use alloc::string::ToString;
use core::cmp::Ordering;
use core::fmt::{self, Write};
use core::ops::{Add, AddAssign, Div, DivAssign, Mul, MulAssign, Rem, RemAssign, Sub, SubAssign};
use core::str::FromStr;
use serde::{de, ser, Deserialize, Deserializer, Serialize};
use crate::errors::{
CheckedFromRatioError, CheckedMultiplyRatioError, DivideByZeroError, OverflowError,
OverflowOperation, RoundUpOverflowError, StdError,
};
use crate::forward_ref::{forward_ref_binop, forward_ref_op_assign};
use crate::{
Decimal, SignedDecimal, SignedDecimal256, Uint512, __internal::forward_ref_partial_eq,
};
use super::Fraction;
use super::Isqrt;
use super::Uint256;
#[derive(Copy, Clone, Default, PartialEq, Eq, PartialOrd, Ord, schemars::JsonSchema)]
pub struct Decimal256(#[schemars(with = "String")] Uint256);
forward_ref_partial_eq!(Decimal256, Decimal256);
#[derive(Debug, PartialEq, Eq, thiserror::Error)]
#[error("Decimal256 range exceeded")]
pub struct Decimal256RangeExceeded;
impl Decimal256 {
const DECIMAL_FRACTIONAL: Uint256 = Uint256::from_u128(1_000_000_000_000_000_000);
const DECIMAL_FRACTIONAL_SQUARED: Uint256 = Uint256::from_u128(1_000_000_000_000_000_000_000_000_000_000_000_000);
pub const DECIMAL_PLACES: u32 = 18;
pub const MAX: Self = Self(Uint256::MAX);
pub const MIN: Self = Self(Uint256::MIN);
pub const fn new(value: Uint256) -> Self {
Self(value)
}
pub const fn raw(value: u128) -> Self {
Self(Uint256::from_u128(value))
}
#[inline]
pub const fn one() -> Self {
Self(Self::DECIMAL_FRACTIONAL)
}
#[inline]
pub const fn zero() -> Self {
Self(Uint256::zero())
}
pub const fn percent(x: u64) -> Self {
let atomics = (x as u128) * 10_000_000_000_000_000;
Self(Uint256::from_u128(atomics))
}
pub const fn permille(x: u64) -> Self {
let atomics = (x as u128) * 1_000_000_000_000_000;
Self(Uint256::from_u128(atomics))
}
pub const fn bps(x: u64) -> Self {
let atomics = (x as u128) * 100_000_000_000_000;
Self(Uint256::from_u128(atomics))
}
pub fn from_atomics(
atomics: impl Into<Uint256>,
decimal_places: u32,
) -> Result<Self, Decimal256RangeExceeded> {
let atomics = atomics.into();
const TEN: Uint256 = Uint256::from_be_bytes([
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 10,
]);
Ok(match decimal_places.cmp(&Self::DECIMAL_PLACES) {
Ordering::Less => {
let digits = (Self::DECIMAL_PLACES) - decimal_places; let factor = TEN.checked_pow(digits).unwrap(); Self(
atomics
.checked_mul(factor)
.map_err(|_| Decimal256RangeExceeded)?,
)
}
Ordering::Equal => Self(atomics),
Ordering::Greater => {
let digits = decimal_places - (Self::DECIMAL_PLACES); if let Ok(factor) = TEN.checked_pow(digits) {
Self(atomics.checked_div(factor).unwrap()) } else {
Self(Uint256::zero())
}
}
})
}
pub fn from_ratio(numerator: impl Into<Uint256>, denominator: impl Into<Uint256>) -> Self {
match Decimal256::checked_from_ratio(numerator, denominator) {
Ok(value) => value,
Err(CheckedFromRatioError::DivideByZero) => {
panic!("Denominator must not be zero")
}
Err(CheckedFromRatioError::Overflow) => panic!("Multiplication overflow"),
}
}
pub fn checked_from_ratio(
numerator: impl Into<Uint256>,
denominator: impl Into<Uint256>,
) -> Result<Self, CheckedFromRatioError> {
let numerator: Uint256 = numerator.into();
let denominator: Uint256 = denominator.into();
match numerator.checked_multiply_ratio(Self::DECIMAL_FRACTIONAL, denominator) {
Ok(ratio) => {
Ok(Self(ratio))
}
Err(CheckedMultiplyRatioError::Overflow) => Err(CheckedFromRatioError::Overflow),
Err(CheckedMultiplyRatioError::DivideByZero) => {
Err(CheckedFromRatioError::DivideByZero)
}
}
}
#[must_use]
pub const fn is_zero(&self) -> bool {
self.0.is_zero()
}
#[must_use]
#[inline]
pub const fn atomics(&self) -> Uint256 {
self.0
}
#[must_use]
#[inline]
pub const fn decimal_places(&self) -> u32 {
Self::DECIMAL_PLACES
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn floor(&self) -> Self {
Self((self.0 / Self::DECIMAL_FRACTIONAL) * Self::DECIMAL_FRACTIONAL)
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn ceil(&self) -> Self {
match self.checked_ceil() {
Ok(value) => value,
Err(_) => panic!("attempt to ceil with overflow"),
}
}
pub fn checked_ceil(&self) -> Result<Self, RoundUpOverflowError> {
let floor = self.floor();
if floor == self {
Ok(floor)
} else {
floor
.checked_add(Decimal256::one())
.map_err(|_| RoundUpOverflowError)
}
}
pub fn checked_add(self, other: Self) -> Result<Self, OverflowError> {
self.0
.checked_add(other.0)
.map(Self)
.map_err(|_| OverflowError::new(OverflowOperation::Add))
}
pub fn checked_sub(self, other: Self) -> Result<Self, OverflowError> {
self.0
.checked_sub(other.0)
.map(Self)
.map_err(|_| OverflowError::new(OverflowOperation::Sub))
}
pub fn checked_mul(self, other: Self) -> Result<Self, OverflowError> {
let result_as_uint512 = self.numerator().full_mul(other.numerator())
/ Uint512::from_uint256(Self::DECIMAL_FRACTIONAL); result_as_uint512
.try_into()
.map(Self)
.map_err(|_| OverflowError::new(OverflowOperation::Mul))
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn pow(self, exp: u32) -> Self {
match self.checked_pow(exp) {
Ok(value) => value,
Err(_) => panic!("Multiplication overflow"),
}
}
pub fn checked_pow(self, exp: u32) -> Result<Self, OverflowError> {
fn inner(mut x: Decimal256, mut n: u32) -> Result<Decimal256, OverflowError> {
if n == 0 {
return Ok(Decimal256::one());
}
let mut y = Decimal256::one();
while n > 1 {
if n % 2 == 0 {
x = x.checked_mul(x)?;
n /= 2;
} else {
y = x.checked_mul(y)?;
x = x.checked_mul(x)?;
n = (n - 1) / 2;
}
}
Ok(x * y)
}
inner(self, exp).map_err(|_| OverflowError::new(OverflowOperation::Pow))
}
pub fn checked_div(self, other: Self) -> Result<Self, CheckedFromRatioError> {
Decimal256::checked_from_ratio(self.numerator(), other.numerator())
}
pub fn checked_rem(self, other: Self) -> Result<Self, DivideByZeroError> {
self.0
.checked_rem(other.0)
.map(Self)
.map_err(|_| DivideByZeroError)
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn sqrt(&self) -> Self {
(0..=Self::DECIMAL_PLACES / 2)
.rev()
.find_map(|i| self.sqrt_with_precision(i))
.unwrap()
}
#[must_use = "this returns the result of the operation, without modifying the original"]
fn sqrt_with_precision(&self, precision: u32) -> Option<Self> {
let inner_mul = Uint256::from(100u128).pow(precision);
self.0.checked_mul(inner_mul).ok().map(|inner| {
let outer_mul = Uint256::from(10u128).pow(Self::DECIMAL_PLACES / 2 - precision);
Self(inner.isqrt().checked_mul(outer_mul).unwrap())
})
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn abs_diff(self, other: Self) -> Self {
if self < other {
other - self
} else {
self - other
}
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn saturating_add(self, other: Self) -> Self {
match self.checked_add(other) {
Ok(value) => value,
Err(_) => Self::MAX,
}
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn saturating_sub(self, other: Self) -> Self {
match self.checked_sub(other) {
Ok(value) => value,
Err(_) => Self::zero(),
}
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn saturating_mul(self, other: Self) -> Self {
match self.checked_mul(other) {
Ok(value) => value,
Err(_) => Self::MAX,
}
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn saturating_pow(self, exp: u32) -> Self {
match self.checked_pow(exp) {
Ok(value) => value,
Err(_) => Self::MAX,
}
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn to_uint_floor(self) -> Uint256 {
self.0 / Self::DECIMAL_FRACTIONAL
}
#[must_use = "this returns the result of the operation, without modifying the original"]
pub fn to_uint_ceil(self) -> Uint256 {
let x = self.0;
let y = Self::DECIMAL_FRACTIONAL;
if x.is_zero() {
Uint256::zero()
} else {
Uint256::one() + ((x - Uint256::one()) / y)
}
}
}
impl Fraction<Uint256> for Decimal256 {
#[inline]
fn numerator(&self) -> Uint256 {
self.0
}
#[inline]
fn denominator(&self) -> Uint256 {
Self::DECIMAL_FRACTIONAL
}
fn inv(&self) -> Option<Self> {
if self.is_zero() {
None
} else {
Some(Self(Self::DECIMAL_FRACTIONAL_SQUARED / self.0))
}
}
}
impl From<Decimal> for Decimal256 {
fn from(input: Decimal) -> Self {
Decimal256::from_atomics(input.atomics(), input.decimal_places()).unwrap()
}
}
impl TryFrom<SignedDecimal> for Decimal256 {
type Error = Decimal256RangeExceeded;
fn try_from(value: SignedDecimal) -> Result<Self, Self::Error> {
value
.atomics()
.try_into()
.map(Decimal256)
.map_err(|_| Decimal256RangeExceeded)
}
}
impl TryFrom<SignedDecimal256> for Decimal256 {
type Error = Decimal256RangeExceeded;
fn try_from(value: SignedDecimal256) -> Result<Self, Self::Error> {
value
.atomics()
.try_into()
.map(Decimal256)
.map_err(|_| Decimal256RangeExceeded)
}
}
impl FromStr for Decimal256 {
type Err = StdError;
fn from_str(input: &str) -> Result<Self, Self::Err> {
let mut parts_iter = input.split('.');
let whole_part = parts_iter.next().unwrap(); let whole = whole_part
.parse::<Uint256>()
.map_err(|_| StdError::generic_err("Error parsing whole"))?;
let mut atomics = whole
.checked_mul(Self::DECIMAL_FRACTIONAL)
.map_err(|_| StdError::generic_err("Value too big"))?;
if let Some(fractional_part) = parts_iter.next() {
let fractional = fractional_part
.parse::<Uint256>()
.map_err(|_| StdError::generic_err("Error parsing fractional"))?;
let exp = (Self::DECIMAL_PLACES.checked_sub(fractional_part.len() as u32)).ok_or_else(
|| {
StdError::generic_err(format!(
"Cannot parse more than {} fractional digits",
Self::DECIMAL_PLACES
))
},
)?;
debug_assert!(exp <= Self::DECIMAL_PLACES);
let fractional_factor = Uint256::from(10u128).pow(exp);
atomics = atomics
.checked_add(
fractional.checked_mul(fractional_factor).unwrap(),
)
.map_err(|_| StdError::generic_err("Value too big"))?;
}
if parts_iter.next().is_some() {
return Err(StdError::generic_err("Unexpected number of dots"));
}
Ok(Self(atomics))
}
}
impl fmt::Display for Decimal256 {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let whole = (self.0) / Self::DECIMAL_FRACTIONAL;
let fractional = (self.0).checked_rem(Self::DECIMAL_FRACTIONAL).unwrap();
if fractional.is_zero() {
write!(f, "{whole}")
} else {
let fractional_string = format!(
"{:0>padding$}",
fractional,
padding = Self::DECIMAL_PLACES as usize
);
f.write_str(&whole.to_string())?;
f.write_char('.')?;
f.write_str(fractional_string.trim_end_matches('0'))?;
Ok(())
}
}
}
impl fmt::Debug for Decimal256 {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "Decimal256({self})")
}
}
impl Add for Decimal256 {
type Output = Self;
fn add(self, other: Self) -> Self {
Self(self.0 + other.0)
}
}
forward_ref_binop!(impl Add, add for Decimal256, Decimal256);
impl AddAssign for Decimal256 {
fn add_assign(&mut self, rhs: Decimal256) {
*self = *self + rhs;
}
}
forward_ref_op_assign!(impl AddAssign, add_assign for Decimal256, Decimal256);
impl Sub for Decimal256 {
type Output = Self;
fn sub(self, other: Self) -> Self {
Self(self.0 - other.0)
}
}
forward_ref_binop!(impl Sub, sub for Decimal256, Decimal256);
impl SubAssign for Decimal256 {
fn sub_assign(&mut self, rhs: Decimal256) {
*self = *self - rhs;
}
}
forward_ref_op_assign!(impl SubAssign, sub_assign for Decimal256, Decimal256);
impl Mul for Decimal256 {
type Output = Self;
#[allow(clippy::suspicious_arithmetic_impl)]
fn mul(self, other: Self) -> Self {
let result_as_uint512 = self.numerator().full_mul(other.numerator())
/ Uint512::from_uint256(Self::DECIMAL_FRACTIONAL); match result_as_uint512.try_into() {
Ok(result) => Self(result),
Err(_) => panic!("attempt to multiply with overflow"),
}
}
}
forward_ref_binop!(impl Mul, mul for Decimal256, Decimal256);
impl MulAssign for Decimal256 {
fn mul_assign(&mut self, rhs: Self) {
*self = *self * rhs;
}
}
forward_ref_op_assign!(impl MulAssign, mul_assign for Decimal256, Decimal256);
impl Div for Decimal256 {
type Output = Self;
fn div(self, other: Self) -> Self {
match Decimal256::checked_from_ratio(self.numerator(), other.numerator()) {
Ok(ratio) => ratio,
Err(CheckedFromRatioError::DivideByZero) => {
panic!("Division failed - denominator must not be zero")
}
Err(CheckedFromRatioError::Overflow) => {
panic!("Division failed - multiplication overflow")
}
}
}
}
forward_ref_binop!(impl Div, div for Decimal256, Decimal256);
impl DivAssign for Decimal256 {
fn div_assign(&mut self, rhs: Decimal256) {
*self = *self / rhs;
}
}
forward_ref_op_assign!(impl DivAssign, div_assign for Decimal256, Decimal256);
impl Div<Uint256> for Decimal256 {
type Output = Self;
fn div(self, rhs: Uint256) -> Self::Output {
Self(self.0 / rhs)
}
}
impl DivAssign<Uint256> for Decimal256 {
fn div_assign(&mut self, rhs: Uint256) {
self.0 /= rhs;
}
}
impl Rem for Decimal256 {
type Output = Self;
#[inline]
fn rem(self, rhs: Self) -> Self {
Self(self.0.rem(rhs.0))
}
}
forward_ref_binop!(impl Rem, rem for Decimal256, Decimal256);
impl RemAssign<Decimal256> for Decimal256 {
fn rem_assign(&mut self, rhs: Decimal256) {
*self = *self % rhs;
}
}
forward_ref_op_assign!(impl RemAssign, rem_assign for Decimal256, Decimal256);
impl<A> core::iter::Sum<A> for Decimal256
where
Self: Add<A, Output = Self>,
{
fn sum<I: Iterator<Item = A>>(iter: I) -> Self {
iter.fold(Self::zero(), Add::add)
}
}
impl Serialize for Decimal256 {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: ser::Serializer,
{
serializer.serialize_str(&self.to_string())
}
}
impl<'de> Deserialize<'de> for Decimal256 {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: Deserializer<'de>,
{
deserializer.deserialize_str(Decimal256Visitor)
}
}
struct Decimal256Visitor;
impl<'de> de::Visitor<'de> for Decimal256Visitor {
type Value = Decimal256;
fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
formatter.write_str("string-encoded decimal")
}
fn visit_str<E>(self, v: &str) -> Result<Self::Value, E>
where
E: de::Error,
{
match Self::Value::from_str(v) {
Ok(d) => Ok(d),
Err(e) => Err(E::custom(format_args!("Error parsing decimal '{v}': {e}"))),
}
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::errors::StdError;
use alloc::vec::Vec;
fn dec(input: &str) -> Decimal256 {
Decimal256::from_str(input).unwrap()
}
#[test]
fn decimal256_new() {
let expected = Uint256::from(300u128);
assert_eq!(Decimal256::new(expected).0, expected);
}
#[test]
fn decimal256_raw() {
let value = 300u128;
let expected = Uint256::from(value);
assert_eq!(Decimal256::raw(value).0, expected);
}
#[test]
fn decimal256_one() {
let value = Decimal256::one();
assert_eq!(value.0, Decimal256::DECIMAL_FRACTIONAL);
}
#[test]
fn decimal256_zero() {
let value = Decimal256::zero();
assert!(value.0.is_zero());
}
#[test]
fn decimal256_percent() {
let value = Decimal256::percent(50);
assert_eq!(value.0, Decimal256::DECIMAL_FRACTIONAL / Uint256::from(2u8));
}
#[test]
fn decimal256_permille() {
let value = Decimal256::permille(125);
assert_eq!(value.0, Decimal256::DECIMAL_FRACTIONAL / Uint256::from(8u8));
}
#[test]
fn decimal256_bps() {
let value = Decimal256::bps(125);
assert_eq!(
value.0,
Decimal256::DECIMAL_FRACTIONAL / Uint256::from(80u8)
);
}
#[test]
fn decimal256_from_atomics_works() {
let one = Decimal256::one();
let two = one + one;
assert_eq!(Decimal256::from_atomics(1u128, 0).unwrap(), one);
assert_eq!(Decimal256::from_atomics(10u128, 1).unwrap(), one);
assert_eq!(Decimal256::from_atomics(100u128, 2).unwrap(), one);
assert_eq!(Decimal256::from_atomics(1000u128, 3).unwrap(), one);
assert_eq!(
Decimal256::from_atomics(1000000000000000000u128, 18).unwrap(),
one
);
assert_eq!(
Decimal256::from_atomics(10000000000000000000u128, 19).unwrap(),
one
);
assert_eq!(
Decimal256::from_atomics(100000000000000000000u128, 20).unwrap(),
one
);
assert_eq!(Decimal256::from_atomics(2u128, 0).unwrap(), two);
assert_eq!(Decimal256::from_atomics(20u128, 1).unwrap(), two);
assert_eq!(Decimal256::from_atomics(200u128, 2).unwrap(), two);
assert_eq!(Decimal256::from_atomics(2000u128, 3).unwrap(), two);
assert_eq!(
Decimal256::from_atomics(2000000000000000000u128, 18).unwrap(),
two
);
assert_eq!(
Decimal256::from_atomics(20000000000000000000u128, 19).unwrap(),
two
);
assert_eq!(
Decimal256::from_atomics(200000000000000000000u128, 20).unwrap(),
two
);
assert_eq!(
Decimal256::from_atomics(4321u128, 20).unwrap(),
Decimal256::from_str("0.000000000000000043").unwrap()
);
assert_eq!(
Decimal256::from_atomics(6789u128, 20).unwrap(),
Decimal256::from_str("0.000000000000000067").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, 38).unwrap(),
Decimal256::from_str("3.402823669209384634").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, 39).unwrap(),
Decimal256::from_str("0.340282366920938463").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, 45).unwrap(),
Decimal256::from_str("0.000000340282366920").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, 51).unwrap(),
Decimal256::from_str("0.000000000000340282").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, 56).unwrap(),
Decimal256::from_str("0.000000000000000003").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, 57).unwrap(),
Decimal256::from_str("0.000000000000000000").unwrap()
);
assert_eq!(
Decimal256::from_atomics(u128::MAX, u32::MAX).unwrap(),
Decimal256::from_str("0.000000000000000000").unwrap()
);
let max = Decimal256::MAX;
assert_eq!(
Decimal256::from_atomics(max.atomics(), max.decimal_places()).unwrap(),
max
);
let result = Decimal256::from_atomics(Uint256::MAX, 17);
assert_eq!(result.unwrap_err(), Decimal256RangeExceeded);
}
#[test]
fn decimal256_from_ratio_works() {
assert_eq!(Decimal256::from_ratio(1u128, 1u128), Decimal256::one());
assert_eq!(Decimal256::from_ratio(53u128, 53u128), Decimal256::one());
assert_eq!(Decimal256::from_ratio(125u128, 125u128), Decimal256::one());
assert_eq!(
Decimal256::from_ratio(3u128, 2u128),
Decimal256::percent(150)
);
assert_eq!(
Decimal256::from_ratio(150u128, 100u128),
Decimal256::percent(150)
);
assert_eq!(
Decimal256::from_ratio(333u128, 222u128),
Decimal256::percent(150)
);
assert_eq!(
Decimal256::from_ratio(1u64, 8u64),
Decimal256::permille(125)
);
assert_eq!(
Decimal256::from_ratio(125u64, 1000u64),
Decimal256::permille(125)
);
assert_eq!(
Decimal256::from_ratio(1u64, 3u64),
Decimal256(Uint256::from_str("333333333333333333").unwrap())
);
assert_eq!(
Decimal256::from_ratio(2u64, 3u64),
Decimal256(Uint256::from_str("666666666666666666").unwrap())
);
assert_eq!(Decimal256::from_ratio(0u128, u128::MAX), Decimal256::zero());
assert_eq!(
Decimal256::from_ratio(u128::MAX, u128::MAX),
Decimal256::one()
);
assert_eq!(
Decimal256::from_ratio(340282366920938463463u128, 1u128),
Decimal256::from_str("340282366920938463463").unwrap()
);
}
#[test]
#[should_panic(expected = "Denominator must not be zero")]
fn decimal256_from_ratio_panics_for_zero_denominator() {
Decimal256::from_ratio(1u128, 0u128);
}
#[test]
#[should_panic(expected = "Multiplication overflow")]
fn decimal256_from_ratio_panics_for_mul_overflow() {
Decimal256::from_ratio(Uint256::MAX, 1u128);
}
#[test]
fn decimal256_checked_from_ratio_does_not_panic() {
assert_eq!(
Decimal256::checked_from_ratio(1u128, 0u128),
Err(CheckedFromRatioError::DivideByZero)
);
assert_eq!(
Decimal256::checked_from_ratio(Uint256::MAX, 1u128),
Err(CheckedFromRatioError::Overflow)
);
}
#[test]
fn decimal256_implements_fraction() {
let fraction = Decimal256::from_str("1234.567").unwrap();
assert_eq!(
fraction.numerator(),
Uint256::from_str("1234567000000000000000").unwrap()
);
assert_eq!(
fraction.denominator(),
Uint256::from_str("1000000000000000000").unwrap()
);
}
#[test]
fn decimal256_implements_from_decimal() {
let a = Decimal::from_str("123.456").unwrap();
let b = Decimal256::from(a);
assert_eq!(b.to_string(), "123.456");
let a = Decimal::from_str("0").unwrap();
let b = Decimal256::from(a);
assert_eq!(b.to_string(), "0");
let a = Decimal::MAX;
let b = Decimal256::from(a);
assert_eq!(b.to_string(), "340282366920938463463.374607431768211455");
}
#[test]
fn decimal256_from_str_works() {
assert_eq!(Decimal256::from_str("0").unwrap(), Decimal256::percent(0));
assert_eq!(Decimal256::from_str("1").unwrap(), Decimal256::percent(100));
assert_eq!(Decimal256::from_str("5").unwrap(), Decimal256::percent(500));
assert_eq!(
Decimal256::from_str("42").unwrap(),
Decimal256::percent(4200)
);
assert_eq!(Decimal256::from_str("000").unwrap(), Decimal256::percent(0));
assert_eq!(
Decimal256::from_str("001").unwrap(),
Decimal256::percent(100)
);
assert_eq!(
Decimal256::from_str("005").unwrap(),
Decimal256::percent(500)
);
assert_eq!(
Decimal256::from_str("0042").unwrap(),
Decimal256::percent(4200)
);
assert_eq!(
Decimal256::from_str("1.0").unwrap(),
Decimal256::percent(100)
);
assert_eq!(
Decimal256::from_str("1.5").unwrap(),
Decimal256::percent(150)
);
assert_eq!(
Decimal256::from_str("0.5").unwrap(),
Decimal256::percent(50)
);
assert_eq!(
Decimal256::from_str("0.123").unwrap(),
Decimal256::permille(123)
);
assert_eq!(
Decimal256::from_str("40.00").unwrap(),
Decimal256::percent(4000)
);
assert_eq!(
Decimal256::from_str("04.00").unwrap(),
Decimal256::percent(400)
);
assert_eq!(
Decimal256::from_str("00.40").unwrap(),
Decimal256::percent(40)
);
assert_eq!(
Decimal256::from_str("00.04").unwrap(),
Decimal256::percent(4)
);
assert_eq!(
Decimal256::from_str("7.123456789012345678").unwrap(),
Decimal256(Uint256::from(7123456789012345678u128))
);
assert_eq!(
Decimal256::from_str("7.999999999999999999").unwrap(),
Decimal256(Uint256::from(7999999999999999999u128))
);
assert_eq!(
Decimal256::from_str(
"115792089237316195423570985008687907853269984665640564039457.584007913129639935"
)
.unwrap(),
Decimal256::MAX
);
}
#[test]
fn decimal256_from_str_errors_for_broken_whole_part() {
match Decimal256::from_str("").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing whole"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str(" ").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing whole"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("-1").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing whole"),
e => panic!("Unexpected error: {e:?}"),
}
}
#[test]
fn decimal256_from_str_errors_for_broken_fractional_part() {
match Decimal256::from_str("1.").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing fractional"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("1. ").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing fractional"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("1.e").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing fractional"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("1.2e3").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Error parsing fractional"),
e => panic!("Unexpected error: {e:?}"),
}
}
#[test]
fn decimal256_from_str_errors_for_more_than_36_fractional_digits() {
match Decimal256::from_str("7.1234567890123456789").unwrap_err() {
StdError::GenericErr { msg, .. } => {
assert_eq!(msg, "Cannot parse more than 18 fractional digits")
}
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("7.1230000000000000000").unwrap_err() {
StdError::GenericErr { msg, .. } => {
assert_eq!(msg, "Cannot parse more than 18 fractional digits")
}
e => panic!("Unexpected error: {e:?}"),
}
}
#[test]
fn decimal256_from_str_errors_for_invalid_number_of_dots() {
match Decimal256::from_str("1.2.3").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Unexpected number of dots"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("1.2.3.4").unwrap_err() {
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Unexpected number of dots"),
e => panic!("Unexpected error: {e:?}"),
}
}
#[test]
fn decimal256_from_str_errors_for_more_than_max_value() {
match Decimal256::from_str("115792089237316195423570985008687907853269984665640564039458")
.unwrap_err()
{
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Value too big"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str("115792089237316195423570985008687907853269984665640564039458.0")
.unwrap_err()
{
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Value too big"),
e => panic!("Unexpected error: {e:?}"),
}
match Decimal256::from_str(
"115792089237316195423570985008687907853269984665640564039457.584007913129639936",
)
.unwrap_err()
{
StdError::GenericErr { msg, .. } => assert_eq!(msg, "Value too big"),
e => panic!("Unexpected error: {e:?}"),
}
}
#[test]
fn decimal256_atomics_works() {
let zero = Decimal256::zero();
let one = Decimal256::one();
let half = Decimal256::percent(50);
let two = Decimal256::percent(200);
let max = Decimal256::MAX;
assert_eq!(zero.atomics(), Uint256::from(0u128));
assert_eq!(one.atomics(), Uint256::from(1000000000000000000u128));
assert_eq!(half.atomics(), Uint256::from(500000000000000000u128));
assert_eq!(two.atomics(), Uint256::from(2000000000000000000u128));
assert_eq!(max.atomics(), Uint256::MAX);
}
#[test]
fn decimal256_decimal_places_works() {
let zero = Decimal256::zero();
let one = Decimal256::one();
let half = Decimal256::percent(50);
let two = Decimal256::percent(200);
let max = Decimal256::MAX;
assert_eq!(zero.decimal_places(), 18);
assert_eq!(one.decimal_places(), 18);
assert_eq!(half.decimal_places(), 18);
assert_eq!(two.decimal_places(), 18);
assert_eq!(max.decimal_places(), 18);
}
#[test]
fn decimal256_is_zero_works() {
assert!(Decimal256::zero().is_zero());
assert!(Decimal256::percent(0).is_zero());
assert!(Decimal256::permille(0).is_zero());
assert!(!Decimal256::one().is_zero());
assert!(!Decimal256::percent(123).is_zero());
assert!(!Decimal256::permille(1234).is_zero());
}
#[test]
fn decimal256_inv_works() {
assert_eq!(Decimal256::zero().inv(), None);
assert_eq!(Decimal256::one().inv(), Some(Decimal256::one()));
assert_eq!(
Decimal256::from_str("2").unwrap().inv(),
Some(Decimal256::from_str("0.5").unwrap())
);
assert_eq!(
Decimal256::from_str("20").unwrap().inv(),
Some(Decimal256::from_str("0.05").unwrap())
);
assert_eq!(
Decimal256::from_str("200").unwrap().inv(),
Some(Decimal256::from_str("0.005").unwrap())
);
assert_eq!(
Decimal256::from_str("2000").unwrap().inv(),
Some(Decimal256::from_str("0.0005").unwrap())
);
assert_eq!(
Decimal256::from_str("3").unwrap().inv(),
Some(Decimal256::from_str("0.333333333333333333").unwrap())
);
assert_eq!(
Decimal256::from_str("6").unwrap().inv(),
Some(Decimal256::from_str("0.166666666666666666").unwrap())
);
assert_eq!(
Decimal256::from_str("0.5").unwrap().inv(),
Some(Decimal256::from_str("2").unwrap())
);
assert_eq!(
Decimal256::from_str("0.05").unwrap().inv(),
Some(Decimal256::from_str("20").unwrap())
);
assert_eq!(
Decimal256::from_str("0.005").unwrap().inv(),
Some(Decimal256::from_str("200").unwrap())
);
assert_eq!(
Decimal256::from_str("0.0005").unwrap().inv(),
Some(Decimal256::from_str("2000").unwrap())
);
}
#[test]
#[allow(clippy::op_ref)]
fn decimal256_add_works() {
let value = Decimal256::one() + Decimal256::percent(50); assert_eq!(
value.0,
Decimal256::DECIMAL_FRACTIONAL * Uint256::from(3u8) / Uint256::from(2u8)
);
assert_eq!(
Decimal256::percent(5) + Decimal256::percent(4),
Decimal256::percent(9)
);
assert_eq!(
Decimal256::percent(5) + Decimal256::zero(),
Decimal256::percent(5)
);
assert_eq!(Decimal256::zero() + Decimal256::zero(), Decimal256::zero());
let a = Decimal256::percent(15);
let b = Decimal256::percent(25);
let expected = Decimal256::percent(40);
assert_eq!(a + b, expected);
assert_eq!(&a + b, expected);
assert_eq!(a + &b, expected);
assert_eq!(&a + &b, expected);
}
#[test]
#[should_panic(expected = "attempt to add with overflow")]
fn decimal256_add_overflow_panics() {
let _value = Decimal256::MAX + Decimal256::percent(50);
}
#[test]
fn decimal256_add_assign_works() {
let mut a = Decimal256::percent(30);
a += Decimal256::percent(20);
assert_eq!(a, Decimal256::percent(50));
let mut a = Decimal256::percent(15);
let b = Decimal256::percent(3);
let expected = Decimal256::percent(18);
a += &b;
assert_eq!(a, expected);
}
#[test]
#[allow(clippy::op_ref)]
fn decimal256_sub_works() {
let value = Decimal256::one() - Decimal256::percent(50); assert_eq!(value.0, Decimal256::DECIMAL_FRACTIONAL / Uint256::from(2u8));
assert_eq!(
Decimal256::percent(9) - Decimal256::percent(4),
Decimal256::percent(5)
);
assert_eq!(
Decimal256::percent(16) - Decimal256::zero(),
Decimal256::percent(16)
);
assert_eq!(
Decimal256::percent(16) - Decimal256::percent(16),
Decimal256::zero()
);
assert_eq!(Decimal256::zero() - Decimal256::zero(), Decimal256::zero());
let a = Decimal256::percent(13);
let b = Decimal256::percent(6);
let expected = Decimal256::percent(7);
assert_eq!(a - b, expected);
assert_eq!(&a - b, expected);
assert_eq!(a - &b, expected);
assert_eq!(&a - &b, expected);
}
#[test]
#[should_panic(expected = "attempt to subtract with overflow")]
fn decimal256_sub_overflow_panics() {
let _value = Decimal256::zero() - Decimal256::percent(50);
}
#[test]
fn decimal256_sub_assign_works() {
let mut a = Decimal256::percent(20);
a -= Decimal256::percent(2);
assert_eq!(a, Decimal256::percent(18));
let mut a = Decimal256::percent(33);
let b = Decimal256::percent(13);
let expected = Decimal256::percent(20);
a -= &b;
assert_eq!(a, expected);
}
#[test]
#[allow(clippy::op_ref)]
fn decimal256_implements_mul() {
let one = Decimal256::one();
let two = one + one;
let half = Decimal256::percent(50);
assert_eq!(one * Decimal256::percent(0), Decimal256::percent(0));
assert_eq!(one * Decimal256::percent(1), Decimal256::percent(1));
assert_eq!(one * Decimal256::percent(10), Decimal256::percent(10));
assert_eq!(one * Decimal256::percent(100), Decimal256::percent(100));
assert_eq!(one * Decimal256::percent(1000), Decimal256::percent(1000));
assert_eq!(one * Decimal256::MAX, Decimal256::MAX);
assert_eq!(Decimal256::percent(0) * one, Decimal256::percent(0));
assert_eq!(Decimal256::percent(1) * one, Decimal256::percent(1));
assert_eq!(Decimal256::percent(10) * one, Decimal256::percent(10));
assert_eq!(Decimal256::percent(100) * one, Decimal256::percent(100));
assert_eq!(Decimal256::percent(1000) * one, Decimal256::percent(1000));
assert_eq!(Decimal256::MAX * one, Decimal256::MAX);
assert_eq!(two * Decimal256::percent(0), Decimal256::percent(0));
assert_eq!(two * Decimal256::percent(1), Decimal256::percent(2));
assert_eq!(two * Decimal256::percent(10), Decimal256::percent(20));
assert_eq!(two * Decimal256::percent(100), Decimal256::percent(200));
assert_eq!(two * Decimal256::percent(1000), Decimal256::percent(2000));
assert_eq!(Decimal256::percent(0) * two, Decimal256::percent(0));
assert_eq!(Decimal256::percent(1) * two, Decimal256::percent(2));
assert_eq!(Decimal256::percent(10) * two, Decimal256::percent(20));
assert_eq!(Decimal256::percent(100) * two, Decimal256::percent(200));
assert_eq!(Decimal256::percent(1000) * two, Decimal256::percent(2000));
assert_eq!(half * Decimal256::percent(0), Decimal256::percent(0));
assert_eq!(half * Decimal256::percent(1), Decimal256::permille(5));
assert_eq!(half * Decimal256::percent(10), Decimal256::percent(5));
assert_eq!(half * Decimal256::percent(100), Decimal256::percent(50));
assert_eq!(half * Decimal256::percent(1000), Decimal256::percent(500));
assert_eq!(Decimal256::percent(0) * half, Decimal256::percent(0));
assert_eq!(Decimal256::percent(1) * half, Decimal256::permille(5));
assert_eq!(Decimal256::percent(10) * half, Decimal256::percent(5));
assert_eq!(Decimal256::percent(100) * half, Decimal256::percent(50));
assert_eq!(Decimal256::percent(1000) * half, Decimal256::percent(500));
let a = dec("123.127726548762582");
assert_eq!(a * dec("1"), dec("123.127726548762582"));
assert_eq!(a * dec("10"), dec("1231.27726548762582"));
assert_eq!(a * dec("100"), dec("12312.7726548762582"));
assert_eq!(a * dec("1000"), dec("123127.726548762582"));
assert_eq!(a * dec("1000000"), dec("123127726.548762582"));
assert_eq!(a * dec("1000000000"), dec("123127726548.762582"));
assert_eq!(a * dec("1000000000000"), dec("123127726548762.582"));
assert_eq!(a * dec("1000000000000000"), dec("123127726548762582"));
assert_eq!(a * dec("1000000000000000000"), dec("123127726548762582000"));
assert_eq!(dec("1") * a, dec("123.127726548762582"));
assert_eq!(dec("10") * a, dec("1231.27726548762582"));
assert_eq!(dec("100") * a, dec("12312.7726548762582"));
assert_eq!(dec("1000") * a, dec("123127.726548762582"));
assert_eq!(dec("1000000") * a, dec("123127726.548762582"));
assert_eq!(dec("1000000000") * a, dec("123127726548.762582"));
assert_eq!(dec("1000000000000") * a, dec("123127726548762.582"));
assert_eq!(dec("1000000000000000") * a, dec("123127726548762582"));
assert_eq!(dec("1000000000000000000") * a, dec("123127726548762582000"));
let max = Decimal256::MAX;
assert_eq!(
max * dec("1.0"),
dec("115792089237316195423570985008687907853269984665640564039457.584007913129639935")
);
assert_eq!(
max * dec("0.1"),
dec("11579208923731619542357098500868790785326998466564056403945.758400791312963993")
);
assert_eq!(
max * dec("0.01"),
dec("1157920892373161954235709850086879078532699846656405640394.575840079131296399")
);
assert_eq!(
max * dec("0.001"),
dec("115792089237316195423570985008687907853269984665640564039.457584007913129639")
);
assert_eq!(
max * dec("0.000001"),
dec("115792089237316195423570985008687907853269984665640564.039457584007913129")
);
assert_eq!(
max * dec("0.000000001"),
dec("115792089237316195423570985008687907853269984665640.564039457584007913")
);
assert_eq!(
max * dec("0.000000000001"),
dec("115792089237316195423570985008687907853269984665.640564039457584007")
);
assert_eq!(
max * dec("0.000000000000001"),
dec("115792089237316195423570985008687907853269984.665640564039457584")
);
assert_eq!(
max * dec("0.000000000000000001"),
dec("115792089237316195423570985008687907853269.984665640564039457")
);
let a = Decimal256::percent(20);
let b = Decimal256::percent(30);
let expected = Decimal256::percent(6);
assert_eq!(a * b, expected);
assert_eq!(&a * b, expected);
assert_eq!(a * &b, expected);
assert_eq!(&a * &b, expected);
}
#[test]
fn decimal256_mul_assign_works() {
let mut a = Decimal256::percent(15);
a *= Decimal256::percent(60);
assert_eq!(a, Decimal256::percent(9));
let mut a = Decimal256::percent(50);
let b = Decimal256::percent(20);
a *= &b;
assert_eq!(a, Decimal256::percent(10));
}
#[test]
#[should_panic(expected = "attempt to multiply with overflow")]
fn decimal256_mul_overflow_panics() {
let _value = Decimal256::MAX * Decimal256::percent(101);
}
#[test]
fn decimal256_checked_mul() {
let test_data = [
(Decimal256::zero(), Decimal256::zero()),
(Decimal256::zero(), Decimal256::one()),
(Decimal256::one(), Decimal256::zero()),
(Decimal256::percent(10), Decimal256::zero()),
(Decimal256::percent(10), Decimal256::percent(5)),
(Decimal256::MAX, Decimal256::one()),
(
Decimal256::MAX / Uint256::from_uint128(2u128.into()),
Decimal256::percent(200),
),
(Decimal256::permille(6), Decimal256::permille(13)),
];
for (x, y) in test_data.into_iter() {
assert_eq!(x * y, x.checked_mul(y).unwrap());
}
}
#[test]
fn decimal256_checked_mul_overflow() {
assert_eq!(
Decimal256::MAX.checked_mul(Decimal256::percent(200)),
Err(OverflowError::new(OverflowOperation::Mul))
);
}
#[test]
#[allow(clippy::op_ref)]
fn decimal256_implements_div() {
let one = Decimal256::one();
let two = one + one;
let half = Decimal256::percent(50);
assert_eq!(one / Decimal256::percent(1), Decimal256::percent(10_000));
assert_eq!(one / Decimal256::percent(10), Decimal256::percent(1_000));
assert_eq!(one / Decimal256::percent(100), Decimal256::percent(100));
assert_eq!(one / Decimal256::percent(1000), Decimal256::percent(10));
assert_eq!(Decimal256::percent(0) / one, Decimal256::percent(0));
assert_eq!(Decimal256::percent(1) / one, Decimal256::percent(1));
assert_eq!(Decimal256::percent(10) / one, Decimal256::percent(10));
assert_eq!(Decimal256::percent(100) / one, Decimal256::percent(100));
assert_eq!(Decimal256::percent(1000) / one, Decimal256::percent(1000));
assert_eq!(two / Decimal256::percent(1), Decimal256::percent(20_000));
assert_eq!(two / Decimal256::percent(10), Decimal256::percent(2_000));
assert_eq!(two / Decimal256::percent(100), Decimal256::percent(200));
assert_eq!(two / Decimal256::percent(1000), Decimal256::percent(20));
assert_eq!(Decimal256::percent(0) / two, Decimal256::percent(0));
assert_eq!(Decimal256::percent(1) / two, dec("0.005"));
assert_eq!(Decimal256::percent(10) / two, Decimal256::percent(5));
assert_eq!(Decimal256::percent(100) / two, Decimal256::percent(50));
assert_eq!(Decimal256::percent(1000) / two, Decimal256::percent(500));
assert_eq!(half / Decimal256::percent(1), Decimal256::percent(5_000));
assert_eq!(half / Decimal256::percent(10), Decimal256::percent(500));
assert_eq!(half / Decimal256::percent(100), Decimal256::percent(50));
assert_eq!(half / Decimal256::percent(1000), Decimal256::percent(5));
assert_eq!(Decimal256::percent(0) / half, Decimal256::percent(0));
assert_eq!(Decimal256::percent(1) / half, Decimal256::percent(2));
assert_eq!(Decimal256::percent(10) / half, Decimal256::percent(20));
assert_eq!(Decimal256::percent(100) / half, Decimal256::percent(200));
assert_eq!(Decimal256::percent(1000) / half, Decimal256::percent(2000));
let a = dec("123127726548762582");
assert_eq!(a / dec("1"), dec("123127726548762582"));
assert_eq!(a / dec("10"), dec("12312772654876258.2"));
assert_eq!(a / dec("100"), dec("1231277265487625.82"));
assert_eq!(a / dec("1000"), dec("123127726548762.582"));
assert_eq!(a / dec("1000000"), dec("123127726548.762582"));
assert_eq!(a / dec("1000000000"), dec("123127726.548762582"));
assert_eq!(a / dec("1000000000000"), dec("123127.726548762582"));
assert_eq!(a / dec("1000000000000000"), dec("123.127726548762582"));
assert_eq!(a / dec("1000000000000000000"), dec("0.123127726548762582"));
assert_eq!(dec("1") / a, dec("0.000000000000000008"));
assert_eq!(dec("10") / a, dec("0.000000000000000081"));
assert_eq!(dec("100") / a, dec("0.000000000000000812"));
assert_eq!(dec("1000") / a, dec("0.000000000000008121"));
assert_eq!(dec("1000000") / a, dec("0.000000000008121647"));
assert_eq!(dec("1000000000") / a, dec("0.000000008121647560"));
assert_eq!(dec("1000000000000") / a, dec("0.000008121647560868"));
assert_eq!(dec("1000000000000000") / a, dec("0.008121647560868164"));
assert_eq!(dec("1000000000000000000") / a, dec("8.121647560868164773"));
let a = dec("0.123127726548762582");
assert_eq!(a / dec("1.0"), dec("0.123127726548762582"));
assert_eq!(a / dec("0.1"), dec("1.23127726548762582"));
assert_eq!(a / dec("0.01"), dec("12.3127726548762582"));
assert_eq!(a / dec("0.001"), dec("123.127726548762582"));
assert_eq!(a / dec("0.000001"), dec("123127.726548762582"));
assert_eq!(a / dec("0.000000001"), dec("123127726.548762582"));
assert_eq!(a / dec("0.000000000001"), dec("123127726548.762582"));
assert_eq!(a / dec("0.000000000000001"), dec("123127726548762.582"));
assert_eq!(a / dec("0.000000000000000001"), dec("123127726548762582"));
assert_eq!(
Decimal256::percent(15) / Decimal256::percent(60),
Decimal256::percent(25)
);
let a = Decimal256::percent(100);
let b = Decimal256::percent(20);
let expected = Decimal256::percent(500);
assert_eq!(a / b, expected);
assert_eq!(&a / b, expected);
assert_eq!(a / &b, expected);
assert_eq!(&a / &b, expected);
}
#[test]
fn decimal256_div_assign_works() {
let mut a = Decimal256::percent(15);
a /= Decimal256::percent(20);
assert_eq!(a, Decimal256::percent(75));
let mut a = Decimal256::percent(50);
let b = Decimal256::percent(20);
a /= &b;
assert_eq!(a, Decimal256::percent(250));
}
#[test]
#[should_panic(expected = "Division failed - multiplication overflow")]
fn decimal256_div_overflow_panics() {
let _value = Decimal256::MAX / Decimal256::percent(10);
}
#[test]
#[should_panic(expected = "Division failed - denominator must not be zero")]
fn decimal256_div_by_zero_panics() {
let _value = Decimal256::one() / Decimal256::zero();
}
#[test]
fn decimal256_uint128_division() {
let left = Decimal256::percent(150); let right = Uint256::from(3u128);
assert_eq!(left / right, Decimal256::percent(50));
let left = Decimal256::zero();
let right = Uint256::from(300u128);
assert_eq!(left / right, Decimal256::zero());
}
#[test]
#[should_panic(expected = "attempt to divide by zero")]
fn decimal256_uint128_divide_by_zero() {
let left = Decimal256::percent(150); let right = Uint256::from(0u128);
let _result = left / right;
}
#[test]
fn decimal256_uint128_div_assign() {
let mut dec = Decimal256::percent(150); dec /= Uint256::from(3u128);
assert_eq!(dec, Decimal256::percent(50));
let mut dec = Decimal256::zero();
dec /= Uint256::from(300u128);
assert_eq!(dec, Decimal256::zero());
}
#[test]
#[should_panic(expected = "attempt to divide by zero")]
fn decimal256_uint128_div_assign_by_zero() {
let mut dec = Decimal256::percent(50);
dec /= Uint256::from(0u128);
}
#[test]
fn decimal256_uint128_sqrt() {
assert_eq!(Decimal256::percent(900).sqrt(), Decimal256::percent(300));
assert!(Decimal256::percent(316) < Decimal256::percent(1000).sqrt());
assert!(Decimal256::percent(1000).sqrt() < Decimal256::percent(317));
}
#[test]
fn decimal256_uint128_sqrt_is_precise() {
assert_eq!(
Decimal256::from_str("2").unwrap().sqrt(),
Decimal256::from_str("1.414213562373095048").unwrap() );
}
#[test]
fn decimal256_uint128_sqrt_does_not_overflow() {
assert_eq!(
Decimal256::from_str("40000000000000000000000000000000000000000000000000000000000")
.unwrap()
.sqrt(),
Decimal256::from_str("200000000000000000000000000000").unwrap()
);
}
#[test]
fn decimal256_uint128_sqrt_intermediate_precision_used() {
assert_eq!(
Decimal256::from_str("40000000000000000000000000000000000000000000000001")
.unwrap()
.sqrt(),
Decimal256::from_str("6324555320336758663997787.088865437067400000").unwrap()
);
}
#[test]
fn decimal256_checked_pow() {
for exp in 0..10 {
assert_eq!(
Decimal256::one().checked_pow(exp).unwrap(),
Decimal256::one()
);
}
assert_eq!(
Decimal256::zero().checked_pow(0).unwrap(),
Decimal256::one()
);
for exp in 1..10 {
assert_eq!(
Decimal256::zero().checked_pow(exp).unwrap(),
Decimal256::zero()
);
}
for num in &[
Decimal256::percent(50),
Decimal256::percent(99),
Decimal256::percent(200),
] {
assert_eq!(num.checked_pow(0).unwrap(), Decimal256::one())
}
assert_eq!(
Decimal256::percent(20).checked_pow(2).unwrap(),
Decimal256::percent(4)
);
assert_eq!(
Decimal256::percent(20).checked_pow(3).unwrap(),
Decimal256::permille(8)
);
assert_eq!(
Decimal256::percent(200).checked_pow(4).unwrap(),
Decimal256::percent(1600)
);
assert_eq!(
Decimal256::percent(200).checked_pow(4).unwrap(),
Decimal256::percent(1600)
);
assert_eq!(
Decimal256::percent(700).checked_pow(5).unwrap(),
Decimal256::percent(1680700)
);
assert_eq!(
Decimal256::percent(700).checked_pow(8).unwrap(),
Decimal256::percent(576480100)
);
assert_eq!(
Decimal256::percent(700).checked_pow(10).unwrap(),
Decimal256::percent(28247524900)
);
assert_eq!(
Decimal256::percent(120).checked_pow(123).unwrap(),
Decimal256(5486473221892422150877397607u128.into())
);
assert_eq!(
Decimal256::percent(10).checked_pow(2).unwrap(),
Decimal256(10000000000000000u128.into())
);
assert_eq!(
Decimal256::percent(10).checked_pow(18).unwrap(),
Decimal256(1u128.into())
);
}
#[test]
fn decimal256_checked_pow_overflow() {
assert_eq!(
Decimal256::MAX.checked_pow(2),
Err(OverflowError::new(OverflowOperation::Pow))
);
}
#[test]
fn decimal256_to_string() {
assert_eq!(Decimal256::zero().to_string(), "0");
assert_eq!(Decimal256::one().to_string(), "1");
assert_eq!(Decimal256::percent(500).to_string(), "5");
assert_eq!(Decimal256::percent(125).to_string(), "1.25");
assert_eq!(Decimal256::percent(42638).to_string(), "426.38");
assert_eq!(Decimal256::percent(3).to_string(), "0.03");
assert_eq!(Decimal256::permille(987).to_string(), "0.987");
assert_eq!(
Decimal256(Uint256::from(1u128)).to_string(),
"0.000000000000000001"
);
assert_eq!(
Decimal256(Uint256::from(10u128)).to_string(),
"0.00000000000000001"
);
assert_eq!(
Decimal256(Uint256::from(100u128)).to_string(),
"0.0000000000000001"
);
assert_eq!(
Decimal256(Uint256::from(1000u128)).to_string(),
"0.000000000000001"
);
assert_eq!(
Decimal256(Uint256::from(10000u128)).to_string(),
"0.00000000000001"
);
assert_eq!(
Decimal256(Uint256::from(100000u128)).to_string(),
"0.0000000000001"
);
assert_eq!(
Decimal256(Uint256::from(1000000u128)).to_string(),
"0.000000000001"
);
assert_eq!(
Decimal256(Uint256::from(10000000u128)).to_string(),
"0.00000000001"
);
assert_eq!(
Decimal256(Uint256::from(100000000u128)).to_string(),
"0.0000000001"
);
assert_eq!(
Decimal256(Uint256::from(1000000000u128)).to_string(),
"0.000000001"
);
assert_eq!(
Decimal256(Uint256::from(10000000000u128)).to_string(),
"0.00000001"
);
assert_eq!(
Decimal256(Uint256::from(100000000000u128)).to_string(),
"0.0000001"
);
assert_eq!(
Decimal256(Uint256::from(10000000000000u128)).to_string(),
"0.00001"
);
assert_eq!(
Decimal256(Uint256::from(100000000000000u128)).to_string(),
"0.0001"
);
assert_eq!(
Decimal256(Uint256::from(1000000000000000u128)).to_string(),
"0.001"
);
assert_eq!(
Decimal256(Uint256::from(10000000000000000u128)).to_string(),
"0.01"
);
assert_eq!(
Decimal256(Uint256::from(100000000000000000u128)).to_string(),
"0.1"
);
}
#[test]
fn decimal256_iter_sum() {
let items = vec![
Decimal256::zero(),
Decimal256::from_str("2").unwrap(),
Decimal256::from_str("2").unwrap(),
];
assert_eq!(
items.iter().sum::<Decimal256>(),
Decimal256::from_str("4").unwrap()
);
assert_eq!(
items.into_iter().sum::<Decimal256>(),
Decimal256::from_str("4").unwrap()
);
let empty: Vec<Decimal256> = vec![];
assert_eq!(Decimal256::zero(), empty.iter().sum::<Decimal256>());
}
#[test]
fn decimal256_serialize() {
assert_eq!(serde_json::to_vec(&Decimal256::zero()).unwrap(), br#""0""#);
assert_eq!(serde_json::to_vec(&Decimal256::one()).unwrap(), br#""1""#);
assert_eq!(
serde_json::to_vec(&Decimal256::percent(8)).unwrap(),
br#""0.08""#
);
assert_eq!(
serde_json::to_vec(&Decimal256::percent(87)).unwrap(),
br#""0.87""#
);
assert_eq!(
serde_json::to_vec(&Decimal256::percent(876)).unwrap(),
br#""8.76""#
);
assert_eq!(
serde_json::to_vec(&Decimal256::percent(8765)).unwrap(),
br#""87.65""#
);
}
#[test]
fn decimal256_deserialize() {
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""0""#).unwrap(),
Decimal256::zero()
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""1""#).unwrap(),
Decimal256::one()
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""000""#).unwrap(),
Decimal256::zero()
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""001""#).unwrap(),
Decimal256::one()
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""0.08""#).unwrap(),
Decimal256::percent(8)
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""0.87""#).unwrap(),
Decimal256::percent(87)
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""8.76""#).unwrap(),
Decimal256::percent(876)
);
assert_eq!(
serde_json::from_slice::<Decimal256>(br#""87.65""#).unwrap(),
Decimal256::percent(8765)
);
}
#[test]
fn decimal256_abs_diff_works() {
let a = Decimal256::percent(285);
let b = Decimal256::percent(200);
let expected = Decimal256::percent(85);
assert_eq!(a.abs_diff(b), expected);
assert_eq!(b.abs_diff(a), expected);
}
#[test]
#[allow(clippy::op_ref)]
fn decimal256_rem_works() {
assert_eq!(
Decimal256::percent(402) % Decimal256::percent(111),
Decimal256::percent(69)
);
assert_eq!(
Decimal256::percent(1525) % Decimal256::percent(400),
Decimal256::percent(325)
);
let a = Decimal256::percent(318);
let b = Decimal256::percent(317);
let expected = Decimal256::percent(1);
assert_eq!(a % b, expected);
assert_eq!(a % &b, expected);
assert_eq!(&a % b, expected);
assert_eq!(&a % &b, expected);
}
#[test]
fn decimal_rem_assign_works() {
let mut a = Decimal256::percent(17673);
a %= Decimal256::percent(2362);
assert_eq!(a, Decimal256::percent(1139)); let mut a = Decimal256::percent(4262);
let b = Decimal256::percent(1270);
a %= &b;
assert_eq!(a, Decimal256::percent(452)); }
#[test]
#[should_panic(expected = "divisor of zero")]
fn decimal256_rem_panics_for_zero() {
let _ = Decimal256::percent(777) % Decimal256::zero();
}
#[test]
fn decimal256_checked_methods() {
assert_eq!(
Decimal256::percent(402)
.checked_add(Decimal256::percent(111))
.unwrap(),
Decimal256::percent(513)
);
assert!(matches!(
Decimal256::MAX.checked_add(Decimal256::percent(1)),
Err(OverflowError { .. })
));
assert_eq!(
Decimal256::percent(1111)
.checked_sub(Decimal256::percent(111))
.unwrap(),
Decimal256::percent(1000)
);
assert!(matches!(
Decimal256::zero().checked_sub(Decimal256::percent(1)),
Err(OverflowError { .. })
));
assert_eq!(
Decimal256::percent(30)
.checked_div(Decimal256::percent(200))
.unwrap(),
Decimal256::percent(15)
);
assert_eq!(
Decimal256::percent(88)
.checked_div(Decimal256::percent(20))
.unwrap(),
Decimal256::percent(440)
);
assert!(matches!(
Decimal256::MAX.checked_div(Decimal256::zero()),
Err(CheckedFromRatioError::DivideByZero { .. })
));
assert!(matches!(
Decimal256::MAX.checked_div(Decimal256::percent(1)),
Err(CheckedFromRatioError::Overflow { .. })
));
assert_eq!(
Decimal256::percent(402)
.checked_rem(Decimal256::percent(111))
.unwrap(),
Decimal256::percent(69)
);
assert_eq!(
Decimal256::percent(1525)
.checked_rem(Decimal256::percent(400))
.unwrap(),
Decimal256::percent(325)
);
assert!(matches!(
Decimal256::MAX.checked_rem(Decimal256::zero()),
Err(DivideByZeroError { .. })
));
}
#[test]
fn decimal256_pow_works() {
assert_eq!(Decimal256::percent(200).pow(2), Decimal256::percent(400));
assert_eq!(
Decimal256::percent(200).pow(10),
Decimal256::percent(102400)
);
}
#[test]
#[should_panic]
fn decimal256_pow_overflow_panics() {
_ = Decimal256::MAX.pow(2u32);
}
#[test]
fn decimal256_saturating_works() {
assert_eq!(
Decimal256::percent(200).saturating_add(Decimal256::percent(200)),
Decimal256::percent(400)
);
assert_eq!(
Decimal256::MAX.saturating_add(Decimal256::percent(200)),
Decimal256::MAX
);
assert_eq!(
Decimal256::percent(200).saturating_sub(Decimal256::percent(100)),
Decimal256::percent(100)
);
assert_eq!(
Decimal256::zero().saturating_sub(Decimal256::percent(200)),
Decimal256::zero()
);
assert_eq!(
Decimal256::percent(200).saturating_mul(Decimal256::percent(50)),
Decimal256::percent(100)
);
assert_eq!(
Decimal256::MAX.saturating_mul(Decimal256::percent(200)),
Decimal256::MAX
);
assert_eq!(
Decimal256::percent(400).saturating_pow(2u32),
Decimal256::percent(1600)
);
assert_eq!(Decimal256::MAX.saturating_pow(2u32), Decimal256::MAX);
}
#[test]
fn decimal256_rounding() {
assert_eq!(Decimal256::one().floor(), Decimal256::one());
assert_eq!(Decimal256::percent(150).floor(), Decimal256::one());
assert_eq!(Decimal256::percent(199).floor(), Decimal256::one());
assert_eq!(Decimal256::percent(200).floor(), Decimal256::percent(200));
assert_eq!(Decimal256::percent(99).floor(), Decimal256::zero());
assert_eq!(Decimal256::one().ceil(), Decimal256::one());
assert_eq!(Decimal256::percent(150).ceil(), Decimal256::percent(200));
assert_eq!(Decimal256::percent(199).ceil(), Decimal256::percent(200));
assert_eq!(Decimal256::percent(99).ceil(), Decimal256::one());
assert_eq!(Decimal256(Uint256::from(1u128)).ceil(), Decimal256::one());
}
#[test]
#[should_panic(expected = "attempt to ceil with overflow")]
fn decimal256_ceil_panics() {
let _ = Decimal256::MAX.ceil();
}
#[test]
fn decimal256_checked_ceil() {
assert_eq!(
Decimal256::percent(199).checked_ceil(),
Ok(Decimal256::percent(200))
);
assert_eq!(Decimal256::MAX.checked_ceil(), Err(RoundUpOverflowError));
}
#[test]
fn decimal256_to_uint_floor_works() {
let d = Decimal256::from_str("12.000000000000000001").unwrap();
assert_eq!(d.to_uint_floor(), Uint256::from_u128(12));
let d = Decimal256::from_str("12.345").unwrap();
assert_eq!(d.to_uint_floor(), Uint256::from_u128(12));
let d = Decimal256::from_str("12.999").unwrap();
assert_eq!(d.to_uint_floor(), Uint256::from_u128(12));
let d = Decimal256::from_str("0.98451384").unwrap();
assert_eq!(d.to_uint_floor(), Uint256::from_u128(0));
let d = Decimal256::from_str("75.0").unwrap();
assert_eq!(d.to_uint_floor(), Uint256::from_u128(75));
let d = Decimal256::from_str("0.0").unwrap();
assert_eq!(d.to_uint_floor(), Uint256::from_u128(0));
let d = Decimal256::MAX;
assert_eq!(
d.to_uint_floor(),
Uint256::from_str("115792089237316195423570985008687907853269984665640564039457")
.unwrap()
);
let tests = vec![
(
Decimal256::from_str("12.345").unwrap(),
Uint256::from(12u128),
),
(
Decimal256::from_str("0.98451384").unwrap(),
Uint256::from(0u128),
),
(
Decimal256::from_str("178.0").unwrap(),
Uint256::from(178u128),
),
(Decimal256::MIN, Uint256::from(0u128)),
(
Decimal256::MAX,
Uint256::MAX / Decimal256::DECIMAL_FRACTIONAL,
),
];
for (my_decimal, expected) in tests.into_iter() {
assert_eq!(my_decimal.to_uint_floor(), expected);
}
}
#[test]
fn decimal256_to_uint_ceil_works() {
let d = Decimal256::from_str("12.000000000000000001").unwrap();
assert_eq!(d.to_uint_ceil(), Uint256::from_u128(13));
let d = Decimal256::from_str("12.345").unwrap();
assert_eq!(d.to_uint_ceil(), Uint256::from_u128(13));
let d = Decimal256::from_str("12.999").unwrap();
assert_eq!(d.to_uint_ceil(), Uint256::from_u128(13));
let d = Decimal256::from_str("75.0").unwrap();
assert_eq!(d.to_uint_ceil(), Uint256::from_u128(75));
let d = Decimal256::from_str("0.0").unwrap();
assert_eq!(d.to_uint_ceil(), Uint256::from_u128(0));
let d = Decimal256::MAX;
assert_eq!(
d.to_uint_ceil(),
Uint256::from_str("115792089237316195423570985008687907853269984665640564039458")
.unwrap()
);
}
#[test]
fn decimal256_partial_eq() {
let test_cases = [
("1", "1", true),
("0.5", "0.5", true),
("0.5", "0.51", false),
("0", "0.00000", true),
]
.into_iter()
.map(|(lhs, rhs, expected)| (dec(lhs), dec(rhs), expected));
#[allow(clippy::op_ref)]
for (lhs, rhs, expected) in test_cases {
assert_eq!(lhs == rhs, expected);
assert_eq!(&lhs == rhs, expected);
assert_eq!(lhs == &rhs, expected);
assert_eq!(&lhs == &rhs, expected);
}
}
#[test]
fn decimal256_implements_debug() {
let decimal = Decimal256::from_str("123.45").unwrap();
assert_eq!(format!("{decimal:?}"), "Decimal256(123.45)");
let test_cases = ["5", "5.01", "42", "0", "2"];
for s in test_cases {
let decimal256 = Decimal256::from_str(s).unwrap();
let expected = format!("Decimal256({s})");
assert_eq!(format!("{decimal256:?}"), expected);
}
}
}