I have a quite simple question, I think. I've got this problem, which can be solved very easily with a recursive function, but which I wasn't able to solve iteratively.

Suppose you have any boolean matrix, like:



I know this is not an ordinary boolean matrix, but it is useful for my example. You can note there is sort of zero-paths in there...

I want to make a function that receives this matrix and a point where a zero is stored and that transforms every zero in the same area into a 2 (suppose the matrix can store any integer even it is initially boolean)

(just like when you paint a zone in Paint or any image editor)

suppose I call the function with this matrix M and the coordinate of the upper right corner zero, the result would be:


well, my question is how to do this iteratively... hope I didn't mess it up too much

Thanks in advance!


ps: I'd appreciate if you could show the function in C, S, python, or pseudo-code, please :D

7 Answers 7


There is a standard technique for converting particular types of recursive algorithms into iterative ones. It is called tail-recursion.

The recursive version of this code would look like (pseudo code - without bounds checking):

paint(cells, i, j) {
   if(cells[i][j] == 0) {
      cells[i][j] = 2;
      paint(cells, i+1, j);
      paint(cells, i-1, j);
      paint(cells, i, j+1);
      paint(cells, i, j-1);

This is not simple tail recursive (more than one recursive call) so you have to add some sort of stack structure to handle the intermediate memory. One version would look like this (pseudo code, java-esque, again, no bounds checking):

paint(cells, i, j) {
    Stack todo = new Stack();
    while(!todo.isEmpty()) {
       (r, c) = todo.pop();
       if(cells[r][c] == 0) {
          cells[r][c] = 2;
          todo.push((r+1, c));
          todo.push((r-1, c));
          todo.push((r, c+1));
          todo.push((r, c-1));              


Input: Startpoint (x,y), Array[w][h], Fillcolor f

Array[x][y] = f
bool hasChanged = false;
  for every Array[x][y] with value f:
    check if the surrounding pixels are 0, if so:
      Change them from 0 to f
      hasChanged = true
until (not hasChanged)

For this I would use a Stack ou Queue object. This is my pseudo-code (python-like):

while stack.size() > 0:
    p = stack.pop()
    matrix[p] = 2
    for each point in Arround(p):
       if matrix[point]==0:
  • Using a stack/queue object is still recursive, you're managing the stack yourself rather than using the programming language to do the housekeeping for you.
    – Skizz
    Jan 19, 2009 at 9:27
  • False. Recursive means a function calling or referencing itself. en.wikipedia.org/wiki/Recursion. I agree with you the compiled code ends up functionally the same, this is not strictly recursive. One justification is that the non-recursive version is parseable in a single pass parser. Jan 19, 2009 at 10:41
  • @Nick: in functional programming, a recursive process is one that uses non-constant space for deferred operations, while an iterative one uses constant space. Thus using a stack or queue is a recursive process (mitpress.mit.edu/sicp/full-text/book/…).
    – outis
    Dec 29, 2009 at 19:28

The easiest way to convert a recursive function into an iterative function is to utilize the stack data structure to store the data instead of storing it on the call stack by calling recursively.

Pseudo code:

var s = new Stack();

s.Push( /*upper right point*/ );

while not s.Empty:

    var p = s.Pop()        
    m[ p.x ][ p.y ] = 2

    s.Push ( /*all surrounding 0 pixels*/ )
  • See comment to ascobol's post - this is still, techinally, recursive.
    – Skizz
    Jan 19, 2009 at 9:28
  • You're using a different definition of "recursive" from everybody else.
    – mqp
    Feb 3, 2009 at 22:41

Not all recursive algorithms can be translated to an iterative algorithm. Normally only linear algorithms with a single branch can. This means that tree algorithm which have two or more branches and 2d algorithms with more paths are extremely hard to transfer into recursive without using a stack (which is basically cheating).



listsum: N* -> N
listsum(n) ==
  if n=[] then 0 
          else hd n + listsum(tl n)


listsum: N* -> N
listsum(n) ==
  res = 0;
  forall i in n do
    res = res + i
  return res


treesum: Tree -> N
treesum(t) ==
  if t=nil then 0
  else let (left, node, right) = t in
    treesum(left) + node + treesum(right)

Partial iteration (try):

treesum: Tree -> N
treesum(t) ==
  res = 0
  while t<>nil 
    let (left, node, right) = t in
      res = res + node + treesum(right)
      t = left
  return res

As you see, there are two paths (left and right). It is possible to turn one of these paths into iteration, but to translate the other into iteration you need to preserve the state which can be done using a stack:

Iteration (with stack):

treesum: Tree -> N
treesum(t) ==
  res = 0

  while not stack.isempty()
    t = stack.pop()
    while t<>nil 
      let (left, node, right) = t in
        res = res + node + treesum(right)
        t = left

  return res

This works, but a recursive algorithm is much easier to understand.


If doing it iteratively is more important than performance, I would use the following algorithm:

  1. Set the initial 2
  2. Scan the matrix for finding a 0 near a 2
  3. If such a 0 is found, change it to 2 and restart the scan in step 2.

This is easy to understand and needs no stack, but is very time consuming.


A simple way to do this iteratively is using a queue.

  1. insert starting point into queue
  2. get first element from queue
  3. set to 2
  4. put all neighbors that are still 0 into queue
  5. if queue is not empty jump to 2.

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