15
fibs :: [Int]
fibs = 0 : 1 : [ a + b | (a, b) <- zip fibs (tail fibs)]

This generates the Fibonacci sequence.

I understand the behaviour of the guards, of :, zip and tail, but I don't understand <-. What is it doing here?

15

Due to the upvotes I made my comment into an answer.

What you see is not a guard but it is list comprehension. For starters think of it as a way to express a mathematical set notation like A = { x | x element N } which means something along the lines of: The set A is the set of all natural numbers. In list comprehension that would be [x | x <- [1..] ].

You can also use constraints on your numbers: [x | x <- [1..], x `mod` 2 == 0 ] and many other things.

There are alot of good haskell turorials out there that cover list comprehension and even a StackOverflow question regarding haskell resources.

11

The only tricky thing is the zip fibs (tail fibs). zip just makes a pairwise list from each of its arguments. So if you have two lists like this:

[ 1, 2, 3, 4 ]
[ "a", "b", "c", "d" ]

Zipping them will make:

[ (1,"a"), (2,"b"), (3,"c"), (4,"d") ]

The left arrow (assignment into a destructuring pattern) just extracts the paired elements so they can be added together. The two lists being zipped are fibs and (tail fibs) -- in other words, the Fibonacci sequence, and the Fibonacci sequence offset by 1 element. Haskell is lazily-evaluated, so it can calculate the list to however many elements are required. This applies to zip as well.

  • Will the two fibs'es be evaluated together once or independently twice? – Thorbjørn Ravn Andersen Dec 26 '10 at 19:42
  • What is the command called to create [(1,"a","A"),(2,"b","B"),...]? Is it still a zip? Well explained -- it works like zip in Python, cool. – hhh May 5 '13 at 0:40
  • 1
    @hhh hey amigo. it looks like you need zip3 for that, which is quite hilarious. a general zip is understandably quirky to implement in Haskell because of its type system. In Mathematica you could do Thread[{ls1, ls2, ls3}] or use Transpose, etc. And yea Python has a small amount of 'functional programming' stuff. But as far as functional programming goes, none of these languages come close to the APL family of languages like J, which are one or two notches above functional programming itself and in their own higher category. :) – amr May 9 '13 at 22:09
  • transpose = foldr (zipWith (:)) (repeat []). – Will Ness Feb 12 '17 at 2:56
4

Let's expand it out.

zip creates pairs out of the contents of two lists. So the first pair zip fibs (tail fibs) gives us is (0, 1), which adds up to 1. So now the list is [0,1,1]. We now know three elements in the list, so the list comprehension can continue, grabbing the next item from the list and the next item from the tail, which gives (1,1) — added together, making 2. Then we get the next pair, which is (1,2), making the next number in the sequence 3. This can continue infinitely, since the comprehension will always provide enough items.

2

For what it's worth, I find the following version easier to understand:

fibs = 0 : 1 : zipWith (+) fibs (tail fibs)
2

One advantage of functional programming is that you can evaluate an expression by hand like it is a math problem:

fibs = 0 : 1 : [ a + b | (a, b) <- zip fibs (tail fibs)]
     = 0 : 1 : [ a + b | (a, b) <- zip [0, 1, ??] (tail [0, 1, ??])]

Here the ?? is the part which has not yet been evaluated. We will fill it in as we proceed.

     = 0 : 1 : [ a + b | (a, b) <- zip [0, 1, ??] [1, ??])]
     = 0 : 1 : [ a + b | (a, b) <- (0, 1) : zip [1, ??] [??]]

Note that I am eliding the evaluation of zip since its definition is not given here and the details are not really germane to the current question. This is the notation I will use to show each pair of numbers is created by zip and consumed by the list comprehension.

     = 0 : 1 : 0+1 : [ a + b | (a, b) <- zip [1, ??] [??]]
     = 0 : 1 : 1 : [ a + b | (a, b) <- zip [1, ??] [??]]

Now we know that the next element in the ?? is a 1:

     = 0 : 1 : 1 : [ a + b | (a, b) <- zip [1, 1, ??] [1, ??]]
     = 0 : 1 : 1 : [ a + b | (a, b) <- (1, 1) : zip [1, ??] [??]]
     = 0 : 1 : 1 : 1+1 : [ a + b | (a, b) <- zip [1, ??] [??]]
     = 0 : 1 : 1 : 2 : [ a + b | (a, b) <- zip [1, ??] [??]]

And the next element is a 2:

     = 0 : 1 : 1 : 2 : [ a + b | (a, b) <- zip [1, 2, ??] [2, ??]]

Rinse and repeat.

1

The list comprehension in the brackets:

[ a + b | (a, b) <- zip fibs (tail fibs)]

returns a list containing the output (a + b) where the variables a and b come from the result of

zip fibs (tail fibs)
0

i still don't understand. i like this answer: https://stackoverflow.com/a/42183415/246387 (from code-apprentice).

but i do not understand how from this line:

= 0 : 1 : 1 : [ a + b | (a, b) <- zip [1, ??] [??]]

it move to this:

= 0 : 1 : 1 : [ a + b | (a, b) <- zip [1, 1, ??] [1, ??]]

and besides of this, i have something else that bother me:

how can i use fib inside the list-comprehension if i don't have fib at all (so it seems, but sure i'm wrong), because fib isn't calculated yet. it "waits" (in the left side of the equal sign) to be calculated in the right side (of the equal sign).

  • This is at best a comment. Not an answer. – Mark Apr 4 '18 at 10:09
0

The key concept here is lazy evaluation which means that if the value is right there then take it without further computing say that i have got the value and the job is done, i don't need to compute future value temporary now. and if the value is not available then just compute it and of course it's lazy so it won't bother computing next needed value.

i write another implementation to illustrate this and use ?? to be a value placeholder which needs to be computed if needed.

fibs = 1:1:[ y!!1 + y!!0 | x<-[2..], y <- [[last (take x fibs), last (take (x-1) fibs)]] ]

i use x to indicate number of available values in fibs (which doesn't need to be computed again) and y to be a [[last fib values]] nested list. its inner list contains last two values of available values in fibs.

so here is the process of the computation:

  1. x == 2, so y is [last (take 2 fibs), last (take 1 fibs)]. lazy evaluation lets us just take available values and don't bother worrying values in the future. it tells me to take first 2 and 1 values of fibs and the values are right there 1,1 and 1. y now is [last [1,1], last [1]] which is [1,1] and to get final value it need to compute y!!1 + y!!0. That's obvious and final value is 2. so now fibs is [1, 1, 2, ??].
  2. x == 3, just the same as step 1. y is [last [take 3 fibs], last [take 2 fibs]] which is [last [1,1,2], last [1,1]], the value now is available so we can just take it and go on. Finally, we got the fourth value 3.
  3. that's it, just repeat the above steps and you can get all values even it is infinite

Doesn't it seems familiar? just like using a recursive function to compute fibs. we now let compiler itself to do the stuff(referring). we use the lazy evaluation here.

the zip implementation is just another representation of [last fibs values] here. you just need a little modification to understand the zip version of fibs implementation.

  1. haskell wiki: lazy evaluation

  2. for <- symbol: List comprehension

-2

How would the parser know what goes into (a,b) otherwise?

EDIT: Thanks to ViralShah, I will make this a little less gnomic. The "<-" tells the parser to assign the list of pairs from the right side "zip fibs (tail fibs)" to the left side "(a,b)".

  • This is a comment, not an answer. – Viral Shah Mar 8 '10 at 19:59

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.