I've been doing problems on recursion in my Data Structures & Algorithms class and for some tail-recursive functions I couldn't think of doing anything but having the main function call a helper function and the helper function being the tail recursive part since I had to pass different parameters than the original function.

While this is technically tail-recursive the original function is the one that ends up handling the base cases and in the main case passes the additional parameters to the actual tail recursive function.

Obviously this sort of defeats the idea of recursion, especially in a class setting for homework, exams and such.

That's why today I thought, instead of making a helper function, couldn't I make an overloaded version of the function that accepts those additional parameters and continues the work? It would technically be recursive since all the calls in the function are to itself, albeit with more parameters than the initial call.

Here's a rough example:

``````int fibonacci(int n) {
if (n == 1)
return 1;
else
return fibonacci(n, 2, 1, 2);
}

int fibonacci(int n, int f1, int f2, int c) {
if (c == n)
return f1;
else
return fibonacci(n, f1 + f2, f1, c + 1);
}
``````

Is it still recursion in the definition sense? Would it work? Would the compilers that do recursion optimization (don't know how it works exactly, but know it exists) apply that to this?

I assume that it's still recursion since it's technically calling itself still and I would think it would optimize, just ignoring the initial call. But that's why I'm asking, to see if I'm right or not.

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As an aside, you made a mistake that is very common for people writing recursive functions: you forgot to `return` the value of the function call (e.g. `return fibonacci(...)`). –  Seth Carnegie Nov 3 '11 at 0:31
Just fixed that, which is odd since the program still ran and output the answer when I did cout << fibonacci(n) –  Portaljacker Nov 3 '11 at 0:34
yeah, that's probably because the last function call returns `f1` from `fibonacci(int, int, int, int)` which is the desired fibonacci number (so it's stored in the eax register if you're on x86), and the `return`s should propogate that upwards but they don't, but since there are no `return`s, the last function call's value isn't overwritten so it just happens to work. But it won't always work on all architectures and it's technically invalid C++ because "not all paths return a value" which your compiler should warn you about. –  Seth Carnegie Nov 3 '11 at 0:36
This is the "standard" way to handle fibonacci recursively. The overloading is irrelevant as the names could be completely random, and still have the desired semantics (even if it would be considered "bad code") -- in a statically typed language with overloading the type signature is part of the "name". While the "prep" function is itself not recursive, the second function clearly is -- and that function is where the work is actually done. –  user166390 Nov 3 '11 at 0:42
Another remark: the main/original/prep function does not handle the base case. The base case is where the recursion ends (in your example `(c==n)`) and handled by the helper function. You can remove the test for `n==1` from the main function and just `return fibonacci(n, 1, 1, 1)`. –  nimi Nov 3 '11 at 1:04

Yes, I would still call this "recursion." The one-argument overload of `fibonacci` is not recursive, but the 4-argument overload is recursive without a doubt.
That said: don't fool yourself into thinking that the `fibonacci` function overall is recursive. The one-argument overload never calls itself. In Java-like languages, where a function/method is uniquely defined by its signature, you still have two distinct functions.
@Portaljacker your function signature would look like `fibonacci(int n, int f1 = 2, int f2 = 1, int c = 2)`. That way, you can call it with one or more (but less than 4) arguments and the others will have their defaults, or you can call it with all of them and they will have those values. –  Seth Carnegie Nov 3 '11 at 0:39