# Shortest Path Algorithms: Dynamic Programming vs Dijkstra's algorithm

Running shortest path algorithm on a Directed Acyclic Graph (DAG) via dynamic programming which uses memoization has a runtime complexity of O(V + E) which can be verified using the following equation:

d(s,v) = min{ d(s,u) + w(u,v) }, over all vertices u->v


Now, Dijkstra's algorithm also requires the graph to be directed. And the algorithm has a runtime complexity of O(E + V.log(V)) using min priority queues and this is clearly slower than the memoized version of DP.

According to wiki:

This is asymptotically the fastest known single-source shortest-path algorithm for arbitrary directed graphs with unbounded non-negative weights.

Am I missing something here? I am just not able to digest the contradiction here..

• From what I gather the dp algorithm you describe is Bellman Ford which is slower than Dijkstra's but can handle arbitrary graphs with no negative cycles. The runtime is O(VE). Please verify you haven't muddled up your analysis. – ldog Jan 26 '15 at 6:41
• No, the analysis of the DP algorithm is correct if you consider the memoization bit. Since we have only O(E) subproblems, the overall complexity will turn out to be O(E+V). – Sankalp Jan 26 '15 at 6:43
• You need to run your algorithm O(V) times in the worst case each with worst case O(E) sub problems hence the runtime of O(VE). Please see the analysis of bellman ford on Wikipedia to see what I mean. – ldog Jan 26 '15 at 6:46
• @ldog: You are barking up the wrong algorithm :D He's talking about Topological sorting, not about Bellman-Ford. – Amadan Jan 26 '15 at 6:49