View Source Date (Elixir v1.19.0-dev)

A Date struct and functions.

The Date struct contains the fields year, month, day and calendar. New dates can be built with the new/3 function or using the ~D (see sigil_D/2) sigil:

iex> ~D[2000-01-01]
~D[2000-01-01]

Both new/3 and sigil return a struct where the date fields can be accessed directly:

iex> date = ~D[2000-01-01]
iex> date.year
2000
iex> date.month
1

The functions on this module work with the Date struct as well as any struct that contains the same fields as the Date struct, such as NaiveDateTime and DateTime. Such functions expect Calendar.date/0 in their typespecs (instead of t/0).

Developers should avoid creating the Date structs directly and instead rely on the functions provided by this module as well as the ones in third-party calendar libraries.

Comparing dates

Comparisons in Elixir using ==/2, >/2, </2 and similar are structural and based on the Date struct fields. For proper comparison between dates, use the compare/2 function. The existence of the compare/2 function in this module also allows using Enum.min/2 and Enum.max/2 functions to get the minimum and maximum date of an Enum. For example:

iex>  Enum.min([~D[2017-03-31], ~D[2017-04-01]], Date)
~D[2017-03-31]

Using epochs

The add/2, diff/2 and shift/2 functions can be used for computing dates or retrieving the number of days between instants. For example, if there is an interest in computing the number of days from the Unix epoch (1970-01-01):

iex> Date.diff(~D[2010-04-17], ~D[1970-01-01])
14716

iex> Date.add(~D[1970-01-01], 14716)
~D[2010-04-17]

iex> Date.shift(~D[1970-01-01], year: 40, month: 3, week: 2, day: 2)
~D[2010-04-17]

Those functions are optimized to deal with common epochs, such as the Unix Epoch above or the Gregorian Epoch (0000-01-01).

Summary

Functions

Adds the number of days to the given date.

Returns true if the first date is strictly later than the second.

Returns true if the first date is strictly earlier than the second.

Calculates a date that is the first day of the month for the given date.

Calculates a date that is the first day of the week for the given date.

Compares two date structs.

Converts the given date from its calendar to the given calendar.

Similar to Date.convert/2, but raises an ArgumentError if the conversion between the two calendars is not possible.

Calculates the day-of-era and era for a given calendar date.

Calculates the day of the week of a given date.

Calculates the day of the year of a given date.

Returns the number of days in the given date month.

Calculates the difference between two dates, in a full number of days.

Calculates a date that is the last day of the month for the given date.

Calculates a date that is the last day of the week for the given date.

Converts an Erlang date tuple to a Date struct.

Converts an Erlang date tuple but raises for invalid dates.

Converts a number of gregorian days to a Date struct.

Parses the extended "Dates" format described by ISO 8601:2019.

Parses the extended "Dates" format described by ISO 8601:2019.

Returns true if the year in the given date is a leap year.

Returns the number of months in the given date year.

Calculates the quarter of the year of a given date.

Returns a range of dates.

Returns a range of dates with a step.

Shifts given date by duration according to its calendar.

Converts the given date to an Erlang date tuple.

Converts a date struct to a number of gregorian days.

Converts the given date to a string according to its calendar.

Returns the current date in UTC.

Calculates the year-of-era and era for a given calendar year.

Types

t()

@type t() :: %Date{
  calendar: Calendar.calendar(),
  day: Calendar.day(),
  month: Calendar.month(),
  year: Calendar.year()
}

Functions

add(date, days)

(since 1.5.0)
@spec add(Calendar.date(), integer()) :: t()

Adds the number of days to the given date.

The days are counted as Gregorian days. The date is returned in the same calendar as it was given in.

To shift a date by a Duration and according to its underlying calendar, use Date.shift/2.

Examples

iex> Date.add(~D[2000-01-03], -2)
~D[2000-01-01]
iex> Date.add(~D[2000-01-01], 2)
~D[2000-01-03]
iex> Date.add(~N[2000-01-01 09:00:00], 2)
~D[2000-01-03]
iex> Date.add(~D[-0010-01-01], -2)
~D[-0011-12-30]

after?(date1, date2)

(since 1.15.0)
@spec after?(Calendar.date(), Calendar.date()) :: boolean()

Returns true if the first date is strictly later than the second.

Examples

iex> Date.after?(~D[2022-02-02], ~D[2021-01-01])
true
iex> Date.after?(~D[2021-01-01], ~D[2021-01-01])
false
iex> Date.after?(~D[2021-01-01], ~D[2022-02-02])
false

before?(date1, date2)

(since 1.15.0)
@spec before?(Calendar.date(), Calendar.date()) :: boolean()

Returns true if the first date is strictly earlier than the second.

Examples

iex> Date.before?(~D[2021-01-01], ~D[2022-02-02])
true
iex> Date.before?(~D[2021-01-01], ~D[2021-01-01])
false
iex> Date.before?(~D[2022-02-02], ~D[2021-01-01])
false

beginning_of_month(date)

(since 1.11.0)
@spec beginning_of_month(Calendar.date()) :: t()

Calculates a date that is the first day of the month for the given date.

Examples

iex> Date.beginning_of_month(~D[2000-01-31])
~D[2000-01-01]
iex> Date.beginning_of_month(~D[2000-01-01])
~D[2000-01-01]
iex> Date.beginning_of_month(~N[2000-01-31 01:23:45])
~D[2000-01-01]

beginning_of_week(date, starting_on \\ :default)

(since 1.11.0)
@spec beginning_of_week(Calendar.date(), starting_on :: :default | atom()) :: t()

Calculates a date that is the first day of the week for the given date.

If the day is already the first day of the week, it returns the day itself. For the built-in ISO calendar, the week starts on Monday. A weekday rather than :default can be given as starting_on.

Examples

iex> Date.beginning_of_week(~D[2020-07-11])
~D[2020-07-06]
iex> Date.beginning_of_week(~D[2020-07-06])
~D[2020-07-06]
iex> Date.beginning_of_week(~D[2020-07-11], :sunday)
~D[2020-07-05]
iex> Date.beginning_of_week(~D[2020-07-11], :saturday)
~D[2020-07-11]
iex> Date.beginning_of_week(~N[2020-07-11 01:23:45])
~D[2020-07-06]

compare(date1, date2)

(since 1.4.0)
@spec compare(Calendar.date(), Calendar.date()) :: :lt | :eq | :gt

Compares two date structs.

Returns :gt if first date is later than the second and :lt for vice versa. If the two dates are equal :eq is returned.

Examples

iex> Date.compare(~D[2016-04-16], ~D[2016-04-28])
:lt

This function can also be used to compare across more complex calendar types by considering only the date fields:

iex> Date.compare(~D[2016-04-16], ~N[2016-04-28 01:23:45])
:lt
iex> Date.compare(~D[2016-04-16], ~N[2016-04-16 01:23:45])
:eq
iex> Date.compare(~N[2016-04-16 12:34:56], ~N[2016-04-16 01:23:45])
:eq

convert(date, calendar)

(since 1.5.0)
@spec convert(Calendar.date(), Calendar.calendar()) ::
  {:ok, t()} | {:error, :incompatible_calendars}

Converts the given date from its calendar to the given calendar.

Returns {:ok, date} if the calendars are compatible, or {:error, :incompatible_calendars} if they are not.

See also Calendar.compatible_calendars?/2.

Examples

Imagine someone implements Calendar.Holocene, a calendar based on the Gregorian calendar that adds exactly 10,000 years to the current Gregorian year:

iex> Date.convert(~D[2000-01-01], Calendar.Holocene)
{:ok, %Date{calendar: Calendar.Holocene, year: 12000, month: 1, day: 1}}

convert!(date, calendar)

(since 1.5.0)
@spec convert!(Calendar.date(), Calendar.calendar()) :: t()

Similar to Date.convert/2, but raises an ArgumentError if the conversion between the two calendars is not possible.

Examples

Imagine someone implements Calendar.Holocene, a calendar based on the Gregorian calendar that adds exactly 10,000 years to the current Gregorian year:

iex> Date.convert!(~D[2000-01-01], Calendar.Holocene)
%Date{calendar: Calendar.Holocene, year: 12000, month: 1, day: 1}

day_of_era(date)

(since 1.8.0)
@spec day_of_era(Calendar.date()) :: {Calendar.day(), non_neg_integer()}

Calculates the day-of-era and era for a given calendar date.

Returns a tuple {day, era} representing the day within the era and the era number.

Examples

iex> Date.day_of_era(~D[0001-01-01])
{1, 1}

iex> Date.day_of_era(~D[0000-12-31])
{1, 0}

day_of_week(date, starting_on \\ :default)

(since 1.4.0)
@spec day_of_week(Calendar.date(), starting_on :: :default | atom()) ::
  Calendar.day_of_week()

Calculates the day of the week of a given date.

Returns the day of the week as an integer. For the ISO 8601 calendar (the default), it is an integer from 1 to 7, where 1 is Monday and 7 is Sunday.

An optional starting_on value may be supplied, which configures the weekday the week starts on. The default value for it is :default, which translates to :monday for the built-in ISO calendar. Any other weekday may be given to.

Examples

iex> Date.day_of_week(~D[2016-10-31])
1
iex> Date.day_of_week(~D[2016-11-01])
2
iex> Date.day_of_week(~N[2016-11-01 01:23:45])
2
iex> Date.day_of_week(~D[-0015-10-30])
3

iex> Date.day_of_week(~D[2016-10-31], :sunday)
2
iex> Date.day_of_week(~D[2016-11-01], :sunday)
3
iex> Date.day_of_week(~N[2016-11-01 01:23:45], :sunday)
3
iex> Date.day_of_week(~D[-0015-10-30], :sunday)
4

day_of_year(date)

(since 1.8.0)
@spec day_of_year(Calendar.date()) :: Calendar.day()

Calculates the day of the year of a given date.

Returns the day of the year as an integer. For the ISO 8601 calendar (the default), it is an integer from 1 to 366.

Examples

iex> Date.day_of_year(~D[2016-01-01])
1
iex> Date.day_of_year(~D[2016-11-01])
306
iex> Date.day_of_year(~D[-0015-10-30])
303
iex> Date.day_of_year(~D[2004-12-31])
366

days_in_month(date)

(since 1.4.0)
@spec days_in_month(Calendar.date()) :: Calendar.day()

Returns the number of days in the given date month.

Examples

iex> Date.days_in_month(~D[1900-01-13])
31
iex> Date.days_in_month(~D[1900-02-09])
28
iex> Date.days_in_month(~N[2000-02-20 01:23:45])
29

diff(date1, date2)

(since 1.5.0)
@spec diff(Calendar.date(), Calendar.date()) :: integer()

Calculates the difference between two dates, in a full number of days.

It returns the number of Gregorian days between the dates. Only Date structs that follow the same or compatible calendars can be compared this way. If two calendars are not compatible, it will raise.

Examples

iex> Date.diff(~D[2000-01-03], ~D[2000-01-01])
2
iex> Date.diff(~D[2000-01-01], ~D[2000-01-03])
-2
iex> Date.diff(~D[0000-01-02], ~D[-0001-12-30])
3
iex> Date.diff(~D[2000-01-01], ~N[2000-01-03 09:00:00])
-2

end_of_month(date)

(since 1.11.0)
@spec end_of_month(Calendar.date()) :: t()

Calculates a date that is the last day of the month for the given date.

Examples

iex> Date.end_of_month(~D[2000-01-01])
~D[2000-01-31]
iex> Date.end_of_month(~D[2000-01-31])
~D[2000-01-31]
iex> Date.end_of_month(~N[2000-01-01 01:23:45])
~D[2000-01-31]

end_of_week(date, starting_on \\ :default)

(since 1.11.0)
@spec end_of_week(Calendar.date(), starting_on :: :default | atom()) :: t()

Calculates a date that is the last day of the week for the given date.

If the day is already the last day of the week, it returns the day itself. For the built-in ISO calendar, the week ends on Sunday. A weekday rather than :default can be given as starting_on.

Examples

iex> Date.end_of_week(~D[2020-07-11])
~D[2020-07-12]
iex> Date.end_of_week(~D[2020-07-05])
~D[2020-07-05]
iex> Date.end_of_week(~D[2020-07-06], :sunday)
~D[2020-07-11]
iex> Date.end_of_week(~D[2020-07-06], :saturday)
~D[2020-07-10]
iex> Date.end_of_week(~N[2020-07-11 01:23:45])
~D[2020-07-12]

from_erl(tuple, calendar \\ Calendar.ISO)

@spec from_erl(:calendar.date(), Calendar.calendar()) :: {:ok, t()} | {:error, atom()}

Converts an Erlang date tuple to a Date struct.

Only supports converting dates which are in the ISO calendar, or other calendars in which the days also start at midnight. Attempting to convert dates from other calendars will return an error tuple.

Examples

iex> Date.from_erl({2000, 1, 1})
{:ok, ~D[2000-01-01]}
iex> Date.from_erl({2000, 13, 1})
{:error, :invalid_date}

from_erl!(tuple, calendar \\ Calendar.ISO)

@spec from_erl!(:calendar.date(), Calendar.calendar()) :: t()

Converts an Erlang date tuple but raises for invalid dates.

Examples

iex> Date.from_erl!({2000, 1, 1})
~D[2000-01-01]
iex> Date.from_erl!({2000, 13, 1})
** (ArgumentError) cannot convert {2000, 13, 1} to date, reason: :invalid_date

from_gregorian_days(days, calendar \\ Calendar.ISO)

(since 1.11.0)
@spec from_gregorian_days(integer(), Calendar.calendar()) :: t()

Converts a number of gregorian days to a Date struct.

Examples

iex> Date.from_gregorian_days(1)
~D[0000-01-02]
iex> Date.from_gregorian_days(730_485)
~D[2000-01-01]
iex> Date.from_gregorian_days(-1)
~D[-0001-12-31]

from_iso8601(string, calendar \\ Calendar.ISO)

@spec from_iso8601(String.t(), Calendar.calendar()) :: {:ok, t()} | {:error, atom()}

Parses the extended "Dates" format described by ISO 8601:2019.

The year parsed by this function is limited to four digits.

Examples

iex> Date.from_iso8601("2015-01-23")
{:ok, ~D[2015-01-23]}

iex> Date.from_iso8601("2015:01:23")
{:error, :invalid_format}

iex> Date.from_iso8601("2015-01-32")
{:error, :invalid_date}

from_iso8601!(string, calendar \\ Calendar.ISO)

@spec from_iso8601!(String.t(), Calendar.calendar()) :: t()

Parses the extended "Dates" format described by ISO 8601:2019.

Raises if the format is invalid.

Examples

iex> Date.from_iso8601!("2015-01-23")
~D[2015-01-23]
iex> Date.from_iso8601!("2015:01:23")
** (ArgumentError) cannot parse "2015:01:23" as date, reason: :invalid_format

leap_year?(date)

(since 1.4.0)
@spec leap_year?(Calendar.date()) :: boolean()

Returns true if the year in the given date is a leap year.

Examples

iex> Date.leap_year?(~D[2000-01-01])
true
iex> Date.leap_year?(~D[2001-01-01])
false
iex> Date.leap_year?(~D[2004-01-01])
true
iex> Date.leap_year?(~D[1900-01-01])
false
iex> Date.leap_year?(~N[2004-01-01 01:23:45])
true

months_in_year(date)

(since 1.7.0)
@spec months_in_year(Calendar.date()) :: Calendar.month()

Returns the number of months in the given date year.

Example

iex> Date.months_in_year(~D[1900-01-13])
12

new(year, month, day, calendar \\ Calendar.ISO)

@spec new(Calendar.year(), Calendar.month(), Calendar.day(), Calendar.calendar()) ::
  {:ok, t()} | {:error, atom()}

Builds a new ISO date.

Expects all values to be integers. Returns {:ok, date} if each entry fits its appropriate range, returns {:error, reason} otherwise.

Examples

iex> Date.new(2000, 1, 1)
{:ok, ~D[2000-01-01]}
iex> Date.new(2000, 13, 1)
{:error, :invalid_date}
iex> Date.new(2000, 2, 29)
{:ok, ~D[2000-02-29]}

iex> Date.new(2000, 2, 30)
{:error, :invalid_date}
iex> Date.new(2001, 2, 29)
{:error, :invalid_date}

new!(year, month, day, calendar \\ Calendar.ISO)

(since 1.11.0)

Builds a new ISO date.

Expects all values to be integers. Returns date if each entry fits its appropriate range, raises if the date is invalid.

Examples

iex> Date.new!(2000, 1, 1)
~D[2000-01-01]
iex> Date.new!(2000, 13, 1)
** (ArgumentError) cannot build date, reason: :invalid_date
iex> Date.new!(2000, 2, 29)
~D[2000-02-29]

quarter_of_year(date)

(since 1.8.0)
@spec quarter_of_year(Calendar.date()) :: non_neg_integer()

Calculates the quarter of the year of a given date.

Returns the day of the year as an integer. For the ISO 8601 calendar (the default), it is an integer from 1 to 4.

Examples

iex> Date.quarter_of_year(~D[2016-10-31])
4
iex> Date.quarter_of_year(~D[2016-01-01])
1
iex> Date.quarter_of_year(~N[2016-04-01 01:23:45])
2
iex> Date.quarter_of_year(~D[-0015-09-30])
3

range(first, last)

(since 1.5.0)
@spec range(Calendar.date(), Calendar.date()) :: Date.Range.t()

Returns a range of dates.

A range of dates represents a discrete number of dates where the first and last values are dates with matching calendars.

Ranges of dates can be increasing (first <= last) and are always inclusive. For a decreasing range, use range/3 with a step of -1 as first argument.

Examples

iex> Date.range(~D[1999-01-01], ~D[2000-01-01])
Date.range(~D[1999-01-01], ~D[2000-01-01])

A range of dates implements the Enumerable protocol, which means functions in the Enum module can be used to work with ranges:

iex> range = Date.range(~D[2001-01-01], ~D[2002-01-01])
iex> range
Date.range(~D[2001-01-01], ~D[2002-01-01])
iex> Enum.count(range)
366
iex> ~D[2001-02-01] in range
true
iex> Enum.take(range, 3)
[~D[2001-01-01], ~D[2001-01-02], ~D[2001-01-03]]

range(first, last, step)

(since 1.12.0)
@spec range(Calendar.date(), Calendar.date(), step :: pos_integer() | neg_integer()) ::
  Date.Range.t()

Returns a range of dates with a step.

Examples

iex> range = Date.range(~D[2001-01-01], ~D[2002-01-01], 2)
iex> range
Date.range(~D[2001-01-01], ~D[2002-01-01], 2)
iex> Enum.count(range)
183
iex> ~D[2001-01-03] in range
true
iex> Enum.take(range, 3)
[~D[2001-01-01], ~D[2001-01-03], ~D[2001-01-05]]

shift(date, duration)

(since 1.17.0)
@spec shift(Calendar.date(), Duration.t() | [unit_pair]) :: t()
when unit_pair:
       {:year, integer()}
       | {:month, integer()}
       | {:week, integer()}
       | {:day, integer()}

Shifts given date by duration according to its calendar.

Allowed units are: :year, :month, :week, :day.

When using the default ISO calendar, durations are collapsed and applied in the order of months and then days:

  • when shifting by 1 year and 2 months the date is actually shifted by 14 months
  • when shifting by 2 weeks and 3 days the date is shifted by 17 days

When shifting by month, days are rounded down to the nearest valid date.

Raises an ArgumentError when called with time scale units.

Examples

iex> Date.shift(~D[2016-01-03], month: 2)
~D[2016-03-03]
iex> Date.shift(~D[2016-01-30], month: -1)
~D[2015-12-30]
iex> Date.shift(~D[2016-01-31], year: 4, day: 1)
~D[2020-02-01]
iex> Date.shift(~D[2016-01-03], Duration.new!(month: 2))
~D[2016-03-03]

# leap years
iex> Date.shift(~D[2024-02-29], year: 1)
~D[2025-02-28]
iex> Date.shift(~D[2024-02-29], year: 4)
~D[2028-02-29]

# rounding down
iex> Date.shift(~D[2015-01-31], month: 1)
~D[2015-02-28]

to_erl(date)

@spec to_erl(Calendar.date()) :: :calendar.date()

Converts the given date to an Erlang date tuple.

Only supports converting dates which are in the ISO calendar, or other calendars in which the days also start at midnight. Attempting to convert dates from other calendars will raise.

Examples

iex> Date.to_erl(~D[2000-01-01])
{2000, 1, 1}

iex> Date.to_erl(~N[2000-01-01 00:00:00])
{2000, 1, 1}

to_gregorian_days(date)

(since 1.11.0)
@spec to_gregorian_days(Calendar.date()) :: integer()

Converts a date struct to a number of gregorian days.

Examples

iex> Date.to_gregorian_days(~D[0000-01-02])
1
iex> Date.to_gregorian_days(~D[2000-01-01])
730_485
iex> Date.to_gregorian_days(~N[2000-01-01 00:00:00])
730_485

to_iso8601(date, format \\ :extended)

@spec to_iso8601(Calendar.date(), :extended | :basic) :: String.t()

Converts the given date to ISO 8601:2019.

By default, Date.to_iso8601/2 returns dates formatted in the "extended" format, for human readability. It also supports the "basic" format through passing the :basic option.

Only supports converting dates which are in the ISO calendar, or other calendars in which the days also start at midnight. Attempting to convert dates from other calendars will raise an ArgumentError.

Examples

iex> Date.to_iso8601(~D[2000-02-28])
"2000-02-28"

iex> Date.to_iso8601(~D[2000-02-28], :basic)
"20000228"

iex> Date.to_iso8601(~N[2000-02-28 00:00:00])
"2000-02-28"

to_string(date)

@spec to_string(Calendar.date()) :: String.t()

Converts the given date to a string according to its calendar.

Examples

iex> Date.to_string(~D[2000-02-28])
"2000-02-28"
iex> Date.to_string(~N[2000-02-28 01:23:45])
"2000-02-28"
iex> Date.to_string(~D[-0100-12-15])
"-0100-12-15"

utc_today(calendar \\ Calendar.ISO)

(since 1.4.0)
@spec utc_today(Calendar.calendar()) :: t()

Returns the current date in UTC.

Examples

iex> date = Date.utc_today()
iex> date.year >= 2016
true

year_of_era(date)

(since 1.8.0)
@spec year_of_era(Calendar.date()) :: {Calendar.year(), non_neg_integer()}

Calculates the year-of-era and era for a given calendar year.

Returns a tuple {year, era} representing the year within the era and the era number.

Examples

iex> Date.year_of_era(~D[0001-01-01])
{1, 1}
iex> Date.year_of_era(~D[0000-12-31])
{1, 0}
iex> Date.year_of_era(~D[-0001-01-01])
{2, 0}