// Copyright 2011 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package time import ( "errors" "sync" "syscall" ) //go:generate env ZONEINFO=$GOROOT/lib/time/zoneinfo.zip go run genzabbrs.go -output zoneinfo_abbrs_windows.go // A Location maps time instants to the zone in use at that time. // Typically, the Location represents the collection of time offsets // in use in a geographical area. For many Locations the time offset varies // depending on whether daylight savings time is in use at the time instant. // // Location is used to provide a time zone in a printed Time value and for // calculations involving intervals that may cross daylight savings time // boundaries. type Location struct { name string zone []zone tx []zoneTrans // The tzdata information can be followed by a string that describes // how to handle DST transitions not recorded in zoneTrans. // The format is the TZ environment variable without a colon; see // https://pubs.opengroup.org/onlinepubs/9699919799/basedefs/V1_chap08.html. // Example string, for America/Los_Angeles: PST8PDT,M3.2.0,M11.1.0 extend string // Most lookups will be for the current time. // To avoid the binary search through tx, keep a // static one-element cache that gives the correct // zone for the time when the Location was created. // if cacheStart <= t < cacheEnd, // lookup can return cacheZone. // The units for cacheStart and cacheEnd are seconds // since January 1, 1970 UTC, to match the argument // to lookup. cacheStart int64 cacheEnd int64 cacheZone *zone } // A zone represents a single time zone such as CET. type zone struct { name string // abbreviated name, "CET" offset int // seconds east of UTC isDST bool // is this zone Daylight Savings Time? } // A zoneTrans represents a single time zone transition. type zoneTrans struct { when int64 // transition time, in seconds since 1970 GMT index uint8 // the index of the zone that goes into effect at that time isstd, isutc bool // ignored - no idea what these mean } // alpha and omega are the beginning and end of time for zone // transitions. const ( alpha = -1 << 63 // math.MinInt64 omega = 1<<63 - 1 // math.MaxInt64 ) // UTC represents Universal Coordinated Time (UTC). var UTC *Location = &utcLoc // utcLoc is separate so that get can refer to &utcLoc // and ensure that it never returns a nil *Location, // even if a badly behaved client has changed UTC. var utcLoc = Location{name: "UTC"} // Local represents the system's local time zone. // On Unix systems, Local consults the TZ environment // variable to find the time zone to use. No TZ means // use the system default /etc/localtime. // TZ="" means use UTC. // TZ="foo" means use file foo in the system timezone directory. var Local *Location = &localLoc // localLoc is separate so that initLocal can initialize // it even if a client has changed Local. var localLoc Location var localOnce sync.Once func (l *Location) get() *Location { if l == nil { return &utcLoc } if l == &localLoc { localOnce.Do(initLocal) } return l } // String returns a descriptive name for the time zone information, // corresponding to the name argument to LoadLocation or FixedZone. func (l *Location) String() string { return l.get().name } var unnamedFixedZones []*Location var unnamedFixedZonesOnce sync.Once // FixedZone returns a Location that always uses // the given zone name and offset (seconds east of UTC). func FixedZone(name string, offset int) *Location { // Most calls to FixedZone have an unnamed zone with an offset by the hour. // Optimize for that case by returning the same *Location for a given hour. const hoursBeforeUTC = 12 const hoursAfterUTC = 14 hour := offset / 60 / 60 if name == "" && -hoursBeforeUTC <= hour && hour <= +hoursAfterUTC && hour*60*60 == offset { unnamedFixedZonesOnce.Do(func() { unnamedFixedZones = make([]*Location, hoursBeforeUTC+1+hoursAfterUTC) for hr := -hoursBeforeUTC; hr <= +hoursAfterUTC; hr++ { unnamedFixedZones[hr+hoursBeforeUTC] = fixedZone("", hr*60*60) } }) return unnamedFixedZones[hour+hoursBeforeUTC] } return fixedZone(name, offset) } func fixedZone(name string, offset int) *Location { l := &Location{ name: name, zone: []zone{{name, offset, false}}, tx: []zoneTrans{{alpha, 0, false, false}}, cacheStart: alpha, cacheEnd: omega, } l.cacheZone = &l.zone[0] return l } // lookup returns information about the time zone in use at an // instant in time expressed as seconds since January 1, 1970 00:00:00 UTC. // // The returned information gives the name of the zone (such as "CET"), // the start and end times bracketing sec when that zone is in effect, // the offset in seconds east of UTC (such as -5*60*60), and whether // the daylight savings is being observed at that time. func (l *Location) lookup(sec int64) (name string, offset int, start, end int64, isDST bool) { l = l.get() if len(l.zone) == 0 { name = "UTC" offset = 0 start = alpha end = omega isDST = false return } if zone := l.cacheZone; zone != nil && l.cacheStart <= sec && sec < l.cacheEnd { name = zone.name offset = zone.offset start = l.cacheStart end = l.cacheEnd isDST = zone.isDST return } if len(l.tx) == 0 || sec < l.tx[0].when { zone := &l.zone[l.lookupFirstZone()] name = zone.name offset = zone.offset start = alpha if len(l.tx) > 0 { end = l.tx[0].when } else { end = omega } isDST = zone.isDST return } // Binary search for entry with largest time <= sec. // Not using sort.Search to avoid dependencies. tx := l.tx end = omega lo := 0 hi := len(tx) for hi-lo > 1 { m := int(uint(lo+hi) >> 1) lim := tx[m].when if sec < lim { end = lim hi = m } else { lo = m } } zone := &l.zone[tx[lo].index] name = zone.name offset = zone.offset start = tx[lo].when // end = maintained during the search isDST = zone.isDST // If we're at the end of the known zone transitions, // try the extend string. if lo == len(tx)-1 && l.extend != "" { if ename, eoffset, estart, eend, eisDST, ok := tzset(l.extend, start, sec); ok { return ename, eoffset, estart, eend, eisDST } } return } // lookupFirstZone returns the index of the time zone to use for times // before the first transition time, or when there are no transition // times. // // The reference implementation in localtime.c from // https://www.iana.org/time-zones/repository/releases/tzcode2013g.tar.gz // implements the following algorithm for these cases: // 1. If the first zone is unused by the transitions, use it. // 2. Otherwise, if there are transition times, and the first // transition is to a zone in daylight time, find the first // non-daylight-time zone before and closest to the first transition // zone. // 3. Otherwise, use the first zone that is not daylight time, if // there is one. // 4. Otherwise, use the first zone. func (l *Location) lookupFirstZone() int { // Case 1. if !l.firstZoneUsed() { return 0 } // Case 2. if len(l.tx) > 0 && l.zone[l.tx[0].index].isDST { for zi := int(l.tx[0].index) - 1; zi >= 0; zi-- { if !l.zone[zi].isDST { return zi } } } // Case 3. for zi := range l.zone { if !l.zone[zi].isDST { return zi } } // Case 4. return 0 } // firstZoneUsed reports whether the first zone is used by some // transition. func (l *Location) firstZoneUsed() bool { for _, tx := range l.tx { if tx.index == 0 { return true } } return false } // tzset takes a timezone string like the one found in the TZ environment // variable, the time of the last time zone transition expressed as seconds // since January 1, 1970 00:00:00 UTC, and a time expressed the same way. // We call this a tzset string since in C the function tzset reads TZ. // The return values are as for lookup, plus ok which reports whether the // parse succeeded. func tzset(s string, lastTxSec, sec int64) (name string, offset int, start, end int64, isDST, ok bool) { var ( stdName, dstName string stdOffset, dstOffset int ) stdName, s, ok = tzsetName(s) if ok { stdOffset, s, ok = tzsetOffset(s) } if !ok { return "", 0, 0, 0, false, false } // The numbers in the tzset string are added to local time to get UTC, // but our offsets are added to UTC to get local time, // so we negate the number we see here. stdOffset = -stdOffset if len(s) == 0 || s[0] == ',' { // No daylight savings time. return stdName, stdOffset, lastTxSec, omega, false, true } dstName, s, ok = tzsetName(s) if ok { if len(s) == 0 || s[0] == ',' { dstOffset = stdOffset + secondsPerHour } else { dstOffset, s, ok = tzsetOffset(s) dstOffset = -dstOffset // as with stdOffset, above } } if !ok { return "", 0, 0, 0, false, false } if len(s) == 0 { // Default DST rules per tzcode. s = ",M3.2.0,M11.1.0" } // The TZ definition does not mention ';' here but tzcode accepts it. if s[0] != ',' && s[0] != ';' { return "", 0, 0, 0, false, false } s = s[1:] var startRule, endRule rule startRule, s, ok = tzsetRule(s) if !ok || len(s) == 0 || s[0] != ',' { return "", 0, 0, 0, false, false } s = s[1:] endRule, s, ok = tzsetRule(s) if !ok || len(s) > 0 { return "", 0, 0, 0, false, false } year, _, _, yday := absDate(uint64(sec+unixToInternal+internalToAbsolute), false) ysec := int64(yday*secondsPerDay) + sec%secondsPerDay // Compute start of year in seconds since Unix epoch. d := daysSinceEpoch(year) abs := int64(d * secondsPerDay) abs += absoluteToInternal + internalToUnix startSec := int64(tzruleTime(year, startRule, stdOffset)) endSec := int64(tzruleTime(year, endRule, dstOffset)) dstIsDST, stdIsDST := true, false // Note: this is a flipping of "DST" and "STD" while retaining the labels // This happens in southern hemispheres. The labelling here thus is a little // inconsistent with the goal. if endSec < startSec { startSec, endSec = endSec, startSec stdName, dstName = dstName, stdName stdOffset, dstOffset = dstOffset, stdOffset stdIsDST, dstIsDST = dstIsDST, stdIsDST } // The start and end values that we return are accurate // close to a daylight savings transition, but are otherwise // just the start and end of the year. That suffices for // the only caller that cares, which is Date. if ysec < startSec { return stdName, stdOffset, abs, startSec + abs, stdIsDST, true } else if ysec >= endSec { return stdName, stdOffset, endSec + abs, abs + 365*secondsPerDay, stdIsDST, true } else { return dstName, dstOffset, startSec + abs, endSec + abs, dstIsDST, true } } // tzsetName returns the timezone name at the start of the tzset string s, // and the remainder of s, and reports whether the parsing is OK. func tzsetName(s string) (string, string, bool) { if len(s) == 0 { return "", "", false } if s[0] != '<' { for i, r := range s { switch r { case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', ',', '-', '+': if i < 3 { return "", "", false } return s[:i], s[i:], true } } if len(s) < 3 { return "", "", false } return s, "", true } else { for i, r := range s { if r == '>' { return s[1:i], s[i+1:], true } } return "", "", false } } // tzsetOffset returns the timezone offset at the start of the tzset string s, // and the remainder of s, and reports whether the parsing is OK. // The timezone offset is returned as a number of seconds. func tzsetOffset(s string) (offset int, rest string, ok bool) { if len(s) == 0 { return 0, "", false } neg := false if s[0] == '+' { s = s[1:] } else if s[0] == '-' { s = s[1:] neg = true } // The tzdata code permits values up to 24 * 7 here, // although POSIX does not. var hours int hours, s, ok = tzsetNum(s, 0, 24*7) if !ok { return 0, "", false } off := hours * secondsPerHour if len(s) == 0 || s[0] != ':' { if neg { off = -off } return off, s, true } var mins int mins, s, ok = tzsetNum(s[1:], 0, 59) if !ok { return 0, "", false } off += mins * secondsPerMinute if len(s) == 0 || s[0] != ':' { if neg { off = -off } return off, s, true } var secs int secs, s, ok = tzsetNum(s[1:], 0, 59) if !ok { return 0, "", false } off += secs if neg { off = -off } return off, s, true } // ruleKind is the kinds of rules that can be seen in a tzset string. type ruleKind int const ( ruleJulian ruleKind = iota ruleDOY ruleMonthWeekDay ) // rule is a rule read from a tzset string. type rule struct { kind ruleKind day int week int mon int time int // transition time } // tzsetRule parses a rule from a tzset string. // It returns the rule, and the remainder of the string, and reports success. func tzsetRule(s string) (rule, string, bool) { var r rule if len(s) == 0 { return rule{}, "", false } ok := false if s[0] == 'J' { var jday int jday, s, ok = tzsetNum(s[1:], 1, 365) if !ok { return rule{}, "", false } r.kind = ruleJulian r.day = jday } else if s[0] == 'M' { var mon int mon, s, ok = tzsetNum(s[1:], 1, 12) if !ok || len(s) == 0 || s[0] != '.' { return rule{}, "", false } var week int week, s, ok = tzsetNum(s[1:], 1, 5) if !ok || len(s) == 0 || s[0] != '.' { return rule{}, "", false } var day int day, s, ok = tzsetNum(s[1:], 0, 6) if !ok { return rule{}, "", false } r.kind = ruleMonthWeekDay r.day = day r.week = week r.mon = mon } else { var day int day, s, ok = tzsetNum(s, 0, 365) if !ok { return rule{}, "", false } r.kind = ruleDOY r.day = day } if len(s) == 0 || s[0] != '/' { r.time = 2 * secondsPerHour // 2am is the default return r, s, true } offset, s, ok := tzsetOffset(s[1:]) if !ok { return rule{}, "", false } r.time = offset return r, s, true } // tzsetNum parses a number from a tzset string. // It returns the number, and the remainder of the string, and reports success. // The number must be between min and max. func tzsetNum(s string, min, max int) (num int, rest string, ok bool) { if len(s) == 0 { return 0, "", false } num = 0 for i, r := range s { if r < '0' || r > '9' { if i == 0 || num < min { return 0, "", false } return num, s[i:], true } num *= 10 num += int(r) - '0' if num > max { return 0, "", false } } if num < min { return 0, "", false } return num, "", true } // tzruleTime takes a year, a rule, and a timezone offset, // and returns the number of seconds since the start of the year // that the rule takes effect. func tzruleTime(year int, r rule, off int) int { var s int switch r.kind { case ruleJulian: s = (r.day - 1) * secondsPerDay if isLeap(year) && r.day >= 60 { s += secondsPerDay } case ruleDOY: s = r.day * secondsPerDay case ruleMonthWeekDay: // Zeller's Congruence. m1 := (r.mon+9)%12 + 1 yy0 := year if r.mon <= 2 { yy0-- } yy1 := yy0 / 100 yy2 := yy0 % 100 dow := ((26*m1-2)/10 + 1 + yy2 + yy2/4 + yy1/4 - 2*yy1) % 7 if dow < 0 { dow += 7 } // Now dow is the day-of-week of the first day of r.mon. // Get the day-of-month of the first "dow" day. d := r.day - dow if d < 0 { d += 7 } for i := 1; i < r.week; i++ { if d+7 >= daysIn(Month(r.mon), year) { break } d += 7 } d += int(daysBefore[r.mon-1]) if isLeap(year) && r.mon > 2 { d++ } s = d * secondsPerDay } return s + r.time - off } // lookupName returns information about the time zone with // the given name (such as "EST") at the given pseudo-Unix time // (what the given time of day would be in UTC). func (l *Location) lookupName(name string, unix int64) (offset int, ok bool) { l = l.get() // First try for a zone with the right name that was actually // in effect at the given time. (In Sydney, Australia, both standard // and daylight-savings time are abbreviated "EST". Using the // offset helps us pick the right one for the given time. // It's not perfect: during the backward transition we might pick // either one.) for i := range l.zone { zone := &l.zone[i] if zone.name == name { nam, offset, _, _, _ := l.lookup(unix - int64(zone.offset)) if nam == zone.name { return offset, true } } } // Otherwise fall back to an ordinary name match. for i := range l.zone { zone := &l.zone[i] if zone.name == name { return zone.offset, true } } // Otherwise, give up. return } // NOTE(rsc): Eventually we will need to accept the POSIX TZ environment // syntax too, but I don't feel like implementing it today. var errLocation = errors.New("time: invalid location name") var zoneinfo *string var zoneinfoOnce sync.Once // LoadLocation returns the Location with the given name. // // If the name is "" or "UTC", LoadLocation returns UTC. // If the name is "Local", LoadLocation returns Local. // // Otherwise, the name is taken to be a location name corresponding to a file // in the IANA Time Zone database, such as "America/New_York". // // LoadLocation looks for the IANA Time Zone database in the following // locations in order: // // - the directory or uncompressed zip file named by the ZONEINFO environment variable // - on a Unix system, the system standard installation location // - $GOROOT/lib/time/zoneinfo.zip // - the time/tzdata package, if it was imported func LoadLocation(name string) (*Location, error) { if name == "" || name == "UTC" { return UTC, nil } if name == "Local" { return Local, nil } if containsDotDot(name) || name[0] == '/' || name[0] == '\\' { // No valid IANA Time Zone name contains a single dot, // much less dot dot. Likewise, none begin with a slash. return nil, errLocation } zoneinfoOnce.Do(func() { env, _ := syscall.Getenv("ZONEINFO") zoneinfo = &env }) var firstErr error if *zoneinfo != "" { if zoneData, err := loadTzinfoFromDirOrZip(*zoneinfo, name); err == nil { if z, err := LoadLocationFromTZData(name, zoneData); err == nil { return z, nil } firstErr = err } else if err != syscall.ENOENT { firstErr = err } } if z, err := loadLocation(name, platformZoneSources); err == nil { return z, nil } else if firstErr == nil { firstErr = err } return nil, firstErr } // containsDotDot reports whether s contains "..". func containsDotDot(s string) bool { if len(s) < 2 { return false } for i := 0; i < len(s)-1; i++ { if s[i] == '.' && s[i+1] == '.' { return true } } return false }