Recursive Functions
A definition that defines an object in terms of itself is said to be recursive. In computer science, recursion refers to a function or subroutine that calls itself, and it is a fundamental paradigm in programming. A recursive program is used for solving problems that can be broken down into sub-problems of the same type, doing so until the problem is easy enough to solve directly.
Examples
Fibonacci Numbers
A common recursive function that you’ve probably encountered is the Fibonacci numbers: 0, 1, 1, 2, 3, 5, 8, 13, and so on. That is, you get the next Fibonacci number by adding together the previous two. Mathematically, this is written as
$$f(N)=f(N-1)+f(N-2)$$
Try finding f(10). No doubt, you have the correct answer, because you intuitively stopped when you reach $f(1)$ and $f(0)$. To be formal about this, we need to define when the recursion stops, called the base cases. The base cases for the Fibonacci function is $f(0)=1$, and $f(1)=1$. The typical way to write this function is as follows: $$f(N)=\cases{1 & if $N=0$\cr 1 & if $N=1$\cr f(N-1)+f(N-2) & if $N > 1$}$$
Here is a Python implementation of the Fibonacci function:
def Fibonacci(x): if (x == 0) return 0 if (x == 1) return 1 return Fibonacci(x-1) + Fibonacci(x-2)
(As a challenge to the reader: How could you implement the Fibonacci function without using recursion?)
Factorial Function
Consider the factorial function, $n! = n * (n-1) * ... * 1$, with 0! defined as having a value of 1. We can define this recursively as follows:
$$f(x)=\cases {1 & if $x=0$\cr x*f(x-1) & if $x\gt 0$\cr }$$
WIth this definition, the factorial of a negative number is not defined.
Here is a Python implementation of the factorial function:
def Factorial(x): if (x<0) return 1 return x*Factorial(x-1)
In the implementation above, the method will never return if called wth a negative number. (Question: How would you fix the code to return, say, a 1 if called with a negative number?)
Some Definitions
A few definitions: Indirection recursion is when a function calls another function which eventually calls the original function. For example, A calls B, and then, before function B exits, function A is called (either by B or by a function that B calls). Single recursion is recursion with a single reference to itself, such as the factorial example above. Multiple recursion, illustrated by the Fibonacci number function, is when a function has multiple self references. Infinite recursion is a recursive function that never returns because it keeps calling itself.
This ACSL category focuses on mathematical recursive functions rather than programming procedures; but you’ll see some of the latter.
Sample Problems
Online Resources
ACSL
The following videos show the solution to problems that have appeared in previous ACSL contests.
Recursion Example 1 (CalculusNguyenify)
The video walks through the solution to a straight-forward single-variable recursive function, that is, $f(x)=\cases{....}$ The problem appeared in ACSL Senior Division Contest #1, 2014-2015. | |
Recursion Example 2 (CalculusNguyenify)
The video walks through the solution to a 2-variable recursive function, that is, $f(x,y)=\cases{....}$ . The problem appeared in ACSL Senior Division Contest #1, 2014-2015. | |
Recursive Functions ACSL Example Problem (Tangerine Code)
The video walks through the solution to a 2-variable recursive function, that is, $f(x,y)=\cases{....}$ . |
Other Videos
The follow YouTube videos cover various aspects of this topic; they were created by authors who are not involved (or aware) of ACSL, to the best of our knowledge. Some of the videos contain ads; ACSL is not responsible for the ads and does not receive compensation in any form for those ads.