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I'm trying to implement an iterative version of Tarjan's strongly connected components (SCCs), reproduced here for your convenience (source:

Input: Graph G = (V, E)

index = 0                         // DFS node number counter 
S = empty                         // An empty stack of nodes
forall v in V do
  if (v.index is undefined)       // Start a DFS at each node
    tarjan(v)                     // we haven't visited yet

procedure tarjan(v)
  v.index = index                 // Set the depth index for v
  v.lowlink = index
  index = index + 1
  S.push(v)                       // Push v on the stack
  forall (v, v') in E do          // Consider successors of v
    if (v'.index is undefined)    // Was successor v' visited?
        tarjan(v')                // Recurse
        v.lowlink = min(v.lowlink, v'.lowlink)
    else if (v' is in S)          // Was successor v' in stack S? 
        v.lowlink = min(v.lowlink, v'.lowlink )
  if (v.lowlink == v.index)       // Is v the root of an SCC?
    print "SCC:"
      v' = S.pop
      print v'
    until (v' == v)

My iterative version uses the following Node struct.

struct Node {
    int id; //Signed int up to 2^31 - 1 = 2,147,483,647
    int index;
    int lowlink;        
    Node *caller;                    //If you were looking at the recursive version, this is the node before the recursive call
    unsigned int vindex;             //Equivalent to the iterator in the for-loop in tarjan
    vector<Node *> *nodeVector;      //Vector of adjacent Nodes 

Here's what I did for the iterative version:

 void Graph::runTarjan(int out[]) {  //You can ignore out. It's a 5-element array that keeps track of the largest 5 SCCs
        int index = 0;
tarStack = new stack<Node *>();
    onStack = new bool[numNodes];
  for (int n = 0; n < numNodes; n++) {
    if (nodes[n].index == unvisited) {
      tarjan_iter(&nodes[n], index);

void Graph::tarjan_iter(Node *u, int &index) {
    u->index = index;
    u->lowlink = index;
    u->vindex = 0; 
    u->caller = NULL;           //Equivalent to the node from which the recursive call would spawn.
    onStack[u->id - 1] = true;
    Node *last = u;
    while(true) {
        if(last->vindex < last->nodeVector->size()) {       //Equivalent to the check in the for-loop in the recursive version
            Node *w = (*(last->nodeVector))[last->vindex];
            last->vindex++;                                   //Equivalent to incrementing the iterator in the for-loop in the recursive version
            if(w->index == unvisited) {
                w->caller = last;                     
                w->vindex = 0;
                w->index = index;
                w->lowlink = index;
                onStack[w->id - 1] = true;
                last = w;
            } else if(onStack[w->id - 1] == true) {
                last->lowlink = min(last->lowlink, w->index);
        } else {  //Equivalent to the nodeSet iterator pointing to end()
            if(last->lowlink == last->index) {
                Node *top = tarStack->top();
                onStack[top->id - 1] = false;
                int size = 1;

                while(top->id != last->id) {
                    top = tarStack->top();
                    onStack[top->id - 1] = false;
                insertNewSCC(size);  //Ranks the size among array of 5 elements

            Node *newLast = last->caller;   //Go up one recursive call
            if(newLast != NULL) {
                newLast->lowlink = min(newLast->lowlink, last->lowlink);
                last = newLast;
            } else {   //We've seen all the nodes

My iterative version runs and gives me the same output as the recursive version. The problem is that the iterative version is slower, and I'm not sure why. Can anyone give me some insight on my implementation? Is there a better way to implement the recursive algorithm iteratively?

share|improve this question
Can you post actual code please instead of semi-pseudocode? It's probably an implementation issue. It looks like you might be doing a lot of unnecessary copies, but I can't tell because you've transformed your actual code into pseudocode. – Peter Alexander Feb 18 '10 at 21:20
I've added the actual code per your request! :) – user5243421 Feb 18 '10 at 21:34
How much slower? – Emile Cormier Feb 18 '10 at 21:51
On some of the larger graphs, it runs 20% slower. – user5243421 Feb 18 '10 at 22:09
up vote 11 down vote accepted

A recursive algorithm uses the stack as storage area. In the iterative version, you use some vectors, which themselves rely on heap allocation. Stack-based allocation is known to be very fast, since it is only a matter of moving an end-of-stack pointer, whereas heap allocation may be substantially slower. That the iterative version is slower is not fully surprising.

Generally speaking, if the problem at hand fits well within a stack-only recursive model, then, by all means, recurse.

share|improve this answer
+1. Just make sure it fits on the stack :) – Billy ONeal Feb 18 '10 at 21:38
@mathee, If you want to support arbitrary data sizes, you will hit the limit eventually. Thus the comments a la "if it fits on the stack". – Georg Fritzsche Feb 18 '10 at 21:53
It looks like your iterative code uses an "artificial stack". As such it should have the same computational complexity and memory coherency as the recursive algorithm. To optimise it, I would use a conventional profiling approach to find out if there are any unexpected hotspots. – Chromatix Apr 3 '10 at 6:06
This algo is supposed to be linear in terms of # of nodes and edges. I would call that fast. Are you doing something wrong perhaps? – Hamish Grubijan Aug 7 '10 at 14:08

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