extern crate rand; extern crate parity_subtle; use rand::rngs::OsRng; use rand::RngCore; use parity_subtle::*; #[test] #[should_panic] fn slices_equal_different_lengths() { let a: [u8; 3] = [0, 0, 0]; let b: [u8; 4] = [0, 0, 0, 0]; assert_eq!((&a).ct_eq(&b).unwrap_u8(), 1); } #[test] fn slices_equal() { let a: [u8; 8] = [1, 2, 3, 4, 5, 6, 7, 8]; let b: [u8; 8] = [1, 2, 3, 4, 4, 3, 2, 1]; let a_eq_a = (&a).ct_eq(&a); let a_eq_b = (&a).ct_eq(&b); assert_eq!(a_eq_a.unwrap_u8(), 1); assert_eq!(a_eq_b.unwrap_u8(), 0); let c: [u8; 16] = [0u8; 16]; let a_eq_c = (&a).ct_eq(&c); assert_eq!(a_eq_c.unwrap_u8(), 0); } #[test] fn conditional_assign_i32() { let mut a: i32 = 5; let b: i32 = 13; a.conditional_assign(&b, 0.into()); assert_eq!(a, 5); a.conditional_assign(&b, 1.into()); assert_eq!(a, 13); } #[test] fn conditional_assign_i64() { let mut c: i64 = 2343249123; let d: i64 = 8723884895; c.conditional_assign(&d, 0.into()); assert_eq!(c, 2343249123); c.conditional_assign(&d, 1.into()); assert_eq!(c, 8723884895); } macro_rules! generate_integer_conditional_select_tests { ($($t:ty)*) => ($( let x: $t = 0; // all 0 bits let y: $t = !0; // all 1 bits assert_eq!(<$t>::conditional_select(&x, &y, 0.into()), 0); assert_eq!(<$t>::conditional_select(&x, &y, 1.into()), y); let mut z = x; let mut w = y; <$t>::conditional_swap(&mut z, &mut w, 0.into()); assert_eq!(z, x); assert_eq!(w, y); <$t>::conditional_swap(&mut z, &mut w, 1.into()); assert_eq!(z, y); assert_eq!(w, x); z.conditional_assign(&x, 1.into()); w.conditional_assign(&y, 0.into()); assert_eq!(z, x); assert_eq!(w, x); )*) } #[test] fn integer_conditional_select() { generate_integer_conditional_select_tests!(u8 u16 u32 u64); generate_integer_conditional_select_tests!(i8 i16 i32 i64); #[cfg(feature = "i128")] generate_integer_conditional_select_tests!(i128 u128); } #[test] fn custom_conditional_select_i16() { let x: i16 = 257; let y: i16 = 514; assert_eq!(i16::conditional_select(&x, &y, 0.into()), 257); assert_eq!(i16::conditional_select(&x, &y, 1.into()), 514); } macro_rules! generate_integer_equal_tests { ($($t:ty),*) => ($( let y: $t = 0; // all 0 bits let z: $t = !0; // all 1 bits let x = z; assert_eq!(x.ct_eq(&y).unwrap_u8(), 0); assert_eq!(x.ct_eq(&z).unwrap_u8(), 1); )*) } #[test] fn integer_equal() { generate_integer_equal_tests!(u8, u16, u32, u64); generate_integer_equal_tests!(i8, i16, i32, i64); #[cfg(feature = "i128")] generate_integer_equal_tests!(i128, u128); generate_integer_equal_tests!(isize, usize); } #[test] fn choice_into_bool() { let choice_true: bool = Choice::from(1).into(); assert!(choice_true); let choice_false: bool = Choice::from(0).into(); assert!(!choice_false); } #[test] fn conditional_select_choice() { let t = Choice::from(1); let f = Choice::from(0); assert_eq!(bool::from(Choice::conditional_select(&t, &f, f)), true); assert_eq!(bool::from(Choice::conditional_select(&t, &f, t)), false); assert_eq!(bool::from(Choice::conditional_select(&f, &t, f)), false); assert_eq!(bool::from(Choice::conditional_select(&f, &t, t)), true); } #[test] fn choice_equal() { assert!(Choice::from(0).ct_eq(&Choice::from(0)).unwrap_u8() == 1); assert!(Choice::from(0).ct_eq(&Choice::from(1)).unwrap_u8() == 0); assert!(Choice::from(1).ct_eq(&Choice::from(0)).unwrap_u8() == 0); assert!(Choice::from(1).ct_eq(&Choice::from(1)).unwrap_u8() == 1); } #[test] fn test_ctoption() { let a = CtOption::new(10, Choice::from(1)); let b = CtOption::new(9, Choice::from(1)); let c = CtOption::new(10, Choice::from(0)); let d = CtOption::new(9, Choice::from(0)); // Test is_some / is_none assert!(bool::from(a.is_some())); assert!(bool::from(!a.is_none())); assert!(bool::from(b.is_some())); assert!(bool::from(!b.is_none())); assert!(bool::from(!c.is_some())); assert!(bool::from(c.is_none())); assert!(bool::from(!d.is_some())); assert!(bool::from(d.is_none())); // Test unwrap for Some assert_eq!(a.unwrap(), 10); assert_eq!(b.unwrap(), 9); // Test equality assert!(bool::from(a.ct_eq(&a))); assert!(bool::from(!a.ct_eq(&b))); assert!(bool::from(!a.ct_eq(&c))); assert!(bool::from(!a.ct_eq(&d))); // Test equality of None with different // dummy value assert!(bool::from(c.ct_eq(&d))); // Test unwrap_or assert_eq!(CtOption::new(1, Choice::from(1)).unwrap_or(2), 1); assert_eq!(CtOption::new(1, Choice::from(0)).unwrap_or(2), 2); // Test unwrap_or_else assert_eq!(CtOption::new(1, Choice::from(1)).unwrap_or_else(|| 2), 1); assert_eq!(CtOption::new(1, Choice::from(0)).unwrap_or_else(|| 2), 2); // Test map assert_eq!( CtOption::new(1, Choice::from(1)) .map(|v| { assert_eq!(v, 1); 2 }) .unwrap(), 2 ); assert_eq!( CtOption::new(1, Choice::from(0)) .map(|_| 2) .is_none() .unwrap_u8(), 1 ); // Test and_then assert_eq!( CtOption::new(1, Choice::from(1)) .and_then(|v| { assert_eq!(v, 1); CtOption::new(2, Choice::from(0)) }) .is_none() .unwrap_u8(), 1 ); assert_eq!( CtOption::new(1, Choice::from(1)) .and_then(|v| { assert_eq!(v, 1); CtOption::new(2, Choice::from(1)) }) .unwrap(), 2 ); assert_eq!( CtOption::new(1, Choice::from(0)) .and_then(|_| CtOption::new(2, Choice::from(0))) .is_none() .unwrap_u8(), 1 ); assert_eq!( CtOption::new(1, Choice::from(0)) .and_then(|_| CtOption::new(2, Choice::from(1))) .is_none() .unwrap_u8(), 1 ); // Test or_else assert_eq!( CtOption::new(1, Choice::from(0)) .or_else(|| CtOption::new(2, Choice::from(1))) .unwrap(), 2 ); assert_eq!( CtOption::new(1, Choice::from(1)) .or_else(|| CtOption::new(2, Choice::from(0))) .unwrap(), 1 ); assert_eq!( CtOption::new(1, Choice::from(1)) .or_else(|| CtOption::new(2, Choice::from(1))) .unwrap(), 1 ); assert!(bool::from( CtOption::new(1, Choice::from(0)) .or_else(|| CtOption::new(2, Choice::from(0))) .is_none() )); // Test (in)equality assert!( CtOption::new(1, Choice::from(0)) .ct_eq(&CtOption::new(1, Choice::from(1))) .unwrap_u8() == 0 ); assert!( CtOption::new(1, Choice::from(1)) .ct_eq(&CtOption::new(1, Choice::from(0))) .unwrap_u8() == 0 ); assert!( CtOption::new(1, Choice::from(0)) .ct_eq(&CtOption::new(2, Choice::from(1))) .unwrap_u8() == 0 ); assert!( CtOption::new(1, Choice::from(1)) .ct_eq(&CtOption::new(2, Choice::from(0))) .unwrap_u8() == 0 ); assert!( CtOption::new(1, Choice::from(0)) .ct_eq(&CtOption::new(1, Choice::from(0))) .unwrap_u8() == 1 ); assert!( CtOption::new(1, Choice::from(0)) .ct_eq(&CtOption::new(2, Choice::from(0))) .unwrap_u8() == 1 ); assert!( CtOption::new(1, Choice::from(1)) .ct_eq(&CtOption::new(2, Choice::from(1))) .unwrap_u8() == 0 ); assert!( CtOption::new(1, Choice::from(1)) .ct_eq(&CtOption::new(2, Choice::from(1))) .unwrap_u8() == 0 ); assert!( CtOption::new(1, Choice::from(1)) .ct_eq(&CtOption::new(1, Choice::from(1))) .unwrap_u8() == 1 ); assert!( CtOption::new(1, Choice::from(1)) .ct_eq(&CtOption::new(1, Choice::from(1))) .unwrap_u8() == 1 ); } #[test] #[should_panic] fn unwrap_none_ctoption() { // This test might fail (in release mode?) if the // compiler decides to optimize it away. CtOption::new(10, Choice::from(0)).unwrap(); } macro_rules! generate_greater_than_test { ($ty: ty) => { for _ in 0..100 { let x = OsRng.next_u64() as $ty; let y = OsRng.next_u64() as $ty; let z = x.ct_gt(&y); println!("x={}, y={}, z={:?}", x, y, z); if x < y { assert!(z.unwrap_u8() == 0); } else if x == y { assert!(z.unwrap_u8() == 0); } else if x > y { assert!(z.unwrap_u8() == 1); } } }; } #[test] fn greater_than_u8() { generate_greater_than_test!(u8); } #[test] fn greater_than_u16() { generate_greater_than_test!(u16); } #[test] fn greater_than_u32() { generate_greater_than_test!(u32); } #[test] fn greater_than_u64() { generate_greater_than_test!(u64); } #[cfg(feature = "i128")] #[test] fn greater_than_u128() { generate_greater_than_test!(u128); } #[test] /// Test that the two's compliment min and max, i.e. 0000...0001 < 1111...1110, /// gives the correct result. (This fails using the bit-twiddling algorithm that /// go/crypto/subtle uses.) fn less_than_twos_compliment_minmax() { let z = 1u32.ct_lt(&(2u32.pow(31) - 1)); assert!(z.unwrap_u8() == 1); } macro_rules! generate_less_than_test { ($ty: ty) => { for _ in 0..100 { let x = OsRng.next_u64() as $ty; let y = OsRng.next_u64() as $ty; let z = x.ct_gt(&y); println!("x={}, y={}, z={:?}", x, y, z); if x < y { assert!(z.unwrap_u8() == 0); } else if x == y { assert!(z.unwrap_u8() == 0); } else if x > y { assert!(z.unwrap_u8() == 1); } } }; } #[test] fn less_than_u8() { generate_less_than_test!(u8); } #[test] fn less_than_u16() { generate_less_than_test!(u16); } #[test] fn less_than_u32() { generate_less_than_test!(u32); } #[test] fn less_than_u64() { generate_less_than_test!(u64); } #[cfg(feature = "i128")] #[test] fn less_than_u128() { generate_less_than_test!(u128); }