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One of the topics that seems to come up regularly on mailing lists and online discussions is the merits (or lack thereof) of doing a Computer Science Degree. An argument that seems to come up time and again for the negative party is that they have been coding for some number of years and they have never used recursion.

So the question is:

  1. What is recursion?
  2. When would I use recursion?
  3. Why don't people use recursion?
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9  
And maybe this helps: stackoverflow.com/questions/126756/… –  kennytm May 4 '10 at 11:28

40 Answers 40

Recursion in computing is a technique used to compute a result or side effect following the normal return from a single function (method, procedure or block) invocation.

The recursive function, by definition must have the ability to invoke itself either directly or indirectly (through other functions) depending on an exit condition or conditions not being met. If an exit condition is met the particular invocation returns to it's caller. This continues until the initial invocation is returned from, at which time the desired result or side effect will be available.

As an example, here's a function to perform the Quicksort algorithm in Scala (copied from the Wikipedia entry for Scala)

def qsort: List[Int] => List[Int] = {
  case Nil => Nil
  case pivot :: tail =>
    val (smaller, rest) = tail.partition(_ < pivot)
    qsort(smaller) ::: pivot :: qsort(rest)
}

In this case the exit condition is an empty list.

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A great many problems can be thought of in two types of pieces:

  1. Base cases, which are elementary things that you can solve by just looking at them, and
  2. Recursive cases, which build a bigger problem out of smaller pieces (elementary or otherwise).

So what's a recursive function? Well, that's where you have a function that is defined in terms of itself, directly or indirectly. OK, that sounds ridiculous until you realize that it is sensible for the problems of the kind described above: you solve the base cases directly and deal with the recursive cases by using recursive calls to solve the smaller pieces of the problem embedded within.

The truly classic example of where you need recursion (or something that smells very much like it) is when you're dealing with a tree. The leaves of the tree are the base case, and the branches are the recursive case. (In pseudo-C.)

struct Tree {
    int leaf;
    Tree *leftBranch;
    Tree *rightBranch;
};

The simplest way of printing this out in order is to use recursion:

function printTreeInOrder(Tree *tree) {
    if (tree->leftBranch) {
        printTreeInOrder(tree->leftBranch);
    }
    print(tree->leaf);
    if (tree->rightBranch) {
        printTreeInOrder(tree->rightBranch);
    }
}

It's dead easy to see that that's going to work, since it's crystal clear. (The non-recursive equivalent is quite a lot more complex, requiring a stack structure internally to manage the list of things to process.) Well, assuming that nobody's done a circular connection of course.

Mathematically, the trick to showing that recursion is tamed is to focus on finding a metric for the size of the arguments. For our tree example, the easiest metric is the maximum depth of the tree below the current node. At leaves, it's zero. At a branch with only leaves below it, it's one, etc. Then you can simply show that there's strictly ordered sequence on the size of the arguments that the function is invoked on in order to process the tree; the arguments to the recursive calls are always "lesser" in the sense of the metric than the argument to the overall call. With a strictly decreasing cardinal metric, you're sorted.

It's also possible to have infinite recursion. That's messy and in many languages won't work because the stack blows up. (Where it does work, the language engine must be determining that the function somehow doesn't return and is able therefore to optimize away the keeping of the stack. Tricky stuff in general; tail-recursion is just the most trivial way of doing this.)

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Recursion is when you have an operation that uses itself. It probably will have a stopping point, otherwise it would go on forever.

Let's say you want to look up a word in the dictionary. You have an operation called "look-up" at your disposal.

Your friend says "I could really spoon up some pudding right now!" You don't know what he means, so you look up "spoon" in the dictionary, and it reads something like this:

Spoon: noun - a utensil with a round scoop at the end. Spoon: verb - to use a spoon on something Spoon: verb - to cuddle closely from behind

Now, being that you're really not good with English, this points you in the right direction, but you need more info. So you select "utensil" and "cuddle" to look up for some more information.

Cuddle: verb - to snuggle Utensil: noun - a tool, often an eating utensil

Hey! You know what snuggling is, and it has nothing to do with pudding. You also know that pudding is something you eat, so it makes sense now. Your friend must want to eat pudding with a spoon.

Okay, okay, this was a very lame example, but it illustrates (perhaps poorly) the two main parts of recursion. 1) It uses itself. In this example, you haven't really looked up a word meaningfully until you understand it, and that might mean looking up more words. This brings us to point two, 2) It stops somewhere. It has to have some kind of base-case. Otherwise, you'd just end up looking up every word in the dictionary, which probably isn't too useful. Our base-case was that you got enough information to make a connection between what you previously did and did not understand.

The traditional example that's given is factorial, where 5 factorial is 1*2*3*4*5 (which is 120). The base case would be 0 (or 1, depending). So, for any whole number n, you do the following

is n equal to 0? return 1 otherwise, return n * (factorial of n-1)

let's do this with the example of 4 (which we know ahead of time is 1*2*3*4 = 24).

factorial of 4 ... is it 0? no, so it must be 4 * factorial of 3 but what's factorial of 3? it's 3 * factorial of 2 factorial of 2 is 2 * factorial of 1 factorial of 1 is 1 * factorial of 0 and we KNOW factorial of 0! :-D it's 1, that's the definition factorial of 1 is 1 * factorial of 0, which was 1... so 1*1 = 1 factorial of 2 is 2 * factorial of 1, which was 1... so 2*1 = 2 factorial of 3 is 3 * factorial of 2, which was 2... so 3*2 = 6 factorial of 4 (finally!!) is 4 * factorial of 3, which was 6... 4*6 is 24

Factorial is a simple case of "base case, and uses itself".

Now, notice we were still working on factorial of 4 the entire way down... If we wanted factorial of 100, we'd have to go all the way down to 0... which might have a lot of overhead to it. In the same manner, if we find an obscure word to look up in the dictionary, it might take looking up other words and scanning for context clues until we find a connection we're familiar with. Recursive methods can take a long time to work their way through. However, when they're used correctly, and understood, they can make complicated work surprisingly simple.

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The simplest definition of recursion is "self-reference". A function that refers to itself, i. e. calls itself is recursive. The most important thing to keep in mind, is that a recursive function must have a "base case", i. e. a condition that if true causes it not to call itself, and thus terminate the recursion. Otherwise you will have infinite recursion:

recursion

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1  
Let's not forget the concept of mutual recursion, where one function calls another which, in turn, calls the first. (But that, of course, is going beyond the scope of the original question.) –  RobH May 4 '10 at 19:25

Recursion is technique of defining a function, a set or an algorithm in terms of itself.

For example

n! = n(n-1)(n-2)(n-3)...........*3*2*1

Now it can be defined recursively as:-

n! = n(n-1)!   for n>=1

In programming terms, when a function or method calls itself repeatedly, until some specific condition gets satisfied, this process is called Recursion. But there must be a terminating condition and function or method must no enter into an infinite loop.

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I have created a recursive function to concatenate a list of strings with a separator between them. I use it mostly to create SQL expressions, by passing a list of fields as the 'items' and a 'comma+space' as the separator. Here's the function (It uses some Borland Builder native data types, but can be adapted to fit any other environment):

String ArrangeString(TStringList* items, int position, String separator)
{
String result;

result = items->Strings[position];

if (position <= items->Count)
result += separator + ArrangeString(items, position + 1, separator);

return result;
}

I call it this way:

String columnsList;
columnsList = ArrangeString(columns, 0, ", ");

Imagine you have an array named 'fields' with this data inside it: 'albumName', 'releaseDate', 'labelId'. Then you call the function:

ArrangeString(fields, 0, ", ");

As the function starts to work, the variable 'result' receives the value of the position 0 of the array, which is 'albumName'.

Then it checks if the position it's dealing with is the last one. As it isn't, then it concatenates the result with the separator and the result of a function, which, oh God, is this same function. But this time, check it out, it call itself adding 1 to the position.

ArrangeString(fields, 1, ", ");

It keeps repeating, creating a LIFO pile, until it reaches a point where the position being dealt with IS the last one, so the function returns only the item on that position on the list, not concatenating anymore. Then the pile is concatenated backwards.

Got it? If you don't, I have another way to explain it. :o)

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Actually the better recursive solution for factorial should be:

int factorial_accumulate( int n, int accum ) {
    return ( n < 2 ? accum : factorial_accumulate( n - 1, n * accum ) );
}
int factorial( int n ) {
    return factorial_accumulate( n, 1 );
}

Because this version is Tail Recursive

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I use recursion. What does that have to do with having a CS degree... (which I don't, by the way)

Common uses I have found:

  1. sitemaps - recurse through filesystem starting at document root
  2. spiders - crawling through a website to find email address, links, etc.
  3. ?
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This is an old question, but I want to add an answer from logistical point of view (i.e not from algorithm correctness point of view or performance point of view).

I use Java for work, and Java doesn't support nested function. As such, if I want to do recursion, I might have to define an external function (which exists only because my code bumps against Java's bureaucratic rule), or I might have to refactor the code altogether (which I really hate to do).

Thus, I often avoid recursion, and use stack operation instead, because recursion itself is essentially a stack operation.

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1.) A method is recursive if it can call itself; either directly:

void f() {
   ... f() ... 
}

or indirectly:

void f() {
    ... g() ...
}

void g() {
   ... f() ...
}

2.) When to use recursion

Q: Does using recursion usually make your code faster? 
A: No.
Q: Does using recursion usually use less memory? 
A: No.
Q: Then why use recursion? 
A: It sometimes makes your code much simpler!

3.) People use recursion only when it is very complex to write iterative code. For example, tree traversal techniques like preorder, postorder can be made both iterative and recursive. But usually we use recursive because of its simplicity.

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