Directed Graph Versus Associative Array

I have been reading up on directed graphs. I have managed to get an abstract graph data type working in my application but I don't find it particularly intuitive and am considering replacing it with an ordinary multi-dimensional array.

My graph is sparse and acyclic. Each vertex is reachable from one particular 'master' vertex. If it was a tree, this master vertex would be the 'root'. It it was a social network, this master vertex would be 'me'.

Although my graph may have hundreds of thousands of vertices it has a finite depth: the greatest distance between any two nodes is 3 edges.

The underlying data representation is an adjacency list. A small example would look like this:

--------------
1  | 2, 3, 4
2  | 5
3  | 5
4  | 5
5  | 6

If I was using an ordinary multi-dim array instead of my graph data type, it would look something like this:

\$me[1][2][5][6]
\$me[1][3][5][6]
\$me[1][4][5][6]

Now, the main things that I want to be able to do with this graph are:

1. Navigate it as a hierarchy. I realise that some child vertices will feature in more than one category (e.g. #5), but that is what I want for this particular use case. I can't see any real difference between an array and a graph for this point.
2. Lay it out as a list (alphabetical, according to vertex name), with no duplicates. I would probably do a DFS, flagging visited vertices as I go, to avoid exploring them more than once. But as far as I can see this is achievable using either the graph or the array, and at the same cost.
3. Do an 'all paths' analysis for any given pair of points. Because I want 'all paths' (ie. I'm not simply checking for reachability), it seems to me that I have to traverse the entire graph, and again I can see no advantage in a graph over an array.

I get the feeling that I am missing something, but I can't put my finger on it. Can you??? Any ideas, suggestions, insights or advice gratefully accepted... (By the way, I'm using PHP, and the data source is a relational DB. I don't think this makes any real difference though).

Thanks!

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What are the dimensions of this multiple dimensions array? Usually the alternatives for graph are a matrix (2 dimensions) or adjancy list (which is basically an implementation of a sparsed matrix...) –  amit Jan 17 '13 at 12:12

One thing you need to understand is that a directed graph (or digraph) is a concept, whereas an associative array is a data structure.

An instance of the digraph concept can be stored in many different data structures, of which you can find the most common on this wikipedia page.

I'm not sure what you are doing with your multidimensional array... storing all paths? You will end up with a N³ space complexity, and trouble building it. A tree-based structure would be more efficient at the very least.

Now to the things you want to do with your graph:

1. Navigate as a hierarchy. The basic digraph concept doesn't allow to go up in the hierarchy, but you can easily store the reverse graph as well (especially with matrix-based representations, just use 3 values instead of 2 - forward, backward and nothing) .
2. Lay it out as a list, according to name. You have to store the name somewhere (either in a side map or in the vertex object), but it shouldn't be any harder than sorting anything else according to name.
3. Do an 'all paths' analysis. You can probably get away with linear complexity (in the number of paths) through DP and a shared representation of paths.
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+1 just for the first sentence –  UmNyobe Jan 17 '13 at 15:19

It looks that your data structure is too complicated. If you represent a directed graph as a multidimensional array, it is almost always of dimension two so that

\$array[\$x][\$y]

is a boolean value that is TRUE if and only if there is an edge from node \$x to node \$y in the graph. In your example if would be e.g.

\$array[1][2] = TRUE
\$array[1][5] = FALSE

But for sparse graphs, using this boolean matrix representation is not usually good. Typically you would have a one-dimensional array that maps every node to a set of nodes to which there is an edge, e.g.

\$array[1] = { 2, 3, 4 }

where { ... } means some sort of an unordered collection data structure, which can be e.g. a binary search tree or a hash set (hash table).

This data structure enables you to quickly find the nodes to which there is an arc from a given node, which is a key feature for graph algorithms.

Sometimes you want to be able to traverse your graph backwards also; in that case you would have another array that maps nodes to the list of their predecessors.

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