Generate an Adjacency Matrix for a Weighted Graph

I am trying to implement Floyd-Warshall Algorithm. To do this it requires me to set up an `adjacency matrix` of a weighted graph. How would I go about doing this? I know the values and have attached a picture of the weighted graph. I have tried to look for some online examples of this, but I cannot seem to find anything. I understand Floyd-Warshall algorithm I just need help getting it set up so I am able to implement it. Here is one that I have built before, but I didn't have to use specific values.

Code:

``````public static void buildAdjMatrix()
{

for (int i = 0; i < 100; i++)
{
for (int j = 0; j < 100; j++)
{
if (directionAllowed(i, j) == true)
{
}
else
{
}
}
}

}
``````

Here is the specific Graph at hand:

Here is a picture of the matrix I need to create.. Sorry for the horrible quality...

-
It would be useful to post the structure of the graph you are using like the `Node` and `Arc` classes –  RMalke Mar 9 '13 at 1:25
I'm not exactly sure what you mean by that. Sorry :( –  JLott Mar 9 '13 at 1:41
@JLott what do you mean with "specific values"? –  ecampver Mar 9 '13 at 2:42
Added a picture of the matrix. –  JLott Mar 9 '13 at 2:44

So, you seem not to be familiarized with Graphs, take a look at Wikipedia. Also browse for some images, it gets easier to understand.

Bit of concept

Your picture can be represented as a `Graph`. Generally graphs are implemented using 2 basic kinds of elements, `Nodes` and `Links` (sometimes called `Arcs`).

A `Node` represent the letters in your picture, they would be A, B, C, etc. An `Arc` or `Link`, is the line that connect two nodes, if you look the connection between H to L, the have a link between the two, in a weighted graph, different links have different weights.

Solving your problem - Part 1

What we have to do is represent your picture as a graph in the code, so let's start creating the basic elements `Node` and `Arc`:

Node

A node has a `Name`, so we can identify the node. And a node can be connected to other nodes, we could use a collection of Nodes, but yours is a weighted graph, so, each of the connections has to be represented by the linked node and it's weight. Therefore, we use a collection of Arcs.

``````public class Node
{
public string Name;
public List<Arc> Arcs = new List<Arc>();

public Node(string name)
{
Name = name;
}

/// <summary>
/// Create a new arc, connecting this Node to the Nod passed in the parameter
/// Also, it creates the inversed node in the passed node
/// </summary>
public Node AddArc(Node child, int w)
{
{
Parent = this,
Child = child,
Weigth = w
});

if (!child.Arcs.Exists(a => a.Parent == child && a.Child == this))
{
}

return this;
}
}
``````

Arc

Really simple class, it contains the linked nodes, and the weight of the connection:

``````public class Arc
{
public int Weigth;
public Node Parent;
public Node Child;
}
``````

Graph

Graph is a kind of wrapper class, for organization purposes. I also have declared a Root for the graph, we're not using it, but is useful in several cases:

``````public class Graph
{
public Node Root;
public List<Node> AllNodes = new List<Node>();

public Node CreateRoot(string name)
{
Root = CreateNode(name);
return Root;
}

public Node CreateNode(string name)
{
var n = new Node(name);
return n;
}

{
// Matrix will be created here...
}
}
``````

Solving your problem - Part 2

Now we have all the data structure for holding the graph, let's fill it with some data. Here's some code that initializes a graph similar to your cube picture. It's boring and dull, but in real life cases, the graph will be created dynamically:

``````static void Main(string[] args)
{
var graph = new Graph();

var a = graph.CreateRoot("A");
var b = graph.CreateNode("B");
var c = graph.CreateNode("C");
var d = graph.CreateNode("D");
var e = graph.CreateNode("E");
var f = graph.CreateNode("F");
var g = graph.CreateNode("G");
var h = graph.CreateNode("H");
var i = graph.CreateNode("I");
var j = graph.CreateNode("J");
var k = graph.CreateNode("K");
var l = graph.CreateNode("L");
var m = graph.CreateNode("M");
var n = graph.CreateNode("N");
var o = graph.CreateNode("O");
var p = graph.CreateNode("P");

int?[,] adj = graph.CreateAdjMatrix(); // We're going to implement that down below

PrintMatrix(ref adj, graph.AllNodes.Count); // We're going to implement that down below
}
``````

Solving your problem - Part 3

So, we have a completelly initialized graph, let's create the matrix. The next method creates a matrix of two dimensions, n by n, where n is the number of node we get from the graph class. Foreach of the nodes, we search if they have a link, if they have a link, a filled the matrix in the appropriate position. Look that in your adjacency matrix example, you only have `1`s, here I put the weight of the link, I've put this way, so there's no sense in having a weighted graph!

``````public int?[,] CreateAdjMatrix()
{
int?[,] adj = new int?[AllNodes.Count, AllNodes.Count];

for (int i = 0; i < AllNodes.Count; i++)
{
Node n1 = AllNodes[i];

for (int j = 0; j < AllNodes.Count; j++)
{
Node n2 = AllNodes[j];

var arc = n1.Arcs.FirstOrDefault(a => a.Child == n2);

if (arc != null)
{
}
}
}
}
``````

Done

That's done, you have your weighted adjacency matrix, some way to print it:

``````private static void PrintMatrix(ref int?[,] matrix, int Count)
{
Console.Write("       ");
for (int i = 0; i < Count; i++)
{
Console.Write("{0}  ", (char)('A' + i));
}

Console.WriteLine();

for (int i = 0; i < Count; i++)
{
Console.Write("{0} | [ ", (char)('A' + i));

for (int j = 0; j < Count; j++)
{
if (i == j)
{
Console.Write(" &,");
}
else if (matrix[i, j] == null)
{
Console.Write(" .,");
}
else
{
Console.Write(" {0},", matrix[i, j]);
}

}
Console.Write(" ]\r\n");
}
Console.Write("\r\n");
}
``````

What give us the following output:

``````       A  B  C  D  E  F  G  H  I  J  K  L  M  N  O  P
A | [  &, 1, 1, ., ., ., ., ., ., ., ., ., ., ., ., ., ]
B | [  1, &, ., 3, 1, ., ., ., ., ., ., ., ., ., ., ., ]
C | [  1, ., &, 3, ., 1, ., ., ., ., ., ., ., ., ., ., ]
D | [  ., 3, 3, &, ., ., ., 8, ., ., ., ., ., ., ., ., ]
E | [  ., 1, ., ., &, ., 1, 3, ., ., ., ., ., ., ., ., ]
F | [  ., ., 1, ., ., &, ., 3, 1, ., ., ., ., ., ., ., ]
G | [  ., ., ., ., 1, ., &, ., ., 3, ., 1, ., ., ., ., ]
H | [  ., ., ., 8, 3, 3, ., &, ., 8, 8, ., 3, ., ., ., ]
I | [  ., ., ., ., ., 1, ., ., &, ., 3, ., ., 1, ., ., ]
J | [  ., ., ., ., ., ., 3, 8, ., &, ., ., ., ., 3, ., ]
K | [  ., ., ., ., ., ., ., 8, 3, ., &, ., ., ., ., 3, ]
L | [  ., ., ., ., ., ., 1, ., ., ., ., &, ., ., 1, ., ]
M | [  ., ., ., ., ., ., ., 3, ., ., ., ., &, ., 1, 1, ]
N | [  ., ., ., ., ., ., ., ., 1, ., ., ., ., &, ., 1, ]
O | [  ., ., ., ., ., ., ., ., ., 3, ., 1, 1, ., &, ., ]
P | [  ., ., ., ., ., ., ., ., ., ., 3, ., 1, 1, ., &, ]
``````
-
Wow! This explanation is incredible! Thank you so much for you help. This really helped me understand what to do and I am sure others will find it helpful as well. –  JLott Mar 9 '13 at 15:02
I did have one problem.. On your CreateAdjMatrix, it says that there is unreachable code in the for loop with the counter 'i' –  JLott Mar 9 '13 at 15:34
Mmmm, in the for line specifically? Mine is working here. PS: The CreateAdjMatrix method should be inside the Graph class –  RMalke Mar 9 '13 at 15:37
Yeah that is where I have it... odd... Where are you putting the structure of the graph? Like where you are adding the new graph. –  JLott Mar 9 '13 at 15:43
Awesome. I just had my parenthesis out of order... of course lol. Thanks again! –  JLott Mar 9 '13 at 15:59

protected by Community♦Jun 25 at 6:43

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