rust/src/test/ui/run-pass/numbers-arithmetic/u128-as-f32.rs

// Copyright 2017 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.

// ignore-emscripten u128 not supported

#![feature(test)]
#![deny(overflowing_literals)]
extern crate test;

use std::f32;
use std::u128;
use test::black_box;

macro_rules! test {
    ($val:expr, $src_ty:ident -> $dest_ty:ident, $expected:expr) => ({
        {
            const X: $src_ty = $val;
            const Y: $dest_ty = X as $dest_ty;
            assert_eq!(Y, $expected,
                        "const eval {} -> {}", stringify!($src_ty), stringify!($dest_ty));
        }
        // black_box disables constant evaluation to test run-time conversions:
        assert_eq!(black_box::<$src_ty>($val) as $dest_ty, $expected,
                    "run-time {} -> {}", stringify!($src_ty), stringify!($dest_ty));
    });
}

pub fn main() {
    // nextDown(f32::MAX) = 2^128 - 2 * 2^104
    const SECOND_LARGEST_F32: f32 = 340282326356119256160033759537265639424.;

    // f32::MAX - 0.5 ULP and smaller should be rounded down
    test!(0xfffffe00000000000000000000000000, u128 -> f32, SECOND_LARGEST_F32);
    test!(0xfffffe7fffffffffffffffffffffffff, u128 -> f32, SECOND_LARGEST_F32);
    test!(0xfffffe80000000000000000000000000, u128 -> f32, SECOND_LARGEST_F32);
    // numbers within < 0.5 ULP of f32::MAX it should be rounded to f32::MAX
    test!(0xfffffe80000000000000000000000001, u128 -> f32, f32::MAX);
    test!(0xfffffeffffffffffffffffffffffffff, u128 -> f32, f32::MAX);
    test!(0xffffff00000000000000000000000000, u128 -> f32, f32::MAX);
    test!(0xffffff00000000000000000000000001, u128 -> f32, f32::MAX);
    test!(0xffffff7fffffffffffffffffffffffff, u128 -> f32, f32::MAX);
    // f32::MAX + 0.5 ULP and greater should be rounded to infinity
    test!(0xffffff80000000000000000000000000, u128 -> f32, f32::INFINITY);
    test!(0xffffff80000000f00000000000000000, u128 -> f32, f32::INFINITY);
    test!(0xffffff87ffffffffffffffff00000001, u128 -> f32, f32::INFINITY);

    // u128->f64 should not be affected by the u128->f32 checks
    test!(0xffffff80000000000000000000000000, u128 -> f64,
          340282356779733661637539395458142568448.0);
    test!(u128::MAX, u128 -> f64, 340282366920938463463374607431768211455.0);
}
Make saturating u128 -> f32 casts the default behavior ... rather than being gated by -Z saturating-float-casts. There are several reasons for this: 1. Const eval already implements this behavior. 2. Unlike with float->int casts, this behavior is uncontroversially the right behavior and it is not as performance critical. Thus there is no particular need to make the bug fix for u128->f32 casts opt-in. 3. Having two orthogonal features under one flag is silly, and never should have happened in the first place. 4. Benchmarking float->int casts with the -Z flag should not pick up performance changes due to the u128->f32 casts (assuming there are any). Fixes #41799 2017-11-09 23:24:05 +00:00			`// Copyright 2017 The Rust Project Developers. See the COPYRIGHT`
			`// file at the top-level directory of this distribution and at`
			`// http://rust-lang.org/COPYRIGHT.`
			`//`
			`// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or`
			`// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license`
			`// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your`
			`// option. This file may not be copied, modified, or distributed`
			`// except according to those terms.`

			`// ignore-emscripten u128 not supported`

Fix missed i128 feature gates 2018-03-17 16:46:31 +00:00			`#![feature(test)]`
Make saturating u128 -> f32 casts the default behavior ... rather than being gated by -Z saturating-float-casts. There are several reasons for this: 1. Const eval already implements this behavior. 2. Unlike with float->int casts, this behavior is uncontroversially the right behavior and it is not as performance critical. Thus there is no particular need to make the bug fix for u128->f32 casts opt-in. 3. Having two orthogonal features under one flag is silly, and never should have happened in the first place. 4. Benchmarking float->int casts with the -Z flag should not pick up performance changes due to the u128->f32 casts (assuming there are any). Fixes #41799 2017-11-09 23:24:05 +00:00			`#![deny(overflowing_literals)]`
			`extern crate test;`

			`use std::f32;`
			`use std::u128;`
			`use test::black_box;`

			`macro_rules! test {`
			`($val:expr, $src_ty:ident -> $dest_ty:ident, $expected:expr) => ({`
			`{`
			`const X: $src_ty = $val;`
			`const Y: $dest_ty = X as $dest_ty;`
			`assert_eq!(Y, $expected,`
			`"const eval {} -> {}", stringify!($src_ty), stringify!($dest_ty));`
			`}`
			`// black_box disables constant evaluation to test run-time conversions:`
			`assert_eq!(black_box::<$src_ty>($val) as $dest_ty, $expected,`
			`"run-time {} -> {}", stringify!($src_ty), stringify!($dest_ty));`
			`});`
			`}`

			`pub fn main() {`
			`// nextDown(f32::MAX) = 2^128 - 2 * 2^104`
			`const SECOND_LARGEST_F32: f32 = 340282326356119256160033759537265639424.;`

			`// f32::MAX - 0.5 ULP and smaller should be rounded down`
			`test!(0xfffffe00000000000000000000000000, u128 -> f32, SECOND_LARGEST_F32);`
			`test!(0xfffffe7fffffffffffffffffffffffff, u128 -> f32, SECOND_LARGEST_F32);`
			`test!(0xfffffe80000000000000000000000000, u128 -> f32, SECOND_LARGEST_F32);`
			`// numbers within < 0.5 ULP of f32::MAX it should be rounded to f32::MAX`
			`test!(0xfffffe80000000000000000000000001, u128 -> f32, f32::MAX);`
			`test!(0xfffffeffffffffffffffffffffffffff, u128 -> f32, f32::MAX);`
			`test!(0xffffff00000000000000000000000000, u128 -> f32, f32::MAX);`
			`test!(0xffffff00000000000000000000000001, u128 -> f32, f32::MAX);`
			`test!(0xffffff7fffffffffffffffffffffffff, u128 -> f32, f32::MAX);`
			`// f32::MAX + 0.5 ULP and greater should be rounded to infinity`
			`test!(0xffffff80000000000000000000000000, u128 -> f32, f32::INFINITY);`
			`test!(0xffffff80000000f00000000000000000, u128 -> f32, f32::INFINITY);`
			`test!(0xffffff87ffffffffffffffff00000001, u128 -> f32, f32::INFINITY);`

			`// u128->f64 should not be affected by the u128->f32 checks`
			`test!(0xffffff80000000000000000000000000, u128 -> f64,`
			`340282356779733661637539395458142568448.0);`
			`test!(u128::MAX, u128 -> f64, 340282366920938463463374607431768211455.0);`
			`}`