//! The [`Date`] struct and its associated `impl`s.
#[cfg(feature = "formatting")] use alloc::string::String; use core::num::NonZeroI32; use core::ops::{Add, Sub}; use core::time::Duration as StdDuration; use core::{cmp, fmt}; #[cfg(feature = "formatting")] use std::io;
use deranged::RangedI32; use num_conv::prelude::*; use powerfmt::ext::FormatterExt; use powerfmt::smart_display::{self, FormatterOptions, Metadata, SmartDisplay};
/// The minimum valid year. pub(crate) const MIN_YEAR: i32 = if cfg!(feature = "large-dates") {
-999_999
} else {
-9999
}; /// The maximum valid year. pub(crate) const MAX_YEAR: i32 = if cfg!(feature = "large-dates") { 999_999
} else { 9999
};
/// Date in the proleptic Gregorian calendar. /// /// By default, years between ±9999 inclusive are representable. This can be expanded to ±999,999 /// inclusive by enabling the `large-dates` crate feature. Doing so has performance implications /// and introduces some ambiguities when parsing. #[derive(Clone, Copy, PartialEq, Eq, Hash, PartialOrd, Ord)] pubstruct Date { /// Bitpacked field containing both the year and ordinal. // | xx | xxxxxxxxxxxxxxxxxxxxx | xxxxxxxxx | // | 2 bits | 21 bits | 9 bits | // | unassigned | year | ordinal | // The year is 15 bits when `large-dates` is not enabled.
value: NonZeroI32,
}
impl Date { /// The minimum valid `Date`. /// /// The value of this may vary depending on the feature flags enabled. // Safety: `ordinal` is not zero. #[allow(clippy::undocumented_unsafe_blocks)] pubconst MIN: Self = unsafe { Self::__from_ordinal_date_unchecked(MIN_YEAR, 1) };
/// The maximum valid `Date`. /// /// The value of this may vary depending on the feature flags enabled. // Safety: `ordinal` is not zero. #[allow(clippy::undocumented_unsafe_blocks)] pubconst MAX: Self = unsafe { Self::__from_ordinal_date_unchecked(MAX_YEAR, days_in_year(MAX_YEAR)) };
// region: constructors /// Construct a `Date` from the year and ordinal values, the validity of which must be /// guaranteed by the caller. /// /// # Safety /// /// `ordinal` must not be zero. `year` should be in the range `MIN_YEAR..=MAX_YEAR`, but this /// is not a safety invariant. #[doc(hidden)] pubconstunsafefn __from_ordinal_date_unchecked(year: i32, ordinal: u16) -> Self {
debug_assert!(year >= MIN_YEAR);
debug_assert!(year <= MAX_YEAR);
debug_assert!(ordinal != 0);
debug_assert!(ordinal <= days_in_year(year));
Self { // Safety: The caller must guarantee that `ordinal` is not zero.
value: unsafe { NonZeroI32::new_unchecked((year << 9) | ordinal as i32) },
}
}
/// Attempt to create a `Date` from the year, month, and day. /// /// ```rust /// # use time::{Date, Month}; /// assert!(Date::from_calendar_date(2019, Month::January, 1).is_ok()); /// assert!(Date::from_calendar_date(2019, Month::December, 31).is_ok()); /// ``` /// /// ```rust /// # use time::{Date, Month}; /// assert!(Date::from_calendar_date(2019, Month::February, 29).is_err()); // 2019 isn't a leap year. /// ``` pubconstfn from_calendar_date(
year: i32,
month: Month,
day: u8,
) -> Result<Self, error::ComponentRange> { /// Cumulative days through the beginning of a month in both common and leap years. const DAYS_CUMULATIVE_COMMON_LEAP: [[u16; 12]; 2] = [
[0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334],
[0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335],
];
ensure_ranged!(Year: year); match day { 1..=28 => {} 29..=31if day <= days_in_year_month(year, month) => {}
_ => { return Err(error::ComponentRange {
name: "day",
minimum: 1,
maximum: days_in_year_month(year, month) as _,
value: day as _,
conditional_range: true,
});
}
}
// Safety: `ordinal` is not zero.
Ok(unsafe { Self::__from_ordinal_date_unchecked(
year,
DAYS_CUMULATIVE_COMMON_LEAP[is_leap_year(year) as usize][month as usize - 1]
+ day as u16,
)
})
}
/// Attempt to create a `Date` from the year and ordinal day number. /// /// ```rust /// # use time::Date; /// assert!(Date::from_ordinal_date(2019, 1).is_ok()); /// assert!(Date::from_ordinal_date(2019, 365).is_ok()); /// ``` /// /// ```rust /// # use time::Date; /// assert!(Date::from_ordinal_date(2019, 366).is_err()); // 2019 isn't a leap year. /// ``` pubconstfn from_ordinal_date(year: i32, ordinal: u16) -> Result<Self, error::ComponentRange> {
ensure_ranged!(Year: year); match ordinal { 1..=365 => {} 366if is_leap_year(year) => {}
_ => { return Err(error::ComponentRange {
name: "ordinal",
minimum: 1,
maximum: days_in_year(year) as _,
value: ordinal as _,
conditional_range: true,
});
}
}
// Safety: `ordinal` is not zero.
Ok(unsafe { Self::__from_ordinal_date_unchecked(year, ordinal) })
}
/// Attempt to create a `Date` from the ISO year, week, and weekday. /// /// ```rust /// # use time::{Date, Weekday::*}; /// assert!(Date::from_iso_week_date(2019, 1, Monday).is_ok()); /// assert!(Date::from_iso_week_date(2019, 1, Tuesday).is_ok()); /// assert!(Date::from_iso_week_date(2020, 53, Friday).is_ok()); /// ``` /// /// ```rust /// # use time::{Date, Weekday::*}; /// assert!(Date::from_iso_week_date(2019, 53, Monday).is_err()); // 2019 doesn't have 53 weeks. /// ``` pubconstfn from_iso_week_date(
year: i32,
week: u8,
weekday: Weekday,
) -> Result<Self, error::ComponentRange> {
ensure_ranged!(Year: year); match week { 1..=52 => {} 53if week <= weeks_in_year(year) => {}
_ => { return Err(error::ComponentRange {
name: "week",
minimum: 1,
maximum: weeks_in_year(year) as _,
value: week as _,
conditional_range: true,
});
}
}
let adj_year = year - 1; let raw = 365 * adj_year + div_floor!(adj_year, 4) - div_floor!(adj_year, 100)
+ div_floor!(adj_year, 400); let jan_4 = match (raw % 7) as i8 {
-6 | 1 => 8,
-5 | 2 => 9,
-4 | 3 => 10,
-3 | 4 => 4,
-2 | 5 => 5,
-1 | 6 => 6,
_ => 7,
}; let ordinal = week as i16 * 7 + weekday.number_from_monday() as i16 - jan_4;
Ok(if ordinal <= 0 { // Safety: `ordinal` is not zero. unsafe { Self::__from_ordinal_date_unchecked(
year - 1,
(ordinal as u16).wrapping_add(days_in_year(year - 1)),
)
}
} elseif ordinal > days_in_year(year) as i16 { // Safety: `ordinal` is not zero. unsafe { Self::__from_ordinal_date_unchecked(year + 1, ordinal as u16 - days_in_year(year))
}
} else { // Safety: `ordinal` is not zero. unsafe { Self::__from_ordinal_date_unchecked(year, ordinal as _) }
})
}
/// Create a `Date` from the Julian day. /// /// The algorithm to perform this conversion is derived from one provided by Peter Baum; it is /// freely available [here](https://www.researchgate.net/publication/316558298_Date_Algorithms). /// /// ```rust /// # use time::Date; /// # use time_macros::date; /// assert_eq!(Date::from_julian_day(0), Ok(date!(-4713 - 11 - 24))); /// assert_eq!(Date::from_julian_day(2_451_545), Ok(date!(2000 - 01 - 01))); /// assert_eq!(Date::from_julian_day(2_458_485), Ok(date!(2019 - 01 - 01))); /// assert_eq!(Date::from_julian_day(2_458_849), Ok(date!(2019 - 12 - 31))); /// ``` #[doc(alias = "from_julian_date")] pubconstfn from_julian_day(julian_day: i32) -> Result<Self, error::ComponentRange> { type JulianDay = RangedI32<{ Date::MIN.to_julian_day() }, { Date::MAX.to_julian_day() }>;
ensure_ranged!(JulianDay: julian_day);
Ok(Self::from_julian_day_unchecked(julian_day))
}
/// Create a `Date` from the Julian day. /// /// This does not check the validity of the provided Julian day, and as such may result in an /// internally invalid value. #[doc(alias = "from_julian_date_unchecked")] pub(crate) constfn from_julian_day_unchecked(julian_day: i32) -> Self {
debug_assert!(julian_day >= Self::MIN.to_julian_day());
debug_assert!(julian_day <= Self::MAX.to_julian_day());
// To avoid a potential overflow, the value may need to be widened for some arithmetic.
let z = julian_day - 1_721_119; let (mut year, mut ordinal) = if julian_day < -19_752_948 || julian_day > 23_195_514 { let g = 100 * z as i64 - 25; let a = (g / 3_652_425) as i32; let b = a - a / 4; let year = div_floor!(100 * b as i64 + g, 36525) as i32; let ordinal = (b + z - div_floor!(36525 * year as i64, 100) as i32) as _;
(year, ordinal)
} else { let g = 100 * z - 25; let a = g / 3_652_425; let b = a - a / 4; let year = div_floor!(100 * b + g, 36525); let ordinal = (b + z - div_floor!(36525 * year, 100)) as _;
(year, ordinal)
};
// Safety: `ordinal` is not zero. unsafe { Self::__from_ordinal_date_unchecked(year, ordinal) }
} // endregion constructors
// region: getters /// Get the year of the date. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).year(), 2019); /// assert_eq!(date!(2019 - 12 - 31).year(), 2019); /// assert_eq!(date!(2020 - 01 - 01).year(), 2020); /// ``` pubconstfn year(self) -> i32 { self.value.get() >> 9
}
/// Get the month. /// /// ```rust /// # use time::Month; /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).month(), Month::January); /// assert_eq!(date!(2019 - 12 - 31).month(), Month::December); /// ``` pubconstfn month(self) -> Month { self.month_day().0
}
/// Get the day of the month. /// /// The returned value will always be in the range `1..=31`. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).day(), 1); /// assert_eq!(date!(2019 - 12 - 31).day(), 31); /// ``` pubconstfn day(self) -> u8 { self.month_day().1
}
/// Get the month and day. This is more efficient than fetching the components individually. // For whatever reason, rustc has difficulty optimizing this function. It's significantly faster // to write the statements out by hand. pub(crate) constfn month_day(self) -> (Month, u8) { /// The number of days up to and including the given month. Common years /// are first, followed by leap years. const CUMULATIVE_DAYS_IN_MONTH_COMMON_LEAP: [[u16; 11]; 2] = [
[31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334],
[31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335],
];
let days = CUMULATIVE_DAYS_IN_MONTH_COMMON_LEAP[is_leap_year(self.year()) as usize]; let ordinal = self.ordinal();
/// Get the day of the year. /// /// The returned value will always be in the range `1..=366` (`1..=365` for common years). /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).ordinal(), 1); /// assert_eq!(date!(2019 - 12 - 31).ordinal(), 365); /// ``` pubconstfn ordinal(self) -> u16 {
(self.value.get() & 0x1FF) as _
}
/// Get the ISO 8601 year and week number. pub(crate) constfn iso_year_week(self) -> (i32, u8) { let (year, ordinal) = self.to_ordinal_date();
/// Get the ISO week number. /// /// The returned value will always be in the range `1..=53`. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).iso_week(), 1); /// assert_eq!(date!(2019 - 10 - 04).iso_week(), 40); /// assert_eq!(date!(2020 - 01 - 01).iso_week(), 1); /// assert_eq!(date!(2020 - 12 - 31).iso_week(), 53); /// assert_eq!(date!(2021 - 01 - 01).iso_week(), 53); /// ``` pubconstfn iso_week(self) -> u8 { self.iso_year_week().1
}
/// Get the week number where week 1 begins on the first Sunday. /// /// The returned value will always be in the range `0..=53`. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).sunday_based_week(), 0); /// assert_eq!(date!(2020 - 01 - 01).sunday_based_week(), 0); /// assert_eq!(date!(2020 - 12 - 31).sunday_based_week(), 52); /// assert_eq!(date!(2021 - 01 - 01).sunday_based_week(), 0); /// ``` pubconstfn sunday_based_week(self) -> u8 {
((self.ordinal() as i16 - self.weekday().number_days_from_sunday() as i16 + 6) / 7) as _
}
/// Get the week number where week 1 begins on the first Monday. /// /// The returned value will always be in the range `0..=53`. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).monday_based_week(), 0); /// assert_eq!(date!(2020 - 01 - 01).monday_based_week(), 0); /// assert_eq!(date!(2020 - 12 - 31).monday_based_week(), 52); /// assert_eq!(date!(2021 - 01 - 01).monday_based_week(), 0); /// ``` pubconstfn monday_based_week(self) -> u8 {
((self.ordinal() as i16 - self.weekday().number_days_from_monday() as i16 + 6) / 7) as _
}
/// Get the year, month, and day. /// /// ```rust /// # use time::Month; /// # use time_macros::date; /// assert_eq!( /// date!(2019 - 01 - 01).to_calendar_date(), /// (2019, Month::January, 1) /// ); /// ``` pubconstfn to_calendar_date(self) -> (i32, Month, u8) { let (month, day) = self.month_day();
(self.year(), month, day)
}
/// Get the year and ordinal day number. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2019 - 01 - 01).to_ordinal_date(), (2019, 1)); /// ``` pubconstfn to_ordinal_date(self) -> (i32, u16) {
(self.year(), self.ordinal())
}
/// Calculates the first occurrence of a weekday that is strictly later than a given `Date`. /// /// # Panics /// Panics if an overflow occurred. /// /// # Examples /// ``` /// # use time::Weekday; /// # use time_macros::date; /// assert_eq!( /// date!(2023 - 06 - 28).next_occurrence(Weekday::Monday), /// date!(2023 - 07 - 03) /// ); /// assert_eq!( /// date!(2023 - 06 - 19).next_occurrence(Weekday::Monday), /// date!(2023 - 06 - 26) /// ); /// ``` pubconstfn next_occurrence(self, weekday: Weekday) -> Self {
expect_opt!( self.checked_next_occurrence(weekday), "overflow calculating the next occurrence of a weekday"
)
}
/// Calculates the first occurrence of a weekday that is strictly earlier than a given `Date`. /// /// # Panics /// Panics if an overflow occurred. /// /// # Examples /// ``` /// # use time::Weekday; /// # use time_macros::date; /// assert_eq!( /// date!(2023 - 06 - 28).prev_occurrence(Weekday::Monday), /// date!(2023 - 06 - 26) /// ); /// assert_eq!( /// date!(2023 - 06 - 19).prev_occurrence(Weekday::Monday), /// date!(2023 - 06 - 12) /// ); /// ``` pubconstfn prev_occurrence(self, weekday: Weekday) -> Self {
expect_opt!( self.checked_prev_occurrence(weekday), "overflow calculating the previous occurrence of a weekday"
)
}
/// Calculates the `n`th occurrence of a weekday that is strictly later than a given `Date`. /// /// # Panics /// Panics if an overflow occurred or if `n == 0`. /// /// # Examples /// ``` /// # use time::Weekday; /// # use time_macros::date; /// assert_eq!( /// date!(2023 - 06 - 25).nth_next_occurrence(Weekday::Monday, 5), /// date!(2023 - 07 - 24) /// ); /// assert_eq!( /// date!(2023 - 06 - 26).nth_next_occurrence(Weekday::Monday, 5), /// date!(2023 - 07 - 31) /// ); /// ``` pubconstfn nth_next_occurrence(self, weekday: Weekday, n: u8) -> Self {
expect_opt!( self.checked_nth_next_occurrence(weekday, n), "overflow calculating the next occurrence of a weekday"
)
}
/// Calculates the `n`th occurrence of a weekday that is strictly earlier than a given `Date`. /// /// # Panics /// Panics if an overflow occurred or if `n == 0`. /// /// # Examples /// ``` /// # use time::Weekday; /// # use time_macros::date; /// assert_eq!( /// date!(2023 - 06 - 27).nth_prev_occurrence(Weekday::Monday, 3), /// date!(2023 - 06 - 12) /// ); /// assert_eq!( /// date!(2023 - 06 - 26).nth_prev_occurrence(Weekday::Monday, 3), /// date!(2023 - 06 - 05) /// ); /// ``` pubconstfn nth_prev_occurrence(self, weekday: Weekday, n: u8) -> Self {
expect_opt!( self.checked_nth_prev_occurrence(weekday, n), "overflow calculating the previous occurrence of a weekday"
)
}
/// Get the Julian day for the date. /// /// The algorithm to perform this conversion is derived from one provided by Peter Baum; it is /// freely available [here](https://www.researchgate.net/publication/316558298_Date_Algorithms). /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(-4713 - 11 - 24).to_julian_day(), 0); /// assert_eq!(date!(2000 - 01 - 01).to_julian_day(), 2_451_545); /// assert_eq!(date!(2019 - 01 - 01).to_julian_day(), 2_458_485); /// assert_eq!(date!(2019 - 12 - 31).to_julian_day(), 2_458_849); /// ``` pubconstfn to_julian_day(self) -> i32 { let year = self.year() - 1; let ordinal = self.ordinal() as i32;
// region: checked arithmetic /// Computes `self + duration`, returning `None` if an overflow occurred. /// /// ```rust /// # use time::{Date, ext::NumericalDuration}; /// # use time_macros::date; /// assert_eq!(Date::MAX.checked_add(1.days()), None); /// assert_eq!(Date::MIN.checked_add((-2).days()), None); /// assert_eq!( /// date!(2020 - 12 - 31).checked_add(2.days()), /// Some(date!(2021 - 01 - 02)) /// ); /// ``` /// /// # Note /// /// This function only takes whole days into account. /// /// ```rust /// # use time::{Date, ext::NumericalDuration}; /// # use time_macros::date; /// assert_eq!(Date::MAX.checked_add(23.hours()), Some(Date::MAX)); /// assert_eq!(Date::MIN.checked_add((-23).hours()), Some(Date::MIN)); /// assert_eq!( /// date!(2020 - 12 - 31).checked_add(23.hours()), /// Some(date!(2020 - 12 - 31)) /// ); /// assert_eq!( /// date!(2020 - 12 - 31).checked_add(47.hours()), /// Some(date!(2021 - 01 - 01)) /// ); /// ``` pubconstfn checked_add(self, duration: Duration) -> Option<Self> { let whole_days = duration.whole_days(); if whole_days < i32::MIN as i64 || whole_days > i32::MAX as i64 { return None;
}
let julian_day = const_try_opt!(self.to_julian_day().checked_add(whole_days as _)); iflet Ok(date) = Self::from_julian_day(julian_day) {
Some(date)
} else {
None
}
}
/// Computes `self + duration`, returning `None` if an overflow occurred. /// /// ```rust /// # use time::{Date, ext::NumericalStdDuration}; /// # use time_macros::date; /// assert_eq!(Date::MAX.checked_add_std(1.std_days()), None); /// assert_eq!( /// date!(2020 - 12 - 31).checked_add_std(2.std_days()), /// Some(date!(2021 - 01 - 02)) /// ); /// ``` /// /// # Note /// /// This function only takes whole days into account. /// /// ```rust /// # use time::{Date, ext::NumericalStdDuration}; /// # use time_macros::date; /// assert_eq!(Date::MAX.checked_add_std(23.std_hours()), Some(Date::MAX)); /// assert_eq!( /// date!(2020 - 12 - 31).checked_add_std(23.std_hours()), /// Some(date!(2020 - 12 - 31)) /// ); /// assert_eq!( /// date!(2020 - 12 - 31).checked_add_std(47.std_hours()), /// Some(date!(2021 - 01 - 01)) /// ); /// ``` pubconstfn checked_add_std(self, duration: StdDuration) -> Option<Self> { let whole_days = duration.as_secs() / Second::per(Day) as u64; if whole_days > i32::MAX as u64 { return None;
}
let julian_day = const_try_opt!(self.to_julian_day().checked_add(whole_days as _)); iflet Ok(date) = Self::from_julian_day(julian_day) {
Some(date)
} else {
None
}
}
/// Computes `self - duration`, returning `None` if an overflow occurred. /// /// ``` /// # use time::{Date, ext::NumericalDuration}; /// # use time_macros::date; /// assert_eq!(Date::MAX.checked_sub((-2).days()), None); /// assert_eq!(Date::MIN.checked_sub(1.days()), None); /// assert_eq!( /// date!(2020 - 12 - 31).checked_sub(2.days()), /// Some(date!(2020 - 12 - 29)) /// ); /// ``` /// /// # Note /// /// This function only takes whole days into account. /// /// ``` /// # use time::{Date, ext::NumericalDuration}; /// # use time_macros::date; /// assert_eq!(Date::MAX.checked_sub((-23).hours()), Some(Date::MAX)); /// assert_eq!(Date::MIN.checked_sub(23.hours()), Some(Date::MIN)); /// assert_eq!( /// date!(2020 - 12 - 31).checked_sub(23.hours()), /// Some(date!(2020 - 12 - 31)) /// ); /// assert_eq!( /// date!(2020 - 12 - 31).checked_sub(47.hours()), /// Some(date!(2020 - 12 - 30)) /// ); /// ``` pubconstfn checked_sub(self, duration: Duration) -> Option<Self> { let whole_days = duration.whole_days(); if whole_days < i32::MIN as i64 || whole_days > i32::MAX as i64 { return None;
}
let julian_day = const_try_opt!(self.to_julian_day().checked_sub(whole_days as _)); iflet Ok(date) = Self::from_julian_day(julian_day) {
Some(date)
} else {
None
}
}
/// Computes `self - duration`, returning `None` if an overflow occurred. /// /// ``` /// # use time::{Date, ext::NumericalStdDuration}; /// # use time_macros::date; /// assert_eq!(Date::MIN.checked_sub_std(1.std_days()), None); /// assert_eq!( /// date!(2020 - 12 - 31).checked_sub_std(2.std_days()), /// Some(date!(2020 - 12 - 29)) /// ); /// ``` /// /// # Note /// /// This function only takes whole days into account. /// /// ``` /// # use time::{Date, ext::NumericalStdDuration}; /// # use time_macros::date; /// assert_eq!(Date::MIN.checked_sub_std(23.std_hours()), Some(Date::MIN)); /// assert_eq!( /// date!(2020 - 12 - 31).checked_sub_std(23.std_hours()), /// Some(date!(2020 - 12 - 31)) /// ); /// assert_eq!( /// date!(2020 - 12 - 31).checked_sub_std(47.std_hours()), /// Some(date!(2020 - 12 - 30)) /// ); /// ``` pubconstfn checked_sub_std(self, duration: StdDuration) -> Option<Self> { let whole_days = duration.as_secs() / Second::per(Day) as u64; if whole_days > i32::MAX as u64 { return None;
}
let julian_day = const_try_opt!(self.to_julian_day().checked_sub(whole_days as _)); iflet Ok(date) = Self::from_julian_day(julian_day) {
Some(date)
} else {
None
}
}
/// Calculates the first occurrence of a weekday that is strictly later than a given `Date`. /// Returns `None` if an overflow occurred. pub(crate) constfn checked_next_occurrence(self, weekday: Weekday) -> Option<Self> { let day_diff = match weekday as i8 - self.weekday() as i8 { 1 | -6 => 1, 2 | -5 => 2, 3 | -4 => 3, 4 | -3 => 4, 5 | -2 => 5, 6 | -1 => 6,
val => {
debug_assert!(val == 0); 7
}
};
self.checked_add(Duration::days(day_diff))
}
/// Calculates the first occurrence of a weekday that is strictly earlier than a given `Date`. /// Returns `None` if an overflow occurred. pub(crate) constfn checked_prev_occurrence(self, weekday: Weekday) -> Option<Self> { let day_diff = match weekday as i8 - self.weekday() as i8 { 1 | -6 => 6, 2 | -5 => 5, 3 | -4 => 4, 4 | -3 => 3, 5 | -2 => 2, 6 | -1 => 1,
val => {
debug_assert!(val == 0); 7
}
};
self.checked_sub(Duration::days(day_diff))
}
/// Calculates the `n`th occurrence of a weekday that is strictly later than a given `Date`. /// Returns `None` if an overflow occurred or if `n == 0`. pub(crate) constfn checked_nth_next_occurrence(self, weekday: Weekday, n: u8) -> Option<Self> { if n == 0 { return None;
}
const_try_opt!(self.checked_next_occurrence(weekday))
.checked_add(Duration::weeks(n as i64 - 1))
}
/// Calculates the `n`th occurrence of a weekday that is strictly earlier than a given `Date`. /// Returns `None` if an overflow occurred or if `n == 0`. pub(crate) constfn checked_nth_prev_occurrence(self, weekday: Weekday, n: u8) -> Option<Self> { if n == 0 { return None;
}
// region: replacement /// Replace the year. The month and day will be unchanged. /// /// ```rust /// # use time_macros::date; /// assert_eq!( /// date!(2022 - 02 - 18).replace_year(2019), /// Ok(date!(2019 - 02 - 18)) /// ); /// assert!(date!(2022 - 02 - 18).replace_year(-1_000_000_000).is_err()); // -1_000_000_000 isn't a valid year /// assert!(date!(2022 - 02 - 18).replace_year(1_000_000_000).is_err()); // 1_000_000_000 isn't a valid year /// ``` #[must_use = "This method does not mutate the original `Date`."] pubconstfn replace_year(self, year: i32) -> Result<Self, error::ComponentRange> {
ensure_ranged!(Year: year);
let ordinal = self.ordinal();
// Dates in January and February are unaffected by leap years. if ordinal <= 59 { // Safety: `ordinal` is not zero. return Ok(unsafe { Self::__from_ordinal_date_unchecked(year, ordinal) });
}
match (is_leap_year(self.year()), is_leap_year(year)) {
(false, false) | (true, true) => { // Safety: `ordinal` is not zero.
Ok(unsafe { Self::__from_ordinal_date_unchecked(year, ordinal) })
} // February 29 does not exist in common years.
(true, false) if ordinal == 60 => Err(error::ComponentRange {
name: "day",
value: 29,
minimum: 1,
maximum: 28,
conditional_range: true,
}), // We're going from a common year to a leap year. Shift dates in March and later by // one day. // Safety: `ordinal` is not zero.
(false, true) => Ok(unsafe { Self::__from_ordinal_date_unchecked(year, ordinal + 1) }), // We're going from a leap year to a common year. Shift dates in January and // February by one day. // Safety: `ordinal` is not zero.
(true, false) => Ok(unsafe { Self::__from_ordinal_date_unchecked(year, ordinal - 1) }),
}
}
/// Replace the month of the year. /// /// ```rust /// # use time_macros::date; /// # use time::Month; /// assert_eq!( /// date!(2022 - 02 - 18).replace_month(Month::January), /// Ok(date!(2022 - 01 - 18)) /// ); /// assert!( /// date!(2022 - 01 - 30) /// .replace_month(Month::February) /// .is_err() /// ); // 30 isn't a valid day in February /// ``` #[must_use = "This method does not mutate the original `Date`."] pubconstfn replace_month(self, month: Month) -> Result<Self, error::ComponentRange> { let (year, _, day) = self.to_calendar_date(); Self::from_calendar_date(year, month, day)
}
/// Replace the day of the month. /// /// ```rust /// # use time_macros::date; /// assert_eq!( /// date!(2022 - 02 - 18).replace_day(1), /// Ok(date!(2022 - 02 - 01)) /// ); /// assert!(date!(2022 - 02 - 18).replace_day(0).is_err()); // 0 isn't a valid day /// assert!(date!(2022 - 02 - 18).replace_day(30).is_err()); // 30 isn't a valid day in February /// ``` #[must_use = "This method does not mutate the original `Date`."] pubconstfn replace_day(self, day: u8) -> Result<Self, error::ComponentRange> { match day { 1..=28 => {} 29..=31if day <= days_in_year_month(self.year(), self.month()) => {}
_ => { return Err(error::ComponentRange {
name: "day",
minimum: 1,
maximum: days_in_year_month(self.year(), self.month()) as _,
value: day as _,
conditional_range: true,
});
}
}
// Safety: `ordinal` is not zero.
Ok(unsafe { Self::__from_ordinal_date_unchecked( self.year(),
(self.ordinal() as i16 - self.day() as i16 + day as i16) as _,
)
})
}
/// Replace the day of the year. /// /// ```rust /// # use time_macros::date; /// assert_eq!(date!(2022 - 049).replace_ordinal(1), Ok(date!(2022 - 001))); /// assert!(date!(2022 - 049).replace_ordinal(0).is_err()); // 0 isn't a valid ordinal /// assert!(date!(2022 - 049).replace_ordinal(366).is_err()); // 2022 isn't a leap year /// ```` #[must_use = "This method does not mutate the original `Date`."] pubconstfn replace_ordinal(self, ordinal: u16) -> Result<Self, error::ComponentRange> { match ordinal { 1..=365 => {} 366if is_leap_year(self.year()) => {}
_ => { return Err(error::ComponentRange {
name: "ordinal",
minimum: 1,
maximum: days_in_year(self.year()) as _,
value: ordinal as _,
conditional_range: true,
});
}
}
// Safety: `ordinal` is in range.
Ok(unsafe { Self::__from_ordinal_date_unchecked(self.year(), ordinal) })
} // endregion replacement
}
// region: attach time /// Methods to add a [`Time`] component, resulting in a [`PrimitiveDateTime`]. impl Date { /// Create a [`PrimitiveDateTime`] using the existing date. The [`Time`] component will be set /// to midnight. /// /// ```rust /// # use time_macros::{date, datetime}; /// assert_eq!(date!(1970-01-01).midnight(), datetime!(1970-01-01 0:00)); /// ``` pubconstfn midnight(self) -> PrimitiveDateTime {
PrimitiveDateTime::new(self, Time::MIDNIGHT)
}
/// Create a [`PrimitiveDateTime`] using the existing date and the provided [`Time`]. /// /// ```rust /// # use time_macros::{date, datetime, time}; /// assert_eq!( /// date!(1970-01-01).with_time(time!(0:00)), /// datetime!(1970-01-01 0:00), /// ); /// ``` pubconstfn with_time(self, time: Time) -> PrimitiveDateTime {
PrimitiveDateTime::new(self, time)
}
/// Attempt to create a [`PrimitiveDateTime`] using the existing date and the provided time. /// /// ```rust /// # use time_macros::date; /// assert!(date!(1970 - 01 - 01).with_hms(0, 0, 0).is_ok()); /// assert!(date!(1970 - 01 - 01).with_hms(24, 0, 0).is_err()); /// ``` pubconstfn with_hms( self,
hour: u8,
minute: u8,
second: u8,
) -> Result<PrimitiveDateTime, error::ComponentRange> {
Ok(PrimitiveDateTime::new( self,
const_try!(Time::from_hms(hour, minute, second)),
))
}
/// Attempt to create a [`PrimitiveDateTime`] using the existing date and the provided time. /// /// ```rust /// # use time_macros::date; /// assert!(date!(1970 - 01 - 01).with_hms_milli(0, 0, 0, 0).is_ok()); /// assert!(date!(1970 - 01 - 01).with_hms_milli(24, 0, 0, 0).is_err()); /// ``` pubconstfn with_hms_milli( self,
hour: u8,
minute: u8,
second: u8,
millisecond: u16,
) -> Result<PrimitiveDateTime, error::ComponentRange> {
Ok(PrimitiveDateTime::new( self,
const_try!(Time::from_hms_milli(hour, minute, second, millisecond)),
))
}
/// Attempt to create a [`PrimitiveDateTime`] using the existing date and the provided time. /// /// ```rust /// # use time_macros::date; /// assert!(date!(1970 - 01 - 01).with_hms_micro(0, 0, 0, 0).is_ok()); /// assert!(date!(1970 - 01 - 01).with_hms_micro(24, 0, 0, 0).is_err()); /// ``` pubconstfn with_hms_micro( self,
hour: u8,
minute: u8,
second: u8,
microsecond: u32,
) -> Result<PrimitiveDateTime, error::ComponentRange> {
Ok(PrimitiveDateTime::new( self,
const_try!(Time::from_hms_micro(hour, minute, second, microsecond)),
))
}
/// Attempt to create a [`PrimitiveDateTime`] using the existing date and the provided time. /// /// ```rust /// # use time_macros::date; /// assert!(date!(1970 - 01 - 01).with_hms_nano(0, 0, 0, 0).is_ok()); /// assert!(date!(1970 - 01 - 01).with_hms_nano(24, 0, 0, 0).is_err()); /// ``` pubconstfn with_hms_nano( self,
hour: u8,
minute: u8,
second: u8,
nanosecond: u32,
) -> Result<PrimitiveDateTime, error::ComponentRange> {
Ok(PrimitiveDateTime::new( self,
const_try!(Time::from_hms_nano(hour, minute, second, nanosecond)),
))
}
} // endregion attach time
// region: formatting & parsing #[cfg(feature = "formatting")] impl Date { /// Format the `Date` using the provided [format description](crate::format_description). pubfn format_into( self,
output: &mutimpl io::Write,
format: &(impl Formattable + ?Sized),
) -> Result<usize, error::Format> {
format.format_into(output, Some(self), None, None)
}
/// Format the `Date` using the provided [format description](crate::format_description). /// /// ```rust /// # use time::{format_description}; /// # use time_macros::date; /// let format = format_description::parse("[year]-[month]-[day]")?; /// assert_eq!(date!(2020 - 01 - 02).format(&format)?, "2020-01-02"); /// # Ok::<_, time::Error>(()) /// ``` pubfn format(self, format: &(impl Formattable + ?Sized)) -> Result<String, error::Format> {
format.format(Some(self), None, None)
}
}
#[cfg(feature = "parsing")] impl Date { /// Parse a `Date` from the input using the provided [format /// description](crate::format_description). /// /// ```rust /// # use time::Date; /// # use time_macros::{date, format_description}; /// let format = format_description!("[year]-[month]-[day]"); /// assert_eq!(Date::parse("2020-01-02", &format)?, date!(2020 - 01 - 02)); /// # Ok::<_, time::Error>(()) /// ``` pubfn parse(
input: &str,
description: &(impl Parsable + ?Sized),
) -> Result<Self, error::Parse> {
description.parse_date(input.as_bytes())
}
}
mod private { #[non_exhaustive] #[derive(Debug, Clone, Copy)] pubstruct DateMetadata { /// The width of the year component, including the sign. pub(super) year_width: u8, /// Whether the sign should be displayed. pub(super) display_sign: bool, pub(super) year: i32, pub(super) month: u8, pub(super) day: u8,
}
} use private::DateMetadata;
impl SmartDisplay for Date { type Metadata = DateMetadata;
// There is a minimum of four digits for any year. letmut year_width = cmp::max(year.unsigned_abs().num_digits(), 4); let display_sign = if !(0..10_000).contains(&year) { // An extra character is required for the sign.
year_width += 1; true
} else { false
};
let formatted_width = year_width.extend::<usize>()
+ smart_display::padded_width_of!( "-",
u8::from(month) => width(2), "-",
day => width(2),
);
Die Informationen auf dieser Webseite wurden
nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit,
noch Qualität der bereit gestellten Informationen zugesichert.
Bemerkung:
Die farbliche Syntaxdarstellung und die Messung sind noch experimentell.