I've been studying the three and I'm stating my inferences from them below. Could someone tell me if I have understood them accurately enough or not? Thank you.

  1. Dijkstra's algorithm is used only when you have a single source and you want to know the smallest path from one node to another, but fails in cases like this

  2. Floyd-Warshall's algorithm is used when any of all the nodes can be a source, so you want the shortest distance to reach any destination node from any source node. This only fails when there are negative cycles

(this is the most important one. I mean, this is the one I'm least sure about:)

3.Bellman-Ford is used like Dijkstra's, when there is only one source. This can handle negative weights and its working is the same as Floyd-Warshall's except for one source, right?

If you need to have a look, the corresponding algorithms are (courtesy Wikipedia):


 procedure BellmanFord(list vertices, list edges, vertex source)
   // This implementation takes in a graph, represented as lists of vertices
   // and edges, and modifies the vertices so that their distance and
   // predecessor attributes store the shortest paths.

   // Step 1: initialize graph
   for each vertex v in vertices:
       if v is source then v.distance := 0
       else v.distance := infinity
       v.predecessor := null

   // Step 2: relax edges repeatedly
   for i from 1 to size(vertices)-1:
       for each edge uv in edges: // uv is the edge from u to v
           u := uv.source
           v := uv.destination
           if u.distance + uv.weight < v.distance:
               v.distance := u.distance + uv.weight
               v.predecessor := u

   // Step 3: check for negative-weight cycles
   for each edge uv in edges:
       u := uv.source
       v := uv.destination
       if u.distance + uv.weight < v.distance:
           error "Graph contains a negative-weight cycle"


 1  function Dijkstra(Graph, source):
 2      for each vertex v in Graph:                                // Initializations
 3          dist[v] := infinity ;                                  // Unknown distance function from 
 4                                                                 // source to v
 5          previous[v] := undefined ;                             // Previous node in optimal path
 6                                                                 // from source
 8      dist[source] := 0 ;                                        // Distance from source to source
 9      Q := the set of all nodes in Graph ;                       // All nodes in the graph are
10                                                                 // unoptimized - thus are in Q
11      while Q is not empty:                                      // The main loop
12          u := vertex in Q with smallest distance in dist[] ;    // Start node in first case
13          if dist[u] = infinity:
14              break ;                                            // all remaining vertices are
15                                                                 // inaccessible from source
17          remove u from Q ;
18          for each neighbor v of u:                              // where v has not yet been 
19                                                                                 removed from Q.
20              alt := dist[u] + dist_between(u, v) ;
21              if alt < dist[v]:                                  // Relax (u,v,a)
22                  dist[v] := alt ;
23                  previous[v] := u ;
24                  decrease-key v in Q;                           // Reorder v in the Queue
25      return dist;


 1 /* Assume a function edgeCost(i,j) which returns the cost of the edge from i to j
 2    (infinity if there is none).
 3    Also assume that n is the number of vertices and edgeCost(i,i) = 0
 4 */
 6 int path[][];
 7 /* A 2-dimensional matrix. At each step in the algorithm, path[i][j] is the shortest path
 8    from i to j using intermediate vertices (1..k−1).  Each path[i][j] is initialized to
 9    edgeCost(i,j).
10 */
12 procedure FloydWarshall ()
13    for k := 1 to n
14       for i := 1 to n
15          for j := 1 to n
16             path[i][j] = min ( path[i][j], path[i][k]+path[k][j] );
  • Maybe the way the algorithms are written in a textbook makes it look like Dijkstra's is only used for single-source, but these algorithms can be used for multiple source and multiple destination with almost no modification. For Dijkstra's you start by Pushing your source vertex into a priority queue with Distance=0, if you want multiple sources just push all of your sources into it with Distance=0. Alternatively you can add a single vertex with zero-weight edges to all of your source vertices, then use that vertex as your real source. Commented Jul 28, 2012 at 21:29
  • 3
    Exact duplicate of: programmers.stackexchange.com/questions/158613/… Commented Jul 28, 2012 at 21:57

2 Answers 2


You are correct about the first two questions, and about the goal of Floyd-Warshall (finding the shortest paths between all pairs), but not about the relationship between Bellman-Ford and Floyd-Warshall: Both algorithms use dynamic programming to find the shortest path, but FW isn't the same as running BF from each starting node to every other node.

In BF, the question is: What is the shortest path from the source to the target using at most k steps, and the running time is O(EV). If we were to run it to each other node, the running time would be O(EV^2).

In FW, the question is: what is the shortest path from i to j through k, for all nodes i,j,k. This leads to O(V^3) running time - better than BF for each starting node (by a factor of up to |V| for dense graphs).

One more note about negative cycles / weights: Dijkstra may simply fail to give the correct results. BF and FW won't fail - they will correctly state that there is no minimum weight path, since the negative weight is unbounded.

  • 1
    The running time specified for BF and FW are correct but the description of them is reversed. At each stage of FW all vertices between 1 to k are considered as the "through" node. Whereas in BF, the k represents the number of edges k required to get from i to j, not the other way around. Commented Sep 8, 2014 at 17:29

Single source shortest paths:

Dijkstra Algorithm - No negative weight allowed - O(E+Vlg(V))

Bellman ford Algorithm - Negative weight is allowed. But if a negative cycle is present Bellman ford will detect the -ve cycle - O(VE)

Directed Acyclic Graph - as name suggests it works only for DAG - O(V+E)

All pairs shortest paths:

Dijkstra Algorithm - No negative weight allowed - O(VE + V^2lg(V))

Bellman ford Algorithm - O(V^2E)

Matrix chain multiplication method -complexity same as Bellman ford algorithm

Floyd Warshall algorithm -uses dynamic programming method - Complexity is O(V^3)


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