import { Decimal } from 'decimal.js'; declare const math: math.MathJsStatic; export as namespace math; export = math; type NoLiteralType = T extends number ? number : T extends string ? string : T extends boolean ? boolean : T; declare namespace math { type MathArray = number[] | number[][]; type MathType = number | BigNumber | Fraction | Complex | Unit | MathArray | Matrix; type MathExpression = string | string[] | MathArray | Matrix; type FactoryFunction = (scope: any) => T; // FactoryFunctionMap can be nested; all nested objects will be flattened interface FactoryFunctionMap { [key: string]: FactoryFunction | FactoryFunctionMap; } /** Available options for parse */ interface ParseOptions { /** a set of custom nodes */ nodes?: Record; } /** * Parse an expression. Returns a node tree, which can be evaluated by * invoking node.evaluate(). * * Note the evaluating arbitrary expressions may involve security risks, * see [https://mathjs.org/docs/expressions/security.html](https://mathjs.org/docs/expressions/security.html) for more information. * * Syntax: * * math.parse(expr) * math.parse(expr, options) * math.parse([expr1, expr2, expr3, ...]) * math.parse([expr1, expr2, expr3, ...], options) * * Example: * * const node1 = math.parse('sqrt(3^2 + 4^2)') * node1.compile().evaluate() // 5 * * let scope = {a:3, b:4} * const node2 = math.parse('a * b') // 12 * const code2 = node2.compile() * code2.evaluate(scope) // 12 * scope.a = 5 * code2.evaluate(scope) // 20 * * const nodes = math.parse(['a = 3', 'b = 4', 'a * b']) * nodes[2].compile().evaluate() // 12 * * See also: * * evaluate, compile */ interface ParseFunction { /** * Parse an expression. Returns a node tree, which can be evaluated by * invoking node.evaluate(); * * @param expr Expression to be parsed * @param options Available options * @returns A node */ (expr: MathExpression, options?: ParseOptions): MathNode; /** * Parse an expression. Returns a node tree, which can be evaluated by * invoking node.evaluate(); * * @param exprs Expressions to be parsed * @param options Available options * @returns An array of nodes */ (exprs: MathExpression[], options?: ParseOptions): MathNode[]; /** * Checks whether the current character `c` is a valid alpha character: * * - A latin letter (upper or lower case) Ascii: a-z, A-Z * - An underscore Ascii: _ * - A dollar sign Ascii: $ * - A latin letter with accents Unicode: \u00C0 - \u02AF * - A greek letter Unicode: \u0370 - \u03FF * - A mathematical alphanumeric symbol Unicode: \u{1D400} - \u{1D7FF} excluding invalid code points * * The previous and next characters are needed to determine whether * this character is part of a unicode surrogate pair. * * @param c Current character in the expression * @param cPrev Previous character * @param cNext Next character */ isAlpha(c: string, cPrev: string, cNext: string): boolean; /** * Test whether a character is a valid latin, greek, or letter-like character * * @param c */ isValidLatinOrGreek(c: string): boolean; /** * Test whether two given 16 bit characters form a surrogate pair of a * unicode math symbol. * * https://unicode-table.com/en/ * https://www.wikiwand.com/en/Mathematical_operators_and_symbols_in_Unicode * * Note: In ES6 will be unicode aware: * https://stackoverflow.com/questions/280712/javascript-unicode-regexes * https://mathiasbynens.be/notes/es6-unicode-regex * * @param high * @param low */ isValidMathSymbol(high: string, low: string): boolean; /** * Check whether given character c is a white space character: space, tab, or enter * * @param c * @param nestingLevel */ isWhitespace(c: string, nestingLevel: number): boolean; /** * Test whether the character c is a decimal mark (dot). * This is the case when it's not the start of a delimiter '.*', './', or '.^' * * @param c * @param cNext */ isDecimalMark(c: string, cNext: string): boolean; /** * checks if the given char c is a digit or dot * * @param c a string with one character */ isDigitDot(c: string): boolean; /** * checks if the given char c is a digit * * @param c a string with one character */ isDigit(c: string): boolean; /** * checks if the given char c is a hex digit * * @param c a string with one character */ isHexDigit(c: string): boolean; } interface AccessorNode extends MathNodeCommon { type: 'AccessorNode'; isAccessorNode: true; object: MathNode; index: IndexNode; name: string; } interface AccessorNodeCtor { new(object: MathNode, index: IndexNode): AccessorNode; } interface ArrayNode extends MathNodeCommon { type: 'ArrayNode'; isArrayNode: true; items: MathNode[]; } interface ArrayNodeCtor { new(items: MathNode[]): ArrayNode; } interface AssignmentNode extends MathNodeCommon { type: 'AssignmentNode'; isAssignmentNode: true; object: SymbolNode | AccessorNode; index: IndexNode | null; value: MathNode; name: string; } interface AssignmentNodeCtor { new(object: SymbolNode, value: MathNode): AssignmentNode; new(object: SymbolNode | AccessorNode, index: IndexNode, value: MathNode): AssignmentNode; } interface BlockNode extends MathNodeCommon { type: 'BlockNode'; isBlockNode: true; blocks: Array<{node: MathNode, visible: boolean}>; } interface BlockNodeCtor { new(arr: Array<{node: MathNode} | {node: MathNode, visible: boolean}>): BlockNode; } interface ConditionalNode extends MathNodeCommon { type: 'ConditionalNode'; isConditionalNode: boolean; condition: MathNode; trueExpr: MathNode; falseExpr: MathNode; } interface ConditionalNodeCtor { new(condition: MathNode, trueExpr: MathNode, falseExpr: MathNode): ConditionalNode; } interface ConstantNode extends MathNodeCommon { type: 'ConstantNode'; isConstantNode: true; value: any; } interface ConstantNodeCtor { new(constant: number): ConstantNode; } interface FunctionAssignmentNode extends MathNodeCommon { type: 'FunctionAssignmentNode'; isFunctionAssignmentNode: true; name: string; params: string[]; expr: MathNode; } interface FunctionAssignmentNodeCtor { new(name: string, params: string[], expr: MathNode): FunctionAssignmentNode; } interface FunctionNode extends MathNodeCommon { type: 'FunctionNode'; isFunctionNode: true; fn: SymbolNode; args: MathNode[]; } interface FunctionNodeCtor { new(fn: MathNode | string, args: MathNode[]): FunctionNode; } interface IndexNode extends MathNodeCommon { type: 'IndexNode'; isIndexNode: true; dimensions: MathNode[]; dotNotation: boolean; } interface IndexNodeCtor { new(dimensions: MathNode[]): IndexNode; new(dimensions: MathNode[], dotNotation: boolean): IndexNode; } interface ObjectNode extends MathNodeCommon { type: 'ObjectNode'; isObjectNode: true; properties: Record; } interface ObjectNodeCtor { new(properties: Record): ObjectNode; } interface OperatorNode extends MathNodeCommon { type: 'OperatorNode'; isOperatorNode: true; op: string; fn: string; args: MathNode[]; implicit: boolean; isUnary(): boolean; isBinary(): boolean; } interface OperatorNodeCtor { new(op: string, fn: string, args: MathNode[], implicit?: boolean): OperatorNode; } interface ParenthesisNode extends MathNodeCommon { type: 'ParenthesisNode'; isParenthesisNode: true; content: MathNode; } interface ParenthesisNodeCtor { new(content: MathNode): ParenthesisNode; } interface RangeNode extends MathNodeCommon { type: 'RangeNode'; isRangeNode: true; start: MathNode; end: MathNode; step: MathNode | null; } interface RangeNodeCtor { new(start: MathNode, end: MathNode, step?: MathNode): RangeNode; } interface RelationalNode extends MathNodeCommon { type: 'RelationalNode'; isRelationalNode: true; conditionals: string[]; params: MathNode[]; } interface RelationalNodeCtor { new(conditionals: string[], params: MathNode[]): RelationalNode; } interface SymbolNode extends MathNodeCommon { type: 'SymbolNode'; isSymbolNode: true; name: string; } interface SymbolNodeCtor { new(name: string): SymbolNode; } type MathNode = AccessorNode | ArrayNode | AssignmentNode | BlockNode | ConditionalNode | ConstantNode | FunctionAssignmentNode | FunctionNode | IndexNode | ObjectNode | OperatorNode | ParenthesisNode | RangeNode | RelationalNode | SymbolNode; type MathJsFunctionName = keyof MathJsStatic; interface MathJsStatic extends FactoryDependencies { e: number; pi: number; i: number; Infinity: number; LN2: number; LN10: number; LOG2E: number; LOG10E: number; NaN: number; phi: number; SQRT1_2: number; SQRT2: number; tau: number; // Class-like constructors AccessorNode: AccessorNodeCtor; ArrayNode: ArrayNodeCtor; AssignmentNode: AssignmentNodeCtor; BlockNode: BlockNodeCtor; ConditionalNode: ConditionalNodeCtor; ConstantNode: ConstantNodeCtor; FunctionAssignmentNode: FunctionAssignmentNodeCtor; FunctionNode: FunctionNodeCtor; IndexNode: IndexNodeCtor; ObjectNode: ObjectNodeCtor; OperatorNode: OperatorNodeCtor; ParenthesisNode: ParenthesisNodeCtor; RangeNode: RangeNodeCtor; RelationalNode: RelationalNodeCtor; SymbolNode: SymbolNodeCtor; /** * If null were to be included in this interface, it would be * auto-suggested as an import in VSCode. This causes issues because * `null` is not a valid label. * * @see https://github.com/josdejong/mathjs/issues/2019 */ // null: number; uninitialized: any; version: string; expression: MathNode; json: MathJsJson; /************************************************************************* * Core functions ************************************************************************/ /** * Set configuration options for math.js, and get current options. Will * emit a ‘config’ event, with arguments (curr, prev, changes). * @param options Available options: {number} epsilon Minimum relative * difference between two compared values, used by all comparison * functions. {string} matrix A string ‘Matrix’ (default) or ‘Array’. * {string} number A string ‘number’ (default), ‘BigNumber’, or * ‘Fraction’ {number} precision The number of significant digits for * BigNumbers. Not applicable for Numbers. {string} parenthesis How to * display parentheses in LaTeX and string output. {string} randomSeed * Random seed for seeded pseudo random number generator. Set to null to * randomly seed. * @returns Returns the current configuration */ config: (options: ConfigOptions) => ConfigOptions; /** * Create a typed-function which checks the types of the arguments and * can match them against multiple provided signatures. The * typed-function automatically converts inputs in order to find a * matching signature. Typed functions throw informative errors in case * of wrong input arguments. * @param name Optional name for the typed-function * @param signatures Object with one or multiple function signatures * @returns The created typed-function. */ typed: (name: string, signatures: Record any>) => (...args: any[]) => any; /************************************************************************* * Construction functions ************************************************************************/ /** * Create a BigNumber, which can store numbers with arbitrary precision. * When a matrix is provided, all elements will be converted to * BigNumber. * @param x Value for the big number, 0 by default. * @returns The created bignumber */ bignumber(x?: number | string | Fraction | BigNumber | MathArray | Matrix | boolean | Fraction | null): BigNumber; /** * Create a boolean or convert a string or number to a boolean. In case * of a number, true is returned for non-zero numbers, and false in case * of zero. Strings can be 'true' or 'false', or can contain a number. * When value is a matrix, all elements will be converted to boolean. * @param x A value of any type * @returns The boolean value */ boolean(x: string | number | boolean | MathArray | Matrix | null): boolean | MathArray | Matrix; /** * Wrap any value in a chain, allowing to perform chained operations on * the value. All methods available in the math.js library can be called * upon the chain, and then will be evaluated with the value itself as * first argument. The chain can be closed by executing chain.done(), * which returns the final value. The chain has a number of special * functions: done() Finalize the chain and return the chain's value. * valueOf() The same as done() toString() Executes math.format() onto * the chain's value, returning a string representation of the value. * @param value A value of any type on which to start a chained * operation. * @returns The created chain */ chain(value?: any): MathJsChain; /** * Create a complex value or convert a value to a complex value. * @param args Arguments specifying the real and imaginary part of the * complex number * @returns Returns a complex value */ complex(arg?: Complex | string | PolarCoordinates): Complex; complex(arg?: MathArray | Matrix): MathArray | Matrix; /** * @param re Argument specifying the real part of the complex number * @param im Argument specifying the imaginary part of the complex * number * @returns Returns a complex value */ complex(re: number, im: number): Complex; /** * Create a user-defined unit and register it with the Unit type. * @param name The name of the new unit. Must be unique. Example: ‘knot’ * @param definition Definition of the unit in terms of existing units. * For example, ‘0.514444444 m / s’. * @param options (optional) An object containing any of the following * properties:
- prefixes {string} “none”, “short”, “long”, * “binary_short”, or “binary_long”. The default is “none”.
- * aliases {Array} Array of strings. Example: [‘knots’, ‘kt’, * ‘kts’]
- offset {Numeric} An offset to apply when converting from * the unit. For example, the offset for celsius is 273.15. Default is * 0. * @returns The new unit */ createUnit(name: string, definition?: string | UnitDefinition, options?: CreateUnitOptions): Unit; /** * Create a user-defined unit and register it with the Unit type. * @param units Definition of the unit * @param options * @returns The new unit */ createUnit(units: Record, options?: CreateUnitOptions): Unit; /** * Create a fraction convert a value to a fraction. * @param args Arguments specifying the numerator and denominator of the * fraction * @returns Returns a fraction */ fraction(args: Fraction | MathArray | Matrix): Fraction | MathArray | Matrix; /** * @param numerator Argument specifying the numerator of the fraction * @param denominator Argument specifying the denominator of the * fraction * @returns Returns a fraction */ fraction( numerator: number | string | MathArray | Matrix, denominator?: number | string | MathArray | Matrix ): Fraction | MathArray | Matrix; /** * Create an index. An Index can store ranges having start, step, and * end for multiple dimensions. Matrix.get, Matrix.set, and math.subset * accept an Index as input. * @param ranges Zero or more ranges or numbers. * @returns Returns the created index */ index(...ranges: any[]): Index; /** * Create a Matrix. The function creates a new math.type.Matrix object * from an Array. A Matrix has utility functions to manipulate the data * in the matrix, like getting the size and getting or setting values in * the matrix. Supported storage formats are 'dense' and 'sparse'. * @param format The Matrix storage format * @returns The created Matrix */ matrix(format?: 'sparse' | 'dense'): Matrix; /** * @param data A multi dimensional array * @param format The Matrix storage format * @param dataType The Matrix data type * @returns The created Matrix */ matrix(data: MathArray | Matrix, format?: 'sparse' | 'dense', dataType?: string): Matrix; /** * Create a number or convert a string, boolean, or unit to a number. * When value is a matrix, all elements will be converted to number. * @param value Value to be converted * @returns The created number */ number(value?: string | number | BigNumber | Fraction | boolean | MathArray | Matrix | Unit | null): number | MathArray | Matrix; /** * @param value Value to be converted * @param valuelessUnit A valueless unit, used to convert a unit to a * number * @returns The created number */ number(unit: Unit, valuelessUnit: Unit | string): number; /** * Create a Sparse Matrix. The function creates a new math.type.Matrix * object from an Array. A Matrix has utility functions to manipulate * the data in the matrix, like getting the size and getting or setting * values in the matrix. * @param data A two dimensional array * @param dataType Sparse Matrix data type * @returns The created matrix */ sparse(data?: MathArray | Matrix, dataType?: string): Matrix; /** * Split a unit in an array of units whose sum is equal to the original * unit. * @param unit A unit to be split * @param parts An array of strings or valueless units * @returns An array of units */ splitUnit(unit: Unit, parts: Unit[]): Unit[]; /** * Create a string or convert any object into a string. Elements of * Arrays and Matrices are processed element wise. * @param value A value to convert to a string * @returns The created string */ string(value: MathType | null): string | MathArray | Matrix; /** * Create a unit. Depending on the passed arguments, the function will * create and return a new math.type.Unit object. When a matrix is * provided, all elements will be converted to units. * @param unit The unit to be created * @returns The created unit */ unit(unit: string): Unit; /** * @param value The value of the unit to be created * @param unit The unit to be created * @returns The created unit */ unit(value: number | MathArray | Matrix, unit: string): Unit; /************************************************************************* * Expression functions ************************************************************************/ /** * Parse and compile an expression. Returns a an object with a function * evaluate([scope]) to evaluate the compiled expression. * @param expr The expression to be compiled * @returns An object with the compiled expression */ compile(expr: MathExpression): EvalFunction; /** * @param exprs The expressions to be compiled * @returns An array of objects with the compiled expressions */ compile(exprs: MathExpression[]): EvalFunction[]; /** * Evaluate an expression. * @param expr The expression to be evaluated * @param scope Scope to read/write variables * @returns The result of the expression */ evaluate(expr: MathExpression | MathExpression[] | Matrix, scope?: object): any; /** * Retrieve help on a function or data type. Help files are retrieved * from the documentation in math.expression.docs. * @param search A function or function name for which to get help * @returns A help object */ help(search: () => any): Help; /** * Parse an expression. Returns a node tree, which can be evaluated by * invoking node.evaluate(); */ parse: ParseFunction; /** * Create a parser. The function creates a new math.expression.Parser * object. * @returns A Parser object */ parser(): Parser; /************************************************************************* * Algebra functions ************************************************************************/ /** * @param expr The expression to differentiate * @param variable The variable over which to differentiate * @param options There is one option available, simplify, which is true * by default. When false, output will not be simplified. * @returns The derivative of expr */ derivative(expr: MathNode | string, variable: MathNode | string, options?: { simplify: boolean }): MathNode; /** * Solves the linear equation system by forwards substitution. Matrix * must be a lower triangular matrix. * @param L A N x N matrix or array (L) * @param b A column vector with the b values * @returns A column vector with the linear system solution (x) */ lsolve(L: Matrix | MathArray, b: Matrix | MathArray): Matrix | MathArray; /** * Calculate the Matrix LU decomposition with partial pivoting. Matrix A * is decomposed in two matrices (L, U) and a row permutation vector p * where A[p,:] = L * U * @param A A two dimensional matrix or array for which to get the LUP * decomposition. * @returns The lower triangular matrix, the upper triangular matrix and * the permutation matrix. */ lup(A?: Matrix | MathArray): { L: MathArray | Matrix; U: MathArray | Matrix; P: number[] }; /** * Solves the linear system A * x = b where A is an [n x n] matrix and b * is a [n] column vector. * @param A Invertible Matrix or the Matrix LU decomposition * @param b Column Vector * @param order The Symbolic Ordering and Analysis order, see slu for * details. Matrix must be a SparseMatrix * @param threshold Partial pivoting threshold (1 for partial pivoting), * see slu for details. Matrix must be a SparseMatrix. * @returns Column vector with the solution to the linear system A * x = * b */ lusolve(A: Matrix | MathArray | number, b: Matrix | MathArray, order?: number, threshold?: number): Matrix | MathArray; /** * Calculate the Matrix QR decomposition. Matrix A is decomposed in two * matrices (Q, R) where Q is an orthogonal matrix and R is an upper * triangular matrix. * @param A A two dimensional matrix or array for which to get the QR * decomposition. * @returns Q: the orthogonal matrix and R: the upper triangular matrix */ qr(A: Matrix | MathArray): { Q: MathArray | Matrix; R: MathArray | Matrix }; rationalize(expr: MathNode | string, optional?: object | boolean, detailed?: false): MathNode; /** * Transform a rationalizable expression in a rational fraction. If * rational fraction is one variable polynomial then converts the * numerator and denominator in canonical form, with decreasing * exponents, returning the coefficients of numerator. * @param expr The expression to check if is a polynomial expression * @param optional scope of expression or true for already evaluated * rational expression at input * @param detailed optional True if return an object, false if return * expression node (default) * @returns The rational polynomial of expr */ rationalize( expr: MathNode | string, optional?: object | boolean, detailed?: true ): { expression: MathNode | string; variables: string[]; coefficients: MathType[] }; /** * Simplify an expression tree. * @param expr The expression to be simplified * @param [rules] (optional) A list of rules are applied to an expression, repeating * over the list until no further changes are made. It’s possible to * pass a custom set of rules to the function as second argument. A rule * can be specified as an object, string, or function. * @param [scope] (optional) Scope to variables * @param [options] (optional) An object with simplify options * @returns Returns the simplified form of expr */ simplify: Simplify; /** * Calculate the Sparse Matrix LU decomposition with full pivoting. * Sparse Matrix A is decomposed in two matrices (L, U) and two * permutation vectors (pinv, q) where P * A * Q = L * U * @param A A two dimensional sparse matrix for which to get the LU * decomposition. * @param order The Symbolic Ordering and Analysis order: 0 - Natural * ordering, no permutation vector q is returned 1 - Matrix must be * square, symbolic ordering and analisis is performed on M = A + A' 2 - * Symbolic ordering and analysis is performed on M = A' * A. Dense * columns from A' are dropped, A recreated from A'. This is appropriate * for LU factorization of non-symmetric matrices. 3 - Symbolic ordering * and analysis is performed on M = A' * A. This is best used for LU * factorization is matrix M has no dense rows. A dense row is a row * with more than 10*sqr(columns) entries. * @param threshold Partial pivoting threshold (1 for partial pivoting) * @returns The lower triangular matrix, the upper triangular matrix and * the permutation vectors. */ slu(A: Matrix, order: number, threshold: number): object; /** * Solves the linear equation system by backward substitution. Matrix * must be an upper triangular matrix. U * x = b * @param U A N x N matrix or array (U) * @param b A column vector with the b values * @returns A column vector with the linear system solution (x) */ usolve(U: Matrix | MathArray, b: Matrix | MathArray): Matrix | MathArray; /************************************************************************* * Arithmetic functions ************************************************************************/ /** * Calculate the absolute value of a number. For matrices, the function * is evaluated element wise. * @param x A number or matrix for which to get the absolute value * @returns Absolute value of x */ abs(x: number): number; abs(x: BigNumber): BigNumber; abs(x: Fraction): Fraction; abs(x: Complex): Complex; abs(x: MathArray): MathArray; abs(x: Matrix): Matrix; abs(x: Unit): Unit; /** * Add two values, x + y. For matrices, the function is evaluated * element wise. * @param x First value to add * @param y Second value to add * @returns Sum of x and y */ add(x: MathType, y: MathType): MathType; /** * Calculate the cubic root of a value. For matrices, the function is * evaluated element wise. * @param x Value for which to calculate the cubic root. * @param allRoots Optional, false by default. Only applicable when x is * a number or complex number. If true, all complex roots are returned, * if false (default) the principal root is returned. * @returns Returns the cubic root of x */ cbrt(x: number, allRoots?: boolean): number; cbrt(x: BigNumber, allRoots?: boolean): BigNumber; cbrt(x: Fraction, allRoots?: boolean): Fraction; cbrt(x: Complex, allRoots?: boolean): Complex; cbrt(x: MathArray, allRoots?: boolean): MathArray; cbrt(x: Matrix, allRoots?: boolean): Matrix; cbrt(x: Unit, allRoots?: boolean): Unit; /** * Round a value towards plus infinity If x is complex, both real and * imaginary part are rounded towards plus infinity. For matrices, the * function is evaluated element wise. * @param x Number to be rounded * @returns Rounded value */ ceil(x: number): number; ceil(x: BigNumber): BigNumber; ceil(x: Fraction): Fraction; ceil(x: Complex): Complex; ceil(x: MathArray): MathArray; ceil(x: Matrix): Matrix; ceil(x: Unit): Unit; /** * Compute the cube of a value, x * x * x. For matrices, the function is * evaluated element wise. * @param x Number for which to calculate the cube * @returns Cube of x */ cube(x: number): number; cube(x: BigNumber): BigNumber; cube(x: Fraction): Fraction; cube(x: Complex): Complex; cube(x: MathArray): MathArray; cube(x: Matrix): Matrix; cube(x: Unit): Unit; /** * Divide two values, x / y. To divide matrices, x is multiplied with * the inverse of y: x * inv(y). * @param x Numerator * @param y Denominator * @returns Quotient, x / y */ divide(x: Unit, y: Unit): Unit | number; divide(x: Unit, y: number): Unit; divide(x: number, y: number): number; divide(x: MathType, y: MathType): MathType; /** * Divide two matrices element wise. The function accepts both matrices * and scalar values. * @param x Numerator * @param y Denominator * @returns Quotient, x ./ y */ dotDivide(x: MathType, y: MathType): MathType; /** * Multiply two matrices element wise. The function accepts both * matrices and scalar values. * @param x Left hand value * @param y Right hand value * @returns Multiplication of x and y */ dotMultiply(x: MathType, y: MathType): MathType; /** * Calculates the power of x to y element wise. * @param x The base * @param y The exponent * @returns The value of x to the power y */ dotPow(x: MathType, y: MathType): MathType; /** * Calculate the exponent of a value. For matrices, the function is * evaluated element wise. * @param x A number or matrix to exponentiate * @returns Exponent of x */ exp(x: number): number; exp(x: BigNumber): BigNumber; exp(x: Complex): Complex; exp(x: MathArray): MathArray; exp(x: Matrix): Matrix; /** * Calculate the value of subtracting 1 from the exponential value. For * matrices, the function is evaluated element wise. * @param x A number or matrix to apply expm1 * @returns Exponent of x */ expm1(x: number): number; expm1(x: BigNumber): BigNumber; expm1(x: Complex): Complex; expm1(x: MathArray): MathArray; expm1(x: Matrix): Matrix; /** * Round a value towards zero. For matrices, the function is evaluated * element wise. * @param x Number to be rounded * @returns Rounded value */ fix(x: number): number; fix(x: BigNumber): BigNumber; fix(x: Fraction): Fraction; fix(x: Complex): Complex; fix(x: MathArray): MathArray; fix(x: Matrix): Matrix; /** * Round a value towards minus infinity. For matrices, the function is * evaluated element wise. * @param Number to be rounded * @returns Rounded value */ floor(x: number): number; floor(x: BigNumber): BigNumber; floor(x: Fraction): Fraction; floor(x: Complex): Complex; floor(x: MathArray): MathArray; floor(x: Matrix): Matrix; /** * Round a value towards minus infinity. For matrices, the function is * evaluated element wise. * @param x Number to be rounded * @param n Number of decimals Default value: 0. * @returns Rounded value */ floor( x: number | BigNumber | Fraction | Complex | MathArray | Matrix, n: number | BigNumber | MathArray ): number | BigNumber | Fraction | Complex | MathArray | Matrix; /** * Calculate the greatest common divisor for two or more values or * arrays. For matrices, the function is evaluated element wise. * @param args Two or more integer numbers * @returns The greatest common divisor */ gcd(...args: number[]): number; gcd(...args: BigNumber[]): BigNumber; gcd(...args: Fraction[]): Fraction; gcd(...args: MathArray[]): MathArray; gcd(...args: Matrix[]): Matrix; /** * Calculate the hypotenusa of a list with values. The hypotenusa is * defined as: hypot(a, b, c, ...) = sqrt(a^2 + b^2 + c^2 + ...) For * matrix input, the hypotenusa is calculated for all values in the * matrix. * @param args A list with numeric values or an Array or Matrix. Matrix * and Array input is flattened and returns a single number for the * whole matrix. * @returns Returns the hypothenuse of the input values. */ hypot(...args: number[]): number; hypot(...args: BigNumber[]): BigNumber; /** * Calculate the least common multiple for two or more values or arrays. * lcm is defined as: lcm(a, b) = abs(a * b) / gcd(a, b) For matrices, * the function is evaluated element wise. * @param a An integer number * @param b An integer number * @returns The least common multiple */ lcm(a: number, b: number): number; lcm(a: BigNumber, b: BigNumber): BigNumber; lcm(a: MathArray, b: MathArray): MathArray; lcm(a: Matrix, b: Matrix): Matrix; /** * Calculate the logarithm of a value. For matrices, the function is * evaluated element wise. * @param x Value for which to calculate the logarithm. * @param base Optional base for the logarithm. If not provided, the * natural logarithm of x is calculated. Default value: e. * @returns Returns the logarithm of x */ log(x: T, base?: number | BigNumber | Complex): NoLiteralType; /** * Calculate the 10-base of a value. This is the same as calculating * log(x, 10). For matrices, the function is evaluated element wise. * @param x Value for which to calculate the logarithm. * @returns Returns the 10-base logarithm of x */ log10(x: number): number; log10(x: BigNumber): BigNumber; log10(x: Complex): Complex; log10(x: MathArray): MathArray; log10(x: Matrix): Matrix; /** * Calculate the logarithm of a value+1. For matrices, the function is * evaluated element wise. * @param x Value for which to calculate the logarithm. * @returns Returns the logarithm of x+1 */ log1p(x: number, base?: number | BigNumber | Complex): number; log1p(x: BigNumber, base?: number | BigNumber | Complex): BigNumber; log1p(x: Complex, base?: number | BigNumber | Complex): Complex; log1p(x: MathArray, base?: number | BigNumber | Complex): MathArray; log1p(x: Matrix, base?: number | BigNumber | Complex): Matrix; /** * Calculate the 2-base of a value. This is the same as calculating * log(x, 2). For matrices, the function is evaluated element wise. * @param x Value for which to calculate the logarithm. * @returns Returns the 2-base logarithm of x */ log2(x: number): number; log2(x: BigNumber): BigNumber; log2(x: Complex): Complex; log2(x: MathArray): MathArray; log2(x: Matrix): Matrix; /** * Calculates the modulus, the remainder of an integer division. For * matrices, the function is evaluated element wise. The modulus is * defined as: x - y * floor(x / y) * @see http://en.wikipedia.org/wiki/Modulo_operation. * @param x Dividend * @param y Divisor * @returns Returns the remainder of x divided by y */ mod( x: T, y: number | BigNumber | Fraction | MathArray | Matrix ): NoLiteralType; /** * Multiply two values, x * y. The result is squeezed. For matrices, the * matrix product is calculated. * @param x The first value to multiply * @param y The second value to multiply * @returns Multiplication of x and y */ multiply(x: T, y: MathType): T; multiply(x: Unit, y: Unit): Unit; multiply(x: number, y: number): number; multiply(x: MathType, y: MathType): MathType; /** * Calculate the norm of a number, vector or matrix. The second * parameter p is optional. If not provided, it defaults to 2. * @param x Value for which to calculate the norm * @param p Vector space. Supported numbers include Infinity and * -Infinity. Supported strings are: 'inf', '-inf', and 'fro' (The * Frobenius norm) Default value: 2. * @returns the p-norm */ norm(x: number | BigNumber | Complex | MathArray | Matrix, p?: number | BigNumber | string): number | BigNumber; /** * Calculate the nth root of a value. The principal nth root of a * positive real number A, is the positive real solution of the equation * x^root = A For matrices, the function is evaluated element wise. * @param a Value for which to calculate the nth root * @param root The root. Default value: 2. * @return The nth root of a */ nthRoot(a: number | BigNumber | MathArray | Matrix | Complex, root?: number | BigNumber): number | Complex | MathArray | Matrix; /** * Calculates the power of x to y, x ^ y. Matrix exponentiation is * supported for square matrices x, and positive integer exponents y. * @param x The base * @param y The exponent * @returns x to the power y */ pow(x: MathType, y: number | BigNumber | Complex): MathType; /** * Round a value towards the nearest integer. For matrices, the function * is evaluated element wise. * @param x Number to be rounded * @param n Number of decimals Default value: 0. * @returns Rounded value of x */ round( x: T, n?: number | BigNumber | MathArray ): NoLiteralType; /** * Compute the sign of a value. The sign of a value x is: 1 when x > 1 * -1 when x < 0 0 when x == 0 For matrices, the function is evaluated * element wise. * @param x The number for which to determine the sign * @returns The sign of x */ sign(x: number): number; sign(x: BigNumber): BigNumber; sign(x: Fraction): Fraction; sign(x: Complex): Complex; sign(x: MathArray): MathArray; sign(x: Matrix): Matrix; sign(x: Unit): Unit; /** * Calculate the square root of a value. For matrices, the function is * evaluated element wise. * @param x Value for which to calculate the square root * @returns Returns the square root of x */ sqrt(x: number): number; sqrt(x: BigNumber): BigNumber; sqrt(x: Complex): Complex; sqrt(x: MathArray): MathArray; sqrt(x: Matrix): Matrix; sqrt(x: Unit): Unit; /** * Compute the square of a value, x * x. For matrices, the function is * evaluated element wise. * @param x Number for which to calculate the square * @returns Squared value */ square(x: number): number; square(x: BigNumber): BigNumber; square(x: Fraction): Fraction; square(x: Complex): Complex; square(x: MathArray): MathArray; square(x: Matrix): Matrix; square(x: Unit): Unit; /** * Subtract two values, x - y. For matrices, the function is evaluated * element wise. * @param x Initial value * @param y Value to subtract from x * @returns Subtraction of x and y */ subtract(x: number, y: number): number; subtract(x: Unit, y: Unit): Unit; subtract(x: MathType, y: MathType): MathType; /** * Inverse the sign of a value, apply a unary minus operation. For * matrices, the function is evaluated element wise. Boolean values and * strings will be converted to a number. For complex numbers, both real * and complex value are inverted. * @param x Number to be inverted * @returns Retursn the value with inverted sign */ unaryMinus(x: number): number; unaryMinus(x: BigNumber): BigNumber; unaryMinus(x: Fraction): Fraction; unaryMinus(x: Complex): Complex; unaryMinus(x: MathArray): MathArray; unaryMinus(x: Matrix): Matrix; unaryMinus(x: Unit): Unit; /** * Unary plus operation. Boolean values and strings will be converted to * a number, numeric values will be returned as is. For matrices, the * function is evaluated element wise. * @param x Input value * @returns Returns the input value when numeric, converts to a number * when input is non-numeric. */ unaryPlus(x: number): number; unaryPlus(x: BigNumber): BigNumber; unaryPlus(x: Fraction): Fraction; unaryPlus(x: string): string; unaryPlus(x: Complex): Complex; unaryPlus(x: MathArray): MathArray; unaryPlus(x: Matrix): Matrix; unaryPlus(x: Unit): Unit; /** * Calculate the extended greatest common divisor for two values. See * http://en.wikipedia.org/wiki/Extended_Euclidean_algorithm. * @param a An integer number * @param b An integer number * @returns Returns an array containing 3 integers [div, m, n] where div * = gcd(a, b) and a*m + b*n = div */ xgcd(a: number | BigNumber, b: number | BigNumber): MathArray; /************************************************************************* * Bitwise functions ************************************************************************/ /** * Bitwise AND two values, x & y. For matrices, the function is * evaluated element wise. * @param x First value to and * @param y Second value to and * @returns AND of x and y */ bitAnd(x: T, y: number | BigNumber | MathArray | Matrix): NoLiteralType; /** * Bitwise NOT value, ~x. For matrices, the function is evaluated * element wise. For units, the function is evaluated on the best prefix * base. * @param x Value to not * @returns NOT of x */ bitNot(x: number): number; bitNot(x: BigNumber): BigNumber; bitNot(x: MathArray): MathArray; bitNot(x: Matrix): Matrix; /** * Bitwise OR two values, x | y. For matrices, the function is evaluated * element wise. For units, the function is evaluated on the lowest * print base. * @param x First value to or * @param y Second value to or * @returns OR of x and y */ bitOr(x: number, y: number): number; bitOr(x: BigNumber, y: BigNumber): BigNumber; bitOr(x: MathArray, y: MathArray): MathArray; bitOr(x: Matrix, y: Matrix): Matrix; /** * Bitwise XOR two values, x ^ y. For matrices, the function is * evaluated element wise. * @param x First value to xor * @param y Second value to xor * @returns XOR of x and y */ bitXor(x: T, y: number | BigNumber | MathArray | Matrix): NoLiteralType; /** * Bitwise left logical shift of a value x by y number of bits, x << y. * For matrices, the function is evaluated element wise. For units, the * function is evaluated on the best prefix base. * @param x Value to be shifted * @param y Amount of shifts * @returns x shifted left y times */ leftShift(x: T, y: number | BigNumber): NoLiteralType; /** * Bitwise right arithmetic shift of a value x by y number of bits, x >> * y. For matrices, the function is evaluated element wise. For units, * the function is evaluated on the best prefix base. * @param x Value to be shifted * @param y Amount of shifts * @returns x sign-filled shifted right y times */ rightArithShift(x: T, y: number | BigNumber): NoLiteralType; /** * Bitwise right logical shift of value x by y number of bits, x >>> y. * For matrices, the function is evaluated element wise. For units, the * function is evaluated on the best prefix base. * @param x Value to be shifted * @param y Amount of shifts * @returns x zero-filled shifted right y times */ rightLogShift(x: T, y: number): NoLiteralType; /************************************************************************* * Combinatorics functions ************************************************************************/ /** * The Bell Numbers count the number of partitions of a set. A partition * is a pairwise disjoint subset of S whose union is S. bellNumbers only * takes integer arguments. The following condition must be enforced: n * >= 0 * @param n Total number of objects in the set * @returns B(n) */ bellNumbers(n: number): number; bellNumbers(n: BigNumber): BigNumber; /** * The Catalan Numbers enumerate combinatorial structures of many * different types. catalan only takes integer arguments. The following * condition must be enforced: n >= 0 * @param n nth Catalan number * @returns Cn(n) */ catalan(n: number): number; catalan(n: BigNumber): BigNumber; /** * The composition counts of n into k parts. Composition only takes * integer arguments. The following condition must be enforced: k <= n. * @param n Total number of objects in the set * @param k Number of objects in the subset * @returns Returns the composition counts of n into k parts. */ composition(n: T, k: number | BigNumber): NoLiteralType; /** * The Stirling numbers of the second kind, counts the number of ways to * partition a set of n labelled objects into k nonempty unlabelled * subsets. stirlingS2 only takes integer arguments. The following * condition must be enforced: k <= n. If n = k or k = 1, then s(n,k) = * 1 * @param n Total number of objects in the set * @param k Number of objects in the subset * @returns S(n,k) */ stirlingS2(n: T, k: number | BigNumber): NoLiteralType; /************************************************************************* * Complex functions ************************************************************************/ /** * Compute the argument of a complex value. For a complex number a + bi, * the argument is computed as atan2(b, a). For matrices, the function * is evaluated element wise. * @param x A complex number or array with complex numbers * @returns The argument of x */ arg(x: number | Complex): number; arg(x: BigNumber | Complex): BigNumber; arg(x: MathArray): MathArray; arg(x: Matrix): Matrix; /** * Compute the complex conjugate of a complex value. If x = a+bi, the * complex conjugate of x is a - bi. For matrices, the function is * evaluated element wise. * @param x A complex number or array with complex numbers * @returns The complex conjugate of x */ conj(x: T): NoLiteralType; /** * Get the imaginary part of a complex number. For a complex number a + * bi, the function returns b. For matrices, the function is evaluated * element wise. * @param x A complex number or array with complex numbers * @returns The imaginary part of x */ im(x: number | BigNumber | Complex | MathArray | Matrix): number | BigNumber | MathArray | Matrix; /** * Get the real part of a complex number. For a complex number a + bi, * the function returns a. For matrices, the function is evaluated * element wise. * @param x A complex number or array of complex numbers * @returns The real part of x */ re(x: number | BigNumber | Complex | MathArray | Matrix): number | BigNumber | MathArray | Matrix; /************************************************************************* * Geometry functions ************************************************************************/ /** * Calculates: The eucledian distance between two points in 2 and 3 * dimensional spaces. Distance between point and a line in 2 and 3 * dimensional spaces. Pairwise distance between a set of 2D or 3D * points NOTE: When substituting coefficients of a line(a, b and c), * use ax + by + c = 0 instead of ax + by = c For parametric equation of * a 3D line, x0, y0, z0, a, b, c are from: (x−x0, y−y0, z−z0) = t(a, b, * c) * @param x Coordinates of the first point * @param y Coordinates of the second point * @returns Returns the distance from two/three points */ distance(x: MathArray | Matrix | object, y: MathArray | Matrix | object): number | BigNumber; /** * Calculates the point of intersection of two lines in two or three * dimensions and of a line and a plane in three dimensions. The inputs * are in the form of arrays or 1 dimensional matrices. The line * intersection functions return null if the lines do not meet. Note: * Fill the plane coefficients as x + y + z = c and not as x + y + z + c * = 0. * @param w Co-ordinates of first end-point of first line * @param x Co-ordinates of second end-point of first line * @param y Co-ordinates of first end-point of second line OR * Coefficients of the plane's equation * @param z Co-ordinates of second end-point of second line OR null if * the calculation is for line and plane * @returns Returns the point of intersection of lines/lines-planes */ intersect(w: MathArray | Matrix, x: MathArray | Matrix, y: MathArray | Matrix, z: MathArray | Matrix): MathArray; /************************************************************************* * Logical functions ************************************************************************/ /** * Logical and. Test whether two values are both defined with a * nonzero/nonempty value. For matrices, the function is evaluated * element wise. * @param x First value to and * @param y Second value to and * @returns Returns true when both inputs are defined with a * nonzero/nonempty value. */ and( x: number | BigNumber | Complex | Unit | MathArray | Matrix, y: number | BigNumber | Complex | Unit | MathArray | Matrix ): boolean | MathArray | Matrix; /** * Logical not. Flips boolean value of a given parameter. For matrices, * the function is evaluated element wise. * @param x First value to not * @returns Returns true when input is a zero or empty value. */ not(x: number | BigNumber | Complex | Unit | MathArray | Matrix): boolean | MathArray | Matrix; /** * Logical or. Test if at least one value is defined with a * nonzero/nonempty value. For matrices, the function is evaluated * element wise. * @param x First value to or * @param y Second value to or * @returns Returns true when one of the inputs is defined with a * nonzero/nonempty value. */ or( x: number | BigNumber | Complex | Unit | MathArray | Matrix, y: number | BigNumber | Complex | Unit | MathArray | Matrix ): boolean | MathArray | Matrix; /** * Logical xor. Test whether one and only one value is defined with a * nonzero/nonempty value. For matrices, the function is evaluated * element wise. * @param x First value to xor * @param y Second value to xor * @returns Returns true when one and only one input is defined with a * nonzero/nonempty value. */ xor( x: number | BigNumber | Complex | Unit | MathArray | Matrix, y: number | BigNumber | Complex | Unit | MathArray | Matrix ): boolean | MathArray | Matrix; /************************************************************************* * Matrix functions ************************************************************************/ /** * Apply a function that maps an array to a scalar along a given axis of a * matrix or array. Returns a new matrix or array with one less dimension * than the input. * @param array The input Matrix * @param dim The dimension along which the callback is applied * @param callback The callback function that is applied. This Function should take an * array or 1-d matrix as an input and return a number. * @returns The residual matrix with the function applied over some dimension. */ apply(array: T, dim: number, callback: (array: MathArray | Matrix) => number): T /** * Concatenate two or more matrices. dim: number is a zero-based * dimension over which to concatenate the matrices. By default the last * dimension of the matrices. * @param args Two or more matrices * @returns Concatenated matrix */ concat(...args: Array): MathArray | Matrix; /** * Calculate the cross product for two vectors in three dimensional * space. The cross product of A = [a1, a2, a3] and B =[b1, b2, b3] is * defined as: cross(A, B) = [ a2 * b3 - a3 * b2, a3 * b1 - a1 * b3, a1 * * b2 - a2 * b1 ] * @param x First vector * @param y Second vector * @returns Returns the cross product of x and y */ cross(x: MathArray | Matrix, y: MathArray | Matrix): Matrix | MathArray; /** * Calculate the determinant of a matrix. * @param x A Matrix * @returns the determinant of x */ det(x: MathArray | Matrix): number; /** * Create a diagonal matrix or retrieve the diagonal of a matrix. When x * is a vector, a matrix with vector x on the diagonal will be returned. * When x is a two dimensional matrix, the matrixes kth diagonal will be * returned as vector. When k is positive, the values are placed on the * super diagonal. When k is negative, the values are placed on the sub * diagonal. * @param X A two dimensional matrix or a vector * @param k The diagonal where the vector will be filled in or * retrieved. Default value: 0. * @param format The matrix storage format. Default value: 'dense'. * @returns Diagonal matrix from input vector, or diagonal from input * matrix */ diag(X: MathArray | Matrix, format?: string): Matrix; diag(X: MathArray | Matrix, k: number | BigNumber, format?: string): Matrix | MathArray; /** * Calculate the dot product of two vectors. The dot product of A = [a1, * a2, a3, ..., an] and B = [b1, b2, b3, ..., bn] is defined as: dot(A, * B) = a1 * b1 + a2 * b2 + a3 * b3 + ... + an * bn * @param x First vector * @param y Second vector * @returns Returns the dot product of x and y */ dot(x: MathArray | Matrix, y: MathArray | Matrix): number; /** * Compute eigenvalues and eigenvectors of a matrix. * The eigenvalues are sorted by their absolute value, ascending. * An eigenvalue with multiplicity k will be listed k times. * The eigenvectors are returned as columns of a matrix – the eigenvector * that belongs to the j-th eigenvalue in the list (eg. values[j]) is the * j-th column (eg. column(vectors, j)). If the algorithm fails to converge, * it will throw an error – in that case, however, you may still find useful * information in err.values and err.vectors * @param x Matrix to be diagonalized * @param prec Precision, default value: 1e-15 * @returns Object containing an array of eigenvalues and a matrix with eigenvectors as columns. */ eigs(x: MathArray | Matrix, prec?:number|BigNumber): {values: MathArray | Matrix, vectors: MathArray | Matrix} /** * Compute the matrix exponential, expm(A) = e^A. The matrix must be * square. Not to be confused with exp(a), which performs element-wise * exponentiation. The exponential is calculated using the Padé * approximant with scaling and squaring; see “Nineteen Dubious Ways to * Compute the Exponential of a Matrix,” by Moler and Van Loan. * @param x A square matrix * @returns The exponential of x */ expm(x: Matrix): Matrix; /** * Create a 2-dimensional identity matrix with size m x n or n x n. The * matrix has ones on the diagonal and zeros elsewhere. * @param size The size for the matrix * @param format The Matrix storage format * @returns A matrix with ones on the diagonal */ identity(size: number | number[] | Matrix | MathArray, format?: string): Matrix | MathArray | number; /** * @param m The x dimension for the matrix * @param n The y dimension for the matrix * @param format The Matrix storage format * @returns A matrix with ones on the diagonal */ identity(m: number, n: number, format?: string): Matrix | MathArray | number; /** * Filter the items in an array or one dimensional matrix. * @param x A one dimensional matrix or array to filter * @param test A function or regular expression to test items. All * entries for which test returns true are returned. When test is a * function, it is invoked with three parameters: the value of the * element, the index of the element, and the matrix/array being * traversed. The function must return a boolean. */ filter( x: Matrix | MathArray | string[], test: ((value: any, index: any, matrix: Matrix | MathArray | string[]) => boolean) | RegExp ): Matrix | MathArray; /** * Flatten a multi dimensional matrix into a single dimensional matrix. * @param x Matrix to be flattened * @returns Returns the flattened matrix */ flatten(x: T): T; /** * Iterate over all elements of a matrix/array, and executes the given * callback function. * @param x The matrix to iterate on. * @param callback The callback function is invoked with three * parameters: the value of the element, the index of the element, and * the Matrix/array being traversed. */ forEach(x: T, callback: (value: any, index: any, matrix: T) => void): void; /** * Calculate the inverse of a square matrix. * @param x Matrix to be inversed * @returns The inverse of x */ inv(x: T): NoLiteralType; /** * Calculate the kronecker product of two matrices or vectors * @param x First vector * @param y Second vector * @returns Returns the kronecker product of x and y */ kron(x: Matrix | MathArray, y: Matrix | MathArray): Matrix; /** * Iterate over all elements of a matrix/array, and executes the given * callback function. * @param x The matrix to iterate on. * @param callback The callback function is invoked with three * parameters: the value of the element, the index of the element, and * the Matrix/array being traversed. * @returns Transformed map of x */ map(x: T, callback: (value: any, index: any, matrix: T) => MathType | string): T; /** * Create a matrix filled with ones. The created matrix can have one or * multiple dimensions. * @param size The size of each dimension of the matrix * @param format The matrix storage format * @returns A matrix filled with ones */ ones(size: number | number[], format?: string): MathArray | Matrix; /** * @param m The x dimension of the matrix * @param n The y dimension of the amtrix * @param format The matrix storage format * @returns A matrix filled with ones */ ones(m: number, n: number, format?: string): MathArray | Matrix; /** * Partition-based selection of an array or 1D matrix. Will find the kth * smallest value, and mutates the input array. Uses Quickselect. * @param x A one dimensional matrix or array to sort * @param k The kth smallest value to be retrieved; zero-based index * @param compare An optional comparator function. The function is * called as compare(a, b), and must return 1 when a > b, -1 when a < b, * and 0 when a == b. Default value: 'asc'. * @returns Returns the kth lowest value. */ partitionSelect(x: MathArray | Matrix, k: number, compare?: 'asc' | 'desc' | ((a: any, b: any) => number)): any; /** * Create an array from a range. By default, the range end is excluded. * This can be customized by providing an extra parameter includeEnd. * @param str A string 'start:end' or 'start:step:end' * @param start Start of the range * @param end End of the range, excluded by default, included when * parameter includeEnd=true * @param step Step size. Default value is 1. * @param includeEnd: Option to specify whether to include the end or * not. False by default * @returns Parameters describing the ranges start, end, and optional * step. */ range(str: string, includeEnd?: boolean): Matrix; range(start: number | BigNumber, end: number | BigNumber, includeEnd?: boolean): Matrix; range(start: number | BigNumber, end: number | BigNumber, step: number | BigNumber, includeEnd?: boolean): Matrix; /** * Reshape a multi dimensional array to fit the specified dimensions * @param x Matrix to be reshaped * @param sizes One dimensional array with integral sizes for each * dimension * @returns A reshaped clone of matrix x */ reshape(x: T, sizes: number[]): T; /** * Resize a matrix * @param x Matrix to be resized * @param size One dimensional array with numbers * @param defaultValue Zero by default, except in case of a string, in * that case defaultValue = ' ' Default value: 0. * @returns A resized clone of matrix x */ resize(x: T, size: MathArray | Matrix, defaultValue?: number | string): T; /** * Return a row from a Matrix. * @param value An array or matrix * @param row The index of the row * @returns The retrieved row */ row( value: T, row: number ): T; /** * Return a column from a Matrix. * @param value An array or matrix * @param column The index of the column * @returns The retrieved column */ column( value: T, column: number ): T; /** * Calculate the size of a matrix or scalar. * @param A matrix * @returns A vector with the size of x */ size(x: boolean | number | Complex | Unit | string | MathArray | Matrix): MathArray | Matrix; /** * Sort the items in a matrix * @param x A one dimensional matrix or array to sort * @param compare An optional _comparator function or name. The function * is called as compare(a, b), and must return 1 when a > b, -1 when a < * b, and 0 when a == b. Default value: ‘asc’ * @returns Returns the sorted matrix */ sort(x: T, compare: ((a: any, b: any) => number) | 'asc' | 'desc' | 'natural'): T; /** * Calculate the principal square root of a square matrix. The principal * square root matrix X of another matrix A is such that X * X = A. * @param A The square matrix A * @returns The principal square root of matrix A */ sqrtm(A: T): T; /** * Squeeze a matrix, remove inner and outer singleton dimensions from a * matrix. * @param x Matrix to be squeezed * @returns Squeezed matrix */ squeeze(x: T): T; /** * Get or set a subset of a matrix or string. * @param value An array, matrix, or string * @param index An index containing ranges for each dimension * @param replacement An array, matrix, or scalar. If provided, the * subset is replaced with replacement. If not provided, the subset is * returned * @param defaultValue Default value, filled in on new entries when the * matrix is resized. If not provided, math.matrix elements will be left * undefined. Default value: undefined. * @returns Either the retrieved subset or the updated matrix */ subset(value: T, index: Index, replacement?: any, defaultValue?: any): T; /** * Calculate the trace of a matrix: the sum of the elements on the main * diagonal of a square matrix. * @param x A matrix * @returns The trace of x */ trace(x: MathArray | Matrix): number; /** * Transpose a matrix. All values of the matrix are reflected over its * main diagonal. Only two dimensional matrices are supported. * @param x Matrix to be transposed * @returns The transposed matrix */ transpose(x: T): T; /** * Create a matrix filled with zeros. The created matrix can have one or * multiple dimensions. * @param size The size of each dimension of the matrix * @param format The matrix storage format * @returns A matrix filled with zeros */ zeros(size: number | number[], format?: string): MathArray | Matrix; /** * @param m The x dimension of the matrix * @param n The y dimension of the matrix * @param format The matrix storage format * @returns A matrix filled with zeros */ zeros(m: number, n: number, format?: string): MathArray | Matrix; /************************************************************************* * Probability functions ************************************************************************/ /** * Compute the number of ways of picking k unordered outcomes from n * possibilities. Combinations only takes integer arguments. The * following condition must be enforced: k <= n. * @param n Total number of objects in the set * @param k Number of objects in the subset * @returns Number of possible combinations */ combinations(n: T, k: number | BigNumber): NoLiteralType; /** * Compute the factorial of a value Factorial only supports an integer * value as argument. For matrices, the function is evaluated element * wise. * @param n An integer number * @returns The factorial of n */ factorial(n: T): NoLiteralType; /** * Compute the gamma function of a value using Lanczos approximation for * small values, and an extended Stirling approximation for large * values. For matrices, the function is evaluated element wise. * @param n A real or complex number * @returns The gamma of n */ gamma(n: number | MathArray | Matrix): number | MathArray | Matrix; /** * Calculate the Kullback-Leibler (KL) divergence between two * distributions * @param q First vector * @param p Second vector * @returns Returns disance between q and p */ kldivergence(q: MathArray | Matrix, p: MathArray | Matrix): number; /** * Multinomial Coefficients compute the number of ways of picking a1, * a2, ..., ai unordered outcomes from n possibilities. multinomial * takes one array of integers as an argument. The following condition * must be enforced: every ai <= 0 * @param a Integer number of objects in the subset * @returns multinomial coefficent */ multinomial(a: T[]): NoLiteralType; /** * Compute the number of ways of obtaining an ordered subset of k * elements from a set of n elements. Permutations only takes integer * arguments. The following condition must be enforced: k <= n. * @param n The number of objects in total * @param k The number of objects in the subset * @returns The number of permutations */ permutations(n: T, k?: number | BigNumber): NoLiteralType; /** * Random pick a value from a one dimensional array. Array element is * picked using a random function with uniform distribution. * @param array A one dimensional array * @param number An int or float * @param weights An array of ints or floats * @returns Returns a single random value from array when number is 1 or * undefined. Returns an array with the configured number of elements * when number is > 1. */ pickRandom(array: number[], number?: number, weights?: number[]): number | number[]; /** * Return a random number larger or equal to min and smaller than max * using a uniform distribution. * @param size If provided, an array or matrix with given size and * filled with random values is returned * @param min Minimum boundary for the random value, included * @param max Maximum boundary for the random value, excluded * @returns A random number */ random(min?: number, max?: number): number; random(size: T, min?: number, max?: number): T; /** * Return a random integer number larger or equal to min and smaller * than max using a uniform distribution. * @param size If provided, an array or matrix with given size and * filled with random values is returned * @param min Minimum boundary for the random value, included * @param max Maximum boundary for the random value, excluded * @returns A random number */ randomInt(min: number, max?: number): number; randomInt(size: T, min?: number, max?: number): T; /************************************************************************* * Relational functions ************************************************************************/ /** * Compare two values. Returns 1 when x > y, -1 when x < y, and 0 when x * == y. x and y are considered equal when the relative difference * between x and y is smaller than the configured epsilon. The function * cannot be used to compare values smaller than approximately 2.22e-16. * For matrices, the function is evaluated element wise. * @param x First value to compare * @param y Second value to compare * @returns Returns the result of the comparison: 1 when x > y, -1 when * x < y, and 0 when x == y. */ compare(x: MathType | string, y: MathType | string): number | BigNumber | Fraction | MathArray | Matrix; /** * Compare two values of any type in a deterministic, natural way. For * numeric values, the function works the same as math.compare. For * types of values that can’t be compared mathematically, the function * compares in a natural way. * @param x First value to compare * @param y Second value to compare * @returns Returns the result of the comparison: 1 when x > y, -1 when * x < y, and 0 when x == y. */ compareNatural(x: any, y: any): number; /** * Compare two strings lexically. Comparison is case sensitive. Returns * 1 when x > y, -1 when x < y, and 0 when x == y. For matrices, the * function is evaluated element wise. * @param x First string to compare * @param y Second string to compare * @returns Returns the result of the comparison: 1 when x > y, -1 when * x < y, and 0 when x == y. */ compareText(x: string | MathArray | Matrix, y: string | MathArray | Matrix): number | MathArray | Matrix; /** * Test element wise whether two matrices are equal. The function * accepts both matrices and scalar values. * @param x First matrix to compare * @param y Second amtrix to compare * @returns Returns true when the input matrices have the same size and * each of their elements is equal. */ deepEqual(x: MathType, y: MathType): number | BigNumber | Fraction | Complex | Unit | MathArray | Matrix; /** * Test whether two values are equal. * * The function tests whether the relative difference between x and y is * smaller than the configured epsilon. The function cannot be used to * compare values smaller than approximately 2.22e-16. For matrices, the * function is evaluated element wise. In case of complex numbers, x.re * must equal y.re, and x.im must equal y.im. Values null and undefined * are compared strictly, thus null is only equal to null and nothing * else, and undefined is only equal to undefined and nothing else. * @param x First value to compare * @param y Second value to compare * @returns Returns true when the compared values are equal, else * returns false */ equal(x: MathType | string, y: MathType | string): boolean | MathArray | Matrix; /** * Check equality of two strings. Comparison is case sensitive. For * matrices, the function is evaluated element wise. * @param x First string to compare * @param y Second string to compare * @returns Returns true if the values are equal, and false if not. */ equalText(x: string | MathArray | Matrix, y: string | MathArray | Matrix): number | MathArray | Matrix; /** * Test whether value x is larger than y. The function returns true when * x is larger than y and the relative difference between x and y is * larger than the configured epsilon. The function cannot be used to * compare values smaller than approximately 2.22e-16. For matrices, the * function is evaluated element wise. * @param x First value to compare * @param y Second value to vcompare * @returns Returns true when x is larger than y, else returns false */ larger(x: MathType | string, y: MathType | string): boolean | MathArray | Matrix; /** * Test whether value x is larger or equal to y. The function returns * true when x is larger than y or the relative difference between x and * y is smaller than the configured epsilon. The function cannot be used * to compare values smaller than approximately 2.22e-16. For matrices, * the function is evaluated element wise. * @param x First value to compare * @param y Second value to vcompare * @returns Returns true when x is larger than or equal to y, else * returns false */ largerEq(x: MathType | string, y: MathType | string): boolean | MathArray | Matrix; /** * Test whether value x is smaller than y. The function returns true * when x is smaller than y and the relative difference between x and y * is smaller than the configured epsilon. The function cannot be used * to compare values smaller than approximately 2.22e-16. For matrices, * the function is evaluated element wise. * @param x First value to compare * @param y Second value to vcompare * @returns Returns true when x is smaller than y, else returns false */ smaller(x: MathType | string, y: MathType | string): boolean | MathArray | Matrix; /** * Test whether value x is smaller or equal to y. The function returns * true when x is smaller than y or the relative difference between x * and y is smaller than the configured epsilon. The function cannot be * used to compare values smaller than approximately 2.22e-16. For * matrices, the function is evaluated element wise. * @param x First value to compare * @param y Second value to vcompare * @returns Returns true when x is smaller than or equal to y, else * returns false */ smallerEq(x: MathType | string, y: MathType | string): boolean | MathArray | Matrix; /** * Test whether two values are unequal. The function tests whether the * relative difference between x and y is larger than the configured * epsilon. The function cannot be used to compare values smaller than * approximately 2.22e-16. For matrices, the function is evaluated * element wise. In case of complex numbers, x.re must unequal y.re, or * x.im must unequal y.im. Values null and undefined are compared * strictly, thus null is unequal with everything except null, and * undefined is unequal with everything except undefined. * @param x First value to compare * @param y Second value to vcompare * @returns Returns true when the compared values are unequal, else * returns false */ unequal(x: MathType | string, y: MathType | string): boolean | MathArray | Matrix; /************************************************************************* * Set functions ************************************************************************/ /** * Create the cartesian product of two (multi)sets. Multi-dimension * arrays will be converted to single-dimension arrays and the values * will be sorted in ascending order before the operation. * @param a1 A (multi)set * @param a2 A (multi)set * @returns The cartesian product of two (multi)sets */ setCartesian(a1: T, a2: MathArray | Matrix): T; /** * Create the difference of two (multi)sets: every element of set1, that * is not the element of set2. Multi-dimension arrays will be converted * to single-dimension arrays before the operation * @param a1 A (multi)set * @param a2 A (multi)set * @returns The difference of two (multi)sets */ setDifference(a1: T, a2: MathArray | Matrix): T; /** * Collect the distinct elements of a multiset. A multi-dimension array * will be converted to a single-dimension array before the operation. * @param a A multiset * @returns A set containing the distinct elements of the multiset */ setDistinct(a: T): T; /** * Create the intersection of two (multi)sets. Multi-dimension arrays * will be converted to single-dimension arrays before the operation. * @param a1 A (multi)set * @param a2 A (multi)set * @returns The intersection of two (multi)sets */ setIntersect(a1: T, a2: MathArray | Matrix): T; /** * Check whether a (multi)set is a subset of another (multi)set. (Every * element of set1 is the element of set2.) Multi-dimension arrays will * be converted to single-dimension arrays before the operation. * @param a1 A (multi)set * @param a2 A (multi)set * @returns True if a1 is subset of a2, else false */ setIsSubset(a1: MathArray | Matrix, a2: MathArray | Matrix): boolean; /** * Count the multiplicity of an element in a multiset. A multi-dimension * array will be converted to a single-dimension array before the * operation. * @param e An element in the multiset * @param a A multiset * @returns The number of how many times the multiset contains the * element */ setMultiplicity(e: number | BigNumber | Fraction | Complex, a: MathArray | Matrix): number; /** * Create the powerset of a (multi)set. (The powerset contains very * possible subsets of a (multi)set.) A multi-dimension array will be * converted to a single-dimension array before the operation. * @param a A multiset * @returns The powerset of the (multi)set */ setPowerset(a: T): T; /** * Count the number of elements of a (multi)set. When a second parameter * is ‘true’, count only the unique values. A multi-dimension array will * be converted to a single-dimension array before the operation. * @param a A multiset * @returns The number of elements of the (multi)set */ setSize(a: MathArray | Matrix): number; /** * Create the symmetric difference of two (multi)sets. Multi-dimension * arrays will be converted to single-dimension arrays before the * operation. * @param a1 A (multi)set * @param a2 A (multi)set * @returns The symmetric difference of two (multi)sets */ setSymDifference(a1: T, a2: MathArray | Matrix): T; /** * Create the union of two (multi)sets. Multi-dimension arrays will be * converted to single-dimension arrays before the operation. * @param a1 A (multi)set * @param a2 A (multi)set * @returns The union of two (multi)sets */ setUnion(a1: T, a2: MathArray | Matrix): T; /************************************************************************* * Special functions ************************************************************************/ /** * Compute the erf function of a value using a rational Chebyshev * approximations for different intervals of x. * @param x A real number * @returns The erf of x */ erf(x: T): NoLiteralType; /************************************************************************* * Statistics functions ************************************************************************/ /** * Compute the median absolute deviation of a matrix or a list with * values. The median absolute deviation is defined as the median of the * absolute deviations from the median. * @param array A single matrix or multiple scalar values. * @returns The median absolute deviation */ mad(array: MathArray | Matrix): any; /** * Compute the maximum value of a matrix or a list with values. In case * of a multi dimensional array, the maximum of the flattened array will * be calculated. When dim is provided, the maximum over the selected * dimension will be calculated. Parameter dim is zero-based. * @param args A single matrix or multiple scalar values * @returns The maximum value */ max(...args: MathType[]): any; /** * @param A A single matrix * @param dim The maximum over the selected dimension * @returns The maximum value */ max(A: MathArray | Matrix, dim?: number): any; /** * Compute the mean value of matrix or a list with values. In case of a * multi dimensional array, the mean of the flattened array will be * calculated. When dim is provided, the maximum over the selected * dimension will be calculated. Parameter dim is zero-based. * @param args A single matrix or multiple scalar values * @returns The mean of all values */ mean(...args: MathType[]): any; /** * @param A A single matrix * @param dim The mean over the selected dimension * @returns The mean of all values */ mean(A: MathArray | Matrix, dim?: number): any; /** * Compute the median of a matrix or a list with values. The values are * sorted and the middle value is returned. In case of an even number of * values, the average of the two middle values is returned. Supported * types of values are: Number, BigNumber, Unit In case of a (multi * dimensional) array or matrix, the median of all elements will be * calculated. * @param args A single matrix or or multiple scalar values * @returns The median */ median(...args: MathType[]): any; /** * Compute the maximum value of a matrix or a list of values. In case of * a multi dimensional array, the maximum of the flattened array will be * calculated. When dim is provided, the maximum over the selected * dimension will be calculated. Parameter dim is zero-based. * @param args A single matrix or or multiple scalar values * @returns The minimum value */ min(...args: MathType[]): any; /** * @param A A single matrix * @param dim The minimum over the selected dimension * @returns The minimum value */ min(A: MathArray | Matrix, dim?: number): any; /** * Computes the mode of a set of numbers or a list with values(numbers * or characters). If there are more than one modes, it returns a list * of those values. * @param args A single matrix * @returns The mode of all values */ mode(...args: MathType[]): any; /** * Compute the product of a matrix or a list with values. In case of a * (multi dimensional) array or matrix, the sum of all elements will be * calculated. * @param args A single matrix or multiple scalar values * @returns The product of all values */ prod(...args: MathType[]): any; /** * Compute the prob order quantile of a matrix or a list with values. * The sequence is sorted and the middle value is returned. Supported * types of sequence values are: Number, BigNumber, Unit Supported types * of probability are: Number, BigNumber In case of a (multi * dimensional) array or matrix, the prob order quantile of all elements * will be calculated. * @param A A single matrix or array * @param probOrN prob is the order of the quantile, while N is the * amount of evenly distributed steps of probabilities; only one of * these options can be provided * @param sorted =false is data sorted in ascending order * @returns Quantile(s) */ quantileSeq(A: MathArray | Matrix, prob: number | BigNumber | MathArray, sorted?: boolean): number | BigNumber | Unit | MathArray; /** * Compute the standard deviation of a matrix or a list with values. The * standard deviations is defined as the square root of the variance: * std(A) = sqrt(variance(A)). In case of a (multi dimensional) array or * matrix, the standard deviation over all elements will be calculated. * Optionally, the type of normalization can be specified as second * parameter. The parameter normalization can be one of the following * values: 'unbiased' (default) The sum of squared errors is divided by * (n - 1) 'uncorrected' The sum of squared errors is divided by n * 'biased' The sum of squared errors is divided by (n + 1) * @param array A single matrix or multiple scalar values * @param normalization Determines how to normalize the variance. Choose * ‘unbiased’ (default), ‘uncorrected’, or ‘biased’. Default value: * ‘unbiased’. * @returns The standard deviation */ std(array: MathArray | Matrix, normalization?: 'unbiased' | 'uncorrected' | 'biased' | 'unbiased'): number; /** * Compute the sum of a matrix or a list with values. In case of a * (multi dimensional) array or matrix, the sum of all elements will be * calculated. * @param args A single matrix or multiple scalar values * @returns The sum of all values */ sum(...args: Array): any; /** * @param array A single matrix * @returns The sum of all values */ sum(array: MathArray | Matrix): any; /** * Compute the variance of a matrix or a list with values. In case of a * (multi dimensional) array or matrix, the variance over all elements * will be calculated. Optionally, the type of normalization can be * specified as second parameter. The parameter normalization can be one * of the following values: 'unbiased' (default) The sum of squared * errors is divided by (n - 1) 'uncorrected' The sum of squared errors * is divided by n 'biased' The sum of squared errors is divided by (n + * 1) Note that older browser may not like the variable name var. In * that case, the function can be called as math['var'](...) instead of * math.variance(...). * @param args A single matrix or multiple scalar values * @returns The variance */ variance(...args: Array): any; /** * @param array A single matrix * @param normalization normalization Determines how to normalize the * variance. Choose ‘unbiased’ (default), ‘uncorrected’, or ‘biased’. * Default value: ‘unbiased’. * @returns The variance */ variance(array: MathArray | Matrix, normalization?: 'unbiased' | 'uncorrected' | 'biased' | 'unbiased'): any; /************************************************************************* * String functions ************************************************************************/ /** * Format a value of any type into a string. * @param value The value to be formatted * @param options An object with formatting options. * @param callback A custom formatting function, invoked for all numeric * elements in value, for example all elements of a matrix, or the real * and imaginary parts of a complex number. This callback can be used to * override the built-in numeric notation with any type of formatting. * Function callback is called with value as parameter and must return a * string. * @see http://mathjs.org/docs/reference/functions/format.html * @returns The formatted value */ format(value: any, options?: FormatOptions | number | ((item: any) => string), callback?: (value: any) => string): string; /** * Interpolate values into a string template. * @param template A string containing variable placeholders. * @param values An object containing variables which will be filled in * in the template. * @param precision Number of digits to format numbers. If not provided, * the value will not be rounded. * @param options Formatting options, or the number of digits to format * numbers. See function math.format for a description of all options. * @returns Interpolated string */ print(template: string, values: any, precision?: number, options?: number | object): void; /************************************************************************* * Trigonometry functions ************************************************************************/ /** * Calculate the inverse cosine of a value. For matrices, the function * is evaluated element wise. * @param x Function input * @returns The arc cosine of x */ acos(x: number): number; acos(x: BigNumber): BigNumber; acos(x: Complex): Complex; acos(x: MathArray): MathArray; acos(x: Matrix): Matrix; /** * Calculate the hyperbolic arccos of a value, defined as acosh(x) = * ln(sqrt(x^2 - 1) + x). For matrices, the function is evaluated * element wise. * @param x Function input * @returns The hyperbolic arccosine of x */ acosh(x: number): number; acosh(x: BigNumber): BigNumber; acosh(x: Complex): Complex; acosh(x: MathArray): MathArray; acosh(x: Matrix): Matrix; /** * Calculate the inverse cotangent of a value. For matrices, the * function is evaluated element wise. * @param x Function input * @returns The arc cotangent of x */ acot(x: number): number; acot(x: BigNumber): BigNumber; acot(x: MathArray): MathArray; acot(x: Matrix): Matrix; /** * Calculate the hyperbolic arccotangent of a value, defined as acoth(x) * = (ln((x+1)/x) + ln(x/(x-1))) / 2. For matrices, the function is * evaluated element wise. * @param x Function input * @returns The hyperbolic arccotangent of x */ acoth(x: number): number; acoth(x: BigNumber): BigNumber; acoth(x: MathArray): MathArray; acoth(x: Matrix): Matrix; /** * Calculate the inverse cosecant of a value. For matrices, the function * is evaluated element wise. * @param x Function input * @returns The arc cosecant of x */ acsc(x: number): number; acsc(x: BigNumber): BigNumber; acsc(x: MathArray): MathArray; acsc(x: Matrix): Matrix; /** * Calculate the hyperbolic arccosecant of a value, defined as acsch(x) * = ln(1/x + sqrt(1/x^2 + 1)). For matrices, the function is evaluated * element wise. * @param x Function input * @returns The hyperbolic arccosecant of x */ acsch(x: number): number; acsch(x: BigNumber): BigNumber; acsch(x: MathArray): MathArray; acsch(x: Matrix): Matrix; /** * Calculate the inverse secant of a value. For matrices, the function * is evaluated element wise. * @param x Function input * @returns The arc secant of x */ asec(x: number): number; asec(x: BigNumber): BigNumber; asec(x: MathArray): MathArray; asec(x: Matrix): Matrix; /** * Calculate the hyperbolic arcsecant of a value, defined as asech(x) = * ln(sqrt(1/x^2 - 1) + 1/x). For matrices, the function is evaluated * element wise. * @param x Function input * @returns The hyperbolic arcsecant of x */ asech(x: number): number; asech(x: BigNumber): BigNumber; asech(x: MathArray): MathArray; asech(x: Matrix): Matrix; /** * Calculate the inverse sine of a value. For matrices, the function is * evaluated element wise. * @param x Function input * @returns The arc sine of x */ asin(x: number): number; asin(x: BigNumber): BigNumber; asin(x: Complex): Complex; asin(x: MathArray): MathArray; asin(x: Matrix): Matrix; /** * Calculate the hyperbolic arcsine of a value, defined as asinh(x) = * ln(x + sqrt(x^2 + 1)). For matrices, the function is evaluated * element wise. * @param x Function input * @returns The hyperbolic arcsine of x */ asinh(x: number): number; asinh(x: BigNumber): BigNumber; asinh(x: MathArray): MathArray; asinh(x: Matrix): Matrix; /** * Calculate the inverse tangent of a value. For matrices, the function * is evaluated element wise. * @param x Function input * @returns The arc tangent of x */ atan(x: number): number; atan(x: BigNumber): BigNumber; atan(x: MathArray): MathArray; atan(x: Matrix): Matrix; /** * Calculate the inverse tangent function with two arguments, y/x. By * providing two arguments, the right quadrant of the computed angle can * be determined. For matrices, the function is evaluated element wise. * @param x Function input * @returns Four quadrant inverse tangent */ atan2(y: number, x: number): number; atan2(y: MathArray | Matrix, x: MathArray | Matrix): MathArray | Matrix; /** * Calculate the hyperbolic arctangent of a value, defined as atanh(x) = * ln((1 + x)/(1 - x)) / 2. For matrices, the function is evaluated * element wise. * @param x Function input * @returns The hyperbolic arctangent of x */ atanh(x: number): number; atanh(x: BigNumber): BigNumber; atanh(x: MathArray): MathArray; atanh(x: Matrix): Matrix; /** * Calculate the cosine of a value. For matrices, the function is * evaluated element wise. * @param x Function input * @returns The cosine of x */ cos(x: number | Unit): number; cos(x: BigNumber): BigNumber; cos(x: Complex): Complex; cos(x: MathArray): MathArray; cos(x: Matrix): Matrix; /** * Calculate the hyperbolic cosine of a value, defined as cosh(x) = 1/2 * * (exp(x) + exp(-x)). For matrices, the function is evaluated element * wise. * @param x Function input * @returns The hyperbolic cosine of x */ cosh(x: number | Unit): number; cosh(x: BigNumber): BigNumber; cosh(x: Complex): Complex; cosh(x: MathArray): MathArray; cosh(x: Matrix): Matrix; /** * Calculate the cotangent of a value. cot(x) is defined as 1 / tan(x). * For matrices, the function is evaluated element wise. * @param x Function input * @returns The cotangent of x */ cot(x: number | Unit): number; cot(x: Complex): Complex; cot(x: MathArray): MathArray; cot(x: Matrix): Matrix; /** * Calculate the hyperbolic cotangent of a value, defined as coth(x) = 1 * / tanh(x). For matrices, the function is evaluated element wise. * @param x Function input * @returns The hyperbolic cotangent of x */ coth(x: number | Unit): number; coth(x: Complex): Complex; coth(x: MathArray): MathArray; coth(x: Matrix): Matrix; /** * Calculate the cosecant of a value, defined as csc(x) = 1/sin(x). For * matrices, the function is evaluated element wise. * @param x Function input * @returns The cosecant hof x */ csc(x: number | Unit): number; csc(x: Complex): Complex; csc(x: MathArray): MathArray; csc(x: Matrix): Matrix; /** * Calculate the hyperbolic cosecant of a value, defined as csch(x) = 1 * / sinh(x). For matrices, the function is evaluated element wise. * @param x Function input * @returns The hyperbolic cosecant of x */ csch(x: number | Unit): number; csch(x: Complex): Complex; csch(x: MathArray): MathArray; csch(x: Matrix): Matrix; /** * Calculate the secant of a value, defined as sec(x) = 1/cos(x). For * matrices, the function is evaluated element wise. * @param x Function input * @returns The secant of x */ sec(x: number | Unit): number; sec(x: Complex): Complex; sec(x: MathArray): MathArray; sec(x: Matrix): Matrix; /** * Calculate the hyperbolic secant of a value, defined as sech(x) = 1 / * cosh(x). For matrices, the function is evaluated element wise. * @param x Function input * @returns The hyperbolic secant of x */ sech(x: number | Unit): number; sech(x: Complex): Complex; sech(x: MathArray): MathArray; sech(x: Matrix): Matrix; /** * Calculate the sine of a value. For matrices, the function is * evaluated element wise. * @param x Function input * @returns The sine of x */ sin(x: number | Unit): number; sin(x: BigNumber): BigNumber; sin(x: Complex): Complex; sin(x: MathArray): MathArray; sin(x: Matrix): Matrix; /** * Calculate the hyperbolic sine of a value, defined as sinh(x) = 1/2 * * (exp(x) - exp(-x)). For matrices, the function is evaluated element * wise. * @param x Function input * @returns The hyperbolic sine of x */ sinh(x: number | Unit): number; sinh(x: BigNumber): BigNumber; sinh(x: Complex): Complex; sinh(x: MathArray): MathArray; sinh(x: Matrix): Matrix; /** * Calculate the tangent of a value. tan(x) is equal to sin(x) / cos(x). * For matrices, the function is evaluated element wise. * @param x Function input * @returns The tangent of x */ tan(x: number | Unit): number; tan(x: BigNumber): BigNumber; tan(x: Complex): Complex; tan(x: MathArray): MathArray; tan(x: Matrix): Matrix; /** * Calculate the hyperbolic tangent of a value, defined as tanh(x) = * (exp(2 * x) - 1) / (exp(2 * x) + 1). For matrices, the function is * evaluated element wise. * @param x Function input * @returns The hyperbolic tangent of x */ tanh(x: number | Unit): number; tanh(x: BigNumber): BigNumber; tanh(x: Complex): Complex; tanh(x: MathArray): MathArray; tanh(x: Matrix): Matrix; /************************************************************************* * Unit functions ************************************************************************/ /** * Change the unit of a value. For matrices, the function is evaluated * element wise. * @param x The unit to be converted. * @param unit New unit. Can be a string like "cm" or a unit without * value. * @returns Value with changed, fixed unit */ to(x: Unit | MathArray | Matrix, unit: Unit | string): Unit | MathArray | Matrix; /************************************************************************* * Utils functions ************************************************************************/ /** * Clone an object. * @param x Object to be cloned * @returns A clone of object x */ clone(x: any): any; /** * Test whether a value is an numeric value. In case of a string, * true is returned if the string contains a numeric value. * @param x Value to be tested * @returns Returns true when x is a number, BigNumber, Fraction, Boolean, or a String containing number. * Returns false for other types. * Throws an error in case of unknown types. */ hasNumericValue(x: any ): boolean| boolean[]; /** * Test whether a value is an integer number. The function supports * number, BigNumber, and Fraction. The function is evaluated * element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x contains a numeric, integer value. * Throws an error in case of an unknown data type. */ isInteger(x: number | BigNumber | Fraction | MathArray | Matrix): boolean; /** * Test whether a value is NaN (not a number). The function supports * types number, BigNumber, Fraction, Unit and Complex. The function is * evaluated element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x is NaN. Throws an error in case of an * unknown data type. */ isNaN(x: number | BigNumber | Fraction | MathArray | Matrix | Unit): boolean; /** * Test whether a value is negative: smaller than zero. The function * supports types number, BigNumber, Fraction, and Unit. The function is * evaluated element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x is larger than zero. Throws an error in * case of an unknown data type. */ isNegative(x: number | BigNumber | Fraction | MathArray | Matrix | Unit): boolean; /** * Test whether a value is an numeric value. The function is evaluated * element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x is a number, BigNumber, Fraction, or * boolean. Returns false for other types. Throws an error in case of * unknown types. */ isNumeric(x: any): x is number | BigNumber | Fraction | boolean; /** * Test whether a value is positive: larger than zero. The function * supports types number, BigNumber, Fraction, and Unit. The function is * evaluated element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x is larger than zero. Throws an error in * case of an unknown data type. */ isPositive(x: number | BigNumber | Fraction | MathArray | Matrix | Unit): boolean; /** * Test whether a value is prime: has no divisors other than itself and * one. The function supports type number, bignumber. The function is * evaluated element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x is larger than zero. Throws an error in * case of an unknown data type. */ isPrime(x: number | BigNumber | MathArray | Matrix): boolean; /** * Test whether a value is zero. The function can check for zero for * types number, BigNumber, Fraction, Complex, and Unit. The function is * evaluated element-wise in case of Array or Matrix input. * @param x Value to be tested * @returns Returns true when x is zero. Throws an error in case of an * unknown data type. */ isZero(x: number | BigNumber | Fraction | MathArray | Matrix | Unit | Complex): boolean; /** * Determine the type of a variable. * @param x The variable for which to test the type * @returns Returns the name of the type. Primitive types are lower * case, non-primitive types are upper-camel-case. For example ‘number’, * ‘string’, ‘Array’, ‘Date’. */ typeOf(x: any): string; /** * Import functions from an object or a module * To avoid errors when using one of the imported functions extend module like this: * * @example * // imported_math_functions.ts * declare module 'mathjs' { * interface MathJsStatic { * hello(a: number): number; * } * } * * @param object An object with functions to be imported. * @param options An object with import options. */ import(object: ImportObject | ImportObject[], options: ImportOptions): void; } /************************************************************************* * Factory and Dependencies ************************************************************************/ interface FactoryDependencies { create: (factories: FactoryFunctionMap, config?: ConfigOptions) => MathJsStatic; factory: ( name: string, dependencies: MathJsFunctionName[], create: (injected: Partial) => T, meta?: any ) => FactoryFunction; all: FactoryFunctionMap; typedDependencies: FactoryFunctionMap; ResultSetDependencies: FactoryFunctionMap; BigNumberDependencies: FactoryFunctionMap; ComplexDependencies: FactoryFunctionMap; FractionDependencies: FactoryFunctionMap; RangeDependencies: FactoryFunctionMap; MatrixDependencies: FactoryFunctionMap; DenseMatrixDependencies: FactoryFunctionMap; cloneDependencies: FactoryFunctionMap; isIntegerDependencies: FactoryFunctionMap; isNegativeDependencies: FactoryFunctionMap; isNumericDependencies: FactoryFunctionMap; hasNumericValueDependencies: FactoryFunctionMap; isPositiveDependencies: FactoryFunctionMap; isZeroDependencies: FactoryFunctionMap; isNaNDependencies: FactoryFunctionMap; typeOfDependencies: FactoryFunctionMap; typeofDependencies: FactoryFunctionMap; equalScalarDependencies: FactoryFunctionMap; SparseMatrixDependencies: FactoryFunctionMap; numberDependencies: FactoryFunctionMap; stringDependencies: FactoryFunctionMap; booleanDependencies: FactoryFunctionMap; bignumberDependencies: FactoryFunctionMap; complexDependencies: FactoryFunctionMap; fractionDependencies: FactoryFunctionMap; matrixDependencies: FactoryFunctionMap; splitUnitDependencies: FactoryFunctionMap; unaryMinusDependencies: FactoryFunctionMap; unaryPlusDependencies: FactoryFunctionMap; absDependencies: FactoryFunctionMap; applyDependencies: FactoryFunctionMap; addScalarDependencies: FactoryFunctionMap; cbrtDependencies: FactoryFunctionMap; ceilDependencies: FactoryFunctionMap; cubeDependencies: FactoryFunctionMap; expDependencies: FactoryFunctionMap; expm1Dependencies: FactoryFunctionMap; fixDependencies: FactoryFunctionMap; floorDependencies: FactoryFunctionMap; gcdDependencies: FactoryFunctionMap; lcmDependencies: FactoryFunctionMap; log10Dependencies: FactoryFunctionMap; log2Dependencies: FactoryFunctionMap; modDependencies: FactoryFunctionMap; multiplyScalarDependencies: FactoryFunctionMap; multiplyDependencies: FactoryFunctionMap; nthRootDependencies: FactoryFunctionMap; signDependencies: FactoryFunctionMap; sqrtDependencies: FactoryFunctionMap; squareDependencies: FactoryFunctionMap; subtractDependencies: FactoryFunctionMap; xgcdDependencies: FactoryFunctionMap; dotMultiplyDependencies: FactoryFunctionMap; bitAndDependencies: FactoryFunctionMap; bitNotDependencies: FactoryFunctionMap; bitOrDependencies: FactoryFunctionMap; bitXorDependencies: FactoryFunctionMap; argDependencies: FactoryFunctionMap; conjDependencies: FactoryFunctionMap; imDependencies: FactoryFunctionMap; reDependencies: FactoryFunctionMap; notDependencies: FactoryFunctionMap; orDependencies: FactoryFunctionMap; xorDependencies: FactoryFunctionMap; concatDependencies: FactoryFunctionMap; columnDependencies: FactoryFunctionMap; crossDependencies: FactoryFunctionMap; diagDependencies: FactoryFunctionMap; eyeDependencies: FactoryFunctionMap; filterDependencies: FactoryFunctionMap; flattenDependencies: FactoryFunctionMap; forEachDependencies: FactoryFunctionMap; getMatrixDataTypeDependencies: FactoryFunctionMap; identityDependencies: FactoryFunctionMap; kronDependencies: FactoryFunctionMap; mapDependencies: FactoryFunctionMap; onesDependencies: FactoryFunctionMap; rangeDependencies: FactoryFunctionMap; reshapeDependencies: FactoryFunctionMap; resizeDependencies: FactoryFunctionMap; rowDependencies: FactoryFunctionMap; sizeDependencies: FactoryFunctionMap; squeezeDependencies: FactoryFunctionMap; subsetDependencies: FactoryFunctionMap; transposeDependencies: FactoryFunctionMap; ctransposeDependencies: FactoryFunctionMap; zerosDependencies: FactoryFunctionMap; erfDependencies: FactoryFunctionMap; modeDependencies: FactoryFunctionMap; prodDependencies: FactoryFunctionMap; formatDependencies: FactoryFunctionMap; printDependencies: FactoryFunctionMap; toDependencies: FactoryFunctionMap; isPrimeDependencies: FactoryFunctionMap; numericDependencies: FactoryFunctionMap; divideScalarDependencies: FactoryFunctionMap; powDependencies: FactoryFunctionMap; roundDependencies: FactoryFunctionMap; logDependencies: FactoryFunctionMap; log1pDependencies: FactoryFunctionMap; nthRootsDependencies: FactoryFunctionMap; dotPowDependencies: FactoryFunctionMap; dotDivideDependencies: FactoryFunctionMap; lsolveDependencies: FactoryFunctionMap; usolveDependencies: FactoryFunctionMap; leftShiftDependencies: FactoryFunctionMap; rightArithShiftDependencies: FactoryFunctionMap; rightLogShiftDependencies: FactoryFunctionMap; andDependencies: FactoryFunctionMap; compareDependencies: FactoryFunctionMap; compareNaturalDependencies: FactoryFunctionMap; compareTextDependencies: FactoryFunctionMap; equalDependencies: FactoryFunctionMap; equalTextDependencies: FactoryFunctionMap; smallerDependencies: FactoryFunctionMap; smallerEqDependencies: FactoryFunctionMap; largerDependencies: FactoryFunctionMap; largerEqDependencies: FactoryFunctionMap; deepEqualDependencies: FactoryFunctionMap; unequalDependencies: FactoryFunctionMap; partitionSelectDependencies: FactoryFunctionMap; sortDependencies: FactoryFunctionMap; maxDependencies: FactoryFunctionMap; minDependencies: FactoryFunctionMap; ImmutableDenseMatrixDependencies: FactoryFunctionMap; IndexDependencies: FactoryFunctionMap; FibonacciHeapDependencies: FactoryFunctionMap; SpaDependencies: FactoryFunctionMap; UnitDependencies: FactoryFunctionMap; unitDependencies: FactoryFunctionMap; sparseDependencies: FactoryFunctionMap; createUnitDependencies: FactoryFunctionMap; acosDependencies: FactoryFunctionMap; acoshDependencies: FactoryFunctionMap; acotDependencies: FactoryFunctionMap; acothDependencies: FactoryFunctionMap; acscDependencies: FactoryFunctionMap; acschDependencies: FactoryFunctionMap; asecDependencies: FactoryFunctionMap; asechDependencies: FactoryFunctionMap; asinDependencies: FactoryFunctionMap; asinhDependencies: FactoryFunctionMap; atanDependencies: FactoryFunctionMap; atan2Dependencies: FactoryFunctionMap; atanhDependencies: FactoryFunctionMap; cosDependencies: FactoryFunctionMap; coshDependencies: FactoryFunctionMap; cotDependencies: FactoryFunctionMap; cothDependencies: FactoryFunctionMap; cscDependencies: FactoryFunctionMap; cschDependencies: FactoryFunctionMap; secDependencies: FactoryFunctionMap; sechDependencies: FactoryFunctionMap; sinDependencies: FactoryFunctionMap; sinhDependencies: FactoryFunctionMap; tanDependencies: FactoryFunctionMap; tanhDependencies: FactoryFunctionMap; setCartesianDependencies: FactoryFunctionMap; setDifferenceDependencies: FactoryFunctionMap; setDistinctDependencies: FactoryFunctionMap; setIntersectDependencies: FactoryFunctionMap; setIsSubsetDependencies: FactoryFunctionMap; setMultiplicityDependencies: FactoryFunctionMap; setPowersetDependencies: FactoryFunctionMap; setSizeDependencies: FactoryFunctionMap; setSymDifferenceDependencies: FactoryFunctionMap; setUnionDependencies: FactoryFunctionMap; addDependencies: FactoryFunctionMap; hypotDependencies: FactoryFunctionMap; normDependencies: FactoryFunctionMap; dotDependencies: FactoryFunctionMap; traceDependencies: FactoryFunctionMap; indexDependencies: FactoryFunctionMap; NodeDependencies: FactoryFunctionMap; AccessorNodeDependencies: FactoryFunctionMap; ArrayNodeDependencies: FactoryFunctionMap; AssignmentNodeDependencies: FactoryFunctionMap; BlockNodeDependencies: FactoryFunctionMap; ConditionalNodeDependencies: FactoryFunctionMap; ConstantNodeDependencies: FactoryFunctionMap; FunctionAssignmentNodeDependencies: FactoryFunctionMap; IndexNodeDependencies: FactoryFunctionMap; ObjectNodeDependencies: FactoryFunctionMap; OperatorNodeDependencies: FactoryFunctionMap; ParenthesisNodeDependencies: FactoryFunctionMap; RangeNodeDependencies: FactoryFunctionMap; RelationalNodeDependencies: FactoryFunctionMap; SymbolNodeDependencies: FactoryFunctionMap; FunctionNodeDependencies: FactoryFunctionMap; parseDependencies: FactoryFunctionMap; compileDependencies: FactoryFunctionMap; evaluateDependencies: FactoryFunctionMap; evalDependencies: FactoryFunctionMap; ParserDependencies: FactoryFunctionMap; parserDependencies: FactoryFunctionMap; lupDependencies: FactoryFunctionMap; qrDependencies: FactoryFunctionMap; sluDependencies: FactoryFunctionMap; lusolveDependencies: FactoryFunctionMap; HelpDependencies: FactoryFunctionMap; ChainDependencies: FactoryFunctionMap; helpDependencies: FactoryFunctionMap; chainDependencies: FactoryFunctionMap; detDependencies: FactoryFunctionMap; invDependencies: FactoryFunctionMap; expmDependencies: FactoryFunctionMap; sqrtmDependencies: FactoryFunctionMap; divideDependencies: FactoryFunctionMap; distanceDependencies: FactoryFunctionMap; intersectDependencies: FactoryFunctionMap; sumDependencies: FactoryFunctionMap; meanDependencies: FactoryFunctionMap; medianDependencies: FactoryFunctionMap; madDependencies: FactoryFunctionMap; varianceDependencies: FactoryFunctionMap; varDependencies: FactoryFunctionMap; quantileSeqDependencies: FactoryFunctionMap; stdDependencies: FactoryFunctionMap; combinationsDependencies: FactoryFunctionMap; gammaDependencies: FactoryFunctionMap; factorialDependencies: FactoryFunctionMap; kldivergenceDependencies: FactoryFunctionMap; multinomialDependencies: FactoryFunctionMap; permutationsDependencies: FactoryFunctionMap; pickRandomDependencies: FactoryFunctionMap; randomDependencies: FactoryFunctionMap; randomIntDependencies: FactoryFunctionMap; stirlingS2Dependencies: FactoryFunctionMap; bellNumbersDependencies: FactoryFunctionMap; catalanDependencies: FactoryFunctionMap; compositionDependencies: FactoryFunctionMap; simplifyDependencies: FactoryFunctionMap; derivativeDependencies: FactoryFunctionMap; rationalizeDependencies: FactoryFunctionMap; reviverDependencies: FactoryFunctionMap; eDependencies: FactoryFunctionMap; EDependencies: FactoryFunctionMap; falseDependencies: FactoryFunctionMap; iDependencies: FactoryFunctionMap; InfinityDependencies: FactoryFunctionMap; LN10Dependencies: FactoryFunctionMap; LN2Dependencies: FactoryFunctionMap; LOG10EDependencies: FactoryFunctionMap; LOG2EDependencies: FactoryFunctionMap; NaNDependencies: FactoryFunctionMap; nullDependencies: FactoryFunctionMap; phiDependencies: FactoryFunctionMap; piDependencies: FactoryFunctionMap; PIDependencies: FactoryFunctionMap; SQRT1_2Dependencies: FactoryFunctionMap; SQRT2Dependencies: FactoryFunctionMap; tauDependencies: FactoryFunctionMap; trueDependencies: FactoryFunctionMap; versionDependencies: FactoryFunctionMap; atomicMassDependencies: FactoryFunctionMap; avogadroDependencies: FactoryFunctionMap; bohrMagnetonDependencies: FactoryFunctionMap; bohrRadiusDependencies: FactoryFunctionMap; boltzmannDependencies: FactoryFunctionMap; classicalElectronRadiusDependencies: FactoryFunctionMap; conductanceQuantumDependencies: FactoryFunctionMap; coulombDependencies: FactoryFunctionMap; deuteronMassDependencies: FactoryFunctionMap; efimovFactorDependencies: FactoryFunctionMap; electricConstantDependencies: FactoryFunctionMap; electronMassDependencies: FactoryFunctionMap; elementaryChargeDependencies: FactoryFunctionMap; faradayDependencies: FactoryFunctionMap; fermiCouplingDependencies: FactoryFunctionMap; fineStructureDependencies: FactoryFunctionMap; firstRadiationDependencies: FactoryFunctionMap; gasConstantDependencies: FactoryFunctionMap; gravitationConstantDependencies: FactoryFunctionMap; gravityDependencies: FactoryFunctionMap; hartreeEnergyDependencies: FactoryFunctionMap; inverseConductanceQuantumDependencies: FactoryFunctionMap; klitzingDependencies: FactoryFunctionMap; loschmidtDependencies: FactoryFunctionMap; magneticConstantDependencies: FactoryFunctionMap; magneticFluxQuantumDependencies: FactoryFunctionMap; molarMassDependencies: FactoryFunctionMap; molarMassC12Dependencies: FactoryFunctionMap; molarPlanckConstantDependencies: FactoryFunctionMap; molarVolumeDependencies: FactoryFunctionMap; neutronMassDependencies: FactoryFunctionMap; nuclearMagnetonDependencies: FactoryFunctionMap; planckChargeDependencies: FactoryFunctionMap; planckConstantDependencies: FactoryFunctionMap; planckLengthDependencies: FactoryFunctionMap; planckMassDependencies: FactoryFunctionMap; planckTemperatureDependencies: FactoryFunctionMap; planckTimeDependencies: FactoryFunctionMap; protonMassDependencies: FactoryFunctionMap; quantumOfCirculationDependencies: FactoryFunctionMap; reducedPlanckConstantDependencies: FactoryFunctionMap; rydbergDependencies: FactoryFunctionMap; sackurTetrodeDependencies: FactoryFunctionMap; secondRadiationDependencies: FactoryFunctionMap; speedOfLightDependencies: FactoryFunctionMap; stefanBoltzmannDependencies: FactoryFunctionMap; thomsonCrossSectionDependencies: FactoryFunctionMap; vacuumImpedanceDependencies: FactoryFunctionMap; weakMixingAngleDependencies: FactoryFunctionMap; wienDisplacementDependencies: FactoryFunctionMap; applyTransformDependencies: FactoryFunctionMap; columnTransformDependencies: FactoryFunctionMap; filterTransformDependencies: FactoryFunctionMap; forEachTransformDependencies: FactoryFunctionMap; indexTransformDependencies: FactoryFunctionMap; mapTransformDependencies: FactoryFunctionMap; maxTransformDependencies: FactoryFunctionMap; meanTransformDependencies: FactoryFunctionMap; minTransformDependencies: FactoryFunctionMap; rangeTransformDependencies: FactoryFunctionMap; rowTransformDependencies: FactoryFunctionMap; subsetTransformDependencies: FactoryFunctionMap; concatTransformDependencies: FactoryFunctionMap; stdTransformDependencies: FactoryFunctionMap; sumTransformDependencies: FactoryFunctionMap; varianceTransformDependencies: FactoryFunctionMap; } interface Matrix { type: string; storage(): string; datatype(): string; create(data: MathArray, datatype?: string): void; density(): number; subset(index: Index, replacement?: any, defaultValue?: any): Matrix; apply(dim: number, callback: (array: MathArray | Matrix) => number): Matrix | MathArray; get(index: number[]): any; set(index: number[], value: any, defaultValue?: number | string): Matrix; resize(size: MathArray | Matrix, defaultValue?: number | string): Matrix; clone(): Matrix; size(): number[]; map(callback: (a: any, b: number, c: Matrix) => any, skipZeros?: boolean): Matrix; forEach(callback: (a: any, b: number, c: Matrix) => void, skipZeros?: boolean): void; toArray(): MathArray; valueOf(): MathArray; format(options?: FormatOptions | number | ((value: any) => string)): string; toString(): string; toJSON(): any; diagonal(k?: number | BigNumber): any[]; swapRows(i: number, j: number): Matrix; } interface BigNumber extends Decimal {} // tslint:disable-line no-empty-interface interface Fraction { s: number; n: number; d: number; } interface Complex { re: number; im: number; clone(): Complex; equals(other: Complex): boolean; format(precision?: number): string; fromJSON(json: object): Complex; fromPolar(polar: object): Complex; fromPolar(r: number, phi: number): Complex; toJSON(): object; toPolar(): PolarCoordinates; toString(): string; compare(a: Complex, b: Complex): number; } interface PolarCoordinates { r: number; phi: number; } interface MathJSON { mathjs?: string; value: number; unit: string; fixPrefix?: boolean; } interface Unit { valueOf(): string; clone(): Unit; hasBase(base: any): boolean; equalBase(unit: Unit): boolean; equals(unit: Unit): boolean; multiply(unit: Unit): Unit; divide(unit: Unit): Unit; pow(unit: Unit): Unit; abs(unit: Unit): Unit; to(unit: string): Unit; toNumber(unit?: string): number; toNumeric(unit?: string): number | Fraction | BigNumber; toSI(): Unit; toString(): string; toJSON(): MathJSON; formatUnits(): string; format(options: FormatOptions): string; splitUnit(parts: ReadonlyArray): Unit[]; } interface CreateUnitOptions { prefixes?: 'none' | 'short' | 'long' | 'binary_short' | 'binary_long'; aliases?: string[]; offset?: number; override?: boolean; } interface SimplifyOptions { /** A boolean which is `true` by default. */ exactFractions?: boolean; /** * When `exactFractions` is true, a fraction will be returned only * when both numerator and denominator are smaller than `fractionsLimit`. * Default value is 10000. */ fractionsLimit?: number; } type SimplifyRule = { l: string; r: string } | string | ((node: MathNode) => MathNode); interface Simplify { ( expr: MathNode | string, rules?: SimplifyRule[], scope?: object, options?: SimplifyOptions, ): MathNode; ( expr: MathNode | string, scope?: object, options?: SimplifyOptions, ): MathNode; rules: SimplifyRule[]; simplifyCore(expr: MathNode): MathNode; } interface UnitDefinition { definition?: string | Unit; prefixes?: string; offset?: number; aliases?: string[]; } interface Index {} // tslint:disable-line no-empty-interface interface EvalFunction { evaluate(scope?: any): any; } interface MathNodeCommon { isNode: true; comment: string; type: 'AccessorNode' | 'ArrayNode' | 'AssignmentNode' | 'BlockNode' | 'ConditionalNode' | 'ConstantNode' | 'FunctionAssignmentNode' | 'FunctionNode' | 'IndexNode' | 'ObjectNode' | 'OperatorNode' | 'ParenthesisNode' | 'RangeNode' | 'RelationalNode' | 'SymbolNode'; isUpdateNode?: boolean; /** * Create a shallow clone of the node. The node itself is cloned, its * childs are not cloned. */ clone(): MathNode; /** * Create a deep clone of the node. Both the node as well as all its * childs are cloned recursively. */ cloneDeep(): MathNode; /** * Compile an expression into optimized JavaScript code. compile returns * an object with a function evaluate([scope]) to evaluate. Example: */ compile(): EvalFunction; /** * Compile and eval an expression, this is the equivalent of doing * node.compile().evaluate(scope). Example: */ evaluate(expr?: any): any; /** * Test whether this node equals an other node. Does a deep comparison * of the values of both nodes. */ equals(other: MathNode): boolean; /** * * Filter nodes in an expression tree. The callback function is called * as callback(node: MathNode, path: string, parent: MathNode) : boolean * for every node in the tree, and must return a boolean. The function * filter returns an array with nodes for which the test returned true. * Parameter path is a string containing a relative JSON Path. * * Example: * * ``` * var node = math.parse('x^2 + x/4 + 3*y'); * var filtered = node.filter(function (node) { * return node.isSymbolMathNode && node.name == 'x'; * }); * // returns an array with two entries: two SymbolMathNodes 'x' * ``` * * The callback function is called as callback(node: MathNode, path: * string, parent: MathNode) : boolean for every node in the tree, and * must return a boolean. The function filter returns an array with * nodes for which the test returned true. Parameter path is a string * containing a relative JSON Path. * @return Returns an array with nodes for which test returned true */ filter(callback: (node: MathNode, path: string, parent: MathNode) => any): MathNode[]; /** * [forEach description] */ forEach(callback: (node: MathNode, path: string, parent: MathNode) => any): MathNode[]; /** * Transform a node. Creates a new MathNode having it’s child's be the * results of calling the provided callback function for each of the * child's of the original node. The callback function is called as * `callback(child: MathNode, path: string, parent: MathNode)` and must * return a MathNode. Parameter path is a string containing a relative * JSON Path. * * * See also transform, which is a recursive version of map. */ map(callback: (node: MathNode, path: string, parent: MathNode) => MathNode): MathNode; /** * Get a HTML representation of the parsed expression. */ toHTML(options?: object): string; /** * Get a string representation of the parsed expression. This is not * exactly the same as the original input. */ toString(options?: object): string; /** * Get a LaTeX representation of the expression. */ toTex(options?: object): string; /** * Recursively transform an expression tree via a transform function. * Similar to Array.map, but recursively executed on all nodes in the * expression tree. The callback function is a mapping function * accepting a node, and returning a replacement for the node or the * original node. Function callback is called as callback(node: * MathNode, path: string, parent: MathNode) for every node in the tree, * and must return a MathNode. Parameter path is a string containing a * relative JSON Path. * * For example, to replace all nodes of type SymbolMathNode having name * ‘x’ with a ConstantMathNode with value 3: * ```js * var node = math.parse('x^2 + 5*x'); * var transformed = node.transform(function (node, path, parent) { * if (node.SymbolMathNode && node.name == 'x') { * return new math.expression.node.ConstantMathNode(3); * } * else { * return node; * } * }); * transformed.toString(); // returns '(3 ^ 2) + (5 * 3)' * ``` */ transform(callback: (node: MathNode, path: string, parent: MathNode) => MathNode): MathNode; /** * `traverse(callback)` * * Recursively traverse all nodes in a node tree. Executes given * callback for this node and each of its child nodes. Similar to * Array.forEach, except recursive. The callback function is a mapping * function accepting a node, and returning a replacement for the node * or the original node. Function callback is called as callback(node: * MathNode, path: string, parent: MathNode) for every node in the tree. * Parameter path is a string containing a relative JSON Path. Example: * * ``` * var node = math.parse('3 * x + 2'); * node.traverse(function (node, path, parent) { * switch (node.type) { * case 'OperatorMathNode': console.log(node.type, node.op); break; * case 'ConstantMathNode': console.log(node.type, node.value); break; * case 'SymbolMathNode': console.log(node.type, node.name); break; * default: console.log(node.type); * } * }); * // outputs: * // OperatorMathNode + * // OperatorMathNode * * // ConstantMathNode 3 * // SymbolMathNode x * // ConstantMathNode 2 * ``` */ traverse(callback: (node: MathNode, path: string, parent: MathNode) => void): any; } interface Parser { evaluate(expr: string | string[]): any; get(variable: string): any; getAll(): { [key: string]: any }; set: (variable: string, value: any) => void; clear: () => void; } interface Distribution { random(size: any, min?: any, max?: any): any; randomInt(min: any, max?: any): any; pickRandom(array: any): any; } interface FormatOptions { /** * Number notation. Choose from: 'fixed' Always use regular number * notation. For example '123.40' and '14000000' 'exponential' Always * use exponential notation. For example '1.234e+2' and '1.4e+7' 'auto' * (default) Regular number notation for numbers having an absolute * value between lower and upper bounds, and uses exponential notation * elsewhere. Lower bound is included, upper bound is excluded. For * example '123.4' and '1.4e7'. */ notation?: 'fixed' | 'exponential' | 'engineering' | 'auto'; /** * A number between 0 and 16 to round the digits of the number. In case * of notations 'exponential' and 'auto', precision defines the total * number of significant digits returned and is undefined by default. In * case of notation 'fixed', precision defines the number of significant * digits after the decimal point, and is 0 by default. */ precision?: number; /** * Exponent determining the lower boundary for formatting a value with * an exponent when notation='auto. Default value is -3. */ lowerExp?: number; /** * Exponent determining the upper boundary for formatting a value with * an exponent when notation='auto. Default value is 5. */ upperExp?: number; /** * Available values: 'ratio' (default) or 'decimal'. For example * format(fraction(1, 3)) will output '1/3' when 'ratio' is configured, * and will output 0.(3) when 'decimal' is configured. */ fraction?: string; } interface Help { toString(): string; toJSON(): string; } interface ConfigOptions { epsilon?: number; matrix?: string; number?: string; precision?: number; parenthesis?: string; randomSeed?: string; } interface MathJsJson { /** * Returns reviver function that can be used as reviver in JSON.parse function. */ reviver(): (key: any, value: any) => any; } interface MathJsChain { done(): any; /************************************************************************* * Construction functions ************************************************************************/ /** * Create a BigNumber, which can store numbers with arbitrary precision. * When a matrix is provided, all elements will be converted to * BigNumber. */ bignumber(): MathJsChain; /** * Create a boolean or convert a string or number to a boolean. In case * of a number, true is returned for non-zero numbers, and false in case * of zero. Strings can be 'true' or 'false', or can contain a number. * When value is a matrix, all elements will be converted to boolean. */ boolean(): MathJsChain; /** * Create a complex value or convert a value to a complex value. * @param im Argument specifying the imaginary part of the complex * number */ complex(im?: number): MathJsChain; /** * Create a user-defined unit and register it with the Unit type. * @param definition Definition of the unit in terms of existing units. * For example, ‘0.514444444 m / s’. * @param options (optional) An object containing any of the following * properties:
- prefixes {string} “none”, “short”, “long”, * “binary_short”, or “binary_long”. The default is “none”.
- * aliases {Array} Array of strings. Example: [‘knots’, ‘kt’, * ‘kts’]
- offset {Numeric} An offset to apply when converting from * the unit. For example, the offset for celsius is 273.15. Default is * 0. */ createUnit(definition?: string | UnitDefinition, options?: CreateUnitOptions): MathJsChain; /** * Create a user-defined unit and register it with the Unit type. * @param options (optional) An object containing any of the following * properties:
- prefixes {string} “none”, “short”, “long”, * “binary_short”, or “binary_long”. The default is “none”.
- * aliases {Array} Array of strings. Example: [‘knots’, ‘kt’, * ‘kts’]
- offset {Numeric} An offset to apply when converting from * the unit. For example, the offset for celsius is 273.15. Default is * 0. */ createUnit(options?: CreateUnitOptions): MathJsChain; /** * Create a fraction convert a value to a fraction. * @param denominator Argument specifying the denominator of the * fraction */ fraction(denominator?: number | string | MathArray | Matrix): MathJsChain; /** * Create an index. An Index can store ranges having start, step, and * end for multiple dimensions. Matrix.get, Matrix.set, and math.subset * accept an Index as input. */ index(): MathJsChain; /** * Create a Matrix. The function creates a new math.type.Matrix object * from an Array. A Matrix has utility functions to manipulate the data * in the matrix, like getting the size and getting or setting values in * the matrix. Supported storage formats are 'dense' and 'sparse'. */ matrix(format?: 'sparse' | 'dense', dataType?: string): MathJsChain; /** * Create a number or convert a string, boolean, or unit to a number. * When value is a matrix, all elements will be converted to number. * @param valuelessUnit A valueless unit, used to convert a unit to a * number */ number(valuelessUnit?: Unit | string): MathJsChain; /** * Create a Sparse Matrix. The function creates a new math.type.Matrix * object from an Array. A Matrix has utility functions to manipulate * the data in the matrix, like getting the size and getting or setting * values in the matrix. * @param dataType Sparse Matrix data type */ sparse(dataType?: string): MathJsChain; /** * Split a unit in an array of units whose sum is equal to the original * unit. * @param parts An array of strings or valueless units */ splitUnit(parts: Unit[]): MathJsChain; /** * Create a string or convert any object into a string. Elements of * Arrays and Matrices are processed element wise. */ string(): MathJsChain; /** * Create a unit. Depending on the passed arguments, the function will * create and return a new math.type.Unit object. When a matrix is * provided, all elements will be converted to units. * @param unit The unit to be created */ unit(unit?: string): MathJsChain; /************************************************************************* * Expression functions ************************************************************************/ /** * Parse and compile an expression. Returns a an object with a function * evaluate([scope]) to evaluate the compiled expression. */ compile(): MathJsChain; /** * Evaluate an expression. * @param scope Scope to read/write variables */ evaluate(scope?: object): MathJsChain; /** * Retrieve help on a function or data type. Help files are retrieved * from the documentation in math.expression.docs. */ help(): MathJsChain; /** * Parse an expression. Returns a node tree, which can be evaluated by * invoking node.evaluate(); * @param options Available options: nodes - a set of custome nodes */ parse(options?: any): MathJsChain; /** * @param options Available options: nodes - a set of custome nodes */ parse(options?: any): MathJsChain; /** * Create a parser. The function creates a new math.expression.Parser * object. */ parser(): MathJsChain; /************************************************************************* * Algebra functions ************************************************************************/ /** * @param variable The variable over which to differentiate * @param options There is one option available, simplify, which is true * by default. When false, output will not be simplified. */ derivative(variable: MathNode | string, options?: { simplify: boolean }): MathJsChain; /** * Solves the linear equation system by forwards substitution. Matrix * must be a lower triangular matrix. * @param b A column vector with the b values */ lsolve(b: Matrix | MathArray): MathJsChain; /** * Calculate the Matrix LU decomposition with partial pivoting. Matrix A * is decomposed in two matrices (L, U) and a row permutation vector p * where A[p,:] = L * U */ lup(): MathJsChain; /** * Solves the linear system A * x = b where A is an [n x n] matrix and b * is a [n] column vector. * @param b Column Vector * @param order The Symbolic Ordering and Analysis order, see slu for * details. Matrix must be a SparseMatrix * @param threshold Partial pivoting threshold (1 for partial pivoting), * see slu for details. Matrix must be a SparseMatrix. */ lusolve(b: Matrix | MathArray, order?: number, threshold?: number): MathJsChain; /** * Calculate the Matrix QR decomposition. Matrix A is decomposed in two * matrices (Q, R) where Q is an orthogonal matrix and R is an upper * triangular matrix. */ qr(): MathJsChain; /** * Transform a rationalizable expression in a rational fraction. If * rational fraction is one variable polynomial then converts the * numerator and denominator in canonical form, with decreasing * exponents, returning the coefficients of numerator. * @param optional scope of expression or true for already evaluated * rational expression at input * @param detailed optional True if return an object, false if return * expression node (default) */ rationalize(optional?: object | boolean, detailed?: boolean): MathJsChain; /** * Simplify an expression tree. * @param rules A list of rules are applied to an expression, repeating * over the list until no further changes are made. It’s possible to * pass a custom set of rules to the function as second argument. A rule * can be specified as an object, string, or function. * @param scope Scope to variables */ simplify(rules?: SimplifyRule[], scope?: object): MathJsChain; /** * Calculate the Sparse Matrix LU decomposition with full pivoting. * Sparse Matrix A is decomposed in two matrices (L, U) and two * permutation vectors (pinv, q) where P * A * Q = L * U * @param order The Symbolic Ordering and Analysis order: 0 - Natural * ordering, no permutation vector q is returned 1 - Matrix must be * square, symbolic ordering and analisis is performed on M = A + A' 2 - * Symbolic ordering and analysis is performed on M = A' * A. Dense * columns from A' are dropped, A recreated from A'. This is appropriate * for LU factorization of non-symmetric matrices. 3 - Symbolic ordering * and analysis is performed on M = A' * A. This is best used for LU * factorization is matrix M has no dense rows. A dense row is a row * with more than 10*sqr(columns) entries. * @param threshold Partial pivoting threshold (1 for partial pivoting) */ slu(order: number, threshold: number): MathJsChain; /** * Solves the linear equation system by backward substitution. Matrix * must be an upper triangular matrix. U * x = b * @param b A column vector with the b values */ usolve(b: Matrix | MathArray): MathJsChain; /************************************************************************* * Arithmetic functions ************************************************************************/ /** * Calculate the absolute value of a number. For matrices, the function * is evaluated element wise. */ abs(): MathJsChain; /** * Add two values, x + y. For matrices, the function is evaluated * element wise. * @param y Second value to add */ add(y: MathType): MathJsChain; /** * Apply a function that maps an array to a scalar along a given axis of the * matrix or array. Returns a new matrix or array with one less dimension * than the input. * @param dim The dimension along which the callback is applied * @param callback The callback function that is applied. This Function should take an * array or 1-d matrix as an input and return a number. * @returns The residual matrix with the function applied over some dimension. */ apply(dim: number, callback: (array: Array | Matrix) => number): MathJsChain; /** * Calculate the cubic root of a value. For matrices, the function is * evaluated element wise. * @param allRoots Optional, false by default. Only applicable when x is * a number or complex number. If true, all complex roots are returned, * if false (default) the principal root is returned. */ cbrt(allRoots?: boolean): MathJsChain; /** * Round a value towards plus infinity If x is complex, both real and * imaginary part are rounded towards plus infinity. For matrices, the * function is evaluated element wise. */ ceil(): MathJsChain; /** * Compute the cube of a value, x * x * x. For matrices, the function is * evaluated element wise. */ cube(): MathJsChain; /** * Divide two values, x / y. To divide matrices, x is multiplied with * the inverse of y: x * inv(y). * @param y Denominator */ divide(y: MathType): MathJsChain; /** * Divide two matrices element wise. The function accepts both matrices * and scalar values. * @param y Denominator */ dotDivide(y: MathType): MathJsChain; /** * Multiply two matrices element wise. The function accepts both * matrices and scalar values. * @param y Right hand value */ dotMultiply(y: MathType): MathJsChain; /** * Calculates the power of x to y element wise. * @param y The exponent */ dotPow(y: MathType): MathJsChain; /** * Calculate the exponent of a value. For matrices, the function is * evaluated element wise. */ exp(): MathJsChain; /** * Calculate the value of subtracting 1 from the exponential value. For * matrices, the function is evaluated element wise. */ expm1(): MathJsChain; /** * Round a value towards zero. For matrices, the function is evaluated * element wise. */ fix(): MathJsChain; /** * Round a value towards minus infinity. For matrices, the function is * evaluated element wise. */ floor(): MathJsChain; /** * Calculate the greatest common divisor for two or more values or * arrays. For matrices, the function is evaluated element wise. */ gcd(): MathJsChain; /** * Calculate the hypotenusa of a list with values. The hypotenusa is * defined as: hypot(a, b, c, ...) = sqrt(a^2 + b^2 + c^2 + ...) For * matrix input, the hypotenusa is calculated for all values in the * matrix. */ hypot(): MathJsChain; /** * Calculate the least common multiple for two or more values or arrays. * lcm is defined as: lcm(a, b) = abs(a * b) / gcd(a, b) For matrices, * the function is evaluated element wise. * @param b An integer number */ lcm(b: number | BigNumber | MathArray | Matrix): MathJsChain; /** * Calculate the logarithm of a value. For matrices, the function is * evaluated element wise. * @param base Optional base for the logarithm. If not provided, the * natural logarithm of x is calculated. Default value: e. */ log(base?: number | BigNumber | Complex): MathJsChain; /** * Calculate the 10-base of a value. This is the same as calculating * log(x, 10). For matrices, the function is evaluated element wise. */ log10(): MathJsChain; /** * Calculate the logarithm of a value+1. For matrices, the function is * evaluated element wise. */ log1p(base?: number | BigNumber | Complex): MathJsChain; /** * Calculate the 2-base of a value. This is the same as calculating * log(x, 2). For matrices, the function is evaluated element wise. */ log2(): MathJsChain; /** * Calculates the modulus, the remainder of an integer division. For * matrices, the function is evaluated element wise. The modulus is * defined as: x - y * floor(x / y) * @see http://en.wikipedia.org/wiki/Modulo_operation. * @param y Divisor */ mod(y: number | BigNumber | Fraction | MathArray | Matrix): MathJsChain; /** * Multiply two values, x * y. The result is squeezed. For matrices, the * matrix product is calculated. * @param y The second value to multiply */ multiply(y: MathType): MathJsChain; /** * Calculate the norm of a number, vector or matrix. The second * parameter p is optional. If not provided, it defaults to 2. * @param p Vector space. Supported numbers include Infinity and * -Infinity. Supported strings are: 'inf', '-inf', and 'fro' (The * Frobenius norm) Default value: 2. */ norm(p?: number | BigNumber | string): MathJsChain; /** * Calculate the nth root of a value. The principal nth root of a * positive real number A, is the positive real solution of the equation * x^root = A For matrices, the function is evaluated element wise. * @param root The root. Default value: 2. */ nthRoot(root?: number | BigNumber): MathJsChain; /** * Calculates the power of x to y, x ^ y. Matrix exponentiation is * supported for square matrices x, and positive integer exponents y. * @param y The exponent */ pow(y: number | BigNumber): MathJsChain; /** * Round a value towards the nearest integer. For matrices, the function * is evaluated element wise. * @param n Number of decimals Default value: 0. */ round(n?: number | BigNumber | MathArray): MathJsChain; /** * Compute the sign of a value. The sign of a value x is: 1 when x > 1 * -1 when x < 0 0 when x == 0 For matrices, the function is evaluated * element wise. * @param x The number for which to determine the sign * @returns The sign of x */ sign(x: number | BigNumber): MathJsChain; /** * Calculate the square root of a value. For matrices, the function is * evaluated element wise. */ sqrt(): MathJsChain; /** * Compute the square of a value, x * x. For matrices, the function is * evaluated element wise. */ square(): MathJsChain; /** * Subtract two values, x - y. For matrices, the function is evaluated * element wise. * @param y Value to subtract from x */ subtract(y: MathType): MathJsChain; /** * Inverse the sign of a value, apply a unary minus operation. For * matrices, the function is evaluated element wise. Boolean values and * strings will be converted to a number. For complex numbers, both real * and complex value are inverted. */ unaryMinus(): MathJsChain; /** * Unary plus operation. Boolean values and strings will be converted to * a number, numeric values will be returned as is. For matrices, the * function is evaluated element wise. */ unaryPlus(): MathJsChain; /** * Calculate the extended greatest common divisor for two values. See * http://en.wikipedia.org/wiki/Extended_Euclidean_algorithm. * @param b An integer number */ xgcd(b: number | BigNumber): MathJsChain; /************************************************************************* * Bitwise functions ************************************************************************/ /** * Bitwise AND two values, x & y. For matrices, the function is * evaluated element wise. * @param y Second value to and */ bitAnd(y: number | BigNumber | MathArray | Matrix): MathJsChain; /** * Bitwise NOT value, ~x. For matrices, the function is evaluated * element wise. For units, the function is evaluated on the best prefix * base. */ bitNot(): MathJsChain; /** * Bitwise OR two values, x | y. For matrices, the function is evaluated * element wise. For units, the function is evaluated on the lowest * print base. * @param y Second value to or */ bitOr(y: number | BigNumber | MathArray | Matrix): MathJsChain; /** * Bitwise XOR two values, x ^ y. For matrices, the function is * evaluated element wise. * @param y Second value to xor */ bitXor(y: number | BigNumber | MathArray | Matrix): MathJsChain; /** * Bitwise left logical shift of a value x by y number of bits, x << y. * For matrices, the function is evaluated element wise. For units, the * function is evaluated on the best prefix base. * @param y Amount of shifts */ leftShift(y: number | BigNumber): MathJsChain; /** * Bitwise right arithmetic shift of a value x by y number of bits, x >> * y. For matrices, the function is evaluated element wise. For units, * the function is evaluated on the best prefix base. * @param y Amount of shifts */ rightArithShift(y: number | BigNumber): MathJsChain; /** * Bitwise right logical shift of value x by y number of bits, x >>> y. * For matrices, the function is evaluated element wise. For units, the * function is evaluated on the best prefix base. * @param y Amount of shifts */ rightLogShift(y: number): MathJsChain; /************************************************************************* * Combinatorics functions ************************************************************************/ /** * The Bell Numbers count the number of partitions of a set. A partition * is a pairwise disjoint subset of S whose union is S. bellNumbers only * takes integer arguments. The following condition must be enforced: n * >= 0 */ bellNumbers(): MathJsChain; /** * The Catalan Numbers enumerate combinatorial structures of many * different types. catalan only takes integer arguments. The following * condition must be enforced: n >= 0 */ catalan(): MathJsChain; /** * The composition counts of n into k parts. Composition only takes * integer arguments. The following condition must be enforced: k <= n. * @param k Number of objects in the subset */ composition(k: number | BigNumber): MathJsChain; /** * The Stirling numbers of the second kind, counts the number of ways to * partition a set of n labelled objects into k nonempty unlabelled * subsets. stirlingS2 only takes integer arguments. The following * condition must be enforced: k <= n. If n = k or k = 1, then s(n,k) = * 1 * @param k Number of objects in the subset */ stirlingS2(k: number | BigNumber): MathJsChain; /************************************************************************* * Complex functions ************************************************************************/ /** * Compute the argument of a complex value. For a complex number a + bi, * the argument is computed as atan2(b, a). For matrices, the function * is evaluated element wise. */ arg(): MathJsChain; /** * Compute the complex conjugate of a complex value. If x = a+bi, the * complex conjugate of x is a - bi. For matrices, the function is * evaluated element wise. */ conj(): MathJsChain; /** * Get the imaginary part of a complex number. For a complex number a + * bi, the function returns b. For matrices, the function is evaluated * element wise. */ im(): MathJsChain; /** * Get the real part of a complex number. For a complex number a + bi, * the function returns a. For matrices, the function is evaluated * element wise. */ re(): MathJsChain; /************************************************************************* * Geometry functions ************************************************************************/ /** * Calculates: The eucledian distance between two points in 2 and 3 * dimensional spaces. Distance between point and a line in 2 and 3 * dimensional spaces. Pairwise distance between a set of 2D or 3D * points NOTE: When substituting coefficients of a line(a, b and c), * use ax + by + c = 0 instead of ax + by = c For parametric equation of * a 3D line, x0, y0, z0, a, b, c are from: (x−x0, y−y0, z−z0) = t(a, b, * c) * @param y Coordinates of the second point */ distance(y: MathArray | Matrix | object): MathJsChain; /** * Calculates the point of intersection of two lines in two or three * dimensions and of a line and a plane in three dimensions. The inputs * are in the form of arrays or 1 dimensional matrices. The line * intersection functions return null if the lines do not meet. Note: * Fill the plane coefficients as x + y + z = c and not as x + y + z + c * = 0. * @param x Co-ordinates of second end-point of first line * @param y Co-ordinates of first end-point of second line OR * Coefficients of the plane's equation * @param z Co-ordinates of second end-point of second line OR null if * the calculation is for line and plane */ intersect(x: MathArray | Matrix, y: MathArray | Matrix, z: MathArray | Matrix): MathJsChain; /************************************************************************* * Logical functions ************************************************************************/ /** * Logical and. Test whether two values are both defined with a * nonzero/nonempty value. For matrices, the function is evaluated * element wise. * @param y Second value to and */ and(y: number | BigNumber | Complex | Unit | MathArray | Matrix): MathJsChain; /** * Logical not. Flips boolean value of a given parameter. For matrices, * the function is evaluated element wise. */ not(): MathJsChain; /** * Logical or. Test if at least one value is defined with a * nonzero/nonempty value. For matrices, the function is evaluated * element wise. * @param y Second value to or */ or(y: number | BigNumber | Complex | Unit | MathArray | Matrix): MathJsChain; /** * Logical xor. Test whether one and only one value is defined with a * nonzero/nonempty value. For matrices, the function is evaluated * element wise. * @param y Second value to xor */ xor(y: number | BigNumber | Complex | Unit | MathArray | Matrix): MathJsChain; /************************************************************************* * Matrix functions ************************************************************************/ /** * Concatenate two or more matrices. dim: number is a zero-based * dimension over which to concatenate the matrices. By default the last * dimension of the matrices. */ concat(): MathJsChain; /** * Calculate the cross product for two vectors in three dimensional * space. The cross product of A = [a1, a2, a3] and B =[b1, b2, b3] is * defined as: cross(A, B) = [ a2 * b3 - a3 * b2, a3 * b1 - a1 * b3, a1 * * b2 - a2 * b1 ] * @param y Second vector */ cross(y: MathArray | Matrix): MathJsChain; /** * Calculate the determinant of a matrix. */ det(): MathJsChain; /** * Create a diagonal matrix or retrieve the diagonal of a matrix. When x * is a vector, a matrix with vector x on the diagonal will be returned. * When x is a two dimensional matrix, the matrixes kth diagonal will be * returned as vector. When k is positive, the values are placed on the * super diagonal. When k is negative, the values are placed on the sub * diagonal. * @param k The diagonal where the vector will be filled in or * retrieved. Default value: 0. * @param format The matrix storage format. Default value: 'dense'. */ diag(format?: string): MathJsChain; diag(k: number | BigNumber, format?: string): MathJsChain; /** * Calculate the dot product of two vectors. The dot product of A = [a1, * a2, a3, ..., an] and B = [b1, b2, b3, ..., bn] is defined as: dot(A, * B) = a1 * b1 + a2 * b2 + a3 * b3 + ... + an * bn * @param y Second vector */ dot(y: MathArray | Matrix): MathJsChain; /** * Compute the matrix exponential, expm(A) = e^A. The matrix must be * square. Not to be confused with exp(a), which performs element-wise * exponentiation. The exponential is calculated using the Padé * approximant with scaling and squaring; see “Nineteen Dubious Ways to * Compute the Exponential of a Matrix,” by Moler and Van Loan. */ expm(): MathJsChain; /** * Create a 2-dimensional identity matrix with size m x n or n x n. The * matrix has ones on the diagonal and zeros elsewhere. * @param format The Matrix storage format */ identity(format?: string): MathJsChain; /** * @param n The y dimension for the matrix * @param format The Matrix storage format */ identity(n: number, format?: string): MathJsChain; /** * Filter the items in an array or one dimensional matrix. */ filter(test: ((value: any, index: any, matrix: Matrix | MathArray) => boolean) | RegExp): MathJsChain; /** * Flatten a multi dimensional matrix into a single dimensional matrix. */ flatten(): MathJsChain; /** * Iterate over all elements of a matrix/array, and executes the given * callback function. */ forEach(callback: (value: any, index: any, matrix: Matrix | MathArray) => void): MathJsChain; /** * Calculate the inverse of a square matrix. */ inv(): MathJsChain; /** * Calculate the kronecker product of two matrices or vectors * @param y Second vector */ kron(y: Matrix | MathArray): MathJsChain; /** * Iterate over all elements of a matrix/array, and executes the given * callback function. * @param callback The callback function is invoked with three * parameters: the value of the element, the index of the element, and * the Matrix/array being traversed. */ map(callback: (value: any, index: any, matrix: Matrix | MathArray) => Matrix | MathArray): MathJsChain; /** * Create a matrix filled with ones. The created matrix can have one or * multiple dimensions. * @param format The matrix storage format */ ones(format?: string): MathJsChain; /** * @param format The matrix storage format */ ones(n: number, format?: string): MathJsChain; /** * Partition-based selection of an array or 1D matrix. Will find the kth * smallest value, and mutates the input array. Uses Quickselect. * @param k The kth smallest value to be retrieved; zero-based index * @param compare An optional comparator function. The function is * called as compare(a, b), and must return 1 when a > b, -1 when a < b, * and 0 when a == b. Default value: 'asc'. */ partitionSelect(k: number, compare?: 'asc' | 'desc' | ((a: any, b: any) => number)): MathJsChain; /** * Create an array from a range. By default, the range end is excluded. * This can be customized by providing an extra parameter includeEnd. * @param end End of the range, excluded by default, included when * parameter includeEnd=true * @param step Step size. Default value is 1. * @param includeEnd: Option to specify whether to include the end or * not. False by default */ range(includeEnd?: boolean): Matrix; range(end: number | BigNumber, includeEnd?: boolean): MathJsChain; range(end: number | BigNumber, step: number | BigNumber, includeEnd?: boolean): MathJsChain; /** * Reshape a multi dimensional array to fit the specified dimensions * @param sizes One dimensional array with integral sizes for each * dimension */ reshape(sizes: number[]): MathJsChain; /** * Resize a matrix * @param size One dimensional array with numbers * @param defaultValue Zero by default, except in case of a string, in * that case defaultValue = ' ' Default value: 0. */ resize(size: MathArray | Matrix, defaultValue?: number | string): MathJsChain; /** * Calculate the size of a matrix or scalar. */ size(): MathJsChain; /** * Sort the items in a matrix * @param compare An optional _comparator function or name. The function * is called as compare(a, b), and must return 1 when a > b, -1 when a < * b, and 0 when a == b. Default value: ‘asc’ */ sort(compare: ((a: any, b: any) => number) | 'asc' | 'desc' | 'natural'): MathJsChain; /** * Calculate the principal square root of a square matrix. The principal * square root matrix X of another matrix A is such that X * X = A. */ sqrtm(): MathJsChain; /** * Squeeze a matrix, remove inner and outer singleton dimensions from a * matrix. */ squeeze(): MathJsChain; /** * Get or set a subset of a matrix or string. * @param index An index containing ranges for each dimension * @param replacement An array, matrix, or scalar. If provided, the * subset is replaced with replacement. If not provided, the subset is * returned * @param defaultValue Default value, filled in on new entries when the * matrix is resized. If not provided, math.matrix elements will be left * undefined. Default value: undefined. */ subset(index: Index, replacement?: any, defaultValue?: any): MathJsChain; /** * Calculate the trace of a matrix: the sum of the elements on the main * diagonal of a square matrix. */ trace(): MathJsChain; /** * Transpose a matrix. All values of the matrix are reflected over its * main diagonal. Only two dimensional matrices are supported. */ transpose(): MathJsChain; /** * Create a matrix filled with zeros. The created matrix can have one or * multiple dimensions. * @param format The matrix storage format * @returns A matrix filled with zeros */ zeros(format?: string): MathJsChain; /** * @param n The y dimension of the matrix * @param format The matrix storage format */ zeros(n: number, format?: string): MathJsChain; /************************************************************************* * Probability functions ************************************************************************/ /** * Compute the number of ways of picking k unordered outcomes from n * possibilities. Combinations only takes integer arguments. The * following condition must be enforced: k <= n. * @param k Number of objects in the subset */ combinations(k: number | BigNumber): MathJsChain; /** * Compute the factorial of a value Factorial only supports an integer * value as argument. For matrices, the function is evaluated element * wise. */ factorial(): MathJsChain; /** * Compute the gamma function of a value using Lanczos approximation for * small values, and an extended Stirling approximation for large * values. For matrices, the function is evaluated element wise. */ gamma(): MathJsChain; /** * Calculate the Kullback-Leibler (KL) divergence between two * distributions * @param p Second vector */ kldivergence(p: MathArray | Matrix): MathJsChain; /** * Multinomial Coefficients compute the number of ways of picking a1, * a2, ..., ai unordered outcomes from n possibilities. multinomial * takes one array of integers as an argument. The following condition * must be enforced: every ai <= 0 */ multinomial(): MathJsChain; /** * Compute the number of ways of obtaining an ordered subset of k * elements from a set of n elements. Permutations only takes integer * arguments. The following condition must be enforced: k <= n. * @param k The number of objects in the subset */ permutations(k?: number | BigNumber): MathJsChain; /** * Random pick a value from a one dimensional array. Array element is * picked using a random function with uniform distribution. * @param number An int or float * @param weights An array of ints or floats */ pickRandom(number?: number, weights?: number[]): MathJsChain; /** * Return a random number larger or equal to min and smaller than max * using a uniform distribution. * @param min Minimum boundary for the random value, included * @param max Maximum boundary for the random value, excluded */ random(max?: number): MathJsChain; // tslint:disable-next-line unified-signatures random(min: number, max: number): MathJsChain; /** * Return a random integer number larger or equal to min and smaller * than max using a uniform distribution. * @param min Minimum boundary for the random value, included * @param max Maximum boundary for the random value, excluded */ randomInt(max?: number): MathJsChain; // tslint:disable-next-line unified-signatures randomInt(min: number, max: number): MathJsChain; /************************************************************************* * Relational functions ************************************************************************/ /** * Compare two values. Returns 1 when x > y, -1 when x < y, and 0 when x * == y. x and y are considered equal when the relative difference * between x and y is smaller than the configured epsilon. The function * cannot be used to compare values smaller than approximately 2.22e-16. * For matrices, the function is evaluated element wise. * @param y Second value to compare */ compare(y: MathType | string): MathJsChain; /** * Compare two values of any type in a deterministic, natural way. For * numeric values, the function works the same as math.compare. For * types of values that can’t be compared mathematically, the function * compares in a natural way. * @param y Second value to compare */ compareNatural(y: any): MathJsChain; /** * Compare two strings lexically. Comparison is case sensitive. Returns * 1 when x > y, -1 when x < y, and 0 when x == y. For matrices, the * function is evaluated element wise. * @param y Second string to compare */ compareText(y: string | MathArray | Matrix): MathJsChain; /** * Test element wise whether two matrices are equal. The function * accepts both matrices and scalar values. * @param y Second amtrix to compare */ deepEqual(y: MathType): MathJsChain; /** * Test whether two values are equal. * * The function tests whether the relative difference between x and y is * smaller than the configured epsilon. The function cannot be used to * compare values smaller than approximately 2.22e-16. For matrices, the * function is evaluated element wise. In case of complex numbers, x.re * must equal y.re, and x.im must equal y.im. Values null and undefined * are compared strictly, thus null is only equal to null and nothing * else, and undefined is only equal to undefined and nothing else. * @param y Second value to compare */ equal(y: MathType | string): MathJsChain; /** * Check equality of two strings. Comparison is case sensitive. For * matrices, the function is evaluated element wise. * @param y Second string to compare */ equalText(y: string | MathArray | Matrix): MathJsChain; /** * Test whether value x is larger than y. The function returns true when * x is larger than y and the relative difference between x and y is * larger than the configured epsilon. The function cannot be used to * compare values smaller than approximately 2.22e-16. For matrices, the * function is evaluated element wise. * @param y Second value to compare */ larger(y: MathType | string): MathJsChain; /** * Test whether value x is larger or equal to y. The function returns * true when x is larger than y or the relative difference between x and * y is smaller than the configured epsilon. The function cannot be used * to compare values smaller than approximately 2.22e-16. For matrices, * the function is evaluated element wise. * @param y Second value to vcompare */ largerEq(y: MathType | string): MathJsChain; /** * Test whether value x is smaller than y. The function returns true * when x is smaller than y and the relative difference between x and y * is smaller than the configured epsilon. The function cannot be used * to compare values smaller than approximately 2.22e-16. For matrices, * the function is evaluated element wise. * @param y Second value to vcompare */ smaller(y: MathType | string): MathJsChain; /** * Test whether value x is smaller or equal to y. The function returns * true when x is smaller than y or the relative difference between x * and y is smaller than the configured epsilon. The function cannot be * used to compare values smaller than approximately 2.22e-16. For * matrices, the function is evaluated element wise. * @param y Second value to compare */ smallerEq(y: MathType | string): MathJsChain; /** * Test whether two values are unequal. The function tests whether the * relative difference between x and y is larger than the configured * epsilon. The function cannot be used to compare values smaller than * approximately 2.22e-16. For matrices, the function is evaluated * element wise. In case of complex numbers, x.re must unequal y.re, or * x.im must unequal y.im. Values null and undefined are compared * strictly, thus null is unequal with everything except null, and * undefined is unequal with everything except undefined. * @param y Second value to vcompare */ unequal(y: MathType | string): MathJsChain; /************************************************************************* * Set functions ************************************************************************/ /** * Create the cartesian product of two (multi)sets. Multi-dimension * arrays will be converted to single-dimension arrays and the values * will be sorted in ascending order before the operation. * @param a2 A (multi)set */ setCartesian(a2: MathArray | Matrix): MathJsChain; /** * Create the difference of two (multi)sets: every element of set1, that * is not the element of set2. Multi-dimension arrays will be converted * to single-dimension arrays before the operation * @param a2 A (multi)set */ setDifference(a2: MathArray | Matrix): MathJsChain; /** * Collect the distinct elements of a multiset. A multi-dimension array * will be converted to a single-dimension array before the operation. */ setDistinct(): MathJsChain; /** * Create the intersection of two (multi)sets. Multi-dimension arrays * will be converted to single-dimension arrays before the operation. * @param a2 A (multi)set */ setIntersect(a2: MathArray | Matrix): MathJsChain; /** * Check whether a (multi)set is a subset of another (multi)set. (Every * element of set1 is the element of set2.) Multi-dimension arrays will * be converted to single-dimension arrays before the operation. * @param a2 A (multi)set */ setIsSubset(a2: MathArray | Matrix): MathJsChain; /** * Count the multiplicity of an element in a multiset. A multi-dimension * array will be converted to a single-dimension array before the * operation. * @param a A multiset */ setMultiplicity(a: MathArray | Matrix): MathJsChain; /** * Create the powerset of a (multi)set. (The powerset contains very * possible subsets of a (multi)set.) A multi-dimension array will be * converted to a single-dimension array before the operation. */ setPowerset(): MathJsChain; /** * Count the number of elements of a (multi)set. When a second parameter * is ‘true’, count only the unique values. A multi-dimension array will * be converted to a single-dimension array before the operation. */ setSize(): MathJsChain; /** * Create the symmetric difference of two (multi)sets. Multi-dimension * arrays will be converted to single-dimension arrays before the * operation. * @param a2 A (multi)set */ setSymDifference(a2: MathArray | Matrix): MathJsChain; /** * Create the union of two (multi)sets. Multi-dimension arrays will be * converted to single-dimension arrays before the operation. * @param a2 A (multi)set */ setUnion(a2: MathArray | Matrix): MathJsChain; /************************************************************************* * Special functions ************************************************************************/ /** * Compute the erf function of a value using a rational Chebyshev * approximations for different intervals of x. */ erf(): MathJsChain; /************************************************************************* * Statistics functions ************************************************************************/ /** * Compute the median absolute deviation of a matrix or a list with * values. The median absolute deviation is defined as the median of the * absolute deviations from the median. */ mad(): MathJsChain; /** * Compute the maximum value of a matrix or a list with values. In case * of a multi dimensional array, the maximum of the flattened array will * be calculated. When dim is provided, the maximum over the selected * dimension will be calculated. Parameter dim is zero-based. * @param dim The maximum over the selected dimension */ max(dim?: number): MathJsChain; /** * Compute the mean value of matrix or a list with values. In case of a * multi dimensional array, the mean of the flattened array will be * calculated. When dim is provided, the maximum over the selected * dimension will be calculated. Parameter dim is zero-based. * @param dim The mean over the selected dimension */ mean(dim?: number): MathJsChain; /** * Compute the median of a matrix or a list with values. The values are * sorted and the middle value is returned. In case of an even number of * values, the average of the two middle values is returned. Supported * types of values are: Number, BigNumber, Unit In case of a (multi * dimensional) array or matrix, the median of all elements will be * calculated. */ median(): MathJsChain; /** * Compute the maximum value of a matrix or a list of values. In case of * a multi dimensional array, the maximum of the flattened array will be * calculated. When dim is provided, the maximum over the selected * dimension will be calculated. Parameter dim is zero-based. * @param dim The minimum over the selected dimension */ min(dim?: number): MathJsChain; /** * Computes the mode of a set of numbers or a list with values(numbers * or characters). If there are more than one modes, it returns a list * of those values. */ mode(): MathJsChain; /** * Compute the product of a matrix or a list with values. In case of a * (multi dimensional) array or matrix, the sum of all elements will be * calculated. */ prod(): MathJsChain; /** * Compute the prob order quantile of a matrix or a list with values. * The sequence is sorted and the middle value is returned. Supported * types of sequence values are: Number, BigNumber, Unit Supported types * of probability are: Number, BigNumber In case of a (multi * dimensional) array or matrix, the prob order quantile of all elements * will be calculated. * @param probOrN prob is the order of the quantile, while N is the * amount of evenly distributed steps of probabilities; only one of * these options can be provided * @param sorted =false is data sorted in ascending order */ quantileSeq(prob: number | BigNumber | MathArray, sorted?: boolean): MathJsChain; /** * Compute the standard deviation of a matrix or a list with values. The * standard deviations is defined as the square root of the variance: * std(A) = sqrt(variance(A)). In case of a (multi dimensional) array or * matrix, the standard deviation over all elements will be calculated. * Optionally, the type of normalization can be specified as second * parameter. The parameter normalization can be one of the following * values: 'unbiased' (default) The sum of squared errors is divided by * (n - 1) 'uncorrected' The sum of squared errors is divided by n * 'biased' The sum of squared errors is divided by (n + 1) * @param array A single matrix or multiple scalar values * @param normalization Determines how to normalize the variance. Choose * ‘unbiased’ (default), ‘uncorrected’, or ‘biased’. Default value: * ‘unbiased’. * @returns The standard deviation */ std(normalization?: 'unbiased' | 'uncorrected' | 'biased' | 'unbiased'): MathJsChain; /** * Compute the sum of a matrix or a list with values. In case of a * (multi dimensional) array or matrix, the sum of all elements will be * calculated. */ sum(): MathJsChain; /** * Compute the variance of a matrix or a list with values. In case of a * (multi dimensional) array or matrix, the variance over all elements * will be calculated. Optionally, the type of normalization can be * specified as second parameter. The parameter normalization can be one * of the following values: 'unbiased' (default) The sum of squared * errors is divided by (n - 1) 'uncorrected' The sum of squared errors * is divided by n 'biased' The sum of squared errors is divided by (n + * 1) Note that older browser may not like the variable name var. In * that case, the function can be called as math['var'](...) instead of * math.variance(...). * @param normalization normalization Determines how to normalize the * variance. Choose ‘unbiased’ (default), ‘uncorrected’, or ‘biased’. * Default value: ‘unbiased’. * @returns The variance */ variance(normalization?: 'unbiased' | 'uncorrected' | 'biased' | 'unbiased'): MathJsChain; /************************************************************************* * String functions ************************************************************************/ /** * Format a value of any type into a string. * @param options An object with formatting options. * @param callback A custom formatting function, invoked for all numeric * elements in value, for example all elements of a matrix, or the real * and imaginary parts of a complex number. This callback can be used to * override the built-in numeric notation with any type of formatting. * Function callback is called with value as parameter and must return a * string. * @see http://mathjs.org/docs/reference/functions/format.html */ format(value: any, options?: FormatOptions | number | ((item: any) => string), callback?: (value: any) => string): MathJsChain; /** * Interpolate values into a string template. * @param values An object containing variables which will be filled in * in the template. * @param precision Number of digits to format numbers. If not provided, * the value will not be rounded. * @param options Formatting options, or the number of digits to format * numbers. See function math.format for a description of all options. */ print(values: any, precision?: number, options?: number | object): MathJsChain; /************************************************************************* * Trigonometry functions ************************************************************************/ /** * Calculate the inverse cosine of a value. For matrices, the function * is evaluated element wise. */ acos(): MathJsChain; /** * Calculate the hyperbolic arccos of a value, defined as acosh(x) = * ln(sqrt(x^2 - 1) + x). For matrices, the function is evaluated * element wise. */ acosh(): MathJsChain; /** * Calculate the inverse cotangent of a value. For matrices, the * function is evaluated element wise. */ acot(): MathJsChain; /** * Calculate the hyperbolic arccotangent of a value, defined as acoth(x) * = (ln((x+1)/x) + ln(x/(x-1))) / 2. For matrices, the function is * evaluated element wise. */ acoth(): MathJsChain; /** * Calculate the inverse cosecant of a value. For matrices, the function * is evaluated element wise. */ acsc(): MathJsChain; /** * Calculate the hyperbolic arccosecant of a value, defined as acsch(x) * = ln(1/x + sqrt(1/x^2 + 1)). For matrices, the function is evaluated * element wise. */ acsch(): MathJsChain; /** * Calculate the inverse secant of a value. For matrices, the function * is evaluated element wise. */ asec(): MathJsChain; /** * Calculate the hyperbolic arcsecant of a value, defined as asech(x) = * ln(sqrt(1/x^2 - 1) + 1/x). For matrices, the function is evaluated * element wise. */ asech(): MathJsChain; /** * Calculate the inverse sine of a value. For matrices, the function is * evaluated element wise. */ asin(): MathJsChain; /** * Calculate the hyperbolic arcsine of a value, defined as asinh(x) = * ln(x + sqrt(x^2 + 1)). For matrices, the function is evaluated * element wise. */ asinh(): MathJsChain; /** * Calculate the inverse tangent of a value. For matrices, the function * is evaluated element wise. */ atan(): MathJsChain; /** * Calculate the inverse tangent function with two arguments, y/x. By * providing two arguments, the right quadrant of the computed angle can * be determined. For matrices, the function is evaluated element wise. */ atan2(): MathJsChain; /** * Calculate the hyperbolic arctangent of a value, defined as atanh(x) = * ln((1 + x)/(1 - x)) / 2. For matrices, the function is evaluated * element wise. */ atanh(): MathJsChain; /** * Calculate the cosine of a value. For matrices, the function is * evaluated element wise. */ cos(): MathJsChain; /** * Calculate the hyperbolic cosine of a value, defined as cosh(x) = 1/2 * * (exp(x) + exp(-x)). For matrices, the function is evaluated element * wise. */ cosh(): MathJsChain; /** * Calculate the cotangent of a value. cot(x) is defined as 1 / tan(x). * For matrices, the function is evaluated element wise. */ cot(): MathJsChain; /** * Calculate the hyperbolic cotangent of a value, defined as coth(x) = 1 * / tanh(x). For matrices, the function is evaluated element wise. */ coth(): MathJsChain; /** * Calculate the cosecant of a value, defined as csc(x) = 1/sin(x). For * matrices, the function is evaluated element wise. */ csc(): MathJsChain; /** * Calculate the hyperbolic cosecant of a value, defined as csch(x) = 1 * / sinh(x). For matrices, the function is evaluated element wise. */ csch(): MathJsChain; /** * Calculate the secant of a value, defined as sec(x) = 1/cos(x). For * matrices, the function is evaluated element wise. */ sec(): MathJsChain; /** * Calculate the hyperbolic secant of a value, defined as sech(x) = 1 / * cosh(x). For matrices, the function is evaluated element wise. */ sech(): MathJsChain; /** * Calculate the sine of a value. For matrices, the function is * evaluated element wise. */ sin(): MathJsChain; /** * Calculate the hyperbolic sine of a value, defined as sinh(x) = 1/2 * * (exp(x) - exp(-x)). For matrices, the function is evaluated element * wise. */ sinh(): MathJsChain; /** * Calculate the tangent of a value. tan(x) is equal to sin(x) / cos(x). * For matrices, the function is evaluated element wise. */ tan(): MathJsChain; /** * Calculate the hyperbolic tangent of a value, defined as tanh(x) = * (exp(2 * x) - 1) / (exp(2 * x) + 1). For matrices, the function is * evaluated element wise. */ tanh(): MathJsChain; /************************************************************************* * Unit functions ************************************************************************/ /** * Change the unit of a value. For matrices, the function is evaluated * element wise. * @param unit New unit. Can be a string like "cm" or a unit without * value. */ to(unit: Unit | string): MathJsChain; /************************************************************************* * Utils functions ************************************************************************/ /** * Clone an object. */ clone(): MathJsChain; /** * Test whether a value is an integer number. The function supports * number, BigNumber, and Fraction. The function is evaluated * element-wise in case of Array or Matrix input. */ isInteger(): MathJsChain; /** * Test whether a value is NaN (not a number). The function supports * types number, BigNumber, Fraction, Unit and Complex. The function is * evaluated element-wise in case of Array or Matrix input. */ isNaN(): MathJsChain; /** * Test whether a value is negative: smaller than zero. The function * supports types number, BigNumber, Fraction, and Unit. The function is * evaluated element-wise in case of Array or Matrix input. */ isNegative(): MathJsChain; /** * Test whether a value is an numeric value. The function is evaluated * element-wise in case of Array or Matrix input. */ isNumeric(): MathJsChain; /** * Test whether a value is positive: larger than zero. The function * supports types number, BigNumber, Fraction, and Unit. The function is * evaluated element-wise in case of Array or Matrix input. */ isPositive(): MathJsChain; /** * Test whether a value is prime: has no divisors other than itself and * one. The function supports type number, bignumber. The function is * evaluated element-wise in case of Array or Matrix input. */ isPrime(): MathJsChain; /** * Test whether a value is zero. The function can check for zero for * types number, BigNumber, Fraction, Complex, and Unit. The function is * evaluated element-wise in case of Array or Matrix input. */ isZero(): MathJsChain; /** * Determine the type of a variable. */ typeOf(): MathJsChain; } interface ImportOptions { override?: boolean; silent?: boolean; wrap?: boolean; } interface ImportObject { [key: string]: any; } }