# iterative version of recursive algorithm to make a binary tree

Given this algorithm, I would like to know if there exists an iterative version. Also, I want to know if the iterative version can be faster.

This some kind of pseudo-python...

the algorithm returns a reference to root of the tree

``````make_tree(array a)
if len(a) == 0
return None;

node = pick a random point from the array
calculate distances of the point against the others
calculate median of such distances
node.left = make_tree(subset of the array, such that the distance of points is lower to the median of distances)
node.right = make_tree(subset, such the distance is greater or equal to the median)
return node
``````
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–  outis Jun 20 '12 at 22:47

A recursive function with only one recursive call can usually be turned into a tail-recursive function without too much effort, and then it's trivial to convert it into an iterative function. The canonical example here is factorial:

``````# naïve recursion
def fac(n):
if n <= 1:
return 1
else:
return n * fac(n - 1)

# tail-recursive with accumulator
def fac(n):
def fac_helper(m, k):
if m <= 1:
return k
else:
return fac_helper(m - 1, m * k)
return fac_helper(n, 1)

# iterative with accumulator
def fac(n):
k = 1
while n > 1:
n, k = n - 1, n * k
return k
``````

However, your case here involves two recursive calls, and unless you significantly rework your algorithm, you need to keep a stack. Managing your own stack may be a little faster than using Python's function call stack, but the added speed and depth will probably not be worth the complexity. The canonical example here would be the Fibonacci sequence:

``````# naïve recursion
def fib(n):
if n <= 1:
return 1
else:
return fib(n - 1) + fib(n - 2)

# tail-recursive with accumulator and stack
def fib(n):
def fib_helper(m, k, stack):
if m <= 1:
if stack:
m = stack.pop()
return fib_helper(m, k + 1, stack)
else:
return k + 1
else:
stack.append(m - 2)
return fib_helper(m - 1, k, stack)
return fib_helper(n, 0, [])

# iterative with accumulator and stack
def fib(n):
k, stack = 0, []
while 1:
if n <= 1:
k = k + 1
if stack:
n = stack.pop()
else:
break
else:
stack.append(n - 2)
n = n - 1
return k
``````

Now, your case is a lot tougher than this: a simple accumulator will have difficulties expressing a partly-built tree with a pointer to where a subtree needs to be generated. You'll want a zipper -- not easy to implement in a not-really-functional language like Python.

-

Making an iterative version is simply a matter of using your own stack instead of the normal language call stack. I doubt the iterative version would be faster, as the normal call stack is optimized for this purpose.

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Ahh...just beat me :) –  Mike Brown Oct 25 '08 at 4:01

The data you're getting is random so the tree can be an arbitrary binary tree. For this case, you can use a threaded binary tree, which can be traversed and built w/o recursion and no stack. The nodes have a flag that indicate if the link is a link to another node or how to get to the "next node".

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Depending on how you define "iterative", there is another solution not mentioned by the previous answers. If "iterative" just means "not subject to a stack overflow exception" (but "allowed to use 'let rec'"), then in a language that supports tail calls, you can write a version using continuations (rather than an "explicit stack"). The F# code below illustrates this. It is similar to your original problem, in that it builds a BST out of an array. If the array is shuffled randomly, the tree is relatively balanced and the recursive version does not create too deep a stack. But turn off shuffling, and the tree gets unbalanced, and the recursive version stack-overflows whereas the iterative-with-continuations version continues along happily.

``````#light
open System

let printResults = false
let MAX = 20000
let shuffleIt = true

// handy helper function
let rng = new Random(0)
let shuffle (arr : array<'a>) = // '
let n = arr.Length
for x in 1..n do
let i = n-x
let j = rng.Next(i+1)
let tmp = arr.[i]
arr.[i] <- arr.[j]
arr.[j] <- tmp

// Same random array
let sampleArray = Array.init MAX (fun x -> x)
if shuffleIt then
shuffle sampleArray

if printResults then
printfn "Sample array is %A" sampleArray

// Tree type
type Tree =
| Node of int * Tree * Tree
| Leaf

// MakeTree1 is recursive
let rec MakeTree1 (arr : array<int>) lo hi =  // [lo,hi)
if lo = hi then
Leaf
else
let pivot = arr.[lo]
// partition
let mutable storeIndex = lo + 1
for i in lo + 1 .. hi - 1 do
if arr.[i] < pivot then
let tmp = arr.[i]
arr.[i] <- arr.[storeIndex]
arr.[storeIndex] <- tmp
storeIndex <- storeIndex + 1
Node(pivot, MakeTree1 arr (lo+1) storeIndex, MakeTree1 arr storeIndex hi)

// MakeTree2 has all tail calls (uses continuations rather than a stack, see
// for more explanation)
let MakeTree2 (arr : array<int>) lo hi =  // [lo,hi)
let rec MakeTree2Helper (arr : array<int>) lo hi k =
if lo = hi then
k Leaf
else
let pivot = arr.[lo]
// partition
let storeIndex = ref(lo + 1)
for i in lo + 1 .. hi - 1 do
if arr.[i] < pivot then
let tmp = arr.[i]
arr.[i] <- arr.[!storeIndex]
arr.[!storeIndex] <- tmp
storeIndex := !storeIndex + 1
MakeTree2Helper arr (lo+1) !storeIndex (fun lacc ->
MakeTree2Helper arr !storeIndex hi (fun racc ->
k (Node(pivot,lacc,racc))))
MakeTree2Helper arr lo hi (fun x -> x)

// MakeTree2 never stack overflows
printfn "calling MakeTree2..."
let tree2 = MakeTree2 sampleArray 0 MAX
if printResults then
printfn "MakeTree2 yields"
printfn "%A" tree2

// MakeTree1 might stack overflow
printfn "calling MakeTree1..."
let tree1 = MakeTree1 sampleArray 0 MAX
if printResults then
printfn "MakeTree1 yields"
printfn "%A" tree1

printfn "Trees are equal: %A" (tree1 = tree2)
``````
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Might want to warn: Instead of running out of stack space, you might run out of heap space because `k` has grown too large -- and it's really the same thing! +1 because continuation-passing style is easier than managing your own stack for this problem. Unfortunately, Python makes CPS hard. –  ephemient Oct 25 '08 at 20:53
This is true of every solution. All the solutions that say "use your own stack" also may run out of heap space. I wouldn't say it's "the same thing" since, while both stack and heap are finite, on most systems stack is much much smaller. All recursion->iteration transforms trade stack for heap. –  Brian Oct 25 '08 at 21:21
I mentioned it because keeping a real `stack` gives you an obvious sense of the amount of space it consumes, while a continuation kind of silently closes over everything it captures. But yes, heap space is generally much more abundant than (call)stack space. –  ephemient Oct 28 '08 at 18:53
True; continuations make the allocation less obvious/apparent. –  Brian Oct 29 '08 at 5:46