math_expressions 2.6.0 math_expressions: ^2.6.0 copied to clipboard
A library for parsing and evaluating mathematical expressions, supporting real numbers, vectors, and basic interval arithmetic.
import 'dart:math' as math;
import 'package:math_expressions/math_expressions.dart';
/// This file contains the following examples:
/// - Example 1: Expression creation and evaluation
/// (through the Parser and programmatically)
/// - Example 2: Expression simplification and differentiation
/// - Example 3: Custom function definition and use (function bound to expression)
/// - Example 4: Generic function definition and use (function bound to Dart handler)
void main() {
_expression_creation_and_evaluation();
_expression_simplification_and_differentiation();
_custom_function_definition_and_use();
_algorithmic_function_definition_and_use();
}
/// Example 1: Expression creation and evaluation
///
/// How to create an expression (a) via the Parser, (b) programmatically,
/// and how to evaluate an expression given a context.
void _expression_creation_and_evaluation() {
print('\nExample 1: Expression creation and evaluation\n');
// You can either create an mathematical expression programmatically or parse
// a string.
// (1a) Parse expression:
Parser p = Parser();
Expression exp = p.parse('(x^2 + cos(y)) / 3');
// (1b) Build expression: (x^2 + cos(y)) / 3
Variable x = Variable('x'), y = Variable('y');
Power xSquare = Power(x, 2);
Cos yCos = Cos(y);
Number three = Number(3.0);
exp = (xSquare + yCos) / three;
// Bind variables and evaluate the expression as real number.
// (2) Bind variables:
ContextModel cm = ContextModel()
..bindVariable(x, Number(2.0))
..bindVariable(y, Number(math.pi));
// (3) Evaluate expression:
double eval = exp.evaluate(EvaluationType.REAL, cm);
print('Expression: $exp');
print('Evaluated expression: $eval\n (with context: $cm)'); // = 1
}
/// Example 2: Expression simplification and differentiation
///
/// How to simplify an expression, and how to differentiate it with respect
/// to a given variable.
void _expression_simplification_and_differentiation() {
print('\nExample 2: Expression simplification and differentiation\n');
// (1) Parse expression:
Parser p = Parser();
Expression exp = p.parse('x*1 - (-5)');
// (2) Simplify expression:
print('Expression: $exp'); // = ((x * 1.0) - -(5.0))
print('Simplified expression: ${exp.simplify()}\n'); // = (x + 5.0)
// (2) Differentiate expression with respect to variable 'x':
Expression expDerived = exp.derive('x');
print(
'Differentiated expression: $expDerived'); // = (((x * 0.0) + (1.0 * 1.0)) - -(0.0))
print(
'Simplified differentiated expression: ${expDerived.simplify()}'); // = 1.0
}
/// Example 3: Custom function definition and use
///
/// How to create an arbitrary custom function expression and evaluate it.
void _custom_function_definition_and_use() {
print('\nExample 3: Custom function definition and use\n');
// (1) Create and evaluate custom function: DOUBLEUP (R -> R)
ContextModel cm = ContextModel();
Variable x = Variable('x');
CustomFunction doubleup = CustomFunction('doubleup', [x], x * Number(2));
cm.bindVariable(x, Number(0.5));
print('$doubleup = ${doubleup.expression}');
print(
'doubleup(${cm.getExpression('x')}) = ${doubleup.evaluate(EvaluationType.REAL, cm)}\n');
// (1) Create and evaluate custom function: LEFTSHIFT (R² -> R)
// Shifting to the left makes the number larger, effectively multiplying the
// number by pow(2, shiftIndex). Custom implementation of x << i.
Variable shiftIndex = Variable('i');
CustomFunction leftshift =
CustomFunction('leftshift', [x, shiftIndex], x * Power(2, shiftIndex));
cm.bindVariable(x, Number(250));
cm.bindVariable(shiftIndex, Number(8));
print('$leftshift = ${leftshift.expression}');
print(
'leftshift(${cm.getExpression('x')}, ${cm.getExpression('i')}) = ${leftshift.evaluate(EvaluationType.REAL, cm)}');
}
/// Example 4: Algorithmic function definition and use
///
/// How to create and parse an algorithmic function that's bound to a Dart handler.
void _algorithmic_function_definition_and_use() {
print('\nExample 4: Algorithmic function definition and use\n');
// (1) Create expression via parser by registering a function name
Parser p = Parser();
p.addFunction('my_min', (List<double> args) => args.reduce(math.min));
Expression exp = p.parse('my_min(1, x, -1)');
print('my_min(1, x, -1) = $exp');
// (1) Evaluate algorithmic function: MY_MIN (R^3 -> R)
ContextModel cm = ContextModel();
Variable x = Variable('x');
cm.bindVariable(x, -Number(2));
double res = exp.evaluate(EvaluationType.REAL, cm);
print('my_min(1, ${cm.getExpression('x')}, -1) = $res');
}