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use super::measurement::*;
use ::time;
pub const HERTZ_NANOHERTZ_FACTOR: f64 = 1e9;
pub const HERTZ_MICROHERTZ_FACTOR: f64 = 1e6;
pub const HERTZ_MILLIHERTZ_FACTOR: f64 = 1e3;
pub const HERTZ_KILOHERTZ_FACTOR: f64 = 1e-3;
pub const HERTZ_MEGAHERTZ_FACTOR: f64 = 1e-6;
pub const HERTZ_GIGAHERTZ_FACTOR: f64 = 1e-9;
pub const HERTZ_TERAHERTZ_FACTOR: f64 = 1e-12;
#[derive(Copy, Clone, Debug)]
pub struct Frequency {
hertz: f64,
}
pub type Distance = Frequency;
impl Frequency {
pub fn from_hertz(hertz: f64) -> Self {
Frequency { hertz: hertz }
}
pub fn from_nanohertz(nanohertz: f64) -> Self {
Self::from_hertz(nanohertz / HERTZ_NANOHERTZ_FACTOR)
}
pub fn from_microhertz(microhertz: f64) -> Self {
Self::from_hertz(microhertz / HERTZ_MICROHERTZ_FACTOR)
}
pub fn from_millihertz(millihertz: f64) -> Self {
Self::from_hertz(millihertz / HERTZ_MILLIHERTZ_FACTOR)
}
pub fn from_kilohertz(kilohertz: f64) -> Self {
Self::from_hertz(kilohertz / HERTZ_KILOHERTZ_FACTOR)
}
pub fn from_megahertz(megahertz: f64) -> Self {
Self::from_hertz(megahertz / HERTZ_MEGAHERTZ_FACTOR)
}
pub fn from_gigahertz(gigahertz: f64) -> Self {
Self::from_hertz(gigahertz / HERTZ_GIGAHERTZ_FACTOR)
}
pub fn from_terahertz(terahertz: f64) -> Self {
Self::from_hertz(terahertz / HERTZ_TERAHERTZ_FACTOR)
}
pub fn from_period(period: time::Duration) -> Self {
Self::from_hertz(1.0 / period.as_base_units())
}
pub fn as_nanohertz(&self) -> f64 {
self.hertz * HERTZ_NANOHERTZ_FACTOR
}
pub fn as_microhertz(&self) -> f64 {
self.hertz * HERTZ_MICROHERTZ_FACTOR
}
pub fn as_millihertz(&self) -> f64 {
self.hertz * HERTZ_MILLIHERTZ_FACTOR
}
pub fn as_hertz(&self) -> f64 {
self.hertz
}
pub fn as_kilohertz(&self) -> f64 {
self.hertz * HERTZ_KILOHERTZ_FACTOR
}
pub fn as_megahertz(&self) -> f64 {
self.hertz * HERTZ_MEGAHERTZ_FACTOR
}
pub fn as_gigahertz(&self) -> f64 {
self.hertz * HERTZ_GIGAHERTZ_FACTOR
}
pub fn as_terahertz(&self) -> f64 {
self.hertz * HERTZ_TERAHERTZ_FACTOR
}
pub fn as_period(&self) -> time::Duration {
time::Duration::from_base_units(1.0 / self.hertz)
}
}
impl Measurement for Frequency {
fn as_base_units(&self) -> f64 {
self.hertz
}
fn from_base_units(units: f64) -> Self {
Self::from_hertz(units)
}
fn get_base_units_name(&self) -> &'static str {
"Hz"
}
fn get_appropriate_units(&self) -> (&'static str, f64) {
let list = [
("nHz", 1e-9),
("\u{00B5}Hz", 1e-6),
("mHz", 1e-3),
("Hz", 1e0),
("kHz", 1e3),
("MHz", 1e6),
("GHz", 1e9),
("THz", 1e12),
];
self.pick_appropriate_units(&list)
}
}
implement_measurement! { Frequency }
#[cfg(test)]
mod test {
use super::*;
use test_utils::assert_almost_eq;
use ::time;
#[test]
pub fn hertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_hertz();
assert_almost_eq(r1, 100.0);
}
#[test]
pub fn nanohertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_nanohertz();
let i2 = Frequency::from_nanohertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e+11);
assert_almost_eq(r2, 1e-7);
}
#[test]
pub fn microhertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_microhertz();
let i2 = Frequency::from_microhertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e+8);
assert_almost_eq(r2, 1e-4);
}
#[test]
pub fn millihertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_millihertz();
let i2 = Frequency::from_millihertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e+5);
assert_almost_eq(r2, 1e-1);
}
#[test]
pub fn kilohertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_kilohertz();
let i2 = Frequency::from_kilohertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e-1);
assert_almost_eq(r2, 1e+5);
}
#[test]
pub fn megahertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_megahertz();
let i2 = Frequency::from_megahertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e-4);
assert_almost_eq(r2, 1e+8);
}
#[test]
pub fn gigahertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_gigahertz();
let i2 = Frequency::from_gigahertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e-7);
assert_almost_eq(r2, 1e+11);
}
#[test]
pub fn terahertz() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_terahertz();
let i2 = Frequency::from_terahertz(100.0);
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e-10);
assert_almost_eq(r2, 1e+14);
}
#[test]
pub fn period() {
let i1 = Frequency::from_hertz(100.0);
let r1 = i1.as_period().as_base_units();
let i2 = Frequency::from_period(time::Duration::new(100, 0));
let r2 = i2.as_hertz();
assert_almost_eq(r1, 1e-2);
assert_almost_eq(r2, 1e-2);
}
#[test]
fn add() {
let a = Frequency::from_hertz(2.0);
let b = Frequency::from_hertz(4.0);
let c = a + b;
let d = b + a;
assert_almost_eq(c.as_hertz(), 6.0);
assert_eq!(c, d);
}
#[test]
fn sub() {
let a = Frequency::from_hertz(2.0);
let b = Frequency::from_hertz(4.0);
let c = a - b;
assert_almost_eq(c.as_hertz(), -2.0);
}
#[test]
fn mul() {
let a = Frequency::from_hertz(3.0);
let b = a * 2.0;
let c = 2.0 * a;
assert_almost_eq(b.as_hertz(), 6.0);
assert_eq!(b, c);
}
#[test]
fn div() {
let a = Frequency::from_hertz(2.0);
let b = Frequency::from_hertz(4.0);
let c = a / b;
let d = a / 2.0;
assert_almost_eq(c, 0.5);
assert_almost_eq(d.as_hertz(), 1.0);
}
#[test]
fn eq() {
let a = Frequency::from_hertz(2.0);
let b = Frequency::from_hertz(2.0);
assert_eq!(a == b, true);
}
#[test]
fn neq() {
let a = Frequency::from_hertz(2.0);
let b = Frequency::from_hertz(4.0);
assert_eq!(a == b, false);
}
#[test]
fn cmp() {
let a = Frequency::from_hertz(2.0);
let b = Frequency::from_hertz(4.0);
assert_eq!(a < b, true);
assert_eq!(a <= b, true);
assert_eq!(a > b, false);
assert_eq!(a >= b, false);
}
}