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// This is a part of Chrono.
// See README.md and LICENSE.txt for details.
//! ISO 8601 date and time without timezone.
#[cfg(any(feature = "alloc", feature = "std", test))]
use core::borrow::Borrow;
use core::ops::{Add, AddAssign, Sub, SubAssign};
use core::{fmt, str};
use num_integer::div_mod_floor;
use num_traits::ToPrimitive;
#[cfg(feature = "rkyv")]
use rkyv::{Archive, Deserialize, Serialize};
#[cfg(any(feature = "alloc", feature = "std", test))]
use crate::format::DelayedFormat;
use crate::format::{parse, ParseError, ParseResult, Parsed, StrftimeItems};
use crate::format::{Fixed, Item, Numeric, Pad};
use crate::naive::{IsoWeek, NaiveDate, NaiveTime};
use crate::oldtime::Duration as OldDuration;
use crate::{DateTime, Datelike, LocalResult, TimeZone, Timelike, Weekday};
#[cfg(feature = "rustc-serialize")]
pub(super) mod rustc_serialize;
/// Tools to help serializing/deserializing `NaiveDateTime`s
#[cfg(feature = "serde")]
pub(crate) mod serde;
#[cfg(test)]
mod tests;
/// The tight upper bound guarantees that a duration with `|Duration| >= 2^MAX_SECS_BITS`
/// will always overflow the addition with any date and time type.
///
/// So why is this needed? `Duration::seconds(rhs)` may overflow, and we don't have
/// an alternative returning `Option` or `Result`. Thus we need some early bound to avoid
/// touching that call when we are already sure that it WILL overflow...
const MAX_SECS_BITS: usize = 44;
/// The minimum possible `NaiveDateTime`.
#[deprecated(since = "0.4.20", note = "Use NaiveDateTime::MIN instead")]
pub const MIN_DATETIME: NaiveDateTime = NaiveDateTime::MIN;
/// The maximum possible `NaiveDateTime`.
#[deprecated(since = "0.4.20", note = "Use NaiveDateTime::MAX instead")]
pub const MAX_DATETIME: NaiveDateTime = NaiveDateTime::MAX;
/// ISO 8601 combined date and time without timezone.
///
/// # Example
///
/// `NaiveDateTime` is commonly created from [`NaiveDate`](./struct.NaiveDate.html).
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2016, 7, 8).and_hms(9, 10, 11);
/// # let _ = dt;
/// ```
///
/// You can use typical [date-like](../trait.Datelike.html) and
/// [time-like](../trait.Timelike.html) methods,
/// provided that relevant traits are in the scope.
///
/// ```
/// # use chrono::{NaiveDate, NaiveDateTime};
/// # let dt: NaiveDateTime = NaiveDate::from_ymd(2016, 7, 8).and_hms(9, 10, 11);
/// use chrono::{Datelike, Timelike, Weekday};
///
/// assert_eq!(dt.weekday(), Weekday::Fri);
/// assert_eq!(dt.num_seconds_from_midnight(), 33011);
/// ```
#[derive(PartialEq, Eq, Hash, PartialOrd, Ord, Copy, Clone)]
#[cfg_attr(feature = "rkyv", derive(Archive, Deserialize, Serialize))]
pub struct NaiveDateTime {
date: NaiveDate,
time: NaiveTime,
}
impl NaiveDateTime {
/// Makes a new `NaiveDateTime` from date and time components.
/// Equivalent to [`date.and_time(time)`](./struct.NaiveDate.html#method.and_time)
/// and many other helper constructors on `NaiveDate`.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveTime, NaiveDateTime};
///
/// let d = NaiveDate::from_ymd(2015, 6, 3);
/// let t = NaiveTime::from_hms_milli(12, 34, 56, 789);
///
/// let dt = NaiveDateTime::new(d, t);
/// assert_eq!(dt.date(), d);
/// assert_eq!(dt.time(), t);
/// ```
#[inline]
pub fn new(date: NaiveDate, time: NaiveTime) -> NaiveDateTime {
NaiveDateTime { date, time }
}
/// Makes a new `NaiveDateTime` corresponding to a UTC date and time,
/// from the number of non-leap seconds
/// since the midnight UTC on January 1, 1970 (aka "UNIX timestamp")
/// and the number of nanoseconds since the last whole non-leap second.
///
/// For a non-naive version of this function see
/// [`TimeZone::timestamp`](../offset/trait.TimeZone.html#method.timestamp).
///
/// The nanosecond part can exceed 1,000,000,000 in order to represent the
/// [leap second](./struct.NaiveTime.html#leap-second-handling). (The true "UNIX
/// timestamp" cannot represent a leap second unambiguously.)
///
/// Panics on the out-of-range number of seconds and/or invalid nanosecond.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDateTime, NaiveDate};
///
/// let dt = NaiveDateTime::from_timestamp(0, 42_000_000);
/// assert_eq!(dt, NaiveDate::from_ymd(1970, 1, 1).and_hms_milli(0, 0, 0, 42));
///
/// let dt = NaiveDateTime::from_timestamp(1_000_000_000, 0);
/// assert_eq!(dt, NaiveDate::from_ymd(2001, 9, 9).and_hms(1, 46, 40));
/// ```
#[inline]
pub fn from_timestamp(secs: i64, nsecs: u32) -> NaiveDateTime {
let datetime = NaiveDateTime::from_timestamp_opt(secs, nsecs);
datetime.expect("invalid or out-of-range datetime")
}
/// Makes a new `NaiveDateTime` corresponding to a UTC date and time,
/// from the number of non-leap seconds
/// since the midnight UTC on January 1, 1970 (aka "UNIX timestamp")
/// and the number of nanoseconds since the last whole non-leap second.
///
/// The nanosecond part can exceed 1,000,000,000
/// in order to represent the [leap second](./struct.NaiveTime.html#leap-second-handling).
/// (The true "UNIX timestamp" cannot represent a leap second unambiguously.)
///
/// Returns `None` on the out-of-range number of seconds and/or invalid nanosecond.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDateTime, NaiveDate};
/// use std::i64;
///
/// let from_timestamp_opt = NaiveDateTime::from_timestamp_opt;
///
/// assert!(from_timestamp_opt(0, 0).is_some());
/// assert!(from_timestamp_opt(0, 999_999_999).is_some());
/// assert!(from_timestamp_opt(0, 1_500_000_000).is_some()); // leap second
/// assert!(from_timestamp_opt(0, 2_000_000_000).is_none());
/// assert!(from_timestamp_opt(i64::MAX, 0).is_none());
/// ```
#[inline]
pub fn from_timestamp_opt(secs: i64, nsecs: u32) -> Option<NaiveDateTime> {
let (days, secs) = div_mod_floor(secs, 86_400);
let date = days
.to_i32()
.and_then(|days| days.checked_add(719_163))
.and_then(NaiveDate::from_num_days_from_ce_opt);
let time = NaiveTime::from_num_seconds_from_midnight_opt(secs as u32, nsecs);
match (date, time) {
(Some(date), Some(time)) => Some(NaiveDateTime { date, time }),
(_, _) => None,
}
}
/// Parses a string with the specified format string and returns a new `NaiveDateTime`.
/// See the [`format::strftime` module](../format/strftime/index.html)
/// on the supported escape sequences.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDateTime, NaiveDate};
///
/// let parse_from_str = NaiveDateTime::parse_from_str;
///
/// assert_eq!(parse_from_str("2015-09-05 23:56:04", "%Y-%m-%d %H:%M:%S"),
/// Ok(NaiveDate::from_ymd(2015, 9, 5).and_hms(23, 56, 4)));
/// assert_eq!(parse_from_str("5sep2015pm012345.6789", "%d%b%Y%p%I%M%S%.f"),
/// Ok(NaiveDate::from_ymd(2015, 9, 5).and_hms_micro(13, 23, 45, 678_900)));
/// ```
///
/// Offset is ignored for the purpose of parsing.
///
/// ```
/// # use chrono::{NaiveDateTime, NaiveDate};
/// # let parse_from_str = NaiveDateTime::parse_from_str;
/// assert_eq!(parse_from_str("2014-5-17T12:34:56+09:30", "%Y-%m-%dT%H:%M:%S%z"),
/// Ok(NaiveDate::from_ymd(2014, 5, 17).and_hms(12, 34, 56)));
/// ```
///
/// [Leap seconds](./struct.NaiveTime.html#leap-second-handling) are correctly handled by
/// treating any time of the form `hh:mm:60` as a leap second.
/// (This equally applies to the formatting, so the round trip is possible.)
///
/// ```
/// # use chrono::{NaiveDateTime, NaiveDate};
/// # let parse_from_str = NaiveDateTime::parse_from_str;
/// assert_eq!(parse_from_str("2015-07-01 08:59:60.123", "%Y-%m-%d %H:%M:%S%.f"),
/// Ok(NaiveDate::from_ymd(2015, 7, 1).and_hms_milli(8, 59, 59, 1_123)));
/// ```
///
/// Missing seconds are assumed to be zero,
/// but out-of-bound times or insufficient fields are errors otherwise.
///
/// ```
/// # use chrono::{NaiveDateTime, NaiveDate};
/// # let parse_from_str = NaiveDateTime::parse_from_str;
/// assert_eq!(parse_from_str("94/9/4 7:15", "%y/%m/%d %H:%M"),
/// Ok(NaiveDate::from_ymd(1994, 9, 4).and_hms(7, 15, 0)));
///
/// assert!(parse_from_str("04m33s", "%Mm%Ss").is_err());
/// assert!(parse_from_str("94/9/4 12", "%y/%m/%d %H").is_err());
/// assert!(parse_from_str("94/9/4 17:60", "%y/%m/%d %H:%M").is_err());
/// assert!(parse_from_str("94/9/4 24:00:00", "%y/%m/%d %H:%M:%S").is_err());
/// ```
///
/// All parsed fields should be consistent to each other, otherwise it's an error.
///
/// ```
/// # use chrono::NaiveDateTime;
/// # let parse_from_str = NaiveDateTime::parse_from_str;
/// let fmt = "%Y-%m-%d %H:%M:%S = UNIX timestamp %s";
/// assert!(parse_from_str("2001-09-09 01:46:39 = UNIX timestamp 999999999", fmt).is_ok());
/// assert!(parse_from_str("1970-01-01 00:00:00 = UNIX timestamp 1", fmt).is_err());
/// ```
pub fn parse_from_str(s: &str, fmt: &str) -> ParseResult<NaiveDateTime> {
let mut parsed = Parsed::new();
parse(&mut parsed, s, StrftimeItems::new(fmt))?;
parsed.to_naive_datetime_with_offset(0) // no offset adjustment
}
/// Retrieves a date component.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2016, 7, 8).and_hms(9, 10, 11);
/// assert_eq!(dt.date(), NaiveDate::from_ymd(2016, 7, 8));
/// ```
#[inline]
pub fn date(&self) -> NaiveDate {
self.date
}
/// Retrieves a time component.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveTime};
///
/// let dt = NaiveDate::from_ymd(2016, 7, 8).and_hms(9, 10, 11);
/// assert_eq!(dt.time(), NaiveTime::from_hms(9, 10, 11));
/// ```
#[inline]
pub fn time(&self) -> NaiveTime {
self.time
}
/// Returns the number of non-leap seconds since the midnight on January 1, 1970.
///
/// Note that this does *not* account for the timezone!
/// The true "UNIX timestamp" would count seconds since the midnight *UTC* on the epoch.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(1970, 1, 1).and_hms_milli(0, 0, 1, 980);
/// assert_eq!(dt.timestamp(), 1);
///
/// let dt = NaiveDate::from_ymd(2001, 9, 9).and_hms(1, 46, 40);
/// assert_eq!(dt.timestamp(), 1_000_000_000);
///
/// let dt = NaiveDate::from_ymd(1969, 12, 31).and_hms(23, 59, 59);
/// assert_eq!(dt.timestamp(), -1);
///
/// let dt = NaiveDate::from_ymd(-1, 1, 1).and_hms(0, 0, 0);
/// assert_eq!(dt.timestamp(), -62198755200);
/// ```
#[inline]
pub fn timestamp(&self) -> i64 {
const UNIX_EPOCH_DAY: i64 = 719_163;
let gregorian_day = i64::from(self.date.num_days_from_ce());
let seconds_from_midnight = i64::from(self.time.num_seconds_from_midnight());
(gregorian_day - UNIX_EPOCH_DAY) * 86_400 + seconds_from_midnight
}
/// Returns the number of non-leap *milliseconds* since midnight on January 1, 1970.
///
/// Note that this does *not* account for the timezone!
/// The true "UNIX timestamp" would count seconds since the midnight *UTC* on the epoch.
///
/// Note also that this does reduce the number of years that can be
/// represented from ~584 Billion to ~584 Million. (If this is a problem,
/// please file an issue to let me know what domain needs millisecond
/// precision over billions of years, I'm curious.)
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(1970, 1, 1).and_hms_milli(0, 0, 1, 444);
/// assert_eq!(dt.timestamp_millis(), 1_444);
///
/// let dt = NaiveDate::from_ymd(2001, 9, 9).and_hms_milli(1, 46, 40, 555);
/// assert_eq!(dt.timestamp_millis(), 1_000_000_000_555);
///
/// let dt = NaiveDate::from_ymd(1969, 12, 31).and_hms_milli(23, 59, 59, 100);
/// assert_eq!(dt.timestamp_millis(), -900);
/// ```
#[inline]
pub fn timestamp_millis(&self) -> i64 {
let as_ms = self.timestamp() * 1000;
as_ms + i64::from(self.timestamp_subsec_millis())
}
/// Returns the number of non-leap *microseconds* since midnight on January 1, 1970.
///
/// Note that this does *not* account for the timezone!
/// The true "UNIX timestamp" would count seconds since the midnight *UTC* on the epoch.
///
/// Note also that this does reduce the number of years that can be
/// represented from ~584 Billion to ~584 Thousand. (If this is a problem,
/// please file an issue to let me know what domain needs microsecond
/// precision over millennia, I'm curious.)
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(1970, 1, 1).and_hms_micro(0, 0, 1, 444);
/// assert_eq!(dt.timestamp_micros(), 1_000_444);
///
/// let dt = NaiveDate::from_ymd(2001, 9, 9).and_hms_micro(1, 46, 40, 555);
/// assert_eq!(dt.timestamp_micros(), 1_000_000_000_000_555);
/// ```
#[inline]
pub fn timestamp_micros(&self) -> i64 {
let as_us = self.timestamp() * 1_000_000;
as_us + i64::from(self.timestamp_subsec_micros())
}
/// Returns the number of non-leap *nanoseconds* since midnight on January 1, 1970.
///
/// Note that this does *not* account for the timezone!
/// The true "UNIX timestamp" would count seconds since the midnight *UTC* on the epoch.
///
/// # Panics
///
/// Note also that this does reduce the number of years that can be
/// represented from ~584 Billion to ~584 years. The dates that can be
/// represented as nanoseconds are between 1677-09-21T00:12:44.0 and
/// 2262-04-11T23:47:16.854775804.
///
/// (If this is a problem, please file an issue to let me know what domain
/// needs nanosecond precision over millennia, I'm curious.)
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime};
///
/// let dt = NaiveDate::from_ymd(1970, 1, 1).and_hms_nano(0, 0, 1, 444);
/// assert_eq!(dt.timestamp_nanos(), 1_000_000_444);
///
/// let dt = NaiveDate::from_ymd(2001, 9, 9).and_hms_nano(1, 46, 40, 555);
///
/// const A_BILLION: i64 = 1_000_000_000;
/// let nanos = dt.timestamp_nanos();
/// assert_eq!(nanos, 1_000_000_000_000_000_555);
/// assert_eq!(
/// dt,
/// NaiveDateTime::from_timestamp(nanos / A_BILLION, (nanos % A_BILLION) as u32)
/// );
/// ```
#[inline]
pub fn timestamp_nanos(&self) -> i64 {
let as_ns = self.timestamp() * 1_000_000_000;
as_ns + i64::from(self.timestamp_subsec_nanos())
}
/// Returns the number of milliseconds since the last whole non-leap second.
///
/// The return value ranges from 0 to 999,
/// or for [leap seconds](./struct.NaiveTime.html#leap-second-handling), to 1,999.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2016, 7, 8).and_hms_nano(9, 10, 11, 123_456_789);
/// assert_eq!(dt.timestamp_subsec_millis(), 123);
///
/// let dt = NaiveDate::from_ymd(2015, 7, 1).and_hms_nano(8, 59, 59, 1_234_567_890);
/// assert_eq!(dt.timestamp_subsec_millis(), 1_234);
/// ```
#[inline]
pub fn timestamp_subsec_millis(&self) -> u32 {
self.timestamp_subsec_nanos() / 1_000_000
}
/// Returns the number of microseconds since the last whole non-leap second.
///
/// The return value ranges from 0 to 999,999,
/// or for [leap seconds](./struct.NaiveTime.html#leap-second-handling), to 1,999,999.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2016, 7, 8).and_hms_nano(9, 10, 11, 123_456_789);
/// assert_eq!(dt.timestamp_subsec_micros(), 123_456);
///
/// let dt = NaiveDate::from_ymd(2015, 7, 1).and_hms_nano(8, 59, 59, 1_234_567_890);
/// assert_eq!(dt.timestamp_subsec_micros(), 1_234_567);
/// ```
#[inline]
pub fn timestamp_subsec_micros(&self) -> u32 {
self.timestamp_subsec_nanos() / 1_000
}
/// Returns the number of nanoseconds since the last whole non-leap second.
///
/// The return value ranges from 0 to 999,999,999,
/// or for [leap seconds](./struct.NaiveTime.html#leap-second-handling), to 1,999,999,999.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2016, 7, 8).and_hms_nano(9, 10, 11, 123_456_789);
/// assert_eq!(dt.timestamp_subsec_nanos(), 123_456_789);
///
/// let dt = NaiveDate::from_ymd(2015, 7, 1).and_hms_nano(8, 59, 59, 1_234_567_890);
/// assert_eq!(dt.timestamp_subsec_nanos(), 1_234_567_890);
/// ```
#[inline]
pub fn timestamp_subsec_nanos(&self) -> u32 {
self.time.nanosecond()
}
/// Adds given `Duration` to the current date and time.
///
/// As a part of Chrono's [leap second handling](./struct.NaiveTime.html#leap-second-handling),
/// the addition assumes that **there is no leap second ever**,
/// except when the `NaiveDateTime` itself represents a leap second
/// in which case the assumption becomes that **there is exactly a single leap second ever**.
///
/// Returns `None` when it will result in overflow.
///
/// # Example
///
/// ```
/// use chrono::{Duration, NaiveDate};
///
/// let from_ymd = NaiveDate::from_ymd;
///
/// let d = from_ymd(2016, 7, 8);
/// let hms = |h, m, s| d.and_hms(h, m, s);
/// assert_eq!(hms(3, 5, 7).checked_add_signed(Duration::zero()),
/// Some(hms(3, 5, 7)));
/// assert_eq!(hms(3, 5, 7).checked_add_signed(Duration::seconds(1)),
/// Some(hms(3, 5, 8)));
/// assert_eq!(hms(3, 5, 7).checked_add_signed(Duration::seconds(-1)),
/// Some(hms(3, 5, 6)));
/// assert_eq!(hms(3, 5, 7).checked_add_signed(Duration::seconds(3600 + 60)),
/// Some(hms(4, 6, 7)));
/// assert_eq!(hms(3, 5, 7).checked_add_signed(Duration::seconds(86_400)),
/// Some(from_ymd(2016, 7, 9).and_hms(3, 5, 7)));
///
/// let hmsm = |h, m, s, milli| d.and_hms_milli(h, m, s, milli);
/// assert_eq!(hmsm(3, 5, 7, 980).checked_add_signed(Duration::milliseconds(450)),
/// Some(hmsm(3, 5, 8, 430)));
/// ```
///
/// Overflow returns `None`.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let hms = |h, m, s| NaiveDate::from_ymd(2016, 7, 8).and_hms(h, m, s);
/// assert_eq!(hms(3, 5, 7).checked_add_signed(Duration::days(1_000_000_000)), None);
/// ```
///
/// Leap seconds are handled,
/// but the addition assumes that it is the only leap second happened.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let from_ymd = NaiveDate::from_ymd;
/// # let hmsm = |h, m, s, milli| from_ymd(2016, 7, 8).and_hms_milli(h, m, s, milli);
/// let leap = hmsm(3, 5, 59, 1_300);
/// assert_eq!(leap.checked_add_signed(Duration::zero()),
/// Some(hmsm(3, 5, 59, 1_300)));
/// assert_eq!(leap.checked_add_signed(Duration::milliseconds(-500)),
/// Some(hmsm(3, 5, 59, 800)));
/// assert_eq!(leap.checked_add_signed(Duration::milliseconds(500)),
/// Some(hmsm(3, 5, 59, 1_800)));
/// assert_eq!(leap.checked_add_signed(Duration::milliseconds(800)),
/// Some(hmsm(3, 6, 0, 100)));
/// assert_eq!(leap.checked_add_signed(Duration::seconds(10)),
/// Some(hmsm(3, 6, 9, 300)));
/// assert_eq!(leap.checked_add_signed(Duration::seconds(-10)),
/// Some(hmsm(3, 5, 50, 300)));
/// assert_eq!(leap.checked_add_signed(Duration::days(1)),
/// Some(from_ymd(2016, 7, 9).and_hms_milli(3, 5, 59, 300)));
/// ```
pub fn checked_add_signed(self, rhs: OldDuration) -> Option<NaiveDateTime> {
let (time, rhs) = self.time.overflowing_add_signed(rhs);
// early checking to avoid overflow in OldDuration::seconds
if rhs <= (-1 << MAX_SECS_BITS) || rhs >= (1 << MAX_SECS_BITS) {
return None;
}
let date = self.date.checked_add_signed(OldDuration::seconds(rhs))?;
Some(NaiveDateTime { date, time })
}
/// Subtracts given `Duration` from the current date and time.
///
/// As a part of Chrono's [leap second handling](./struct.NaiveTime.html#leap-second-handling),
/// the subtraction assumes that **there is no leap second ever**,
/// except when the `NaiveDateTime` itself represents a leap second
/// in which case the assumption becomes that **there is exactly a single leap second ever**.
///
/// Returns `None` when it will result in overflow.
///
/// # Example
///
/// ```
/// use chrono::{Duration, NaiveDate};
///
/// let from_ymd = NaiveDate::from_ymd;
///
/// let d = from_ymd(2016, 7, 8);
/// let hms = |h, m, s| d.and_hms(h, m, s);
/// assert_eq!(hms(3, 5, 7).checked_sub_signed(Duration::zero()),
/// Some(hms(3, 5, 7)));
/// assert_eq!(hms(3, 5, 7).checked_sub_signed(Duration::seconds(1)),
/// Some(hms(3, 5, 6)));
/// assert_eq!(hms(3, 5, 7).checked_sub_signed(Duration::seconds(-1)),
/// Some(hms(3, 5, 8)));
/// assert_eq!(hms(3, 5, 7).checked_sub_signed(Duration::seconds(3600 + 60)),
/// Some(hms(2, 4, 7)));
/// assert_eq!(hms(3, 5, 7).checked_sub_signed(Duration::seconds(86_400)),
/// Some(from_ymd(2016, 7, 7).and_hms(3, 5, 7)));
///
/// let hmsm = |h, m, s, milli| d.and_hms_milli(h, m, s, milli);
/// assert_eq!(hmsm(3, 5, 7, 450).checked_sub_signed(Duration::milliseconds(670)),
/// Some(hmsm(3, 5, 6, 780)));
/// ```
///
/// Overflow returns `None`.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let hms = |h, m, s| NaiveDate::from_ymd(2016, 7, 8).and_hms(h, m, s);
/// assert_eq!(hms(3, 5, 7).checked_sub_signed(Duration::days(1_000_000_000)), None);
/// ```
///
/// Leap seconds are handled,
/// but the subtraction assumes that it is the only leap second happened.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let from_ymd = NaiveDate::from_ymd;
/// # let hmsm = |h, m, s, milli| from_ymd(2016, 7, 8).and_hms_milli(h, m, s, milli);
/// let leap = hmsm(3, 5, 59, 1_300);
/// assert_eq!(leap.checked_sub_signed(Duration::zero()),
/// Some(hmsm(3, 5, 59, 1_300)));
/// assert_eq!(leap.checked_sub_signed(Duration::milliseconds(200)),
/// Some(hmsm(3, 5, 59, 1_100)));
/// assert_eq!(leap.checked_sub_signed(Duration::milliseconds(500)),
/// Some(hmsm(3, 5, 59, 800)));
/// assert_eq!(leap.checked_sub_signed(Duration::seconds(60)),
/// Some(hmsm(3, 5, 0, 300)));
/// assert_eq!(leap.checked_sub_signed(Duration::days(1)),
/// Some(from_ymd(2016, 7, 7).and_hms_milli(3, 6, 0, 300)));
/// ```
pub fn checked_sub_signed(self, rhs: OldDuration) -> Option<NaiveDateTime> {
let (time, rhs) = self.time.overflowing_sub_signed(rhs);
// early checking to avoid overflow in OldDuration::seconds
if rhs <= (-1 << MAX_SECS_BITS) || rhs >= (1 << MAX_SECS_BITS) {
return None;
}
let date = self.date.checked_sub_signed(OldDuration::seconds(rhs))?;
Some(NaiveDateTime { date, time })
}
/// Subtracts another `NaiveDateTime` from the current date and time.
/// This does not overflow or underflow at all.
///
/// As a part of Chrono's [leap second handling](./struct.NaiveTime.html#leap-second-handling),
/// the subtraction assumes that **there is no leap second ever**,
/// except when any of the `NaiveDateTime`s themselves represents a leap second
/// in which case the assumption becomes that
/// **there are exactly one (or two) leap second(s) ever**.
///
/// # Example
///
/// ```
/// use chrono::{Duration, NaiveDate};
///
/// let from_ymd = NaiveDate::from_ymd;
///
/// let d = from_ymd(2016, 7, 8);
/// assert_eq!(d.and_hms(3, 5, 7).signed_duration_since(d.and_hms(2, 4, 6)),
/// Duration::seconds(3600 + 60 + 1));
///
/// // July 8 is 190th day in the year 2016
/// let d0 = from_ymd(2016, 1, 1);
/// assert_eq!(d.and_hms_milli(0, 7, 6, 500).signed_duration_since(d0.and_hms(0, 0, 0)),
/// Duration::seconds(189 * 86_400 + 7 * 60 + 6) + Duration::milliseconds(500));
/// ```
///
/// Leap seconds are handled, but the subtraction assumes that
/// there were no other leap seconds happened.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let from_ymd = NaiveDate::from_ymd;
/// let leap = from_ymd(2015, 6, 30).and_hms_milli(23, 59, 59, 1_500);
/// assert_eq!(leap.signed_duration_since(from_ymd(2015, 6, 30).and_hms(23, 0, 0)),
/// Duration::seconds(3600) + Duration::milliseconds(500));
/// assert_eq!(from_ymd(2015, 7, 1).and_hms(1, 0, 0).signed_duration_since(leap),
/// Duration::seconds(3600) - Duration::milliseconds(500));
/// ```
pub fn signed_duration_since(self, rhs: NaiveDateTime) -> OldDuration {
self.date.signed_duration_since(rhs.date) + self.time.signed_duration_since(rhs.time)
}
/// Formats the combined date and time with the specified formatting items.
/// Otherwise it is the same as the ordinary [`format`](#method.format) method.
///
/// The `Iterator` of items should be `Clone`able,
/// since the resulting `DelayedFormat` value may be formatted multiple times.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
/// use chrono::format::strftime::StrftimeItems;
///
/// let fmt = StrftimeItems::new("%Y-%m-%d %H:%M:%S");
/// let dt = NaiveDate::from_ymd(2015, 9, 5).and_hms(23, 56, 4);
/// assert_eq!(dt.format_with_items(fmt.clone()).to_string(), "2015-09-05 23:56:04");
/// assert_eq!(dt.format("%Y-%m-%d %H:%M:%S").to_string(), "2015-09-05 23:56:04");
/// ```
///
/// The resulting `DelayedFormat` can be formatted directly via the `Display` trait.
///
/// ```
/// # use chrono::NaiveDate;
/// # use chrono::format::strftime::StrftimeItems;
/// # let fmt = StrftimeItems::new("%Y-%m-%d %H:%M:%S").clone();
/// # let dt = NaiveDate::from_ymd(2015, 9, 5).and_hms(23, 56, 4);
/// assert_eq!(format!("{}", dt.format_with_items(fmt)), "2015-09-05 23:56:04");
/// ```
#[cfg(any(feature = "alloc", feature = "std", test))]
#[inline]
pub fn format_with_items<'a, I, B>(&self, items: I) -> DelayedFormat<I>
where
I: Iterator<Item = B> + Clone,
B: Borrow<Item<'a>>,
{
DelayedFormat::new(Some(self.date), Some(self.time), items)
}
/// Formats the combined date and time with the specified format string.
/// See the [`format::strftime` module](../format/strftime/index.html)
/// on the supported escape sequences.
///
/// This returns a `DelayedFormat`,
/// which gets converted to a string only when actual formatting happens.
/// You may use the `to_string` method to get a `String`,
/// or just feed it into `print!` and other formatting macros.
/// (In this way it avoids the redundant memory allocation.)
///
/// A wrong format string does *not* issue an error immediately.
/// Rather, converting or formatting the `DelayedFormat` fails.
/// You are recommended to immediately use `DelayedFormat` for this reason.
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2015, 9, 5).and_hms(23, 56, 4);
/// assert_eq!(dt.format("%Y-%m-%d %H:%M:%S").to_string(), "2015-09-05 23:56:04");
/// assert_eq!(dt.format("around %l %p on %b %-d").to_string(), "around 11 PM on Sep 5");
/// ```
///
/// The resulting `DelayedFormat` can be formatted directly via the `Display` trait.
///
/// ```
/// # use chrono::NaiveDate;
/// # let dt = NaiveDate::from_ymd(2015, 9, 5).and_hms(23, 56, 4);
/// assert_eq!(format!("{}", dt.format("%Y-%m-%d %H:%M:%S")), "2015-09-05 23:56:04");
/// assert_eq!(format!("{}", dt.format("around %l %p on %b %-d")), "around 11 PM on Sep 5");
/// ```
#[cfg(any(feature = "alloc", feature = "std", test))]
#[inline]
pub fn format<'a>(&self, fmt: &'a str) -> DelayedFormat<StrftimeItems<'a>> {
self.format_with_items(StrftimeItems::new(fmt))
}
/// Converts the `NaiveDateTime` into the timezone-aware `DateTime<Tz>`
/// with the provided timezone, if possible.
///
/// This can fail in cases where the local time represented by the `NaiveDateTime`
/// is not a valid local timestamp in the target timezone due to an offset transition
/// for example if the target timezone had a change from +00:00 to +01:00
/// occuring at 2015-09-05 22:59:59, then a local time of 2015-09-05 23:56:04
/// could never occur. Similarly, if the offset transitioned in the opposite direction
/// then there would be two local times of 2015-09-05 23:56:04, one at +00:00 and one
/// at +01:00.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, Utc};
/// let dt = NaiveDate::from_ymd(2015, 9, 5).and_hms(23, 56, 4).and_local_timezone(Utc).unwrap();
/// assert_eq!(dt.timezone(), Utc);
pub fn and_local_timezone<Tz: TimeZone>(&self, tz: Tz) -> LocalResult<DateTime<Tz>> {
tz.from_local_datetime(self)
}
/// The minimum possible `NaiveDateTime`.
pub const MIN: Self = Self { date: NaiveDate::MIN, time: NaiveTime::MIN };
/// The maximum possible `NaiveDateTime`.
pub const MAX: Self = Self { date: NaiveDate::MAX, time: NaiveTime::MAX };
}
impl Datelike for NaiveDateTime {
/// Returns the year number in the [calendar date](./index.html#calendar-date).
///
/// See also the [`NaiveDate::year`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.year(), 2015);
/// ```
#[inline]
fn year(&self) -> i32 {
self.date.year()
}
/// Returns the month number starting from 1.
///
/// The return value ranges from 1 to 12.
///
/// See also the [`NaiveDate::month`](./struct.NaiveDate.html#method.month) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.month(), 9);
/// ```
#[inline]
fn month(&self) -> u32 {
self.date.month()
}
/// Returns the month number starting from 0.
///
/// The return value ranges from 0 to 11.
///
/// See also the [`NaiveDate::month0`](./struct.NaiveDate.html#method.month0) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.month0(), 8);
/// ```
#[inline]
fn month0(&self) -> u32 {
self.date.month0()
}
/// Returns the day of month starting from 1.
///
/// The return value ranges from 1 to 31. (The last day of month differs by months.)
///
/// See also the [`NaiveDate::day`](./struct.NaiveDate.html#method.day) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.day(), 25);
/// ```
#[inline]
fn day(&self) -> u32 {
self.date.day()
}
/// Returns the day of month starting from 0.
///
/// The return value ranges from 0 to 30. (The last day of month differs by months.)
///
/// See also the [`NaiveDate::day0`](./struct.NaiveDate.html#method.day0) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.day0(), 24);
/// ```
#[inline]
fn day0(&self) -> u32 {
self.date.day0()
}
/// Returns the day of year starting from 1.
///
/// The return value ranges from 1 to 366. (The last day of year differs by years.)
///
/// See also the [`NaiveDate::ordinal`](./struct.NaiveDate.html#method.ordinal) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.ordinal(), 268);
/// ```
#[inline]
fn ordinal(&self) -> u32 {
self.date.ordinal()
}
/// Returns the day of year starting from 0.
///
/// The return value ranges from 0 to 365. (The last day of year differs by years.)
///
/// See also the [`NaiveDate::ordinal0`](./struct.NaiveDate.html#method.ordinal0) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.ordinal0(), 267);
/// ```
#[inline]
fn ordinal0(&self) -> u32 {
self.date.ordinal0()
}
/// Returns the day of week.
///
/// See also the [`NaiveDate::weekday`](./struct.NaiveDate.html#method.weekday) method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike, Weekday};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.weekday(), Weekday::Fri);
/// ```
#[inline]
fn weekday(&self) -> Weekday {
self.date.weekday()
}
#[inline]
fn iso_week(&self) -> IsoWeek {
self.date.iso_week()
}
/// Makes a new `NaiveDateTime` with the year number changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_year`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 25).and_hms(12, 34, 56);
/// assert_eq!(dt.with_year(2016), Some(NaiveDate::from_ymd(2016, 9, 25).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_year(-308), Some(NaiveDate::from_ymd(-308, 9, 25).and_hms(12, 34, 56)));
/// ```
#[inline]
fn with_year(&self, year: i32) -> Option<NaiveDateTime> {
self.date.with_year(year).map(|d| NaiveDateTime { date: d, ..*self })
}
/// Makes a new `NaiveDateTime` with the month number (starting from 1) changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_month`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 30).and_hms(12, 34, 56);
/// assert_eq!(dt.with_month(10), Some(NaiveDate::from_ymd(2015, 10, 30).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_month(13), None); // no month 13
/// assert_eq!(dt.with_month(2), None); // no February 30
/// ```
#[inline]
fn with_month(&self, month: u32) -> Option<NaiveDateTime> {
self.date.with_month(month).map(|d| NaiveDateTime { date: d, ..*self })
}
/// Makes a new `NaiveDateTime` with the month number (starting from 0) changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_month0`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 30).and_hms(12, 34, 56);
/// assert_eq!(dt.with_month0(9), Some(NaiveDate::from_ymd(2015, 10, 30).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_month0(12), None); // no month 13
/// assert_eq!(dt.with_month0(1), None); // no February 30
/// ```
#[inline]
fn with_month0(&self, month0: u32) -> Option<NaiveDateTime> {
self.date.with_month0(month0).map(|d| NaiveDateTime { date: d, ..*self })
}
/// Makes a new `NaiveDateTime` with the day of month (starting from 1) changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_day`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms(12, 34, 56);
/// assert_eq!(dt.with_day(30), Some(NaiveDate::from_ymd(2015, 9, 30).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_day(31), None); // no September 31
/// ```
#[inline]
fn with_day(&self, day: u32) -> Option<NaiveDateTime> {
self.date.with_day(day).map(|d| NaiveDateTime { date: d, ..*self })
}
/// Makes a new `NaiveDateTime` with the day of month (starting from 0) changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_day0`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms(12, 34, 56);
/// assert_eq!(dt.with_day0(29), Some(NaiveDate::from_ymd(2015, 9, 30).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_day0(30), None); // no September 31
/// ```
#[inline]
fn with_day0(&self, day0: u32) -> Option<NaiveDateTime> {
self.date.with_day0(day0).map(|d| NaiveDateTime { date: d, ..*self })
}
/// Makes a new `NaiveDateTime` with the day of year (starting from 1) changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_ordinal`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms(12, 34, 56);
/// assert_eq!(dt.with_ordinal(60),
/// Some(NaiveDate::from_ymd(2015, 3, 1).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_ordinal(366), None); // 2015 had only 365 days
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2016, 9, 8).and_hms(12, 34, 56);
/// assert_eq!(dt.with_ordinal(60),
/// Some(NaiveDate::from_ymd(2016, 2, 29).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_ordinal(366),
/// Some(NaiveDate::from_ymd(2016, 12, 31).and_hms(12, 34, 56)));
/// ```
#[inline]
fn with_ordinal(&self, ordinal: u32) -> Option<NaiveDateTime> {
self.date.with_ordinal(ordinal).map(|d| NaiveDateTime { date: d, ..*self })
}
/// Makes a new `NaiveDateTime` with the day of year (starting from 0) changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveDate::with_ordinal0`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Datelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms(12, 34, 56);
/// assert_eq!(dt.with_ordinal0(59),
/// Some(NaiveDate::from_ymd(2015, 3, 1).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_ordinal0(365), None); // 2015 had only 365 days
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2016, 9, 8).and_hms(12, 34, 56);
/// assert_eq!(dt.with_ordinal0(59),
/// Some(NaiveDate::from_ymd(2016, 2, 29).and_hms(12, 34, 56)));
/// assert_eq!(dt.with_ordinal0(365),
/// Some(NaiveDate::from_ymd(2016, 12, 31).and_hms(12, 34, 56)));
/// ```
#[inline]
fn with_ordinal0(&self, ordinal0: u32) -> Option<NaiveDateTime> {
self.date.with_ordinal0(ordinal0).map(|d| NaiveDateTime { date: d, ..*self })
}
}
impl Timelike for NaiveDateTime {
/// Returns the hour number from 0 to 23.
///
/// See also the [`NaiveTime::hour`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.hour(), 12);
/// ```
#[inline]
fn hour(&self) -> u32 {
self.time.hour()
}
/// Returns the minute number from 0 to 59.
///
/// See also the [`NaiveTime::minute`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.minute(), 34);
/// ```
#[inline]
fn minute(&self) -> u32 {
self.time.minute()
}
/// Returns the second number from 0 to 59.
///
/// See also the [`NaiveTime::second`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.second(), 56);
/// ```
#[inline]
fn second(&self) -> u32 {
self.time.second()
}
/// Returns the number of nanoseconds since the whole non-leap second.
/// The range from 1,000,000,000 to 1,999,999,999 represents
/// the [leap second](./struct.NaiveTime.html#leap-second-handling).
///
/// See also the [`NaiveTime::nanosecond`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.nanosecond(), 789_000_000);
/// ```
#[inline]
fn nanosecond(&self) -> u32 {
self.time.nanosecond()
}
/// Makes a new `NaiveDateTime` with the hour number changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the [`NaiveTime::with_hour`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.with_hour(7),
/// Some(NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(7, 34, 56, 789)));
/// assert_eq!(dt.with_hour(24), None);
/// ```
#[inline]
fn with_hour(&self, hour: u32) -> Option<NaiveDateTime> {
self.time.with_hour(hour).map(|t| NaiveDateTime { time: t, ..*self })
}
/// Makes a new `NaiveDateTime` with the minute number changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
///
/// See also the
/// [`NaiveTime::with_minute`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.with_minute(45),
/// Some(NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 45, 56, 789)));
/// assert_eq!(dt.with_minute(60), None);
/// ```
#[inline]
fn with_minute(&self, min: u32) -> Option<NaiveDateTime> {
self.time.with_minute(min).map(|t| NaiveDateTime { time: t, ..*self })
}
/// Makes a new `NaiveDateTime` with the second number changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid. As
/// with the [`NaiveDateTime::second`] method, the input range is
/// restricted to 0 through 59.
///
/// See also the [`NaiveTime::with_second`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.with_second(17),
/// Some(NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 17, 789)));
/// assert_eq!(dt.with_second(60), None);
/// ```
#[inline]
fn with_second(&self, sec: u32) -> Option<NaiveDateTime> {
self.time.with_second(sec).map(|t| NaiveDateTime { time: t, ..*self })
}
/// Makes a new `NaiveDateTime` with nanoseconds since the whole non-leap second changed.
///
/// Returns `None` when the resulting `NaiveDateTime` would be invalid.
/// As with the [`NaiveDateTime::nanosecond`] method,
/// the input range can exceed 1,000,000,000 for leap seconds.
///
/// See also the [`NaiveTime::with_nanosecond`] method.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDate, NaiveDateTime, Timelike};
///
/// let dt: NaiveDateTime = NaiveDate::from_ymd(2015, 9, 8).and_hms_milli(12, 34, 56, 789);
/// assert_eq!(dt.with_nanosecond(333_333_333),
/// Some(NaiveDate::from_ymd(2015, 9, 8).and_hms_nano(12, 34, 56, 333_333_333)));
/// assert_eq!(dt.with_nanosecond(1_333_333_333), // leap second
/// Some(NaiveDate::from_ymd(2015, 9, 8).and_hms_nano(12, 34, 56, 1_333_333_333)));
/// assert_eq!(dt.with_nanosecond(2_000_000_000), None);
/// ```
#[inline]
fn with_nanosecond(&self, nano: u32) -> Option<NaiveDateTime> {
self.time.with_nanosecond(nano).map(|t| NaiveDateTime { time: t, ..*self })
}
}
/// An addition of `Duration` to `NaiveDateTime` yields another `NaiveDateTime`.
///
/// As a part of Chrono's [leap second handling](./struct.NaiveTime.html#leap-second-handling),
/// the addition assumes that **there is no leap second ever**,
/// except when the `NaiveDateTime` itself represents a leap second
/// in which case the assumption becomes that **there is exactly a single leap second ever**.
///
/// Panics on underflow or overflow. Use [`NaiveDateTime::checked_add_signed`]
/// to detect that.
///
/// # Example
///
/// ```
/// use chrono::{Duration, NaiveDate};
///
/// let from_ymd = NaiveDate::from_ymd;
///
/// let d = from_ymd(2016, 7, 8);
/// let hms = |h, m, s| d.and_hms(h, m, s);
/// assert_eq!(hms(3, 5, 7) + Duration::zero(), hms(3, 5, 7));
/// assert_eq!(hms(3, 5, 7) + Duration::seconds(1), hms(3, 5, 8));
/// assert_eq!(hms(3, 5, 7) + Duration::seconds(-1), hms(3, 5, 6));
/// assert_eq!(hms(3, 5, 7) + Duration::seconds(3600 + 60), hms(4, 6, 7));
/// assert_eq!(hms(3, 5, 7) + Duration::seconds(86_400),
/// from_ymd(2016, 7, 9).and_hms(3, 5, 7));
/// assert_eq!(hms(3, 5, 7) + Duration::days(365),
/// from_ymd(2017, 7, 8).and_hms(3, 5, 7));
///
/// let hmsm = |h, m, s, milli| d.and_hms_milli(h, m, s, milli);
/// assert_eq!(hmsm(3, 5, 7, 980) + Duration::milliseconds(450), hmsm(3, 5, 8, 430));
/// ```
///
/// Leap seconds are handled,
/// but the addition assumes that it is the only leap second happened.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let from_ymd = NaiveDate::from_ymd;
/// # let hmsm = |h, m, s, milli| from_ymd(2016, 7, 8).and_hms_milli(h, m, s, milli);
/// let leap = hmsm(3, 5, 59, 1_300);
/// assert_eq!(leap + Duration::zero(), hmsm(3, 5, 59, 1_300));
/// assert_eq!(leap + Duration::milliseconds(-500), hmsm(3, 5, 59, 800));
/// assert_eq!(leap + Duration::milliseconds(500), hmsm(3, 5, 59, 1_800));
/// assert_eq!(leap + Duration::milliseconds(800), hmsm(3, 6, 0, 100));
/// assert_eq!(leap + Duration::seconds(10), hmsm(3, 6, 9, 300));
/// assert_eq!(leap + Duration::seconds(-10), hmsm(3, 5, 50, 300));
/// assert_eq!(leap + Duration::days(1),
/// from_ymd(2016, 7, 9).and_hms_milli(3, 5, 59, 300));
/// ```
impl Add<OldDuration> for NaiveDateTime {
type Output = NaiveDateTime;
#[inline]
fn add(self, rhs: OldDuration) -> NaiveDateTime {
self.checked_add_signed(rhs).expect("`NaiveDateTime + Duration` overflowed")
}
}
impl AddAssign<OldDuration> for NaiveDateTime {
#[inline]
fn add_assign(&mut self, rhs: OldDuration) {
*self = self.add(rhs);
}
}
/// A subtraction of `Duration` from `NaiveDateTime` yields another `NaiveDateTime`.
/// It is the same as the addition with a negated `Duration`.
///
/// As a part of Chrono's [leap second handling](./struct.NaiveTime.html#leap-second-handling),
/// the addition assumes that **there is no leap second ever**,
/// except when the `NaiveDateTime` itself represents a leap second
/// in which case the assumption becomes that **there is exactly a single leap second ever**.
///
/// Panics on underflow or overflow. Use [`NaiveDateTime::checked_sub_signed`]
/// to detect that.
///
/// # Example
///
/// ```
/// use chrono::{Duration, NaiveDate};
///
/// let from_ymd = NaiveDate::from_ymd;
///
/// let d = from_ymd(2016, 7, 8);
/// let hms = |h, m, s| d.and_hms(h, m, s);
/// assert_eq!(hms(3, 5, 7) - Duration::zero(), hms(3, 5, 7));
/// assert_eq!(hms(3, 5, 7) - Duration::seconds(1), hms(3, 5, 6));
/// assert_eq!(hms(3, 5, 7) - Duration::seconds(-1), hms(3, 5, 8));
/// assert_eq!(hms(3, 5, 7) - Duration::seconds(3600 + 60), hms(2, 4, 7));
/// assert_eq!(hms(3, 5, 7) - Duration::seconds(86_400),
/// from_ymd(2016, 7, 7).and_hms(3, 5, 7));
/// assert_eq!(hms(3, 5, 7) - Duration::days(365),
/// from_ymd(2015, 7, 9).and_hms(3, 5, 7));
///
/// let hmsm = |h, m, s, milli| d.and_hms_milli(h, m, s, milli);
/// assert_eq!(hmsm(3, 5, 7, 450) - Duration::milliseconds(670), hmsm(3, 5, 6, 780));
/// ```
///
/// Leap seconds are handled,
/// but the subtraction assumes that it is the only leap second happened.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let from_ymd = NaiveDate::from_ymd;
/// # let hmsm = |h, m, s, milli| from_ymd(2016, 7, 8).and_hms_milli(h, m, s, milli);
/// let leap = hmsm(3, 5, 59, 1_300);
/// assert_eq!(leap - Duration::zero(), hmsm(3, 5, 59, 1_300));
/// assert_eq!(leap - Duration::milliseconds(200), hmsm(3, 5, 59, 1_100));
/// assert_eq!(leap - Duration::milliseconds(500), hmsm(3, 5, 59, 800));
/// assert_eq!(leap - Duration::seconds(60), hmsm(3, 5, 0, 300));
/// assert_eq!(leap - Duration::days(1),
/// from_ymd(2016, 7, 7).and_hms_milli(3, 6, 0, 300));
/// ```
impl Sub<OldDuration> for NaiveDateTime {
type Output = NaiveDateTime;
#[inline]
fn sub(self, rhs: OldDuration) -> NaiveDateTime {
self.checked_sub_signed(rhs).expect("`NaiveDateTime - Duration` overflowed")
}
}
impl SubAssign<OldDuration> for NaiveDateTime {
#[inline]
fn sub_assign(&mut self, rhs: OldDuration) {
*self = self.sub(rhs);
}
}
/// Subtracts another `NaiveDateTime` from the current date and time.
/// This does not overflow or underflow at all.
///
/// As a part of Chrono's [leap second handling](./struct.NaiveTime.html#leap-second-handling),
/// the subtraction assumes that **there is no leap second ever**,
/// except when any of the `NaiveDateTime`s themselves represents a leap second
/// in which case the assumption becomes that
/// **there are exactly one (or two) leap second(s) ever**.
///
/// The implementation is a wrapper around [`NaiveDateTime::signed_duration_since`].
///
/// # Example
///
/// ```
/// use chrono::{Duration, NaiveDate};
///
/// let from_ymd = NaiveDate::from_ymd;
///
/// let d = from_ymd(2016, 7, 8);
/// assert_eq!(d.and_hms(3, 5, 7) - d.and_hms(2, 4, 6), Duration::seconds(3600 + 60 + 1));
///
/// // July 8 is 190th day in the year 2016
/// let d0 = from_ymd(2016, 1, 1);
/// assert_eq!(d.and_hms_milli(0, 7, 6, 500) - d0.and_hms(0, 0, 0),
/// Duration::seconds(189 * 86_400 + 7 * 60 + 6) + Duration::milliseconds(500));
/// ```
///
/// Leap seconds are handled, but the subtraction assumes that no other leap
/// seconds happened.
///
/// ```
/// # use chrono::{Duration, NaiveDate};
/// # let from_ymd = NaiveDate::from_ymd;
/// let leap = from_ymd(2015, 6, 30).and_hms_milli(23, 59, 59, 1_500);
/// assert_eq!(leap - from_ymd(2015, 6, 30).and_hms(23, 0, 0),
/// Duration::seconds(3600) + Duration::milliseconds(500));
/// assert_eq!(from_ymd(2015, 7, 1).and_hms(1, 0, 0) - leap,
/// Duration::seconds(3600) - Duration::milliseconds(500));
/// ```
impl Sub<NaiveDateTime> for NaiveDateTime {
type Output = OldDuration;
#[inline]
fn sub(self, rhs: NaiveDateTime) -> OldDuration {
self.signed_duration_since(rhs)
}
}
/// The `Debug` output of the naive date and time `dt` is the same as
/// [`dt.format("%Y-%m-%dT%H:%M:%S%.f")`](crate::format::strftime).
///
/// The string printed can be readily parsed via the `parse` method on `str`.
///
/// It should be noted that, for leap seconds not on the minute boundary,
/// it may print a representation not distinguishable from non-leap seconds.
/// This doesn't matter in practice, since such leap seconds never happened.
/// (By the time of the first leap second on 1972-06-30,
/// every time zone offset around the world has standardized to the 5-minute alignment.)
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2016, 11, 15).and_hms(7, 39, 24);
/// assert_eq!(format!("{:?}", dt), "2016-11-15T07:39:24");
/// ```
///
/// Leap seconds may also be used.
///
/// ```
/// # use chrono::NaiveDate;
/// let dt = NaiveDate::from_ymd(2015, 6, 30).and_hms_milli(23, 59, 59, 1_500);
/// assert_eq!(format!("{:?}", dt), "2015-06-30T23:59:60.500");
/// ```
impl fmt::Debug for NaiveDateTime {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{:?}T{:?}", self.date, self.time)
}
}
/// The `Display` output of the naive date and time `dt` is the same as
/// [`dt.format("%Y-%m-%d %H:%M:%S%.f")`](crate::format::strftime).
///
/// It should be noted that, for leap seconds not on the minute boundary,
/// it may print a representation not distinguishable from non-leap seconds.
/// This doesn't matter in practice, since such leap seconds never happened.
/// (By the time of the first leap second on 1972-06-30,
/// every time zone offset around the world has standardized to the 5-minute alignment.)
///
/// # Example
///
/// ```
/// use chrono::NaiveDate;
///
/// let dt = NaiveDate::from_ymd(2016, 11, 15).and_hms(7, 39, 24);
/// assert_eq!(format!("{}", dt), "2016-11-15 07:39:24");
/// ```
///
/// Leap seconds may also be used.
///
/// ```
/// # use chrono::NaiveDate;
/// let dt = NaiveDate::from_ymd(2015, 6, 30).and_hms_milli(23, 59, 59, 1_500);
/// assert_eq!(format!("{}", dt), "2015-06-30 23:59:60.500");
/// ```
impl fmt::Display for NaiveDateTime {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{} {}", self.date, self.time)
}
}
/// Parsing a `str` into a `NaiveDateTime` uses the same format,
/// [`%Y-%m-%dT%H:%M:%S%.f`](crate::format::strftime), as in `Debug`.
///
/// # Example
///
/// ```
/// use chrono::{NaiveDateTime, NaiveDate};
///
/// let dt = NaiveDate::from_ymd(2015, 9, 18).and_hms(23, 56, 4);
/// assert_eq!("2015-09-18T23:56:04".parse::<NaiveDateTime>(), Ok(dt));
///
/// let dt = NaiveDate::from_ymd(12345, 6, 7).and_hms_milli(7, 59, 59, 1_500); // leap second
/// assert_eq!("+12345-6-7T7:59:60.5".parse::<NaiveDateTime>(), Ok(dt));
///
/// assert!("foo".parse::<NaiveDateTime>().is_err());
/// ```
impl str::FromStr for NaiveDateTime {
type Err = ParseError;
fn from_str(s: &str) -> ParseResult<NaiveDateTime> {
const ITEMS: &[Item<'static>] = &[
Item::Numeric(Numeric::Year, Pad::Zero),
Item::Space(""),
Item::Literal("-"),
Item::Numeric(Numeric::Month, Pad::Zero),
Item::Space(""),
Item::Literal("-"),
Item::Numeric(Numeric::Day, Pad::Zero),
Item::Space(""),
Item::Literal("T"), // XXX shouldn't this be case-insensitive?
Item::Numeric(Numeric::Hour, Pad::Zero),
Item::Space(""),
Item::Literal(":"),
Item::Numeric(Numeric::Minute, Pad::Zero),
Item::Space(""),
Item::Literal(":"),
Item::Numeric(Numeric::Second, Pad::Zero),
Item::Fixed(Fixed::Nanosecond),
Item::Space(""),
];
let mut parsed = Parsed::new();
parse(&mut parsed, s, ITEMS.iter())?;
parsed.to_naive_datetime_with_offset(0)
}
}
/// The default value for a NaiveDateTime is one with epoch 0
/// that is, 1st of January 1970 at 00:00:00.
///
/// # Example
///
/// ```rust
/// use chrono::NaiveDateTime;
///
/// let default_date = NaiveDateTime::default();
/// assert_eq!(default_date, NaiveDateTime::from_timestamp(0, 0));
/// ```
impl Default for NaiveDateTime {
fn default() -> Self {
NaiveDateTime::from_timestamp(0, 0)
}
}
#[cfg(all(test, any(feature = "rustc-serialize", feature = "serde")))]
fn test_encodable_json<F, E>(to_string: F)
where
F: Fn(&NaiveDateTime) -> Result<String, E>,
E: ::std::fmt::Debug,
{
assert_eq!(
to_string(&NaiveDate::from_ymd(2016, 7, 8).and_hms_milli(9, 10, 48, 90)).ok(),
Some(r#""2016-07-08T09:10:48.090""#.into())
);
assert_eq!(
to_string(&NaiveDate::from_ymd(2014, 7, 24).and_hms(12, 34, 6)).ok(),
Some(r#""2014-07-24T12:34:06""#.into())
);
assert_eq!(
to_string(&NaiveDate::from_ymd(0, 1, 1).and_hms_milli(0, 0, 59, 1_000)).ok(),
Some(r#""0000-01-01T00:00:60""#.into())
);
assert_eq!(
to_string(&NaiveDate::from_ymd(-1, 12, 31).and_hms_nano(23, 59, 59, 7)).ok(),
Some(r#""-0001-12-31T23:59:59.000000007""#.into())
);
assert_eq!(
to_string(&NaiveDate::MIN.and_hms(0, 0, 0)).ok(),
Some(r#""-262144-01-01T00:00:00""#.into())
);
assert_eq!(
to_string(&NaiveDate::MAX.and_hms_nano(23, 59, 59, 1_999_999_999)).ok(),
Some(r#""+262143-12-31T23:59:60.999999999""#.into())
);
}
#[cfg(all(test, any(feature = "rustc-serialize", feature = "serde")))]
fn test_decodable_json<F, E>(from_str: F)
where
F: Fn(&str) -> Result<NaiveDateTime, E>,
E: ::std::fmt::Debug,
{
assert_eq!(
from_str(r#""2016-07-08T09:10:48.090""#).ok(),
Some(NaiveDate::from_ymd(2016, 7, 8).and_hms_milli(9, 10, 48, 90))
);
assert_eq!(
from_str(r#""2016-7-8T9:10:48.09""#).ok(),
Some(NaiveDate::from_ymd(2016, 7, 8).and_hms_milli(9, 10, 48, 90))
);
assert_eq!(
from_str(r#""2014-07-24T12:34:06""#).ok(),
Some(NaiveDate::from_ymd(2014, 7, 24).and_hms(12, 34, 6))
);
assert_eq!(
from_str(r#""0000-01-01T00:00:60""#).ok(),
Some(NaiveDate::from_ymd(0, 1, 1).and_hms_milli(0, 0, 59, 1_000))
);
assert_eq!(
from_str(r#""0-1-1T0:0:60""#).ok(),
Some(NaiveDate::from_ymd(0, 1, 1).and_hms_milli(0, 0, 59, 1_000))
);
assert_eq!(
from_str(r#""-0001-12-31T23:59:59.000000007""#).ok(),
Some(NaiveDate::from_ymd(-1, 12, 31).and_hms_nano(23, 59, 59, 7))
);
assert_eq!(from_str(r#""-262144-01-01T00:00:00""#).ok(), Some(NaiveDate::MIN.and_hms(0, 0, 0)));
assert_eq!(
from_str(r#""+262143-12-31T23:59:60.999999999""#).ok(),
Some(NaiveDate::MAX.and_hms_nano(23, 59, 59, 1_999_999_999))
);
assert_eq!(
from_str(r#""+262143-12-31T23:59:60.9999999999997""#).ok(), // excess digits are ignored
Some(NaiveDate::MAX.and_hms_nano(23, 59, 59, 1_999_999_999))
);
// bad formats
assert!(from_str(r#""""#).is_err());
assert!(from_str(r#""2016-07-08""#).is_err());
assert!(from_str(r#""09:10:48.090""#).is_err());
assert!(from_str(r#""20160708T091048.090""#).is_err());
assert!(from_str(r#""2000-00-00T00:00:00""#).is_err());
assert!(from_str(r#""2000-02-30T00:00:00""#).is_err());
assert!(from_str(r#""2001-02-29T00:00:00""#).is_err());
assert!(from_str(r#""2002-02-28T24:00:00""#).is_err());
assert!(from_str(r#""2002-02-28T23:60:00""#).is_err());
assert!(from_str(r#""2002-02-28T23:59:61""#).is_err());
assert!(from_str(r#""2016-07-08T09:10:48,090""#).is_err());
assert!(from_str(r#""2016-07-08 09:10:48.090""#).is_err());
assert!(from_str(r#""2016-007-08T09:10:48.090""#).is_err());
assert!(from_str(r#""yyyy-mm-ddThh:mm:ss.fffffffff""#).is_err());
assert!(from_str(r#"20160708000000"#).is_err());
assert!(from_str(r#"{}"#).is_err());
// pre-0.3.0 rustc-serialize format is now invalid
assert!(from_str(r#"{"date":{"ymdf":20},"time":{"secs":0,"frac":0}}"#).is_err());
assert!(from_str(r#"null"#).is_err());
}
#[cfg(all(test, feature = "rustc-serialize"))]
fn test_decodable_json_timestamp<F, E>(from_str: F)
where
F: Fn(&str) -> Result<rustc_serialize::TsSeconds, E>,
E: ::std::fmt::Debug,
{
assert_eq!(
*from_str("0").unwrap(),
NaiveDate::from_ymd(1970, 1, 1).and_hms(0, 0, 0),
"should parse integers as timestamps"
);
assert_eq!(
*from_str("-1").unwrap(),
NaiveDate::from_ymd(1969, 12, 31).and_hms(23, 59, 59),
"should parse integers as timestamps"
);
}