# recursion versus iteration

Is it correct to say that everywhere `recursion` is used a for loop could be used? And if recursion is usually slower what is the technical reason for ever using it over for loop iteration?

And if it is always possible to convert an recursion into a for loop is there a rule of thumb way to do it?

• `recursion` vs `iteration`? `iteration = for loop` I think. – gongzhitaao Mar 28 '13 at 17:13
• Tom Moertel's blog has four excellent posts on converting recursive code to iterative code: blog.moertel.com/tags/recursion.html – cjohnson318 Jul 24 '15 at 16:30

Recursion is usually much slower because all function calls must be stored in a stack to allow the return back to the caller functions. In many cases, memory has to be allocated and copied to implement scope isolation.

Some optimizations, like tail call optimization, make recursions faster but aren't always possible, and aren't implemented in all languages.

The main reasons to use recursion are

• that it's more intuitive in many cases when it mimics our approach of the problem
• that some data structures like trees are easier to explore using recursion (or would need stacks in any case)

Of course every recursion can be modeled as a kind of loop : that's what the CPU will ultimately do. And the recursion itself, more directly, means putting the function calls and scopes in a stack. But changing your recursive algorithm to a looping one might need a lot of work and make your code less maintainable : as for every optimization, it should only be attempted when some profiling or evidence showed it to be necessary.

• To add on it - recursion is closely related to the term of reduction which plays a central role in many algorithms and in CS in general. – SomeWittyUsername Mar 28 '13 at 17:19
• Can you please provide me an example where recursion makes the code more maintainable? In my experience, it is always the other way around. Thank you – Yeikel Feb 3 '18 at 4:36
• @Yeikel Write a function `f(n)` that returns the nth Fibonacci number. – Matt Feb 19 at 23:49

Is it correct to say that everywhere recursion is used a for loop could be used?

Yes, because recursion in most CPUs is modeled with loops and a stack data structure.

And if recursion is usually slower what is the technical reason for using it?

It is not "usually slower": it's recursion that is applied incorrectly that's slower. On top of that, modern compilers are good at converting some recursions to loops without even asking.

And if it is always possible to convert an recursion into a for loop is there a rule of thumb way to do it?

Write iterative programs for algorithms best understood when explained iteratively; write recursive programs for algorithms best explained recursively.

For example, searching binary trees, running quicksort, and parsing expressions in many programming languages is often explained recursively. These are best coded recursively as well. On the other hand, computing factorials and calculating Fibonacci numbers are much easier to explain in terms of iterations. Using recursion for them is like swatting flies with a sledgehammer: it is not a good idea, even when the sledgehammer does a really good job at it+.

+ I borrowed the sledgehammer analogy from Dijkstra's "Discipline of Programming".

• Recursion is usually more expensive (slower / more memory), because of creating stack frames and such. The difference may be small when applied correctly for a sufficiently complex problem, but it's still more expensive. There are possible exceptions such as tail recursion optimization. – Dukeling Mar 28 '13 at 17:17
• I'm not sure about a single for loop in every case. Consider a more complex recursion or a recursion with more than single variable – SomeWittyUsername Mar 28 '13 at 17:18
• @icepack You are right, "loops" should be plural. Thanks! – dasblinkenlight Mar 28 '13 at 17:21
• @dasblinkenlight It might be theoretically possible to reduce multiple loops to a single one, but not sure about this. – SomeWittyUsername Mar 28 '13 at 17:22
• @icepack Yes, it is possible. It may not be pretty, but it's possible. – Dukeling Mar 28 '13 at 17:23

# Question :

And if recursion is usually slower what is the technical reason for ever using it over for loop iteration?

Because in some algorithms are hard to solve it iteratively. Try to solve depth-first search in both recursively and iteratively. You will get the idea that it is plain hard to solve DFS with iteration.

Another good thing to try out : Try to write Merge sort iteratively. It will take you quite some time.

# Question :

Is it correct to say that everywhere recursion is used a for loop could be used?

Yes. This thread has a very good answer for this.

# Question :

And if it is always possible to convert an recursion into a for loop is there a rule of thumb way to do it?

Trust me. Try to write your own version to solve depth-first search iteratively. You will notice that some problems are easier to solve it recursively.

Hint : Recursion is good when you are solving a problem that can be solved by divide and conquer technique.

• I appreciate the attempt at providing an authoritative answer and I'm sure the author is intelligent but "trust me" isn't a helpful response to a meaningful question whose answer is not immediately obvious. There are very straightforward algorithms for doing an iterative depth-first search. See the example at the bottom of this page for a description of an algorithm in pseudocode: csl.mtu.edu/cs2321/www/newLectures/26_Depth_First_Search.html – jdelman Feb 21 '18 at 15:53

Besides being slower, recursion can also result in stack overflow errors depending on how deep it goes.

To write an equivalent method using iteration, we must explicitly use a stack. The fact that the iterative version requires a stack for its solution indicates that the problem is difficult enough that it can benefit from recursion. As a general rule, recursion is most suitable for problems that cannot be solved with a fixed amount of memory and consequently require a stack when solved iteratively. Having said that, recursion and iteration can show the same outcome while they follow different pattern.To decide which method works better is case by case and best practice is to choose based on the pattern that problem follows.

For example, to find the nth triangular number of Triangular sequence: 1 3 6 10 15 … A program that uses an iterative algorithm to find the n th triangular number:

Using an iterative algorithm:

``````//Triangular.java
import java.util.*;
class Triangular {
public static int iterativeTriangular(int n) {
int sum = 0;
for (int i = 1; i <= n; i ++)
sum += i;
return sum;
}
public static void main(String args[]) {
Scanner stdin = new Scanner(System.in);
System.out.print("Please enter a number: ");
int n = stdin.nextInt();
System.out.println("The " + n + "-th triangular number is: " +
iterativeTriangular(n));
}
}//enter code here
``````

Using a recursive algorithm:

``````//Triangular.java
import java.util.*;
class Triangular {
public static int recursiveTriangular(int n) {
if (n == 1)
return 1;
return recursiveTriangular(n-1) + n;
}

public static void main(String args[]) {
Scanner stdin = new Scanner(System.in);
System.out.print("Please enter a number: ");
int n = stdin.nextInt();
System.out.println("The " + n + "-th triangular number is: " +
recursiveTriangular(n));
}
}
``````

Most of the answers seem to assume that `iterative` = `for loop`. If your for loop is unrestricted (a la C, you can do whatever you want with your loop counter), then that is correct. If it's a real `for` loop (say as in Python or most functional languages where you cannot manually modify the loop counter), then it is not correct.

All (computable) functions can be implemented both recursively and using `while` loops (or conditional jumps, which are basically the same thing). If you truly restrict yourself to `for loops`, you will only get a subset of those functions (the primitive recursive ones, if your elementary operations are reasonable). Granted, it's a pretty large subset which happens to contain every single function you're likely to encouter in practice.

What is much more important is that a lot of functions are very easy to implement recursively and awfully hard to implement iteratively (manually managing your call stack does not count).

Yes, as said by Thanakron Tandavas,

Recursion is good when you are solving a problem that can be solved by divide and conquer technique.

For example: Towers of Hanoi

1. N rings in increasing size
2. 3 poles
3. Rings start stacked on pole 1. Goal is to move rings so that they are stacked on pole 3 ...But
• Can only move one ring at a time.
• Can’t put larger ring on top of smaller.
4. Iterative solution is “powerful yet ugly”; recursive solution is “elegant”.
• An interesting example. I guess you know the paper by M.C. Er "The Towers of Hanoi and Binary Numerals". Also treated in a fantastic video by 3brown1blue. – Andrestand Jul 18 at 14:32

I seem to remember my computer science professor say back in the day that all problems that have recursive solutions also have iterative solutions. He says that a recursive solution is usually slower, but they are frequently used when they are easier to reason about and code than iterative solutions.

However, in the case of more advanced recursive solutions, I don't believe that it will always be able to implement them using a simple `for` loop.

• It is always possible to convert a recursive algorithm to an iterative one (using stacks). You might not end up with a particularly simple loop, but it is possible. – Dukeling Apr 22 '17 at 0:54

A lot of good reasons have been given and I would like to share one more point. Some of the problems are beautifully solved by recursion rather can only be solved by recursion. A sample example would be:

Print all the values of an array but the items of an array could be arrays as well. There could be nested arrays as well but we are not sure about the depth of nested arrays.

A beautiful solution would be this:

``````<?php
function print_all_items(\$array){

foreach(\$array as \$key=>\$value){
if(is_array(\$value)) {
print_all_items(\$value);
}
else{
echo "\$key => \$value <br/>";
}
}
}

\$array = array("first" => "first value",
"second" => "second value",
"third" => "third value",
"fourth"=>array(1,2,3,4,5),
"fifth"=>array(
"second array 1",
"second array 2",
"second array 3",
array(
"third array 1",
"third array 2",
"third array 3",
)
),
);

print_all_items(\$array);
``````

Output:

``````first => first value
second => second value
third => third value
0 => 1
1 => 2
2 => 3
3 => 4
4 => 5
0 => second array 1
1 => second array 2
2 => second array 3
0 => third array 1
1 => third array 2
2 => third array 3
``````

Now this kind of problem cannot be solved by `iterative approach` since the nature of problems demands dynamic solution.

• There is NO problem that cannot be solved by iterative approach given that it can be solved by recursion. It has been formally proven long ago and this fact is taught in all decent CS university programs. You have limited yourself to the 'foreach' construct, which is a simplified syntax for regular 'for' loops and therefore cannot fully represent iterative approach. – alkoln Apr 11 at 22:14
• can you tell me iterative approach to solve these kind of problems?@alkoln – Danyal Sandeelo Apr 14 at 9:23
• `Can you always turn a recursive function into an iterative one? Yes, absolutely, and the Church-Turing thesis proves it if memory serves. In lay terms, it states that what is computable by recursive functions is computable by an iterative model (such as the Turing machine) and vice versa. The thesis does not tell you precisely how to do the conversion, but it does say that it's definitely possible.` – Danyal Sandeelo Apr 14 at 9:25
• The iterative approach would be to save a pointer to a current element into a stack structure each time you start processing a nested array, and retrieve the last saved pointer when you're done. – alkoln Apr 15 at 22:30

recursion + memorization could lead to a more efficient solution compare with a pure iterative approach, e.g. check this: http://jsperf.com/fibonacci-memoized-vs-iterative-for-large-n

• Any recursive code can be converted to functionally identical iterative code using stacks. The difference you're showing is the difference between two approaches to solve the same problem, not the difference between recursion and iteration. – Dukeling Apr 22 '17 at 0:45

Short answer: the trade off is recursion is faster and for loops take up less memory in almost all cases. However there are usually ways to change the for loop or recursion to make it run faster