Crates.io | float_duration |
lib.rs | float_duration |
version | 0.3.3 |
source | src |
created_at | 2017-05-25 21:04:43.901508 |
updated_at | 2017-06-22 14:29:35.60547 |
description | Floating-point Duration support. Provides quantification for spans of time. Unlike the standard std::time or the chrono crate, this crate aims to provide a fully featured Duration type which exposes and uses floating-point values instead of integer ones. |
homepage | https://github.com/tylerreisinger/rust-float-duration |
repository | https://github.com/tylerreisinger/rust-float-duration |
max_upload_size | |
id | 15978 |
size | 55,373 |
Temporal quantification using floating-point quantities.
This crate provides quantification for spans of time. Unlike the standard
std::time
or the
chrono crate, this crate aims
to provide a fully featured Duration type which exposes and uses floating-point
values instead of integer ones.
The existing solutions for time spans are high precision and good for displaying and storing time values, but they are less than convenient to use in simulations or mathematical contexts where a single fractional value in some unit is needed. Thus, this crate was developed in order to fill that need while being maximally compatible with the existing time libraries and not re-inventing the wheel. The interface aims to be very similar to these libraries, just using floating point values so it may be used as a near drop-in replacement for existing programs that would benefit from floating point durations.
The goal is to provide a type with the same set of features and flexibility as
std::chrono::duration
in C++ while being "Rusty" in design.
Put this in your Cargo.toml
:
[dependencies]
float_duration = "0.3.3
This crate provides a single primary type:
FloatDuration
which represents an
arbitrary distance in time with no defined start or end point.
Internally, it stores a single f64
holding the number of seconds the duration
represents, which can be negative for a "backward" duration. It provides accessors
methods to create and read the value in various units, as well as impl
s for many
arithmetic operators in std::ops
.
let timespan = FloatDuration::hours(2.5) + FloatDuration::seconds(30.0);
assert_eq!(timespan, FloatDuration::seconds(9030.0));
assert_eq!(timespan, FloatDuration::minutes(150.5));
Additionally, a TimePoint
trait is provided
for computing a FloatDuration
between two objects representing a point in time.
Compute the number of blocks in a larger interval:
use float_duration::FloatDuration;
let time_block = FloatDuration::minutes(5.0);
let blocks_per_hour = FloatDuration::hours(1.0) / time_block;
assert_eq!(blocks_per_hour, 12.0);
Perform a basic numerical integration of a mass on a spring:
use float_duration::FloatDuration;
fn acceleration(m: f64, x: f64, t: FloatDuration) -> f64 {
0.5*m*x*x
}
fn main() {
let mut sim_time = FloatDuration::zero();
let end_time = FloatDuration::minutes(2.0);
let dt = FloatDuration::milliseconds(50.0);
let mut x = 2.0;
let mut v = 0.0;
let m = 1.0;
while sim_time < end_time {
let acc = acceleration(m, x, sim_time);
v += acc*dt.as_seconds();
x += v*dt.as_seconds();
sim_time += dt;
}
}
Run a function on 100 evenly spaced durations:
use float_duration::{FloatDuration, subdivide};
fn compute_value(t: FloatDuration) -> f64 {
t.as_seconds()*t.as_seconds()
}
for time in subdivide(FloatDuration::zero(), FloatDuration::hours(1.0), 100) {
println!("{}", compute_value(time));
}
Currently float_duration
can be compiled without any dependencies, but it
provides optional features for interfacing with other libraries.
The std::time
module is supported and FloatDuration
can be used directly with SystemTime
and Instant
:
// TimePoint needed for `float_duration_since`.
use float_duration::{FloatDuration, TimePoint};
use std::time::{Instant, SystemTime};
let start_time = Instant::now();
//Do lengthy operation...
let end_time = Instant::now();
println!("Took {}.", end_time.float_duration_since(start_time).unwrap());
FloatDuration
may also be converted to/from std::time::Duration
via the
to_std
and from_std
methods.
FloatDuration
provides an implementation of approx::ApproxEq
for near-equality comparisons of FloatDuration
if the approx
feature is enabled.
Since FloatDuration
uses floating point values, this should be the
preferred way to establish equality between two duration objects.
Similar to std::time
, computing a FloatDuration
between any two of the same type of
date or time objects
is supported via TimePoint
trait impls, assuming the feature
"chrono" is enabled.
Additionally, FloatDuration
objects can be converted to/from
chrono::Duration
objects via the to_chrono
and from_chrono
methods.
Note: if the chrono
feature is enabled, the time
feature must also be enabled
as chrono
directly relies on some types defined in time
.
use chrono::{UTC, TimeZone};
use float_duration::{TimePoint, FloatDuration};
let date1 = UTC.ymd(2017, 5, 25).and_hms(10, 0, 0);
let date2 = UTC.ymd(2017, 5, 26).and_hms(12, 0, 0);
assert_eq!(date2.float_duration_since(date1).unwrap(), FloatDuration::days(1.0) +
FloatDuration::hours(2.0));
FloatDuration
supports serialization with serde
. Presently, a FloatDuration
is serialized to a single f64
value representing the number of seconds in the
duration.