# The Walks Mathematica Package

Wolfram Mathematica™ is an incredibly powerful piece of software which can perform almost any kind of computation imaginable, and unsurprisingly it is very handy for performing computations on graphs. (Unfortunately Mathematica is not free, neither in the libre sense, nor in the gratis sense, but if you are a student you can probably get it for free.)

The `Walks`

Mathematica package, in addition to various walk/CDC related commands, provides plenty of nice commands which are useful for working with matrices of graphs in general. It is very easy to download and install.

- Installation and Usage Instructions
- Command Documentation
- Download ⬇️ (.m file, 25.1K)

### Release List

- v1.0 (September 2021, Latest version)

## Installation and Usage Instructions

Download the package file from above and save it somewhere.
Then open a new Mathematica notebook, go to `File` → `Install`, and you should see something like this:

From the first drop down, select **Package** (mine already has that selected by default). For Source, select **From File**; at this stage you'll have to find the file you downloaded from this webpage and selected it.

The Install name should come on its own when you select the file, it should say **Walks**.

Then hit "OK", and exit Mathematica (don't save the notebook, just close). That's it, the installation is done!

### Loading the Walks Package

If you reopen a new Mathematica notebook, type

`<<"Walks`"`

(note the tick ` symbol), and hit `Shift` + `Enter`, you should be able to use commands like `CDC[]`

, etc.

To see a list of available commands, type `?Walks`*`

, you should be able to click on any of them to see what they do.

To get information about any particular command, you can also run it with a question mark before it, and it will tell you what it does.

Please reach out if you run into any difficulties, or find any bugs!

## List of Commands

Here is a list of commands and features which are included in the Walks package. As explained above, the use of the package requires first running `<<"Walks`"`

(or `Needs["Walks`"]`

), and information about any commands here is also available in Mathematica by typing `?`

followed by the command name.

### Graph Arithmetic and Linear Algebra Commands

The first thing to mention isn't the addition of a command per se, but a convenient adaptation of certain Mathematica commands to be applied to graphs. For instance, usually, to obtain the eigenvalues of a graph, one would have to do

`Eigenvalues[AdjacencyMatrix[g]]`

and indeed, in countless situations, you would find yourself having to wrap a graph object in `AdjacencyMatrix[]`

to do any spectral calculations. Since I do these all the time, I thought it would make life easier to redefine the commands to first check whether the object is a graph; in that case, the command makes the conversion automatically, so you can just type

`Eigenvalues[g]`

instead. The commands which have been adapted include: `Eigenvectors`

, `Eigenvalues`

, `Eigensystem`

, `Det`

, `Tr`

, `NullSpace`

, `CharacteristicPolynomial`

, and `Inverse`

.

In addition to linear algebra commands, I adapted the symbol `+`

and integer multiplication to denote graph disjoint union, so that we can do things like the following.

### Commands

Here are all the commands made available by the package.`CDC[g]`

This computes the canonical double cover of the graph `g`

.

`IsomorphicCDCQ[g,h]`

This returns True if `g`

and `h`

have isomorphic CDCs, and false otherwise.

Note: This is not equivalent to `IsomorphicGraphQ[CDC[g],CDC[h]]`

, it is faster due to many other considerations made before the CDC is computed, so you are encouraged to use this command for speed.

`WalkMatrix[g]`

WalkMatrix[g,k]

This computes the walk matrix of the graph `g`

, or the `k`

-walk matrix if the optional integer argument `k`

is provided.

`ColourfulWalkMatrix[g]`

ColourfulWalkMatrix[g,k]

ColourfulWalkMatrix[g,k,χ]

This computes the walk matrix of the graph `g`

, or the `k`

-walk matrix if the optional integer argument `k`

is provided, colouring the matrix rows according to the number of walks. An optional colouring function `χ`

:*V*(`g`

)→ℕ can also be passed to it.

`WalkDimension[g]`

This computes the dimension of the main eigenspace of `g`

, or equivalently, the number of columns in the walk matrix.

`MainEigenvectors[g]`

MainEigenvectors[m]

`MainEigenvectors[g]`

gives a list of the main eigenvectors of the adjacency matrix corresponding to the graph object `g`

.

`MainEigenvectors[m]`

gives a list of the main eigenvectors of the square matrix `m`

.

Note: An eigenvector `v`

of a square matrix `m`

is said to be main if it is not orthogonal to the all ones vector `(1,...,1)`

, i.e., if `v.j!=0`

.

`MainEigenvalues[g]`

MainEigenvalues[m]

`MainEigenvalues[g]`

gives a list of the main eigenvalues of the adjacency matrix corresponding to the graph object `g`

.

`MainEigenvalues[m]`

gives a list of the main eigenvalues of the square matrix `m`

.

Note: An eigenvalue `λ`

of a square matrix `m`

is said to be main if at least one of its corresponding eigenvectors is not orthogonal to the all ones vector `(1,...,1)`

, i.e., if `v.j!=0`

.

`MainEigensystem[g]`

MainEigensystem[m]

`MainEigensystem[g]`

gives a list `{values, vectors}`

of the main eigenvalues and eigenvectors of the adjacency matrix corresponding to the graph object `g`

.

`MainEigensystem[m]`

gives a list of the main eigenvalues and eigenvectors of the square matrix `m`

.

`BoldEigenvalues[g]`

`BoldEigenvalues[g]`

gives a list of the eigenvalues of the graph object or square matrix `g`

, with main eigenvalues shown in **bold**. Eigenvalues which are not easily expressed as radicals are rounded to two decimal places, for nice presentation.

`MainCharacteristicPolynomial[g,x]`

This command gives a monic polynomial whose roots are precisely the main eigenvalues of the graph object (or adjacency matrix) `g`

, each with multiplicity 1.

`WalkPartition[g]`

This function partitions the vertex set of the graph `g`

, so that vertices in the same set have the same number of walks (of any length).

`WalkColouringFunction[g]`

This function associates a colour (natural number) with each vertex of the graph object `g`

, so that vertices receiving the same colour have the same number of walks (of any length).

`Colourful[g]`

Colourful[g,χ]

Colourful[g,χ,options...]

`Colourful[g]`

colours each vertex of the graph object `g`

, so that vertices receiving the same colour have the same number of walks (of any length).

`Colourful[g,χ]`

colours each vertex of the graph object `g`

, according to the colouring function `χ`

:*V*(`g`

)→ℕ.

Warning: If ≥10 colours are required, the extra colours will be randomly generated and might result in similar looking colours for differently coloured vertices. In that case, run the command multiple times to be safe.

`ActualColours[`

*Assoc*]

Converts a "colouring function" (i.e., association), which outputs positive integers, into a function which actually outputs RGB colours.

Warning: If ≥10 colours are required, the extra colours will be randomly generated and might result in similar looking colours for differently coloured inputs. In that case, run the command multiple times to be safe.

`LabelVertices[g]`

This displays the graph object `g`

with labelled vertices.

`UnlabelVertices[g]`

This displays the graph object `g`

without labelled vertices.

`IsolatedVertices[g]`

This returns a list of vertices in the graph object `g`

which are isolated (i.e., have no neighbours).

`IsolatedVerticesQ[g]`

This returns True if `g`

contains isolated vertices, and False otherwise.

`RemoveIsolatedVerticesQ[g]`

This returns the graph object `g`

with any isolated vertices removed.

`AddIsolatedVertex[g]`

AddIsolatedVertex[g,k]

This returns the graph object `g`

with an isolated vertex added, or if the optional argument `k`

is given, then it returns the graph with `k`

isolated vertices added.

`AddLoops[g]`

AddLoops[g,{v_{1},...}]

This returns the graph object `g`

with loops added to each vertex, or if the optional list of vertices is given, it returns `g`

with a loop added only to those vertices in the list.

`RyserSwitch[g,u,v,x,y]`

This function performs a Ryser switch on the edges `uv`

, `xy`

in the graph object `g`

.

Note: Given a graph `g`

and four vertices `u`

, `v`

, `x`

, `y`

such that:

- all of
`u`

,`v`

,`x`

,`y`

are distinct, -
`uv`

,`xy`

are edges in`g`

, -
`ux`

,`vy`

are not edges in`g`

,

`uv`

, `xy`

in `g`

replaces the edges `uv`

and `xy`

with the edges `ux`

and `vy`

.`PartiteSets[g]`

Given a bipartite graph `g`

, this function returns a pair `{A, B}`

of partite sets, i.e., a bipartition of the vertex set *V*(`g`

) such that all the edges in `g`

go from `A`

to `B`

.

Warning: These are only uniquely determined if `g`

is connected.

`KeepNonIsomorphic[{g`

_{1},...}]

Given a list of graphs, this returns a list with any isomorphic duplicates removed.

`Nullity[g]`

Nullity[m]

Even though the nullity of a matrix `m`

(or graph `g`

) is a standard concept in linear algebra (i.e., the dimension of its nullspace), there is no `Nullity[]`

function in Mathematica by default, so we provide one here.