# How can I find Maximum Common Subgraph of two graphs?

Hi i need a help in finding a graph algorithm

im working on the following equation related to distance functions

``````d (g1, g2)   = 1-       │mcs(g1,g2) │  /
│g1│+│g2│-│mcs (g1, g2) │
``````

Where

• `d (g1,g2)` : is a distance function based on maximum common sub graph .
• `g1, g2` are two graphs .
• `mcs (g1,g2)`: is the maximum common sub graph of two graphs g1,g2 where mcs is the largest graph (by some measure involving the number of nodes and edges )contained in both subject graphs .
• `│g1│`: Cardinality of the common induced sub graph g1
• `│g2│`: Cardinality of the common induced sub graph g2

My Question: How can I calculate MCS?
I searched the internet but most of the algorithms are complicated anyone know from where i can get a simple algorithm to program this equation in matlab.

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I'm going to ask what might be a silly question. You mention tracking a fleet of cars in the comments below. Is there any correspondence between the nodes of these graphs that is known beforehand? Something like "node A in both graphs is always the intersection of 4th and Main". –  beaker Feb 1 '13 at 16:21
@ beaker ok the input for the distance function will be a gps data for cars movement i will represent this data as graph each node is the GPs location for the car at a certain time ... i will compare each daily car movement vector with the other car graph in the same day i need mcs to find how much similar is the 2 journey in the same date .... hope the idea is more clear now ..thanks for the help –  user2032084 Feb 4 '13 at 7:59
Knowing that the nodes of each graph represent geographical information reduces the complexity of the problem tremendously. Instead of an exponential search, as in the Clique Problem pointed out by @amit, you can use some distance metric to generate a correspondence between nodes and/or edges in polynomial time. I'll work up an answer with some strategies you can try to move forward, but if you've got any additional information beforehand, for instance a graph representing the map on which these cars move, that would help even more. –  beaker Feb 4 '13 at 19:28
@beaker thanks for the explanation what other details you think its useful to make your suggestion doable cause i tried to search for an efficent algorithm couldnt find one –  user2032084 Feb 27 '13 at 10:03
See my answer below, but here's a quick summary: Ideally you'd like to have a graph representing the map on which all of these routes occur. It would probably make more sense to model sections of road (city blocks, stretches of highway between on/off ramps, etc.) as nodes rather than edges. It would also be helpful to know the frequency of the gps updates, i.e. the number of nodes you can expect to pass through before the next update. –  beaker Feb 27 '13 at 15:07

The problem is NP-Complete1.

The reduction from the Clique Problem2. Given an instance of Clique Problem - a graph `G=(V,E)`, create a complete clique `G'=(V,E')` such that `E' = {(u,v) | u != v, for each u,v in V)`.

The solution to the maximal clique problem is the same solution for the maximal subgraph problem for G and G'. Since clique problem is NP-Hard, so does this problem.

Thus, there is no known polynomial solution to this problem.

If you are looking for an exact algorithm, you could try exhaustive search approach and/or a branch & bound approach to solve it. Sorry for the bad news, but at least you know not to look for something that (probably) doesn't exist (unless P=NP, of course)

EDIT: exponential brute force solution to the problem:
You can just check all possible subsets, and check if it is a feasible solution.
Pseudo Code:

``````findMCS(vertices,G1,G2,currentSubset):
if vertices is empty: //base clause, no more candidates to check
if isCommonSubgraph(G1,G2,currentSubset):
return clone(currentSubset)
else:
return {}
v <- vertices.pop() //take a look at the first element
cand1 <- findMCS(vertices,G1,G2,currentSubset) //find MCS if it is NOT in the subset
currentSubset.append(v)
if isCommonSubgrah(G1,G2,currentSubset): //find MCS if it is in the subset
cand2 <- findMCS(vertices,G1,G2,currentSubset)
currentSubset.remvoe(v) //clean up environment before getting back from recursive call
return (|cand1| > |cand2| ? cand1 : cand2) //return the maximal subset from all candidates
``````

Complexity of the above is `O(2^n)` (checking all possible subsets), and invoke it with: `findMCS(G1.vertices, G1, G2, [])` (where `[]` is an empty list).

Note:

• `isCommonSubgrah(G1,G2,currentSubset)` is an easy to calculate method that just answers true if and only if `currentSubset` is a common subgraph of G1 and G2.
• |cand1| and |cand2| is the sizes of these lists.

(1)Assuming that Maximum sub graph is a subset `U` in `V` such that for each `u1,u2` in `U` `(u1,u2)` is in `E1` if and only if `(u1,u2)` is in `E2` (intuitively, a maximal subset of the vertices that share the exact same edges in the two graphs)

(2) Clique Problem: Given an instance of `G=(V,E)` find maximal subset `U` in `V` such that for each `u1,u2` in `U` : `u1 = u2` or `(u1,u2)` is in `E`.

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i need this to calculate how much is 2 graphs is similar in two trajectories ...so you mean there is no specific algorithm to calculate MCS !!! –  user2032084 Feb 1 '13 at 10:36
@fidam I mean there is no known efficient algorithm to calculate MCS, sorry for the bad news. brute force algorithms that check all subsets will find the maximal common subgraph, but for large graphs will just consume too much time to be feasible I am afraid. –  amit Feb 1 '13 at 10:38
im not concerened on complexity or time consuming i only need an algorithm to calculate the MCS,i just cant find a direct algorithm for mcs –  user2032084 Feb 1 '13 at 10:38
@fidam What is the size of your graph? For larger then 50 nodes a branch and bound solution is just not feasible. –  amit Feb 1 '13 at 10:39
i will use the graph structure to represent one day journy for a certain car movement ...im not expert in graph theory –  user2032084 Feb 1 '13 at 10:41

Not sure if I'm missing something obvious but can't you just:

Iterate through all edges + all vertices of the first graph, check if they are in the second graph, and if so add them to your subgraph?

The subgraph you would get is just the intersection of the two graphs.

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You can't even check if one graph is a subgraph of the other one, it's the subgraph isomorphism problem known to be NP-complete. Hereby you can't find the maximal subgraph because you can't check the isomorphism property (in polynomial time).

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this is only true if you assume that you are actually looking for isomorphic subgraphs, which isn't mentioned in the original question. If the nodes in the graph have 'identity' i.e. that you can check if it is or isn't part of a graph it becomes a completely different problem. –  Jens Schauder Feb 1 '13 at 16:51

The main problem is finding a correspondence between nodes in the original graphs (essentially a renumbering of the vertices). For instance, if we have node p in graph g1 and node q in graph g2 where p and q are equivalent, we'd like to map them to a node s in the common subgraph, c.

The reason that the Clique Problem is so difficult is that, without any way of checking whether two nodes in different graphs actually refer to the same node, we have to try all possible combinations of pairs of nodes and check if each pair is consistent and represents the "best" correspondence.

Since the nodes in these graphs represent geographic locations, we should be able to come up with a reasonable distance metric that tells us how likely it is that a node in one graph is the same as any node in the other graph. Since the GPS coordinates of the two nodes are probably not identical, we need to make some assumptions based on the problem.

• If we have a map of the region in which the data points occur, represented as a graph m, we can renumber or rename the nodes in g1 and g2 to correspond to their closest equivalent in in m.
• Distance (either between the original graphs and m or between points in g1 and g2) can either be the Euclidean distance or the Manhattan distance, depending on what makes more sense for your graphs.
• You'll have to be careful in deciding how far apart two nodes can be and still be considered equivalent. Too small and you won't get any matches; too large and your entire graph could be condensed into one node.
• Two or more nodes in an original graph could possible all map to the same node in c. If the location data is updated frequently in relation to the distance between nodes, for instance.
• Conversely, an edge between a pair of successive nodes in an original graph could also map to a path containing multiple edges if the update frequency is low in relation to the distances. So you'll have to figure out whether it makes sense to introduce these intermediate nodes into the common graph or treat the whole path as a single edge.

Once you've got the renumbering of the nodes you can use the method that Jens suggests to find the intersection of the renumbered graphs. This is all very general since I don't have a lot of details about your specific problem, but hopefully it's enough to get you started.

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