/*** 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 "alloc-util.h" #include "fd-util.h" #include "fileio.h" #include "fs-util.h" #include "log.h" #include "macro.h" #include "parse-util.h" #include "path-util.h" #include "string-util.h" #include "strv.h" #include "time-util.h" static clockid_t map_clock_id(clockid_t c) { /* Some more exotic archs (s390, ppc, …) lack the "ALARM" flavour of the clocks. Thus, clock_gettime() will * fail for them. Since they are essentially the same as their non-ALARM pendants (their only difference is * when timers are set on them), let's just map them accordingly. This way, we can get the correct time even on * those archs. */ switch (c) { case CLOCK_BOOTTIME_ALARM: return CLOCK_BOOTTIME; case CLOCK_REALTIME_ALARM: return CLOCK_REALTIME; default: return c; } } usec_t now(clockid_t clock_id) { struct timespec ts; assert_se(clock_gettime(map_clock_id(clock_id), &ts) == 0); return timespec_load(&ts); } nsec_t now_nsec(clockid_t clock_id) { struct timespec ts; assert_se(clock_gettime(map_clock_id(clock_id), &ts) == 0); return timespec_load_nsec(&ts); } dual_timestamp* dual_timestamp_get(dual_timestamp *ts) { assert(ts); ts->realtime = now(CLOCK_REALTIME); ts->monotonic = now(CLOCK_MONOTONIC); return ts; } triple_timestamp* triple_timestamp_get(triple_timestamp *ts) { assert(ts); ts->realtime = now(CLOCK_REALTIME); ts->monotonic = now(CLOCK_MONOTONIC); ts->boottime = clock_boottime_supported() ? now(CLOCK_BOOTTIME) : USEC_INFINITY; return ts; } dual_timestamp* dual_timestamp_from_realtime(dual_timestamp *ts, usec_t u) { int64_t delta; assert(ts); if (u == USEC_INFINITY || u <= 0) { ts->realtime = ts->monotonic = u; return ts; } ts->realtime = u; delta = (int64_t) now(CLOCK_REALTIME) - (int64_t) u; ts->monotonic = usec_sub_signed(now(CLOCK_MONOTONIC), delta); return ts; } triple_timestamp* triple_timestamp_from_realtime(triple_timestamp *ts, usec_t u) { int64_t delta; assert(ts); if (u == USEC_INFINITY || u <= 0) { ts->realtime = ts->monotonic = ts->boottime = u; return ts; } ts->realtime = u; delta = (int64_t) now(CLOCK_REALTIME) - (int64_t) u; ts->monotonic = usec_sub_signed(now(CLOCK_MONOTONIC), delta); ts->boottime = clock_boottime_supported() ? usec_sub_signed(now(CLOCK_BOOTTIME), delta) : USEC_INFINITY; return ts; } dual_timestamp* dual_timestamp_from_monotonic(dual_timestamp *ts, usec_t u) { int64_t delta; assert(ts); if (u == USEC_INFINITY) { ts->realtime = ts->monotonic = USEC_INFINITY; return ts; } ts->monotonic = u; delta = (int64_t) now(CLOCK_MONOTONIC) - (int64_t) u; ts->realtime = usec_sub_signed(now(CLOCK_REALTIME), delta); return ts; } dual_timestamp* dual_timestamp_from_boottime_or_monotonic(dual_timestamp *ts, usec_t u) { int64_t delta; if (u == USEC_INFINITY) { ts->realtime = ts->monotonic = USEC_INFINITY; return ts; } dual_timestamp_get(ts); delta = (int64_t) now(clock_boottime_or_monotonic()) - (int64_t) u; ts->realtime = usec_sub_signed(ts->realtime, delta); ts->monotonic = usec_sub_signed(ts->monotonic, delta); return ts; } usec_t triple_timestamp_by_clock(triple_timestamp *ts, clockid_t clock) { switch (clock) { case CLOCK_REALTIME: case CLOCK_REALTIME_ALARM: return ts->realtime; case CLOCK_MONOTONIC: return ts->monotonic; case CLOCK_BOOTTIME: case CLOCK_BOOTTIME_ALARM: return ts->boottime; default: return USEC_INFINITY; } } usec_t timespec_load(const struct timespec *ts) { assert(ts); if (ts->tv_sec < 0 || ts->tv_nsec < 0) return USEC_INFINITY; if ((usec_t) ts->tv_sec > (UINT64_MAX - (ts->tv_nsec / NSEC_PER_USEC)) / USEC_PER_SEC) return USEC_INFINITY; return (usec_t) ts->tv_sec * USEC_PER_SEC + (usec_t) ts->tv_nsec / NSEC_PER_USEC; } nsec_t timespec_load_nsec(const struct timespec *ts) { assert(ts); if (ts->tv_sec < 0 || ts->tv_nsec < 0) return NSEC_INFINITY; if ((nsec_t) ts->tv_sec >= (UINT64_MAX - ts->tv_nsec) / NSEC_PER_SEC) return NSEC_INFINITY; return (nsec_t) ts->tv_sec * NSEC_PER_SEC + (nsec_t) ts->tv_nsec; } struct timespec *timespec_store(struct timespec *ts, usec_t u) { assert(ts); if (u == USEC_INFINITY || u / USEC_PER_SEC >= TIME_T_MAX) { ts->tv_sec = (time_t) -1; ts->tv_nsec = (long) -1; return ts; } ts->tv_sec = (time_t) (u / USEC_PER_SEC); ts->tv_nsec = (long int) ((u % USEC_PER_SEC) * NSEC_PER_USEC); return ts; } usec_t timeval_load(const struct timeval *tv) { assert(tv); if (tv->tv_sec < 0 || tv->tv_usec < 0) return USEC_INFINITY; if ((usec_t) tv->tv_sec > (UINT64_MAX - tv->tv_usec) / USEC_PER_SEC) return USEC_INFINITY; return (usec_t) tv->tv_sec * USEC_PER_SEC + (usec_t) tv->tv_usec; } struct timeval *timeval_store(struct timeval *tv, usec_t u) { assert(tv); if (u == USEC_INFINITY|| u / USEC_PER_SEC > TIME_T_MAX) { tv->tv_sec = (time_t) -1; tv->tv_usec = (suseconds_t) -1; } else { tv->tv_sec = (time_t) (u / USEC_PER_SEC); tv->tv_usec = (suseconds_t) (u % USEC_PER_SEC); } return tv; } static char *format_timestamp_internal( char *buf, size_t l, usec_t t, bool utc, bool us) { /* The weekdays in non-localized (English) form. We use this instead of the localized form, so that our * generated timestamps may be parsed with parse_timestamp(), and always read the same. */ static const char * const weekdays[] = { [0] = "Sun", [1] = "Mon", [2] = "Tue", [3] = "Wed", [4] = "Thu", [5] = "Fri", [6] = "Sat", }; struct tm tm; time_t sec; size_t n; assert(buf); if (l < 3 + /* week day */ 1 + 10 + /* space and date */ 1 + 8 + /* space and time */ (us ? 1 + 6 : 0) + /* "." and microsecond part */ 1 + 1 + /* space and shortest possible zone */ 1) return NULL; /* Not enough space even for the shortest form. */ if (t <= 0 || t == USEC_INFINITY) return NULL; /* Timestamp is unset */ /* Let's not format times with years > 9999 */ if (t > USEC_TIMESTAMP_FORMATTABLE_MAX) return NULL; sec = (time_t) (t / USEC_PER_SEC); /* Round down */ if (!localtime_or_gmtime_r(&sec, &tm, utc)) return NULL; /* Start with the week day */ assert((size_t) tm.tm_wday < ELEMENTSOF(weekdays)); memcpy(buf, weekdays[tm.tm_wday], 4); /* Add the main components */ if (strftime(buf + 3, l - 3, " %Y-%m-%d %H:%M:%S", &tm) <= 0) return NULL; /* Doesn't fit */ /* Append the microseconds part, if that's requested */ if (us) { n = strlen(buf); if (n + 8 > l) return NULL; /* Microseconds part doesn't fit. */ sprintf(buf + n, ".%06"PRI_USEC, t % USEC_PER_SEC); } /* Append the timezone */ n = strlen(buf); if (utc) { /* If this is UTC then let's explicitly use the "UTC" string here, because gmtime_r() normally uses the * obsolete "GMT" instead. */ if (n + 5 > l) return NULL; /* "UTC" doesn't fit. */ strcpy(buf + n, " UTC"); } else if (!isempty(tm.tm_zone)) { size_t tn; /* An explicit timezone is specified, let's use it, if it fits */ tn = strlen(tm.tm_zone); if (n + 1 + tn + 1 > l) { /* The full time zone does not fit in. Yuck. */ if (n + 1 + _POSIX_TZNAME_MAX + 1 > l) return NULL; /* Not even enough space for the POSIX minimum (of 6)? In that case, complain that it doesn't fit */ /* So the time zone doesn't fit in fully, but the caller passed enough space for the POSIX * minimum time zone length. In this case suppress the timezone entirely, in order not to dump * an overly long, hard to read string on the user. This should be safe, because the user will * assume the local timezone anyway if none is shown. And so does parse_timestamp(). */ } else { buf[n++] = ' '; strcpy(buf + n, tm.tm_zone); } } return buf; } char *format_timestamp(char *buf, size_t l, usec_t t) { return format_timestamp_internal(buf, l, t, false, false); } char *format_timestamp_utc(char *buf, size_t l, usec_t t) { return format_timestamp_internal(buf, l, t, true, false); } char *format_timestamp_us(char *buf, size_t l, usec_t t) { return format_timestamp_internal(buf, l, t, false, true); } char *format_timestamp_us_utc(char *buf, size_t l, usec_t t) { return format_timestamp_internal(buf, l, t, true, true); } char *format_timestamp_relative(char *buf, size_t l, usec_t t) { const char *s; usec_t n, d; if (t <= 0 || t == USEC_INFINITY) return NULL; n = now(CLOCK_REALTIME); if (n > t) { d = n - t; s = "ago"; } else { d = t - n; s = "left"; } if (d >= USEC_PER_YEAR) snprintf(buf, l, USEC_FMT " years " USEC_FMT " months %s", d / USEC_PER_YEAR, (d % USEC_PER_YEAR) / USEC_PER_MONTH, s); else if (d >= USEC_PER_MONTH) snprintf(buf, l, USEC_FMT " months " USEC_FMT " days %s", d / USEC_PER_MONTH, (d % USEC_PER_MONTH) / USEC_PER_DAY, s); else if (d >= USEC_PER_WEEK) snprintf(buf, l, USEC_FMT " weeks " USEC_FMT " days %s", d / USEC_PER_WEEK, (d % USEC_PER_WEEK) / USEC_PER_DAY, s); else if (d >= 2*USEC_PER_DAY) snprintf(buf, l, USEC_FMT " days %s", d / USEC_PER_DAY, s); else if (d >= 25*USEC_PER_HOUR) snprintf(buf, l, "1 day " USEC_FMT "h %s", (d - USEC_PER_DAY) / USEC_PER_HOUR, s); else if (d >= 6*USEC_PER_HOUR) snprintf(buf, l, USEC_FMT "h %s", d / USEC_PER_HOUR, s); else if (d >= USEC_PER_HOUR) snprintf(buf, l, USEC_FMT "h " USEC_FMT "min %s", d / USEC_PER_HOUR, (d % USEC_PER_HOUR) / USEC_PER_MINUTE, s); else if (d >= 5*USEC_PER_MINUTE) snprintf(buf, l, USEC_FMT "min %s", d / USEC_PER_MINUTE, s); else if (d >= USEC_PER_MINUTE) snprintf(buf, l, USEC_FMT "min " USEC_FMT "s %s", d / USEC_PER_MINUTE, (d % USEC_PER_MINUTE) / USEC_PER_SEC, s); else if (d >= USEC_PER_SEC) snprintf(buf, l, USEC_FMT "s %s", d / USEC_PER_SEC, s); else if (d >= USEC_PER_MSEC) snprintf(buf, l, USEC_FMT "ms %s", d / USEC_PER_MSEC, s); else if (d > 0) snprintf(buf, l, USEC_FMT"us %s", d, s); else snprintf(buf, l, "now"); buf[l-1] = 0; return buf; } char *format_timespan(char *buf, size_t l, usec_t t, usec_t accuracy) { static const struct { const char *suffix; usec_t usec; } table[] = { { "y", USEC_PER_YEAR }, { "month", USEC_PER_MONTH }, { "w", USEC_PER_WEEK }, { "d", USEC_PER_DAY }, { "h", USEC_PER_HOUR }, { "min", USEC_PER_MINUTE }, { "s", USEC_PER_SEC }, { "ms", USEC_PER_MSEC }, { "us", 1 }, }; unsigned i; char *p = buf; bool something = false; assert(buf); assert(l > 0); if (t == USEC_INFINITY) { strncpy(p, "infinity", l-1); p[l-1] = 0; return p; } if (t <= 0) { strncpy(p, "0", l-1); p[l-1] = 0; return p; } /* The result of this function can be parsed with parse_sec */ for (i = 0; i < ELEMENTSOF(table); i++) { int k = 0; size_t n; bool done = false; usec_t a, b; if (t <= 0) break; if (t < accuracy && something) break; if (t < table[i].usec) continue; if (l <= 1) break; a = t / table[i].usec; b = t % table[i].usec; /* Let's see if we should shows this in dot notation */ if (t < USEC_PER_MINUTE && b > 0) { usec_t cc; int j; j = 0; for (cc = table[i].usec; cc > 1; cc /= 10) j++; for (cc = accuracy; cc > 1; cc /= 10) { b /= 10; j--; } if (j > 0) { k = snprintf(p, l, "%s"USEC_FMT".%0*"PRI_USEC"%s", p > buf ? " " : "", a, j, b, table[i].suffix); t = 0; done = true; } } /* No? Then let's show it normally */ if (!done) { k = snprintf(p, l, "%s"USEC_FMT"%s", p > buf ? " " : "", a, table[i].suffix); t = b; } n = MIN((size_t) k, l); l -= n; p += n; something = true; } *p = 0; return buf; } void dual_timestamp_serialize(FILE *f, const char *name, dual_timestamp *t) { assert(f); assert(name); assert(t); if (!dual_timestamp_is_set(t)) return; fprintf(f, "%s="USEC_FMT" "USEC_FMT"\n", name, t->realtime, t->monotonic); } int dual_timestamp_deserialize(const char *value, dual_timestamp *t) { uint64_t a, b; int r, pos; assert(value); assert(t); pos = strspn(value, WHITESPACE); if (value[pos] == '-') return -EINVAL; pos += strspn(value + pos, DIGITS); pos += strspn(value + pos, WHITESPACE); if (value[pos] == '-') return -EINVAL; r = sscanf(value, "%" PRIu64 "%" PRIu64 "%n", &a, &b, &pos); if (r != 2) { log_debug("Failed to parse dual timestamp value \"%s\".", value); return -EINVAL; } if (value[pos] != '\0') /* trailing garbage */ return -EINVAL; t->realtime = a; t->monotonic = b; return 0; } int timestamp_deserialize(const char *value, usec_t *timestamp) { int r; assert(value); r = safe_atou64(value, timestamp); if (r < 0) return log_debug_errno(r, "Failed to parse timestamp value \"%s\": %m", value); return r; } int parse_timestamp(const char *t, usec_t *usec) { static const struct { const char *name; const int nr; } day_nr[] = { { "Sunday", 0 }, { "Sun", 0 }, { "Monday", 1 }, { "Mon", 1 }, { "Tuesday", 2 }, { "Tue", 2 }, { "Wednesday", 3 }, { "Wed", 3 }, { "Thursday", 4 }, { "Thu", 4 }, { "Friday", 5 }, { "Fri", 5 }, { "Saturday", 6 }, { "Sat", 6 }, }; const char *k, *utc, *tzn = NULL; struct tm tm, copy; time_t x; usec_t x_usec, plus = 0, minus = 0, ret; int r, weekday = -1, dst = -1; unsigned i; /* * Allowed syntaxes: * * 2012-09-22 16:34:22 * 2012-09-22 16:34 (seconds will be set to 0) * 2012-09-22 (time will be set to 00:00:00) * 16:34:22 (date will be set to today) * 16:34 (date will be set to today, seconds to 0) * now * yesterday (time is set to 00:00:00) * today (time is set to 00:00:00) * tomorrow (time is set to 00:00:00) * +5min * -5days * @2147483647 (seconds since epoch) * */ assert(t); assert(usec); if (t[0] == '@') return parse_sec(t + 1, usec); ret = now(CLOCK_REALTIME); if (streq(t, "now")) goto finish; else if (t[0] == '+') { r = parse_sec(t+1, &plus); if (r < 0) return r; goto finish; } else if (t[0] == '-') { r = parse_sec(t+1, &minus); if (r < 0) return r; goto finish; } else if ((k = endswith(t, " ago"))) { t = strndupa(t, k - t); r = parse_sec(t, &minus); if (r < 0) return r; goto finish; } else if ((k = endswith(t, " left"))) { t = strndupa(t, k - t); r = parse_sec(t, &plus); if (r < 0) return r; goto finish; } /* See if the timestamp is suffixed with UTC */ utc = endswith_no_case(t, " UTC"); if (utc) t = strndupa(t, utc - t); else { const char *e = NULL; int j; tzset(); /* See if the timestamp is suffixed by either the DST or non-DST local timezone. Note that we only * support the local timezones here, nothing else. Not because we wouldn't want to, but simply because * there are no nice APIs available to cover this. By accepting the local time zone strings, we make * sure that all timestamps written by format_timestamp() can be parsed correctly, even though we don't * support arbitrary timezone specifications. */ for (j = 0; j <= 1; j++) { if (isempty(tzname[j])) continue; e = endswith_no_case(t, tzname[j]); if (!e) continue; if (e == t) continue; if (e[-1] != ' ') continue; break; } if (IN_SET(j, 0, 1)) { /* Found one of the two timezones specified. */ t = strndupa(t, e - t - 1); dst = j; tzn = tzname[j]; } } x = (time_t) (ret / USEC_PER_SEC); x_usec = 0; if (!localtime_or_gmtime_r(&x, &tm, utc)) return -EINVAL; tm.tm_isdst = dst; if (tzn) tm.tm_zone = tzn; if (streq(t, "today")) { tm.tm_sec = tm.tm_min = tm.tm_hour = 0; goto from_tm; } else if (streq(t, "yesterday")) { tm.tm_mday--; tm.tm_sec = tm.tm_min = tm.tm_hour = 0; goto from_tm; } else if (streq(t, "tomorrow")) { tm.tm_mday++; tm.tm_sec = tm.tm_min = tm.tm_hour = 0; goto from_tm; } for (i = 0; i < ELEMENTSOF(day_nr); i++) { size_t skip; if (!startswith_no_case(t, day_nr[i].name)) continue; skip = strlen(day_nr[i].name); if (t[skip] != ' ') continue; weekday = day_nr[i].nr; t += skip + 1; break; } copy = tm; k = strptime(t, "%y-%m-%d %H:%M:%S", &tm); if (k) { if (*k == '.') goto parse_usec; else if (*k == 0) goto from_tm; } tm = copy; k = strptime(t, "%Y-%m-%d %H:%M:%S", &tm); if (k) { if (*k == '.') goto parse_usec; else if (*k == 0) goto from_tm; } tm = copy; k = strptime(t, "%y-%m-%d %H:%M", &tm); if (k && *k == 0) { tm.tm_sec = 0; goto from_tm; } tm = copy; k = strptime(t, "%Y-%m-%d %H:%M", &tm); if (k && *k == 0) { tm.tm_sec = 0; goto from_tm; } tm = copy; k = strptime(t, "%y-%m-%d", &tm); if (k && *k == 0) { tm.tm_sec = tm.tm_min = tm.tm_hour = 0; goto from_tm; } tm = copy; k = strptime(t, "%Y-%m-%d", &tm); if (k && *k == 0) { tm.tm_sec = tm.tm_min = tm.tm_hour = 0; goto from_tm; } tm = copy; k = strptime(t, "%H:%M:%S", &tm); if (k) { if (*k == '.') goto parse_usec; else if (*k == 0) goto from_tm; } tm = copy; k = strptime(t, "%H:%M", &tm); if (k && *k == 0) { tm.tm_sec = 0; goto from_tm; } return -EINVAL; parse_usec: { unsigned add; k++; r = parse_fractional_part_u(&k, 6, &add); if (r < 0) return -EINVAL; if (*k) return -EINVAL; x_usec = add; } from_tm: x = mktime_or_timegm(&tm, utc); if (x == (time_t) -1) return -EOVERFLOW; if (weekday >= 0 && tm.tm_wday != weekday) return -EINVAL; if (x < 0) ret = 0; else ret = (usec_t) x * USEC_PER_SEC + x_usec; if (ret > USEC_TIMESTAMP_FORMATTABLE_MAX) return -EINVAL; finish: if (ret + plus < ret) /* overflow? */ return -EOVERFLOW; ret += plus; if (ret > USEC_TIMESTAMP_FORMATTABLE_MAX) return -EINVAL; if (ret > minus) ret -= minus; else ret = 0; *usec = ret; return 0; } static char* extract_multiplier(char *p, usec_t *multiplier) { static const struct { const char *suffix; usec_t usec; } table[] = { { "seconds", USEC_PER_SEC }, { "second", USEC_PER_SEC }, { "sec", USEC_PER_SEC }, { "s", USEC_PER_SEC }, { "minutes", USEC_PER_MINUTE }, { "minute", USEC_PER_MINUTE }, { "min", USEC_PER_MINUTE }, { "months", USEC_PER_MONTH }, { "month", USEC_PER_MONTH }, { "M", USEC_PER_MONTH }, { "msec", USEC_PER_MSEC }, { "ms", USEC_PER_MSEC }, { "m", USEC_PER_MINUTE }, { "hours", USEC_PER_HOUR }, { "hour", USEC_PER_HOUR }, { "hr", USEC_PER_HOUR }, { "h", USEC_PER_HOUR }, { "days", USEC_PER_DAY }, { "day", USEC_PER_DAY }, { "d", USEC_PER_DAY }, { "weeks", USEC_PER_WEEK }, { "week", USEC_PER_WEEK }, { "w", USEC_PER_WEEK }, { "years", USEC_PER_YEAR }, { "year", USEC_PER_YEAR }, { "y", USEC_PER_YEAR }, { "usec", 1ULL }, { "us", 1ULL }, { "µs", 1ULL }, }; unsigned i; for (i = 0; i < ELEMENTSOF(table); i++) { char *e; e = startswith(p, table[i].suffix); if (e) { *multiplier = table[i].usec; return e; } } return p; } int parse_time(const char *t, usec_t *usec, usec_t default_unit) { const char *p, *s; usec_t r = 0; bool something = false; assert(t); assert(usec); assert(default_unit > 0); p = t; p += strspn(p, WHITESPACE); s = startswith(p, "infinity"); if (s) { s += strspn(s, WHITESPACE); if (*s != 0) return -EINVAL; *usec = USEC_INFINITY; return 0; } for (;;) { long long l, z = 0; char *e; unsigned n = 0; usec_t multiplier = default_unit, k; p += strspn(p, WHITESPACE); if (*p == 0) { if (!something) return -EINVAL; break; } errno = 0; l = strtoll(p, &e, 10); if (errno > 0) return -errno; if (l < 0) return -ERANGE; if (*e == '.') { char *b = e + 1; errno = 0; z = strtoll(b, &e, 10); if (errno > 0) return -errno; if (z < 0) return -ERANGE; if (e == b) return -EINVAL; n = e - b; } else if (e == p) return -EINVAL; e += strspn(e, WHITESPACE); p = extract_multiplier(e, &multiplier); something = true; k = (usec_t) z * multiplier; for (; n > 0; n--) k /= 10; r += (usec_t) l * multiplier + k; } *usec = r; return 0; } int parse_sec(const char *t, usec_t *usec) { return parse_time(t, usec, USEC_PER_SEC); } int parse_sec_fix_0(const char *t, usec_t *usec) { t += strspn(t, WHITESPACE); if (streq(t, "0")) { *usec = USEC_INFINITY; return 0; } return parse_sec(t, usec); } int parse_nsec(const char *t, nsec_t *nsec) { static const struct { const char *suffix; nsec_t nsec; } table[] = { { "seconds", NSEC_PER_SEC }, { "second", NSEC_PER_SEC }, { "sec", NSEC_PER_SEC }, { "s", NSEC_PER_SEC }, { "minutes", NSEC_PER_MINUTE }, { "minute", NSEC_PER_MINUTE }, { "min", NSEC_PER_MINUTE }, { "months", NSEC_PER_MONTH }, { "month", NSEC_PER_MONTH }, { "msec", NSEC_PER_MSEC }, { "ms", NSEC_PER_MSEC }, { "m", NSEC_PER_MINUTE }, { "hours", NSEC_PER_HOUR }, { "hour", NSEC_PER_HOUR }, { "hr", NSEC_PER_HOUR }, { "h", NSEC_PER_HOUR }, { "days", NSEC_PER_DAY }, { "day", NSEC_PER_DAY }, { "d", NSEC_PER_DAY }, { "weeks", NSEC_PER_WEEK }, { "week", NSEC_PER_WEEK }, { "w", NSEC_PER_WEEK }, { "years", NSEC_PER_YEAR }, { "year", NSEC_PER_YEAR }, { "y", NSEC_PER_YEAR }, { "usec", NSEC_PER_USEC }, { "us", NSEC_PER_USEC }, { "µs", NSEC_PER_USEC }, { "nsec", 1ULL }, { "ns", 1ULL }, { "", 1ULL }, /* default is nsec */ }; const char *p, *s; nsec_t r = 0; bool something = false; assert(t); assert(nsec); p = t; p += strspn(p, WHITESPACE); s = startswith(p, "infinity"); if (s) { s += strspn(s, WHITESPACE); if (*s != 0) return -EINVAL; *nsec = NSEC_INFINITY; return 0; } for (;;) { long long l, z = 0; char *e; unsigned i, n = 0; p += strspn(p, WHITESPACE); if (*p == 0) { if (!something) return -EINVAL; break; } errno = 0; l = strtoll(p, &e, 10); if (errno > 0) return -errno; if (l < 0) return -ERANGE; if (*e == '.') { char *b = e + 1; errno = 0; z = strtoll(b, &e, 10); if (errno > 0) return -errno; if (z < 0) return -ERANGE; if (e == b) return -EINVAL; n = e - b; } else if (e == p) return -EINVAL; e += strspn(e, WHITESPACE); for (i = 0; i < ELEMENTSOF(table); i++) if (startswith(e, table[i].suffix)) { nsec_t k = (nsec_t) z * table[i].nsec; for (; n > 0; n--) k /= 10; r += (nsec_t) l * table[i].nsec + k; p = e + strlen(table[i].suffix); something = true; break; } if (i >= ELEMENTSOF(table)) return -EINVAL; } *nsec = r; return 0; } bool ntp_synced(void) { struct timex txc = {}; if (adjtimex(&txc) < 0) return false; if (txc.status & STA_UNSYNC) return false; return true; } int get_timezones(char ***ret) { _cleanup_fclose_ FILE *f = NULL; _cleanup_strv_free_ char **zones = NULL; size_t n_zones = 0, n_allocated = 0; assert(ret); zones = strv_new("UTC", NULL); if (!zones) return -ENOMEM; n_allocated = 2; n_zones = 1; f = fopen("/usr/share/zoneinfo/zone.tab", "re"); if (f) { char l[LINE_MAX]; FOREACH_LINE(l, f, return -errno) { char *p, *w; size_t k; p = strstrip(l); if (isempty(p) || *p == '#') continue; /* Skip over country code */ p += strcspn(p, WHITESPACE); p += strspn(p, WHITESPACE); /* Skip over coordinates */ p += strcspn(p, WHITESPACE); p += strspn(p, WHITESPACE); /* Found timezone name */ k = strcspn(p, WHITESPACE); if (k <= 0) continue; w = strndup(p, k); if (!w) return -ENOMEM; if (!GREEDY_REALLOC(zones, n_allocated, n_zones + 2)) { free(w); return -ENOMEM; } zones[n_zones++] = w; zones[n_zones] = NULL; } strv_sort(zones); } else if (errno != ENOENT) return -errno; *ret = zones; zones = NULL; return 0; } bool timezone_is_valid(const char *name) { bool slash = false; const char *p, *t; struct stat st; if (isempty(name)) return false; if (name[0] == '/') return false; for (p = name; *p; p++) { if (!(*p >= '0' && *p <= '9') && !(*p >= 'a' && *p <= 'z') && !(*p >= 'A' && *p <= 'Z') && !(*p == '-' || *p == '_' || *p == '+' || *p == '/')) return false; if (*p == '/') { if (slash) return false; slash = true; } else slash = false; } if (slash) return false; t = strjoina("/usr/share/zoneinfo/", name); if (stat(t, &st) < 0) return false; if (!S_ISREG(st.st_mode)) return false; return true; } bool clock_boottime_supported(void) { static int supported = -1; /* Note that this checks whether CLOCK_BOOTTIME is available in general as well as available for timerfds()! */ if (supported < 0) { int fd; fd = timerfd_create(CLOCK_BOOTTIME, TFD_NONBLOCK|TFD_CLOEXEC); if (fd < 0) supported = false; else { safe_close(fd); supported = true; } } return supported; } clockid_t clock_boottime_or_monotonic(void) { if (clock_boottime_supported()) return CLOCK_BOOTTIME; else return CLOCK_MONOTONIC; } bool clock_supported(clockid_t clock) { struct timespec ts; switch (clock) { case CLOCK_MONOTONIC: case CLOCK_REALTIME: return true; case CLOCK_BOOTTIME: return clock_boottime_supported(); case CLOCK_BOOTTIME_ALARM: if (!clock_boottime_supported()) return false; /* fall through */ default: /* For everything else, check properly */ return clock_gettime(clock, &ts) >= 0; } } int get_timezone(char **tz) { _cleanup_free_ char *t = NULL; const char *e; char *z; int r; r = readlink_malloc("/etc/localtime", &t); if (r < 0) return r; /* returns EINVAL if not a symlink */ e = path_startswith(t, "/usr/share/zoneinfo/"); if (!e) e = path_startswith(t, "../usr/share/zoneinfo/"); if (!e) return -EINVAL; if (!timezone_is_valid(e)) return -EINVAL; z = strdup(e); if (!z) return -ENOMEM; *tz = z; return 0; } time_t mktime_or_timegm(struct tm *tm, bool utc) { return utc ? timegm(tm) : mktime(tm); } struct tm *localtime_or_gmtime_r(const time_t *t, struct tm *tm, bool utc) { return utc ? gmtime_r(t, tm) : localtime_r(t, tm); } unsigned long usec_to_jiffies(usec_t u) { static thread_local unsigned long hz = 0; long r; if (hz == 0) { r = sysconf(_SC_CLK_TCK); assert(r > 0); hz = r; } return DIV_ROUND_UP(u , USEC_PER_SEC / hz); } usec_t usec_shift_clock(usec_t x, clockid_t from, clockid_t to) { usec_t a, b; if (x == USEC_INFINITY) return USEC_INFINITY; if (map_clock_id(from) == map_clock_id(to)) return x; a = now(from); b = now(to); if (x > a) /* x lies in the future */ return usec_add(b, usec_sub_unsigned(x, a)); else /* x lies in the past */ return usec_sub_unsigned(b, usec_sub_unsigned(a, x)); }