Float
Double precision (64-bit) floating-point numbers in IEEE 754 representation.
This module contains common floating-point constants and utility functions.
Notation for special values in the documentation below:
+inf
: Positive infinity
-inf
: Negative infinity
NaN
: "not a number" (can have different sign bit values, but NaN != NaN
regardless of the sign).
Note: Floating point numbers have limited precision and operations may inherently result in numerical errors.
Examples of numerical errors:
0.1 + 0.1 + 0.1 == 0.3 // => false
1e16 + 1.0 != 1e16 // => false
(and many more cases)
Advice:
Floating point number comparisons by
==
or!=
are discouraged. Instead, it is better to compare floating-point numbers with a numerical tolerance, called epsilon.Example:
import Float "mo:base/Float";
let x = 0.1 + 0.1 + 0.1;
let y = 0.3;
let epsilon = 1e-6; // This depends on the application case (needs a numerical error analysis).
Float.equalWithin(x, y, epsilon) // => trueFor absolute precision, it is recommened to encode the fraction number as a pair of a Nat for the base and a Nat for the exponent (decimal point).
NaN sign:
- The NaN sign is only applied by
abs
,neg
, andcopySign
. Other operations can have an arbitrary sign bit for NaN results.
Type Float
type Float = Prim.Types.Float
64-bit floating point number type.
Value pi
let pi : Float
Ratio of the circumference of a circle to its diameter. Note: Limited precision.
Value e
let e : Float
Base of the natural logarithm. Note: Limited precision.
Function isNaN
func isNaN(number : Float) : Bool
Determines whether the number
is a NaN
("not a number" in the floating point representation).
Notes:
- Equality test of
NaN
with itself or another number is alwaysfalse
. - There exist many internal
NaN
value representations, such as positive and negative NaN, signalling and quiet NaNs, each with many different bit representations.
Example:
import Float "mo:base/Float";
Float.isNaN(0.0/0.0) // => true
Value abs
let abs : (x : Float) -> Float
Returns the absolute value of x
.
Special cases:
abs(+inf) => +inf
abs(-inf) => +inf
abs(-NaN) => +NaN
abs(-0.0) => 0.0
Example:
import Float "mo:base/Float";
Float.abs(-1.2) // => 1.2
Value sqrt
let sqrt : (x : Float) -> Float
Returns the square root of x
.
Special cases:
sqrt(+inf) => +inf
sqrt(-0.0) => -0.0
sqrt(x) => NaN if x < 0.0
sqrt(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.sqrt(6.25) // => 2.5
Value ceil
let ceil : (x : Float) -> Float
Returns the smallest integral float greater than or equal to x
.
Special cases:
ceil(+inf) => +inf
ceil(-inf) => -inf
ceil(NaN) => NaN
ceil(0.0) => 0.0
ceil(-0.0) => -0.0
Example:
import Float "mo:base/Float";
Float.ceil(1.2) // => 2.0
Value floor
let floor : (x : Float) -> Float
Returns the largest integral float less than or equal to x
.
Special cases:
floor(+inf) => +inf
floor(-inf) => -inf
floor(NaN) => NaN
floor(0.0) => 0.0
floor(-0.0) => -0.0
Example:
import Float "mo:base/Float";
Float.floor(1.2) // => 1.0
Value trunc
let trunc : (x : Float) -> Float
Returns the nearest integral float not greater in magnitude than x
.
This is equilvent to returning x
with truncating its decimal places.
Special cases:
trunc(+inf) => +inf
trunc(-inf) => -inf
trunc(NaN) => NaN
trunc(0.0) => 0.0
trunc(-0.0) => -0.0
Example:
import Float "mo:base/Float";
Float.trunc(2.75) // => 2.0
Value nearest
let nearest : (x : Float) -> Float
Returns the nearest integral float to x
.
A decimal place of exactly .5 is rounded up for x > 0
and rounded down for x < 0
Special cases:
nearest(+inf) => +inf
nearest(-inf) => -inf
nearest(NaN) => NaN
nearest(0.0) => 0.0
nearest(-0.0) => -0.0
Example:
import Float "mo:base/Float";
Float.nearest(2.75) // => 3.0
Value copySign
let copySign : (x : Float, y : Float) -> Float
Returns x
if x
and y
have same sign, otherwise x
with negated sign.
The sign bit of zero, infinity, and NaN
is considered.
Example:
import Float "mo:base/Float";
Float.copySign(1.2, -2.3) // => -1.2
Value min
let min : (x : Float, y : Float) -> Float
Returns the smaller value of x
and y
.
Special cases:
min(NaN, y) => NaN for any Float y
min(x, NaN) => NaN for any Float x
Example:
import Float "mo:base/Float";
Float.min(1.2, -2.3) // => -2.3 (with numerical imprecision)
Value max
let max : (x : Float, y : Float) -> Float
Returns the larger value of x
and y
.
Special cases:
max(NaN, y) => NaN for any Float y
max(x, NaN) => NaN for any Float x
Example:
import Float "mo:base/Float";
Float.max(1.2, -2.3) // => 1.2
Value sin
let sin : (x : Float) -> Float
Returns the sine of the radian angle x
.
Special cases:
sin(+inf) => NaN
sin(-inf) => NaN
sin(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.sin(Float.pi / 2) // => 1.0
Value cos
let cos : (x : Float) -> Float
Returns the cosine of the radian angle x
.
Special cases:
cos(+inf) => NaN
cos(-inf) => NaN
cos(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.cos(Float.pi / 2) // => 0.0 (with numerical imprecision)
Value tan
let tan : (x : Float) -> Float
Returns the tangent of the radian angle x
.
Special cases:
tan(+inf) => NaN
tan(-inf) => NaN
tan(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.tan(Float.pi / 4) // => 1.0 (with numerical imprecision)
Value arcsin
let arcsin : (x : Float) -> Float
Returns the arc sine of x
in radians.
Special cases:
arcsin(x) => NaN if x > 1.0
arcsin(x) => NaN if x < -1.0
arcsin(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.arcsin(1.0) // => Float.pi / 2
Value arccos
let arccos : (x : Float) -> Float
Returns the arc cosine of x
in radians.
Special cases:
arccos(x) => NaN if x > 1.0
arccos(x) => NaN if x < -1.0
arcos(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.arccos(1.0) // => 0.0
Value arctan
let arctan : (x : Float) -> Float
Returns the arc tangent of x
in radians.
Special cases:
arctan(+inf) => pi / 2
arctan(-inf) => -pi / 2
arctan(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.arctan(1.0) // => Float.pi / 4
Value arctan2
let arctan2 : (y : Float, x : Float) -> Float
Given (y,x)
, returns the arc tangent in radians of y/x
based on the signs of both values to determine the correct quadrant.
Special cases:
arctan2(0.0, 0.0) => 0.0
arctan2(-0.0, 0.0) => -0.0
arctan2(0.0, -0.0) => pi
arctan2(-0.0, -0.0) => -pi
arctan2(+inf, +inf) => pi / 4
arctan2(+inf, -inf) => 3 * pi / 4
arctan2(-inf, +inf) => -pi / 4
arctan2(-inf, -inf) => -3 * pi / 4
arctan2(NaN, x) => NaN for any Float x
arctan2(y, NaN) => NaN for any Float y
Example:
import Float "mo:base/Float";
let sqrt2over2 = Float.sqrt(2) / 2;
Float.arctan2(sqrt2over2, sqrt2over2) // => Float.pi / 4
Value exp
let exp : (x : Float) -> Float
Returns the value of e
raised to the x
-th power.
Special cases:
exp(+inf) => +inf
exp(-inf) => 0.0
exp(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.exp(1.0) // => Float.e
Value log
let log : (x : Float) -> Float
Returns the natural logarithm (base-e
) of x
.
Special cases:
log(0.0) => -inf
log(-0.0) => -inf
log(x) => NaN if x < 0.0
log(+inf) => +inf
log(NaN) => NaN
Example:
import Float "mo:base/Float";
Float.log(Float.e) // => 1.0
Function format
func format(fmt : {#fix : Nat8; #exp : Nat8; #gen : Nat8; #hex : Nat8; #exact}, x : Float) : Text
Formatting. format(fmt, x)
formats x
to Text
according to the
formatting directive fmt
, which can take one of the following forms:
#fix prec
as fixed-point format withprec
digits#exp prec
as exponential format withprec
digits#gen prec
as generic format withprec
digits#hex prec
as hexadecimal format withprec
digits#exact
as exact format that can be decoded without loss.
-0.0
is formatted with negative sign bit.
Positive infinity is formatted as inf
.
Negative infinity is formatted as -inf
.
NaN
is formatted as NaN
or -NaN
depending on its sign bit.
Example:
import Float "mo:base/Float";
Float.format(#exp 3, 123.0) // => "1.230e+02"
Value toText
let toText : Float -> Text
Conversion to Text. Use format(fmt, x)
for more detailed control.
-0.0
is formatted with negative sign bit.
Positive infinity is formatted as inf
.
Negative infinity is formatted as -inf
.
NaN
is formatted as NaN
or -NaN
depending on its sign bit.
Example:
import Float "mo:base/Float";
Float.toText(0.12) // => "0.12"
Value toInt64
let toInt64 : Float -> Int64
Conversion to Int64 by truncating Float, equivalent to toInt64(trunc(f))
Traps if the floating point number is larger or smaller than the representable Int64.
Also traps for inf
, -inf
, and NaN
.
Example:
import Float "mo:base/Float";
Float.toInt64(-12.3) // => -12
Value fromInt64
let fromInt64 : Int64 -> Float
Conversion from Int64.
Note: The floating point number may be imprecise for large or small Int64.
Example:
import Float "mo:base/Float";
Float.fromInt64(-42) // => -42.0
Value toInt
let toInt : Float -> Int
Conversion to Int.
Traps for inf
, -inf
, and NaN
.
Example:
import Float "mo:base/Float";
Float.toInt(1.2e6) // => +1_200_000
Value fromInt
let fromInt : Int -> Float
Conversion from Int. May result in Inf
.
Note: The floating point number may be imprecise for large or small Int values.
Returns inf
if the integer is greater than the maximum floating point number.
Returns -inf
if the integer is less than the minimum floating point number.
Example:
import Float "mo:base/Float";
Float.fromInt(-123) // => -123.0
Function equal
func equal(x : Float, y : Float) : Bool
Returns x == y
.
@deprecated Use Float.equalWithin()
as this function does not consider numerical errors.
Function notEqual
func notEqual(x : Float, y : Float) : Bool
Returns x != y
.
@deprecated Use Float.notEqualWithin()
as this function does not consider numerical errors.
Function equalWithin
func equalWithin(x : Float, y : Float, epsilon : Float) : Bool
Determines whether x
is equal to y
within the defined tolerance of epsilon
.
The epsilon
considers numerical erros, see comment above.
Equivalent to Float.abs(x - y) <= epsilon
for a non-negative epsilon.
Traps if epsilon
is negative or NaN
.
Special cases:
equal(+0.0, -0.0, epsilon) => true for any `epsilon >= 0.0`
equal(-0.0, +0.0, epsilon) => true for any `epsilon >= 0.0`
equal(+inf, +inf, epsilon) => true for any `epsilon >= 0.0`
equal(-inf, -inf, epsilon) => true for any `epsilon >= 0.0`
equal(x, NaN, epsilon) => false for any x and `epsilon >= 0.0`
equal(NaN, y, epsilon) => false for any y and `epsilon >= 0.0`
Example:
import Float "mo:base/Float";
let epsilon = 1e-6;
Float.equal(-12.3, -1.23e1, epsilon) // => true
Function notEqualWithin
func notEqualWithin(x : Float, y : Float, epsilon : Float) : Bool
Determines whether x
is not equal to y
within the defined tolerance of epsilon
.
The epsilon
considers numerical erros, see comment above.
Equivalent to not equal(x, y, epsilon)
.
Traps if epsilon
is negative or NaN
.
Special cases:
notEqual(+0.0, -0.0, epsilon) => false for any `epsilon >= 0.0`
notEqual(-0.0, +0.0, epsilon) => false for any `epsilon >= 0.0`
notEqual(+inf, +inf, epsilon) => false for any `epsilon >= 0.0`
notEqual(-inf, -inf, epsilon) => false for any `epsilon >= 0.0`
notEqual(x, NaN, epsilon) => true for any x and `epsilon >= 0.0`
notEqual(NaN, y, epsilon) => true for any y and `epsilon >= 0.0`
Example:
import Float "mo:base/Float";
let epsilon = 1e-6;
Float.notEqual(-12.3, -1.23e1, epsilon) // => false
Function less
func less(x : Float, y : Float) : Bool
Returns x < y
.
Special cases:
less(+0.0, -0.0) => false
less(-0.0, +0.0) => false
less(NaN, y) => false for any Float y
less(x, NaN) => false for any Float x
Example:
import Float "mo:base/Float";
Float.less(Float.e, Float.pi) // => true
Function lessOrEqual
func lessOrEqual(x : Float, y : Float) : Bool
Returns x <= y
.
Special cases:
lessOrEqual(+0.0, -0.0) => true
lessOrEqual(-0.0, +0.0) => true
lessOrEqual(NaN, y) => false for any Float y
lessOrEqual(x, NaN) => false for any Float x
Example:
import Float "mo:base/Float";
Float.lessOrEqual(0.123, 0.1234) // => true
Function greater
func greater(x : Float, y : Float) : Bool
Returns x > y
.
Special cases:
greater(+0.0, -0.0) => false
greater(-0.0, +0.0) => false
greater(NaN, y) => false for any Float y
greater(x, NaN) => false for any Float x
Example:
import Float "mo:base/Float";
Float.greater(Float.pi, Float.e) // => true
Function greaterOrEqual
func greaterOrEqual(x : Float, y : Float) : Bool
Returns x >= y
.
Special cases:
greaterOrEqual(+0.0, -0.0) => true
greaterOrEqual(-0.0, +0.0) => true
greaterOrEqual(NaN, y) => false for any Float y
greaterOrEqual(x, NaN) => false for any Float x
Example:
import Float "mo:base/Float";
Float.greaterOrEqual(0.1234, 0.123) // => true
Function compare
func compare(x : Float, y : Float) : {#less; #equal; #greater}
Defines a total order of x
and y
for use in sorting.
Note: Using this operation to determine equality or inequality is discouraged for two reasons:
- It does not consider numerical errors, see comment above. Use
equal(x, y)
ornotEqual(x, y)
to test for equality or inequality, respectively. NaN
are here considered equal if their sign matches, which is different to the standard equality by==
or when usingequal()
ornotEqual()
.
Total order:
- negative NaN (no distinction between signalling and quiet negative NaN)
- negative infinity
- negative numbers (including negative subnormal numbers in standard order)
- negative zero (
-0.0
) - positive zero (
+0.0
) - positive numbers (including positive subnormal numbers in standard order)
- positive infinity
- positive NaN (no distinction between signalling and quiet positive NaN)
Example:
import Float "mo:base/Float";
Float.compare(0.123, 0.1234) // => #less
Function neg
func neg(x : Float) : Float
Returns the negation of x
, -x
.
Changes the sign bit for infinity.
Special cases:
neg(+inf) => -inf
neg(-inf) => +inf
neg(+NaN) => -NaN
neg(-NaN) => +NaN
neg(+0.0) => -0.0
neg(-0.0) => +0.0
Example:
import Float "mo:base/Float";
Float.neg(1.23) // => -1.23
Function add
func add(x : Float, y : Float) : Float
Returns the sum of x
and y
, x + y
.
Note: Numerical errors may occur, see comment above.
Special cases:
add(+inf, y) => +inf if y is any Float except -inf and NaN
add(-inf, y) => -inf if y is any Float except +inf and NaN
add(+inf, -inf) => NaN
add(NaN, y) => NaN for any Float y
The same cases apply commutatively, i.e. for add(y, x)
.
Example:
import Float "mo:base/Float";
Float.add(1.23, 0.123) // => 1.353
Function sub
func sub(x : Float, y : Float) : Float
Returns the difference of x
and y
, x - y
.
Note: Numerical errors may occur, see comment above.
Special cases:
sub(+inf, y) => +inf if y is any Float except +inf or NaN
sub(-inf, y) => -inf if y is any Float except -inf and NaN
sub(x, +inf) => -inf if x is any Float except +inf and NaN
sub(x, -inf) => +inf if x is any Float except -inf and NaN
sub(+inf, +inf) => NaN
sub(-inf, -inf) => NaN
sub(NaN, y) => NaN for any Float y
sub(x, NaN) => NaN for any Float x
Example:
import Float "mo:base/Float";
Float.sub(1.23, 0.123) // => 1.107
Function mul
func mul(x : Float, y : Float) : Float
Returns the product of x
and y
, x * y
.
Note: Numerical errors may occur, see comment above.
Special cases:
mul(+inf, y) => +inf if y > 0.0
mul(-inf, y) => -inf if y > 0.0
mul(+inf, y) => -inf if y < 0.0
mul(-inf, y) => +inf if y < 0.0
mul(+inf, 0.0) => NaN
mul(-inf, 0.0) => NaN
mul(NaN, y) => NaN for any Float y
The same cases apply commutatively, i.e. for mul(y, x)
.
Example:
import Float "mo:base/Float";
Float.mul(1.23, 1e2) // => 123.0
Function div
func div(x : Float, y : Float) : Float
Returns the division of x
by y
, x / y
.
Note: Numerical errors may occur, see comment above.
Special cases:
div(0.0, 0.0) => NaN
div(x, 0.0) => +inf for x > 0.0
div(x, 0.0) => -inf for x < 0.0
div(x, +inf) => 0.0 for any x except +inf, -inf, and NaN
div(x, -inf) => 0.0 for any x except +inf, -inf, and NaN
div(+inf, y) => +inf if y >= 0.0
div(+inf, y) => -inf if y < 0.0
div(-inf, y) => -inf if y >= 0.0
div(-inf, y) => +inf if y < 0.0
div(NaN, y) => NaN for any Float y
div(x, NaN) => NaN for any Float x
Example:
import Float "mo:base/Float";
Float.div(1.23, 1e2) // => 0.0123
Function rem
func rem(x : Float, y : Float) : Float
Returns the floating point division remainder x % y
,
which is defined as x - trunc(x / y) * y
.
Note: Numerical errors may occur, see comment above.
Special cases:
rem(0.0, 0.0) => NaN
rem(x, y) => +inf if sign(x) == sign(y) for any x and y not being +inf, -inf, or NaN
rem(x, y) => -inf if sign(x) != sign(y) for any x and y not being +inf, -inf, or NaN
rem(x, +inf) => x for any x except +inf, -inf, and NaN
rem(x, -inf) => x for any x except +inf, -inf, and NaN
rem(+inf, y) => NaN for any Float y
rem(-inf, y) => NaN for any Float y
rem(NaN, y) => NaN for any Float y
rem(x, NaN) => NaN for any Float x
Example:
import Float "mo:base/Float";
Float.rem(7.2, 2.3) // => 0.3 (with numerical imprecision)
Function pow
func pow(x : Float, y : Float) : Float
Returns x
to the power of y
, x ** y
.
Note: Numerical errors may occur, see comment above.
Special cases:
pow(+inf, y) => +inf for any y > 0.0 including +inf
pow(+inf, 0.0) => 1.0
pow(+inf, y) => 0.0 for any y < 0.0 including -inf
pow(x, +inf) => +inf if x > 0.0 or x < 0.0
pow(0.0, +inf) => 0.0
pow(x, -inf) => 0.0 if x > 0.0 or x < 0.0
pow(0.0, -inf) => +inf
pow(x, y) => NaN if x < 0.0 and y is a non-integral Float
pow(-inf, y) => +inf if y > 0.0 and y is a non-integral or an even integral Float
pow(-inf, y) => -inf if y > 0.0 and y is an odd integral Float
pow(-inf, 0.0) => 1.0
pow(-inf, y) => 0.0 if y < 0.0
pow(-inf, +inf) => +inf
pow(-inf, -inf) => 1.0
pow(NaN, y) => NaN if y != 0.0
pow(NaN, 0.0) => 1.0
pow(x, NaN) => NaN for any Float x
Example:
import Float "mo:base/Float";
Float.pow(2.5, 2.0) // => 6.25