First, find your base case: `call(n), when n<=0`

does nothing and just returns.

In the general case for `code(n)`

the definition says: "decrement `n`

and recurse (all the way down); when the control is back, print `n`

(its value is preserved), decrement again and recurse again".

Or, with equations:

```
call(n) | when(n<=0) = NO-OP
call(n) | otherwise = call(n-1), print(n-1), call(n-2)
```

So,

```
call(1) = call(0), print(0), call(-1)
= print(0)
call(2) = call(1), print(1), call(0)
= print(0), print(1)
call(3) = call(2), print(2), call(1)
= (print(0), print(1)), print(2), print(0)
```

Continuing,

```
call(4) = 0120+3+01
call(5) = 0120301+4+0120
call(6) = 012030140120+5+0120301
....
```

It seems we can generate the indefinite sequence of resulting outputs, maintaining just the two most recent values:

```
(n,a,b) --> (n+1,b,b+n+a)
```

So instead of *recursion* down towards the base case, this describes *corecursion* up away from the starting case, `(2,0,1)`

(the `1`

case is covered by a special fact `(1,_,0)`

). We can code it as an actual indefinitely growing (i.e. *"infinite"*) sequence, or we can just make an infinite loop out of it.

What would be the purpose of such non-terminating computations? To *describe* the computation of the results, *in general*. But of course it is extremely easy to cut short such computation when we reach a target value for `n`

.

The benefit? Instead of recursion, we get an iterative loop!

```
output(1) = "0"
output(n) | when(n>1) =
let {i = 2, a="0", b="1"}
while( i<n ):
i,a,b = (i+1),b,(b+"i"+a)
return b
```

`gcc -Wall -g prog.c -o binprog`

, then`gdb binprog`

and run it step by step (`s`

command of`gdb`

), using the`bt`

command of`gdb`

to get backtraces. Explaining recursion is difficult, you need to get the insight about it. – Basile Starynkevitch Dec 15 '12 at 8:04