I am new to haskell and just learning the fun of functional programming. but have run into trouble right away with an implementation of the fibonacci function. Please find the code below.

``````--fibonacci :: Num -> [Num]
fibonacci 1 = 
fibonacci 2 = [1,1]
--fibonacci 3 = 
--fibonacci n = fibonacci n-1
fibonacci n = fibonacci (n-1) ++ [last(fibonacci (n-1)) + last(fibonacci (n-2))]
``````

Rather awkward, I know. I can't find time to look up and write a better one. Though I wonder what makes this so inefficient. I know I should look it up, just hoping someone would feel the need to be pedagogic and spare me the effort.

• If you can't even find the time to lookup a better one then how can you find the time to learn from an answer presenting a better one and explaining why it is better? Oct 21, 2011 at 19:03
• Possibly a duplicate of this: stackoverflow.com/questions/6562387/…. In my opnion the questions are identical just that this one has a less clear code example. Oct 22, 2011 at 13:51
• @ThomasM.DuBuisson: It was midnight, and i was sleepy when i wrote that. so the context should have been 'don't have time right now'. Now am looking it up and going to irc.. Oct 22, 2011 at 14:01
• @HaskellElephant: Took a look at that one. I have worded this one bad. Will edit this question, look up answers and update. Oct 22, 2011 at 14:02

orangegoat's answer and Sec Oe's answer contain a link to probably the best place to learn how to properly write the fibonacci sequence in Haskell, but here's some reasons why your code is inefficient (note, your code is not that different from the classic naive definition. Elegant? Sure. Efficient? Goodness, no):

Let's consider what happens when you call

``````fibonacci 5
``````

That expands into

``````(fibonacci 4) ++ [(last (fibonacci 4)) + (last (fibonacci 3))]
``````

In addition to concatenating two lists together with `++`, we can already see that one place we're being inefficient is that we calculate `fibonacci 4` twice (the two places we called `fibonacci (n-1)`. But it gets worst.

Everywhere it says `fibonacci 4`, that expands into

``````(fibonacci 3) ++ [(last (fibonacci 3)) + (last (fibonacci 2))]
``````

And everywhere it says `fibonacci 3`, that expands into

``````(fibonacci 2) ++ [(last (fibonacci 2)) + (last (fibonacci 1))]
``````

Clearly, this naive definition has a lot of repeated computations, and it only gets worse when n gets bigger and bigger (say, 1000). `fibonacci` is not a list, it just returns lists, so it isn't going to magically memoize the results of the previous computations.

Additionally, by using `last`, you have to navigate through the list to get its last element, which adds on top of the problems with this recursive definition (remember, lists in Haskell don't support constant time random access--they aren't dynamic arrays, they are linked lists).

One example of a recursive definition (from the links mentioned) that does keep down on the computations is this:

``````fibs = 0 : 1 : zipWith (+) fibs (tail fibs)
``````

Here, `fibs` is actually a list, and we can take advantage of Haskell's lazy evaluation to generate `fibs` and `tail fibs` as needed, while the previous computations are still stored inside of fibs. And to get the first five numbers, it's as simple as:

``````take 5 fibs -- [0,1,1,2,3]
``````

(Optionally, you can replace the first 0 with a 1 if you want the sequence to start at 1).

• Thanks i learnt a lot from that... It was lazy of me to ask this question here instead of looking up. Thanks for the patience. Oct 30, 2011 at 17:29

This implementation is inefficient because it makes three recursive calls. If we were to write a recurrence relation for computing `fibonacci n` to a normal form (note, pedantic readers: not whnf), it would look like:

``````T(1) = c
T(2) = c'
T(n) = T(n-1) + T(n-1) + T(n-2) + c''
``````

(Here `c`, `c'`, and `c''` are some constants that we don't know.) Here's a recurrence which is smaller:

``````S(1) = min(c, c')
S(n) = 2 * S(n-1)
``````

...but this recurrence has a nice easy closed form, namely `S(n) = min(c, c') * 2^(n-1)`: it's exponential! Bad news.

I like the general idea of your implementation (that is, track the second-to-last and last terms of the sequence together), but you fell down by recursively calling `fibonacci` multiple times, when that's totally unnecessary. Here's a version that fixes that mistake:

``````fibonacci 1 = 
fibonacci 2 = [1,1]
fibonacci n = case fibonacci (n-1) of
all@(last:secondLast:_) -> (last + secondLast) : all
``````

This version should be significantly faster. As an optimization, it produces the list in reverse order, but the most important optimization here was making only one recursive call, not building the list efficiently.

So even if you wouldn't know about the more efficient ways, how could you improve your solution?

First, looking at the signature it seems you don't want an infinite list, but a list of a given length. That's fine, the infinite stuff might be too crazy for you right now.

The second observation is that you need to access the end of the list quite often in your version, which is bad. So here is a trick which is often useful when working with lists: Write a version that work backwards:

``````fibRev 0 = []
fibRev 1 = 
fibRev 2 = [1,1]
fibRev n = let zs@(x:y:_) = fibRev (n-1) in (x+y) : zs
``````

Here is how the last case works: We get the list which is one element shorter and call it `zs`. At the same time we match against the pattern `(x:y:_)` (this use of `@` is called an as-pattern). This gives us the first two elements of that list. To calculate the next value of the sequence, we have just to add these elements. We just put the sum `(x+y)` in front of the list `zs` we already got.

Now we have the fibonacci list, but it is backwards. No problem, just use `reverse`:

``````fibonacci :: Int -> [Int]
fibonacci n = reverse (fibRev n)
``````

The `reverse` function isn't that expensive, and we call it here only one time.