# How does recursion work in C?

I'm trying to understand how recursion works in C. Can anyone give me an explanation of the control flow?

#include <stdio.h>
/* printd: print n in decimal */
void printd(int n)
{
if (n < 0)
{
putchar('-');
n = -n;
}
if (n / 10) printd(n / 10);
putchar(n % 10 + '0');
}

int main()
{
printd(123);
return 0;
}
-
Try to run it ? –  stefan Mar 30 '11 at 22:41
–  Mehrdad Mar 30 '11 at 22:43
Additionally, run it through a debugger and you'll see for yourself. –  nil Mar 30 '11 at 22:43
To understand recursion you must first understand recursion –  pmg Mar 30 '11 at 22:47
To understand recursion, see related post. –  tomlogic Mar 30 '11 at 23:25

The control flow looks like this (where -> is a function call)

main()
└─> printd(123)
├─> printd(12)
│    ├─> printd(1)
│    │    └─> putchar('1')
│    └─> putchar('2')
└─> putchar('3')
-
did you draw that by hand? –  Carl Norum Mar 30 '11 at 22:47
@Carl: straight into the browser... the legacy of a youth partially misspent in 80x25 text mode. –  caf Mar 30 '11 at 22:50
shucks, I was hoping for a nifty code analysis tool to learn more about... ;-) –  Carl Norum Mar 30 '11 at 22:50
This is beautiful. :o –  nil Mar 31 '11 at 0:15
Call printd(123)
(123 / 10) != 0, so Call printd(12)
(12 / 10) != 0, so Call printd(1)
(1 / 10) == 0, so Call putchar "1"
Call putchar "2"
Call putchar "3"
return 0 (from main())
-

You have recursion in C (or any other programming language) by breaking a problem into 2 smaller problems.

Your example: print a number can be broken in these 2 parts

1. print the first part if it exists
2. print the last digit

To print "123", the simpler problems are then to print "12" (12 is 123 / 10) and to print "3".
To print "12", the simpler problems are then to print "1" (1 is 12 / 10) and to print "2".
To print "1", ... just print "1".

-
#include <stdio.h>

#define putd(d) (printf("%d", d))

#define RECURSIVE

void rprint(int n)
{
#ifndef RECURSIVE
int i = n < 0 ? -n : n;

for (; i / 10; i /= 10)
putd(i % 10);

putd(i % 10);

if (n < 0)
putchar('-');
/* Don't forget to reverse :D */
#else
if (n < 0) {
n = -n;
putchar('-');
}

int i = n / 10;
if (i)
rprint(i);

putd(n % 10);
#endif
}

int main()
{
rprint(-321);
return 0;
}
-

Recursion works on stack i.e, first in last out.

Recursion is a process of calling itself with different parameters until a base condition is achieved. Stack overflow occurs when too many recursive calls are performed.

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Could you reshape your answer for better understanding. Reformatting, grammar rules etc. –  Seçkin Savaşçı Sep 16 '12 at 13:05
@AustinHenley -- What was the point in making that edit?? –  Hot Licks Sep 25 '12 at 3:12
@HotLicks As Seckin said, it was hard to read. –  Austin Henley Sep 25 '12 at 3:15

To understand recursion, you need to understand the storage model. Though there are several variations, basically "automatic" storage, the storage used to contain automatic variables, parameters, compiler temps, and call/return information, is arranged as a "stack". This is a storage structure starting at some location in process storage and "growing" either "up" (increasing addresses) or "down" (decreasing addresses) as procedures are called.

One might start out with a couple of variables:

00 -- Variable A -- 27
01 -- Variable B -- 45

Then we decide to call procedure X, so we generate a parameter of A+B:

02 -- Parameter -- 72

We need to save the location where we want control to return. Say instruction 104 is the call, so we'll make 105 the return address:

03 -- Return address -- 105

We also need to save the size of the above "stack frame" -- four words, 5 with the frame size itself:

04 -- Frame size -- 5

Now we begin executing in X. It needs a variable C:

05 -- Variable C -- 123

And it needs to reference the parameter. But how does it do that? Well, on entry a stack pointer was set to point at the "bottom" of X's "stack frame". We could make the "bottom" be any of several places, but let's make it the first variable in X's frame.

05 -- Variable C -- 123  <=== (Stack frame pointer = 5)

But we still need to reference the parameter. We know that "below" our frame (where the stack frame pointer is pointing) are (in decreasing address order) the frame size, return address, and then our parameter. So if we subtract 3 (for those 3 values) from 5 we get 2, which is the location of the parameter.

Note that at this point we don't really care if our frame pointer is 5 or 55555 -- we just subtract to reference parameters, add to reference our local variables. If we want to make a call we "stack" parameters, return address, and frame size, as we did with the first call. We could make call after call after call and just continue "pushing" stack frames.

To return we, load the frame size and the return address into registers. Subtract frame size from the stack frame pointer and put the return address into the instruction counter and we're back in the calling procedure.

Now this is an over-simplification, and there are numerous different ways to handle the stack frame pointer, parameter passing, and keeping track of frame size. But the basics apply regardless.

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Wow, that's a really old question –  Maël Nison Sep 25 '12 at 3:08
Yep, I didn't look at the date before I started answering. I dunno why someone decided to edit one of the responses -- I hate that! –  Hot Licks Sep 25 '12 at 3:10