src/test/ui/simd/simd-intrinsic-float-math.rs - third_party/rust - Git at Google

 // run-pass
 // ignore-emscripten
 // ignore-android

 // FIXME: this test fails on arm-android because the NDK version 14 is too old.
 // It needs at least version 18. We disable it on all android build bots because
 // there is no way in compile-test to disable it for an (arch,os) pair.

 // Test that the simd floating-point math intrinsics produce correct results.

 #![feature(repr_simd, platform_intrinsics)]
 #![allow(non_camel_case_types)]

 #[repr(simd)]
 #[derive(Copy, Clone, PartialEq, Debug)]
 struct f32x4(pub f32, pub f32, pub f32, pub f32);

 extern "platform-intrinsic" {
     fn simd_fsqrt<T>(x: T) -> T;
     fn simd_fabs<T>(x: T) -> T;
     fn simd_fsin<T>(x: T) -> T;
     fn simd_fcos<T>(x: T) -> T;
     fn simd_ceil<T>(x: T) -> T;
     fn simd_fexp<T>(x: T) -> T;
     fn simd_fexp2<T>(x: T) -> T;
     fn simd_floor<T>(x: T) -> T;
     fn simd_fma<T>(x: T, y: T, z: T) -> T;
     fn simd_flog<T>(x: T) -> T;
     fn simd_flog10<T>(x: T) -> T;
     fn simd_flog2<T>(x: T) -> T;
     fn simd_fpow<T>(x: T, y: T) -> T;
     fn simd_fpowi<T>(x: T, y: i32) -> T;
 }

 macro_rules! assert_approx_eq_f32 {
     ($a:expr, $b:expr) => ({
         let (a, b) = (&$a, &$b);
         assert!((*a - *b).abs() < 1.0e-6,
                 "{} is not approximately equal to {}", *a, *b);
     })
 }
 macro_rules! assert_approx_eq {
     ($a:expr, $b:expr) => ({
         let a = $a;
         let b = $b;
         assert_approx_eq_f32!(a.0, b.0);
         assert_approx_eq_f32!(a.1, b.1);
         assert_approx_eq_f32!(a.2, b.2);
         assert_approx_eq_f32!(a.3, b.3);
     })
 }

 fn main() {
     let x = f32x4(1.0, 1.0, 1.0, 1.0);
     let y = f32x4(-1.0, -1.0, -1.0, -1.0);
     let z = f32x4(0.0, 0.0, 0.0, 0.0);

     let h = f32x4(0.5, 0.5, 0.5, 0.5);

     unsafe {
         let r = simd_fabs(y);
         assert_approx_eq!(x, r);

         let r = simd_fcos(z);
         assert_approx_eq!(x, r);

         let r = simd_ceil(h);
         assert_approx_eq!(x, r);

         let r = simd_fexp(z);
         assert_approx_eq!(x, r);

         let r = simd_fexp2(z);
         assert_approx_eq!(x, r);

         let r = simd_floor(h);
         assert_approx_eq!(z, r);

         let r = simd_fma(x, h, h);
         assert_approx_eq!(x, r);

         let r = simd_fsqrt(x);
         assert_approx_eq!(x, r);

         let r = simd_flog(x);
         assert_approx_eq!(z, r);

         let r = simd_flog2(x);
         assert_approx_eq!(z, r);

         let r = simd_flog10(x);
         assert_approx_eq!(z, r);

         let r = simd_fpow(h, x);
         assert_approx_eq!(h, r);

         let r = simd_fpowi(h, 1);
         assert_approx_eq!(h, r);

         let r = simd_fsin(z);
         assert_approx_eq!(z, r);
     }
 }
	// run-pass
	// ignore-emscripten
	// ignore-android

	// FIXME: this test fails on arm-android because the NDK version 14 is too old.
	// It needs at least version 18. We disable it on all android build bots because
	// there is no way in compile-test to disable it for an (arch,os) pair.

	// Test that the simd floating-point math intrinsics produce correct results.

	#![feature(repr_simd, platform_intrinsics)]
	#![allow(non_camel_case_types)]

	#[repr(simd)]
	#[derive(Copy, Clone, PartialEq, Debug)]
	struct f32x4(pub f32, pub f32, pub f32, pub f32);

	extern "platform-intrinsic" {
	fn simd_fsqrt<T>(x: T) -> T;
	fn simd_fabs<T>(x: T) -> T;
	fn simd_fsin<T>(x: T) -> T;
	fn simd_fcos<T>(x: T) -> T;
	fn simd_ceil<T>(x: T) -> T;
	fn simd_fexp<T>(x: T) -> T;
	fn simd_fexp2<T>(x: T) -> T;
	fn simd_floor<T>(x: T) -> T;
	fn simd_fma<T>(x: T, y: T, z: T) -> T;
	fn simd_flog<T>(x: T) -> T;
	fn simd_flog10<T>(x: T) -> T;
	fn simd_flog2<T>(x: T) -> T;
	fn simd_fpow<T>(x: T, y: T) -> T;
	fn simd_fpowi<T>(x: T, y: i32) -> T;
	}

	macro_rules! assert_approx_eq_f32 {
	($a:expr, $b:expr) => ({
	let (a, b) = (&$a, &$b);
	assert!((a - b).abs() < 1.0e-6,
	"{} is not approximately equal to {}", a, b);
	})
	}
	macro_rules! assert_approx_eq {
	($a:expr, $b:expr) => ({
	let a = $a;
	let b = $b;
	assert_approx_eq_f32!(a.0, b.0);
	assert_approx_eq_f32!(a.1, b.1);
	assert_approx_eq_f32!(a.2, b.2);
	assert_approx_eq_f32!(a.3, b.3);
	})
	}

	fn main() {
	let x = f32x4(1.0, 1.0, 1.0, 1.0);
	let y = f32x4(-1.0, -1.0, -1.0, -1.0);
	let z = f32x4(0.0, 0.0, 0.0, 0.0);

	let h = f32x4(0.5, 0.5, 0.5, 0.5);

	unsafe {
	let r = simd_fabs(y);
	assert_approx_eq!(x, r);

	let r = simd_fcos(z);
	assert_approx_eq!(x, r);

	let r = simd_ceil(h);
	assert_approx_eq!(x, r);

	let r = simd_fexp(z);
	assert_approx_eq!(x, r);

	let r = simd_fexp2(z);
	assert_approx_eq!(x, r);

	let r = simd_floor(h);
	assert_approx_eq!(z, r);

	let r = simd_fma(x, h, h);
	assert_approx_eq!(x, r);

	let r = simd_fsqrt(x);
	assert_approx_eq!(x, r);

	let r = simd_flog(x);
	assert_approx_eq!(z, r);

	let r = simd_flog2(x);
	assert_approx_eq!(z, r);

	let r = simd_flog10(x);
	assert_approx_eq!(z, r);

	let r = simd_fpow(h, x);
	assert_approx_eq!(h, r);

	let r = simd_fpowi(h, 1);
	assert_approx_eq!(h, r);

	let r = simd_fsin(z);
	assert_approx_eq!(z, r);
	}
	}