third_party/rust_crates/vendor/num-integer/tests/roots.rs - fuchsia - Git at Google

 extern crate num_integer;
 extern crate num_traits;

 use num_integer::Roots;
 use num_traits::checked_pow;
 use num_traits::{AsPrimitive, PrimInt, Signed};
 use std::f64::MANTISSA_DIGITS;
 use std::fmt::Debug;
 use std::mem;

 trait TestInteger: Roots + PrimInt + Debug + AsPrimitive<f64> + 'static {}

 impl<T> TestInteger for T
 where
     T: Roots + PrimInt + Debug + AsPrimitive<f64> + 'static,
 {
 }

 /// Check that each root is correct
 ///
 /// If `x` is positive, check `rⁿ ≤ x < (r+1)ⁿ`.
 /// If `x` is negative, check `(r-1)ⁿ < x ≤ rⁿ`.
 fn check<T>(v: &[T], n: u32)
 where
     T: TestInteger,
 {
     for i in v {
         let rt = i.nth_root(n);
         // println!("nth_root({:?}, {}) = {:?}", i, n, rt);
         if n == 2 {
             assert_eq!(rt, i.sqrt());
         } else if n == 3 {
             assert_eq!(rt, i.cbrt());
         }
         if *i >= T::zero() {
             let rt1 = rt + T::one();
             assert!(rt.pow(n) <= *i);
             if let Some(x) = checked_pow(rt1, n as usize) {
                 assert!(*i < x);
             }
         } else {
             let rt1 = rt - T::one();
             assert!(rt < T::zero());
             assert!(*i <= rt.pow(n));
             if let Some(x) = checked_pow(rt1, n as usize) {
                 assert!(x < *i);
             }
         };
     }
 }

 /// Get the maximum value that will round down as `f64` (if any),
 /// and its successor that will round up.
 ///
 /// Important because the `std` implementations cast to `f64` to
 /// get a close approximation of the roots.
 fn mantissa_max<T>() -> Option<(T, T)>
 where
     T: TestInteger,
 {
     let bits = if T::min_value().is_zero() {
         8 * mem::size_of::<T>()
     } else {
         8 * mem::size_of::<T>() - 1
     };
     if bits > MANTISSA_DIGITS as usize {
         let rounding_bit = T::one() << (bits - MANTISSA_DIGITS as usize - 1);
         let x = T::max_value() - rounding_bit;

         let x1 = x + T::one();
         let x2 = x1 + T::one();
         assert!(x.as_() < x1.as_());
         assert_eq!(x1.as_(), x2.as_());

         Some((x, x1))
     } else {
         None
     }
 }

 fn extend<T>(v: &mut Vec<T>, start: T, end: T)
 where
     T: TestInteger,
 {
     let mut i = start;
     while i < end {
         v.push(i);
         i = i + T::one();
     }
     v.push(i);
 }

 fn extend_shl<T>(v: &mut Vec<T>, start: T, end: T, mask: T)
 where
     T: TestInteger,
 {
     let mut i = start;
     while i != end {
         v.push(i);
         i = (i << 1) & mask;
     }
 }

 fn extend_shr<T>(v: &mut Vec<T>, start: T, end: T)
 where
     T: TestInteger,
 {
     let mut i = start;
     while i != end {
         v.push(i);
         i = i >> 1;
     }
 }

 fn pos<T>() -> Vec<T>
 where
     T: TestInteger,
     i8: AsPrimitive<T>,
 {
     let mut v: Vec<T> = vec![];
     if mem::size_of::<T>() == 1 {
         extend(&mut v, T::zero(), T::max_value());
     } else {
         extend(&mut v, T::zero(), i8::max_value().as_());
         extend(
             &mut v,
             T::max_value() - i8::max_value().as_(),
             T::max_value(),
         );
         if let Some((i, j)) = mantissa_max::<T>() {
             v.push(i);
             v.push(j);
         }
         extend_shl(&mut v, T::max_value(), T::zero(), !T::min_value());
         extend_shr(&mut v, T::max_value(), T::zero());
     }
     v
 }

 fn neg<T>() -> Vec<T>
 where
     T: TestInteger + Signed,
     i8: AsPrimitive<T>,
 {
     let mut v: Vec<T> = vec![];
     if mem::size_of::<T>() <= 1 {
         extend(&mut v, T::min_value(), T::zero());
     } else {
         extend(&mut v, i8::min_value().as_(), T::zero());
         extend(
             &mut v,
             T::min_value(),
             T::min_value() - i8::min_value().as_(),
         );
         if let Some((i, j)) = mantissa_max::<T>() {
             v.push(-i);
             v.push(-j);
         }
         extend_shl(&mut v, -T::one(), T::min_value(), !T::zero());
         extend_shr(&mut v, T::min_value(), -T::one());
     }
     v
 }

 macro_rules! test_roots {
     ($I:ident, $U:ident) => {
         mod $I {
             use check;
             use neg;
             use num_integer::Roots;
             use pos;
             use std::mem;

             #[test]
             #[should_panic]
             fn zeroth_root() {
                 (123 as $I).nth_root(0);
             }

             #[test]
             fn sqrt() {
                 check(&pos::<$I>(), 2);
             }

             #[test]
             #[should_panic]
             fn sqrt_neg() {
                 (-123 as $I).sqrt();
             }

             #[test]
             fn cbrt() {
                 check(&pos::<$I>(), 3);
             }

             #[test]
             fn cbrt_neg() {
                 check(&neg::<$I>(), 3);
             }

             #[test]
             fn nth_root() {
                 let bits = 8 * mem::size_of::<$I>() as u32 - 1;
                 let pos = pos::<$I>();
                 for n in 4..bits {
                     check(&pos, n);
                 }
             }

             #[test]
             fn nth_root_neg() {
                 let bits = 8 * mem::size_of::<$I>() as u32 - 1;
                 let neg = neg::<$I>();
                 for n in 2..bits / 2 {
                     check(&neg, 2 * n + 1);
                 }
             }

             #[test]
             fn bit_size() {
                 let bits = 8 * mem::size_of::<$I>() as u32 - 1;
                 assert_eq!($I::max_value().nth_root(bits - 1), 2);
                 assert_eq!($I::max_value().nth_root(bits), 1);
                 assert_eq!($I::min_value().nth_root(bits), -2);
                 assert_eq!(($I::min_value() + 1).nth_root(bits), -1);
             }
         }

         mod $U {
             use check;
             use num_integer::Roots;
             use pos;
             use std::mem;

             #[test]
             #[should_panic]
             fn zeroth_root() {
                 (123 as $U).nth_root(0);
             }

             #[test]
             fn sqrt() {
                 check(&pos::<$U>(), 2);
             }

             #[test]
             fn cbrt() {
                 check(&pos::<$U>(), 3);
             }

             #[test]
             fn nth_root() {
                 let bits = 8 * mem::size_of::<$I>() as u32 - 1;
                 let pos = pos::<$I>();
                 for n in 4..bits {
                     check(&pos, n);
                 }
             }

             #[test]
             fn bit_size() {
                 let bits = 8 * mem::size_of::<$U>() as u32;
                 assert_eq!($U::max_value().nth_root(bits - 1), 2);
                 assert_eq!($U::max_value().nth_root(bits), 1);
             }
         }
     };
 }

 test_roots!(i8, u8);
 test_roots!(i16, u16);
 test_roots!(i32, u32);
 test_roots!(i64, u64);
 #[cfg(has_i128)]
 test_roots!(i128, u128);
 test_roots!(isize, usize);
	extern crate num_integer;
	extern crate num_traits;

	use num_integer::Roots;
	use num_traits::checked_pow;
	use num_traits::{AsPrimitive, PrimInt, Signed};
	use std::f64::MANTISSA_DIGITS;
	use std::fmt::Debug;
	use std::mem;

	trait TestInteger: Roots + PrimInt + Debug + AsPrimitive<f64> + 'static {}

	impl<T> TestInteger for T
	where
	T: Roots + PrimInt + Debug + AsPrimitive<f64> + 'static,
	{
	}

	/// Check that each root is correct
	///
	/// If `x` is positive, check `rⁿ ≤ x < (r+1)ⁿ`.
	/// If `x` is negative, check `(r-1)ⁿ < x ≤ rⁿ`.
	fn check<T>(v: &[T], n: u32)
	where
	T: TestInteger,
	{
	for i in v {
	let rt = i.nth_root(n);
	// println!("nth_root({:?}, {}) = {:?}", i, n, rt);
	if n == 2 {
	assert_eq!(rt, i.sqrt());
	} else if n == 3 {
	assert_eq!(rt, i.cbrt());
	}
	if *i >= T::zero() {
	let rt1 = rt + T::one();
	assert!(rt.pow(n) <= *i);
	if let Some(x) = checked_pow(rt1, n as usize) {
	assert!(*i < x);
	}
	} else {
	let rt1 = rt - T::one();
	assert!(rt < T::zero());
	assert!(*i <= rt.pow(n));
	if let Some(x) = checked_pow(rt1, n as usize) {
	assert!(x < *i);
	}
	};
	}
	}

	/// Get the maximum value that will round down as `f64` (if any),
	/// and its successor that will round up.
	///
	/// Important because the `std` implementations cast to `f64` to
	/// get a close approximation of the roots.
	fn mantissa_max<T>() -> Option<(T, T)>
	where
	T: TestInteger,
	{
	let bits = if T::min_value().is_zero() {
	8 * mem::size_of::<T>()
	} else {
	8 * mem::size_of::<T>() - 1
	};
	if bits > MANTISSA_DIGITS as usize {
	let rounding_bit = T::one() << (bits - MANTISSA_DIGITS as usize - 1);
	let x = T::max_value() - rounding_bit;

	let x1 = x + T::one();
	let x2 = x1 + T::one();
	assert!(x.as_() < x1.as_());
	assert_eq!(x1.as_(), x2.as_());

	Some((x, x1))
	} else {
	None
	}
	}

	fn extend<T>(v: &mut Vec<T>, start: T, end: T)
	where
	T: TestInteger,
	{
	let mut i = start;
	while i < end {
	v.push(i);
	i = i + T::one();
	}
	v.push(i);
	}

	fn extend_shl<T>(v: &mut Vec<T>, start: T, end: T, mask: T)
	where
	T: TestInteger,
	{
	let mut i = start;
	while i != end {
	v.push(i);
	i = (i << 1) & mask;
	}
	}

	fn extend_shr<T>(v: &mut Vec<T>, start: T, end: T)
	where
	T: TestInteger,
	{
	let mut i = start;
	while i != end {
	v.push(i);
	i = i >> 1;
	}
	}

	fn pos<T>() -> Vec<T>
	where
	T: TestInteger,
	i8: AsPrimitive<T>,
	{
	let mut v: Vec<T> = vec![];
	if mem::size_of::<T>() == 1 {
	extend(&mut v, T::zero(), T::max_value());
	} else {
	extend(&mut v, T::zero(), i8::max_value().as_());
	extend(
	&mut v,
	T::max_value() - i8::max_value().as_(),
	T::max_value(),
	);
	if let Some((i, j)) = mantissa_max::<T>() {
	v.push(i);
	v.push(j);
	}
	extend_shl(&mut v, T::max_value(), T::zero(), !T::min_value());
	extend_shr(&mut v, T::max_value(), T::zero());
	}
	v
	}

	fn neg<T>() -> Vec<T>
	where
	T: TestInteger + Signed,
	i8: AsPrimitive<T>,
	{
	let mut v: Vec<T> = vec![];
	if mem::size_of::<T>() <= 1 {
	extend(&mut v, T::min_value(), T::zero());
	} else {
	extend(&mut v, i8::min_value().as_(), T::zero());
	extend(
	&mut v,
	T::min_value(),
	T::min_value() - i8::min_value().as_(),
	);
	if let Some((i, j)) = mantissa_max::<T>() {
	v.push(-i);
	v.push(-j);
	}
	extend_shl(&mut v, -T::one(), T::min_value(), !T::zero());
	extend_shr(&mut v, T::min_value(), -T::one());
	}
	v
	}

	macro_rules! test_roots {
	($I:ident, $U:ident) => {
	mod $I {
	use check;
	use neg;
	use num_integer::Roots;
	use pos;
	use std::mem;

	#[test]
	#[should_panic]
	fn zeroth_root() {
	(123 as $I).nth_root(0);
	}

	#[test]
	fn sqrt() {
	check(&pos::<$I>(), 2);
	}

	#[test]
	#[should_panic]
	fn sqrt_neg() {
	(-123 as $I).sqrt();
	}

	#[test]
	fn cbrt() {
	check(&pos::<$I>(), 3);
	}

	#[test]
	fn cbrt_neg() {
	check(&neg::<$I>(), 3);
	}

	#[test]
	fn nth_root() {
	let bits = 8 * mem::size_of::<$I>() as u32 - 1;
	let pos = pos::<$I>();
	for n in 4..bits {
	check(&pos, n);
	}
	}

	#[test]
	fn nth_root_neg() {
	let bits = 8 * mem::size_of::<$I>() as u32 - 1;
	let neg = neg::<$I>();
	for n in 2..bits / 2 {
	check(&neg, 2 * n + 1);
	}
	}

	#[test]
	fn bit_size() {
	let bits = 8 * mem::size_of::<$I>() as u32 - 1;
	assert_eq!($I::max_value().nth_root(bits - 1), 2);
	assert_eq!($I::max_value().nth_root(bits), 1);
	assert_eq!($I::min_value().nth_root(bits), -2);
	assert_eq!(($I::min_value() + 1).nth_root(bits), -1);
	}
	}

	mod $U {
	use check;
	use num_integer::Roots;
	use pos;
	use std::mem;

	#[test]
	#[should_panic]
	fn zeroth_root() {
	(123 as $U).nth_root(0);
	}

	#[test]
	fn sqrt() {
	check(&pos::<$U>(), 2);
	}

	#[test]
	fn cbrt() {
	check(&pos::<$U>(), 3);
	}

	#[test]
	fn nth_root() {
	let bits = 8 * mem::size_of::<$I>() as u32 - 1;
	let pos = pos::<$I>();
	for n in 4..bits {
	check(&pos, n);
	}
	}

	#[test]
	fn bit_size() {
	let bits = 8 * mem::size_of::<$U>() as u32;
	assert_eq!($U::max_value().nth_root(bits - 1), 2);
	assert_eq!($U::max_value().nth_root(bits), 1);
	}
	}
	};
	}

	test_roots!(i8, u8);
	test_roots!(i16, u16);
	test_roots!(i32, u32);
	test_roots!(i64, u64);
	#[cfg(has_i128)]
	test_roots!(i128, u128);
	test_roots!(isize, usize);