tests/roots.rs - platform/external/rust/crates/num-bigint - Git at Google

 mod biguint {
     use num_bigint::BigUint;
     use num_traits::{One, Zero};
     use std::{i32, u32};

     fn check<T: Into<BigUint>>(x: T, n: u32) {
         let x: BigUint = x.into();
         let root = x.nth_root(n);
         println!("check {}.nth_root({}) = {}", x, n, root);

         if n == 2 {
             assert_eq!(root, x.sqrt())
         } else if n == 3 {
             assert_eq!(root, x.cbrt())
         }

         let lo = root.pow(n);
         assert!(lo <= x);
         assert_eq!(lo.nth_root(n), root);
         if !lo.is_zero() {
             assert_eq!((&lo - 1u32).nth_root(n), &root - 1u32);
         }

         let hi = (&root + 1u32).pow(n);
         assert!(hi > x);
         assert_eq!(hi.nth_root(n), &root + 1u32);
         assert_eq!((&hi - 1u32).nth_root(n), root);
     }

     #[test]
     fn test_sqrt() {
         check(99u32, 2);
         check(100u32, 2);
         check(120u32, 2);
     }

     #[test]
     fn test_cbrt() {
         check(8u32, 3);
         check(26u32, 3);
     }

     #[test]
     fn test_nth_root() {
         check(0u32, 1);
         check(10u32, 1);
         check(100u32, 4);
     }

     #[test]
     #[should_panic]
     fn test_nth_root_n_is_zero() {
         check(4u32, 0);
     }

     #[test]
     fn test_nth_root_big() {
         let x = BigUint::from(123_456_789_u32);
         let expected = BigUint::from(6u32);

         assert_eq!(x.nth_root(10), expected);
         check(x, 10);
     }

     #[test]
     fn test_nth_root_googol() {
         let googol = BigUint::from(10u32).pow(100u32);

         // perfect divisors of 100
         for &n in &[2, 4, 5, 10, 20, 25, 50, 100] {
             let expected = BigUint::from(10u32).pow(100u32 / n);
             assert_eq!(googol.nth_root(n), expected);
             check(googol.clone(), n);
         }
     }

     #[test]
     fn test_nth_root_twos() {
         const EXP: u32 = 12;
         const LOG2: usize = 1 << EXP;
         let x = BigUint::one() << LOG2;

         // the perfect divisors are just powers of two
         for exp in 1..=EXP {
             let n = 2u32.pow(exp);
             let expected = BigUint::one() << (LOG2 / n as usize);
             assert_eq!(x.nth_root(n), expected);
             check(x.clone(), n);
         }

         // degenerate cases should return quickly
         assert!(x.nth_root(x.bits() as u32).is_one());
         assert!(x.nth_root(i32::MAX as u32).is_one());
         assert!(x.nth_root(u32::MAX).is_one());
     }

     #[test]
     fn test_roots_rand1() {
         // A random input that found regressions
         let s = "575981506858479247661989091587544744717244516135539456183849\
                  986593934723426343633698413178771587697273822147578889823552\
                  182702908597782734558103025298880194023243541613924361007059\
                  353344183590348785832467726433749431093350684849462759540710\
                  026019022227591412417064179299354183441181373862905039254106\
                  4781867";
         let x: BigUint = s.parse().unwrap();

         check(x.clone(), 2);
         check(x.clone(), 3);
         check(x.clone(), 10);
         check(x, 100);
     }
 }

 mod bigint {
     use num_bigint::BigInt;
     use num_traits::Signed;

     fn check(x: i64, n: u32) {
         let big_x = BigInt::from(x);
         let res = big_x.nth_root(n);

         if n == 2 {
             assert_eq!(&res, &big_x.sqrt())
         } else if n == 3 {
             assert_eq!(&res, &big_x.cbrt())
         }

         if big_x.is_negative() {
             assert!(res.pow(n) >= big_x);
             assert!((res - 1u32).pow(n) < big_x);
         } else {
             assert!(res.pow(n) <= big_x);
             assert!((res + 1u32).pow(n) > big_x);
         }
     }

     #[test]
     fn test_nth_root() {
         check(-100, 3);
     }

     #[test]
     #[should_panic]
     fn test_nth_root_x_neg_n_even() {
         check(-100, 4);
     }

     #[test]
     #[should_panic]
     fn test_sqrt_x_neg() {
         check(-4, 2);
     }

     #[test]
     fn test_cbrt() {
         check(8, 3);
         check(-8, 3);
     }
 }
	mod biguint {
	use num_bigint::BigUint;
	use num_traits::{One, Zero};
	use std::{i32, u32};

	fn check<T: Into<BigUint>>(x: T, n: u32) {
	let x: BigUint = x.into();
	let root = x.nth_root(n);
	println!("check {}.nth_root({}) = {}", x, n, root);

	if n == 2 {
	assert_eq!(root, x.sqrt())
	} else if n == 3 {
	assert_eq!(root, x.cbrt())
	}

	let lo = root.pow(n);
	assert!(lo <= x);
	assert_eq!(lo.nth_root(n), root);
	if !lo.is_zero() {
	assert_eq!((&lo - 1u32).nth_root(n), &root - 1u32);
	}

	let hi = (&root + 1u32).pow(n);
	assert!(hi > x);
	assert_eq!(hi.nth_root(n), &root + 1u32);
	assert_eq!((&hi - 1u32).nth_root(n), root);
	}

	#[test]
	fn test_sqrt() {
	check(99u32, 2);
	check(100u32, 2);
	check(120u32, 2);
	}

	#[test]
	fn test_cbrt() {
	check(8u32, 3);
	check(26u32, 3);
	}

	#[test]
	fn test_nth_root() {
	check(0u32, 1);
	check(10u32, 1);
	check(100u32, 4);
	}

	#[test]
	#[should_panic]
	fn test_nth_root_n_is_zero() {
	check(4u32, 0);
	}

	#[test]
	fn test_nth_root_big() {
	let x = BigUint::from(123_456_789_u32);
	let expected = BigUint::from(6u32);

	assert_eq!(x.nth_root(10), expected);
	check(x, 10);
	}

	#[test]
	fn test_nth_root_googol() {
	let googol = BigUint::from(10u32).pow(100u32);

	// perfect divisors of 100
	for &n in &[2, 4, 5, 10, 20, 25, 50, 100] {
	let expected = BigUint::from(10u32).pow(100u32 / n);
	assert_eq!(googol.nth_root(n), expected);
	check(googol.clone(), n);
	}
	}

	#[test]
	fn test_nth_root_twos() {
	const EXP: u32 = 12;
	const LOG2: usize = 1 << EXP;
	let x = BigUint::one() << LOG2;

	// the perfect divisors are just powers of two
	for exp in 1..=EXP {
	let n = 2u32.pow(exp);
	let expected = BigUint::one() << (LOG2 / n as usize);
	assert_eq!(x.nth_root(n), expected);
	check(x.clone(), n);
	}

	// degenerate cases should return quickly
	assert!(x.nth_root(x.bits() as u32).is_one());
	assert!(x.nth_root(i32::MAX as u32).is_one());
	assert!(x.nth_root(u32::MAX).is_one());
	}

	#[test]
	fn test_roots_rand1() {
	// A random input that found regressions
	let s = "575981506858479247661989091587544744717244516135539456183849\
	986593934723426343633698413178771587697273822147578889823552\
	182702908597782734558103025298880194023243541613924361007059\
	353344183590348785832467726433749431093350684849462759540710\
	026019022227591412417064179299354183441181373862905039254106\
	4781867";
	let x: BigUint = s.parse().unwrap();

	check(x.clone(), 2);
	check(x.clone(), 3);
	check(x.clone(), 10);
	check(x, 100);
	}
	}

	mod bigint {
	use num_bigint::BigInt;
	use num_traits::Signed;

	fn check(x: i64, n: u32) {
	let big_x = BigInt::from(x);
	let res = big_x.nth_root(n);

	if n == 2 {
	assert_eq!(&res, &big_x.sqrt())
	} else if n == 3 {
	assert_eq!(&res, &big_x.cbrt())
	}

	if big_x.is_negative() {
	assert!(res.pow(n) >= big_x);
	assert!((res - 1u32).pow(n) < big_x);
	} else {
	assert!(res.pow(n) <= big_x);
	assert!((res + 1u32).pow(n) > big_x);
	}
	}

	#[test]
	fn test_nth_root() {
	check(-100, 3);
	}

	#[test]
	#[should_panic]
	fn test_nth_root_x_neg_n_even() {
	check(-100, 4);
	}

	#[test]
	#[should_panic]
	fn test_sqrt_x_neg() {
	check(-4, 2);
	}

	#[test]
	fn test_cbrt() {
	check(8, 3);
	check(-8, 3);
	}
	}