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#[cfg(feature = "num-traits")]
#[allow(unused_imports)]
use num_traits::float::FloatCore;
use super::Ulps;
pub trait ApproxEqUlps {
type Flt: Ulps;
fn approx_eq_ulps(&self, other: &Self, ulps: <Self::Flt as Ulps>::U) -> bool;
#[inline]
fn approx_ne_ulps(&self, other: &Self, ulps: <Self::Flt as Ulps>::U) -> bool {
!self.approx_eq_ulps(other, ulps)
}
}
impl ApproxEqUlps for f32 {
type Flt = f32;
fn approx_eq_ulps(&self, other: &f32, ulps: i32) -> bool {
if *self==*other { return true; }
if self.is_sign_positive() != other.is_sign_positive() { return false; }
let diff: i32 = self.ulps(other);
diff >= -ulps && diff <= ulps
}
}
#[test]
fn f32_approx_eq_ulps_test1() {
let f: f32 = 0.1_f32;
let mut sum: f32 = 0.0_f32;
for _ in 0_isize..10_isize { sum += f; }
let product: f32 = f * 10.0_f32;
assert!(sum != product);
assert!(sum.approx_eq_ulps(&product,1) == true);
assert!(sum.approx_eq_ulps(&product,0) == false);
}
#[test]
fn f32_approx_eq_ulps_test2() {
let x: f32 = 1000000_f32;
let y: f32 = 1000000.1_f32;
assert!(x != y);
assert!(x.approx_eq_ulps(&y,2) == true);
assert!(x.approx_eq_ulps(&y,1) == false);
}
#[test]
fn f32_approx_eq_ulps_test_zeroes() {
let x: f32 = 0.0_f32;
let y: f32 = -0.0_f32;
assert!(x.approx_eq_ulps(&y,0) == true);
}
impl ApproxEqUlps for f64 {
type Flt = f64;
fn approx_eq_ulps(&self, other: &f64, ulps: i64) -> bool {
if *self==*other { return true; }
if self.is_sign_positive() != other.is_sign_positive() { return false; }
let diff: i64 = self.ulps(other);
diff >= -ulps && diff <= ulps
}
}
#[test]
fn f64_approx_eq_ulps_test1() {
let f: f64 = 0.1_f64;
let mut sum: f64 = 0.0_f64;
for _ in 0_isize..10_isize { sum += f; }
let product: f64 = f * 10.0_f64;
assert!(sum != product);
assert!(sum.approx_eq_ulps(&product,1) == true);
assert!(sum.approx_eq_ulps(&product,0) == false);
}
#[test]
fn f64_approx_eq_ulps_test2() {
let x: f64 = 1000000_f64;
let y: f64 = 1000000.0000000003_f64;
assert!(x != y);
assert!(x.approx_eq_ulps(&y,3) == true);
assert!(x.approx_eq_ulps(&y,2) == false);
}
#[test]
fn f64_approx_eq_ulps_test_zeroes() {
let x: f64 = 0.0_f64;
let y: f64 = -0.0_f64;
assert!(x.approx_eq_ulps(&y,0) == true);
}