# how to increment a variable in functional programming

How do you increment a variable in a functional programming language?

For example, I want to do:

main :: IO ()
main = do
let i = 0
i = i + 1
print i

Expected output: 1.

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I gave a +1 because this is sort of a valid question. But something I found when I learned Haskell was that it taught you to think about solving problems is a different way. The kind of way where you don't need to use for loops. – Abizern Aug 12 '12 at 12:28
I don't think this deserves downvotes. Its a legitamate question and is doable (you need to use MVar, IORef, or even STRef. In addition, it serves as a way to tell people "don't do this. ever" – alternative Aug 12 '12 at 13:02
Well that's nonsense! 0 is not equal to itself plus one! How in the sweet heavens does that make any mathematical sense? I'm beeing cheeky, but in Haskell = means equals, like in math. You're looking for some other operator that modifies the contents of a mutable variable. As probie indicated, that operator is modifyIORef or something similar. – Dan Burton Aug 12 '12 at 19:19
You are getting down-voted because it is (more or less) obvious you have not made an effort to read the most basic introductory material available on Haskell (or functional programming in general). Your questions sound like "I just bought a plane - does anybody know how I can get on the freeway?". Why would you get on the freeway if you have a plane? Try going through learnyouahaskell.com or book.realworldhaskell.org. – ozataman Aug 12 '12 at 21:09
For crap sake it was a FAQ, see below to help other people. I answered my own question. Do you really think noobs like me do not try to do i=i+1? – Gert Cuykens Aug 12 '12 at 22:09

Simple way is to introduce shadowing of a variable name:

main :: IO ()
main = do
let i = 0
let j = i
let i = j+1
print i

Prints 1. Just writing let i=i+1 doesn't work because let in Haskell makes recursive definitions - it is actually Scheme's letrec.

So i in right-hand side of let i=i+1 refers to i in left hand side of this equation - not to the upper level i as might be intended. Shadowing takes care of that.

## How to "think functional"

One thing to understand here is that functional programming with pure - immutable - values forces us to make time explicit in our code.

In imperative setting time is implicit. We "change" our vars - but any change is sequential. We can never change what that var was a moment ago - only what it will be from now on.

In pure functional programming this is just made explicit. One of the simplest forms this can take is with using lists of values as records of sequential change in imperative programming. Even simpler is to use different variables altogether to represent different values of an entity at different points in time.

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Very smart way! Thanks – ye9ane Aug 26 '13 at 10:46

As a general rule, you don't (and you don't need to). However, in the interests of completeness.

import Data.IORef
main = do
i <- newIORef 0       -- new IORef i
modifyIORef i (+1)    -- increase it by 1
readIORef i >>= print -- print it

However, any answer that says you need to use something like MVar, IORef, STRef etc. is wrong. There is a purely functional way to do this, which in this small rapidly written example doesn't really look very nice.

type Lens a b = ((a -> b -> a), (a -> b))
setL = fst
getL = snd
modifyL :: Lens a b -> a -> (b -> b) -> a
modifyL lens x f = setL lens x (f (getL lens x))
lensComp :: Lens b c -> Lens a b -> Lens a c
lensComp (set1, get1) (set2, get2) =         -- Compose two lenses
(\s x -> set2 s (set1 (get2 s) x)        -- Not needed here
, get1 . get2)                          -- But added for completeness

(+=) :: (Num b) => Lens a b -> Lens a b -> State a ()
x += y = do
s <- get
put (modifyL x s (+ (getL y s)))

swap :: Lens a b -> Lens a b -> State a ()
swap x y = do
s <- get
let x' = getL x s
let y' = getL y s
put (setL y (setL x s y') x')

nFibs :: Int -> Int
nFibs n = evalState (nFibs_ n) (0,1)

nFibs_ :: Int -> State (Int,Int) Int
nFibs_ 0 = fmap snd get -- The second Int is our result
nFibs_ n = do
x += y       -- Add y to x
swap x y     -- Swap them
nFibs_ (n-1) -- Repeat
where x = ((\(x,y) x' -> (x', y)), fst)
y = ((\(x,y) y' -> (x, y')), snd)
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isn't it just another way to write nFibs n = snd.head \$ iterate g [(0,1)] !! n where g (s:_) = let { s1=addIn s ; s2=swap s1 } in [s2,s1] ; addIn(a,b)=(a+b,b) ; swap(a,b)=(b,a) ? (small oversight - it's the first Int that's the result here). – Will Ness Aug 12 '12 at 19:56
and this is why I shouldn't write things at 3am :p But if you want a simple fib function nFibs n = let fibs = iterate (\(x,y) -> (y, x+y)) (0,1) in (snd . (!! n)) fibs However, the idea has nothing to do with a fibonacci function. The idea was to give an example of functional lenses. – Probie Aug 13 '12 at 2:29
I wasn't questioning your writing, at all. :) I don't understand why try so hard to be able to write in imperative style, in the first place. Same as calling monadic inject a "return", for some peculiar salesmanship reasons. Why not "sell" functional style better, striving for better compiler support for it (case in point - stackoverflow.com/a/9605197/849891 where destructive array update should/could have been used automagically by a compiler, IMHO, although many smart people disagree). – Will Ness Aug 13 '12 at 7:08
Because the question was asked for how to do i=i+1 in a functional programming language. Simply saying you can't or shouldn't is unhelpful. – Probie Aug 13 '12 at 9:09
Probie, you're such a troll! – luqui Apr 26 '14 at 19:13

There are several solutions to translate imperative i=i+1 programming to functional programming. Recursive function solution is the recommended way in functional programming, creating a state is almost never what you want to do.

After a while you will learn that you can use [1..] if you need a index for example, but it takes a lot of time and practice to think functionally instead of imperatively.

Here's one purely functional way to do something similar (not identical because there aren't any destructive updates) using the State monad:

module Count where

count :: Int -> Int
count c = c+1

count' :: State Int Int
count' = do
c <- get
put (c+1)
return (c+1)

main :: IO ()
main = do
print \$ count \$ count \$ count \$ count \$ count \$ count 0
print \$ evalState count' \$ evalState count' \$ evalState count' \$ evalState count' 0
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Yeah, except, don't do that. State monad is not something you sprinkle your code with just to make it act imperative. In fact, don't write imperative code in Haskell unless it's needed. – Cat Plus Plus Aug 12 '12 at 12:42
I don't think this is a good answer. The use case in which you imperatively would use i=i+1 is almost never translated to "Use State!" in Haskell. A "don't do this!" or "If you really, really need this, use MVar" seems much more sane. – Sarah Aug 12 '12 at 15:59
ok changing answer – Gert Cuykens Aug 12 '12 at 16:03
Deceptive question' so -1. If you already knew how to model state, why lie about it? – Richard Huxton Aug 12 '12 at 21:32
PLEAS READ! blog.stackoverflow.com/2011/07/… – Gert Cuykens Aug 13 '12 at 15:58