// To the extent possible under law, the author(s) have dedicated all
// copyright and related and neighboring rights to this software to
// the public domain worldwide. This software is distributed without
// any warranty.
//
// You should have received a copy of the CC0 Public Domain Dedication
// along with this software.
// If not, see .
//
//! Amounts
//!
//! This module mainly introduces the [Amount] and [SignedAmount] types.
//! We refer to the documentation on the types for more information.
//!
use std::default;
use std::error;
use std::fmt::{self, Write};
use std::ops;
use std::str::FromStr;
/// A set of denominations in which amounts can be expressed.
#[derive(Debug, Clone, Copy, Eq, PartialEq, Hash)]
pub enum Denomination {
/// BTC
Bitcoin,
/// mBTC
MilliBitcoin,
/// uBTC
MicroBitcoin,
/// bits
Bit,
/// satoshi
Satoshi,
/// msat
MilliSatoshi,
}
impl Denomination {
/// The number of decimal places more than a satoshi.
fn precision(self) -> i32 {
match self {
Denomination::Bitcoin => -8,
Denomination::MilliBitcoin => -5,
Denomination::MicroBitcoin => -2,
Denomination::Bit => -2,
Denomination::Satoshi => 0,
Denomination::MilliSatoshi => 3,
}
}
}
impl fmt::Display for Denomination {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str(match *self {
Denomination::Bitcoin => "BTC",
Denomination::MilliBitcoin => "mBTC",
Denomination::MicroBitcoin => "uBTC",
Denomination::Bit => "bits",
Denomination::Satoshi => "satoshi",
Denomination::MilliSatoshi => "msat",
})
}
}
impl FromStr for Denomination {
type Err = ParseAmountError;
fn from_str(s: &str) -> Result {
match s {
"BTC" => Ok(Denomination::Bitcoin),
"mBTC" => Ok(Denomination::MilliBitcoin),
"uBTC" => Ok(Denomination::MicroBitcoin),
"bits" => Ok(Denomination::Bit),
"satoshi" => Ok(Denomination::Satoshi),
"sat" => Ok(Denomination::Satoshi),
"msat" => Ok(Denomination::MilliSatoshi),
d => Err(ParseAmountError::UnknownDenomination(d.to_owned())),
}
}
}
/// An error during amount parsing.
#[derive(Debug, Clone, PartialEq, Eq)]
pub enum ParseAmountError {
/// Amount is negative.
Negative,
/// Amount is too big to fit inside the type.
TooBig,
/// Amount has higher precision than supported by the type.
TooPrecise,
/// Invalid number format.
InvalidFormat,
/// Input string was too large.
InputTooLarge,
/// Invalid character in input.
InvalidCharacter(char),
/// The denomination was unknown.
UnknownDenomination(String),
}
impl fmt::Display for ParseAmountError {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let desc = ::std::error::Error::description(self);
match *self {
ParseAmountError::InvalidCharacter(c) => write!(f, "{}: {}", desc, c),
ParseAmountError::UnknownDenomination(ref d) => write!(f, "{}: {}", desc, d),
_ => f.write_str(desc),
}
}
}
impl error::Error for ParseAmountError {
fn cause(&self) -> Option<&error::Error> {
None
}
fn description(&self) -> &'static str {
match *self {
ParseAmountError::Negative => "amount is negative",
ParseAmountError::TooBig => "amount is too big",
ParseAmountError::TooPrecise => "amount has a too high precision",
ParseAmountError::InvalidFormat => "invalid number format",
ParseAmountError::InputTooLarge => "input string was too large",
ParseAmountError::InvalidCharacter(_) => "invalid character in input",
ParseAmountError::UnknownDenomination(_) => "unknown denomination",
}
}
}
fn is_too_precise(s: &str, precision: usize) -> bool {
s.contains(".") || precision >= s.len() || s.chars().rev().take(precision).any(|d| d != '0')
}
/// Parse decimal string in the given denomination into a satoshi value and a
/// bool indicator for a negative amount.
fn parse_signed_to_satoshi(
mut s: &str,
denom: Denomination,
) -> Result<(bool, u64), ParseAmountError> {
if s.len() == 0 {
return Err(ParseAmountError::InvalidFormat);
}
if s.len() > 50 {
return Err(ParseAmountError::InputTooLarge);
}
let is_negative = s.chars().next().unwrap() == '-';
if is_negative {
if s.len() == 1 {
return Err(ParseAmountError::InvalidFormat);
}
s = &s[1..];
}
let max_decimals = {
// The difference in precision between native (satoshi)
// and desired denomination.
let precision_diff = -denom.precision();
if precision_diff < 0 {
// If precision diff is negative, this means we are parsing
// into a less precise amount. That is not allowed unless
// there are no decimals and the last digits are zeroes as
// many as the difference in precision.
let last_n = precision_diff.abs() as usize;
if is_too_precise(s, last_n) {
return Err(ParseAmountError::TooPrecise);
}
s = &s[0..s.len() - last_n];
0
} else {
precision_diff
}
};
let mut decimals = None;
let mut value: u64 = 0; // as satoshis
for c in s.chars() {
match c {
'0'...'9' => {
// Do `value = 10 * value + digit`, catching overflows.
match 10_u64.checked_mul(value) {
None => return Err(ParseAmountError::TooBig),
Some(val) => match val.checked_add((c as u8 - b'0') as u64) {
None => return Err(ParseAmountError::TooBig),
Some(val) => value = val,
},
}
// Increment the decimal digit counter if past decimal.
decimals = match decimals {
None => None,
Some(d) if d < max_decimals => Some(d + 1),
_ => return Err(ParseAmountError::TooPrecise),
};
}
'.' => match decimals {
None => decimals = Some(0),
// Double decimal dot.
_ => return Err(ParseAmountError::InvalidFormat),
},
c => return Err(ParseAmountError::InvalidCharacter(c)),
}
}
// Decimally shift left by `max_decimals - decimals`.
let scale_factor = max_decimals - decimals.unwrap_or(0);
for _ in 0..scale_factor {
value = match 10_u64.checked_mul(value) {
Some(v) => v,
None => return Err(ParseAmountError::TooBig),
};
}
Ok((is_negative, value))
}
/// Format the given satoshi amount in the given denomination.
///
/// Does not include the denomination.
fn fmt_satoshi_in(
satoshi: u64,
negative: bool,
f: &mut fmt::Write,
denom: Denomination,
) -> fmt::Result {
if negative {
f.write_str("-")?;
}
if denom.precision() > 0 {
// add zeroes in the end
let width = denom.precision() as usize;
write!(f, "{}{:0width$}", satoshi, 0, width = width)?;
} else if denom.precision() < 0 {
// need to inject a comma in the number
let nb_decimals = denom.precision().abs() as usize;
let real = format!("{:0width$}", satoshi, width = nb_decimals);
if real.len() == nb_decimals {
write!(f, "0.{}", &real[real.len() - nb_decimals..])?;
} else {
write!(
f,
"{}.{}",
&real[0..(real.len() - nb_decimals)],
&real[real.len() - nb_decimals..]
)?;
}
} else {
// denom.precision() == 0
write!(f, "{}", satoshi)?;
}
Ok(())
}
/// Amount
///
/// The [Amount] type can be used to express Bitcoin amounts that supports
/// arithmetic and conversion to various denominations.
///
///
/// Warning!
///
/// This type implements several arithmetic operations from [std::ops].
/// To prevent errors due to overflow or underflow when using these operations,
/// it is advised to instead use the checked arithmetic methods whose names
/// start with `checked_`. The operations from [std::ops] that [Amount]
/// implements will panic when overflow or underflow occurs. Also note that
/// since the internal representation of amounts is unsigned, subtracting below
/// zero is considered an underflow and will cause a panic if you're not using
/// the checked arithmetic methods.
///
#[derive(Copy, Clone, Hash)]
pub struct Amount(u64);
impl Amount {
/// The zero amount.
pub const ZERO: Amount = Amount(0);
/// Exactly one satoshi.
pub const ONE_SAT: Amount = Amount(1);
/// Exactly one bitcoin.
pub const ONE_BTC: Amount = Amount(100_000_000);
/// Create an [Amount] with satoshi precision and the given number of satoshis.
pub fn from_sat(satoshi: u64) -> Amount {
Amount(satoshi)
}
/// Get the number of satoshis in this [Amount].
pub fn as_sat(self) -> u64 {
self.0
}
/// The maximum value of an [Amount].
pub fn max_value() -> Amount {
Amount(u64::max_value())
}
/// The minimum value of an [Amount].
pub fn min_value() -> Amount {
Amount(u64::min_value())
}
/// Convert from a value expressing bitcoins to an [Amount].
pub fn from_btc(btc: f64) -> Result {
Amount::from_float_in(btc, Denomination::Bitcoin)
}
/// Parse a decimal string as a value in the given denomination.
///
/// Note: This only parses the value string. If you want to parse a value
/// with denomination, use [FromStr].
pub fn from_str_in(s: &str, denom: Denomination) -> Result {
let (negative, satoshi) = parse_signed_to_satoshi(s, denom)?;
if negative {
return Err(ParseAmountError::Negative);
}
if satoshi > i64::max_value() as u64 {
return Err(ParseAmountError::TooBig);
}
Ok(Amount::from_sat(satoshi))
}
/// Parses amounts with denomination suffix like they are produced with
/// [to_string_with_denomination] or with [fmt::Display].
/// If you want to parse only the amount without the denomination,
/// use [from_str_in].
pub fn from_str_with_denomination(s: &str) -> Result {
let mut split = s.splitn(3, " ");
let amt_str = split.next().unwrap();
let denom_str = split.next().ok_or(ParseAmountError::InvalidFormat)?;
if split.next().is_some() {
return Err(ParseAmountError::InvalidFormat);
}
Ok(Amount::from_str_in(amt_str, denom_str.parse()?)?)
}
/// Express this [Amount] as a floating-point value in the given denomination.
///
/// Please be aware of the risk of using floating-point numbers.
pub fn to_float_in(&self, denom: Denomination) -> f64 {
f64::from_str(&self.to_string_in(denom)).unwrap()
}
/// Express this [Amount] as a floating-point value in Bitcoin.
///
/// Equivalent to `to_float_in(Denomination::Bitcoin)`.
///
/// Please be aware of the risk of using floating-point numbers.
pub fn as_btc(&self) -> f64 {
self.to_float_in(Denomination::Bitcoin)
}
/// Convert this [Amount] in floating-point notation with a given
/// denomination.
/// Can return error if the amount is too big, too precise or negative.
///
/// Please be aware of the risk of using floating-point numbers.
pub fn from_float_in(value: f64, denom: Denomination) -> Result {
if value < 0.0 {
return Err(ParseAmountError::Negative);
}
// This is inefficient, but the safest way to deal with this. The parsing logic is safe.
// Any performance-critical application should not be dealing with floats.
Amount::from_str_in(&value.to_string(), denom)
}
/// Format the value of this [Amount] in the given denomination.
///
/// Does not include the denomination.
pub fn fmt_value_in(&self, f: &mut fmt::Write, denom: Denomination) -> fmt::Result {
fmt_satoshi_in(self.as_sat(), false, f, denom)
}
/// Get a string number of this [Amount] in the given denomination.
///
/// Does not include the denomination.
pub fn to_string_in(&self, denom: Denomination) -> String {
let mut buf = String::new();
self.fmt_value_in(&mut buf, denom).unwrap();
buf
}
/// Get a formatted string of this [Amount] in the given denomination,
/// suffixed with the abbreviation for the denomination.
pub fn to_string_with_denomination(&self, denom: Denomination) -> String {
let mut buf = String::new();
self.fmt_value_in(&mut buf, denom).unwrap();
write!(buf, " {}", denom).unwrap();
buf
}
// Some arithmetic that doesn't fit in `std::ops` traits.
/// Checked addition.
/// Returns [None] if overflow occurred.
pub fn checked_add(self, rhs: Amount) -> Option {
self.0.checked_add(rhs.0).map(Amount)
}
/// Checked subtraction.
/// Returns [None] if overflow occurred.
pub fn checked_sub(self, rhs: Amount) -> Option {
self.0.checked_sub(rhs.0).map(Amount)
}
/// Checked multiplication.
/// Returns [None] if overflow occurred.
pub fn checked_mul(self, rhs: u64) -> Option {
self.0.checked_mul(rhs).map(Amount)
}
/// Checked integer division.
/// Be aware that integer division loses the remainder if no exact division
/// can be made.
/// Returns [None] if overflow occurred.
pub fn checked_div(self, rhs: u64) -> Option {
self.0.checked_div(rhs).map(Amount)
}
/// Checked remainder.
/// Returns [None] if overflow occurred.
pub fn checked_rem(self, rhs: u64) -> Option {
self.0.checked_rem(rhs).map(Amount)
}
/// Convert to a signed amount.
pub fn to_signed(self) -> Result {
if self.as_sat() > SignedAmount::max_value().as_sat() as u64 {
Err(ParseAmountError::TooBig)
} else {
Ok(SignedAmount::from_sat(self.as_sat() as i64))
}
}
}
impl default::Default for Amount {
fn default() -> Self {
Amount::ZERO
}
}
impl PartialEq for Amount {
fn eq(&self, other: &Amount) -> bool {
PartialEq::eq(&self.0, &other.0)
}
}
impl Eq for Amount {}
impl PartialOrd for Amount {
fn partial_cmp(&self, other: &Amount) -> Option<::std::cmp::Ordering> {
PartialOrd::partial_cmp(&self.0, &other.0)
}
}
impl Ord for Amount {
fn cmp(&self, other: &Amount) -> ::std::cmp::Ordering {
Ord::cmp(&self.0, &other.0)
}
}
impl fmt::Debug for Amount {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "Amount({} satoshi)", self.as_sat())
}
}
// No one should depend on a binding contract for Display for this type.
// Just using Bitcoin denominated string.
impl fmt::Display for Amount {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
self.fmt_value_in(f, Denomination::Bitcoin)?;
write!(f, " {}", Denomination::Bitcoin)
}
}
impl ops::Add for Amount {
type Output = Amount;
fn add(self, rhs: Amount) -> Self::Output {
self.checked_add(rhs).expect("Amount addition error")
}
}
impl ops::AddAssign for Amount {
fn add_assign(&mut self, other: Amount) {
*self = *self + other
}
}
impl ops::Sub for Amount {
type Output = Amount;
fn sub(self, rhs: Amount) -> Self::Output {
self.checked_sub(rhs).expect("Amount subtraction error")
}
}
impl ops::SubAssign for Amount {
fn sub_assign(&mut self, other: Amount) {
*self = *self - other
}
}
impl ops::Rem for Amount {
type Output = Amount;
fn rem(self, modulus: u64) -> Self {
self.checked_rem(modulus).expect("Amount remainder error")
}
}
impl ops::RemAssign for Amount {
fn rem_assign(&mut self, modulus: u64) {
*self = *self % modulus
}
}
impl ops::Mul for Amount {
type Output = Amount;
fn mul(self, rhs: u64) -> Self::Output {
self.checked_mul(rhs).expect("Amount multiplication error")
}
}
impl ops::MulAssign for Amount {
fn mul_assign(&mut self, rhs: u64) {
*self = *self * rhs
}
}
impl ops::Div for Amount {
type Output = Amount;
fn div(self, rhs: u64) -> Self::Output {
self.checked_div(rhs).expect("Amount division error")
}
}
impl ops::DivAssign for Amount {
fn div_assign(&mut self, rhs: u64) {
*self = *self / rhs
}
}
impl FromStr for Amount {
type Err = ParseAmountError;
fn from_str(s: &str) -> Result {
Amount::from_str_with_denomination(s)
}
}
/// SignedAmount
///
/// The [SignedAmount] type can be used to express Bitcoin amounts that supports
/// arithmetic and conversion to various denominations.
///
///
/// Warning!
///
/// This type implements several arithmetic operations from [std::ops].
/// To prevent errors due to overflow or underflow when using these operations,
/// it is advised to instead use the checked arithmetic methods whose names
/// start with `checked_`. The operations from [std::ops] that [Amount]
/// implements will panic when overflow or underflow occurs.
///
#[derive(Copy, Clone, Hash)]
pub struct SignedAmount(i64);
impl SignedAmount {
/// The zero amount.
pub const ZERO: SignedAmount = SignedAmount(0);
/// Exactly one satoshi.
pub const ONE_SAT: SignedAmount = SignedAmount(1);
/// Exactly one bitcoin.
pub const ONE_BTC: SignedAmount = SignedAmount(100_000_000);
/// Create an [SignedAmount] with satoshi precision and the given number of satoshis.
pub fn from_sat(satoshi: i64) -> SignedAmount {
SignedAmount(satoshi)
}
/// Get the number of satoshis in this [SignedAmount].
pub fn as_sat(self) -> i64 {
self.0
}
/// The maximum value of an [SignedAmount].
pub fn max_value() -> SignedAmount {
SignedAmount(i64::max_value())
}
/// The minimum value of an [SignedAmount].
pub fn min_value() -> SignedAmount {
SignedAmount(i64::min_value())
}
/// Convert from a value expressing bitcoins to an [SignedAmount].
pub fn from_btc(btc: f64) -> Result {
SignedAmount::from_float_in(btc, Denomination::Bitcoin)
}
/// Parse a decimal string as a value in the given denomination.
///
/// Note: This only parses the value string. If you want to parse a value
/// with denomination, use [FromStr].
pub fn from_str_in(s: &str, denom: Denomination) -> Result {
let (negative, satoshi) = parse_signed_to_satoshi(s, denom)?;
if satoshi > i64::max_value() as u64 {
return Err(ParseAmountError::TooBig);
}
Ok(match negative {
true => SignedAmount(-1 * satoshi as i64),
false => SignedAmount(satoshi as i64),
})
}
/// Parses amounts with denomination suffix like they are produced with
/// [to_string_with_denomination] or with [fmt::Display].
/// If you want to parse only the amount without the denomination,
/// use [from_str_in].
pub fn from_str_with_denomination(s: &str) -> Result {
let mut split = s.splitn(3, " ");
let amt_str = split.next().unwrap();
let denom_str = split.next().ok_or(ParseAmountError::InvalidFormat)?;
if split.next().is_some() {
return Err(ParseAmountError::InvalidFormat);
}
Ok(SignedAmount::from_str_in(amt_str, denom_str.parse()?)?)
}
/// Express this [SignedAmount] as a floating-point value in the given denomination.
///
/// Please be aware of the risk of using floating-point numbers.
pub fn to_float_in(&self, denom: Denomination) -> f64 {
f64::from_str(&self.to_string_in(denom)).unwrap()
}
/// Express this [SignedAmount] as a floating-point value in Bitcoin.
///
/// Equivalent to `to_float_in(Denomination::Bitcoin)`.
///
/// Please be aware of the risk of using floating-point numbers.
pub fn as_btc(&self) -> f64 {
self.to_float_in(Denomination::Bitcoin)
}
/// Convert this [SignedAmount] in floating-point notation with a given
/// denomination.
/// Can return error if the amount is too big, too precise or negative.
///
/// Please be aware of the risk of using floating-point numbers.
pub fn from_float_in(
value: f64,
denom: Denomination,
) -> Result {
// This is inefficient, but the safest way to deal with this. The parsing logic is safe.
// Any performance-critical application should not be dealing with floats.
SignedAmount::from_str_in(&value.to_string(), denom)
}
/// Format the value of this [SignedAmount] in the given denomination.
///
/// Does not include the denomination.
pub fn fmt_value_in(&self, f: &mut fmt::Write, denom: Denomination) -> fmt::Result {
fmt_satoshi_in(self.as_sat().abs() as u64, self.is_negative(), f, denom)
}
/// Get a string number of this [SignedAmount] in the given denomination.
///
/// Does not include the denomination.
pub fn to_string_in(&self, denom: Denomination) -> String {
let mut buf = String::new();
self.fmt_value_in(&mut buf, denom).unwrap();
buf
}
/// Get a formatted string of this [SignedAmount] in the given denomination,
/// suffixed with the abbreviation for the denomination.
pub fn to_string_with_denomination(&self, denom: Denomination) -> String {
let mut buf = String::new();
self.fmt_value_in(&mut buf, denom).unwrap();
write!(buf, " {}", denom).unwrap();
buf
}
// Some arithmetic that doesn't fit in `std::ops` traits.
/// Get the absolute value of this [SignedAmount].
pub fn abs(self) -> SignedAmount {
SignedAmount(self.0.abs())
}
/// Returns a number representing sign of this [SignedAmount].
///
/// - `0` if the amount is zero
/// - `1` if the amount is positive
/// - `-1` if the amount is negative
pub fn signum(self) -> i64 {
self.0.signum()
}
/// Returns `true` if this [SignedAmount] is positive and `false` if
/// this [SignedAmount] is zero or negative.
pub fn is_positive(self) -> bool {
self.0.is_positive()
}
/// Returns `true` if this [SignedAmount] is negative and `false` if
/// this [SignedAmount] is zero or positive.
pub fn is_negative(self) -> bool {
self.0.is_negative()
}
/// Checked addition.
/// Returns [None] if overflow occurred.
pub fn checked_add(self, rhs: SignedAmount) -> Option {
self.0.checked_add(rhs.0).map(SignedAmount)
}
/// Checked subtraction.
/// Returns [None] if overflow occurred.
pub fn checked_sub(self, rhs: SignedAmount) -> Option {
self.0.checked_sub(rhs.0).map(SignedAmount)
}
/// Checked multiplication.
/// Returns [None] if overflow occurred.
pub fn checked_mul(self, rhs: i64) -> Option {
self.0.checked_mul(rhs).map(SignedAmount)
}
/// Checked integer division.
/// Be aware that integer division loses the remainder if no exact division
/// can be made.
/// Returns [None] if overflow occurred.
pub fn checked_div(self, rhs: i64) -> Option {
self.0.checked_div(rhs).map(SignedAmount)
}
/// Checked remainder.
/// Returns [None] if overflow occurred.
pub fn checked_rem(self, rhs: i64) -> Option {
self.0.checked_rem(rhs).map(SignedAmount)
}
/// Subtraction that doesn't allow negative [SignedAmount]s.
/// Returns [None] if either [self], [rhs] or the result is strictly negative.
pub fn positive_sub(self, rhs: SignedAmount) -> Option {
if self.is_negative() || rhs.is_negative() || rhs > self {
None
} else {
self.checked_sub(rhs)
}
}
/// Convert to an unsigned amount.
pub fn to_unsigned(self) -> Result {
if self.is_negative() {
Err(ParseAmountError::Negative)
} else {
Ok(Amount::from_sat(self.as_sat() as u64))
}
}
}
impl default::Default for SignedAmount {
fn default() -> Self {
SignedAmount::ZERO
}
}
impl PartialEq for SignedAmount {
fn eq(&self, other: &SignedAmount) -> bool {
PartialEq::eq(&self.0, &other.0)
}
}
impl Eq for SignedAmount {}
impl PartialOrd for SignedAmount {
fn partial_cmp(&self, other: &SignedAmount) -> Option<::std::cmp::Ordering> {
PartialOrd::partial_cmp(&self.0, &other.0)
}
}
impl Ord for SignedAmount {
fn cmp(&self, other: &SignedAmount) -> ::std::cmp::Ordering {
Ord::cmp(&self.0, &other.0)
}
}
impl fmt::Debug for SignedAmount {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "SignedAmount({} satoshi)", self.as_sat())
}
}
// No one should depend on a binding contract for Display for this type.
// Just using Bitcoin denominated string.
impl fmt::Display for SignedAmount {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
self.fmt_value_in(f, Denomination::Bitcoin)?;
write!(f, " {}", Denomination::Bitcoin)
}
}
impl ops::Add for SignedAmount {
type Output = SignedAmount;
fn add(self, rhs: SignedAmount) -> Self::Output {
self.checked_add(rhs).expect("SignedAmount addition error")
}
}
impl ops::AddAssign for SignedAmount {
fn add_assign(&mut self, other: SignedAmount) {
*self = *self + other
}
}
impl ops::Sub for SignedAmount {
type Output = SignedAmount;
fn sub(self, rhs: SignedAmount) -> Self::Output {
self.checked_sub(rhs).expect("SignedAmount subtraction error")
}
}
impl ops::SubAssign for SignedAmount {
fn sub_assign(&mut self, other: SignedAmount) {
*self = *self - other
}
}
impl ops::Rem for SignedAmount {
type Output = SignedAmount;
fn rem(self, modulus: i64) -> Self {
self.checked_rem(modulus).expect("SignedAmount remainder error")
}
}
impl ops::RemAssign for SignedAmount {
fn rem_assign(&mut self, modulus: i64) {
*self = *self % modulus
}
}
impl ops::Mul for SignedAmount {
type Output = SignedAmount;
fn mul(self, rhs: i64) -> Self::Output {
self.checked_mul(rhs).expect("SignedAmount multiplication error")
}
}
impl ops::MulAssign for SignedAmount {
fn mul_assign(&mut self, rhs: i64) {
*self = *self * rhs
}
}
impl ops::Div for SignedAmount {
type Output = SignedAmount;
fn div(self, rhs: i64) -> Self::Output {
self.checked_div(rhs).expect("SignedAmount division error")
}
}
impl ops::DivAssign for SignedAmount {
fn div_assign(&mut self, rhs: i64) {
*self = *self / rhs
}
}
impl FromStr for SignedAmount {
type Err = ParseAmountError;
fn from_str(s: &str) -> Result {
SignedAmount::from_str_with_denomination(s)
}
}
#[cfg(feature = "serde")]
pub mod serde {
// methods are implementation of a standardized serde-specific signature
#![allow(missing_docs)]
//! This module adds serde serialization and deserialization support for Amounts.
//! Since there is not a default way to serialize and deserialize Amounts, multiple
//! ways are supported and it's up to the user to decide which serialiation to use.
//! The provided modules can be used as follows:
//!
//! ```rust,ignore
//! use serde::{Serialize, Deserialize};
//! use bitcoin::Amount;
//!
//! #[derive(Serialize, Deserialize)]
//! pub struct HasAmount {
//! #[serde(with = "bitcoin::util::amount::serde::as_btc")]
//! pub amount: Amount,
//! }
//! ```
use serde::{Deserialize, Deserializer, Serialize, Serializer};
use util::amount::{Amount, Denomination, SignedAmount};
/// This trait is used only to avoid code duplication and naming collisions
/// of the different serde serialization crates.
pub trait SerdeAmount: Copy + Sized {
fn ser_sat(self, s: S) -> Result;
fn des_sat<'d, D: Deserializer<'d>>(d: D) -> Result;
fn ser_btc(self, s: S) -> Result;
fn des_btc<'d, D: Deserializer<'d>>(d: D) -> Result;
}
impl SerdeAmount for Amount {
fn ser_sat(self, s: S) -> Result {
u64::serialize(&self.as_sat(), s)
}
fn des_sat<'d, D: Deserializer<'d>>(d: D) -> Result {
Ok(Amount::from_sat(u64::deserialize(d)?))
}
fn ser_btc(self, s: S) -> Result {
f64::serialize(&self.to_float_in(Denomination::Bitcoin), s)
}
fn des_btc<'d, D: Deserializer<'d>>(d: D) -> Result {
use serde::de::Error;
Ok(Amount::from_btc(f64::deserialize(d)?).map_err(D::Error::custom)?)
}
}
impl SerdeAmount for SignedAmount {
fn ser_sat(self, s: S) -> Result {
i64::serialize(&self.as_sat(), s)
}
fn des_sat<'d, D: Deserializer<'d>>(d: D) -> Result {
Ok(SignedAmount::from_sat(i64::deserialize(d)?))
}
fn ser_btc(self, s: S) -> Result {
f64::serialize(&self.to_float_in(Denomination::Bitcoin), s)
}
fn des_btc<'d, D: Deserializer<'d>>(d: D) -> Result {
use serde::de::Error;
Ok(SignedAmount::from_btc(f64::deserialize(d)?).map_err(D::Error::custom)?)
}
}
pub mod as_sat {
//! Serialize and deserialize [Amount] as real numbers denominated in satoshi.
//! Use with `#[serde(with = "amount::serde::as_sat")]`.
use serde::{Deserialize, Deserializer, Serialize, Serializer};
use util::amount::serde::SerdeAmount;
pub fn serialize(a: &A, s: S) -> Result {
a.ser_sat(s)
}
pub fn deserialize<'d, A: SerdeAmount, D: Deserializer<'d>>(d: D) -> Result {
A::des_sat(d)
}
pub mod opt {
//! Serialize and deserialize [Optoin] as real numbers denominated in satoshi.
//! Use with `#[serde(default, with = "amount::serde::as_sat::opt")]`.
use serde::{Deserialize, Deserializer, Serializer};
use util::amount::serde::SerdeAmount;
pub fn serialize(
a: &Option,
s: S,
) -> Result {
match *a {
Some(a) => a.ser_sat(s),
None => s.serialize_none(),
}
}
pub fn deserialize<'d, A: SerdeAmount, D: Deserializer<'d>>(
d: D,
) -> Result