src/ops/euclid.rs - platform/external/rust/crates/num-traits - Git at Google

 use core::ops::{Div, Rem};

 pub trait Euclid: Sized + Div<Self, Output = Self> + Rem<Self, Output = Self> {
     /// Calculates Euclidean division, the matching method for `rem_euclid`.
     ///
     /// This computes the integer `n` such that
     /// `self = n * v + self.rem_euclid(v)`.
     /// In other words, the result is `self / v` rounded to the integer `n`
     /// such that `self >= n * v`.
     ///
     /// # Examples
     ///
     /// ```
     /// use num_traits::Euclid;
     ///
     /// let a: i32 = 7;
     /// let b: i32 = 4;
     /// assert_eq!(Euclid::div_euclid(&a, &b), 1); // 7 > 4 * 1
     /// assert_eq!(Euclid::div_euclid(&-a, &b), -2); // -7 >= 4 * -2
     /// assert_eq!(Euclid::div_euclid(&a, &-b), -1); // 7 >= -4 * -1
     /// assert_eq!(Euclid::div_euclid(&-a, &-b), 2); // -7 >= -4 * 2
     /// ```
     fn div_euclid(&self, v: &Self) -> Self;

     /// Calculates the least nonnegative remainder of `self (mod v)`.
     ///
     /// In particular, the return value `r` satisfies `0.0 <= r < v.abs()` in
     /// most cases. However, due to a floating point round-off error it can
     /// result in `r == v.abs()`, violating the mathematical definition, if
     /// `self` is much smaller than `v.abs()` in magnitude and `self < 0.0`.
     /// This result is not an element of the function's codomain, but it is the
     /// closest floating point number in the real numbers and thus fulfills the
     /// property `self == self.div_euclid(v) * v + self.rem_euclid(v)`
     /// approximatively.
     ///
     /// # Examples
     ///
     /// ```
     /// use num_traits::Euclid;
     ///
     /// let a: i32 = 7;
     /// let b: i32 = 4;
     /// assert_eq!(Euclid::rem_euclid(&a, &b), 3);
     /// assert_eq!(Euclid::rem_euclid(&-a, &b), 1);
     /// assert_eq!(Euclid::rem_euclid(&a, &-b), 3);
     /// assert_eq!(Euclid::rem_euclid(&-a, &-b), 1);
     /// ```
     fn rem_euclid(&self, v: &Self) -> Self;
 }

 macro_rules! euclid_forward_impl {
     ($($t:ty)*) => {$(
         #[cfg(has_div_euclid)]
         impl Euclid for $t {
             #[inline]
             fn div_euclid(&self, v: &$t) -> Self {
                 <$t>::div_euclid(*self, *v)
             }

             #[inline]
             fn rem_euclid(&self, v: &$t) -> Self {
                 <$t>::rem_euclid(*self, *v)
             }
         }
     )*}
 }

 macro_rules! euclid_int_impl {
     ($($t:ty)*) => {$(
         euclid_forward_impl!($t);

         #[cfg(not(has_div_euclid))]
         impl Euclid for $t {
             #[inline]
             fn div_euclid(&self, v: &$t) -> Self {
                 let q = self / v;
                 if self % v < 0 {
                     return if *v > 0 { q - 1 } else { q + 1 }
                 }
                 q
             }

             #[inline]
             fn rem_euclid(&self, v: &$t) -> Self {
                 let r = self % v;
                 if r < 0 {
                     if *v < 0 {
                         r - v
                     } else {
                         r + v
                     }
                 } else {
                     r
                 }
             }
         }
     )*}
 }

 macro_rules! euclid_uint_impl {
     ($($t:ty)*) => {$(
         euclid_forward_impl!($t);

         #[cfg(not(has_div_euclid))]
         impl Euclid for $t {
             #[inline]
             fn div_euclid(&self, v: &$t) -> Self {
                 self / v
             }

             #[inline]
             fn rem_euclid(&self, v: &$t) -> Self {
                 self % v
             }
         }
     )*}
 }

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

 #[cfg(all(has_div_euclid, feature = "std"))]
 euclid_forward_impl!(f32 f64);

 #[cfg(not(all(has_div_euclid, feature = "std")))]
 impl Euclid for f32 {
     #[inline]
     fn div_euclid(&self, v: &f32) -> f32 {
         let q = <f32 as ::float::FloatCore>::trunc(self / v);
         if self % v < 0.0 {
             return if *v > 0.0 { q - 1.0 } else { q + 1.0 };
         }
         q
     }

     #[inline]
     fn rem_euclid(&self, v: &f32) -> f32 {
         let r = self % v;
         if r < 0.0 {
             r + <f32 as ::float::FloatCore>::abs(*v)
         } else {
             r
         }
     }
 }

 #[cfg(not(all(has_div_euclid, feature = "std")))]
 impl Euclid for f64 {
     #[inline]
     fn div_euclid(&self, v: &f64) -> f64 {
         let q = <f64 as ::float::FloatCore>::trunc(self / v);
         if self % v < 0.0 {
             return if *v > 0.0 { q - 1.0 } else { q + 1.0 };
         }
         q
     }

     #[inline]
     fn rem_euclid(&self, v: &f64) -> f64 {
         let r = self % v;
         if r < 0.0 {
             r + <f64 as ::float::FloatCore>::abs(*v)
         } else {
             r
         }
     }
 }

 pub trait CheckedEuclid: Euclid {
     /// Performs euclid division that returns `None` instead of panicking on division by zero
     /// and instead of wrapping around on underflow and overflow.
     fn checked_div_euclid(&self, v: &Self) -> Option<Self>;

     /// Finds the euclid remainder of dividing two numbers, checking for underflow, overflow and
     /// division by zero. If any of that happens, `None` is returned.
     fn checked_rem_euclid(&self, v: &Self) -> Option<Self>;
 }

 macro_rules! checked_euclid_forward_impl {
     ($($t:ty)*) => {$(
         #[cfg(has_div_euclid)]
         impl CheckedEuclid for $t {
             #[inline]
             fn checked_div_euclid(&self, v: &$t) -> Option<Self> {
                 <$t>::checked_div_euclid(*self, *v)
             }

             #[inline]
             fn checked_rem_euclid(&self, v: &$t) -> Option<Self> {
                 <$t>::checked_rem_euclid(*self, *v)
             }
         }
     )*}
 }

 macro_rules! checked_euclid_int_impl {
     ($($t:ty)*) => {$(
         checked_euclid_forward_impl!($t);

         #[cfg(not(has_div_euclid))]
         impl CheckedEuclid for $t {
             #[inline]
             fn checked_div_euclid(&self, v: &$t) -> Option<$t> {
                 if *v == 0 || (*self == Self::min_value() && *v == -1) {
                     None
                 } else {
                     Some(Euclid::div_euclid(self, v))
                 }
             }

             #[inline]
             fn checked_rem_euclid(&self, v: &$t) -> Option<$t> {
                 if *v == 0 || (*self == Self::min_value() && *v == -1) {
                     None
                 } else {
                     Some(Euclid::rem_euclid(self, v))
                 }
             }
         }
     )*}
 }

 macro_rules! checked_euclid_uint_impl {
     ($($t:ty)*) => {$(
         checked_euclid_forward_impl!($t);

         #[cfg(not(has_div_euclid))]
         impl CheckedEuclid for $t {
             #[inline]
             fn checked_div_euclid(&self, v: &$t) -> Option<$t> {
                 if *v == 0 {
                     None
                 } else {
                     Some(Euclid::div_euclid(self, v))
                 }
             }

             #[inline]
             fn checked_rem_euclid(&self, v: &$t) -> Option<$t> {
                 if *v == 0 {
                     None
                 } else {
                     Some(Euclid::rem_euclid(self, v))
                 }
             }
         }
     )*}
 }

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

 #[cfg(test)]
 mod tests {
     use super::*;

     #[test]
     fn euclid_unsigned() {
         macro_rules! test_euclid {
             ($($t:ident)+) => {
                 $(
                     {
                         let x: $t = 10;
                         let y: $t = 3;
                         assert_eq!(Euclid::div_euclid(&x, &y), 3);
                         assert_eq!(Euclid::rem_euclid(&x, &y), 1);
                     }
                 )+
             };
         }

         test_euclid!(usize u8 u16 u32 u64);
     }

     #[test]
     fn euclid_signed() {
         macro_rules! test_euclid {
             ($($t:ident)+) => {
                 $(
                     {
                         let x: $t = 10;
                         let y: $t = -3;
                         assert_eq!(Euclid::div_euclid(&x, &y), -3);
                         assert_eq!(Euclid::div_euclid(&-x, &y), 4);
                         assert_eq!(Euclid::rem_euclid(&x, &y), 1);
                         assert_eq!(Euclid::rem_euclid(&-x, &y), 2);
                         let x: $t = $t::min_value() + 1;
                         let y: $t = -1;
                         assert_eq!(Euclid::div_euclid(&x, &y), $t::max_value());
                     }
                 )+
             };
         }

         test_euclid!(isize i8 i16 i32 i64);
     }

     #[test]
     fn euclid_float() {
         macro_rules! test_euclid {
             ($($t:ident)+) => {
                 $(
                     {
                         let x: $t = 12.1;
                         let y: $t = 3.2;
                         assert!(Euclid::div_euclid(&x, &y) * y + Euclid::rem_euclid(&x, &y) - x
                         <= 46.4 * <$t as ::float::FloatCore>::epsilon());
                         assert!(Euclid::div_euclid(&x, &-y) * -y + Euclid::rem_euclid(&x, &-y) - x
                         <= 46.4 * <$t as ::float::FloatCore>::epsilon());
                         assert!(Euclid::div_euclid(&-x, &y) * y + Euclid::rem_euclid(&-x, &y) + x
                         <= 46.4 * <$t as ::float::FloatCore>::epsilon());
                         assert!(Euclid::div_euclid(&-x, &-y) * -y + Euclid::rem_euclid(&-x, &-y) + x
                         <= 46.4 * <$t as ::float::FloatCore>::epsilon());
                     }
                 )+
             };
         }

         test_euclid!(f32 f64);
     }

     #[test]
     fn euclid_checked() {
         macro_rules! test_euclid_checked {
             ($($t:ident)+) => {
                 $(
                     {
                         assert_eq!(CheckedEuclid::checked_div_euclid(&$t::min_value(), &-1), None);
                         assert_eq!(CheckedEuclid::checked_rem_euclid(&$t::min_value(), &-1), None);
                         assert_eq!(CheckedEuclid::checked_div_euclid(&1, &0), None);
                         assert_eq!(CheckedEuclid::checked_rem_euclid(&1, &0), None);
                     }
                 )+
             };
         }

         test_euclid_checked!(isize i8 i16 i32 i64);
     }
 }
	use core::ops::{Div, Rem};

	pub trait Euclid: Sized + Div<Self, Output = Self> + Rem<Self, Output = Self> {
	/// Calculates Euclidean division, the matching method for `rem_euclid`.
	///
	/// This computes the integer `n` such that
	/// `self = n * v + self.rem_euclid(v)`.
	/// In other words, the result is `self / v` rounded to the integer `n`
	/// such that `self >= n * v`.
	///
	/// # Examples
	///
	/// ```
	/// use num_traits::Euclid;
	///
	/// let a: i32 = 7;
	/// let b: i32 = 4;
	/// assert_eq!(Euclid::div_euclid(&a, &b), 1); // 7 > 4 * 1
	/// assert_eq!(Euclid::div_euclid(&-a, &b), -2); // -7 >= 4 * -2
	/// assert_eq!(Euclid::div_euclid(&a, &-b), -1); // 7 >= -4 * -1
	/// assert_eq!(Euclid::div_euclid(&-a, &-b), 2); // -7 >= -4 * 2
	/// ```
	fn div_euclid(&self, v: &Self) -> Self;

	/// Calculates the least nonnegative remainder of `self (mod v)`.
	///
	/// In particular, the return value `r` satisfies `0.0 <= r < v.abs()` in
	/// most cases. However, due to a floating point round-off error it can
	/// result in `r == v.abs()`, violating the mathematical definition, if
	/// `self` is much smaller than `v.abs()` in magnitude and `self < 0.0`.
	/// This result is not an element of the function's codomain, but it is the
	/// closest floating point number in the real numbers and thus fulfills the
	/// property `self == self.div_euclid(v) * v + self.rem_euclid(v)`
	/// approximatively.
	///
	/// # Examples
	///
	/// ```
	/// use num_traits::Euclid;
	///
	/// let a: i32 = 7;
	/// let b: i32 = 4;
	/// assert_eq!(Euclid::rem_euclid(&a, &b), 3);
	/// assert_eq!(Euclid::rem_euclid(&-a, &b), 1);
	/// assert_eq!(Euclid::rem_euclid(&a, &-b), 3);
	/// assert_eq!(Euclid::rem_euclid(&-a, &-b), 1);
	/// ```
	fn rem_euclid(&self, v: &Self) -> Self;
	}

	macro_rules! euclid_forward_impl {
	($($t:ty)*) => {$(
	#[cfg(has_div_euclid)]
	impl Euclid for $t {
	#[inline]
	fn div_euclid(&self, v: &$t) -> Self {
	<$t>::div_euclid(self, v)
	}

	#[inline]
	fn rem_euclid(&self, v: &$t) -> Self {
	<$t>::rem_euclid(self, v)
	}
	}
	)*}
	}

	macro_rules! euclid_int_impl {
	($($t:ty)*) => {$(
	euclid_forward_impl!($t);

	#[cfg(not(has_div_euclid))]
	impl Euclid for $t {
	#[inline]
	fn div_euclid(&self, v: &$t) -> Self {
	let q = self / v;
	if self % v < 0 {
	return if *v > 0 { q - 1 } else { q + 1 }
	}
	q
	}

	#[inline]
	fn rem_euclid(&self, v: &$t) -> Self {
	let r = self % v;
	if r < 0 {
	if *v < 0 {
	r - v
	} else {
	r + v
	}
	} else {
	r
	}
	}
	}
	)*}
	}

	macro_rules! euclid_uint_impl {
	($($t:ty)*) => {$(
	euclid_forward_impl!($t);

	#[cfg(not(has_div_euclid))]
	impl Euclid for $t {
	#[inline]
	fn div_euclid(&self, v: &$t) -> Self {
	self / v
	}

	#[inline]
	fn rem_euclid(&self, v: &$t) -> Self {
	self % v
	}
	}
	)*}
	}

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

	#[cfg(all(has_div_euclid, feature = "std"))]
	euclid_forward_impl!(f32 f64);

	#[cfg(not(all(has_div_euclid, feature = "std")))]
	impl Euclid for f32 {
	#[inline]
	fn div_euclid(&self, v: &f32) -> f32 {
	let q = <f32 as ::float::FloatCore>::trunc(self / v);
	if self % v < 0.0 {
	return if *v > 0.0 { q - 1.0 } else { q + 1.0 };
	}
	q
	}

	#[inline]
	fn rem_euclid(&self, v: &f32) -> f32 {
	let r = self % v;
	if r < 0.0 {
	r + <f32 as ::float::FloatCore>::abs(*v)
	} else {
	r
	}
	}
	}

	#[cfg(not(all(has_div_euclid, feature = "std")))]
	impl Euclid for f64 {
	#[inline]
	fn div_euclid(&self, v: &f64) -> f64 {
	let q = <f64 as ::float::FloatCore>::trunc(self / v);
	if self % v < 0.0 {
	return if *v > 0.0 { q - 1.0 } else { q + 1.0 };
	}
	q
	}

	#[inline]
	fn rem_euclid(&self, v: &f64) -> f64 {
	let r = self % v;
	if r < 0.0 {
	r + <f64 as ::float::FloatCore>::abs(*v)
	} else {
	r
	}
	}
	}

	pub trait CheckedEuclid: Euclid {
	/// Performs euclid division that returns `None` instead of panicking on division by zero
	/// and instead of wrapping around on underflow and overflow.
	fn checked_div_euclid(&self, v: &Self) -> Option<Self>;

	/// Finds the euclid remainder of dividing two numbers, checking for underflow, overflow and
	/// division by zero. If any of that happens, `None` is returned.
	fn checked_rem_euclid(&self, v: &Self) -> Option<Self>;
	}

	macro_rules! checked_euclid_forward_impl {
	($($t:ty)*) => {$(
	#[cfg(has_div_euclid)]
	impl CheckedEuclid for $t {
	#[inline]
	fn checked_div_euclid(&self, v: &$t) -> Option<Self> {
	<$t>::checked_div_euclid(self, v)
	}

	#[inline]
	fn checked_rem_euclid(&self, v: &$t) -> Option<Self> {
	<$t>::checked_rem_euclid(self, v)
	}
	}
	)*}
	}

	macro_rules! checked_euclid_int_impl {
	($($t:ty)*) => {$(
	checked_euclid_forward_impl!($t);

	#[cfg(not(has_div_euclid))]
	impl CheckedEuclid for $t {
	#[inline]
	fn checked_div_euclid(&self, v: &$t) -> Option<$t> {
	if v == 0 \|\| (self == Self::min_value() && *v == -1) {
	None
	} else {
	Some(Euclid::div_euclid(self, v))
	}
	}

	#[inline]
	fn checked_rem_euclid(&self, v: &$t) -> Option<$t> {
	if v == 0 \|\| (self == Self::min_value() && *v == -1) {
	None
	} else {
	Some(Euclid::rem_euclid(self, v))
	}
	}
	}
	)*}
	}

	macro_rules! checked_euclid_uint_impl {
	($($t:ty)*) => {$(
	checked_euclid_forward_impl!($t);

	#[cfg(not(has_div_euclid))]
	impl CheckedEuclid for $t {
	#[inline]
	fn checked_div_euclid(&self, v: &$t) -> Option<$t> {
	if *v == 0 {
	None
	} else {
	Some(Euclid::div_euclid(self, v))
	}
	}

	#[inline]
	fn checked_rem_euclid(&self, v: &$t) -> Option<$t> {
	if *v == 0 {
	None
	} else {
	Some(Euclid::rem_euclid(self, v))
	}
	}
	}
	)*}
	}

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

	#[cfg(test)]
	mod tests {
	use super::*;

	#[test]
	fn euclid_unsigned() {
	macro_rules! test_euclid {
	($($t:ident)+) => {
	$(
	{
	let x: $t = 10;
	let y: $t = 3;
	assert_eq!(Euclid::div_euclid(&x, &y), 3);
	assert_eq!(Euclid::rem_euclid(&x, &y), 1);
	}
	)+
	};
	}

	test_euclid!(usize u8 u16 u32 u64);
	}

	#[test]
	fn euclid_signed() {
	macro_rules! test_euclid {
	($($t:ident)+) => {
	$(
	{
	let x: $t = 10;
	let y: $t = -3;
	assert_eq!(Euclid::div_euclid(&x, &y), -3);
	assert_eq!(Euclid::div_euclid(&-x, &y), 4);
	assert_eq!(Euclid::rem_euclid(&x, &y), 1);
	assert_eq!(Euclid::rem_euclid(&-x, &y), 2);
	let x: $t = $t::min_value() + 1;
	let y: $t = -1;
	assert_eq!(Euclid::div_euclid(&x, &y), $t::max_value());
	}
	)+
	};
	}

	test_euclid!(isize i8 i16 i32 i64);
	}

	#[test]
	fn euclid_float() {
	macro_rules! test_euclid {
	($($t:ident)+) => {
	$(
	{
	let x: $t = 12.1;
	let y: $t = 3.2;
	assert!(Euclid::div_euclid(&x, &y) * y + Euclid::rem_euclid(&x, &y) - x
	<= 46.4 * <$t as ::float::FloatCore>::epsilon());
	assert!(Euclid::div_euclid(&x, &-y) * -y + Euclid::rem_euclid(&x, &-y) - x
	<= 46.4 * <$t as ::float::FloatCore>::epsilon());
	assert!(Euclid::div_euclid(&-x, &y) * y + Euclid::rem_euclid(&-x, &y) + x
	<= 46.4 * <$t as ::float::FloatCore>::epsilon());
	assert!(Euclid::div_euclid(&-x, &-y) * -y + Euclid::rem_euclid(&-x, &-y) + x
	<= 46.4 * <$t as ::float::FloatCore>::epsilon());
	}
	)+
	};
	}

	test_euclid!(f32 f64);
	}

	#[test]
	fn euclid_checked() {
	macro_rules! test_euclid_checked {
	($($t:ident)+) => {
	$(
	{
	assert_eq!(CheckedEuclid::checked_div_euclid(&$t::min_value(), &-1), None);
	assert_eq!(CheckedEuclid::checked_rem_euclid(&$t::min_value(), &-1), None);
	assert_eq!(CheckedEuclid::checked_div_euclid(&1, &0), None);
	assert_eq!(CheckedEuclid::checked_rem_euclid(&1, &0), None);
	}
	)+
	};
	}

	test_euclid_checked!(isize i8 i16 i32 i64);
	}
	}