Math.NET Symbolics is a basic open source computer algebra library for .Net and Mono written in F#.

This project does not aim to become a full computer algebra system. If you need such a system, have a look at Axiom or Maxima instead, or for commercial solutions Maple, Mathematica or Wolfram Alpha.

Math.NET Symbolics is part of the Math.NET initiative. Available for free under the MIT/X11 License.

The recommended way to get Math.NET Symbolics is to use NuGet. The following packages are provided and maintained in the public NuGet Gallery:

Core Package:

MathNet.Symbolics - core package

.NETFramework 4.5, .NETFramework 4.6.1 and .NETStandard 2.0

Package Dependencies:

FParsec (isolated usage only for infix parsing)

With NuGet you can start quickly by installing the MathNet.Symbolics package, which automatically loads its dependencies MathNet.Numerics and MathNet.Numerics.FSharp . In F# interactive you can reference them by loading two scripts, along the lines of

1: 2: #load @"..\..\packages\MathNet.Numerics.FSharp.4.6.0\MathNet.Numerics.fsx" #load @"..\..\packages\MathNet.Symbolics.0.19.0\MathNet.Symbolics.fsx"

To get started, open the namespaces and the Operators module and declare the variables and constants you intend to use as symbols:

1: 2: 3: 4: 5: 6: 7: 8: 9: 10: 11: 12: open System . Numerics open MathNet . Numerics open MathNet . Symbolics open Operators let x = symbol "x" let y = symbol "y" let a = symbol "a" let b = symbol "b" let c = symbol "c" let d = symbol "d"

Then we're all set to start writing expressions:

1: 2: 3: 4: a + a // returns 2*a a * a // returns a^2 2 + 1 / x - 1 // returns 1 + 1/x ( a / b / ( c * a )) * ( c * d / a ) / d // returns 1/(a*b)

Math.NET Symbolics expressions are always in a simplified form according to a set of rules. Expressions are tree structures, but F# interactive shows them in a readable infix form thanks to a display printer added in the script loaded above. You can also use these printers manually to format any expression as infix string, LaTeX expression or in strict mode to see the actual internal representation:

1: 2: 3: Infix . format ( 1 / ( a * b )) // returns string "1/(a*b)" Infix . formatStrict ( 1 / ( a * b )) // returns string "a^(-1)*b^(-1)" LaTeX . format ( 1 / ( a * b )) // returns string "\frac{1}{ab}"

Strings in infix notation can be parsed back into expressions:

1: 2: 3: 4: 5: Infix . parse "1/(a*b)" // Returns ParsedExpression 1/(a*b) Infix . parse "1/(a*b" // Returns ParseFailure, 7: Expecting infix operator or ')' Infix . tryParse "1/(a*b)" // Returns Some (1/(a*b)) Infix . parseOrUndefined "1/(a*b)" // Returns 1/(a*b) Infix . parseOrThrow "1/(a*b)" // Returns 1/(a*b)

Numbers can be forced to become expressions using the Q suffix, e.g. 3Q is an expression representing an integer with value 3. This is usually not needed if at least one of the operands is an expression, e.g. a symbol. But if all operands are standard .Net numbers, they will be treated as such. For example (3 + 2)*4/6 is a standard F# integer expression and will result in 3 due to .Net integer arithmetics. However, if we force it to become an expression by writing (3Q + 2)*4/6 , it will result in the fraction expression 10/3 as expected.

Since Math.NET Symbolics is about algebra, all number literals are arbitrarily big rational numbers, i.e. integers or fractions. If you need floating point numbers, use a symbol for them instead and provide their value at evaluation time.

Often you need to evaluate the resulting number value of an expression given the values for all its symbols. To do so, prepare the value set as map or dictionary and pass it to the evaluate function. Values need to be of type FloatingPoint which is a discriminated union that can represent not only float and complex but also vectors and matrices of the same.

1: 2: let symbols = Map . ofList [ "a" , Real 2.0 ; "b" , Real 3.0 ] Evaluate . evaluate symbols ( 1 / ( a * b )) // Returns Real 0.1666666667 (as float)

There are various modules to help you combine and manipulate expressions:

Operators: standard operators, recommended to open always.

standard operators, recommended to open always. Structure: structural analysis, operand access, substitution, map

structural analysis, operand access, substitution, map Algebraic: algebraic expansion, separate factors

algebraic expansion, separate factors Polynomial: properties, degrees, coefficients, terms, divide, gcd, expansion, partial fraction

properties, degrees, coefficients, terms, divide, gcd, expansion, partial fraction Rational: numerator/denominator, properties, rationalize, expand, simplify

numerator/denominator, properties, rationalize, expand, simplify Exponential: expand, contract, simplify

expand, contract, simplify Trigonometric: expand, separate, contract, substitute, simplify

expand, separate, contract, substitute, simplify Calculus: differentiate

For example, let's try to contract the trigonometric expression \((\cos{x})^4\) into \(\frac{3}{8} + \frac{1}{2}\cos{2x} + \frac{1}{8}\cos{4x}\):

1: Trigonometric . contract ( cos ( x ) ** 4 ) // Returns 3/8 + cos(2*x)/2 + cos(4*x)/8

These modules can also be combined to build more interesting manipulations. For example, let's implement a taylor expansion routine to approximate the shape of a differentiable function \(x(\zeta)\) at some point \(\zeta = a\) by its \(k-1\) first derivatives at that point (order \(k\)). We can leverage the existing structural substitute routine to substitute \(\zeta\) with \(a\) to get the resulting expression at \(a\), and the differentiate routine to evaluate the partial derivative \(\frac{\partial{x}}{\partial\zeta}\).

1: 2: 3: 4: 5: 6: 7: let taylor ( k : int ) symbol a x = let rec impl n nf acc dxn = if n = k then acc else let dxn_a = dxn |> Structure . substitute symbol a let dxn' = dxn |> Calculus . differentiate symbol impl ( n + 1 ) ( nf * ( n + 1 )) ( acc + dxn_a / nf * ( symbol - a ) ** n ) dxn' impl 0 1 zero x |> Algebraic . expand

Let's use this routine to approximate \(\sin{x}+\cos{x}\) at \(x = 0\) using the first 4 derivatives:

1: taylor 4 x 0Q ( sin ( x ) + cos ( x )) // Returns 1 + x - x^2/2 - x^3/6

Even though Math.NET Symbolics is written entirely in F#, it can be used in C# almost exactly the same way. The equivalent C# code to the F# code above could look as follows:

1: 2: 3: 4: 5: 6: 7: 8: 9: 10: 11: 12: 13: 14: 15: 16: 17: 18: 19: 20: 21: 22: 23: 24: 25: 26: 27: 28: 29: 30: 31: 32: 33: 34: 35: 36: 37: 38: 39: 40: 41: 42: 43: 44: 45: 46: 47: 48: 49: 50: 51: 52: 53: 54: using MathNet.Symbolics; using Expr = MathNet.Symbolics.SymbolicExpression; var x = Expr.Variable( "x" ); var y = Expr.Variable( "y" ); var a = Expr.Variable( "a" ); var b = Expr.Variable( "b" ); var c = Expr.Variable( "c" ); var d = Expr.Variable( "d" ); (a + a).ToString(); // returns string "2*a" (a * a).ToString(); // returns string "a^2" ( 2 + 1 / x - 1 ).ToString(); // returns string "1 + 1/x" ((a / b / (c * a)) * (c * d / a) / d).ToString(); // returns string "1/(a*b)" ( 1 / (a * b)).ToString(); // returns string "1/(a*b)" ( 1 / (a * b)).ToInternalString(); // returns string "a^(-1)*b^(-1)" ( 1 / (a * b)).ToLaTeX(); // returns string "\frac{1}{ab}" Expr.Parse( "1/(a*b" ); // throws an exception Expr.Parse( "1/(a*b)" ).ToString(); // Returns string "1/(a*b)" var symbols = new Dictionary< string ,FloatingPoint> {{ "a" , 2.0 }, { "b" , 3.0 }}; // Returns 0.166666666666667 ( 1 / (a * b)).Evaluate(symbols).RealValue; // Compilation to a function Func< double , double , double > f = ( 1 / (a * b)).Compile( "a" , "b" ); f( 2.0 , 3.0 ) // returns 0.166666666666667 // Returns string "3/8 + cos(2*x)/2 + cos(4*x)/8" x.Cos().Pow( 4 ).TrigonometricContract().ToString(); // Taylor Expansion Expr Taylor( int k, Expr symbol, Expr al, Expr xl) { int factorial = 1 ; Expr accumulator = Expr.Zero; Expr derivative = xl; for ( int i = 0 ; i < k; i+ + ) { var subs = derivative.Substitute(symbol, al); derivative = derivative.Differentiate(symbol); accumulator = accumulator + subs / factorial * ((symbol - al).Pow(i)); factorial * = (i + 1 ); } return accumulator.Expand(); } // Returns string "1 + x - x^2/2 - x^3/6" Taylor( 4 , x, 0 , x.Sin() + x.Cos()).ToString();

Code for C++/CLI project is almost exactly the same but there are some things that worth to mention separately:

1.NuGet package manager doesn't have support for C++/CLI projects yet. So if you try to install the package with NuGet you may see this error:

Could not install package 'MathNet.Symbolics 0.19.0'. You are trying to install this package into a project that targets 'native,Version=v0.0', but the package does not contain any assembly references or content files that are compatible with that framework.

There are other ways to add the library to the project:

Use other dependency manager like Paket.

Add references manually: Download packages. Although NuGet cannot include packages to the project it is downloading them to common package directory anyway. Right click on the project in the Solution Explorer Add -> References... Click Browse button Navigate to packages directory. Add reference to the next dlls: FParsec.dll FParsecCS.dll FSharp.Core.dll MathNet.Numerics.FSharp.dll MathNet.Symbolics.dll



Also to avoid version conflict of FSharp.Core you have to set AutoGenerateBindingRedirects to true . Put the instruction in your .vcxproj file under "Globals" property section:

1: 2: 3: < PropertyGroup Label = "Globals" > .. . < AutoGenerateBindingRedirects > true </ AutoGenerateBindingRedirects >

Instead of using + and - operators it's better to choose Add and Subtract methods to get away from warning about matching more than one operator.

Here is F# sample translated into C++/CLI:

1: 2: 3: 4: 5: 6: 7: 8: 9: 10: 11: 12: 13: 14: 15: 16: 17: 18: 19: 20: 21: 22: 23: 24: 25: 26: 27: 28: 29: 30: 31: 32: 33: 34: 35: 36: 37: 38: 39: 40: 41: 42: 43: 44: 45: 46: 47: auto x = SymbolicExpression::Variable("x"); auto y = SymbolicExpression::Variable("y"); auto a = SymbolicExpression::Variable("a"); auto b = SymbolicExpression::Variable("b"); auto c = SymbolicExpression::Variable("c"); auto d = SymbolicExpression::Variable("d"); a->Add(a)->ToString(); // returns string "2*a" (a * a)->ToString(); // returns string "a^2" (2 + 1 / x)->Subtract(1)->ToString(); // returns string "1 + 1/x" ((a / b / (c * a)) * (c * d / a) / d)->ToString(); // returns 1/(a*b) (1 / (a * b))->ToString(); // returns string "1/(a*b)" (1 / (a * b))->ToInternalString(); // returns string "a^(-1)*b^(-1)" (1 / (a * b))->ToLaTeX(); // returns string "\frac{1}{ab}" Infix::Format(Infix::ParseOrUndefined("1/(a*b)")); // Returns string "1/(a*b)" Infix::Format(Infix::ParseOrUndefined("1/(a*b")); // Returns string "Undefined" Infix::Format(Infix::ParseOrThrow("1/(a*b)")); // Returns string "1/(a*b)" auto symbols = gcnew Dictionary<String^, FloatingPoint^>; symbols->Add("a", 2.0); symbols->Add("b", 3.0); // Returns 0.166666666666667 (1 / (a * b))->Evaluate(symbols)->RealValue; // Returns string "3/8 + cos(2*x)/2 + cos(4*x)/8" x->Cos()->Pow(4)->TrigonometricContract()->ToString(); SymbolicExpression^ Taylor(int k, SymbolicExpression^ symbol, SymbolicExpression^ a, SymbolicExpression^ x) { int factorial = 1; auto accumulator = SymbolicExpression::Zero; auto derivative = x; for (int i = 0; i < k; i++) { auto subs = derivative->Substitute(symbol, a); derivative = derivative->Differentiate(symbol); accumulator = accumulator->Add(subs / factorial * (symbol->Subtract(a))->Pow(i)); factorial *= (i + 1); } return accumulator->Expand(); } // Returns string "1 + x - x^2/2 - x^3/6" Taylor(4, x, 0, x->Sin()->Add(x->Cos()))->ToString();

For VB.NET we won't do the same thing here but instead we just show basic usage for now