# What algorithm can I use to find the shortest path between specified node types in a graph?

This is the problem:

I have n points (p1, p2, p3, .. pn), each of them can connect to any other with a determined cost x.

Each point belongs to one of a set of point-types (for example "A" "B" "C" "D"...).

The input of the method is the path I want to follow, for example "A-B-C-A-D-B".

The output is the shortest path connecting the points of the type I give in input so for example "p1-p4-p32-p83-p43-p12" where p1 is an A-type, p4 a B-type, p32 a C-type, p83 an A-type, p43 a D-type and p12 a B-type.

The "easy" solution consists of calculating ALL the possible paths but the computational cost is very high!

Can someone find a better algorithm?

As I said in title, I don't know if it exists!

Update:

The key point that prevents me from using Dijkstra and the other similar algorithms is that I have to link the points according to type.

As input I have an array of types and I have to link in that order.

This is an image of Kent Fredric (thanks a lot) which describes the initial situation (in red allowed links)!

A real life example:

A man wants to visit a church in the morning, go to restaurant and finally visit a museum in the afternoon.

In the map there are 6 churchs, 30 restaurants and 4 museums.

He wants that the distance church-rest-museum is the minimum possible.

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I don't understand what you mean exactly. Isn't that just some kind of minimum spanning tree? – Mehrdad Afshari Jul 17 '09 at 12:38
Do you plan on selling anything at any of these points? en.wikipedia.org/wiki/Travelling_salesman_problem – Andrew Hare Jul 17 '09 at 12:39
Wait is it that you can follow only a single node for each letter? – EFraim Jul 17 '09 at 12:49
@EFraim: My impression is that there are multiple nodes of each lettered type. – chaos Jul 17 '09 at 12:52
Andrew Hare: Please tell me that's intended ironically. – RBarryYoung Jul 17 '09 at 13:03

You can use the Floyd–Warshall algorithm. Here's the pseudocode given by WikiPedia:

``````/* Assume a function edgeCost(i,j) which returns the cost of the edge from i to
(infinity if there is none).
Also assume that n is the number of vertices and edgeCost(i,i)=0
*/

int path[][];

/* A 2-dimensional matrix. At each step in the algorithm, path[i][j] is the shortest path
from i to j using intermediate vertices (1..k-1).  Each path[i][j] is initialized to
edgeCost(i,j) or infinity if there is no edge between i and j.
*/

procedure FloydWarshall ()
for k: = 1 to n
for each (i,j) in {1,..,n}2
path[i][j] = min ( path[i][j], path[i][k]+path[k][j] );
``````

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+1 for actually understanding the question. :-) – RBarryYoung Jul 17 '09 at 13:01
Dijkstra's algorithm has better complexity. – niteria Jul 17 '09 at 13:24
I can't see how you want to deal with type constraint. – niteria Jul 17 '09 at 13:29
How can I set the type rule? – Alberto Jul 17 '09 at 13:38

As Jan mentioned, you just need a normal boring shortest path algorithm (like Dijkstra's or Floyd's algorithm); however, you need to transform your input graph so that the output path will respect your path constraint.

Given a path constraint of: A - B - A

Create a new graph `G` and insert all of the vertexes from `A` into `G` with new labels like a_01. Then insert all the vertexes from `B` into `G` and connect the `A` vertexes with the `B` vertexes (edges should be directed towards the newly inserted nodes) copying the costs from the original graph. You then repeat this step with `A` (and any other path components) connecting the newly inserted vertexes to those in `B`. Thus, you create a graph where only the paths that exist satisfy the path constraint. You can then use normal shortest path algorithms.

The key insight is that when you revisit a class you are actually visiting a distinct set of nodes and that you only want edges that connect adjacent classes of nodes.

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this is the same to calculate all the possible paths... – Alberto Jul 17 '09 at 13:17
@Alberto: This is not the same as calculating all possible paths. Just like Djikstra's algorithm isn't calculating all the possible paths in the regular shortest-path problem. It finds the best path without enumerating all the possible paths! Aaron's answer is the correct one. He and niteria (although I don't like the code) are right. The rest are wrong or unclear. – yairchu Jul 18 '09 at 21:07

There are many algorithms that will do better than calculating all the possible paths. Breadth-first search is the basic starting point for the family of algorithms I have in mind, Best-first search is appropriate because you have vertex costs defined, and if you can get more information about your problem space, you may be able to use A* or Dijkstra's algorithm. (In each case, finding the paths from the set of allowed starting nodes.)

Re your edit: Your path constraint (the array of node types you need to satisfy) doesn't prevent you from working with these algorithms; quite the opposite, it helps them all work better. You just need to implement them in a way that allows the path constraint to be incorporated, limiting the vertices available at each step in the search to those that are valid given the constraint.

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+1 for actually understanding the question. :-) – RBarryYoung Jul 17 '09 at 13:01
If you use Dijkstra's algorithm you want to have following tuple in priority queue: (cost_so_far, current_vertex, number_of_vertices_visited). Then when iterating through outcoming edges you just ignore edges that lead to not wanted types according to number_of_vertices_visited. – niteria Jul 17 '09 at 13:19
I can't use A* or Dijkstra. IF I USE BFS IT'S THE SAME OF CALCULATING ALL THE PATHS! – Alberto Jul 17 '09 at 13:24
You can if you follow the advice. – niteria Jul 17 '09 at 13:25
it isn't better, it' exactly the same – Alberto Jul 17 '09 at 13:52

This is how I presently interpret your problem.

Red arrows are me manually tracing the paths that conform to the given ordering constraint.

Costs are not provided, but it is assumed all links incur a cost, and the link costs are different.

If this accurately describes the scenario you are trying to solve, please say so, so that others can better answer the question.

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+1 for pretty pictures! – chaos Jul 17 '09 at 13:22
However, I don't think he has a start node like you depict; rather, if his path constraint starts with A, he starts from the set of A nodes. – chaos Jul 17 '09 at 13:23
very similar BUT if the rule is A-B-C I have to link an A-type point to a B-type to a C-type and STOP!!!! – Alberto Jul 17 '09 at 13:29
oh, I was stating with "..." It was ABC repeat :) – Kent Fredric Jul 17 '09 at 13:33
PERFECT! I'll edit! – Alberto Jul 17 '09 at 14:13

On the revision of your question it seems you ask for one node per letter - in that case it is a simple dynamic programming solution: Calculate all the shortest paths of length 1, which satisfy the beginning of your sequence, between each pair of nodes. Then having for k all such paths for all node pairs, it is trivial to construct for k+1.

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this is the same to calculate all the possible paths... – Alberto Jul 17 '09 at 13:19
...but in a clever way. You reuse results from your earlier computation. – niteria Jul 17 '09 at 13:38

Here is pseudocode with dynamic programming solution:

``````n - length of desired path
m - number of vertices
types[n] // desired type of ith node
vertice_types[m]
d[n][m] // our DP tab initially filled with infinities

d[0][0..m] = 0
for length from 1 to n
for b from 0 to m
if types[length] == vertice_types[b]
for a from 0 to m
if types[length-1] == vertice_types[a]
d[length][b] = min(d[length][b], d[length-1][a] + cost(a,b))
``````

your minimum cost path is min(d[n][0..m])

you can reduce size of d table to 2 rows, but it would obfuscate the solution

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imho it's much better to make your pseudo-code python-style, that is - no endif/endfor noise: indentation matters. congrats for a correct solution. – yairchu Jul 18 '09 at 21:09
ok, edited. It seemed incomplete without end{if,for}. – niteria Jul 19 '09 at 4:14

As far as I understand your question you need a shortest path in a directed graph. http://en.wikipedia.org/wiki/Dijkstra%27s_algorithm should give you an idea.

regards, Jan

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no, thanks for reply but it's different! Please read my (editeed) question better. – Alberto Jul 17 '09 at 13:15
1. Calculate all the pairs of shortest paths within each equivalence block.
2. Now build a graph which has NO inter-class edges, but whose edges between classes match the shortest path within that class, leading to the specific node of another class.

Hope this is clear.

This solution is not particularly efficient, but clearly polynomial.

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+1 for actually understanding the question. (:-)) – RBarryYoung Jul 17 '09 at 13:00
this is the same to calculate all the possible paths... – Alberto Jul 17 '09 at 13:20
@Alberto: No, it is not. – EFraim Jul 31 '09 at 15:09