rustmax::jiff::civil

Struct TimeWith

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pub struct TimeWith { /* private fields */ }
Expand description

A builder for setting the fields on a Time.

This builder is constructed via Time::with.

§Example

Unlike Date, a Time is valid for all possible valid values of its fields. That is, there is no way for two valid field values to combine into an invalid Time. So, for Time, this builder does have as much of a benefit versus an API design with methods like Time::with_hour and Time::with_minute. Nevertheless, this builder permits settings multiple fields at the same time and performing only one validity check. Moreover, this provides a consistent API with other date and time types in this crate.

use jiff::civil::time;

let t1 = time(0, 0, 24, 0);
let t2 = t1.with().hour(15).minute(30).millisecond(10).build()?;
assert_eq!(t2, time(15, 30, 24, 10_000_000));

Implementations§

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impl TimeWith

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pub fn build(self) -> Result<Time, Error>

Create a new Time from the fields set on this configuration.

An error occurs when the fields combine to an invalid time. This only occurs when at least one field has an invalid value, or if at least one of millisecond, microsecond or nanosecond is set and subsec_nanosecond is set. Otherwise, if all fields are valid, then the entire Time is guaranteed to be valid.

For any fields not set on this configuration, the values are taken from the Time that originally created this configuration. When no values are set, this routine is guaranteed to succeed and will always return the original time without modification.

§Example

This creates a time but with its fractional nanosecond component stripped:

use jiff::civil::time;

let t = time(14, 27, 30, 123_456_789);
assert_eq!(t.with().subsec_nanosecond(0).build()?, time(14, 27, 30, 0));
§Example: error for invalid time
use jiff::civil::time;

let t = time(14, 27, 30, 0);
assert!(t.with().hour(24).build().is_err());
§Example: error for ambiguous sub-second value
use jiff::civil::time;

let t = time(14, 27, 30, 123_456_789);
// Setting both the individual sub-second fields and the entire
// fractional component could lead to a misleading configuration. So
// if it's done, it results in an error in all cases. Callers must
// choose one or the other.
assert!(t.with().microsecond(1).subsec_nanosecond(0).build().is_err());
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pub fn hour(self, hour: i8) -> TimeWith

Set the hour field on a Time.

One can access this value via Time::hour.

This overrides any previous hour settings.

§Errors

This returns an error when TimeWith::build is called if the given hour is outside the range 0..=23.

§Example
use jiff::civil::time;

let t1 = time(15, 21, 59, 0);
assert_eq!(t1.hour(), 15);
let t2 = t1.with().hour(3).build()?;
assert_eq!(t2.hour(), 3);
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pub fn minute(self, minute: i8) -> TimeWith

Set the minute field on a Time.

One can access this value via Time::minute.

This overrides any previous minute settings.

§Errors

This returns an error when TimeWith::build is called if the given minute is outside the range 0..=59.

§Example
use jiff::civil::time;

let t1 = time(15, 21, 59, 0);
assert_eq!(t1.minute(), 21);
let t2 = t1.with().minute(3).build()?;
assert_eq!(t2.minute(), 3);
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pub fn second(self, second: i8) -> TimeWith

Set the second field on a Time.

One can access this value via Time::second.

This overrides any previous second settings.

§Errors

This returns an error when TimeWith::build is called if the given second is outside the range 0..=59.

§Example
use jiff::civil::time;

let t1 = time(15, 21, 59, 0);
assert_eq!(t1.second(), 59);
let t2 = t1.with().second(3).build()?;
assert_eq!(t2.second(), 3);
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pub fn millisecond(self, millisecond: i16) -> TimeWith

Set the millisecond field on a Time.

One can access this value via Time::millisecond.

This overrides any previous millisecond settings.

§Errors

This returns an error when TimeWith::build is called if the given millisecond is outside the range 0..=999, or if both this and TimeWith::subsec_nanosecond are set.

§Example

This shows the relationship between Time::millisecond and Time::subsec_nanosecond:

use jiff::civil::time;

let t = time(15, 21, 35, 0).with().millisecond(123).build()?;
assert_eq!(t.subsec_nanosecond(), 123_000_000);
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pub fn microsecond(self, microsecond: i16) -> TimeWith

Set the microsecond field on a Time.

One can access this value via Time::microsecond.

This overrides any previous microsecond settings.

§Errors

This returns an error when TimeWith::build is called if the given microsecond is outside the range 0..=999, or if both this and TimeWith::subsec_nanosecond are set.

§Example

This shows the relationship between Time::microsecond and Time::subsec_nanosecond:

use jiff::civil::time;

let t = time(15, 21, 35, 0).with().microsecond(123).build()?;
assert_eq!(t.subsec_nanosecond(), 123_000);
Source

pub fn nanosecond(self, nanosecond: i16) -> TimeWith

Set the nanosecond field on a Time.

One can access this value via Time::nanosecond.

This overrides any previous nanosecond settings.

§Errors

This returns an error when TimeWith::build is called if the given nanosecond is outside the range 0..=999, or if both this and TimeWith::subsec_nanosecond are set.

§Example

This shows the relationship between Time::nanosecond and Time::subsec_nanosecond:

use jiff::civil::time;

let t = time(15, 21, 35, 0).with().nanosecond(123).build()?;
assert_eq!(t.subsec_nanosecond(), 123);
Source

pub fn subsec_nanosecond(self, subsec_nanosecond: i32) -> TimeWith

Set the subsecond nanosecond field on a Time.

If you want to access this value on Time, then use Time::subsec_nanosecond.

This overrides any previous subsecond nanosecond settings.

§Errors

This returns an error when TimeWith::build is called if the given subsecond nanosecond is outside the range 0..=999,999,999, or if both this and one of TimeWith::millisecond, TimeWith::microsecond or TimeWith::nanosecond are set.

§Example

This shows the relationship between constructing a Time value with subsecond nanoseconds and its individual subsecond fields:

use jiff::civil::time;

let t1 = time(15, 21, 35, 0);
let t2 = t1.with().subsec_nanosecond(123_456_789).build()?;
assert_eq!(t2.millisecond(), 123);
assert_eq!(t2.microsecond(), 456);
assert_eq!(t2.nanosecond(), 789);

Trait Implementations§

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impl Clone for TimeWith

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fn clone(&self) -> TimeWith

Returns a copy of the value. Read more
1.0.0 · Source§

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source. Read more
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impl Debug for TimeWith

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fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter. Read more
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impl Copy for TimeWith

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