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time.go
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time.go
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// Copyright 2015 PingCAP, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// See the License for the specific language governing permissions and
// limitations under the License.
package types
import (
"bytes"
"fmt"
"math"
"regexp"
"strconv"
"strings"
gotime "time"
"unicode"
"github.com/juju/errors"
"github.com/pingcap/tidb/mysql"
"github.com/pingcap/tidb/sessionctx/stmtctx"
"github.com/pingcap/tidb/terror"
log "github.com/sirupsen/logrus"
)
// Portable analogs of some common call errors.
var (
ErrInvalidTimeFormat = terror.ClassTypes.New(mysql.ErrTruncatedWrongValue, "invalid time format: '%v'")
ErrInvalidYearFormat = errors.New("invalid year format")
ErrInvalidYear = errors.New("invalid year")
ErrZeroDate = errors.New("datetime zero in date")
ErrIncorrectDatetimeValue = terror.ClassTypes.New(mysql.ErrTruncatedWrongValue, "Incorrect datetime value: '%s'")
)
// Time format without fractional seconds precision.
const (
DateFormat = "2006-01-02"
TimeFormat = "2006-01-02 15:04:05"
// TimeFSPFormat is time format with fractional seconds precision.
TimeFSPFormat = "2006-01-02 15:04:05.000000"
)
const (
// MinYear is the minimum for mysql year type.
MinYear int16 = 1901
// MaxYear is the maximum for mysql year type.
MaxYear int16 = 2155
// MinTime is the minimum for mysql time type.
MinTime = -gotime.Duration(838*3600+59*60+59) * gotime.Second
// MaxTime is the maximum for mysql time type.
MaxTime = gotime.Duration(838*3600+59*60+59) * gotime.Second
// ZeroDatetimeStr is the string representation of a zero datetime.
ZeroDatetimeStr = "0000-00-00 00:00:00"
// ZeroDateStr is the string representation of a zero date.
ZeroDateStr = "0000-00-00"
// TimeMaxHour is the max hour for mysql time type.
TimeMaxHour = 838
// TimeMaxMinute is the max minute for mysql time type.
TimeMaxMinute = 59
// TimeMaxSecond is the max second for mysql time type.
TimeMaxSecond = 59
// TimeMaxValue is the maximum value for mysql time type.
TimeMaxValue = TimeMaxHour*10000 + TimeMaxMinute*100 + TimeMaxSecond
// TimeMaxValueSeconds is the maximum second value for mysql time type.
TimeMaxValueSeconds = TimeMaxHour*3600 + TimeMaxMinute*60 + TimeMaxSecond
)
// Zero values for different types.
var (
// ZeroDuration is the zero value for Duration type.
ZeroDuration = Duration{Duration: gotime.Duration(0), Fsp: DefaultFsp}
// ZeroTime is the zero value for TimeInternal type.
ZeroTime = MysqlTime{}
// ZeroDatetime is the zero value for datetime Time.
ZeroDatetime = Time{
Time: ZeroTime,
Type: mysql.TypeDatetime,
Fsp: DefaultFsp,
}
// ZeroTimestamp is the zero value for timestamp Time.
ZeroTimestamp = Time{
Time: ZeroTime,
Type: mysql.TypeTimestamp,
Fsp: DefaultFsp,
}
// ZeroDate is the zero value for date Time.
ZeroDate = Time{
Time: ZeroTime,
Type: mysql.TypeDate,
Fsp: DefaultFsp,
}
)
var (
// MinDatetime is the minimum for mysql datetime type.
MinDatetime = FromDate(1000, 1, 1, 0, 0, 0, 0)
// MaxDatetime is the maximum for mysql datetime type.
MaxDatetime = FromDate(9999, 12, 31, 23, 59, 59, 999999)
// MinTimestamp is the minimum for mysql timestamp type.
MinTimestamp = FromDate(1970, 1, 1, 0, 0, 1, 0)
// maxTimestamp is the maximum for mysql timestamp type.
maxTimestamp = FromDate(2038, 1, 19, 3, 14, 7, 999999)
// WeekdayNames lists names of weekdays, which are used in builtin time function `dayname`.
WeekdayNames = []string{
"Monday",
"Tuesday",
"Wednesday",
"Thursday",
"Friday",
"Saturday",
"Sunday",
}
// MonthNames lists names of months, which are used in builtin time function `monthname`.
MonthNames = []string{
"January", "February",
"March", "April",
"May", "June",
"July", "August",
"September", "October",
"November", "December",
}
)
// FromGoTime translates time.Time to mysql time internal representation.
func FromGoTime(t gotime.Time) MysqlTime {
year, month, day := t.Date()
hour, minute, second := t.Clock()
microsecond := t.Nanosecond() / 1000
return FromDate(year, int(month), day, hour, minute, second, microsecond)
}
// FromDate makes a internal time representation from the given date.
func FromDate(year int, month int, day int, hour int, minute int, second int, microsecond int) MysqlTime {
return MysqlTime{
uint16(year),
uint8(month),
uint8(day),
hour,
uint8(minute),
uint8(second),
uint32(microsecond),
}
}
// Clock returns the hour, minute, and second within the day specified by t.
func (t Time) Clock() (hour int, minute int, second int) {
return t.Time.Hour(), t.Time.Minute(), t.Time.Second()
}
// Time is the struct for handling datetime, timestamp and date.
// TODO: check if need a NewTime function to set Fsp default value?
type Time struct {
Time MysqlTime
Type uint8
// Fsp is short for Fractional Seconds Precision.
// See http://dev.mysql.com/doc/refman/5.7/en/fractional-seconds.html
Fsp int
}
// MaxMySQLTime returns Time with maximum mysql time type.
func MaxMySQLTime(fsp int) Time {
return Time{Time: FromDate(0, 0, 0, TimeMaxHour, TimeMaxMinute, TimeMaxSecond, 0), Type: mysql.TypeDuration, Fsp: fsp}
}
// CurrentTime returns current time with type tp.
func CurrentTime(tp uint8) Time {
return Time{Time: FromGoTime(gotime.Now()), Type: tp, Fsp: 0}
}
// ConvertTimeZone converts the time value from one timezone to another.
// The input time should be a valid timestamp.
func (t *Time) ConvertTimeZone(from, to *gotime.Location) error {
if !t.IsZero() {
raw, err := t.Time.GoTime(from)
if err != nil {
return errors.Trace(err)
}
converted := raw.In(to)
t.Time = FromGoTime(converted)
}
return nil
}
func (t Time) String() string {
if t.Type == mysql.TypeDate {
// We control the format, so no error would occur.
str, err := t.DateFormat("%Y-%m-%d")
terror.Log(errors.Trace(err))
return str
}
str, err := t.DateFormat("%Y-%m-%d %H:%i:%s")
terror.Log(errors.Trace(err))
if t.Fsp > 0 {
tmp := fmt.Sprintf(".%06d", t.Time.Microsecond())
str = str + tmp[:1+t.Fsp]
}
return str
}
// IsZero returns a boolean indicating whether the time is equal to ZeroTime.
func (t Time) IsZero() bool {
return compareTime(t.Time, ZeroTime) == 0
}
// InvalidZero returns a boolean indicating whether the month or day is zero.
func (t Time) InvalidZero() bool {
return t.Time.Month() == 0 || t.Time.Day() == 0
}
const numberFormat = "%Y%m%d%H%i%s"
const dateFormat = "%Y%m%d"
// ToNumber returns a formatted number.
// e.g,
// 2012-12-12 -> 20121212
// 2012-12-12T10:10:10 -> 20121212101010
// 2012-12-12T10:10:10.123456 -> 20121212101010.123456
func (t Time) ToNumber() *MyDecimal {
if t.IsZero() {
return &MyDecimal{}
}
// Fix issue #1046
// Prevents from converting 2012-12-12 to 20121212000000
var tfStr string
if t.Type == mysql.TypeDate {
tfStr = dateFormat
} else {
tfStr = numberFormat
}
s, err := t.DateFormat(tfStr)
if err != nil {
log.Error("Fatal: never happen because we've control the format!")
}
if t.Fsp > 0 {
s1 := fmt.Sprintf("%s.%06d", s, t.Time.Microsecond())
s = s1[:len(s)+t.Fsp+1]
}
// We skip checking error here because time formatted string can be parsed certainly.
dec := new(MyDecimal)
err = dec.FromString([]byte(s))
terror.Log(errors.Trace(err))
return dec
}
// Convert converts t with type tp.
func (t Time) Convert(sc *stmtctx.StatementContext, tp uint8) (Time, error) {
if t.Type == tp || t.IsZero() {
return Time{Time: t.Time, Type: tp, Fsp: t.Fsp}, nil
}
t1 := Time{Time: t.Time, Type: tp, Fsp: t.Fsp}
err := t1.check(sc)
return t1, errors.Trace(err)
}
// ConvertToDuration converts mysql datetime, timestamp and date to mysql time type.
// e.g,
// 2012-12-12T10:10:10 -> 10:10:10
// 2012-12-12 -> 0
func (t Time) ConvertToDuration() (Duration, error) {
if t.IsZero() {
return ZeroDuration, nil
}
hour, minute, second := t.Clock()
frac := t.Time.Microsecond() * 1000
d := gotime.Duration(hour*3600+minute*60+second)*gotime.Second + gotime.Duration(frac)
// TODO: check convert validation
return Duration{Duration: d, Fsp: t.Fsp}, nil
}
// Compare returns an integer comparing the time instant t to o.
// If t is after o, return 1, equal o, return 0, before o, return -1.
func (t Time) Compare(o Time) int {
return compareTime(t.Time, o.Time)
}
func compareTime(a, b MysqlTime) int {
ta := datetimeToUint64(a)
tb := datetimeToUint64(b)
switch {
case ta < tb:
return -1
case ta > tb:
return 1
}
switch {
case a.Microsecond() < b.Microsecond():
return -1
case a.Microsecond() > b.Microsecond():
return 1
}
return 0
}
// CompareString is like Compare,
// but parses string to Time then compares.
func (t Time) CompareString(sc *stmtctx.StatementContext, str string) (int, error) {
// use MaxFsp to parse the string
o, err := ParseTime(sc, str, t.Type, MaxFsp)
if err != nil {
return 0, errors.Trace(err)
}
return t.Compare(o), nil
}
// roundTime rounds the time value according to digits count specified by fsp.
func roundTime(t gotime.Time, fsp int) gotime.Time {
d := gotime.Duration(math.Pow10(9 - fsp))
return t.Round(d)
}
// RoundFrac rounds the fraction part of a time-type value according to `fsp`.
func (t Time) RoundFrac(sc *stmtctx.StatementContext, fsp int) (Time, error) {
if t.Type == mysql.TypeDate || t.IsZero() {
// date type has no fsp
return t, nil
}
fsp, err := CheckFsp(fsp)
if err != nil {
return t, errors.Trace(err)
}
if fsp == t.Fsp {
// have same fsp
return t, nil
}
var nt MysqlTime
if t1, err := t.Time.GoTime(sc.TimeZone); err == nil {
t1 = roundTime(t1, fsp)
nt = FromGoTime(t1)
} else {
// Take the hh:mm:ss part out to avoid handle month or day = 0.
hour, minute, second, microsecond := t.Time.Hour(), t.Time.Minute(), t.Time.Second(), t.Time.Microsecond()
t1 := gotime.Date(1, 1, 1, hour, minute, second, microsecond*1000, gotime.Local)
t2 := roundTime(t1, fsp)
hour, minute, second = t2.Clock()
microsecond = t2.Nanosecond() / 1000
// TODO: when hh:mm:ss overflow one day after rounding, it should be add to yy:mm:dd part,
// but mm:dd may contain 0, it makes the code complex, so we ignore it here.
if t2.Day()-1 > 0 {
return t, errors.Trace(ErrInvalidTimeFormat.GenByArgs(t.String()))
}
nt = FromDate(t.Time.Year(), t.Time.Month(), t.Time.Day(), hour, minute, second, microsecond)
}
return Time{Time: nt, Type: t.Type, Fsp: fsp}, nil
}
// GetFsp gets the fsp of a string.
func GetFsp(s string) (fsp int) {
fsp = len(s) - strings.LastIndex(s, ".") - 1
if fsp == len(s) {
fsp = 0
} else if fsp > 6 {
fsp = 6
}
return
}
// RoundFrac rounds fractional seconds precision with new fsp and returns a new one.
// We will use the “round half up” rule, e.g, >= 0.5 -> 1, < 0.5 -> 0,
// so 2011:11:11 10:10:10.888888 round 0 -> 2011:11:11 10:10:11
// and 2011:11:11 10:10:10.111111 round 0 -> 2011:11:11 10:10:10
func RoundFrac(t gotime.Time, fsp int) (gotime.Time, error) {
_, err := CheckFsp(fsp)
if err != nil {
return t, errors.Trace(err)
}
return t.Round(gotime.Duration(math.Pow10(9-fsp)) * gotime.Nanosecond), nil
}
// ToPackedUint encodes Time to a packed uint64 value.
//
// 1 bit 0
// 17 bits year*13+month (year 0-9999, month 0-12)
// 5 bits day (0-31)
// 5 bits hour (0-23)
// 6 bits minute (0-59)
// 6 bits second (0-59)
// 24 bits microseconds (0-999999)
//
// Total: 64 bits = 8 bytes
//
// 0YYYYYYY.YYYYYYYY.YYdddddh.hhhhmmmm.mmssssss.ffffffff.ffffffff.ffffffff
//
func (t Time) ToPackedUint() (uint64, error) {
tm := t.Time
if t.IsZero() {
return 0, nil
}
year, month, day := tm.Year(), tm.Month(), tm.Day()
hour, minute, sec := tm.Hour(), tm.Minute(), tm.Second()
ymd := uint64(((year*13 + month) << 5) | day)
hms := uint64(hour<<12 | minute<<6 | sec)
micro := uint64(tm.Microsecond())
return ((ymd<<17 | hms) << 24) | micro, nil
}
// FromPackedUint decodes Time from a packed uint64 value.
func (t *Time) FromPackedUint(packed uint64) error {
if packed == 0 {
t.Time = ZeroTime
return nil
}
ymdhms := packed >> 24
ymd := ymdhms >> 17
day := int(ymd & (1<<5 - 1))
ym := ymd >> 5
month := int(ym % 13)
year := int(ym / 13)
hms := ymdhms & (1<<17 - 1)
second := int(hms & (1<<6 - 1))
minute := int((hms >> 6) & (1<<6 - 1))
hour := int(hms >> 12)
microsec := int(packed % (1 << 24))
t.Time = FromDate(year, month, day, hour, minute, second, microsec)
return nil
}
// check whether t matches valid Time format.
// If allowZeroInDate is false, it returns ErrZeroDate when month or day is zero.
// FIXME: See https://dev.mysql.com/doc/refman/5.7/en/sql-mode.html#sqlmode_no_zero_in_date
func (t *Time) check(sc *stmtctx.StatementContext) error {
allowZeroInDate := false
// We should avoid passing sc as nil here as far as possible.
if sc != nil {
allowZeroInDate = sc.IgnoreZeroInDate
}
var err error
switch t.Type {
case mysql.TypeTimestamp:
err = checkTimestampType(t.Time)
case mysql.TypeDatetime:
err = checkDatetimeType(t.Time, allowZeroInDate)
case mysql.TypeDate:
err = checkDateType(t.Time, allowZeroInDate)
}
return errors.Trace(err)
}
// Check if 't' is valid
func (t *Time) Check() error {
return t.check(nil)
}
// Sub subtracts t1 from t, returns a duration value.
// Note that sub should not be done on different time types.
func (t *Time) Sub(sc *stmtctx.StatementContext, t1 *Time) Duration {
var duration gotime.Duration
if t.Type == mysql.TypeTimestamp && t1.Type == mysql.TypeTimestamp {
a, err := t.Time.GoTime(sc.TimeZone)
terror.Log(errors.Trace(err))
b, err := t1.Time.GoTime(sc.TimeZone)
terror.Log(errors.Trace(err))
duration = a.Sub(b)
} else {
seconds, microseconds, neg := calcTimeDiff(t.Time, t1.Time, 1)
duration = gotime.Duration(seconds*1e9 + microseconds*1e3)
if neg {
duration = -duration
}
}
fsp := t.Fsp
if fsp < t1.Fsp {
fsp = t1.Fsp
}
return Duration{
Duration: duration,
Fsp: fsp,
}
}
// Add adds d to t, returns the result time value.
func (t *Time) Add(d Duration) (Time, error) {
sign, hh, mm, ss, micro := splitDuration(d.Duration)
seconds, microseconds, _ := calcTimeDiff(t.Time, FromDate(0, 0, 0, hh, mm, ss, micro), -sign)
days := seconds / secondsIn24Hour
year, month, day := getDateFromDaynr(uint(days))
var tm MysqlTime
tm.year, tm.month, tm.day = uint16(year), uint8(month), uint8(day)
calcTimeFromSec(&tm, seconds%secondsIn24Hour, microseconds)
if t.Type == mysql.TypeDate {
tm.hour = 0
tm.minute = 0
tm.second = 0
tm.microsecond = 0
}
fsp := t.Fsp
if d.Fsp > fsp {
fsp = d.Fsp
}
ret := Time{
Time: tm,
Type: t.Type,
Fsp: fsp,
}
return ret, ret.Check()
}
// TimestampDiff returns t2 - t1 where t1 and t2 are date or datetime expressions.
// The unit for the result (an integer) is given by the unit argument.
// The legal values for unit are "YEAR" "QUARTER" "MONTH" "DAY" "HOUR" "SECOND" and so on.
func TimestampDiff(unit string, t1 Time, t2 Time) int64 {
return timestampDiff(unit, t1.Time, t2.Time)
}
// ParseDateFormat parses a formatted date string and returns separated components.
func ParseDateFormat(format string) []string {
format = strings.TrimSpace(format)
start := 0
var seps = make([]string, 0)
for i := 0; i < len(format); i++ {
// Date format must start and end with number.
if i == 0 || i == len(format)-1 {
if !unicode.IsNumber(rune(format[i])) {
return nil
}
continue
}
// Separator is a single none-number char.
if !unicode.IsNumber(rune(format[i])) {
if !unicode.IsNumber(rune(format[i-1])) {
return nil
}
seps = append(seps, format[start:i])
start = i + 1
}
}
seps = append(seps, format[start:])
return seps
}
// See https://dev.mysql.com/doc/refman/5.7/en/date-and-time-literals.html.
// The only delimiter recognized between a date and time part and a fractional seconds part is the decimal point.
func splitDateTime(format string) (seps []string, fracStr string) {
if i := strings.LastIndex(format, "."); i > 0 {
fracStr = strings.TrimSpace(format[i+1:])
format = format[:i]
}
seps = ParseDateFormat(format)
return
}
// See https://dev.mysql.com/doc/refman/5.7/en/date-and-time-literals.html.
func parseDatetime(str string, fsp int, isFloat bool) (Time, error) {
// Try to split str with delimiter.
// TODO: only punctuation can be the delimiter for date parts or time parts.
// But only space and T can be the delimiter between the date and time part.
var (
year, month, day, hour, minute, second int
fracStr string
hhmmss bool
err error
)
seps, fracStr := splitDateTime(str)
switch len(seps) {
case 1:
len := len(seps[0])
switch len {
case 14: // No delimiter.
// YYYYMMDDHHMMSS
_, err = fmt.Sscanf(seps[0], "%4d%2d%2d%2d%2d%2d", &year, &month, &day, &hour, &minute, &second)
hhmmss = true
case 12: // YYMMDDHHMMSS
_, err = fmt.Sscanf(seps[0], "%2d%2d%2d%2d%2d%2d", &year, &month, &day, &hour, &minute, &second)
year = adjustYear(year)
hhmmss = true
case 11: // YYMMDDHHMMS
_, err = fmt.Sscanf(seps[0], "%2d%2d%2d%2d%2d%1d", &year, &month, &day, &hour, &minute, &second)
year = adjustYear(year)
hhmmss = true
case 8: // YYYYMMDD
_, err = fmt.Sscanf(seps[0], "%4d%2d%2d", &year, &month, &day)
case 6:
// YYMMDD
_, err = fmt.Sscanf(seps[0], "%2d%2d%2d", &year, &month, &day)
year = adjustYear(year)
default:
return ZeroDatetime, errors.Trace(ErrInvalidTimeFormat.GenByArgs(str))
}
if len == 6 || len == 8 {
// YYMMDD or YYYYMMDD
// We must handle float => string => datetime, the difference is that fractional
// part of float type is discarded directly, while fractional part of string type
// is parsed to HH:MM:SS.
if isFloat {
// 20170118.123423 => 2017-01-18 00:00:00
} else {
// '20170118.123423' => 2017-01-18 12:34:23.234
_, err1 := fmt.Sscanf(fracStr, "%2d%2d%2d", &hour, &minute, &second)
terror.Log(err1)
}
}
case 3:
// YYYY-MM-DD
err = scanTimeArgs(seps, &year, &month, &day)
case 5:
// YYYY-MM-DD HH-MM
err = scanTimeArgs(seps, &year, &month, &day, &hour, &minute)
case 6:
// We don't have fractional seconds part.
// YYYY-MM-DD HH-MM-SS
err = scanTimeArgs(seps, &year, &month, &day, &hour, &minute, &second)
hhmmss = true
default:
return ZeroDatetime, errors.Trace(ErrInvalidTimeFormat.GenByArgs(str))
}
if err != nil {
return ZeroDatetime, errors.Trace(err)
}
// If str is sepereated by delimiters, the first one is year, and if the year is 2 digit,
// we should adjust it.
// TODO: adjust year is very complex, now we only consider the simplest way.
if len(seps[0]) == 2 {
if year == 0 && month == 0 && day == 0 && hour == 0 && minute == 0 && second == 0 && fracStr == "" {
// Skip a special case "00-00-00".
} else {
year = adjustYear(year)
}
}
var microsecond int
var overflow bool
if hhmmss {
// If input string is "20170118.999", without hhmmss, fsp is meanless.
microsecond, overflow, err = ParseFrac(fracStr, fsp)
if err != nil {
return ZeroDatetime, errors.Trace(err)
}
}
tmp := FromDate(year, month, day, hour, minute, second, microsecond)
if overflow {
// Convert to Go time and add 1 second, to handle input like 2017-01-05 08:40:59.575601
t1, err := tmp.GoTime(gotime.Local)
if err != nil {
return ZeroDatetime, errors.Trace(err)
}
tmp = FromGoTime(t1.Add(gotime.Second))
}
nt := Time{
Time: tmp,
Type: mysql.TypeDatetime,
Fsp: fsp}
return nt, nil
}
func scanTimeArgs(seps []string, args ...*int) error {
if len(seps) != len(args) {
return errors.Trace(ErrInvalidTimeFormat.GenByArgs(seps))
}
var err error
for i, s := range seps {
*args[i], err = strconv.Atoi(s)
if err != nil {
return errors.Trace(err)
}
}
return nil
}
// ParseYear parses a formatted string and returns a year number.
func ParseYear(str string) (int16, error) {
v, err := strconv.ParseInt(str, 10, 16)
if err != nil {
return 0, errors.Trace(err)
}
y := int16(v)
if len(str) == 4 {
// Nothing to do.
} else if len(str) == 2 || len(str) == 1 {
y = int16(adjustYear(int(y)))
} else {
return 0, errors.Trace(ErrInvalidYearFormat)
}
if y < MinYear || y > MaxYear {
return 0, errors.Trace(ErrInvalidYearFormat)
}
return y, nil
}
// adjustYear adjusts year according to y.
// See https://dev.mysql.com/doc/refman/5.7/en/two-digit-years.html
func adjustYear(y int) int {
if y >= 0 && y <= 69 {
y = 2000 + y
} else if y >= 70 && y <= 99 {
y = 1900 + y
}
return y
}
// AdjustYear is used for adjusting year and checking its validation.
func AdjustYear(y int64) (int64, error) {
y = int64(adjustYear(int(y)))
if y < int64(MinYear) || y > int64(MaxYear) {
return 0, errors.Trace(ErrInvalidYear)
}
return y, nil
}
// Duration is the type for MySQL time type.
type Duration struct {
gotime.Duration
// Fsp is short for Fractional Seconds Precision.
// See http://dev.mysql.com/doc/refman/5.7/en/fractional-seconds.html
Fsp int
}
//Add adds d to d, returns a duration value.
func (d Duration) Add(v Duration) (Duration, error) {
if &v == nil {
return d, nil
}
dsum, err := AddInt64(int64(d.Duration), int64(v.Duration))
if err != nil {
return Duration{}, errors.Trace(err)
}
if d.Fsp >= v.Fsp {
return Duration{Duration: gotime.Duration(dsum), Fsp: d.Fsp}, nil
}
return Duration{Duration: gotime.Duration(dsum), Fsp: v.Fsp}, nil
}
// Sub subtracts d to d, returns a duration value.
func (d Duration) Sub(v Duration) (Duration, error) {
if &v == nil {
return d, nil
}
dsum, err := SubInt64(int64(d.Duration), int64(v.Duration))
if err != nil {
return Duration{}, errors.Trace(err)
}
if d.Fsp >= v.Fsp {
return Duration{Duration: gotime.Duration(dsum), Fsp: d.Fsp}, nil
}
return Duration{Duration: gotime.Duration(dsum), Fsp: v.Fsp}, nil
}
// String returns the time formatted using default TimeFormat and fsp.
func (d Duration) String() string {
var buf bytes.Buffer
sign, hours, minutes, seconds, fraction := splitDuration(d.Duration)
if sign < 0 {
buf.WriteByte('-')
}
fmt.Fprintf(&buf, "%02d:%02d:%02d", hours, minutes, seconds)
if d.Fsp > 0 {
buf.WriteString(".")
buf.WriteString(d.formatFrac(fraction))
}
p := buf.String()
return p
}
func (d Duration) formatFrac(frac int) string {
s := fmt.Sprintf("%06d", frac)
return s[0:d.Fsp]
}
// ToNumber changes duration to number format.
// e.g,
// 10:10:10 -> 101010
func (d Duration) ToNumber() *MyDecimal {
sign, hours, minutes, seconds, fraction := splitDuration(d.Duration)
var (
s string
signStr string
)
if sign < 0 {
signStr = "-"
}
if d.Fsp == 0 {
s = fmt.Sprintf("%s%02d%02d%02d", signStr, hours, minutes, seconds)
} else {
s = fmt.Sprintf("%s%02d%02d%02d.%s", signStr, hours, minutes, seconds, d.formatFrac(fraction))
}
// We skip checking error here because time formatted string can be parsed certainly.
dec := new(MyDecimal)
err := dec.FromString([]byte(s))
terror.Log(errors.Trace(err))
return dec
}
// ConvertToTime converts duration to Time.
// Tp is TypeDatetime, TypeTimestamp and TypeDate.
func (d Duration) ConvertToTime(sc *stmtctx.StatementContext, tp uint8) (Time, error) {
year, month, day := gotime.Now().In(sc.TimeZone).Date()
sign, hour, minute, second, frac := splitDuration(d.Duration)
datePart := FromDate(year, int(month), day, 0, 0, 0, 0)
timePart := FromDate(0, 0, 0, hour, minute, second, frac)
mixDateAndTime(&datePart, &timePart, sign < 0)
t := Time{
Time: datePart,
Type: mysql.TypeDatetime,
Fsp: d.Fsp,
}
return t.Convert(nil, tp)
}
// RoundFrac rounds fractional seconds precision with new fsp and returns a new one.
// We will use the “round half up” rule, e.g, >= 0.5 -> 1, < 0.5 -> 0,
// so 10:10:10.999999 round 0 -> 10:10:11
// and 10:10:10.000000 round 0 -> 10:10:10
func (d Duration) RoundFrac(fsp int) (Duration, error) {
fsp, err := CheckFsp(fsp)
if err != nil {
return d, errors.Trace(err)
}
if fsp == d.Fsp {
return d, nil
}
n := gotime.Date(0, 0, 0, 0, 0, 0, 0, gotime.Local)
nd := n.Add(d.Duration).Round(gotime.Duration(math.Pow10(9-fsp)) * gotime.Nanosecond).Sub(n)
return Duration{Duration: nd, Fsp: fsp}, nil
}
// Compare returns an integer comparing the Duration instant t to o.
// If d is after o, return 1, equal o, return 0, before o, return -1.
func (d Duration) Compare(o Duration) int {
if d.Duration > o.Duration {
return 1
} else if d.Duration == o.Duration {
return 0
} else {
return -1
}
}
// CompareString is like Compare,
// but parses str to Duration then compares.
func (d Duration) CompareString(sc *stmtctx.StatementContext, str string) (int, error) {
// use MaxFsp to parse the string
o, err := ParseDuration(str, MaxFsp)
if err != nil {
return 0, err
}
return d.Compare(o), nil
}
// Hour returns current hour.
// e.g, hour("11:11:11") -> 11
func (d Duration) Hour() int {
_, hour, _, _, _ := splitDuration(d.Duration)
return hour
}
// Minute returns current minute.
// e.g, hour("11:11:11") -> 11
func (d Duration) Minute() int {
_, _, minute, _, _ := splitDuration(d.Duration)
return minute
}
// Second returns current second.
// e.g, hour("11:11:11") -> 11
func (d Duration) Second() int {
_, _, _, second, _ := splitDuration(d.Duration)
return second
}
// MicroSecond returns current microsecond.
// e.g, hour("11:11:11.11") -> 110000
func (d Duration) MicroSecond() int {
_, _, _, _, frac := splitDuration(d.Duration)
return frac
}
// ParseDuration parses the time form a formatted string with a fractional seconds part,
// returns the duration type Time value.
// See http://dev.mysql.com/doc/refman/5.7/en/fractional-seconds.html
func ParseDuration(str string, fsp int) (Duration, error) {
var (
day, hour, minute, second int
err error
sign = 0
dayExists = false
origStr = str
)
fsp, err = CheckFsp(fsp)
if err != nil {
return ZeroDuration, errors.Trace(err)
}
if len(str) == 0 {
return ZeroDuration, nil
} else if str[0] == '-' {
str = str[1:]
sign = -1
}
// Time format may has day.
if n := strings.IndexByte(str, ' '); n >= 0 {
if day, err = strconv.Atoi(str[:n]); err == nil {
dayExists = true
}
str = str[n+1:]
}
var (
integeralPart = str
fracPart int
overflow bool
)
if n := strings.IndexByte(str, '.'); n >= 0 {
// It has fractional precision parts.
fracStr := str[n+1:]
fracPart, overflow, err = ParseFrac(fracStr, fsp)
if err != nil {
return ZeroDuration, errors.Trace(err)
}
integeralPart = str[0:n]
}
// It tries to split integeralPart with delimiter, time delimiter must be :
seps := strings.Split(integeralPart, ":")
switch len(seps) {
case 1:
if dayExists {
hour, err = strconv.Atoi(seps[0])
} else {
// No delimiter.
switch len(integeralPart) {
case 7: // HHHMMSS
_, err = fmt.Sscanf(integeralPart, "%3d%2d%2d", &hour, &minute, &second)
case 6: // HHMMSS
_, err = fmt.Sscanf(integeralPart, "%2d%2d%2d", &hour, &minute, &second)
case 5: // HMMSS
_, err = fmt.Sscanf(integeralPart, "%1d%2d%2d", &hour, &minute, &second)
case 4: // MMSS
_, err = fmt.Sscanf(integeralPart, "%2d%2d", &minute, &second)
case 3: // MSS
_, err = fmt.Sscanf(integeralPart, "%1d%2d", &minute, &second)
case 2: // SS
_, err = fmt.Sscanf(integeralPart, "%2d", &second)
case 1: // 0S