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// `Add`/`Sub` ops may flip from `BigInt` to its `BigUint` magnitude
#![allow(clippy::suspicious_arithmetic_impl)]
use alloc::string::String;
use alloc::vec::Vec;
use core::cmp::Ordering::{self, Equal};
use core::default::Default;
use core::fmt;
use core::hash;
use core::ops::{Neg, Not};
use core::str;
use num_integer::{Integer, Roots};
use num_traits::{ConstZero, Num, One, Pow, Signed, Zero};
use self::Sign::{Minus, NoSign, Plus};
use crate::big_digit::BigDigit;
use crate::biguint::to_str_radix_reversed;
use crate::biguint::{BigUint, IntDigits, U32Digits, U64Digits};
mod addition;
mod division;
mod multiplication;
mod subtraction;
mod arbitrary;
mod bits;
mod convert;
mod power;
mod serde;
mod shift;
/// A `Sign` is a [`BigInt`]'s composing element.
#[derive(PartialEq, PartialOrd, Eq, Ord, Copy, Clone, Debug, Hash)]
pub enum Sign {
Minus,
NoSign,
Plus,
}
impl Neg for Sign {
type Output = Sign;
/// Negate `Sign` value.
#[inline]
fn neg(self) -> Sign {
match self {
Minus => Plus,
NoSign => NoSign,
Plus => Minus,
}
}
}
/// A big signed integer type.
pub struct BigInt {
sign: Sign,
data: BigUint,
}
// Note: derived `Clone` doesn't specialize `clone_from`,
// but we want to keep the allocation in `data`.
impl Clone for BigInt {
#[inline]
fn clone(&self) -> Self {
BigInt {
sign: self.sign,
data: self.data.clone(),
}
}
#[inline]
fn clone_from(&mut self, other: &Self) {
self.sign = other.sign;
self.data.clone_from(&other.data);
}
}
impl hash::Hash for BigInt {
#[inline]
fn hash<H: hash::Hasher>(&self, state: &mut H) {
debug_assert!((self.sign != NoSign) ^ self.data.is_zero());
self.sign.hash(state);
if self.sign != NoSign {
self.data.hash(state);
}
}
}
impl PartialEq for BigInt {
#[inline]
fn eq(&self, other: &BigInt) -> bool {
debug_assert!((self.sign != NoSign) ^ self.data.is_zero());
debug_assert!((other.sign != NoSign) ^ other.data.is_zero());
self.sign == other.sign && (self.sign == NoSign || self.data == other.data)
}
}
impl Eq for BigInt {}
impl PartialOrd for BigInt {
#[inline]
fn partial_cmp(&self, other: &BigInt) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for BigInt {
#[inline]
fn cmp(&self, other: &BigInt) -> Ordering {
debug_assert!((self.sign != NoSign) ^ self.data.is_zero());
debug_assert!((other.sign != NoSign) ^ other.data.is_zero());
let scmp = self.sign.cmp(&other.sign);
if scmp != Equal {
return scmp;
}
match self.sign {
NoSign => Equal,
Plus => self.data.cmp(&other.data),
Minus => other.data.cmp(&self.data),
}
}
}
impl Default for BigInt {
#[inline]
fn default() -> BigInt {
Self::ZERO
}
}
impl fmt::Debug for BigInt {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Display::fmt(self, f)
}
}
impl fmt::Display for BigInt {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.pad_integral(!self.is_negative(), "", &self.data.to_str_radix(10))
}
}
impl fmt::Binary for BigInt {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.pad_integral(!self.is_negative(), "0b", &self.data.to_str_radix(2))
}
}
impl fmt::Octal for BigInt {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.pad_integral(!self.is_negative(), "0o", &self.data.to_str_radix(8))
}
}
impl fmt::LowerHex for BigInt {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.pad_integral(!self.is_negative(), "0x", &self.data.to_str_radix(16))
}
}
impl fmt::UpperHex for BigInt {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
let mut s = self.data.to_str_radix(16);
s.make_ascii_uppercase();
f.pad_integral(!self.is_negative(), "0x", &s)
}
}
// !-2 = !...f fe = ...0 01 = +1
// !-1 = !...f ff = ...0 00 = 0
// ! 0 = !...0 00 = ...f ff = -1
// !+1 = !...0 01 = ...f fe = -2
impl Not for BigInt {
type Output = BigInt;
fn not(mut self) -> BigInt {
match self.sign {
NoSign | Plus => {
self.data += 1u32;
self.sign = Minus;
}
Minus => {
self.data -= 1u32;
self.sign = if self.data.is_zero() { NoSign } else { Plus };
}
}
self
}
}
impl Not for &BigInt {
type Output = BigInt;
fn not(self) -> BigInt {
match self.sign {
NoSign => -BigInt::one(),
Plus => -BigInt::from(&self.data + 1u32),
Minus => BigInt::from(&self.data - 1u32),
}
}
}
impl Zero for BigInt {
#[inline]
fn zero() -> BigInt {
Self::ZERO
}
#[inline]
fn set_zero(&mut self) {
self.data.set_zero();
self.sign = NoSign;
}
#[inline]
fn is_zero(&self) -> bool {
self.sign == NoSign
}
}
impl ConstZero for BigInt {
// forward to the inherent const
const ZERO: Self = Self::ZERO;
}
impl One for BigInt {
#[inline]
fn one() -> BigInt {
BigInt {
sign: Plus,
data: BigUint::one(),
}
}
#[inline]
fn set_one(&mut self) {
self.data.set_one();
self.sign = Plus;
}
#[inline]
fn is_one(&self) -> bool {
self.sign == Plus && self.data.is_one()
}
}
impl Signed for BigInt {
#[inline]
fn abs(&self) -> BigInt {
match self.sign {
Plus | NoSign => self.clone(),
Minus => BigInt::from(self.data.clone()),
}
}
#[inline]
fn abs_sub(&self, other: &BigInt) -> BigInt {
if *self <= *other {
Self::ZERO
} else {
self - other
}
}
#[inline]
fn signum(&self) -> BigInt {
match self.sign {
Plus => BigInt::one(),
Minus => -BigInt::one(),
NoSign => Self::ZERO,
}
}
#[inline]
fn is_positive(&self) -> bool {
self.sign == Plus
}
#[inline]
fn is_negative(&self) -> bool {
self.sign == Minus
}
}
trait UnsignedAbs {
type Unsigned;
fn checked_uabs(self) -> CheckedUnsignedAbs<Self::Unsigned>;
}
enum CheckedUnsignedAbs<T> {
Positive(T),
Negative(T),
}
use self::CheckedUnsignedAbs::{Negative, Positive};
macro_rules! impl_unsigned_abs {
($Signed:ty, $Unsigned:ty) => {
impl UnsignedAbs for $Signed {
type Unsigned = $Unsigned;
#[inline]
fn checked_uabs(self) -> CheckedUnsignedAbs<Self::Unsigned> {
if self >= 0 {
Positive(self as $Unsigned)
} else {
Negative(self.wrapping_neg() as $Unsigned)
}
}
}
};
}
impl_unsigned_abs!(i8, u8);
impl_unsigned_abs!(i16, u16);
impl_unsigned_abs!(i32, u32);
impl_unsigned_abs!(i64, u64);
impl_unsigned_abs!(i128, u128);
impl_unsigned_abs!(isize, usize);
impl Neg for BigInt {
type Output = BigInt;
#[inline]
fn neg(mut self) -> BigInt {
self.sign = -self.sign;
self
}
}
impl Neg for &BigInt {
type Output = BigInt;
#[inline]
fn neg(self) -> BigInt {
-self.clone()
}
}
impl Integer for BigInt {
#[inline]
fn div_rem(&self, other: &BigInt) -> (BigInt, BigInt) {
// r.sign == self.sign
let (d_ui, r_ui) = self.data.div_rem(&other.data);
let d = BigInt::from_biguint(self.sign, d_ui);
let r = BigInt::from_biguint(self.sign, r_ui);
if other.is_negative() {
(-d, r)
} else {
(d, r)
}
}
#[inline]
fn div_floor(&self, other: &BigInt) -> BigInt {
let (d_ui, m) = self.data.div_mod_floor(&other.data);
let d = BigInt::from(d_ui);
match (self.sign, other.sign) {
(Plus, Plus) | (NoSign, Plus) | (Minus, Minus) => d,
(Plus, Minus) | (NoSign, Minus) | (Minus, Plus) => {
if m.is_zero() {
-d
} else {
-d - 1u32
}
}
(_, NoSign) => unreachable!(),
}
}
#[inline]
fn mod_floor(&self, other: &BigInt) -> BigInt {
// m.sign == other.sign
let m_ui = self.data.mod_floor(&other.data);
let m = BigInt::from_biguint(other.sign, m_ui);
match (self.sign, other.sign) {
(Plus, Plus) | (NoSign, Plus) | (Minus, Minus) => m,
(Plus, Minus) | (NoSign, Minus) | (Minus, Plus) => {
if m.is_zero() {
m
} else {
other - m
}
}
(_, NoSign) => unreachable!(),
}
}
fn div_mod_floor(&self, other: &BigInt) -> (BigInt, BigInt) {
// m.sign == other.sign
let (d_ui, m_ui) = self.data.div_mod_floor(&other.data);
let d = BigInt::from(d_ui);
let m = BigInt::from_biguint(other.sign, m_ui);
match (self.sign, other.sign) {
(Plus, Plus) | (NoSign, Plus) | (Minus, Minus) => (d, m),
(Plus, Minus) | (NoSign, Minus) | (Minus, Plus) => {
if m.is_zero() {
(-d, m)
} else {
(-d - 1u32, other - m)
}
}
(_, NoSign) => unreachable!(),
}
}
#[inline]
fn div_ceil(&self, other: &Self) -> Self {
let (d_ui, m) = self.data.div_mod_floor(&other.data);
let d = BigInt::from(d_ui);
match (self.sign, other.sign) {
(Plus, Minus) | (NoSign, Minus) | (Minus, Plus) => -d,
(Plus, Plus) | (NoSign, Plus) | (Minus, Minus) => {
if m.is_zero() {
d
} else {
d + 1u32
}
}
(_, NoSign) => unreachable!(),
}
}
/// Calculates the Greatest Common Divisor (GCD) of the number and `other`.
///
/// The result is always positive.
#[inline]
fn gcd(&self, other: &BigInt) -> BigInt {
BigInt::from(self.data.gcd(&other.data))
}
/// Calculates the Lowest Common Multiple (LCM) of the number and `other`.
#[inline]
fn lcm(&self, other: &BigInt) -> BigInt {
BigInt::from(self.data.lcm(&other.data))
}
/// Calculates the Greatest Common Divisor (GCD) and
/// Lowest Common Multiple (LCM) together.
#[inline]
fn gcd_lcm(&self, other: &BigInt) -> (BigInt, BigInt) {
let (gcd, lcm) = self.data.gcd_lcm(&other.data);
(BigInt::from(gcd), BigInt::from(lcm))
}
/// Greatest common divisor, least common multiple, and Bézout coefficients.
#[inline]
fn extended_gcd_lcm(&self, other: &BigInt) -> (num_integer::ExtendedGcd<BigInt>, BigInt) {
let egcd = self.extended_gcd(other);
let lcm = if egcd.gcd.is_zero() {
Self::ZERO
} else {
BigInt::from(&self.data / &egcd.gcd.data * &other.data)
};
(egcd, lcm)
}
/// Deprecated, use `is_multiple_of` instead.
#[inline]
fn divides(&self, other: &BigInt) -> bool {
self.is_multiple_of(other)
}
/// Returns `true` if the number is a multiple of `other`.
#[inline]
fn is_multiple_of(&self, other: &BigInt) -> bool {
self.data.is_multiple_of(&other.data)
}
/// Returns `true` if the number is divisible by `2`.
#[inline]
fn is_even(&self) -> bool {
self.data.is_even()
}
/// Returns `true` if the number is not divisible by `2`.
#[inline]
fn is_odd(&self) -> bool {
self.data.is_odd()
}
/// Rounds up to nearest multiple of argument.
#[inline]
fn next_multiple_of(&self, other: &Self) -> Self {
let m = self.mod_floor(other);
if m.is_zero() {
self.clone()
} else {
self + (other - m)
}
}
/// Rounds down to nearest multiple of argument.
#[inline]
fn prev_multiple_of(&self, other: &Self) -> Self {
self - self.mod_floor(other)
}
fn dec(&mut self) {
*self -= 1u32;
}
fn inc(&mut self) {
*self += 1u32;
}
}
impl Roots for BigInt {
fn nth_root(&self, n: u32) -> Self {
assert!(
!(self.is_negative() && n.is_even()),
"root of degree {} is imaginary",
n
);
BigInt::from_biguint(self.sign, self.data.nth_root(n))
}
fn sqrt(&self) -> Self {
assert!(!self.is_negative(), "square root is imaginary");
BigInt::from_biguint(self.sign, self.data.sqrt())
}
fn cbrt(&self) -> Self {
BigInt::from_biguint(self.sign, self.data.cbrt())
}
}
impl IntDigits for BigInt {
#[inline]
fn digits(&self) -> &[BigDigit] {
self.data.digits()
}
#[inline]
fn digits_mut(&mut self) -> &mut Vec<BigDigit> {
self.data.digits_mut()
}
#[inline]
fn normalize(&mut self) {
self.data.normalize();
if self.data.is_zero() {
self.sign = NoSign;
}
}
#[inline]
fn capacity(&self) -> usize {
self.data.capacity()
}
#[inline]
fn len(&self) -> usize {
self.data.len()
}
}
/// A generic trait for converting a value to a [`BigInt`]. This may return
/// `None` when converting from `f32` or `f64`, and will always succeed
/// when converting from any integer or unsigned primitive, or [`BigUint`].
pub trait ToBigInt {
/// Converts the value of `self` to a [`BigInt`].
fn to_bigint(&self) -> Option<BigInt>;
}
impl BigInt {
/// A constant `BigInt` with value 0, useful for static initialization.
pub const ZERO: Self = BigInt {
sign: NoSign,
data: BigUint::ZERO,
};
/// Creates and initializes a [`BigInt`].
///
/// The base 2<sup>32</sup> digits are ordered least significant digit first.
#[inline]
pub fn new(sign: Sign, digits: Vec<u32>) -> BigInt {
BigInt::from_biguint(sign, BigUint::new(digits))
}
/// Creates and initializes a [`BigInt`].
///
/// The base 2<sup>32</sup> digits are ordered least significant digit first.
#[inline]
pub fn from_biguint(mut sign: Sign, mut data: BigUint) -> BigInt {
if sign == NoSign {
data.assign_from_slice(&[]);
} else if data.is_zero() {
sign = NoSign;
}
BigInt { sign, data }
}
/// Creates and initializes a [`BigInt`].
///
/// The base 2<sup>32</sup> digits are ordered least significant digit first.
#[inline]
pub fn from_slice(sign: Sign, slice: &[u32]) -> BigInt {
BigInt::from_biguint(sign, BigUint::from_slice(slice))
}
/// Reinitializes a [`BigInt`].
///
/// The base 2<sup>32</sup> digits are ordered least significant digit first.
#[inline]
pub fn assign_from_slice(&mut self, sign: Sign, slice: &[u32]) {
if sign == NoSign {
self.set_zero();
} else {
self.data.assign_from_slice(slice);
self.sign = if self.data.is_zero() { NoSign } else { sign };
}
}
/// Creates and initializes a [`BigInt`].
///
/// The bytes are in big-endian byte order.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// assert_eq!(BigInt::from_bytes_be(Sign::Plus, b"A"),
/// BigInt::parse_bytes(b"65", 10).unwrap());
/// assert_eq!(BigInt::from_bytes_be(Sign::Plus, b"AA"),
/// BigInt::parse_bytes(b"16705", 10).unwrap());
/// assert_eq!(BigInt::from_bytes_be(Sign::Plus, b"AB"),
/// BigInt::parse_bytes(b"16706", 10).unwrap());
/// assert_eq!(BigInt::from_bytes_be(Sign::Plus, b"Hello world!"),
/// BigInt::parse_bytes(b"22405534230753963835153736737", 10).unwrap());
/// ```
#[inline]
pub fn from_bytes_be(sign: Sign, bytes: &[u8]) -> BigInt {
BigInt::from_biguint(sign, BigUint::from_bytes_be(bytes))
}
/// Creates and initializes a [`BigInt`].
///
/// The bytes are in little-endian byte order.
#[inline]
pub fn from_bytes_le(sign: Sign, bytes: &[u8]) -> BigInt {
BigInt::from_biguint(sign, BigUint::from_bytes_le(bytes))
}
/// Creates and initializes a [`BigInt`] from an array of bytes in
/// two's complement binary representation.
///
/// The digits are in big-endian base 2<sup>8</sup>.
#[inline]
pub fn from_signed_bytes_be(digits: &[u8]) -> BigInt {
convert::from_signed_bytes_be(digits)
}
/// Creates and initializes a [`BigInt`] from an array of bytes in two's complement.
///
/// The digits are in little-endian base 2<sup>8</sup>.
#[inline]
pub fn from_signed_bytes_le(digits: &[u8]) -> BigInt {
convert::from_signed_bytes_le(digits)
}
/// Creates and initializes a [`BigInt`].
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, ToBigInt};
///
/// assert_eq!(BigInt::parse_bytes(b"1234", 10), ToBigInt::to_bigint(&1234));
/// assert_eq!(BigInt::parse_bytes(b"ABCD", 16), ToBigInt::to_bigint(&0xABCD));
/// assert_eq!(BigInt::parse_bytes(b"G", 16), None);
/// ```
#[inline]
pub fn parse_bytes(buf: &[u8], radix: u32) -> Option<BigInt> {
let s = str::from_utf8(buf).ok()?;
BigInt::from_str_radix(s, radix).ok()
}
/// Creates and initializes a [`BigInt`]. Each `u8` of the input slice is
/// interpreted as one digit of the number
/// and must therefore be less than `radix`.
///
/// The bytes are in big-endian byte order.
/// `radix` must be in the range `2...256`.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// let inbase190 = vec![15, 33, 125, 12, 14];
/// let a = BigInt::from_radix_be(Sign::Minus, &inbase190, 190).unwrap();
/// assert_eq!(a.to_radix_be(190), (Sign:: Minus, inbase190));
/// ```
pub fn from_radix_be(sign: Sign, buf: &[u8], radix: u32) -> Option<BigInt> {
let u = BigUint::from_radix_be(buf, radix)?;
Some(BigInt::from_biguint(sign, u))
}
/// Creates and initializes a [`BigInt`]. Each `u8` of the input slice is
/// interpreted as one digit of the number
/// and must therefore be less than `radix`.
///
/// The bytes are in little-endian byte order.
/// `radix` must be in the range `2...256`.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// let inbase190 = vec![14, 12, 125, 33, 15];
/// let a = BigInt::from_radix_be(Sign::Minus, &inbase190, 190).unwrap();
/// assert_eq!(a.to_radix_be(190), (Sign::Minus, inbase190));
/// ```
pub fn from_radix_le(sign: Sign, buf: &[u8], radix: u32) -> Option<BigInt> {
let u = BigUint::from_radix_le(buf, radix)?;
Some(BigInt::from_biguint(sign, u))
}
/// Returns the sign and the byte representation of the [`BigInt`] in big-endian byte order.
///
/// # Examples
///
/// ```
/// use num_bigint::{ToBigInt, Sign};
///
/// let i = -1125.to_bigint().unwrap();
/// assert_eq!(i.to_bytes_be(), (Sign::Minus, vec![4, 101]));
/// ```
#[inline]
pub fn to_bytes_be(&self) -> (Sign, Vec<u8>) {
(self.sign, self.data.to_bytes_be())
}
/// Returns the sign and the byte representation of the [`BigInt`] in little-endian byte order.
///
/// # Examples
///
/// ```
/// use num_bigint::{ToBigInt, Sign};
///
/// let i = -1125.to_bigint().unwrap();
/// assert_eq!(i.to_bytes_le(), (Sign::Minus, vec![101, 4]));
/// ```
#[inline]
pub fn to_bytes_le(&self) -> (Sign, Vec<u8>) {
(self.sign, self.data.to_bytes_le())
}
/// Returns the sign and the `u32` digits representation of the [`BigInt`] ordered least
/// significant digit first.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// assert_eq!(BigInt::from(-1125).to_u32_digits(), (Sign::Minus, vec![1125]));
/// assert_eq!(BigInt::from(4294967295u32).to_u32_digits(), (Sign::Plus, vec![4294967295]));
/// assert_eq!(BigInt::from(4294967296u64).to_u32_digits(), (Sign::Plus, vec![0, 1]));
/// assert_eq!(BigInt::from(-112500000000i64).to_u32_digits(), (Sign::Minus, vec![830850304, 26]));
/// assert_eq!(BigInt::from(112500000000i64).to_u32_digits(), (Sign::Plus, vec![830850304, 26]));
/// ```
#[inline]
pub fn to_u32_digits(&self) -> (Sign, Vec<u32>) {
(self.sign, self.data.to_u32_digits())
}
/// Returns the sign and the `u64` digits representation of the [`BigInt`] ordered least
/// significant digit first.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// assert_eq!(BigInt::from(-1125).to_u64_digits(), (Sign::Minus, vec![1125]));
/// assert_eq!(BigInt::from(4294967295u32).to_u64_digits(), (Sign::Plus, vec![4294967295]));
/// assert_eq!(BigInt::from(4294967296u64).to_u64_digits(), (Sign::Plus, vec![4294967296]));
/// assert_eq!(BigInt::from(-112500000000i64).to_u64_digits(), (Sign::Minus, vec![112500000000]));
/// assert_eq!(BigInt::from(112500000000i64).to_u64_digits(), (Sign::Plus, vec![112500000000]));
/// assert_eq!(BigInt::from(1u128 << 64).to_u64_digits(), (Sign::Plus, vec![0, 1]));
/// ```
#[inline]
pub fn to_u64_digits(&self) -> (Sign, Vec<u64>) {
(self.sign, self.data.to_u64_digits())
}
/// Returns an iterator of `u32` digits representation of the [`BigInt`] ordered least
/// significant digit first.
///
/// # Examples
///
/// ```
/// use num_bigint::BigInt;
///
/// assert_eq!(BigInt::from(-1125).iter_u32_digits().collect::<Vec<u32>>(), vec![1125]);
/// assert_eq!(BigInt::from(4294967295u32).iter_u32_digits().collect::<Vec<u32>>(), vec![4294967295]);
/// assert_eq!(BigInt::from(4294967296u64).iter_u32_digits().collect::<Vec<u32>>(), vec![0, 1]);
/// assert_eq!(BigInt::from(-112500000000i64).iter_u32_digits().collect::<Vec<u32>>(), vec![830850304, 26]);
/// assert_eq!(BigInt::from(112500000000i64).iter_u32_digits().collect::<Vec<u32>>(), vec![830850304, 26]);
/// ```
#[inline]
pub fn iter_u32_digits(&self) -> U32Digits<'_> {
self.data.iter_u32_digits()
}
/// Returns an iterator of `u64` digits representation of the [`BigInt`] ordered least
/// significant digit first.
///
/// # Examples
///
/// ```
/// use num_bigint::BigInt;
///
/// assert_eq!(BigInt::from(-1125).iter_u64_digits().collect::<Vec<u64>>(), vec![1125u64]);
/// assert_eq!(BigInt::from(4294967295u32).iter_u64_digits().collect::<Vec<u64>>(), vec![4294967295u64]);
/// assert_eq!(BigInt::from(4294967296u64).iter_u64_digits().collect::<Vec<u64>>(), vec![4294967296u64]);
/// assert_eq!(BigInt::from(-112500000000i64).iter_u64_digits().collect::<Vec<u64>>(), vec![112500000000u64]);
/// assert_eq!(BigInt::from(112500000000i64).iter_u64_digits().collect::<Vec<u64>>(), vec![112500000000u64]);
/// assert_eq!(BigInt::from(1u128 << 64).iter_u64_digits().collect::<Vec<u64>>(), vec![0, 1]);
/// ```
#[inline]
pub fn iter_u64_digits(&self) -> U64Digits<'_> {
self.data.iter_u64_digits()
}
/// Returns the two's-complement byte representation of the [`BigInt`] in big-endian byte order.
///
/// # Examples
///
/// ```
/// use num_bigint::ToBigInt;
///
/// let i = -1125.to_bigint().unwrap();
/// assert_eq!(i.to_signed_bytes_be(), vec![251, 155]);
/// ```
#[inline]
pub fn to_signed_bytes_be(&self) -> Vec<u8> {
convert::to_signed_bytes_be(self)
}
/// Returns the two's-complement byte representation of the [`BigInt`] in little-endian byte order.
///
/// # Examples
///
/// ```
/// use num_bigint::ToBigInt;
///
/// let i = -1125.to_bigint().unwrap();
/// assert_eq!(i.to_signed_bytes_le(), vec![155, 251]);
/// ```
#[inline]
pub fn to_signed_bytes_le(&self) -> Vec<u8> {
convert::to_signed_bytes_le(self)
}
/// Returns the integer formatted as a string in the given radix.
/// `radix` must be in the range `2...36`.
///
/// # Examples
///
/// ```
/// use num_bigint::BigInt;
///
/// let i = BigInt::parse_bytes(b"ff", 16).unwrap();
/// assert_eq!(i.to_str_radix(16), "ff");
/// ```
#[inline]
pub fn to_str_radix(&self, radix: u32) -> String {
let mut v = to_str_radix_reversed(&self.data, radix);
if self.is_negative() {
v.push(b'-');
}
v.reverse();
unsafe { String::from_utf8_unchecked(v) }
}
/// Returns the integer in the requested base in big-endian digit order.
/// The output is not given in a human readable alphabet but as a zero
/// based `u8` number.
/// `radix` must be in the range `2...256`.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// assert_eq!(BigInt::from(-0xFFFFi64).to_radix_be(159),
/// (Sign::Minus, vec![2, 94, 27]));
/// // 0xFFFF = 65535 = 2*(159^2) + 94*159 + 27
/// ```
#[inline]
pub fn to_radix_be(&self, radix: u32) -> (Sign, Vec<u8>) {
(self.sign, self.data.to_radix_be(radix))
}
/// Returns the integer in the requested base in little-endian digit order.
/// The output is not given in a human readable alphabet but as a zero
/// based `u8` number.
/// `radix` must be in the range `2...256`.
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// assert_eq!(BigInt::from(-0xFFFFi64).to_radix_le(159),
/// (Sign::Minus, vec![27, 94, 2]));
/// // 0xFFFF = 65535 = 27 + 94*159 + 2*(159^2)
/// ```
#[inline]
pub fn to_radix_le(&self, radix: u32) -> (Sign, Vec<u8>) {
(self.sign, self.data.to_radix_le(radix))
}
/// Returns the sign of the [`BigInt`] as a [`Sign`].
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, Sign};
///
/// assert_eq!(BigInt::from(1234).sign(), Sign::Plus);
/// assert_eq!(BigInt::from(-4321).sign(), Sign::Minus);
/// assert_eq!(BigInt::ZERO.sign(), Sign::NoSign);
/// ```
#[inline]
pub fn sign(&self) -> Sign {
self.sign
}
/// Returns the magnitude of the [`BigInt`] as a [`BigUint`].
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, BigUint};
/// use num_traits::Zero;
///
/// assert_eq!(BigInt::from(1234).magnitude(), &BigUint::from(1234u32));
/// assert_eq!(BigInt::from(-4321).magnitude(), &BigUint::from(4321u32));
/// assert!(BigInt::ZERO.magnitude().is_zero());
/// ```
#[inline]
pub fn magnitude(&self) -> &BigUint {
&self.data
}
/// Convert this [`BigInt`] into its [`Sign`] and [`BigUint`] magnitude,
/// the reverse of [`BigInt::from_biguint()`].
///
/// # Examples
///
/// ```
/// use num_bigint::{BigInt, BigUint, Sign};
///
/// assert_eq!(BigInt::from(1234).into_parts(), (Sign::Plus, BigUint::from(1234u32)));
/// assert_eq!(BigInt::from(-4321).into_parts(), (Sign::Minus, BigUint::from(4321u32)));
/// assert_eq!(BigInt::ZERO.into_parts(), (Sign::NoSign, BigUint::ZERO));
/// ```
#[inline]
pub fn into_parts(self) -> (Sign, BigUint) {
(self.sign, self.data)
}
/// Determines the fewest bits necessary to express the [`BigInt`],
/// not including the sign.
#[inline]
pub fn bits(&self) -> u64 {
self.data.bits()
}
/// Converts this [`BigInt`] into a [`BigUint`], if it's not negative.
#[inline]
pub fn to_biguint(&self) -> Option<BigUint> {
match self.sign {
Plus => Some(self.data.clone()),
NoSign => Some(BigUint::ZERO),
Minus => None,
}
}
#[inline]
pub fn checked_add(&self, v: &BigInt) -> Option<BigInt> {
Some(self + v)
}
#[inline]
pub fn checked_sub(&self, v: &BigInt) -> Option<BigInt> {
Some(self - v)
}
#[inline]
pub fn checked_mul(&self, v: &BigInt) -> Option<BigInt> {
Some(self * v)
}
#[inline]
pub fn checked_div(&self, v: &BigInt) -> Option<BigInt> {
if v.is_zero() {
return None;
}
Some(self / v)
}
/// Returns `self ^ exponent`.
pub fn pow(&self, exponent: u32) -> Self {
Pow::pow(self, exponent)
}
/// Returns `(self ^ exponent) mod modulus`
///
/// Note that this rounds like `mod_floor`, not like the `%` operator,
/// which makes a difference when given a negative `self` or `modulus`.
/// The result will be in the interval `[0, modulus)` for `modulus > 0`,
/// or in the interval `(modulus, 0]` for `modulus < 0`
///
/// Panics if the exponent is negative or the modulus is zero.
pub fn modpow(&self, exponent: &Self, modulus: &Self) -> Self {
power::modpow(self, exponent, modulus)
}
/// Returns the modular multiplicative inverse if it exists, otherwise `None`.
///
/// This solves for `x` such that `self * x ≡ 1 (mod modulus)`.
/// Note that this rounds like `mod_floor`, not like the `%` operator,
/// which makes a difference when given a negative `self` or `modulus`.
/// The solution will be in the interval `[0, modulus)` for `modulus > 0`,
/// or in the interval `(modulus, 0]` for `modulus < 0`,
/// and it exists if and only if `gcd(self, modulus) == 1`.
///
/// ```
/// use num_bigint::BigInt;
/// use num_integer::Integer;
/// use num_traits::{One, Zero};
///
/// let m = BigInt::from(383);
///
/// // Trivial cases
/// assert_eq!(BigInt::zero().modinv(&m), None);
/// assert_eq!(BigInt::one().modinv(&m), Some(BigInt::one()));
/// let neg1 = &m - 1u32;
/// assert_eq!(neg1.modinv(&m), Some(neg1));
///
/// // Positive self and modulus
/// let a = BigInt::from(271);
/// let x = a.modinv(&m).unwrap();
/// assert_eq!(x, BigInt::from(106));
/// assert_eq!(x.modinv(&m).unwrap(), a);
/// assert_eq!((&a * x).mod_floor(&m), BigInt::one());
///
/// // Negative self and positive modulus
/// let b = -&a;
/// let x = b.modinv(&m).unwrap();
/// assert_eq!(x, BigInt::from(277));
/// assert_eq!((&b * x).mod_floor(&m), BigInt::one());
///
/// // Positive self and negative modulus
/// let n = -&m;
/// let x = a.modinv(&n).unwrap();
/// assert_eq!(x, BigInt::from(-277));
/// assert_eq!((&a * x).mod_floor(&n), &n + 1);
///
/// // Negative self and modulus
/// let x = b.modinv(&n).unwrap();
/// assert_eq!(x, BigInt::from(-106));
/// assert_eq!((&b * x).mod_floor(&n), &n + 1);
/// ```
pub fn modinv(&self, modulus: &Self) -> Option<Self> {
let result = self.data.modinv(&modulus.data)?;
// The sign of the result follows the modulus, like `mod_floor`.
let (sign, mag) = match (self.is_negative(), modulus.is_negative()) {
(false, false) => (Plus, result),
(true, false) => (Plus, &modulus.data - result),
(false, true) => (Minus, &modulus.data - result),
(true, true) => (Minus, result),
};
Some(BigInt::from_biguint(sign, mag))
}
/// Returns the truncated principal square root of `self` --
/// see [`num_integer::Roots::sqrt()`].
pub fn sqrt(&self) -> Self {
Roots::sqrt(self)
}
/// Returns the truncated principal cube root of `self` --
/// see [`num_integer::Roots::cbrt()`].
pub fn cbrt(&self) -> Self {
Roots::cbrt(self)
}
/// Returns the truncated principal `n`th root of `self` --
/// See [`num_integer::Roots::nth_root()`].
pub fn nth_root(&self, n: u32) -> Self {
Roots::nth_root(self, n)
}
/// Returns the number of least-significant bits that are zero,
/// or `None` if the entire number is zero.
pub fn trailing_zeros(&self) -> Option<u64> {
self.data.trailing_zeros()
}
/// Returns whether the bit in position `bit` is set,
/// using the two's complement for negative numbers
pub fn bit(&self, bit: u64) -> bool {
if self.is_negative() {
// Let the binary representation of a number be
// ... 0 x 1 0 ... 0
// Then the two's complement is
// ... 1 !x 1 0 ... 0
// where !x is obtained from x by flipping each bit
if bit >= u64::from(crate::big_digit::BITS) * self.len() as u64 {
true
} else {
let trailing_zeros = self.data.trailing_zeros().unwrap();
match Ord::cmp(&bit, &trailing_zeros) {
Ordering::Less => false,
Ordering::Equal => true,
Ordering::Greater => !self.data.bit(bit),
}
}
} else {
self.data.bit(bit)
}
}
/// Sets or clears the bit in the given position,
/// using the two's complement for negative numbers
///
/// Note that setting/clearing a bit (for positive/negative numbers,
/// respectively) greater than the current bit length, a reallocation
/// may be needed to store the new digits
pub fn set_bit(&mut self, bit: u64, value: bool) {
match self.sign {
Sign::Plus => self.data.set_bit(bit, value),
Sign::Minus => bits::set_negative_bit(self, bit, value),
Sign::NoSign => {
if value {
self.data.set_bit(bit, true);
self.sign = Sign::Plus;
} else {
// Clearing a bit for zero is a no-op
}
}
}
// The top bit may have been cleared, so normalize
self.normalize();
}
}
impl num_traits::FromBytes for BigInt {
type Bytes = [u8];
fn from_be_bytes(bytes: &Self::Bytes) -> Self {
Self::from_signed_bytes_be(bytes)
}
fn from_le_bytes(bytes: &Self::Bytes) -> Self {
Self::from_signed_bytes_le(bytes)
}
}
impl num_traits::ToBytes for BigInt {
type Bytes = Vec<u8>;
fn to_be_bytes(&self) -> Self::Bytes {
self.to_signed_bytes_be()
}
fn to_le_bytes(&self) -> Self::Bytes {
self.to_signed_bytes_le()
}
}
#[test]
fn test_from_biguint() {
fn check(inp_s: Sign, inp_n: usize, ans_s: Sign, ans_n: usize) {
let inp = BigInt::from_biguint(inp_s, BigUint::from(inp_n));
let ans = BigInt {
sign: ans_s,
data: BigUint::from(ans_n),
};
assert_eq!(inp, ans);
}
check(Plus, 1, Plus, 1);
check(Plus, 0, NoSign, 0);
check(Minus, 1, Minus, 1);
check(NoSign, 1, NoSign, 0);
}
#[test]
fn test_from_slice() {
fn check(inp_s: Sign, inp_n: u32, ans_s: Sign, ans_n: u32) {
let inp = BigInt::from_slice(inp_s, &[inp_n]);
let ans = BigInt {
sign: ans_s,
data: BigUint::from(ans_n),
};
assert_eq!(inp, ans);
}
check(Plus, 1, Plus, 1);
check(Plus, 0, NoSign, 0);
check(Minus, 1, Minus, 1);
check(NoSign, 1, NoSign, 0);
}
#[test]
fn test_assign_from_slice() {
fn check(inp_s: Sign, inp_n: u32, ans_s: Sign, ans_n: u32) {
let mut inp = BigInt::from_slice(Minus, &[2627_u32, 0_u32, 9182_u32, 42_u32]);
inp.assign_from_slice(inp_s, &[inp_n]);
let ans = BigInt {
sign: ans_s,
data: BigUint::from(ans_n),
};
assert_eq!(inp, ans);
}
check(Plus, 1, Plus, 1);
check(Plus, 0, NoSign, 0);
check(Minus, 1, Minus, 1);
check(NoSign, 1, NoSign, 0);
}