aarch64/usr/lib/rustlib/src/rust/library/core/tests/num/flt2dec/random.rs - manifest_repos/toolchain - Git at Google

 #![cfg(not(target_arch = "wasm32"))]

 use std::mem::MaybeUninit;
 use std::str;

 use core::num::flt2dec::strategy::grisu::format_exact_opt;
 use core::num::flt2dec::strategy::grisu::format_shortest_opt;
 use core::num::flt2dec::MAX_SIG_DIGITS;
 use core::num::flt2dec::{decode, DecodableFloat, Decoded, FullDecoded};

 use rand::distributions::{Distribution, Uniform};
 use rand::rngs::StdRng;
 use rand::SeedableRng;

 pub fn decode_finite<T: DecodableFloat>(v: T) -> Decoded {
     match decode(v).1 {
         FullDecoded::Finite(decoded) => decoded,
         full_decoded => panic!("expected finite, got {full_decoded:?} instead"),
     }
 }

 fn iterate<F, G, V>(func: &str, k: usize, n: usize, mut f: F, mut g: G, mut v: V) -> (usize, usize)
 where
     F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
     G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
     V: FnMut(usize) -> Decoded,
 {
     assert!(k <= 1024);

     let mut npassed = 0; // f(x) = Some(g(x))
     let mut nignored = 0; // f(x) = None

     for i in 0..n {
         if (i & 0xfffff) == 0 {
             println!(
                 "in progress, {:x}/{:x} (ignored={} passed={} failed={})",
                 i,
                 n,
                 nignored,
                 npassed,
                 i - nignored - npassed
             );
         }

         let decoded = v(i);
         let mut buf1 = [MaybeUninit::new(0); 1024];
         if let Some((buf1, e1)) = f(&decoded, &mut buf1[..k]) {
             let mut buf2 = [MaybeUninit::new(0); 1024];
             let (buf2, e2) = g(&decoded, &mut buf2[..k]);
             if e1 == e2 && buf1 == buf2 {
                 npassed += 1;
             } else {
                 println!(
                     "equivalence test failed, {:x}/{:x}: {:?} f(i)={}e{} g(i)={}e{}",
                     i,
                     n,
                     decoded,
                     str::from_utf8(buf1).unwrap(),
                     e1,
                     str::from_utf8(buf2).unwrap(),
                     e2
                 );
             }
         } else {
             nignored += 1;
         }
     }
     println!(
         "{}({}): done, ignored={} passed={} failed={}",
         func,
         k,
         nignored,
         npassed,
         n - nignored - npassed
     );
     assert!(
         nignored + npassed == n,
         "{}({}): {} out of {} values returns an incorrect value!",
         func,
         k,
         n - nignored - npassed,
         n
     );
     (npassed, nignored)
 }

 pub fn f32_random_equivalence_test<F, G>(f: F, g: G, k: usize, n: usize)
 where
     F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
     G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
 {
     if cfg!(target_os = "emscripten") {
         return; // using rng pulls in i128 support, which doesn't work
     }
     let mut rng = StdRng::from_entropy();
     let f32_range = Uniform::new(0x0000_0001u32, 0x7f80_0000);
     iterate("f32_random_equivalence_test", k, n, f, g, |_| {
         let x = f32::from_bits(f32_range.sample(&mut rng));
         decode_finite(x)
     });
 }

 pub fn f64_random_equivalence_test<F, G>(f: F, g: G, k: usize, n: usize)
 where
     F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
     G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
 {
     if cfg!(target_os = "emscripten") {
         return; // using rng pulls in i128 support, which doesn't work
     }
     let mut rng = StdRng::from_entropy();
     let f64_range = Uniform::new(0x0000_0000_0000_0001u64, 0x7ff0_0000_0000_0000);
     iterate("f64_random_equivalence_test", k, n, f, g, |_| {
         let x = f64::from_bits(f64_range.sample(&mut rng));
         decode_finite(x)
     });
 }

 pub fn f32_exhaustive_equivalence_test<F, G>(f: F, g: G, k: usize)
 where
     F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
     G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
 {
     // we have only 2^23 * (2^8 - 1) - 1 = 2,139,095,039 positive finite f32 values,
     // so why not simply testing all of them?
     //
     // this is of course very stressful (and thus should be behind an `#[ignore]` attribute),
     // but with `-C opt-level=3 -C lto` this only takes about an hour or so.

     // iterate from 0x0000_0001 to 0x7f7f_ffff, i.e., all finite ranges
     let (npassed, nignored) =
         iterate("f32_exhaustive_equivalence_test", k, 0x7f7f_ffff, f, g, |i: usize| {
             let x = f32::from_bits(i as u32 + 1);
             decode_finite(x)
         });
     assert_eq!((npassed, nignored), (2121451881, 17643158));
 }

 #[test]
 fn shortest_random_equivalence_test() {
     use core::num::flt2dec::strategy::dragon::format_shortest as fallback;
     // Miri is too slow
     let n = if cfg!(miri) { 10 } else { 10_000 };

     f64_random_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS, n);
     f32_random_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS, n);
 }

 #[test]
 #[ignore] // it is too expensive
 fn shortest_f32_exhaustive_equivalence_test() {
     // it is hard to directly test the optimality of the output, but we can at least test if
     // two different algorithms agree to each other.
     //
     // this reports the progress and the number of f32 values returned `None`.
     // with `--nocapture` (and plenty of time and appropriate rustc flags), this should print:
     // `done, ignored=17643158 passed=2121451881 failed=0`.

     use core::num::flt2dec::strategy::dragon::format_shortest as fallback;
     f32_exhaustive_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS);
 }

 #[test]
 #[ignore] // it is too expensive
 fn shortest_f64_hard_random_equivalence_test() {
     // this again probably has to use appropriate rustc flags.

     use core::num::flt2dec::strategy::dragon::format_shortest as fallback;
     f64_random_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS, 100_000_000);
 }

 #[test]
 fn exact_f32_random_equivalence_test() {
     use core::num::flt2dec::strategy::dragon::format_exact as fallback;
     // Miri is too slow
     let n = if cfg!(miri) { 3 } else { 1_000 };

     for k in 1..21 {
         f32_random_equivalence_test(
             |d, buf| format_exact_opt(d, buf, i16::MIN),
             |d, buf| fallback(d, buf, i16::MIN),
             k,
             n,
         );
     }
 }

 #[test]
 fn exact_f64_random_equivalence_test() {
     use core::num::flt2dec::strategy::dragon::format_exact as fallback;
     // Miri is too slow
     let n = if cfg!(miri) { 2 } else { 1_000 };

     for k in 1..21 {
         f64_random_equivalence_test(
             |d, buf| format_exact_opt(d, buf, i16::MIN),
             |d, buf| fallback(d, buf, i16::MIN),
             k,
             n,
         );
     }
 }
	#![cfg(not(target_arch = "wasm32"))]

	use std::mem::MaybeUninit;
	use std::str;

	use core::num::flt2dec::strategy::grisu::format_exact_opt;
	use core::num::flt2dec::strategy::grisu::format_shortest_opt;
	use core::num::flt2dec::MAX_SIG_DIGITS;
	use core::num::flt2dec::{decode, DecodableFloat, Decoded, FullDecoded};

	use rand::distributions::{Distribution, Uniform};
	use rand::rngs::StdRng;
	use rand::SeedableRng;

	pub fn decode_finite<T: DecodableFloat>(v: T) -> Decoded {
	match decode(v).1 {
	FullDecoded::Finite(decoded) => decoded,
	full_decoded => panic!("expected finite, got {full_decoded:?} instead"),
	}
	}

	fn iterate<F, G, V>(func: &str, k: usize, n: usize, mut f: F, mut g: G, mut v: V) -> (usize, usize)
	where
	F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
	G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
	V: FnMut(usize) -> Decoded,
	{
	assert!(k <= 1024);

	let mut npassed = 0; // f(x) = Some(g(x))
	let mut nignored = 0; // f(x) = None

	for i in 0..n {
	if (i & 0xfffff) == 0 {
	println!(
	"in progress, {:x}/{:x} (ignored={} passed={} failed={})",
	i,
	n,
	nignored,
	npassed,
	i - nignored - npassed
	);
	}

	let decoded = v(i);
	let mut buf1 = [MaybeUninit::new(0); 1024];
	if let Some((buf1, e1)) = f(&decoded, &mut buf1[..k]) {
	let mut buf2 = [MaybeUninit::new(0); 1024];
	let (buf2, e2) = g(&decoded, &mut buf2[..k]);
	if e1 == e2 && buf1 == buf2 {
	npassed += 1;
	} else {
	println!(
	"equivalence test failed, {:x}/{:x}: {:?} f(i)={}e{} g(i)={}e{}",
	i,
	n,
	decoded,
	str::from_utf8(buf1).unwrap(),
	e1,
	str::from_utf8(buf2).unwrap(),
	e2
	);
	}
	} else {
	nignored += 1;
	}
	}
	println!(
	"{}({}): done, ignored={} passed={} failed={}",
	func,
	k,
	nignored,
	npassed,
	n - nignored - npassed
	);
	assert!(
	nignored + npassed == n,
	"{}({}): {} out of {} values returns an incorrect value!",
	func,
	k,
	n - nignored - npassed,
	n
	);
	(npassed, nignored)
	}

	pub fn f32_random_equivalence_test<F, G>(f: F, g: G, k: usize, n: usize)
	where
	F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
	G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
	{
	if cfg!(target_os = "emscripten") {
	return; // using rng pulls in i128 support, which doesn't work
	}
	let mut rng = StdRng::from_entropy();
	let f32_range = Uniform::new(0x0000_0001u32, 0x7f80_0000);
	iterate("f32_random_equivalence_test", k, n, f, g, \|_\| {
	let x = f32::from_bits(f32_range.sample(&mut rng));
	decode_finite(x)
	});
	}

	pub fn f64_random_equivalence_test<F, G>(f: F, g: G, k: usize, n: usize)
	where
	F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
	G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
	{
	if cfg!(target_os = "emscripten") {
	return; // using rng pulls in i128 support, which doesn't work
	}
	let mut rng = StdRng::from_entropy();
	let f64_range = Uniform::new(0x0000_0000_0000_0001u64, 0x7ff0_0000_0000_0000);
	iterate("f64_random_equivalence_test", k, n, f, g, \|_\| {
	let x = f64::from_bits(f64_range.sample(&mut rng));
	decode_finite(x)
	});
	}

	pub fn f32_exhaustive_equivalence_test<F, G>(f: F, g: G, k: usize)
	where
	F: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> Option<(&'a [u8], i16)>,
	G: for<'a> FnMut(&Decoded, &'a mut [MaybeUninit<u8>]) -> (&'a [u8], i16),
	{
	// we have only 2^23 * (2^8 - 1) - 1 = 2,139,095,039 positive finite f32 values,
	// so why not simply testing all of them?
	//
	// this is of course very stressful (and thus should be behind an `#[ignore]` attribute),
	// but with `-C opt-level=3 -C lto` this only takes about an hour or so.

	// iterate from 0x0000_0001 to 0x7f7f_ffff, i.e., all finite ranges
	let (npassed, nignored) =
	iterate("f32_exhaustive_equivalence_test", k, 0x7f7f_ffff, f, g, \|i: usize\| {
	let x = f32::from_bits(i as u32 + 1);
	decode_finite(x)
	});
	assert_eq!((npassed, nignored), (2121451881, 17643158));
	}

	#[test]
	fn shortest_random_equivalence_test() {
	use core::num::flt2dec::strategy::dragon::format_shortest as fallback;
	// Miri is too slow
	let n = if cfg!(miri) { 10 } else { 10_000 };

	f64_random_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS, n);
	f32_random_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS, n);
	}

	#[test]
	#[ignore] // it is too expensive
	fn shortest_f32_exhaustive_equivalence_test() {
	// it is hard to directly test the optimality of the output, but we can at least test if
	// two different algorithms agree to each other.
	//
	// this reports the progress and the number of f32 values returned `None`.
	// with `--nocapture` (and plenty of time and appropriate rustc flags), this should print:
	// `done, ignored=17643158 passed=2121451881 failed=0`.

	use core::num::flt2dec::strategy::dragon::format_shortest as fallback;
	f32_exhaustive_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS);
	}

	#[test]
	#[ignore] // it is too expensive
	fn shortest_f64_hard_random_equivalence_test() {
	// this again probably has to use appropriate rustc flags.

	use core::num::flt2dec::strategy::dragon::format_shortest as fallback;
	f64_random_equivalence_test(format_shortest_opt, fallback, MAX_SIG_DIGITS, 100_000_000);
	}

	#[test]
	fn exact_f32_random_equivalence_test() {
	use core::num::flt2dec::strategy::dragon::format_exact as fallback;
	// Miri is too slow
	let n = if cfg!(miri) { 3 } else { 1_000 };

	for k in 1..21 {
	f32_random_equivalence_test(
	\|d, buf\| format_exact_opt(d, buf, i16::MIN),
	\|d, buf\| fallback(d, buf, i16::MIN),
	k,
	n,
	);
	}
	}

	#[test]
	fn exact_f64_random_equivalence_test() {
	use core::num::flt2dec::strategy::dragon::format_exact as fallback;
	// Miri is too slow
	let n = if cfg!(miri) { 2 } else { 1_000 };

	for k in 1..21 {
	f64_random_equivalence_test(
	\|d, buf\| format_exact_opt(d, buf, i16::MIN),
	\|d, buf\| fallback(d, buf, i16::MIN),
	k,
	n,
	);
	}
	}