math-expressions
Math-expressions is client- or server-side JavaScript library for
parse expressions like sin^2 (x^3) and do some basic computer
algebra with them, like symbolic differentiation and numerically
identifying equivalent expressions.
Demo of client-side use
There is a demo available which focuses on the equality testing.
Code Example
Include the script in build/math-expressions.js on your page.
<script type="text/javascript" src="math-expressions.js"></script>`This adds MathExpression to the global namespace, so you can then perform the following parsing and equality-testing.
var f = MathExpression.fromText("sin^2 (x^3)");
console.log(f.tex());
var g = MathExpression.fromText("sin^2 x + cos^2 x");
var h = MathExpression.fromText("1");
console.log( g.equals(h) );
var g = MathExpression.fromText("x + x^2");
var h = MathExpression.fromText("x + x^3");
console.log( g.equals(h) );For server-side use, you can load the package as usual via var MathExpression = require('math-expressions');.
Installation
The pre-built library is stored in build/math-expressions.js. This
is packaged in a "unified" module format, so it can be treated as an
AMD-style or a CommonJS-style module (and imported via a module loader
like RequireJS). If you are not using a module loader, you can import
it via
<script type="text/javascript" src="math-expressions.js"></script>`to add MathExpression to the global namespace.
API Reference
Expression constructors
MathExpression.fromText(string)
Convert string to expression through the text parser. For example, var f = MathExpression.fromText('x^2'); will result in f representing the expression x^2. Then f.evaluate({x:3}) is 9.
This is often used for student-facing text, considering that even MathExpression.fromText('sin^2 x') does the right thing and produces the square of the sine function. Exceptions are thrown when string does not parse.
MathExpression.fromLatex(string)
Convert string to an expression through the LaTeX parser. For example, var f = MathExpression.fromLatex('\\frac{x+1}{2}'); will result in f representing the expression (x+1)/2. Then f.evaluate({x:3}) is 2.
Expression methods
expression.toString()
Produce a textual representation of expression. For example, MathExpression.fromText( f.toString() ) recreates f.
expression.toLatex()
Produce a LaTeX representation of expression. For example, if f is MathExpression.fromText('x^10'), then f.toLatex() is x^{10} since LaTeX requires braces for exponents.
expression.variables()
Return the list of variables used in expression. For example, if f is MathExpression.fromText('x + cos(y)'), then f.variables() is ['x','y'].
expression.equals(another)
Determine whether expression and another represent the "same" expression.
The current algorithm randomly samples the two expressions in a neighborhood of the real line of the complex plane and demands approximate numeric equality most of the time for random assignments to the variables. This is, quite admittedly, not a perfect algorithm, and it is likely to be replaced in a future version of this library.
expression.derivative(variable)
Symbolically differentiate expression with respect to the given variable. For example, if f is MathExpression.fromText('x^10'), then f.derivative('x') is 10 x^9.
Tests
Assuming you have git cloneed the repository and npm installed to
populate node_modules with jasmine, you can then run the tests with
npm test.
Most of the tests are used to determine if expression.equals(another) does the expected thing on student input.
License
Math-expressions is dual-licensed under GPLv3 and under Apache Version 2.0.