Given this pseudo code of a function
f(0) = 1; f(1) = 3; f(n) = 3 * f(n - 1) - f(n - 2); // for n >= 2.
Is there a non recursive way of doing this?
Yes, all recursive algorithms can be converted into iterative ones. The recursive solution to your problem is something like (pseudo-code):
Since you only have to remember the previous two terms to calculate the current one, you can use something like the following pseudo-code:
This simply handles the "recursive" termination condition first then iterates where it would normally call itself. At each iteration, you calculate the current term, then rotate the terms through the grandparent and parent.
There is no need to keep the grandparent around once you've calculated the current iteration since it's no longer used.
In fact, it could be said that the iterative solution is better (from a performance viewpoint) since terms are not recalculated as they are in the recursive solution. The recursive solution does have a certain elegance about it though (recursive solutions generally do).
Of course, like the Fibonacci sequence, that value you calculate rises very quickly so, if you want what's possibly the fastest solution (you should check all performance claims, including mine), a pre-calculated lookup table may be the way to go.
Using the following Java code to create a table of long values (that
gives you an array definition that you can just plug in to a lookup function, as per the following example:
Interestingly enough, WolframAlpha comes up with a formulaic approach that doesn't even use iteration. If you go to their site and enter
Unfortunately, it may not be as fast as the iteration, given the limited number of input values that result in something that can fit in a Java
And, it's probably perfect in the world of maths where real-world limits like non-infinite storage don't come into play but, possibly due to the limits of IEEE precision, it breaks down at higher values of
The following functions are the equivalent of that expression and the lookup solution:
Now we need a mainline to compare them:
This will output:
Looking good up to here, some more:
But then something starts going awry:
The fact that the above are tantalisingly close, and that the number of digits in the error is proportional to the number of digits in the result, indicates it's probably a loss-of-precision problem.
After this point, the formulaic function just starts returning the maximum long value:
And then our lookup function breaks down as well since the numbers are too big for a long:
The Fibonacci series sequence of numbers starts as: 0,1,1,2,3,5,8,13,21,34,55....
this can be defined by simple recurrence relation F(n)=F(n-1)+F(n-2) for n>1 and two initial conditions, F(0)=1 and F(1)=1
//Computes the nth Fibonacci number
//Input: A non-negative integer
//Output: The nth Fibonacci number
As requested by @paxdiablo I'm making this an answer. It's a recurrence relation and can be solved non-recursively, similar to the fibonacci sequence mentioned in another answer. It turns out to be (Python notation).
However, this forumula does most probably not work for large n, because of limited float precision. The given python version fails for n = 30:
Warning: I used a "+" instead of a "-", so the formula is wrong. See comments.
If your question is about whether an equivalent non-recursive definition of the function can be found, you should search for properties of the Fibonacci sequence.
Your sequence can be found by writing the Fibonacci (without the first 2 numbers) and removing every 2nd number: 1, 3, 8, 21, 55, 144, ...
Answers here are correct, but they work in O(n), while you can do it in O(log n), exponentially faster. Observe that
Let vn be the vector [f(n), f(n-1)] and A the matrix as above, so you get vn = A vn-1, therefore vn = An-1 v1. Compute (n-1)-th power of matrix A using binary exponentiation and multiply it by v1. For more on linear recurrences see here.
It's simple, in Java the solution looks like this:
All recursive solutions can be transformed into iterative solutions (the opposite is also true, see this post), albeit it's easier if the recursive solution it's in tail-recursive form.
The above algorithm can be understood as a dynamic-programming solution to the original recursion, it's very efficient since it only needs to save the two previous values at each point in the iteration.
The function is defined in terms of itself, so in one sense any implementation is recursive, unless some mathematician comes and tells us
[ Oops, I thought this was a Perl question. Still, the code should be readable enough to a Java developer. ]
This is really just moving the recursion to userland, but you could use:
Of course, this begs for caching. There's no need to recalculate values we already know.