Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Finding edge in weighted graph

I have a graph with four nodes, each node represents a position and they are laid out like a two dimensional grid. Every node has a connection (an edge) to all (according to the position) adjacent nodes. Every edge also has a weight.

Here are the nodes represented by A,B,C,D and the weight of the edges is indicated by the numbers:

``````A     100     B

120         220

C     150     D
``````

I want to structure a container and an algorithm that switches the nodes sharing the edge with the highest weight. Then reset the weight of that edge. No node (position) can be switched more than once each time the algorithm is executed.

For example, processing the above, the highest weight is on edge BD, so we switch those. Since no node can be switched more than once, all edges involved in either B or D is reset.

``````A             D

120

C             B
``````

Then, the next highest weight is on the only edge left, switching those would give us the final layout: C,D,A,B.

I'm currently running a quite awful implementation of this. I store a long list of edges, holding four values for the nodes they are (potentially) connected to, a value for its weight and the position for the node itself. Every time anything is requested, I loop through the entire list.

I'm writing this in C++, could some parts of the STL help speed this up? Also, how to avoid the duplication of data? A node position is currently in five objects. The node itself that is there and the four nodes indicating a connection to it.

In short, I want help with:

• Can this be structured in a way so that there is no data duplication?
• Recognise the problem? If any of this has a name, tell me so I can google for more info on the subject.
• Fast algorithms are always nice.
-
Assuming that the edges only connects orthogonally between the grid positions and the grid itself is square, the number of edges can be given by 2n(n+1) where n=sizex-1=sizey-1... If it helps. Source: research.att.com/~njas/sequences/A046092 – Mizipzor Jul 24 '09 at 21:10

As for names, this is a vertex cover problem. Optimal vertex cover is NP-hard with decent approximation solutions, but your problem is simpler. You're looking at a pseudo-maximum under a tighter edge selection criterion. Specifically, once an edge is selected every connected edge is removed (representing the removal of vertices to be swapped).

For example, here's a standard greedy approach:

0) sort the edges; retain adjacency information
while edges remain:
1) select the highest edge
2) remove all adjacent edges from the list
endwhile

The list of edges selected gives you the vertices to swap.
Time complexity is O(Sorting vertices + linear pass over vertices), which in general will boil down to O(sorting vertices), which will likely by O(V*log(V)).