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bignumber.d.ts
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bignumber.d.ts
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// Type definitions for bignumber.js >=8.1.0
// Project: https://github.com/MikeMcl/bignumber.js
// Definitions by: Michael Mclaughlin <https://github.com/MikeMcl>
// Definitions: https://github.com/MikeMcl/bignumber.js
// Documentation: http://mikemcl.github.io/bignumber.js/
//
// Exports:
//
// class BigNumber (default export)
// type BigNumber.Constructor
// type BigNumber.ModuloMode
// type BigNumber.RoundingMOde
// type BigNumber.Value
// interface BigNumber.Config
// interface BigNumber.Format
// interface BigNumber.Instance
//
// Example:
//
// import {BigNumber} from "bignumber.js"
// //import BigNumber from "bignumber.js"
//
// let rm: BigNumber.RoundingMode = BigNumber.ROUND_UP;
// let f: BigNumber.Format = { decimalSeparator: ',' };
// let c: BigNumber.Config = { DECIMAL_PLACES: 4, ROUNDING_MODE: rm, FORMAT: f };
// BigNumber.config(c);
//
// let v: BigNumber.Value = '12345.6789';
// let b: BigNumber = new BigNumber(v);
//
// The use of compiler option `--strictNullChecks` is recommended.
export default BigNumber;
export namespace BigNumber {
/** See `BigNumber.config` (alias `BigNumber.set`) and `BigNumber.clone`. */
interface Config {
/**
* An integer, 0 to 1e+9. Default value: 20.
*
* The maximum number of decimal places of the result of operations involving division, i.e.
* division, square root and base conversion operations, and exponentiation when the exponent is
* negative.
*
* ```ts
* BigNumber.config({ DECIMAL_PLACES: 5 })
* BigNumber.set({ DECIMAL_PLACES: 5 })
* ```
*/
DECIMAL_PLACES?: number;
/**
* An integer, 0 to 8. Default value: `BigNumber.ROUND_HALF_UP` (4).
*
* The rounding mode used in operations that involve division (see `DECIMAL_PLACES`) and the
* default rounding mode of the `decimalPlaces`, `precision`, `toExponential`, `toFixed`,
* `toFormat` and `toPrecision` methods.
*
* The modes are available as enumerated properties of the BigNumber constructor.
*
* ```ts
* BigNumber.config({ ROUNDING_MODE: 0 })
* BigNumber.set({ ROUNDING_MODE: BigNumber.ROUND_UP })
* ```
*/
ROUNDING_MODE?: BigNumber.RoundingMode;
/**
* An integer, 0 to 1e+9, or an array, [-1e+9 to 0, 0 to 1e+9].
* 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 exponential notation is used.
*
* For example, to emulate JavaScript numbers in terms of the exponent values at which they begin
* to use exponential notation, use `[-7, 20]`.
*
* ```ts
* 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.
*/
EXPONENTIAL_AT?: number | [number, number];
/**
* An integer, magnitude 1 to 1e+9, or an array, [-1e+9 to -1, 1 to 1e+9].
* 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].
*
* ```ts
* 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.
*/
RANGE?: number | [number, number];
/**
* A 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 a
* version of Node.js that supports it.
*
* 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 `BigNumber.random`.
*
* ```ts
* // Node.js
* global.crypto = require('crypto')
*
* BigNumber.config({ CRYPTO: true })
* BigNumber.config().CRYPTO // true
* BigNumber.random() // 0.54340758610486147524
* ```
*/
CRYPTO?: boolean;
/**
* An integer, 0, 1, 3, 6 or 9. Default value: `BigNumber.ROUND_DOWN` (1).
*
* 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.
*
* Property | Value | Description
* :------------------|:------|:------------------------------------------------------------------
* `ROUND_UP` | 0 | The remainder is positive if the dividend is negative.
* `ROUND_DOWN` | 1 | The remainder has the same sign as the dividend.
* | | Uses 'truncating division' and matches JavaScript's `%` operator .
* `ROUND_FLOOR` | 3 | The remainder has the same sign as the divisor.
* | | This matches Python's `%` operator.
* `ROUND_HALF_EVEN` | 6 | The IEEE 754 remainder function.
* `EUCLID` | 9 | 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`.
*
* ```ts
* BigNumber.config({ MODULO_MODE: BigNumber.EUCLID })
* BigNumber.set({ MODULO_MODE: 9 }) // equivalent
* ```
*/
MODULO_MODE?: BigNumber.ModuloMode;
/**
* An integer, 0 to 1e+9. 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`.
*
* ```ts
* BigNumber.config({ POW_PRECISION: 100 })
* ```
*/
POW_PRECISION?: number;
/**
* An object including any number of the properties shown below.
*
* The object configures the format of the string returned by the `toFormat` method.
* The example below shows the properties of the 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 object will simply be replaced by the object
* that is passed in.
*
* See `toFormat`.
*
* ```ts
* BigNumber.config({
* FORMAT: {
* // string to prepend
* prefix: '',
* // the decimal separator
* decimalSeparator: '.',
* // the grouping separator of the integer part
* groupSeparator: ',',
* // the primary grouping size of the integer part
* groupSize: 3,
* // the secondary grouping size of the integer part
* secondaryGroupSize: 0,
* // the grouping separator of the fraction part
* fractionGroupSeparator: ' ',
* // the grouping size of the fraction part
* fractionGroupSize: 0,
* // string to append
* suffix: ''
* }
* })
* ```
*/
FORMAT?: BigNumber.Format;
/**
* 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`.
*
* Default value: `'0123456789abcdefghijklmnopqrstuvwxyz'`.
*
* 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 '.'.
*
* ```ts
* // duodecimal (base 12)
* BigNumber.config({ ALPHABET: '0123456789TE' })
* x = new BigNumber('T', 12)
* x.toString() // '10'
* x.toString(12) // 'T'
* ```
*/
ALPHABET?: string;
}
/** See `FORMAT` and `toFormat`. */
interface Format {
/** The string to prepend. */
prefix?: string;
/** The decimal separator. */
decimalSeparator?: string;
/** The grouping separator of the integer part. */
groupSeparator?: string;
/** The primary grouping size of the integer part. */
groupSize?: number;
/** The secondary grouping size of the integer part. */
secondaryGroupSize?: number;
/** The grouping separator of the fraction part. */
fractionGroupSeparator?: string;
/** The grouping size of the fraction part. */
fractionGroupSize?: number;
/** The string to append. */
suffix?: string;
}
interface Instance {
/** The coefficient of the value of this BigNumber, an array of base 1e14 integer numbers, or null. */
readonly c: number[] | null;
/** The exponent of the value of this BigNumber, an integer number, -1000000000 to 1000000000, or null. */
readonly e: number | null;
/** The sign of the value of this BigNumber, -1, 1, or null. */
readonly s: number | null;
[key: string]: any;
}
type Constructor = typeof BigNumber;
type ModuloMode = 0 | 1 | 3 | 6 | 9;
type RoundingMode = 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8;
type Value = string | number | Instance;
}
export declare class BigNumber implements BigNumber.Instance {
/** Used internally to identify a BigNumber instance. */
private readonly _isBigNumber: true;
/** The coefficient of the value of this BigNumber, an array of base 1e14 integer numbers, or null. */
readonly c: number[] | null;
/** The exponent of the value of this BigNumber, an integer number, -1000000000 to 1000000000, or null. */
readonly e: number | null;
/** The sign of the value of this BigNumber, -1, 1, or null. */
readonly s: number | null;
/**
* 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`.
*
* ```ts
* 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.
*
* ```ts
* 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.
*
* ```ts
* 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'`, 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.
*
* ```ts
* 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 desired.
*
* ```ts
* 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.
*
* 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.
*
* ```ts
* new BigNumber('5032485723458348569331745.33434346346912144534543')
* new BigNumber('4.321e10000000')
* ```
*
* BigNumber `NaN` is returned if `n` is invalid (unless `BigNumber.DEBUG` is `true`, see below).
*
* ```ts
* 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.
*
* ```ts
* console.log(823456789123456.3) // 823456789123456.2
* new BigNumber(823456789123456.3) // '823456789123456.2'
* BigNumber.DEBUG = true
* // 'Error: Number has more than 15 significant digits'
* new BigNumber(823456789123456.3)
* // '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.
*
* ```ts
* new BigNumber({ s: 1, e: 2, c: [ 777, 12300000000000 ], _isBigNumber: true }) // '777.123'
* ```
*
* @param n A numeric value.
* @param base The base of `n`, integer, 2 to 36 (or `ALPHABET.length`, see `ALPHABET`).
*/
constructor(n: BigNumber.Value, base?: number);
/**
* 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.
*
* ```ts
* x = new BigNumber(-0.8)
* x.absoluteValue() // '0.8'
* ```
*/
absoluteValue(): 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.
*
* ```ts
* x = new BigNumber(-0.8)
* x.abs() // '0.8'
* ```
*/
abs(): BigNumber;
/**
* 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`
*
* ```ts
*
* 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
* ```
* @param n A numeric value.
* @param [base] The base of n.
*/
comparedTo(n: BigNumber.Value, base?: number): number;
/**
* Returns a BigNumber whose value is the value of this BigNumber rounded by rounding mode
* `roundingMode` to a maximum of `decimalPlaces` decimal places.
*
* If `decimalPlaces` 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 `roundingMode` is omitted, or is `null` or `undefined`, `ROUNDING_MODE` is used.
*
* Throws if `decimalPlaces` or `roundingMode` is invalid.
*
* ```ts
* x = new BigNumber(1234.56)
* x.decimalPlaces() // 2
* x.decimalPlaces(1) // '1234.6'
* x.decimalPlaces(2) // '1234.56'
* x.decimalPlaces(10) // '1234.56'
* x.decimalPlaces(0, 1) // '1234'
* x.decimalPlaces(0, 6) // '1235'
* x.decimalPlaces(1, 1) // '1234.5'
* x.decimalPlaces(1, BigNumber.ROUND_HALF_EVEN) // '1234.6'
* x // '1234.56'
* y = new BigNumber('9.9e-101')
* y.decimalPlaces() // 102
* ```
*
* @param [decimalPlaces] Decimal places, integer, 0 to 1e+9.
* @param [roundingMode] Rounding mode, integer, 0 to 8.
*/
decimalPlaces(): number;
decimalPlaces(decimalPlaces: number, roundingMode?: BigNumber.RoundingMode): BigNumber;
/**
* Returns a BigNumber whose value is the value of this BigNumber rounded by rounding mode
* `roundingMode` to a maximum of `decimalPlaces` decimal places.
*
* If `decimalPlaces` 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 `roundingMode` is omitted, or is `null` or `undefined`, `ROUNDING_MODE` is used.
*
* Throws if `decimalPlaces` or `roundingMode` is invalid.
*
* ```ts
* x = new BigNumber(1234.56)
* x.dp() // 2
* x.dp(1) // '1234.6'
* x.dp(2) // '1234.56'
* x.dp(10) // '1234.56'
* x.dp(0, 1) // '1234'
* x.dp(0, 6) // '1235'
* x.dp(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
* ```
*
* @param [decimalPlaces] Decimal places, integer, 0 to 1e+9.
* @param [roundingMode] Rounding mode, integer, 0 to 8.
*/
dp(): number;
dp(decimalPlaces: number, roundingMode?: BigNumber.RoundingMode): BigNumber;
/**
* 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.
*
* ```ts
* x = new BigNumber(355)
* y = new BigNumber(113)
* x.dividedBy(y) // '3.14159292035398230088'
* x.dividedBy(5) // '71'
* x.dividedBy(47, 16) // '5'
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
dividedBy(n: BigNumber.Value, base?: number): BigNumber;
/**
* 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.
*
* ```ts
* x = new BigNumber(355)
* y = new BigNumber(113)
* x.div(y) // '3.14159292035398230088'
* x.div(5) // '71'
* x.div(47, 16) // '5'
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
div(n: BigNumber.Value, base?: number): BigNumber;
/**
* Returns a BigNumber whose value is the integer part of dividing the value of this BigNumber by
* `n`.
*
* ```ts
* x = new BigNumber(5)
* y = new BigNumber(3)
* x.dividedToIntegerBy(y) // '1'
* x.dividedToIntegerBy(0.7) // '7'
* x.dividedToIntegerBy('0.f', 16) // '5'
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
dividedToIntegerBy(n: BigNumber.Value, base?: number): BigNumber;
/**
* Returns a BigNumber whose value is the integer part of dividing the value of this BigNumber by
* `n`.
*
* ```ts
* x = new BigNumber(5)
* y = new BigNumber(3)
* x.idiv(y) // '1'
* x.idiv(0.7) // '7'
* x.idiv('0.f', 16) // '5'
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
idiv(n: BigNumber.Value, base?: number): 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`.
*
* 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. 123.456**10000 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.
*
* Throws if `n` is not an integer.
*
* ```ts
* Math.pow(0.7, 2) // 0.48999999999999994
* x = new BigNumber(0.7)
* x.exponentiatedBy(2) // '0.49'
* BigNumber(3).exponentiatedBy(-2) // '0.11111111111111111111'
* ```
*
* @param n The exponent, an integer.
* @param [m] The modulus.
*/
exponentiatedBy(n: BigNumber.Value, m?: BigNumber.Value): BigNumber;
exponentiatedBy(n: number, m?: BigNumber.Value): 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`.
*
* 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. 123.456**10000 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.pow(n).modulo(m)` with a `POW_PRECISION` of 0.
*
* Throws if `n` is not an integer.
*
* ```ts
* Math.pow(0.7, 2) // 0.48999999999999994
* x = new BigNumber(0.7)
* x.pow(2) // '0.49'
* BigNumber(3).pow(-2) // '0.11111111111111111111'
* ```
*
* @param n The exponent, an integer.
* @param [m] The modulus.
*/
pow(n: BigNumber.Value, m?: BigNumber.Value): BigNumber;
pow(n: number, m?: BigNumber.Value): BigNumber;
/**
* 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.
*
* ```ts
* x = new BigNumber(123.456)
* x.integerValue() // '123'
* x.integerValue(BigNumber.ROUND_CEIL) // '124'
* y = new BigNumber(-12.7)
* y.integerValue() // '-13'
* x.integerValue(BigNumber.ROUND_DOWN) // '-12'
* ```
*
* @param {BigNumber.RoundingMode} [rm] The roundng mode, an integer, 0 to 8.
*/
integerValue(rm?: BigNumber.RoundingMode): BigNumber;
/**
* 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`.
*
* ```ts
* 0 === 1e-324 // true
* x = new BigNumber(0)
* x.isEqualTo('1e-324') // false
* BigNumber(-0).isEqualTo(x) // true ( -0 === 0 )
* BigNumber(255).isEqualTo('ff', 16) // true
*
* y = new BigNumber(NaN)
* y.isEqualTo(NaN) // false
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
isEqualTo(n: BigNumber.Value, base?: number): boolean;
/**
* 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`.
*
* ```ts
* 0 === 1e-324 // true
* x = new BigNumber(0)
* x.eq('1e-324') // false
* BigNumber(-0).eq(x) // true ( -0 === 0 )
* BigNumber(255).eq('ff', 16) // true
*
* y = new BigNumber(NaN)
* y.eq(NaN) // false
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
eq(n: BigNumber.Value, base?: number): 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`.
*
* ```ts
* x = new BigNumber(1)
* x.isFinite() // true
* y = new BigNumber(Infinity)
* y.isFinite() // false
* ```
*/
isFinite(): boolean;
/**
* Returns `true` if the value of this BigNumber is greater than the value of `n`, otherwise
* returns `false`.
*
* ```ts
* 0.1 > (0.3 - 0.2) // true
* x = new BigNumber(0.1)
* x.isGreaterThan(BigNumber(0.3).minus(0.2)) // false
* BigNumber(0).isGreaterThan(x) // false
* BigNumber(11, 3).isGreaterThan(11.1, 2) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
isGreaterThan(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is greater than the value of `n`, otherwise
* returns `false`.
*
* ```ts
* 0.1 > (0.3 - 0 // true
* x = new BigNumber(0.1)
* x.gt(BigNumber(0.3).minus(0.2)) // false
* BigNumber(0).gt(x) // false
* BigNumber(11, 3).gt(11.1, 2) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
gt(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is greater than or equal to the value of `n`,
* otherwise returns `false`.
*
* ```ts
* (0.3 - 0.2) >= 0.1 // false
* x = new BigNumber(0.3).minus(0.2)
* x.isGreaterThanOrEqualTo(0.1) // true
* BigNumber(1).isGreaterThanOrEqualTo(x) // true
* BigNumber(10, 18).isGreaterThanOrEqualTo('i', 36) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
isGreaterThanOrEqualTo(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is greater than or equal to the value of `n`,
* otherwise returns `false`.
*
* ```ts
* (0.3 - 0.2) >= 0.1 // false
* x = new BigNumber(0.3).minus(0.2)
* x.gte(0.1) // true
* BigNumber(1).gte(x) // true
* BigNumber(10, 18).gte('i', 36) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
gte(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is an integer, otherwise returns `false`.
*
* ```ts
* x = new BigNumber(1)
* x.isInteger() // true
* y = new BigNumber(123.456)
* y.isInteger() // false
* ```
*/
isInteger(): boolean;
/**
* Returns `true` if the value of this BigNumber is less than the value of `n`, otherwise returns
* `false`.
*
* ```ts
* (0.3 - 0.2) < 0.1 // true
* x = new BigNumber(0.3).minus(0.2)
* x.isLessThan(0.1) // false
* BigNumber(0).isLessThan(x) // true
* BigNumber(11.1, 2).isLessThan(11, 3) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
isLessThan(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is less than the value of `n`, otherwise returns
* `false`.
*
* ```ts
* (0.3 - 0.2) < 0.1 // true
* x = new BigNumber(0.3).minus(0.2)
* x.lt(0.1) // false
* BigNumber(0).lt(x) // true
* BigNumber(11.1, 2).lt(11, 3) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
lt(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is less than or equal to the value of `n`,
* otherwise returns `false`.
*
* ```ts
* 0.1 <= (0.3 - 0.2) // false
* x = new BigNumber(0.1)
* x.isLessThanOrEqualTo(BigNumber(0.3).minus(0.2)) // true
* BigNumber(-1).isLessThanOrEqualTo(x) // true
* BigNumber(10, 18).isLessThanOrEqualTo('i', 36) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
isLessThanOrEqualTo(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is less than or equal to the value of `n`,
* otherwise returns `false`.
*
* ```ts
* 0.1 <= (0.3 - 0.2) // false
* x = new BigNumber(0.1)
* x.lte(BigNumber(0.3).minus(0.2)) // true
* BigNumber(-1).lte(x) // true
* BigNumber(10, 18).lte('i', 36) // true
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
lte(n: BigNumber.Value, base?: number): boolean;
/**
* Returns `true` if the value of this BigNumber is `NaN`, otherwise returns `false`.
*
* ```ts
* x = new BigNumber(NaN)
* x.isNaN() // true
* y = new BigNumber('Infinity')
* y.isNaN() // false
* ```
*/
isNaN(): boolean;
/**
* Returns `true` if the value of this BigNumber is negative, otherwise returns `false`.
*
* ```ts
* x = new BigNumber(-0)
* x.isNegative() // true
* y = new BigNumber(2)
* y.isNegative() // false
* ```
*/
isNegative(): boolean;
/**
* Returns `true` if the value of this BigNumber is positive, otherwise returns `false`.
*
* ```ts
* x = new BigNumber(-0)
* x.isPositive() // false
* y = new BigNumber(2)
* y.isPositive() // true
* ```
*/
isPositive(): boolean;
/**
* Returns `true` if the value of this BigNumber is zero or minus zero, otherwise returns `false`.
*
* ```ts
* x = new BigNumber(-0)
* x.isZero() // true
* ```
*/
isZero(): boolean;
/**
* Returns a BigNumber whose value is the value of this BigNumber minus `n`.
*
* The return value is always exact and unrounded.
*
* ```ts
* 0.3 - 0.1 // 0.19999999999999998
* x = new BigNumber(0.3)
* x.minus(0.1) // '0.2'
* x.minus(0.6, 20) // '0'
* ```
*
* @param n A numeric value.
* @param [base] The base of n.
*/
minus(n: BigNumber.Value, base?: number): BigNumber;
/**
* 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.
*
* ```ts
* 1 % 0.9 // 0.09999999999999998
* x = new BigNumber(1)
* x.modulo(0.9) // '0.1'
* y = new BigNumber(33)
* y.modulo('a', 33) // '3'