/* SPDX-License-Identifier: LGPL-2.1-or-later */ #include #include "cgroup-setup.h" #include "cgroup-util.h" #include "errno-util.h" #include "fd-util.h" #include "fileio.h" #include "fs-util.h" #include "missing_threads.h" #include "mkdir.h" #include "parse-util.h" #include "path-util.h" #include "proc-cmdline.h" #include "process-util.h" #include "recurse-dir.h" #include "stdio-util.h" #include "string-util.h" #include "user-util.h" #include "virt.h" static int cg_any_controller_used_for_v1(void) { _cleanup_free_ char *buf = NULL; _cleanup_strv_free_ char **lines = NULL; int r; r = read_full_virtual_file("/proc/cgroups", &buf, NULL); if (r < 0) return log_debug_errno(r, "Could not read /proc/cgroups, ignoring: %m"); r = strv_split_newlines_full(&lines, buf, 0); if (r < 0) return r; /* The intention of this is to check if the fully unified cgroup tree setup is possible, meaning all * enabled kernel cgroup controllers are currently not in use by cgroup1. For reference: * https://systemd.io/CGROUP_DELEGATION/#three-different-tree-setups- * * Note that this is typically only useful to check inside a container where we don't know what * cgroup tree setup is in use by the host; if the host is using legacy or hybrid, we can't use * unified since some or all controllers would be missing. This is not the best way to detect this, * as whatever container manager created our container should have mounted /sys/fs/cgroup * appropriately, but in case that wasn't done, we try to detect if it's possible for us to use * unified cgroups. */ STRV_FOREACH(line, lines) { _cleanup_free_ char *name = NULL, *hierarchy_id = NULL, *num = NULL, *enabled = NULL; /* Skip header line */ if (startswith(*line, "#")) continue; const char *p = *line; r = extract_many_words(&p, NULL, 0, &name, &hierarchy_id, &num, &enabled, NULL); if (r < 0) return log_debug_errno(r, "Error parsing /proc/cgroups line, ignoring: %m"); else if (r < 4) { log_debug("Invalid /proc/cgroups line, ignoring."); continue; } /* Ignore disabled controllers. */ if (streq(enabled, "0")) continue; /* Ignore controllers we don't care about. */ if (cgroup_controller_from_string(name) < 0) continue; /* Since the unified cgroup doesn't use multiple hierarchies, if any controller has a * non-zero hierarchy_id that means it's in use already in a legacy (or hybrid) cgroup v1 * hierarchy, and can't be used in a unified cgroup. */ if (!streq(hierarchy_id, "0")) { log_debug("Cgroup controller %s in use by legacy v1 hierarchy.", name); return 1; } } return 0; } bool cg_is_unified_wanted(void) { static thread_local int wanted = -1; bool b; const bool is_default = DEFAULT_HIERARCHY == CGROUP_UNIFIED_ALL; _cleanup_free_ char *c = NULL; int r; /* 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. */ r = cg_unified_cached(true); if (r >= 0) return (wanted = r >= CGROUP_UNIFIED_ALL); /* If we were explicitly passed systemd.unified_cgroup_hierarchy, respect that. */ r = proc_cmdline_get_bool("systemd.unified_cgroup_hierarchy", /* flags = */ 0, &b); if (r > 0) return (wanted = b); /* If we passed cgroup_no_v1=all with no other instructions, it seems highly unlikely that we want to * use hybrid or legacy hierarchy. */ r = proc_cmdline_get_key("cgroup_no_v1", 0, &c); if (r > 0 && streq_ptr(c, "all")) return (wanted = true); /* If any controller is in use as v1, don't use unified. */ if (cg_any_controller_used_for_v1() > 0) return (wanted = false); return (wanted = 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 cgroup v2 already mounted. */ if (cg_unified_cached(true) == CGROUP_UNIFIED_ALL) return (wanted = false); /* Otherwise, assume that at least partial legacy is wanted, * since cgroup v2 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_cached(true) == 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", /* flags = */ 0, &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; } int cg_cpu_weight_parse(const char *s, uint64_t *ret) { if (streq_ptr(s, "idle")) return *ret = CGROUP_WEIGHT_IDLE; return cg_weight_parse(s, ret); } 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; } static int trim_cb( RecurseDirEvent event, const char *path, int dir_fd, int inode_fd, const struct dirent *de, const struct statx *sx, void *userdata) { /* Failures to delete inner cgroup we ignore (but debug log in case error code is unexpected) */ if (event == RECURSE_DIR_LEAVE && de->d_type == DT_DIR && unlinkat(dir_fd, de->d_name, AT_REMOVEDIR) < 0 && !IN_SET(errno, ENOENT, ENOTEMPTY, EBUSY)) log_debug_errno(errno, "Failed to trim inner cgroup %s, ignoring: %m", path); return RECURSE_DIR_CONTINUE; } int cg_trim(const char *controller, const char *path, bool delete_root) { _cleanup_free_ char *fs = NULL; int r, q; assert(path); assert(controller); r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; r = recurse_dir_at( AT_FDCWD, fs, /* statx_mask= */ 0, /* n_depth_max= */ UINT_MAX, RECURSE_DIR_ENSURE_TYPE, trim_cb, NULL); if (r == -ENOENT) /* non-existing is the ultimate trimming, hence no error */ r = 0; else if (r < 0) log_debug_errno(r, "Failed to iterate through cgroup %s: %m", path); /* If we shall delete the top-level cgroup, then propagate the failure to do so (except if it is * already gone anyway). Also, let's debug log about this failure, except if the error code is an * expected one. */ if (delete_root && !empty_or_root(path) && rmdir(fs) < 0 && errno != ENOENT) { if (!IN_SET(errno, ENOTEMPTY, EBUSY)) log_debug_errno(errno, "Failed to trim cgroup %s: %m", path); if (r >= 0) r = -errno; } q = cg_hybrid_unified(); if (q < 0) return q; if (q > 0 && streq(controller, SYSTEMD_CGROUP_CONTROLLER)) (void) cg_trim(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path, delete_root); return r; } /* Create a cgroup in the hierarchy of controller. * Returns 0 if the group already existed, 1 on success, negative otherwise. */ 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; r = RET_NERRNO(mkdir(fs, 0755)); if (r == -EEXIST) return 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_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_cached(); xsprintf(c, PID_FMT "\n", pid); r = write_string_file(fs, c, WRITE_STRING_FILE_DISABLE_BUFFER); if (r == -EOPNOTSUPP && cg_is_threaded(controller, path) > 0) /* When the threaded mode is used, we cannot read/write the file. Let's return recognizable error. */ return -EUCLEAN; 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 "PID_FMT" 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_access( const char *controller, const char *path, uid_t uid, gid_t gid) { struct Attribute { const char *name; bool fatal; }; /* cgroup v1, aka legacy/non-unified */ static const struct Attribute legacy_attributes[] = { { "cgroup.procs", true }, { "tasks", false }, { "cgroup.clone_children", false }, {}, }; /* cgroup v2, aka unified */ static const struct Attribute unified_attributes[] = { { "cgroup.procs", true }, { "cgroup.subtree_control", true }, { "cgroup.threads", false }, {}, }; static const struct Attribute* const attributes[] = { [false] = legacy_attributes, [true] = unified_attributes, }; _cleanup_free_ char *fs = NULL; const struct Attribute *i; int r, unified; assert(path); if (uid == UID_INVALID && gid == GID_INVALID) return 0; unified = cg_unified_controller(controller); if (unified < 0) return unified; /* Configure access to the cgroup itself */ r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; r = chmod_and_chown(fs, 0755, uid, gid); if (r < 0) return r; /* Configure access to the cgroup's attributes */ for (i = attributes[unified]; i->name; i++) { fs = mfree(fs); r = cg_get_path(controller, path, i->name, &fs); if (r < 0) return r; r = chmod_and_chown(fs, 0644, uid, gid); if (r < 0) { if (i->fatal) return r; log_debug_errno(r, "Failed to set access on cgroup %s, ignoring: %m", fs); } } if (streq(controller, SYSTEMD_CGROUP_CONTROLLER)) { r = cg_hybrid_unified(); if (r < 0) return r; if (r > 0) { /* Always propagate access mode from unified to legacy controller */ r = cg_set_access(SYSTEMD_CGROUP_CONTROLLER_LEGACY, path, uid, gid); if (r < 0) log_debug_errno(r, "Failed to set access on compatibility systemd cgroup %s, ignoring: %m", path); } } return 0; } struct access_callback_data { uid_t uid; gid_t gid; int error; }; static int access_callback( RecurseDirEvent event, const char *path, int dir_fd, int inode_fd, const struct dirent *de, const struct statx *sx, void *userdata) { struct access_callback_data *d = ASSERT_PTR(userdata); if (!IN_SET(event, RECURSE_DIR_ENTER, RECURSE_DIR_ENTRY)) return RECURSE_DIR_CONTINUE; assert(inode_fd >= 0); /* fchown() doesn't support O_PATH fds, hence we use the /proc/self/fd/ trick */ if (chown(FORMAT_PROC_FD_PATH(inode_fd), d->uid, d->gid) < 0) { log_debug_errno(errno, "Failed to change ownership of '%s', ignoring: %m", ASSERT_PTR(path)); if (d->error == 0) /* Return last error to caller */ d->error = errno; } return RECURSE_DIR_CONTINUE; } int cg_set_access_recursive( const char *controller, const char *path, uid_t uid, gid_t gid) { _cleanup_close_ int fd = -EBADF; _cleanup_free_ char *fs = NULL; int r; /* A recursive version of cg_set_access(). But note that this one changes ownership of *all* files, * not just the allowlist that cg_set_access() uses. Use cg_set_access() on the cgroup you want to * delegate, and cg_set_access_recursive() for any subcrgoups you might want to create below it. */ if (!uid_is_valid(uid) && !gid_is_valid(gid)) return 0; r = cg_get_path(controller, path, NULL, &fs); if (r < 0) return r; fd = open(fs, O_DIRECTORY|O_CLOEXEC|O_RDONLY); if (fd < 0) return -errno; struct access_callback_data d = { .uid = uid, .gid = gid, }; r = recurse_dir(fd, fs, /* statx_mask= */ 0, /* n_depth_max= */ UINT_MAX, RECURSE_DIR_SAME_MOUNT|RECURSE_DIR_INODE_FD|RECURSE_DIR_TOPLEVEL, access_callback, &d); if (r < 0) return r; return -d.error; } 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_cached(); 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 && empty_or_root(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 = path_join(empty_to_root(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 && !IN_SET(r, -ENOENT, -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; } int cg_create_everywhere(CGroupMask supported, CGroupMask mask, const char *path) { CGroupController c; CGroupMask done; bool created; 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. * * Returns 0 if the group already existed in the systemd hierarchy, * 1 on success, negative otherwise. */ /* First create the cgroup in our own hierarchy. */ r = cg_create(SYSTEMD_CGROUP_CONTROLLER, path); if (r < 0) return r; created = 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 created; supported &= CGROUP_MASK_V1; mask = CGROUP_MASK_EXTEND_JOINED(mask); done = 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; if (!FLAGS_SET(supported, bit)) continue; if (FLAGS_SET(done, bit)) continue; n = cgroup_controller_to_string(c); if (FLAGS_SET(mask, bit)) (void) cg_create(n, path); done |= CGROUP_MASK_EXTEND_JOINED(bit); } return created; } int cg_attach_everywhere(CGroupMask supported, const char *path, pid_t pid, cg_migrate_callback_t path_callback, void *userdata) { 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; supported &= CGROUP_MASK_V1; CGroupMask done = 0; for (CGroupController c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); const char *p = NULL; if (!FLAGS_SET(supported, bit)) continue; if (FLAGS_SET(done, 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); done |= CGROUP_MASK_EXTEND_JOINED(bit); } return 0; } int cg_migrate_v1_controllers(CGroupMask supported, CGroupMask mask, const char *from, cg_migrate_callback_t to_callback, void *userdata) { CGroupController c; CGroupMask done; int r = 0, q; assert(to_callback); supported &= CGROUP_MASK_V1; mask = CGROUP_MASK_EXTEND_JOINED(mask); done = 0; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); const char *to = NULL; if (!FLAGS_SET(supported, bit)) continue; if (FLAGS_SET(done, bit)) continue; if (!FLAGS_SET(mask, bit)) continue; to = to_callback(bit, userdata); /* Remember first error and try continuing */ q = cg_migrate_recursive_fallback(SYSTEMD_CGROUP_CONTROLLER, from, cgroup_controller_to_string(c), to, 0); r = (r < 0) ? r : q; done |= CGROUP_MASK_EXTEND_JOINED(bit); } return r; } int cg_trim_everywhere(CGroupMask supported, const char *path, bool delete_root) { 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; return cg_trim_v1_controllers(supported, _CGROUP_MASK_ALL, path, delete_root); } int cg_trim_v1_controllers(CGroupMask supported, CGroupMask mask, const char *path, bool delete_root) { CGroupController c; CGroupMask done; int r = 0, q; supported &= CGROUP_MASK_V1; mask = CGROUP_MASK_EXTEND_JOINED(mask); done = 0; for (c = 0; c < _CGROUP_CONTROLLER_MAX; c++) { CGroupMask bit = CGROUP_CONTROLLER_TO_MASK(c); if (!FLAGS_SET(supported, bit)) continue; if (FLAGS_SET(done, bit)) continue; if (FLAGS_SET(mask, bit)) { /* Remember first error and try continuing */ q = cg_trim(cgroup_controller_to_string(c), path, delete_root); r = (r < 0) ? r : q; } done |= CGROUP_MASK_EXTEND_JOINED(bit); } return r; } int cg_enable_everywhere( CGroupMask supported, CGroupMask mask, const char *p, CGroupMask *ret_result_mask) { _cleanup_fclose_ FILE *f = NULL; _cleanup_free_ char *fs = NULL; CGroupController c; CGroupMask ret = 0; int r; assert(p); if (supported == 0) { if (ret_result_mask) *ret_result_mask = 0; return 0; } r = cg_all_unified(); if (r < 0) return r; if (r == 0) { /* On the legacy hierarchy there's no concept of "enabling" controllers in cgroups defined. Let's claim * complete success right away. (If you wonder why we return the full mask here, rather than zero: the * caller tends to use the returned mask later on to compare if all controllers where properly joined, * and if not requeues realization. This use is the primary purpose of the return value, hence let's * minimize surprises here and reduce triggers for re-realization by always saying we fully * succeeded.) */ if (ret_result_mask) *ret_result_mask = mask & supported & CGROUP_MASK_V2; /* If you wonder why we mask this with * CGROUP_MASK_V2: The 'supported' mask * might contain pure-V1 or BPF * controllers, and we never want to * claim that we could enable those with * cgroup.subtree_control */ 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 (!FLAGS_SET(CGROUP_MASK_V2, bit)) continue; if (!FLAGS_SET(supported, bit)) continue; n = cgroup_controller_to_string(c); { char s[1 + strlen(n) + 1]; s[0] = FLAGS_SET(mask, bit) ? '+' : '-'; strcpy(s + 1, n); if (!f) { f = fopen(fs, "we"); if (!f) return log_debug_errno(errno, "Failed to open cgroup.subtree_control file of %s: %m", p); } r = write_string_stream(f, s, WRITE_STRING_FILE_DISABLE_BUFFER); if (r < 0) { log_debug_errno(r, "Failed to %s controller %s for %s (%s): %m", FLAGS_SET(mask, bit) ? "enable" : "disable", n, p, fs); clearerr(f); /* If we can't turn off a controller, leave it on in the reported resulting mask. This * happens for example when we attempt to turn off a controller up in the tree that is * used down in the tree. */ if (!FLAGS_SET(mask, bit) && r == -EBUSY) /* You might wonder why we check for EBUSY * only here, and not follow the same logic * for other errors such as EINVAL or * EOPNOTSUPP or anything else. That's * because EBUSY indicates that the * controllers is currently enabled and * cannot be disabled because something down * the hierarchy is still using it. Any other * error most likely means something like "I * never heard of this controller" or * similar. In the former case it's hence * safe to assume the controller is still on * after the failed operation, while in the * latter case it's safer to assume the * controller is unknown and hence certainly * not enabled. */ ret |= bit; } else { /* Otherwise, if we managed to turn on a controller, set the bit reflecting that. */ if (FLAGS_SET(mask, bit)) ret |= bit; } } } /* Let's return the precise set of controllers now enabled for the cgroup. */ if (ret_result_mask) *ret_result_mask = ret; return 0; }