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use crate::natural::Natural;
use malachite_base::num::arithmetic::traits::{
ModPowerOf2, ModPowerOf2Assign, ModPowerOf2Shl, ModPowerOf2ShlAssign, UnsignedAbs,
};
use malachite_base::num::basic::signeds::PrimitiveSigned;
use malachite_base::num::basic::traits::Zero;
use malachite_base::num::basic::unsigneds::PrimitiveUnsigned;
use malachite_base::num::conversion::traits::ExactFrom;
use std::ops::{Shr, ShrAssign};
fn mod_power_of_2_shl_unsigned_nz<T: PrimitiveUnsigned>(x: &Natural, bits: T, pow: u64) -> Natural
where
u64: ExactFrom<T>,
{
let bits = u64::exact_from(bits);
if bits >= pow {
Natural::ZERO
} else {
x.mod_power_of_2(pow - bits) << bits
}
}
fn mod_power_of_2_shl_assign_unsigned_nz<T: PrimitiveUnsigned>(x: &mut Natural, bits: T, pow: u64)
where
u64: ExactFrom<T>,
{
let bits = u64::exact_from(bits);
if bits >= pow {
*x = Natural::ZERO;
} else {
x.mod_power_of_2_assign(pow - bits);
*x <<= bits;
}
}
macro_rules! impl_mod_power_of_2_shl_unsigned {
($t:ident) => {
impl ModPowerOf2Shl<$t> for Natural {
type Output = Natural;
/// Left-shifts a [`Natural`] (multiplies it by a power of 2) modulo $2^k$. Assumes the
/// input is already reduced modulo $2^k$. The [`Natural`] is taken by value.
///
/// $f(x, n, k) = y$, where $x, y < 2^k$ and $2^nx \equiv y \mod 2^k$.
///
/// # Worst-case complexity
/// $T(n) = O(n)$
///
/// $M(n) = O(n)$
///
/// where $T$ is time, $M$ is additional memory, and $n$ is `pow`.
///
/// # Examples
/// See [here](super::mod_power_of_2_shl#mod_power_of_2_shl).
#[inline]
fn mod_power_of_2_shl(mut self, bits: $t, pow: u64) -> Natural {
self.mod_power_of_2_shl_assign(bits, pow);
self
}
}
impl<'a> ModPowerOf2Shl<$t> for &'a Natural {
type Output = Natural;
/// Left-shifts a [`Natural`] (multiplies it by a power of 2) modulo $2^k$. Assumes the
/// input is already reduced modulo $2^k$. The [`Natural`] is taken by reference.
///
/// $f(x, n, k) = y$, where $x, y < 2^k$ and $2^nx \equiv y \mod 2^k$.
///
/// # Worst-case complexity
/// $T(n) = O(n)$
///
/// $M(n) = O(n)$
///
/// where $T$ is time, $M$ is additional memory, and $n$ is `pow`.
///
/// # Examples
/// See [here](super::mod_power_of_2_shl#mod_power_of_2_shl).
#[inline]
fn mod_power_of_2_shl(self, bits: $t, pow: u64) -> Natural {
mod_power_of_2_shl_unsigned_nz(self, bits, pow)
}
}
impl ModPowerOf2ShlAssign<$t> for Natural {
/// Left-shifts a [`Natural`] (multiplies it by a power of 2) modulo $2^k$, in place.
/// Assumes the input is already reduced modulo $2^k$.
///
/// $x \gets y$, where $x, y < 2^k$ and $2^nx \equiv y \mod 2^k$.
///
/// # Worst-case complexity
/// $T(n) = O(n)$
///
/// $M(n) = O(n)$
///
/// where $T$ is time, $M$ is additional memory, and $n$ is `pow`.
///
/// # Examples
/// See [here](super::mod_power_of_2_shl#mod_power_of_2_shl_assign).
#[inline]
fn mod_power_of_2_shl_assign(&mut self, bits: $t, pow: u64) {
mod_power_of_2_shl_assign_unsigned_nz(self, bits, pow);
}
}
};
}
apply_to_unsigneds!(impl_mod_power_of_2_shl_unsigned);
fn mod_power_of_2_shl_signed_nz<'a, U, S: PrimitiveSigned + UnsignedAbs<Output = U>>(
x: &'a Natural,
bits: S,
pow: u64,
) -> Natural
where
&'a Natural: ModPowerOf2Shl<U, Output = Natural> + Shr<U, Output = Natural>,
{
if bits >= S::ZERO {
x.mod_power_of_2_shl(bits.unsigned_abs(), pow)
} else {
x >> bits.unsigned_abs()
}
}
fn mod_power_of_2_shl_assign_signed_nz<U, S: PrimitiveSigned + UnsignedAbs<Output = U>>(
x: &mut Natural,
bits: S,
pow: u64,
) where
Natural: ModPowerOf2ShlAssign<U> + ShrAssign<U>,
{
if bits >= S::ZERO {
x.mod_power_of_2_shl_assign(bits.unsigned_abs(), pow);
} else {
*x >>= bits.unsigned_abs();
}
}
macro_rules! impl_mod_power_of_2_shl_signed {
($t:ident) => {
impl ModPowerOf2Shl<$t> for Natural {
type Output = Natural;
/// Left-shifts a [`Natural`] (multiplies it by a power of 2) modulo $2^k$. Assumes the
/// input is already reduced modulo $2^k$. The [`Natural`] is taken by value.
///
/// $f(x, n, k) = y$, where $x, y < 2^k$ and $\lfloor 2^nx \rfloor \equiv y \mod 2^k$.
///
/// # Worst-case complexity
/// $T(n) = O(n)$
///
/// $M(n) = O(n)$
///
/// where $T$ is time, $M$ is additional memory, and $n$ is `pow`.
///
/// # Examples
/// See [here](super::mod_power_of_2_shl#mod_power_of_2_shl).
#[inline]
fn mod_power_of_2_shl(mut self, bits: $t, pow: u64) -> Natural {
self.mod_power_of_2_shl_assign(bits, pow);
self
}
}
impl<'a> ModPowerOf2Shl<$t> for &'a Natural {
type Output = Natural;
/// Left-shifts a [`Natural`] (multiplies it by a power of 2) modulo $2^k$. Assumes the
/// input is already reduced modulo $2^k$. The [`Natural`] is taken by reference.
///
/// $f(x, n, k) = y$, where $x, y < 2^k$ and $\lfloor 2^nx \rfloor \equiv y \mod 2^k$.
///
/// # Worst-case complexity
/// $T(n) = O(n)$
///
/// $M(n) = O(n)$
///
/// where $T$ is time, $M$ is additional memory, and $n$ is `pow`.
///
/// # Examples
/// See [here](super::mod_power_of_2_shl#mod_power_of_2_shl).
#[inline]
fn mod_power_of_2_shl(self, bits: $t, pow: u64) -> Natural {
mod_power_of_2_shl_signed_nz(self, bits, pow)
}
}
impl ModPowerOf2ShlAssign<$t> for Natural {
/// Left-shifts a [`Natural`] (multiplies it by a power of 2) modulo $2^k$, in place.
/// Assumes the input is already reduced modulo $2^k$.
///
/// $x \gets y$, where $x, y < 2^k$ and $\lfloor 2^nx \rfloor \equiv y \mod 2^k$.
///
/// # Worst-case complexity
/// $T(n) = O(n)$
///
/// $M(n) = O(n)$
///
/// where $T$ is time, $M$ is additional memory, and $n$ is `pow`.
///
/// # Examples
/// See [here](super::mod_power_of_2_shl#mod_power_of_2_shl_assign).
#[inline]
fn mod_power_of_2_shl_assign(&mut self, bits: $t, pow: u64) {
mod_power_of_2_shl_assign_signed_nz(self, bits, pow)
}
}
};
}
apply_to_signeds!(impl_mod_power_of_2_shl_signed);