Showing posts with label Fibonacci. Show all posts
Showing posts with label Fibonacci. Show all posts

Monday, July 9, 2018

Speed up Fibonacci Sequence with Tail Recursion

Target audience: Intermediate
Estimated reading time: 5'

The Fibonacci sequence is characterized by each number being the summation of its two immediate predecessors. In this article, we delve into an examination and comparison of tail recursion's efficiency in Scala, specifically when applied to the Fibonacci sequence.


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There are many ways to skin a cat and implement the Fibonacci recursion. This post illustrates the power of tail recursion in Scala, relative to alternative solution such as recursion without tail elimination and iterations. This post compares the performance of the simple "out-of-the-box" implementation of the Fibonacci recursion with an Scala implementation using tail-recursion.

Note: This post relies on Scala 2.11.8


Non-tail recursive Fibonacci

The Fibonacci algorithm is defined as
   f(n) = f(n-1) + f(n-2)
   f(0) = 0
   f(1) = 1
Let's look at text book recursive implementation.

 
def fibonacci(n: Int): Long =  {
    if(n == 0) 0
    else if(n == 1) 1
    else fibonacci1(n-1) + fibonacci1(n-2)
}

The duration of execution is recorded for values between 2 and 50, run 10,000 times.
The profile of the performance of the non-tail recursion of Fibonacci should not be a surprise. After all, the time complexity of this implementation is a staggering O(2n)


Tail recursion

Let's look at one example of implementation of the Fibonacci formula using the Scala tail recursion.

def fibonacci(n: Int): Long = {
   
   @tailrec
   def _fibonacci(i: Int, next: Long, sum: Long): Long = 
       if(i ==0) sum
       else fibonacci(i-1, sum+ next, next)

   fibonacci(n, 1, 0)
}

The performance of the tail recursion is measure against a plain-vanilla iterative execution. The duration of execution is recorded for values between 5 and 200, run 100,000 times.

 
def fibonacci(n: Int): Long = {
    var s1 = 0
    var s2 = 1 
 
    (n-1 to 0 by -1).foreach(
       _ => {
           val tmp = s2 + s1
           s1 = s2
           s2 = tmp    
      }
   )
   
   s1
}

The following chart illustrates that the performance of the implementation of Fibonacci using the tail recursion and the iterative execution is almost identical.

Iterative computation

For good measure, I thought it would be interesting to measure the performance of an iterative approach using a fold.

def fibonacci(n: Int): Long = 
 
  (n-1 to 0 by -1)./:((0, 1)) {  
      case ((s1, s2), n) => { 
          val tmp = s2 + s1
          (s2, tmp) 
      }
   }._1

Here is the performance profile for the iterative computation.
Note: The fold (:/) can be implemented as a closure using a recursive formula for the function argument.

Conclusion

Scala tail recursion is indeed as effective as the iterative implementation at processing the Fibonacci formula. The performance of the recursion without tail elimination is extremely poor. Aggregators or reducers such as fold, reduce and scan add some overhead to the computation although the performance is still decent.

Thank you for reading this article. For more information ...

References



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Patrick Nicolas has over 25 years of experience in software and data engineering, architecture design and end-to-end deployment and support with extensive knowledge in machine learning. 
He has been director of data engineering at Aideo Technologies since 2017 and he is the author of "Scala for Machine Learning" Packt Publishing ISBN 978-1-78712-238-3