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i am trying to compile a quite simple haskell program. Either I don't know how to sequence statements (expressions) in Haskell, or there isn't a way to do it.

I essentially want a function of the form:

f = <do stuff 1>
    <do stuff 2>

the following was supposed to simulate a pattern of

<do stuff>
<tail recursion>

but failed to compile:

go 0 = 0
go i =  case i of
            1 -> 2
            _ -> 3
        go (i-1)

This doesn't work either (simpler, no recursion):

go i =  1

The code directly above compiles, but while running I get the cryptic:

No instance for (Num (a0 -> t0))
  arising from a use of `go'
Possible fix: add an instance declaration for (Num (a0 -> t0))
In the expression: go 2
In an equation for `it': it = go 2

Am I having a problem with indention? A problem with not sequencing correctly? Or is there no sequencing capability? If no sequencing, how would you straightforwardly do

<do stuff>
<tail recursion>


Thanks for the responses.

Hard to believe a function in Haskell is basically limited to one "expression" or "statement" or whatever you want to call it. How would you solve the following contrived toy example (written in erlang, but could easily be translated direcly into prolog or a whole host of other langs):

count([], X) -> X;
count([_|B], X) ->
    Y = X+1,
    count(B, Y).

An example run:

erlang> count([a,b,c,d,e],0).

The 2nd clause fits the pattern I described earlier of:

<do stuff>
<tail recursion>

I guess this particular example maps onto the Haskell "let... in" someone described here. But what if there needs to be 10 "do stuffs", or 20, or more? And is this "let... in" guaranteed to be tail recursive (the above example is guaranteed to be in erlang, prolog, scheme, etc).

Is there a way I can simply "string together" or "sequence" a bunch of statements or expressions? In prolog or erlang the sequencing is accomplished by the comma (see toy example above). In c/c++ it is accomplished by the semicolon. I thought the Haskell operator was simply whitespace, but perhaps it just isn't done in this language?

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What is sequencing of expressions supposed to do? Evaluate the first, discard it, evaluate and result in the second? That does not make sense, evaluating pure code never has any side effects. –  delnan Mar 31 '12 at 10:12
I suggest you study the syntax of Haskell a little before you start writing code. Statements in Haskell are introduced by do and only relevant in monadic code. –  augustss Mar 31 '12 at 10:29
Perhaps you are looking for let ... in ...? (Not sequencing: introducing variables and then using them in a subsequent expression.) Without knowing what your simple program is trying to do, we can't help you with it. –  dave4420 Mar 31 '12 at 11:02
@delnan: It does make sense in some cases (you just described what seq does), but not here. –  hammar Mar 31 '12 at 14:14
If the "do stuff" you want to do is introduce new bindings, then a let expression will suffice. You can introduce multiple bindings in a single let statement by separating them with newlines, or with semicolons. Additionally, tail recursion is meaningless in the presence of non-strictness; the Haskell stack works much differently than a strict language's stack does. In regards to your final question, I stand by my original answer: in Haskell you compose. For IO actions, this is often done with >>=. For pure functions, . is the canonical composition operator. –  Dan Burton Mar 31 '12 at 23:08

6 Answers 6

Update: Be careful that you’re not writing Scheme programs in Haskell. Accumulating parameters are rare in idiomatic Haskell, which uses laziness rather than tail recursion.

For example, the definition of count in Haskell will resemble

count [] = 0
count (x:xs) = 1 + count xs

You might object that the source of length looks more Scheme-ish

-- | /O(n)/. 'length' returns the length of a finite list as an 'Int'.
-- It is an instance of the more general 'Data.List.genericLength',
-- the result type of which may be any kind of number.
length                  :: [a] -> Int
length l                =  len l 0#
    len :: [a] -> Int# -> Int
    len []     a# = I# a#
    len (_:xs) a# = len xs (a# +# 1#)

but this is low-level, non-idiomatic code. The referenced genericLength has the same structure as count above and has broader applicability when compared to length.

genericLength           :: (Num i) => [b] -> i
genericLength []        =  0
genericLength (_:l)     =  1 + genericLength l

“Do this and then do that” in Haskell is expressed as function composition in pure code. For example, to compute the length of the longest sublist, we’d compute the sublists’ lengths and then the maximum over those lengths. In Haskell, that’s expressed

Prelude> :t maximum . map length
maximum . map length :: [[a]] -> Int


Prelude> :m + Data.List 
Prelude Data.List> :t maximum . map genericLength
maximum . map genericLength :: (Ord c, Num c) => [[b]] -> c

Note: laziness adds nuance, but the general point holds.

Even in “imperative” code inside IO such as

main :: IO ()
main = do
  putStr "Hello "
  purStrLn "world!"

is function composition under the covers because it has the same semantics as

main :: IO ()
main = putStr "Hello " >>= \_ -> putStrLn "world!"

Perhaps an example that uses the list monad will make this clearer. Say we want all Pythagorean triples (a,b,c) such that no component is greater than some maximum n.

import Control.Monad (guard)

triples :: Integer -> [(Integer,Integer,Integer)]
triples n = do
  a <- [1 .. n]
  b <- [a .. n]
  c <- [b .. n]
  guard $ a*a + b*b == c*c
  return (a,b,c)

As you can see, we must first choose a candidate value of a, then of b, and so on.

The compiler transforms this code to explicitly use >>=, the monadic bind combinator.

-- indented to show nested scopes
triples_bind :: Integer -> [(Integer,Integer,Integer)]
triples_bind n =
  [1 .. n] >>= \a ->
    [a .. n] >>= \b ->
      [b .. n] >>= \c ->
        (guard $ a*a + b*b == c*c) >>= \_ ->
          return (a,b,c)

Inside the list monad, >>= is concatMap, so the above is identical to

triples_stacked :: Integer -> [(Integer,Integer,Integer)]
triples_stacked n =
  concatMap (\a ->
    concatMap (\b ->
      concatMap (\c ->
        concatMap (\_ ->
          (guard $ a*a + b*b == c*c))
        [b .. n])
      [a .. n])
    [1 .. n]

The indentation shows structure and is pleasing because it gives the impression of the Haskell logo that combines λ with >>=.

Yet another way to express the same semantics is

triples_cm n = concatMap step2 [1 .. n]  -- step 1
  where step2 a = concatMap step3 [a .. n]
          where step3 b = concatMap step4 [b .. n]
                  where step4 c = concatMap step5 (guard $ a*a + b*b == c*c)
                          where step5 _ = [(a,b,c)]

Haskell’s pattern matching already does case matching behind the scenes. Instead of

go 0 = 0
go i =  case i of
            1 -> 2
            _ -> 3
        go (i-1)

finish the pattern you started.

go 0 = 0
go 1 = go (2 - 1)
go _ = go (3 - 1)

Remember that variables in Haskell are immutable: they do not have destructive update as in C or Java. You get one shot at defining a variable’s value, and then you’re stuck with it. You might instead define go as

go 0 = 0
go x = let i = case x of 1 -> 2
                         _ -> 3
       in go (i - 1)


go 0 = 0
go x | x == 1    = go (2 - 1)
     | otherwise = go (3 - 1)

The examples above all typecheck but have the same big problem, namely that go terminates only when its argument is zero. You didn’t provide enough information for us to help with that problem. Tell us what it is you’re trying to do, and we can offer specific advice for your situation.

share|improve this answer
yup, already know haskell does pattern matching / case matching behind the scenes, and that the toy example could have been converted to your example. the point was simply to create an expression that "did stuff", thus the case statement (it could have been any other statement/expression). see edit at the top of my post for count function which is less of a "toy" example (although still a toy example). the point isn't to focus on any particulars though, but rather "how do you have several expressions or statements in 1 function (i.e. 'sequencing'), or is it possible?" –  X Y Z Mar 31 '12 at 19:25
@XYZ See updated answer. Try not to speak Haskell with an imperative accent. Yes, you can express explicit sequencing in IO, but that should be the exception. Keep most of your code in the nice, happy purely functional world with the thinnest imperative skin possible for interacting with the outside world. –  Greg Bacon Mar 31 '12 at 21:08
didn't know i was speaking "imperative" per se. do you consider the erlang example i posted to be imperative code? it has "sequencing" but i figured most people would call it a "functional" style (btw, when I say "sequencing" i don't necessarily mean IO, i just mean "expressions in a sequence"), and it has no destructive updates. either way, thanks so much for that in-depth explanation! very insightful! –  X Y Z Mar 31 '12 at 23:09
@XYZ: Your count example would become count [] x = x; count (_:bs) x = count bs (1 + x) -- or you could write it with count [] x = x; count (_:bs) x = let y = x + 1 in count bs x or equivalently count [] x = x; count (_:bs) x = count bs y where y = x + 1. you are looking for a let or where clause to make those local names for you, but these aren't ordered effects, let doesn't make things happen, just allows you to reference shared values/computations. –  Edward KMETT Apr 3 '12 at 1:28

It is very good that you were able to provide an Erlang code example of what you mean by 'doing stuff'. Until now it's been a little vague. So long as the discussion is only about strict languages, it's okay to be somewhat vague on that point since the rules are fairly uniform and understood.

On the other hand, we are talking about Haskell, a language with 'lazy' evaluation, so it is good to be very specific about what 'doing stuff' means, otherwise there is likely to be confusion due to incorrect assumptions.

Here's a fairly direct translation of the Erlang function you provided in Haskell:

count ([],x) = x
count (_:b, x) =
    let y = x + 1
    in count (b, y)

As you can see, it's pretty much identical in structure to the Erlang version. As such, you may be wondering what is the big deal? If it's that easy to 'do stuff' in Haskell, then why is everyone making it sound so complicated?

One way to explain what is the big deal is to point out that the above Haskell function is equivalent to this one:

count ([],x) = x
count (_:b, x) = count (b, x + 1)

Also this one:

count ([],x) = x
count (_:b, x) = count (b, y) where y = x + 1

This is because the order in which Haskell evaluates expressions does not depend on the lexical order of those expressions. In general, Haskell will delay expression evaluation to the last possible moment.

Now when you think about composing this scheme of lazy evaluation together with side-effects (reading or writing files, sending output to the screen, etc.), it gets a little fuzzy. The order in which side-effects happen is generally very important. Fortunately, functions in Haskell that deal with side-effects generally do not perform the side-effecting action themselves. Rather they produce an 'action' value that describes the side-effect. Then there are other functions that can compose these 'action' values in a way that respects order. Then you just need something that will actually perform the side-effects that are described by the 'action' values...

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Obligatory meme

In Haskell, you don't write functions that "do stuff". You write functions that compute a value. In that light, it makes no sense to structure a function in the way you suggest:

f = <do stuff 1>
    <do stuff 2>

Instead, you write an actual, math-y function, which is a single expression dependent on certain inputs:

f x y = blah x blah y blah

It might be convenient to break it up into sub-expressions

f x y = res1 + res2
  where res1 = x * 3
        res2 = y + 4

But in the end, it is just a single expression.

Monadic code written in do notation can appear to "do stuff" sequentially:

f = do

But this is just an illusion. It desugars into a single expression as well:

f = thing1 >> thing2

This expression states that f is a value which is the composition of thing1 and thing2. Now, IO code might compile to code that "does stuff" sequentially, but that's not what it means in Haskell. One does not simply "do stuff" in Haskell. Instead, you compose.

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+1 for a decent explanation that makes clever use of an internet meme. –  delnan Mar 31 '12 at 16:14
your haskell code appears to be sequential, in that res1 and res2 are computed before res1+res2 are computed, no? so can you accomplish the same thing with your do? –  X Y Z Mar 31 '12 at 19:26
@XYZ: res1 and res2 aren't necessarily computed before the expression. (They are in this case, but not just because they were defined in the while clause.) Because Haskell is lazy, the compiler is free to reorder those computations however it wants. You're not specifying an execution order; you're just specifying how to compute res1 and res2 whenever they're needed. –  Louis Wasserman Mar 31 '12 at 19:34
For example, if it was f x y = if res2 /= 0 then res1 else 0 where ..., then res1 wouldn't necessarily get computed at all unless res2 was nonzero. –  Louis Wasserman Mar 31 '12 at 19:36

I'm not sure got correctly what your function has to do. May be you need something like this:

go :: Int -> Int
go 0 = 0
go i = go (i-1)

if that function takes argument e.g. '3' it calculates go 3 -> go 2 -> go 1 -> go 0 -> 0 and get answer '0'

Now if you want some sequencing you can use keyword 'do', but I am sure it is now what you need. If you are trying to create some kind of 'variables' look at 'let' & 'in' statements :

someInput = 7

gogogo 0  = 0
gogogo n = 
        gavk = n + 1
        kravk = gavk * 2
        out = kravk + 1

main = 
       putStrLn "this is sample do statement"
       putStrLn "gogogo:"
       putStrLn $ gogogo someInput 

UPD. edited mistypes

share|improve this answer
What are imput, input, and gogogo? –  Andre Mar 31 '12 at 11:27
You can't use in as a variable name. –  augustss Mar 31 '12 at 11:29

When you say "do stuff", what do you mean?

  • calculate something, transform data we already have?
  • interact with the user, read/write a file, download something from the web?

In the first case, use let...in:

quadraticRoots a b c = let discriminant = b * b - 4 * a * c
                           root = sqrt discriminant
                       in case compare discriminant 0 of
                               LT -> []
                               EQ -> [-b / (2 * a)]
                               GT -> [(-b + root) / (2 * a), (-b - root) / (2 * a)]

In the second case, use do notation:

main = do args <- getArgs
          case map read args of
               [a, b, c] -> putStrLn $ case quadraticRoots a b c of
                                            [] -> "no real roots"
                                            [x] -> "single root: " ++ show x
                                            [x1, x2] -> unwords ["two real roots:", show x1,
                                                                 "and", show x2]
               _ -> hPutStrLn stderr "Please provide three coefficients on the command line"
share|improve this answer
I suggest sqrt instead of (** 0.5), it's faster and more descriptive. –  augustss Mar 31 '12 at 11:30

Basically, there is no way to do it. Haskell is a purely functional language, there is neither change nor order of statements. One way to simulate sequence are monads. There are plenty of tutorials in the internet, I personally advise you to read the monad-chapters of Learn You A Haskell For Great Good! or Real World Haskell. Another thing is: Sequential operations are not very idiomatic in Haskell. You should better start with something different.

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I strongly disagree with "there is no way to do it". I'd say instead "there is a universal way to do it, and you can express uniformly whatever you could ever mean by 'sequencing' with it" (always stay positive !) –  Alexandre C. Mar 31 '12 at 11:04
@AlexandreC That's what I wanted to hint by »One way to simulate sequence...«. Your wording is probably better, feel free to adjust my answer. –  FUZxxl Mar 31 '12 at 11:06

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