Expand description
This crate provides a fast implementation of Decimal
fixed-point
arithmetics.
It is targeted at typical business applications, dealing with numbers
representing quantities, money and the like, not at scientific computations,
for which the accuracy of floating point math is - in most cases - sufficient.
Objectives
- “Exact” representation of decimal numbers (no deviation as with binary floating point numbers)
- No hidden rounding errors (as inherent to floating point math)
- Very fast operations (by mapping them to integer ops)
- Range of representable decimal numbers sufficient for typical business applications
At the binary level a Decimal
number is represented as a coefficient (stored
as an i128
value) combined with a value specifying the number of fractional
decimal digits (stored as a u8
). The latter is limited to a value given by
the constant MAX_N_FRAC_DIGITS
= 18.
Status
Work in progess, but most of the API is stable.
Getting started
Add fpdec
to your Cargo.toml
:
[dependencies]
fpdec = "0.5"
Usage
A Decimal
number can be created in different ways.
The easiest method is to use the procedural macro Dec
:
let d = Dec!(-17.5);
assert_eq!(d.to_string(), "-17.5");
Alternatively you can convert an integer, a float or a string to a Decimal
:
let d = Decimal::from(297_i32);
assert_eq!(d.to_string(), "297");
let d = Decimal::try_from(83.25_f64)?;
assert_eq!(d.to_string(), "83.25");
let d = Decimal::from_str("38.2070")?;
assert_eq!(d.to_string(), "38.2070");
The sign of a Decimal
can be inverted using the unary minus operator and a
Decimal
instance can be compared to other instances of type Decimal
or all
basic types of integers (besides u128):
let x = Dec!(129.24);
let y = -x;
assert_eq!(y.to_string(), "-129.24");
assert!(-129_i64 > y);
let z = -y;
assert_eq!(x, z);
let z = Dec!(0.00097);
assert!(x > z);
assert!(y <= z);
assert!(z != 7_u32);
assert!(7_u32 == Dec!(7.00));
Decimal
supports all five binary numerical operators +, -, *, /, and %, with
two Decimal
s or with a Decimal
and a basic integer (besides u128):
let x = Dec!(17.5);
let y = Dec!(6.40);
let z = x + y;
assert_eq!(z.to_string(), "23.90");
let z = x - y;
assert_eq!(z.to_string(), "11.10");
let z = x * y;
assert_eq!(z.to_string(), "112.000");
let z = x / y;
assert_eq!(z.to_string(), "2.734375");
let z = x % y;
assert_eq!(z.to_string(), "4.70");
let x = Dec!(17.5);
let y = -5_i64;
let z = x + y;
assert_eq!(z.to_string(), "12.5");
let z = x - y;
assert_eq!(z.to_string(), "22.5");
let z = y * x;
assert_eq!(z.to_string(), "-87.5");
let z = x / y;
assert_eq!(z.to_string(), "-3.5");
let z = x % y;
assert_eq!(z.to_string(), "2.5");
The results of Multiplication or Division are not exact in any case. If the
number of fractional decimal digits of the exact result would exceed
MAX_N_FRAC_DIGITS
fractional decimal digits, the result given is rounded to
fit this limit.
let x = Dec!(1e-10);
let y = Dec!(75e-9);
let z = x * y;
assert_eq!(z.to_string(), "0.000000000000000008");
let x = Dec!(1.);
let y = Dec!(3.);
let z = x / y;
assert_eq!(z.to_string(), "0.333333333333333333");
All these binary numeric operators panic if the result is not representable as
a Decimal
according to the constraints stated above. In addition, there are
functions implementing “checked” variants of the operators which return
Option::None
instead of panicking.
For Multiplication and Division there are also functions which return a result rounded to a given number of fractional digits:
let x = Dec!(17.5);
let y = Dec!(6.47);
let z: Decimal = x.mul_rounded(y, 1);
assert_eq!(z.to_string(), "113.2");
let z: Decimal = x.div_rounded(y, 3);
assert_eq!(z.to_string(), "2.705");
Macros
Macro used to convert a number literal into a Decimal
.
Structs
Represents a decimal number as a coefficient (i128
) combined with a
value (u8
) specifying the number of fractional decimal digits.
Enums
An error which can be returned from converting numbers to Decimal
or from
binary operators on Decimal
.
An error which can be returned when parsing a decimal literal.
Enum representing the different methods used when rounding a number.
Constants
The maximum number of fractional decimal digits supported by Decimal
.
Traits
Conversion of a number into an equivalent ratio of integers.
Checked addition.
Computes self + rhs
.
Returns None
if the result can not be represented by the Output
type.
Checked division.
Computes self / rhs
.
Returns None
if the result can not be represented by the Output
type.
Checked multiplication.
Computes self * rhs
.
Returns None
if the result can not be represented by the Output
type.
Checked remainder.
Computes self % rhs
.
Returns None
if the result can not be represented by the Output
type.
Checked subtraction.
Computes self - rhs
.
Returns None
if the result can not be represented by the Output
type.
Division giving a result rounded to fit a given number of fractional digits.
Multiplication giving a result rounded to a given number of fractional digits.
Rounding a number to the nearest integer multiple of a given quantum.
Rounding a number to a given number of fractional digits.