bignumber.js

A JavaScript library for arbitrary-precision arithmetic.

Hosted on GitHub.

The library is incorporated into this page, so it should be available in the console now.

API

See the README on GitHub for a quick-start introduction.

In all examples below, var and semicolons are not shown, and if a commented-out value is in quotes it means toString has been called on the preceding expression.

CONSTRUCTOR

BigNumberBigNumber(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number: integer, 2 to 36 inclusive. (See ALPHABET to extend this range).

Returns a new instance of a BigNumber object with value n, where n is a numeric value in the specified base, or base 10 if base is omitted or is null or undefined.

x = new BigNumber(123.4567)                // '123.4567'
// 'new' is optional
y = BigNumber(x)                           // '123.4567'

If n is a base 10 value it can be in normal (fixed-point) or exponential notation. Values in other bases must be in normal notation. Values in any base can have fraction digits, i.e. digits after the decimal point.

new BigNumber(43210)                       // '43210'
new BigNumber('4.321e+4')                  // '43210'
new BigNumber('-735.0918e-430')            // '-7.350918e-428'
new BigNumber('123412421.234324', 5)       // '607236.557696'

Signed 0, signed Infinity and NaN are supported.

new BigNumber('-Infinity')                 // '-Infinity'
new BigNumber(NaN)                         // 'NaN'
new BigNumber(-0)                          // '0'
new BigNumber('.5')                        // '0.5'
new BigNumber('+2')                        // '2'

String values in hexadecimal literal form, e.g. '0xff' or '0xFF' (but not '0xfF'), are valid, as are string values with the octal and binary prefixs '0o' and '0b'. String values in octal literal form without the prefix will be interpreted as decimals, e.g. '011' is interpreted as 11, not 9.

new BigNumber(-10110100.1, 2)              // '-180.5'
new BigNumber('-0b10110100.1')             // '-180.5'
new BigNumber('ff.8', 16)                  // '255.5'
new BigNumber('0xff.8')                    // '255.5'

If a base is specified, n is rounded according to the current DECIMAL_PLACES and ROUNDING_MODE settings. This includes base 10 so don't include a base parameter for decimal values unless this behaviour is wanted.

BigNumber.config({ DECIMAL_PLACES: 5 })
new BigNumber(1.23456789)                  // '1.23456789'
new BigNumber(1.23456789, 10)              // '1.23457'

An error is thrown if base is invalid. See Errors.

There is no limit to the number of digits of a value of type string (other than that of JavaScript's maximum array size). See RANGE to set the maximum and minimum possible exponent value of a BigNumber.

new BigNumber('5032485723458348569331745.33434346346912144534543')
new BigNumber('4.321e10000000')

BigNumber NaN is returned if n is invalid (unless BigNumber.DEBUG is true, see below).

new BigNumber('.1*')                       // 'NaN'
new BigNumber('blurgh')                    // 'NaN'
new BigNumber(9, 2)                        // 'NaN'

To aid in debugging, if BigNumber.DEBUG is true then an error will be thrown on an invalid n. An error will also be thrown if n is of type number with more than 15 significant digits, as calling toString or valueOf on these numbers may not result in the intended value.

console.log(823456789123456.3)            //  823456789123456.2
new BigNumber(823456789123456.3)          // '823456789123456.2'
BigNumber.DEBUG = true
// '[BigNumber Error] Number primitive has more than 15 significant digits'
new BigNumber(823456789123456.3)
// '[BigNumber Error] Not a base 2 number'
new BigNumber(9, 2)

A BigNumber can also be created from an object literal. Use isBigNumber to check that it is well-formed.

new BigNumber({ s: 1, e: 2, c: [ 777, 12300000000000 ], _isBigNumber: true })    // '777.123'

Methods

The static methods of a BigNumber constructor.

clone .clone([object]) ⇒ BigNumber constructor

object: object

Returns a new independent BigNumber constructor with configuration as described by object (see config), or with the default configuration if object is null or undefined.

Throws if object is not an object. See Errors.

BigNumber.config({ DECIMAL_PLACES: 5 })
BN = BigNumber.clone({ DECIMAL_PLACES: 9 })

x = new BigNumber(1)
y = new BN(1)

x.div(3)                        // 0.33333
y.div(3)                        // 0.333333333

// BN = BigNumber.clone({ DECIMAL_PLACES: 9 }) is equivalent to:
BN = BigNumber.clone()
BN.config({ DECIMAL_PLACES: 9 })
configset([object]) ⇒ object

object: object: an object that contains some or all of the following properties.

Configures the settings for this particular BigNumber constructor.

DECIMAL_PLACES
number: integer, 0 to 1e+9 inclusive
Default value: 20
The maximum number of decimal places of the results of operations involving division, i.e. division, square root and base conversion operations, and power operations with negative exponents.
BigNumber.config({ DECIMAL_PLACES: 5 })
BigNumber.set({ DECIMAL_PLACES: 5 })    // equivalent
ROUNDING_MODE
number: integer, 0 to 8 inclusive
Default value: 4 (ROUND_HALF_UP)
The rounding mode used in the above operations and the default rounding mode of decimalPlaces, precision, toExponential, toFixed, toFormat and toPrecision.
The modes are available as enumerated properties of the BigNumber constructor.
BigNumber.config({ ROUNDING_MODE: 0 })
BigNumber.set({ ROUNDING_MODE: BigNumber.ROUND_UP })    // equivalent
EXPONENTIAL_AT
number: integer, magnitude 0 to 1e+9 inclusive, or
number[]: [ integer -1e+9 to 0 inclusive, integer 0 to 1e+9 inclusive ]
Default value: [-7, 20]
The exponent value(s) at which toString returns exponential notation.
If a single number is assigned, the value is the exponent magnitude.
If an array of two numbers is assigned then the first number is the negative exponent value at and beneath which exponential notation is used, and the second number is the positive exponent value at and above which the same.
For example, to emulate JavaScript numbers in terms of the exponent values at which they begin to use exponential notation, use [-7, 20].
BigNumber.config({ EXPONENTIAL_AT: 2 })
new BigNumber(12.3)         // '12.3'        e is only 1
new BigNumber(123)          // '1.23e+2'
new BigNumber(0.123)        // '0.123'       e is only -1
new BigNumber(0.0123)       // '1.23e-2'

BigNumber.config({ EXPONENTIAL_AT: [-7, 20] })
new BigNumber(123456789)    // '123456789'   e is only 8
new BigNumber(0.000000123)  // '1.23e-7'

// Almost never return exponential notation:
BigNumber.config({ EXPONENTIAL_AT: 1e+9 })

// Always return exponential notation:
BigNumber.config({ EXPONENTIAL_AT: 0 })
Regardless of the value of EXPONENTIAL_AT, the toFixed method will always return a value in normal notation and the toExponential method will always return a value in exponential form.
Calling toString with a base argument, e.g. toString(10), will also always return normal notation.
RANGE
number: integer, magnitude 1 to 1e+9 inclusive, or
number[]: [ integer -1e+9 to -1 inclusive, integer 1 to 1e+9 inclusive ]
Default value: [-1e+9, 1e+9]
The exponent value(s) beyond which overflow to Infinity and underflow to zero occurs.
If a single number is assigned, it is the maximum exponent magnitude: values wth a positive exponent of greater magnitude become Infinity and those with a negative exponent of greater magnitude become zero.
If an array of two numbers is assigned then the first number is the negative exponent limit and the second number is the positive exponent limit.
For example, to emulate JavaScript numbers in terms of the exponent values at which they become zero and Infinity, use [-324, 308].
BigNumber.config({ RANGE: 500 })
BigNumber.config().RANGE     // [ -500, 500 ]
new BigNumber('9.999e499')   // '9.999e+499'
new BigNumber('1e500')       // 'Infinity'
new BigNumber('1e-499')      // '1e-499'
new BigNumber('1e-500')      // '0'

BigNumber.config({ RANGE: [-3, 4] })
new BigNumber(99999)         // '99999'      e is only 4
new BigNumber(100000)        // 'Infinity'   e is 5
new BigNumber(0.001)         // '0.01'       e is only -3
new BigNumber(0.0001)        // '0'          e is -4
The largest possible magnitude of a finite BigNumber is 9.999...e+1000000000.
The smallest possible magnitude of a non-zero BigNumber is 1e-1000000000.
CRYPTO
boolean: true or false.
Default value: false
The value that determines whether cryptographically-secure pseudo-random number generation is used.
If CRYPTO is set to true then the random method will generate random digits using crypto.getRandomValues in browsers that support it, or crypto.randomBytes if using Node.js.
If neither function is supported by the host environment then attempting to set CRYPTO to true will fail and an exception will be thrown.
If CRYPTO is false then the source of randomness used will be Math.random (which is assumed to generate at least 30 bits of randomness).
See random.
// Node.js
global.crypto = require('crypto')

BigNumber.config({ CRYPTO: true })
BigNumber.config().CRYPTO       // true
BigNumber.random()              // 0.54340758610486147524
MODULO_MODE
number: integer, 0 to 9 inclusive
Default value: 1 (ROUND_DOWN)
The modulo mode used when calculating the modulus: a mod n.
The quotient, q = a / n, is calculated according to the ROUNDING_MODE that corresponds to the chosen MODULO_MODE.
The remainder, r, is calculated as: r = a - n * q.
The modes that are most commonly used for the modulus/remainder operation are shown in the following table. Although the other rounding modes can be used, they may not give useful results.
PropertyValueDescription
ROUND_UP0 The remainder is positive if the dividend is negative, otherwise it is negative.
ROUND_DOWN1 The remainder has the same sign as the dividend.
This uses 'truncating division' and matches the behaviour of JavaScript's remainder operator %.
ROUND_FLOOR3 The remainder has the same sign as the divisor.
This matches Python's % operator.
ROUND_HALF_EVEN6 The IEEE 754 remainder function.
EUCLID9 The remainder is always positive. Euclidian division:
q = sign(n) * floor(a / abs(n))
The rounding/modulo modes are available as enumerated properties of the BigNumber constructor.
See modulo.
BigNumber.config({ MODULO_MODE: BigNumber.EUCLID })
BigNumber.config({ MODULO_MODE: 9 })          // equivalent
POW_PRECISION
number: integer, 0 to 1e+9 inclusive.
Default value: 0
The maximum precision, i.e. number of significant digits, of the result of the power operation (unless a modulus is specified).
If set to 0, the number of significant digits will not be limited.
See exponentiatedBy.
BigNumber.config({ POW_PRECISION: 100 })
FORMAT
object
The FORMAT object configures the format of the string returned by the toFormat method.
The example below shows the properties of the FORMAT object that are recognised, and their default values.
Unlike the other configuration properties, the values of the properties of the FORMAT object will not be checked for validity. The existing FORMAT object will simply be replaced by the object that is passed in. The object can include any number of the properties shown below.
See toFormat for examples of usage.
BigNumber.config({
  FORMAT: {
    // string to prepend
    prefix: '',
    // decimal separator
    decimalSeparator: '.',
    // grouping separator of the integer part
    groupSeparator: ',',
    // primary grouping size of the integer part
    groupSize: 3,
    // secondary grouping size of the integer part
    secondaryGroupSize: 0,
    // grouping separator of the fraction part
    fractionGroupSeparator: ' ',
    // grouping size of the fraction part
    fractionGroupSize: 0,
    // string to append
    suffix: ''
  }
});
ALPHABET
string
Default value: '0123456789abcdefghijklmnopqrstuvwxyz'
The alphabet used for base conversion. The length of the alphabet corresponds to the maximum value of the base argument that can be passed to the BigNumber constructor or toString.
There is no maximum length for the alphabet, but it must be at least 2 characters long, and it must not contain whitespace or a repeated character, or the sign indicators '+' and '-', or the decimal separator '.'.
// duodecimal (base 12)
BigNumber.config({ ALPHABET: '0123456789TE' })
x = new BigNumber('T', 12)
x.toString()                // '10'
x.toString(12)              // 'T'


Returns an object with the above properties and their current values.

Throws if object is not an object, or if an invalid value is assigned to one or more of the above properties. See Errors.

BigNumber.config({
  DECIMAL_PLACES: 40,
  ROUNDING_MODE: BigNumber.ROUND_HALF_CEIL,
  EXPONENTIAL_AT: [-10, 20],
  RANGE: [-500, 500],
  CRYPTO: true,
  MODULO_MODE: BigNumber.ROUND_FLOOR,
  POW_PRECISION: 80,
  FORMAT: {
    groupSize: 3,
    groupSeparator: ' ',
    decimalSeparator: ','
  },
  ALPHABET: '0123456789abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ$_'
});

obj = BigNumber.config();
obj.DECIMAL_PLACES        // 40
obj.RANGE                 // [-500, 500]
isBigNumber.isBigNumber(value) ⇒ boolean

value: any

Returns true if value is a BigNumber instance, otherwise returns false.

x = 42
y = new BigNumber(x)

BigNumber.isBigNumber(x)             // false
y instanceof BigNumber               // true
BigNumber.isBigNumber(y)             // true

BN = BigNumber.clone();
z = new BN(x)
z instanceof BigNumber               // false
BigNumber.isBigNumber(z)             // true

If value is a BigNumber instance and BigNumber.DEBUG is true, then this method will also check if value is well-formed, and throw if it is not. See Errors.

The check can be useful if creating a BigNumber from an object literal. See BigNumber.

x = new BigNumber(10)

// Change x.c to an illegitimate value.
x.c = NaN

BigNumber.DEBUG = false

// No error.
BigNumber.isBigNumber(x)    // true

BigNumber.DEBUG = true

// Error.
BigNumber.isBigNumber(x)    // '[BigNumber Error] Invalid BigNumber'
maximum.max(n...) ⇒ BigNumber

n: number|string|BigNumber
See BigNumber for further parameter details.

Returns a BigNumber whose value is the maximum of the arguments.

The return value is always exact and unrounded.

x = new BigNumber('3257869345.0378653')
BigNumber.maximum(4e9, x, '123456789.9')      // '4000000000'

arr = [12, '13', new BigNumber(14)]
BigNumber.max.apply(null, arr)                // '14'
minimum.min(n...) ⇒ BigNumber

n: number|string|BigNumber
See BigNumber for further parameter details.

Returns a BigNumber whose value is the minimum of the arguments.

The return value is always exact and unrounded.

x = new BigNumber('3257869345.0378653')
BigNumber.minimum(4e9, x, '123456789.9')      // '123456789.9'

arr = [2, new BigNumber(-14), '-15.9999', -12]
BigNumber.min.apply(null, arr)                // '-15.9999'
random.random([dp]) ⇒ BigNumber

dp: number: integer, 0 to 1e+9 inclusive

Returns a new BigNumber with a pseudo-random value equal to or greater than 0 and less than 1.

The return value will have dp decimal places (or less if trailing zeros are produced).
If dp is omitted then the number of decimal places will default to the current DECIMAL_PLACES setting.

Depending on the value of this BigNumber constructor's CRYPTO setting and the support for the crypto object in the host environment, the random digits of the return value are generated by either Math.random (fastest), crypto.getRandomValues (Web Cryptography API in recent browsers) or crypto.randomBytes (Node.js).

To be able to set CRYPTO to true when using Node.js, the crypto object must be available globally:

global.crypto = require('crypto')

If CRYPTO is true, i.e. one of the crypto methods is to be used, the value of a returned BigNumber should be cryptographically-secure and statistically indistinguishable from a random value.

Throws if dp is invalid. See Errors.

BigNumber.config({ DECIMAL_PLACES: 10 })
BigNumber.random()              // '0.4117936847'
BigNumber.random(20)            // '0.78193327636914089009'
sum.sum(n...) ⇒ BigNumber

n: number|string|BigNumber
See BigNumber for further parameter details.

Returns a BigNumber whose value is the sum of the arguments.

The return value is always exact and unrounded.

x = new BigNumber('3257869345.0378653')
BigNumber.sum(4e9, x, '123456789.9')      // '7381326134.9378653'

arr = [2, new BigNumber(14), '15.9999', 12]
BigNumber.sum.apply(null, arr)            // '43.9999'

Properties

The library's enumerated rounding modes are stored as properties of the constructor.
(They are not referenced internally by the library itself.)

Rounding modes 0 to 6 (inclusive) are the same as those of Java's BigDecimal class.

Property Value Description
ROUND_UP 0 Rounds away from zero
ROUND_DOWN 1 Rounds towards zero
ROUND_CEIL 2 Rounds towards Infinity
ROUND_FLOOR 3 Rounds towards -Infinity
ROUND_HALF_UP 4 Rounds towards nearest neighbour.
If equidistant, rounds away from zero
ROUND_HALF_DOWN 5 Rounds towards nearest neighbour.
If equidistant, rounds towards zero
ROUND_HALF_EVEN 6 Rounds towards nearest neighbour.
If equidistant, rounds towards even neighbour
ROUND_HALF_CEIL 7 Rounds towards nearest neighbour.
If equidistant, rounds towards Infinity
ROUND_HALF_FLOOR 8 Rounds towards nearest neighbour.
If equidistant, rounds towards -Infinity
BigNumber.config({ ROUNDING_MODE: BigNumber.ROUND_CEIL })
BigNumber.config({ ROUNDING_MODE: 2 })     // equivalent
DEBUG

undefined|false|true

If BigNumber.DEBUG is set true then an error will be thrown if this BigNumber constructor receives an invalid value, such as a value of type number with more than 15 significant digits. See BigNumber.

An error will also be thrown if the isBigNumber method receives a BigNumber that is not well-formed. See isBigNumber.

BigNumber.DEBUG = true

INSTANCE

Methods

The methods inherited by a BigNumber instance from its constructor's prototype object.

A BigNumber is immutable in the sense that it is not changed by its methods.

The treatment of ±0, ±Infinity and NaN is consistent with how JavaScript treats these values.

Many method names have a shorter alias.

absoluteValue.abs() ⇒ BigNumber

Returns a BigNumber whose value is the absolute value, i.e. the magnitude, of the value of this BigNumber.

The return value is always exact and unrounded.

x = new BigNumber(-0.8)
y = x.absoluteValue()           // '0.8'
z = y.abs()                     // '0.8'
comparedTo.comparedTo(n [, base]) ⇒ number

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns 
1 If the value of this BigNumber is greater than the value of n
-1 If the value of this BigNumber is less than the value of n
0 If this BigNumber and n have the same value
null If the value of either this BigNumber or n is NaN
x = new BigNumber(Infinity)
y = new BigNumber(5)
x.comparedTo(y)                 // 1
x.comparedTo(x.minus(1))        // 0
y.comparedTo(NaN)               // null
y.comparedTo('110', 2)          // -1
decimalPlaces.dp([dp [, rm]]) ⇒ BigNumber|number

dp: number: integer, 0 to 1e+9 inclusive
rm: number: integer, 0 to 8 inclusive

If dp is a number, returns a BigNumber whose value is the value of this BigNumber rounded by rounding mode rm to a maximum of dp decimal places.

If dp is omitted, or is null or undefined, the return value is the number of decimal places of the value of this BigNumber, or null if the value of this BigNumber is ±Infinity or NaN.

If rm is omitted, or is null or undefined, ROUNDING_MODE is used.

Throws if dp or rm is invalid. See Errors.

x = new BigNumber(1234.56)
x.decimalPlaces(1)                     // '1234.6'
x.dp()                                 // 2
x.decimalPlaces(2)                     // '1234.56'
x.dp(10)                               // '1234.56'
x.decimalPlaces(0, 1)                  // '1234'
x.dp(0, 6)                             // '1235'
x.decimalPlaces(1, 1)                  // '1234.5'
x.dp(1, BigNumber.ROUND_HALF_EVEN)     // '1234.6'
x                                      // '1234.56'
y = new BigNumber('9.9e-101')
y.dp()                                 // 102
dividedBy.div(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns a BigNumber whose value is the value of this BigNumber divided by n, rounded according to the current DECIMAL_PLACES and ROUNDING_MODE settings.

x = new BigNumber(355)
y = new BigNumber(113)
x.dividedBy(y)                  // '3.14159292035398230088'
x.div(5)                        // '71'
x.div(47, 16)                   // '5'
dividedToIntegerBy.idiv(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns a BigNumber whose value is the integer part of dividing the value of this BigNumber by n.

x = new BigNumber(5)
y = new BigNumber(3)
x.dividedToIntegerBy(y)         // '1'
x.idiv(0.7)                     // '7'
x.idiv('0.f', 16)               // '5'
exponentiatedBy.pow(n [, m]) ⇒ BigNumber

n: number|string|BigNumber: integer
m: number|string|BigNumber

Returns a BigNumber whose value is the value of this BigNumber exponentiated by n, i.e. raised to the power n, and optionally modulo a modulus m.

Throws if n is not an integer. See Errors.

If n is negative the result is rounded according to the current DECIMAL_PLACES and ROUNDING_MODE settings.

As the number of digits of the result of the power operation can grow so large so quickly, e.g. 123.45610000 has over 50000 digits, the number of significant digits calculated is limited to the value of the POW_PRECISION setting (unless a modulus m is specified).

By default POW_PRECISION is set to 0. This means that an unlimited number of significant digits will be calculated, and that the method's performance will decrease dramatically for larger exponents.

If m is specified and the value of m, n and this BigNumber are integers, and n is positive, then a fast modular exponentiation algorithm is used, otherwise the operation will be performed as x.exponentiatedBy(n).modulo(m) with a POW_PRECISION of 0.

Math.pow(0.7, 2)                // 0.48999999999999994
x = new BigNumber(0.7)
x.exponentiatedBy(2)            // '0.49'
BigNumber(3).pow(-2)            // '0.11111111111111111111'
integerValue.integerValue([rm]) ⇒ BigNumber

rm: number: integer, 0 to 8 inclusive

Returns a BigNumber whose value is the value of this BigNumber rounded to an integer using rounding mode rm.

If rm is omitted, or is null or undefined, ROUNDING_MODE is used.

Throws if rm is invalid. See Errors.

x = new BigNumber(123.456)
x.integerValue()                        // '123'
x.integerValue(BigNumber.ROUND_CEIL)    // '124'
y = new BigNumber(-12.7)
y.integerValue()                        // '-13'
y.integerValue(BigNumber.ROUND_DOWN)    // '-12'

The following is an example of how to add a prototype method that emulates JavaScript's Math.round function. Math.ceil, Math.floor and Math.trunc can be emulated in the same way with BigNumber.ROUND_CEIL, BigNumber.ROUND_FLOOR and BigNumber.ROUND_DOWN respectively.

BigNumber.prototype.round = function () {
  return this.integerValue(BigNumber.ROUND_HALF_CEIL);
};
x.round()                               // '123'
isEqualTo.eq(n [, base]) ⇒ boolean

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns true if the value of this BigNumber is equal to the value of n, otherwise returns false.
As with JavaScript, NaN does not equal NaN.

Note: This method uses the comparedTo method internally.

0 === 1e-324                    // true
x = new BigNumber(0)
x.isEqualTo('1e-324')           // false
BigNumber(-0).eq(x)             // true  ( -0 === 0 )
BigNumber(255).eq('ff', 16)     // true

y = new BigNumber(NaN)
y.isEqualTo(NaN)                // false
isFinite.isFinite() ⇒ boolean

Returns true if the value of this BigNumber is a finite number, otherwise returns false.

The only possible non-finite values of a BigNumber are NaN, Infinity and -Infinity.

x = new BigNumber(1)
x.isFinite()                    // true
y = new BigNumber(Infinity)
y.isFinite()                    // false

Note: The native method isFinite() can be used if n <= Number.MAX_VALUE.

isGreaterThan.gt(n [, base]) ⇒ boolean

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns true if the value of this BigNumber is greater than the value of n, otherwise returns false.

Note: This method uses the comparedTo method internally.

0.1 > (0.3 - 0.2)                             // true
x = new BigNumber(0.1)
x.isGreaterThan(BigNumber(0.3).minus(0.2))    // false
BigNumber(0).gt(x)                            // false
BigNumber(11, 3).gt(11.1, 2)                  // true
isGreaterThanOrEqualTo.gte(n [, base]) ⇒ boolean

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns true if the value of this BigNumber is greater than or equal to the value of n, otherwise returns false.

Note: This method uses the comparedTo method internally.

(0.3 - 0.2) >= 0.1                     // false
x = new BigNumber(0.3).minus(0.2)
x.isGreaterThanOrEqualTo(0.1)          // true
BigNumber(1).gte(x)                    // true
BigNumber(10, 18).gte('i', 36)         // true
isInteger.isInteger() ⇒ boolean

Returns true if the value of this BigNumber is an integer, otherwise returns false.

x = new BigNumber(1)
x.isInteger()                   // true
y = new BigNumber(123.456)
y.isInteger()                   // false
isLessThan.lt(n [, base]) ⇒ boolean

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns true if the value of this BigNumber is less than the value of n, otherwise returns false.

Note: This method uses the comparedTo method internally.

(0.3 - 0.2) < 0.1                       // true
x = new BigNumber(0.3).minus(0.2)
x.isLessThan(0.1)                       // false
BigNumber(0).lt(x)                      // true
BigNumber(11.1, 2).lt(11, 3)            // true
isLessThanOrEqualTo.lte(n [, base]) ⇒ boolean

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns true if the value of this BigNumber is less than or equal to the value of n, otherwise returns false.

Note: This method uses the comparedTo method internally.

0.1 <= (0.3 - 0.2)                                // false
x = new BigNumber(0.1)
x.isLessThanOrEqualTo(BigNumber(0.3).minus(0.2))  // true
BigNumber(-1).lte(x)                              // true
BigNumber(10, 18).lte('i', 36)                    // true
isNaN.isNaN() ⇒ boolean

Returns true if the value of this BigNumber is NaN, otherwise returns false.

x = new BigNumber(NaN)
x.isNaN()                       // true
y = new BigNumber('Infinity')
y.isNaN()                       // false

Note: The native method isNaN() can also be used.

isNegative.isNegative() ⇒ boolean

Returns true if the sign of this BigNumber is negative, otherwise returns false.

x = new BigNumber(-0)
x.isNegative()                  // true
y = new BigNumber(2)
y.isNegative()                  // false

Note: n < 0 can be used if n <= -Number.MIN_VALUE.

isPositive.isPositive() ⇒ boolean

Returns true if the sign of this BigNumber is positive, otherwise returns false.

x = new BigNumber(-0)
x.isPositive()                  // false
y = new BigNumber(2)
y.isPositive()                  // true
isZero.isZero() ⇒ boolean

Returns true if the value of this BigNumber is zero or minus zero, otherwise returns false.

x = new BigNumber(-0)
x.isZero() && x.isNegative()         // true
y = new BigNumber(Infinity)
y.isZero()                      // false

Note: n == 0 can be used if n >= Number.MIN_VALUE.

minus.minus(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns a BigNumber whose value is the value of this BigNumber minus n.

The return value is always exact and unrounded.

0.3 - 0.1                       // 0.19999999999999998
x = new BigNumber(0.3)
x.minus(0.1)                    // '0.2'
x.minus(0.6, 20)                // '0'
modulo.mod(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns a BigNumber whose value is the value of this BigNumber modulo n, i.e. the integer remainder of dividing this BigNumber by n.

The value returned, and in particular its sign, is dependent on the value of the MODULO_MODE setting of this BigNumber constructor. If it is 1 (default value), the result will have the same sign as this BigNumber, and it will match that of Javascript's % operator (within the limits of double precision) and BigDecimal's remainder method.

The return value is always exact and unrounded.

See MODULO_MODE for a description of the other modulo modes.

1 % 0.9                         // 0.09999999999999998
x = new BigNumber(1)
x.modulo(0.9)                   // '0.1'
y = new BigNumber(33)
y.mod('a', 33)                  // '3'
multipliedBy.times(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns a BigNumber whose value is the value of this BigNumber multiplied by n.

The return value is always exact and unrounded.

0.6 * 3                         // 1.7999999999999998
x = new BigNumber(0.6)
y = x.multipliedBy(3)           // '1.8'
BigNumber('7e+500').times(y)    // '1.26e+501'
x.multipliedBy('-a', 16)        // '-6'
negated.negated() ⇒ BigNumber

Returns a BigNumber whose value is the value of this BigNumber negated, i.e. multiplied by -1.

x = new BigNumber(1.8)
x.negated()                     // '-1.8'
y = new BigNumber(-1.3)
y.negated()                     // '1.3'
plus.plus(n [, base]) ⇒ BigNumber

n: number|string|BigNumber
base: number
See BigNumber for further parameter details.

Returns a BigNumber whose value is the value of this BigNumber plus n.

The return value is always exact and unrounded.

0.1 + 0.2                       // 0.30000000000000004
x = new BigNumber(0.1)
y = x.plus(0.2)                 // '0.3'
BigNumber(0.7).plus(x).plus(y)  // '1.1'
x.plus('0.1', 8)                // '0.225'
precision.sd([d [, rm]]) ⇒ BigNumber|number

d: number|boolean: integer, 1 to 1e+9 inclusive, or true or false
rm: number: integer, 0 to 8 inclusive.

If d is a number, returns a BigNumber whose value is the value of this BigNumber rounded to a precision of d significant digits using rounding mode rm.

If d is omitted or is null or undefined, the return value is the number of significant digits of the value of this BigNumber, or null if the value of this BigNumber is ±Infinity or NaN.

If d is true then any trailing zeros of the integer part of a number are counted as significant digits, otherwise they are not.

If rm is omitted or is null or undefined, ROUNDING_MODE will be used.

Throws if d or rm is invalid. See Errors.

x = new BigNumber(9876.54321)
x.precision(6)                         // '9876.54'
x.sd()                                 // 9
x.precision(6, BigNumber.ROUND_UP)     // '9876.55'
x.sd(2)                                // '9900'
x.precision(2, 1)                      // '9800'
x                                      // '9876.54321'
y = new BigNumber(987000)
y.precision()                          // 3
y.sd(true)                             // 6
shiftedBy.shiftedBy(n) ⇒ BigNumber

n: number: integer, -9007199254740991 to 9007199254740991 inclusive

Returns a BigNumber whose value is the value of this BigNumber shifted by n places.

The shift is of the decimal point, i.e. of powers of ten, and is to the left if n is negative or to the right if n is positive.

The return value is always exact and unrounded.

Throws if n is invalid. See Errors.

x = new BigNumber(1.23)
x.shiftedBy(3)                      // '1230'
x.shiftedBy(-3)                     // '0.00123'
squareRoot.sqrt() ⇒ BigNumber

Returns a BigNumber whose value is the square root of the value of this BigNumber, rounded according to the current DECIMAL_PLACES and ROUNDING_MODE settings.

The return value will be correctly rounded, i.e. rounded as if the result was first calculated to an infinite number of correct digits before rounding.

x = new BigNumber(16)
x.squareRoot()                  // '4'
y = new BigNumber(3)
y.sqrt()                        // '1.73205080756887729353'
toExponential.toExponential([dp [, rm]]) ⇒ string

dp: number: integer, 0 to 1e+9 inclusive
rm: number: integer, 0 to 8 inclusive

Returns a string representing the value of this BigNumber in exponential notation rounded using rounding mode rm to dp decimal places, i.e with one digit before the decimal point and dp digits after it.

If the value of this BigNumber in exponential notation has fewer than dp fraction digits, the return value will be appended with zeros accordingly.

If dp is omitted, or is null or undefined, the number of digits after the decimal point defaults to the minimum number of digits necessary to represent the value exactly.
If rm is omitted or is null or undefined, ROUNDING_MODE is used.

Throws if dp or rm is invalid. See Errors.

x = 45.6
y = new BigNumber(x)
x.toExponential()               // '4.56e+1'
y.toExponential()               // '4.56e+1'
x.toExponential(0)              // '5e+1'
y.toExponential(0)              // '5e+1'
x.toExponential(1)              // '4.6e+1'
y.toExponential(1)              // '4.6e+1'
y.toExponential(1, 1)           // '4.5e+1'  (ROUND_DOWN)
x.toExponential(3)              // '4.560e+1'
y.toExponential(3)              // '4.560e+1'
toFixed.toFixed([dp [, rm]]) ⇒ string

dp: number: integer, 0 to 1e+9 inclusive
rm: number: integer, 0 to 8 inclusive

Returns a string representing the value of this BigNumber in normal (fixed-point) notation rounded to dp decimal places using rounding mode rm.

If the value of this BigNumber in normal notation has fewer than dp fraction digits, the return value will be appended with zeros accordingly.

Unlike Number.prototype.toFixed, which returns exponential notation if a number is greater or equal to 1021, this method will always return normal notation.

If dp is omitted or is null or undefined, the return value will be unrounded and in normal notation. This is also unlike Number.prototype.toFixed, which returns the value to zero decimal places.
It is useful when fixed-point notation is required and the current EXPONENTIAL_AT setting causes toString to return exponential notation.
If rm is omitted or is null or undefined, ROUNDING_MODE is used.

Throws if dp or rm is invalid. See Errors.

x = 3.456
y = new BigNumber(x)
x.toFixed()                     // '3'
y.toFixed()                     // '3.456'
y.toFixed(0)                    // '3'
x.toFixed(2)                    // '3.46'
y.toFixed(2)                    // '3.46'
y.toFixed(2, 1)                 // '3.45'  (ROUND_DOWN)
x.toFixed(5)                    // '3.45600'
y.toFixed(5)                    // '3.45600'
toFormat.toFormat([dp [, rm[, format]]]) ⇒ string

dp: number: integer, 0 to 1e+9 inclusive
rm: number: integer, 0 to 8 inclusive
format: object: see FORMAT

Returns a string representing the value of this BigNumber in normal (fixed-point) notation rounded to dp decimal places using rounding mode rm, and formatted according to the properties of the format object.

See FORMAT and the examples below for the properties of the format object, their types, and their usage. A formatting object may contain some or all of the recognised properties.

If dp is omitted or is null or undefined, then the return value is not rounded to a fixed number of decimal places.
If rm is omitted or is null or undefined, ROUNDING_MODE is used.
If format is omitted or is null or undefined, the FORMAT object is used.

Throws if dp, rm or format is invalid. See Errors.

fmt = {
  prefix: '',
  decimalSeparator: '.',
  groupSeparator: ',',
  groupSize: 3,
  secondaryGroupSize: 0,
  fractionGroupSeparator: ' ',
  fractionGroupSize: 0,
  suffix: ''
}

x = new BigNumber('123456789.123456789')

// Set the global formatting options
BigNumber.config({ FORMAT: fmt })

x.toFormat()                              // '123,456,789.123456789'
x.toFormat(3)                             // '123,456,789.123'

// If a reference to the object assigned to FORMAT has been retained,
// the format properties can be changed directly
fmt.groupSeparator = ' '
fmt.fractionGroupSize = 5
x.toFormat()                              // '123 456 789.12345 6789'

// Alternatively, pass the formatting options as an argument
fmt = {
  prefix: '=> ',
  decimalSeparator: ',',
  groupSeparator: '.',
  groupSize: 3,
  secondaryGroupSize: 2
}

x.toFormat()                              // '123 456 789.12345 6789'
x.toFormat(fmt)                           // '=> 12.34.56.789,123456789'
x.toFormat(2, fmt)                        // '=> 12.34.56.789,12'
x.toFormat(3, BigNumber.ROUND_UP, fmt)    // '=> 12.34.56.789,124'
toFraction.toFraction([maximum_denominator]) ⇒ [BigNumber, BigNumber]

maximum_denominator: number|string|BigNumber: integer >= 1 and <= Infinity

Returns an array of two BigNumbers representing the value of this BigNumber as a simple fraction with an integer numerator and an integer denominator. The denominator will be a positive non-zero value less than or equal to maximum_denominator.

If a maximum_denominator is not specified, or is null or undefined, the denominator will be the lowest value necessary to represent the number exactly.

Throws if maximum_denominator is invalid. See Errors.

x = new BigNumber(1.75)
x.toFraction()                  // '7, 4'

pi = new BigNumber('3.14159265358')
pi.toFraction()                 // '157079632679,50000000000'
pi.toFraction(100000)           // '312689, 99532'
pi.toFraction(10000)            // '355, 113'
pi.toFraction(100)              // '311, 99'
pi.toFraction(10)               // '22, 7'
pi.toFraction(1)                // '3, 1'
toJSON.toJSON() ⇒ string

As valueOf.

x = new BigNumber('177.7e+457')
y = new BigNumber(235.4325)
z = new BigNumber('0.0098074')

// Serialize an array of three BigNumbers
str = JSON.stringify( [x, y, z] )
// "["1.777e+459","235.4325","0.0098074"]"

// Return an array of three BigNumbers
JSON.parse(str, function (key, val) {
    return key === '' ? val : new BigNumber(val)
})
toNumber.toNumber() ⇒ number

Returns the value of this BigNumber as a JavaScript number primitive.

This method is identical to using type coercion with the unary plus operator.

x = new BigNumber(456.789)
x.toNumber()                    // 456.789
+x                              // 456.789

y = new BigNumber('45987349857634085409857349856430985')
y.toNumber()                    // 4.598734985763409e+34

z = new BigNumber(-0)
1 / z.toNumber()                // -Infinity
1 / +z                          // -Infinity
toPrecision.toPrecision([sd [, rm]]) ⇒ string

sd: number: integer, 1 to 1e+9 inclusive
rm: number: integer, 0 to 8 inclusive

Returns a string representing the value of this BigNumber rounded to sd significant digits using rounding mode rm.

If sd is less than the number of digits necessary to represent the integer part of the value in normal (fixed-point) notation, then exponential notation is used.

If sd is omitted, or is null or undefined, then the return value is the same as n.toString().
If rm is omitted or is null or undefined, ROUNDING_MODE is used.

Throws if sd or rm is invalid. See Errors.

x = 45.6
y = new BigNumber(x)
x.toPrecision()                 // '45.6'
y.toPrecision()                 // '45.6'
x.toPrecision(1)                // '5e+1'
y.toPrecision(1)                // '5e+1'
y.toPrecision(2, 0)             // '4.6e+1'  (ROUND_UP)
y.toPrecision(2, 1)             // '4.5e+1'  (ROUND_DOWN)
x.toPrecision(5)                // '45.600'
y.toPrecision(5)                // '45.600'
toString.toString([base]) ⇒ string

base: number: integer, 2 to ALPHABET.length inclusive (see ALPHABET).

Returns a string representing the value of this BigNumber in the specified base, or base 10 if base is omitted or is null or undefined.

For bases above 10, and using the default base conversion alphabet (see ALPHABET), values from 10 to 35 are represented by a-z (as with Number.prototype.toString).

If a base is specified the value is rounded according to the current DECIMAL_PLACES and ROUNDING_MODE settings.

If a base is not specified, and this BigNumber has a positive exponent that is equal to or greater than the positive component of the current EXPONENTIAL_AT setting, or a negative exponent equal to or less than the negative component of the setting, then exponential notation is returned.

If base is null or undefined it is ignored.

Throws if base is invalid. See Errors.

x = new BigNumber(750000)
x.toString()                    // '750000'
BigNumber.config({ EXPONENTIAL_AT: 5 })
x.toString()                    // '7.5e+5'

y = new BigNumber(362.875)
y.toString(2)                   // '101101010.111'
y.toString(9)                   // '442.77777777777777777778'
y.toString(32)                  // 'ba.s'

BigNumber.config({ DECIMAL_PLACES: 4 });
z = new BigNumber('1.23456789')
z.toString()                    // '1.23456789'
z.toString(10)                  // '1.2346'
valueOf.valueOf() ⇒ string

As toString, but does not accept a base argument and includes the minus sign for negative zero.

x = new BigNumber('-0')
x.toString()                    // '0'
x.valueOf()                     // '-0'
y = new BigNumber('1.777e+457')
y.valueOf()                     // '1.777e+457'

Properties

The properties of a BigNumber instance:

Property Description Type Value
c coefficient* number[] Array of base 1e14 numbers
e exponent number Integer, -1000000000 to 1000000000 inclusive
s sign number -1 or 1

*significand

The value of any of the c, e and s properties may also be null.

The above properties are best considered to be read-only. In early versions of this library it was okay to change the exponent of a BigNumber by writing to its exponent property directly, but this is no longer reliable as the value of the first element of the coefficient array is now dependent on the exponent.

Note that, as with JavaScript numbers, the original exponent and fractional trailing zeros are not necessarily preserved.

x = new BigNumber(0.123)              // '0.123'
x.toExponential()                     // '1.23e-1'
x.c                                   // '1,2,3'
x.e                                   // -1
x.s                                   // 1

y = new Number(-123.4567000e+2)       // '-12345.67'
y.toExponential()                     // '-1.234567e+4'
z = new BigNumber('-123.4567000e+2')  // '-12345.67'
z.toExponential()                     // '-1.234567e+4'
z.c                                   // '1,2,3,4,5,6,7'
z.e                                   // 4
z.s                                   // -1

Zero, NaN and Infinity

The table below shows how ±0, NaN and ±Infinity are stored.

c e s
±0 [0] 0 ±1
NaN null null null
±Infinity null null ±1
x = new Number(-0)              // 0
1 / x == -Infinity              // true

y = new BigNumber(-0)           // '0'
y.c                             // '0' ( [0].toString() )
y.e                             // 0
y.s                             // -1

Errors

The table below shows the errors that are thrown.

The errors are generic Error objects whose message begins '[BigNumber Error]'.

Method Throws
BigNumber
comparedTo
dividedBy
dividedToIntegerBy
isEqualTo
isGreaterThan
isGreaterThanOrEqualTo
isLessThan
isLessThanOrEqualTo
minus
modulo
plus
multipliedBy
Base not a primitive number
Base not an integer
Base out of range
Number primitive has more than 15 significant digits*
Not a base... number*
Not a number*
clone Object expected
config Object expected
DECIMAL_PLACES not a primitive number
DECIMAL_PLACES not an integer
DECIMAL_PLACES out of range
ROUNDING_MODE not a primitive number
ROUNDING_MODE not an integer
ROUNDING_MODE out of range
EXPONENTIAL_AT not a primitive number
EXPONENTIAL_AT not an integer
EXPONENTIAL_AT out of range
RANGE not a primitive number
RANGE not an integer
RANGE cannot be zero
RANGE cannot be zero
CRYPTO not true or false
crypto unavailable
MODULO_MODE not a primitive number
MODULO_MODE not an integer
MODULO_MODE out of range
POW_PRECISION not a primitive number
POW_PRECISION not an integer
POW_PRECISION out of range
FORMAT not an object
ALPHABET invalid
decimalPlaces
precision
random
shiftedBy
toExponential
toFixed
toFormat
toPrecision
Argument not a primitive number
Argument not an integer
Argument out of range
decimalPlaces
precision
Argument not true or false
exponentiatedBy Argument not an integer
isBigNumber Invalid BigNumber*
minimum
maximum
Not a number*
random crypto unavailable
toFormat Argument not an object
toFraction Argument not an integer
Argument out of range
toString Base not a primitive number
Base not an integer
Base out of range

*Only thrown if BigNumber.DEBUG is true.

To determine if an exception is a BigNumber Error:

try {
  // ...
} catch (e) {
  if (e instanceof Error && e.message.indexOf('[BigNumber Error]') === 0) {
      // ...
  }
}

Type coercion

To prevent the accidental use of a BigNumber in primitive number operations, or the accidental addition of a BigNumber to a string, the valueOf method can be safely overwritten as shown below.

The valueOf method is the same as the toJSON method, and both are the same as the toString method except they do not take a base argument and they include the minus sign for negative zero.

BigNumber.prototype.valueOf = function () {
  throw Error('valueOf called!')
}

x = new BigNumber(1)
x / 2                    // '[BigNumber Error] valueOf called!'
x + 'abc'                // '[BigNumber Error] valueOf called!'

FAQ

Why are trailing fractional zeros removed from BigNumbers?

Some arbitrary-precision libraries retain trailing fractional zeros as they can indicate the precision of a value. This can be useful but the results of arithmetic operations can be misleading.

x = new BigDecimal("1.0")
y = new BigDecimal("1.1000")
z = x.add(y)                      // 2.1000

x = new BigDecimal("1.20")
y = new BigDecimal("3.45000")
z = x.multiply(y)                 // 4.1400000

To specify the precision of a value is to specify that the value lies within a certain range.

In the first example, x has a value of 1.0. The trailing zero shows the precision of the value, implying that it is in the range 0.95 to 1.05. Similarly, the precision indicated by the trailing zeros of y indicates that the value is in the range 1.09995 to 1.10005.

If we add the two lowest values in the ranges we have, 0.95 + 1.09995 = 2.04995, and if we add the two highest values we have, 1.05 + 1.10005 = 2.15005, so the range of the result of the addition implied by the precision of its operands is 2.04995 to 2.15005.

The result given by BigDecimal of 2.1000 however, indicates that the value is in the range 2.09995 to 2.10005 and therefore the precision implied by its trailing zeros may be misleading.

In the second example, the true range is 4.122744 to 4.157256 yet the BigDecimal answer of 4.1400000 indicates a range of 4.13999995 to 4.14000005. Again, the precision implied by the trailing zeros may be misleading.

This library, like binary floating point and most calculators, does not retain trailing fractional zeros. Instead, the toExponential, toFixed and toPrecision methods enable trailing zeros to be added if and when required.