup in our private tree, but also * duplicate it in the trees specified in mask, and remove it * in all others */ /* First create the cgroup in our own hierarchy. */ r = cg_create(SYSTEMD_CGROUP_CONTROLLER, path); if (r < 0) return r; /* If we are in the unified hierarchy, we are done now */ r = cg_all_unified(); if (r < 0) return r; if (r > 0) return 0; /* Otherwise, do the same in the other hierarchies */ for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); const char *n; n = cgroup_controller_to_string(c); if (mask & bit) (void) cg_create(n, path); else if (supported & bit) (void) cg_trim(n, path, true); } return 0; } int cg_attach_everywhere(CGroupMask supported, const char *path, pid_t pid, cg_migrate_callback_t path_callback, void *userdata) { CGroupController c; int r; r = cg_attach(SYSTEMD_CGROUP_CONTROLLER, path, pid); if (r < 0) return r; r = cg_all_unified(); if (r < 0) return r; if (r > 0) return 0; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); const char *p = NULL; if (!(supported & bit)) continue; if (path_callback) p = path_callback(bit, userdata); if (!p) p = path; (void) cg_attach_fallback(cgroup_controller_to_string(c), p, pid); } return 0; } int cg_attach_many_everywhere(CGroupMask supported, const char *path, Set* pids, cg_migrate_callback_t path_callback, void *userdata) { Iterator i; void *pidp; int r = 0; SET_FOREACH(pidp, pids, i) { pid_t pid = PTR_TO_PID(pidp); int q; q = cg_attach_everywhere(supported, path, pid, path_callback, userdata); if (q < 0 && r >= 0) r = q; } return r; } int cg_migrate_everywhere(CGroupMask supported, const char *from, const char *to, cg_migrate_callback_t to_callback, void *userdata) { CGroupController c; int r = 0, q; if (!path_equal(from, to)) { r = cg_migrate_recursive(SYSTEMD_CGROUP_CONTROLLER, from, SYSTEMD_CGROUP_CONTROLLER, to, CGROUP_REMOVE); if (r < 0) return r; } q = cg_all_unified(); if (q < 0) return q; if (q > 0) return r; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); const char *p = NULL; if (!(supported & bit)) continue; if (to_callback) p = to_callback(bit, userdata); if (!p) p = to; (void) cg_migrate_recursive_fallback(SYSTEMD_CGROUP_CONTROLLER, to, cgroup_controller_to_string(c), p, 0); } return 0; } int cg_trim_everywhere(CGroupMask supported, const char *path, bool delete_root) { CGroupController c; int r, q; r = cg_trim(SYSTEMD_CGROUP_CONTROLLER, path, delete_root); if (r < 0) return r; q = cg_all_unified(); if (q < 0) return q; if (q > 0) return r; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); if (!(supported & bit)) continue; (void) cg_trim(cgroup_controller_to_string(c), path, delete_root); } return 0; } int cg_mask_supported(CGroupMask *ret) { CGroupMask mask = 0; int r; /* Determines the mask of supported cgroup controllers. Only * includes controllers we can make sense of and that are * actually accessible. */ r = cg_all_unified(); if (r < 0) return r; if (r > 0) { _cleanup_free_ char *root = NULL, *controllers = NULL, *path = NULL; const char *c; /* In the unified hierarchy we can read the supported * and accessible controllers from a the top-level * cgroup attribute */ r = cg_get_root_path(&root); if (r < 0) return r; r = cg_get_path(SYSTEMD_CGROUP_CONTROLLER, root, "cgroup.controllers", &path); if (r < 0) return r; r = read_one_line_file(path, &controllers); if (r < 0) return r; c = controllers; for (;;) { _cleanup_free_ char *n = NULL; CGroupController v; r = extract_first_word(&c, &n, NULL, 0); if (r < 0) return r; if (r == 0) break; v = cgroup_controller_from_string(n); if (v < 0) continue; mask |= CGROUP_CONTROLLER_TO_MASK(v); } /* Currently, we support the cpu, memory, io and pids * controller in the unified hierarchy, mask * everything else off. */ mask &= CGROUP_MASK_CPU | CGROUP_MASK_MEMORY | CGROUP_MASK_IO | CGROUP_MASK_PIDS; } else { CGroupController c; /* In the legacy hierarchy, we check whether which * hierarchies are mounted. */ for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { const char *n; n = cgroup_controller_to_string(c); if (controller_is_accessible(n) >= 0) mask |= CGROUP_CONTROLLER_TO_MASK(c); } } *ret = mask; return 0; } int cg_kernel_controllers(Set *controllers) { _cleanup_fclose_ FILE *f = NULL; char buf[LINE_MAX]; int r; assert(controllers); /* Determines the full list of kernel-known controllers. Might * include controllers we don't actually support, arbitrary * named hierarchies and controllers that aren't currently * accessible (because not mounted). */ f = fopen("/proc/cgroups", "re"); if (!f) { if (errno == ENOENT) return 0; return -errno; } /* Ignore the header line */ (void) fgets(buf, sizeof(buf), f); for (;;) { char *controller; int enabled = 0; errno = 0; if (fscanf(f, "%ms %*i %*i %i", &controller, &enabled) != 2) { if (feof(f)) break; if (ferror(f) && errno > 0) return -errno; return -EBADMSG; } if (!enabled) { free(controller); continue; } if (!cg_controller_is_valid(controller)) { free(controller); return -EBADMSG; } r = set_consume(controllers, controller); if (r < 0) return r; } return 0; } static thread_local CGroupUnified unified_cache = CGROUP_UNIFIED_UNKNOWN; /* The hybrid mode was initially implemented in v232 and simply mounted cgroup v2 on /sys/fs/cgroup/systemd. This * unfortunately broke other tools (such as docker) which expected the v1 "name=systemd" hierarchy on * /sys/fs/cgroup/systemd. From v233 and on, the hybrid mode mountnbs v2 on /sys/fs/cgroup/unified and maintains * "name=systemd" hierarchy on /sys/fs/cgroup/systemd for compatibility with other tools. * * To keep live upgrade working, we detect and support v232 layout. When v232 layout is detected, to keep cgroup v2 * process management but disable the compat dual layout, we return %true on * cg_unified_controller(SYSTEMD_CGROUP_CONTROLLER) and %false on cg_hybrid_unified(). */ static thread_local bool unified_systemd_v232; static int cg_unified_update(void) { struct statfs fs; /* Checks if we support the unified hierarchy. Returns an * error when the cgroup hierarchies aren't mounted yet or we * have any other trouble determining if the unified hierarchy * is supported. */ if (unified_cache >= CGROUP_UNIFIED_NONE) return 0; if (statfs("/sys/fs/cgroup/", &fs) < 0) return -errno; if (F_TYPE_EQUAL(fs.f_type, CGROUP2_SUPER_MAGIC)) unified_cache = CGROUP_UNIFIED_ALL; else if (F_TYPE_EQUAL(fs.f_type, TMPFS_MAGIC)) { if (statfs("/sys/fs/cgroup/unified/", &fs) == 0 && F_TYPE_EQUAL(fs.f_type, CGROUP2_SUPER_MAGIC)) { unified_cache = CGROUP_UNIFIED_SYSTEMD; unified_systemd_v232 = false; } else if (statfs("/sys/fs/cgroup/systemd/", &fs) == 0 && F_TYPE_EQUAL(fs.f_type, CGROUP2_SUPER_MAGIC)) { unified_cache = CGROUP_UNIFIED_SYSTEMD; unified_systemd_v232 = true; } else { if (statfs("/sys/fs/cgroup/systemd/", &fs) < 0) return -errno; if (!F_TYPE_EQUAL(fs.f_type, CGROUP_SUPER_MAGIC)) return -ENOMEDIUM; unified_cache = CGROUP_UNIFIED_NONE; } } else return -ENOMEDIUM; return 0; } int cg_unified_controller(const char *controller) { int r; r = cg_unified_update(); if (r < 0) return r; if (unified_cache == CGROUP_UNIFIED_NONE) return false; if (unified_cache >= CGROUP_UNIFIED_ALL) return true; return streq_ptr(controller, SYSTEMD_CGROUP_CONTROLLER); } int cg_all_unified(void) { return cg_unified_controller(NULL); } int cg_hybrid_unified(void) { int r; r = cg_unified_update(); if (r < 0) return r; return unified_cache == CGROUP_UNIFIED_SYSTEMD && !unified_systemd_v232; } int cg_unified_flush(void) { unified_cache = CGROUP_UNIFIED_UNKNOWN; return cg_unified_update(); } int cg_enable_everywhere(CGroupMask supported, CGroupMask mask, const char *p) { _cleanup_free_ char *fs = NULL; CGroupController c; int r; assert(p); if (supported == 0) return 0; r = cg_all_unified(); if (r < 0) return r; if (r == 0) /* on the legacy hiearchy there's no joining of controllers defined */ return 0; r = cg_get_path(SYSTEMD_CGROUP_CONTROLLER, p, "cgroup.subtree_control", &fs); if (r < 0) return r; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); const char *n; if (!(supported & bit)) continue; n = cgroup_controller_to_string(c); { char s[1 + strlen(n) + 1]; s[0] = mask & bit ? '+' : '-'; strcpy(s + 1, n); r = write_string_file(fs, s, 0); if (r < 0) log_debug_errno(r, "Failed to enable controller %s for %s (%s): %m", n, p, fs); } } return 0; } bool cg_is_unified_wanted(void) { static thread_local int wanted = -1; int r; bool b; const bool is_default = DEFAULT_HIERARCHY == CGROUP_UNIFIED_ALL; /* If we have a cached value, return that. */ if (wanted >= 0) return wanted; /* If the hierarchy is already mounted, then follow whatever * was chosen for it. */ if (cg_unified_flush() >= 0) return (wanted = unified_cache >= CGROUP_UNIFIED_ALL); /* Otherwise, let's see what the kernel command line has to say. * Since checking is expensive, cache a non-error result. */ r = proc_cmdline_get_bool("systemd.unified_cgroup_hierarchy", &b); return (wanted = r > 0 ? b : is_default); } bool cg_is_legacy_wanted(void) { static thread_local int wanted = -1; /* If we have a cached value, return that. */ if (wanted >= 0) return wanted; /* Check if we have cgroups2 already mounted. */ if (cg_unified_flush() >= 0 && unified_cache == CGROUP_UNIFIED_ALL) return (wanted = false); /* Otherwise, assume that at least partial legacy is wanted, * since cgroups2 should already be mounted at this point. */ return (wanted = true); } bool cg_is_hybrid_wanted(void) { static thread_local int wanted = -1; int r; bool b; const bool is_default = DEFAULT_HIERARCHY >= CGROUP_UNIFIED_SYSTEMD; /* We default to true if the default is "hybrid", obviously, * but also when the default is "unified", because if we get * called, it means that unified hierarchy was not mounted. */ /* If we have a cached value, return that. */ if (wanted >= 0) return wanted; /* If the hierarchy is already mounted, then follow whatever * was chosen for it. */ if (cg_unified_flush() >= 0 && unified_cache == CGROUP_UNIFIED_ALL) return (wanted = false); /* Otherwise, let's see what the kernel command line has to say. * Since checking is expensive, cache a non-error result. */ r = proc_cmdline_get_bool("systemd.legacy_systemd_cgroup_controller", &b); /* The meaning of the kernel option is reversed wrt. to the return value * of this function, hence the negation. */ return (wanted = r > 0 ? !b : is_default); } int cg_weight_parse(const char *s, uint64_t *ret) { uint64_t u; int r; if (isempty(s)) { *ret = CGROUP_WEIGHT_INVALID; return 0; } r = safe_atou64(s, &u); if (r < 0) return r; if (u < CGROUP_WEIGHT_MIN || u > CGROUP_WEIGHT_MAX) return -ERANGE; *ret = u; return 0; } const uint64_t cgroup_io_limit_defaults[_CGROUP_IO_LIMIT_TYPE_MAX] = { [CGROUP_IO_RBPS_MAX] = CGROUP_LIMIT_MAX, [CGROUP_IO_WBPS_MAX] = CGROUP_LIMIT_MAX, [CGROUP_IO_RIOPS_MAX] = CGROUP_LIMIT_MAX, [CGROUP_IO_WIOPS_MAX] = CGROUP_LIMIT_MAX, }; static const char* const cgroup_io_limit_type_table[_CGROUP_IO_LIMIT_TYPE_MAX] = { [CGROUP_IO_RBPS_MAX] = "IOReadBandwidthMax", [CGROUP_IO_WBPS_MAX] = "IOWriteBandwidthMax", [CGROUP_IO_RIOPS_MAX] = "IOReadIOPSMax", [CGROUP_IO_WIOPS_MAX] = "IOWriteIOPSMax", }; DEFINE_STRING_TABLE_LOOKUP(cgroup_io_limit_type, CGroupIOLimitType); int cg_cpu_shares_parse(const char *s, uint64_t *ret) { uint64_t u; int r; if (isempty(s)) { *ret = CGROUP_CPU_SHARES_INVALID; return 0; } r = safe_atou64(s, &u); if (r < 0) return r; if (u < CGROUP_CPU_SHARES_MIN || u > CGROUP_CPU_SHARES_MAX) return -ERANGE; *ret = u; return 0; } int cg_blkio_weight_parse(const char *s, uint64_t *ret) { uint64_t u; int r; if (isempty(s)) { *ret = CGROUP_BLKIO_WEIGHT_INVALID; return 0; } r = safe_atou64(s, &u); if (r < 0) return r; if (u < CGROUP_BLKIO_WEIGHT_MIN || u > CGROUP_BLKIO_WEIGHT_MAX) return -ERANGE; *ret = u; return 0; } bool is_cgroup_fs(const struct statfs *s) { return is_fs_type(s, CGROUP_SUPER_MAGIC) || is_fs_type(s, CGROUP2_SUPER_MAGIC); } bool fd_is_cgroup_fs(int fd) { struct statfs s; if (fstatfs(fd, &s) < 0) return -errno; return is_cgroup_fs(&s); } static const char *cgroup_controller_table[_CGROUP_CONTROLLER_MAX] = { [CGROUP_CONTROLLER_CPU] = "cpu", [CGROUP_CONTROLLER_CPUACCT] = "cpuacct", [CGROUP_CONTROLLER_IO] = "io", [CGROUP_CONTROLLER_BLKIO] = "blkio", [CGROUP_CONTROLLER_MEMORY] = "memory", [CGROUP_CONTROLLER_DEVICES] = "devices", [CGROUP_CONTROLLER_PIDS] = "pids", }; DEFINE_STRING_TABLE_LOOKUP(cgroup_controller, CGroupController);