// Copyright (c) 2019 Alexander Medvednikov. All rights reserved. // Use of this source code is governed by an MIT license // that can be found in the LICENSE file. module time import rand const ( days_string = 'MonTueWedThuFriSatSun' month_days = [31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31] months_string = 'JanFebMarAprMayJunJulAugSepOctNovDec' // The unsigned zero year for internal calculations. // Must be 1 mod 400, and times before it will not compute correctly, // but otherwise can be changed at will. absolute_zero_year = i64(-292277022399) seconds_per_minute = 60 seconds_per_hour = 60 * seconds_per_minute seconds_per_day = 24 * seconds_per_hour seconds_per_week = 7 * seconds_per_day days_per_400_years = 365*400 + 97 days_per_100_years = 365*100 + 24 days_per_4_years = 365*4 + 1 days_before = [ 0, 31, 31 + 28, 31 + 28 + 31, 31 + 28 + 31 + 30, 31 + 28 + 31 + 30 + 31, 31 + 28 + 31 + 30 + 31 + 30, 31 + 28 + 31 + 30 + 31 + 30 + 31, 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31, 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30, 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31, 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31 + 30, 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31 + 30 + 31, ] ) #include pub struct Time { pub: year int month int day int hour int minute int second int uni int // TODO it's safe to use "unix" now } pub enum FormatTime { hhmm12 hhmm24 hhmmss12 hhmmss24 no_time } pub enum FormatDate { ddmmyy ddmmyyyy mmddyy mmddyyyy mmmd mmmdd mmmddyyyy no_date yyyymmdd } pub enum FormatDelimiter { dot hyphen slash space } fn C.localtime(int) &C.tm fn remove_me_when_c_bug_is_fixed() { // TODO } pub struct C.time_t {} struct C.tm { tm_year int tm_mon int tm_mday int tm_hour int tm_min int tm_sec int } fn C.time(int) C.time_t pub fn now() Time { t := C.time(0) mut now := &C.tm{!} now = C.localtime(&t) return convert_ctime(now) } pub fn random() Time { now_unix := now().uni rand_unix := rand.next(now_unix) return time.unix(rand_unix) } // Based on Go's time package. // Copyright 2009 The Go Authors. pub fn unix(abs int) Time { // Split into time and day. mut d := abs / seconds_per_day // Account for 400 year cycles. mut n := d / days_per_400_years mut y := 400 * n d -= days_per_400_years * n // Cut off 100-year cycles. // The last cycle has one extra leap year, so on the last day // of that year, day / days_per_100_years will be 4 instead of 3. // Cut it back down to 3 by subtracting n>>2. n = d / days_per_100_years n -= n >> 2 y += 100 * n d -= days_per_100_years * n // Cut off 4-year cycles. // The last cycle has a missing leap year, which does not // affect the computation. n = d / days_per_4_years y += 4 * n d -= days_per_4_years * n // Cut off years within a 4-year cycle. // The last year is a leap year, so on the last day of that year, // day / 365 will be 4 instead of 3. Cut it back down to 3 // by subtracting n>>2. n = d / 365 n -= n >> 2 y += n d -= 365 * n yday := int(d) mut day := yday year := abs / int(3.154e+7) + 1970 //int(i64(y) + absolute_zero_year) hour := int(abs%seconds_per_day) / seconds_per_hour minute := int(abs % seconds_per_hour) / seconds_per_minute second := int(abs % seconds_per_minute) if is_leap_year(year) { // Leap year if day > 31+29-1 { // After leap day; pretend it wasn't there. day-- } else if day == 31+29-1 { // Leap day. day = 29 return Time{year:year, month:2, day:day, hour:hour, minute: minute, second: second} } } // Estimate month on assumption that every month has 31 days. // The estimate may be too low by at most one month, so adjust. mut month := day / 31 mut begin := 0 end := int(days_before[month+1]) if day >= end { month++ begin = end } else { begin = int(days_before[month]) } month++ // because January is 1 day = day - begin + 1 return Time{ year:year month: month day:day hour:hour minute: minute second: second uni: abs } } pub fn convert_ctime(t tm) Time { return Time { year: t.tm_year + 1900 month: t.tm_mon + 1 day: t.tm_mday hour: t.tm_hour minute: t.tm_min second: t.tm_sec uni: C.mktime(&t) } } // format_ss returns a string for t in a given format YYYY-MM-DD HH:MM:SS in // 24h notation // @param // @return string // @example 1980-07-11 21:23:42 pub fn (t Time) format_ss() string { return t.get_fmt_str(.hyphen, .hhmmss24, .yyyymmdd) } // format_ss returns a string for t in a given format YYYY-MM-DD HH:MM in 24h // notation // @param // @return string // @example 1980-07-11 21:23 pub fn (t Time) format() string { return t.get_fmt_str(.hyphen, .hhmm24, .yyyymmdd) } pub fn (t Time) smonth() string { i := t.month - 1 return months_string[i * 3..(i + 1) * 3] } // hhmm returns a string for t in the given format HH:MM in 24h notation // @example 21:04 pub fn (t Time) hhmm() string { return t.get_fmt_time_str(.hhmm24) } /* fn (t Time) hhmm_tmp() string { return '${t.hour:02d}:${t.minute:02d}' } */ // hhmm12 returns a string for t in the given format HH:MM in 12h notation pub fn (t Time) hhmm12() string { return t.get_fmt_time_str(.hhmm12) } // hhmmss returns a string for t in the given format HH:MM:SS in 24h notation pub fn (t Time) hhmmss() string { return t.get_fmt_time_str(.hhmmss24) } // ymmdd returns a string for t in the given format YYYY-MM-DD pub fn (t Time) ymmdd() string { return t.get_fmt_date_str(.hyphen, .yyyymmdd) } // ddmmy returns a string for t in the given format DD.MM.YYYY pub fn (t Time) ddmmy() string { return t.get_fmt_date_str(.dot, .ddmmyyyy) } // md returns a string for t in the given format MMM D pub fn (t Time) md() string { return t.get_fmt_date_str(.space, .mmmd) } pub fn (t Time) clean() string { nowe := time.now() // if amtime { // hm = t.Format("3:04 pm") // } // Today if t.month == nowe.month && t.year == nowe.year && t.day == nowe.day { return t.get_fmt_time_str(.hhmm24) } // This week // if time.Since(t) < 24*7*time.Hour { // return t.Weekday().String()[:3] + " " + hm // } // This year if t.year == nowe.year { return t.get_fmt_str(.space, .hhmm24, .mmmd) } return t.format() // return fmt.Sprintf("%4d/%02d/%02d", t.Year(), t.Month(), t.Day()) + " " + hm } pub fn (t Time) clean12() string { nowe := time.now() // if amtime { // hm = t.Format("3:04 pm") // } // Today if t.month == nowe.month && t.year == nowe.year && t.day == nowe.day { return t.get_fmt_time_str(.hhmm12) } // This week // if time.Since(t) < 24*7*time.Hour { // return t.Weekday().String()[:3] + " " + hm // } // This year if t.year == nowe.year { return t.get_fmt_str(.space, .hhmm12, .mmmd) } return t.format() // return fmt.Sprintf("%4d/%02d/%02d", t.Year(), t.Month(), t.Day()) + " " + hm } // `parse` parses time in the following format: "2018-01-27 12:48:34" pub fn parse(s string) Time { // println('parse="$s"') pos := s.index(' ') if pos <= 0 { println('bad time format') return now() } symd := s[..pos] ymd := symd.split('-') if ymd.len != 3 { println('bad time format') return now() } shms := s[pos..] hms := shms.split(':') hour := hms[0] minute := hms[1] second := hms[2] // ////////// return new_time(Time { year: ymd[0].int() month: ymd[1].int() day: ymd[2].int() hour: hour.int() minute: minute.int() second: second.int() }) } pub fn new_time(t Time) Time { return{t | uni: t.calc_unix()} } pub fn (t &Time) calc_unix() int { if t.uni != 0 { return t.uni } tt := C.tm{ tm_sec : t.second tm_min : t.minute tm_hour : t.hour tm_mday : t.day tm_mon : t.month-1 tm_year : t.year - 1900 } return C.mktime(&tt) } // TODO add(d time.Duration) pub fn (t Time) add_seconds(seconds int) Time { return unix(t.uni + seconds) } pub fn (t Time) add_days(days int) Time { return unix(t.uni + days * 3600 * 24) } // TODO use time.Duration instead of seconds fn since(t Time) int { return 0 } pub fn (t Time) relative() string { now := time.now() secs := now.uni - t.uni if secs <= 30 { // right now or in the future // TODO handle time in the future return 'now' } if secs < 60 { return '1m' } if secs < 3600 { return '${secs/60}m' } if secs < 3600 * 24 { return '${secs/3600}h' } if secs < 3600 * 24 * 5 { return '${secs/3600/24}d' } if secs > 3600 * 24 * 10000 { return '' } return t.md() } pub fn day_of_week(y, m, d int) int { // Sakomotho's algorithm is explained here: // https://stackoverflow.com/a/6385934 t := [0, 3, 2, 5, 0, 3, 5, 1, 4, 6, 2, 4] mut sy := y if (m < 3) { sy = sy - 1 } return ( sy + sy/4 - sy/100 + sy/400 + t[m-1] + d - 1) % 7 + 1 } pub fn (t Time) day_of_week() int { return day_of_week(t.year, t.month, t.day) } // weekday_str() returns the current day in string (upto 3 characters) pub fn (t Time) weekday_str() string { i := t.day_of_week() - 1 return days_string[i * 3..(i + 1) * 3] } pub struct C.timeval { tv_sec u64 tv_usec u64 } // in ms pub fn ticks() i64 { $if windows { return C.GetTickCount() } $else { ts := C.timeval{} C.gettimeofday(&ts,0) return i64(ts.tv_sec * u64(1000) + (ts.tv_usec / u64(1000))) } /* t := i64(C.mach_absolute_time()) # Nanoseconds elapsedNano = AbsoluteToNanoseconds( *(AbsoluteTime *) &t ); # return (double)(* (uint64_t *) &elapsedNano) / 1000000; */ } pub fn sleep(seconds int) { $if windows { C.Sleep(seconds * 1000) } $else { C.sleep(seconds) } } pub fn usleep(n int) { $if windows { //C._usleep(n) } $else { C.usleep(n) } } pub fn sleep_ms(n int) { $if windows { C.Sleep(n) } $else { C.usleep(n * 1000) } } // Determine whether a year is a leap year. pub fn is_leap_year(year int) bool { return (year%4 == 0) && (year%100 != 0 || year%400 == 0) } // Returns number of days in month pub fn days_in_month(month, year int) ?int { if month > 12 || month < 1 { return error('Invalid month: $month') } extra := if month == 2 && is_leap_year(year) {1} else {0} res := month_days[month-1] + extra return res } // get_fmt_time_str returns a string for time t in a given format // @param FormatTime // @return string // @example 21:23:42 pub fn (t Time) get_fmt_time_str(fmt_time FormatTime) string { if fmt_time == .no_time { return '' } tp := if t.hour > 11 { 'p.m.' } else { 'a.m.' } hour := if t.hour > 12 { t.hour - 12 } else if t.hour == 0 { 12 } else { t.hour } return match fmt_time { .hhmm12 { '$hour:${t.minute:02d} $tp' } .hhmm24 { '${t.hour:02d}:${t.minute:02d}' } .hhmmss12 { '$hour:${t.minute:02d}:${t.second:02d} $tp' } .hhmmss24 { '${t.hour:02d}:${t.minute:02d}:${t.second:02d}' } else { 'unknown enumeration $fmt_time' } } } // get_fmt_date_str returns a string for t in a given date format // @param FormatDelimiter, FormatDate // @return string // @example 11.07.1980 pub fn (t Time) get_fmt_date_str(fmt_dlmtr FormatDelimiter, fmt_date FormatDate) string { if fmt_date == .no_date { return '' } month := '${t.smonth()}' year := t.year.str()[2..] return match fmt_date { .ddmmyy { '${t.day:02d}|${t.month:02d}|$year' } .ddmmyyyy { '${t.day:02d}|${t.month:02d}|${t.year}' } .mmddyy { '${t.month:02d}|${t.day:02d}|$year' } .mmddyyyy { '${t.month:02d}|${t.day:02d}|${t.year}' } .mmmd { '$month|${t.day}' } .mmmdd { '$month|${t.day:02d}' } .mmmddyyyy { '$month|${t.day:02d}|${t.year}' } .yyyymmdd { '${t.year}|${t.month:02d}|${t.day:02d}' } else { 'unknown enumeration $fmt_date' } }.replace('|', match fmt_dlmtr { .dot { '.' } .hyphen { '-' } .slash { '/' } .space { ' ' } else { 'unknown enumeration $fmt_dlmtr' } }) } // get_fmt_str returns a string for t in a given format for time and date // @param FormatDelimiter, FormatTime, FormatDate // @return string // @example 11.07.1980 21:23:42 pub fn (t Time) get_fmt_str(fmt_dlmtr FormatDelimiter, fmt_time FormatTime, fmt_date FormatDate) string { if fmt_date == .no_date { if fmt_time == .no_time { // saving one function call although it's checked in // t.get_fmt_time_str(fmt_time) in the beginning return '' } else { return t.get_fmt_time_str(fmt_time) } } else { if fmt_time != .no_time { return t.get_fmt_date_str(fmt_dlmtr, fmt_date) + ' ' + t.get_fmt_time_str(fmt_time) } else { return t.get_fmt_date_str(fmt_dlmtr, fmt_date) } } }