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org.jetbrains.kotlinx:kotlinx-datetime-jvm
Advanced tools
A multiplatform Kotlin library for working with date and time.
See Using in your projects for the instructions how to setup a dependency in your project.
There are a few guiding principles in the design of kotlinx-datetime
. First of all, it is pragmatic, focused
on the most common problems developers face every day (pun intended) when working with dates and times. It is not
all-encompassing and lacks some domain-specific utilities that special-purpose applications might need.
We chose convenience over generality, so the API surface this library provides is as minimal as possible
to meet the use-cases.
The library puts a clear boundary between the physical time of an instant and the local, time-zone dependent civil time, consisting of components such as year, month, etc that people use when talking about time. We intentionally avoid entities in the library that mix both together and could be misused. However, there are convenience operations that take, for example, a physical instant and perform a calendar-based adjustment (such as adding a month); all such operations explicitly take a time-zone information as parameter to clearly state that their result depends on the civil time-zone rules which are subject to change at any time.
The library is based on the ISO 8601 international standard, other ways to represent dates and times are out of its scope. Internationalization (such as locale-specific month and day names) is out the scope, too.
The library provides a basic set of types for working with date and time:
Instant
to represent a moment on the UTC-SLS time scale;Clock
to obtain the current instant;LocalDateTime
to represent date and time components without a reference to the particular time zone;LocalDate
to represent the components of date only;LocalTime
to represent the components of time only;TimeZone
and FixedOffsetTimeZone
provide time zone information to convert between Instant
and LocalDateTime
;Month
and DayOfWeek
enums;DateTimePeriod
to represent a difference between two instants decomposed into date and time units;DatePeriod
is a subclass of DateTimePeriod
with zero time components,
it represents a difference between two LocalDate values decomposed into date units.DateTimeUnit
provides a set of predefined date and time units to use in arithmetic operations on Instant
and LocalDate
.UtcOffset
represents the amount of time the local datetime at a particular time zone differs from the datetime at UTC.Here is some basic advice on how to choose which of the date-carrying types to use in what cases:
Use Instant
to represent a timestamp of the event that had already happened in the past (like a timestamp of
a log entry) or will definitely happen in a well-defined instant of time in the future not far away from now
(like an order confirmation deadline in 1 hour from now).
Use LocalDateTime
to represent a time of the event that is scheduled to happen in the far future at a certain
local time (like a scheduled meeting in a few months from now). You'll have to keep track of the TimeZone
of
the scheduled event separately. Try to avoid converting future events to Instant
in advance, because time-zone
rules might change unexpectedly in the future. In this blog post, you can read more about why it's not always
a good idea to use Instant
everywhere.
Also, use LocalDateTime
to decode an Instant
to its local datetime components for display and UIs.
Use LocalDate
to represent the date of an event that does not have a specific time associated with it (like a birth date).
Use LocalTime
to represent the time of an event that does not have a specific date associated with it.
With the above types you can get the following operations done.
The current moment of time can be captured with the Instant
type.
To obtain an Instant
corresponding to the current moment of time,
use now()
function of the Clock
interface:
val clock: Clock = ...
val currentMoment = clock.now()
An instance of Clock
can be injected through the function/class parameters,
or you can use its default implementation Clock.System
that represents the system clock:
val currentMoment = Clock.System.now()
An Instant
is just a counter of high resolution time intervals since the beginning of time scale.
To get human readable components from an Instant
value, you need to convert it to the LocalDateTime
type that represents date and time components without a reference to the particular time zone.
The TimeZone
type provides the rules to convert instants from and to datetime components.
val currentMoment: Instant = Clock.System.now()
val datetimeInUtc: LocalDateTime = currentMoment.toLocalDateTime(TimeZone.UTC)
val datetimeInSystemZone: LocalDateTime = currentMoment.toLocalDateTime(TimeZone.currentSystemDefault())
A LocalDateTime
instance exposes familiar components of the Gregorian calendar:
year
, month
, dayOfMonth
, hour
, and so on up to nanosecond
.
The property dayOfWeek
shows what weekday that date is,
and dayOfYear
shows the day number since the beginning of a year.
Additional time zones can be acquired by their string identifier with the TimeZone.of(id: String)
function.
val tzBerlin = TimeZone.of("Europe/Berlin")
val datetimeInBerlin = currentMoment.toLocalDateTime(tzBerlin)
A LocalDateTime
instance can be constructed from individual components:
val kotlinReleaseDateTime = LocalDateTime(2016, 2, 15, 16, 57, 0, 0)
An instant can be obtained from LocalDateTime
by interpreting it as a time moment
in a particular TimeZone
:
val kotlinReleaseInstant = kotlinReleaseDateTime.toInstant(TimeZone.of("UTC+3"))
A LocalDate
represents a local date without time. You can obtain one from an Instant
by converting it to LocalDateTime
and taking its date
property.
val now: Instant = Clock.System.now()
val today: LocalDate = now.toLocalDateTime(TimeZone.currentSystemDefault()).date
// or shorter
val today: LocalDate = Clock.System.todayIn(TimeZone.currentSystemDefault())
Note, that today's date really depends on the time zone in which you're observing the current moment.
LocalDate
can be constructed from three components, year, month, and day:
val knownDate = LocalDate(2020, 2, 21)
A LocalTime
represents local time without date. You can obtain one from an Instant
by converting it to LocalDateTime
and taking its time
property.
val now: Instant = Clock.System.now()
val thisTime: LocalTime = now.toLocalDateTime(TimeZone.currentSystemDefault()).time
A LocalTime
can be constructed from four components, hour, minute, second and nanosecond:
val knownTime = LocalTime(hour = 23, minute = 59, second = 12)
val timeWithNanos = LocalTime(hour = 23, minute = 59, second = 12, nanosecond = 999)
val hourMinute = LocalTime(hour = 12, minute = 13)
An Instant
can be converted to a number of milliseconds since the Unix/POSIX epoch with the toEpochMilliseconds()
function.
To convert back, use the companion object function Instant.fromEpochMilliseconds(Long)
.
Instant
, LocalDateTime
, LocalDate
and LocalTime
provide shortcuts for
parsing and formatting them using the extended ISO 8601 format.
The toString()
function is used to convert the value to a string in that format, and
the parse
function in companion object is used to parse a string representation back.
val instantNow = Clock.System.now()
instantNow.toString() // returns something like 2015-12-31T12:30:00Z
val instantBefore = Instant.parse("2010-06-01T22:19:44.475Z")
LocalDateTime
uses a similar format, but without Z
UTC time zone designator in the end.
LocalDate
uses a format with just year, month, and date components, e.g. 2010-06-01
.
LocalTime
uses a format with just hour, minute, second and (if non-zero) nanosecond components, e.g. 12:01:03
.
LocalDateTime.parse("2010-06-01T22:19:44")
LocalDate.parse("2010-06-01")
LocalTime.parse("12:01:03")
LocalTime.parse("12:00:03.999")
LocalTime.parse("12:0:03.999") // fails with an IllegalArgumentException
When some data needs to be formatted in some format other than ISO 8601, one can define their own format or use some of the predefined ones:
// import kotlinx.datetime.format.*
val dateFormat = LocalDate.Format {
monthNumber(padding = Padding.SPACE)
char('/')
dayOfMonth()
char(' ')
year()
}
val date = dateFormat.parse("12/24 2023")
println(date.format(LocalDate.Formats.ISO_BASIC)) // "20231224"
yyyy-MM-dd
)Given a constant format string like the ones used by Java's DateTimeFormatter.ofPattern can be converted to Kotlin code using the following invocation:
// import kotlinx.datetime.format.*
println(DateTimeFormat.formatAsKotlinBuilderDsl(DateTimeComponents.Format {
byUnicodePattern("uuuu-MM-dd'T'HH:mm:ss[.SSS]Z")
}))
// will print:
/*
date(LocalDate.Formats.ISO)
char('T')
hour()
char(':')
minute()
char(':')
second()
alternativeParsing({
}) {
char('.')
secondFraction(3)
}
offset(UtcOffset.Formats.FOUR_DIGITS)
*/
When your format string is not constant, with the FormatStringsInDatetimeFormats
opt-in,
you can use the format without converting it to Kotlin code beforehand:
val formatPattern = "yyyy-MM-dd'T'HH:mm:ss[.SSS]"
@OptIn(FormatStringsInDatetimeFormats::class)
val dateTimeFormat = LocalDateTime.Format {
byUnicodePattern(formatPattern)
}
dateTimeFormat.parse("2023-12-24T23:59:59")
Sometimes, the required string format doesn't fully correspond to any of the
classes kotlinx-datetime
provides. In these cases, DateTimeComponents
, a
collection of all datetime fields, can be used instead.
// import kotlinx.datetime.format.*
val yearMonth = DateTimeComponents.Format { year(); char('-'); monthNumber() }
.parse("2024-01")
println(yearMonth.year)
println(yearMonth.monthNumber)
val dateTimeOffset = DateTimeComponents.Formats.ISO_DATE_TIME_OFFSET
.parse("2023-01-07T23:16:15.53+02:00")
println(dateTimeOffset.toUtcOffset()) // +02:00
println(dateTimeOffset.toLocalDateTime()) // 2023-01-07T23:16:15.53
Occasionally, one can encounter strings where the values are slightly off:
for example, 23:59:60
, where 60
is an invalid value for the second.
DateTimeComponents
allows parsing such values as well and then mutating them
before conversion.
val time = DateTimeComponents.Format { time(LocalTime.Formats.ISO) }
.parse("23:59:60").apply {
if (second == 60) second = 59
}.toLocalTime()
println(time) // 23:59:59
Because DateTimeComponents
is provided specifically for parsing and
formatting, there is no way to construct it normally. If one needs to format
partial, complex or out-of-bounds data, the format
function allows building
DateTimeComponents
specifically for formatting it:
DateTimeComponents.Formats.RFC_1123.format {
// the receiver of this lambda is DateTimeComponents
setDate(LocalDate(2023, 1, 7))
hour = 23
minute = 59
second = 60
setOffset(UtcOffset(hours = 2))
} // Sat, 7 Jan 2023 23:59:60 +0200
val now = Clock.System.now()
val instantInThePast: Instant = Instant.parse("2020-01-01T00:00:00Z")
val durationSinceThen: Duration = now - instantInThePast
val equidistantInstantInTheFuture: Instant = now + durationSinceThen
Duration
is a type from the experimental kotlin.time
package in the Kotlin standard library.
This type holds the amount of time that can be represented in different time units: from nanoseconds to 24H days.
To get the calendar difference between two instants you can use the Instant.periodUntil(Instant, TimeZone)
function.
val period: DateTimePeriod = instantInThePast.periodUntil(Clock.System.now(), TimeZone.UTC)
A DateTimePeriod
represents a difference between two particular moments as a sum of calendar components,
like "2 years, 3 months, 10 days, and 22 hours".
The difference can be calculated as an integer amount of specified date or time units:
val diffInMonths = instantInThePast.until(Clock.System.now(), DateTimeUnit.MONTH, TimeZone.UTC)
There are also shortcuts yearsUntil(...)
, monthsUntil(...)
, and daysUntil(...)
.
A particular amount of datetime units or a datetime period can be added to an Instant
with the plus
function:
val now = Clock.System.now()
val systemTZ = TimeZone.currentSystemDefault()
val tomorrow = now.plus(2, DateTimeUnit.DAY, systemTZ)
val threeYearsAndAMonthLater = now.plus(DateTimePeriod(years = 3, months = 1), systemTZ)
Note that plus
and ...until
operations require a TimeZone
as a parameter because the calendar interval between
two particular instants can be different, when calculated in different time zones.
Similar operations with date units are provided for LocalDate
type:
LocalDate.plus(number, DateTimeUnit.DateBased)
LocalDate.plus(DatePeriod)
LocalDate.until(LocalDate, DateTimeUnit.DateBased)
and the shortcuts yearsUntil
, monthUntil
, daysUntil
LocalDate.periodUntil(LocalDate): DatePeriod
and LocalDate.minus(LocalDate): DatePeriod
Notice that, instead of the general DateTimeUnit
and DateTimePeriod
types, we're using their subtypes
DateTimeUnit.DateBased
and DatePeriod
respectively. This allows preventing the situations when
time components are being added to a date at compile time.
Arithmetic on LocalDateTime
is intentionally omitted. The reason for this is that the presence of daylight saving time
transitions (changing from standard time to daylight saving time and back) causes LocalDateTime
arithmetic to be
ill-defined. For example, consider time gaps (or, as dst
tag wiki on Stack Overflow
calls them, "spring forward" transitions), that is, ranges of date + time combinations that never occur in a given
time zone due to clocks moving forward. If we allowed LocalDateTime
arithmetic that ignored time zones, then it
could result in LocalDateTime
instances that are inside a time gap and are invalid in the implied time zone.
Therefore, the recommended way to use a LocalDateTime
is to treat it as a representation of an Instant
,
perform all the required arithmetic on Instant
values, and only convert to LocalDateTime
when a human-readable
representation is needed.
val timeZone = TimeZone.of("Europe/Berlin")
val localDateTime = LocalDateTime.parse("2021-03-27T02:16:20")
val instant = localDateTime.toInstant(timeZone)
val instantOneDayLater = instant.plus(1, DateTimeUnit.DAY, timeZone)
val localDateTimeOneDayLater = instantOneDayLater.toLocalDateTime(timeZone)
// 2021-03-28T03:16:20, as 02:16:20 that day is in a time gap
val instantTwoDaysLater = instant.plus(2, DateTimeUnit.DAY, timeZone)
val localDateTimeTwoDaysLater = instantTwoDaysLater.toLocalDateTime(timeZone)
// 2021-03-29T02:16:20
The implementation of datetime types, such as Instant
, LocalDateTime
, TimeZone
and so on, relies on:
java.time
API;js-joda
library;Clock
interface is needed as a pluggable replacement for Instant.now()
.Note that the library is experimental, and the API is subject to change.
The library is published to Maven Central.
The library is compatible with the Kotlin Standard Library not lower than 1.9.0
.
If you target Android devices running below API 26, you need to use Android Gradle plugin 4.0 or newer and enable core library desugaring.
repositories {
mavenCentral()
}
kotlin {
sourceSets {
commonMain {
dependencies {
implementation("org.jetbrains.kotlinx:kotlinx-datetime:0.6.1")
}
}
}
}
dependencies {
implementation("org.jetbrains.kotlinx:kotlinx-datetime:0.6.1")
}
By default, there's only one time zone available in Kotlin/JS: the SYSTEM
time zone with a fixed offset.
If you want to use all time zones in Kotlin/JS platform, you need to add the following npm dependency:
kotlin {
sourceSets {
val jsMain by getting {
dependencies {
implementation(npm("@js-joda/timezone", "2.3.0"))
}
}
}
}
and after that add the following initialization code in your project:
@JsModule("@js-joda/timezone")
@JsNonModule
external object JsJodaTimeZoneModule
private val jsJodaTz = JsJodaTimeZoneModule
Add a dependency to the <dependencies>
element. Note that you need to use the platform-specific -jvm
artifact in Maven.
<dependency>
<groupId>org.jetbrains.kotlinx</groupId>
<artifactId>kotlinx-datetime-jvm</artifactId>
<version>0.6.1</version>
</dependency>
The project requires JDK 8 to build classes and to run tests.
Gradle will try to find it among the installed JDKs or provision it automatically if it couldn't be found.
The path to JDK 8 can be additionally specified with the environment variable JDK_8
.
For local builds, you can use a later version of JDK if you don't have that
version installed. Specify the version of this JDK with the java.mainToolchainVersion
Gradle property.
After that, the project can be opened in IDEA and built with Gradle.
For building and running benchmarks, see README.md
FAQs
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