# Full set of subgraphs in Haskell

I'm faced with a problem of generating a full set of subgraphs of any graph with limited length. Graphs are represented as lists of ordered pairs, for example:

let g = [(1,2),(1,7),(1,3),(2,9),(2,4),(3,5),(4,6),(5,6), (7,8),(8,10),(8,9),(10,12),(10,11),(11,13),(12,14),(13,15),(14,15)]

One way is getting all subsequences wherein pairs are bounded, but standard function subsequences generates 2^n variants, at that more of these variants are not bounded, so that represent disconnected subgraphs.

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Doesn't this problem take O(2^n) time to begin with? –  Rhymoid Aug 15 '13 at 9:12
"full set of subgraphs of any graph with limited length", better than O(2^n), enumerate all (breadth-first search) pruning by length. –  josejuan Aug 15 '13 at 22:30

I found the way, let we have a graph

``````let g = [(1,2),(1,7),(1,3),(2,9),(2,4),(3,5),(4,6),(5,6), (7,8),(8,10),(8,9),(10,12),(10,11),(11,13),(12,14),(13,15),(14,15)]
``````

We can get all subgraps by this code:

``````subgraphs g = nub \$ subgraphs' g

subgraphs' [] = [[]]
subgraphs' (x:xz) = subgraphs xz ++ map (contact x) (subgraphs xz)

contact (i,j) [] = [(i,j)]
contact (i,j) set = if ([i] ++ [j]) `intersect` ((\(f,g) -> f ++ g) \$ unzip set) /= [] then ([(i,j)] ++ set) else set
``````

Test it:

``````*Main> length \$ subgraphs g
164
``````
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