2

I have the following problem:

I want to read from a file line by line and write the lines to another file. However, I want to return the number of lines.

Therefore, inside a pure function I would use an accumulator like this:

function parameters=method 0 ......
                    method accu  {end case scenario} =accu
                    method accu  {not end case} = accu+1 //and other stuff

How can I achieve the same in a do-block without using another function?

Concrete example

module Main where 

    import System.IO
    import Data.Char(toUpper)


    main::IO()
    main=do
        let inHandle=openFile "in.txt" ReadMode
        let outHandle=openFile "out.txt" WriteMode
        inHandle>>= \a ->outHandle>>= \b ->loop a b 0>>=print . show 


    loop::Handle->Handle->Int->IO Int
    loop inh outh cnt=hIsEOF inh>>= \l ->if l then return elem
                                        else
                                            do
                                                hGetLine inh>>=hPutStrLn outh
                                                loop inh outh (cnt+1)

Edit

Refactored the way loop gets its parameters

P.S 2 (after K. A. Buhr's thorough response)

I. What I really wanted to achieve, was the last expression of the main method. I wanted to take the multiple IO Actions and bind their results to a method. Specifically:

inHandle>>= \a ->outHandle>>= \b ->loop a b 0>>=print . show

What I do not understand in this case is:

If inHandle>>= is supplied to \a -> and then the result is passed to ...>>=\b, do the variables inside the outer scope get closured in \b?

If not, shouldn't it be >>=\a->..>>= \a b? Shouldn't the inner scope hold a parameter corresponding to the result of the outer scope?

Eliminating the do inside the helper method

What I wanted to know, is if there is a way to glue together multiple actions without them being in a do block.

In my case:

loop::Handle->Handle->Int->IO Int
        loop inh outh cnt=hIsEOF inh>>= \l ->if l then return elem
                                            else
                                                do
                                                    hGetLine inh>>=hPutStrLn outh
                                                    loop inh outh (cnt+1)

Can't I say something like:

if ... then ...
else
hPutStrLn=<<action1 [something] v2=<<action2 [something] loop inh outh (cnt+1)

where something could be an operator? I do not know, that is why I am asking.

7
  • 1
    Why do you not want to use another function? That would be the 'normal' way to do something like this in Haskell.
    – Cubic
    Jul 24, 2018 at 14:40
  • 6
    You are making the same mistake with let inHandle = (=<<ioIn) that was pointed out in your previous question. Please fix your code here using the answer you accepted before trying to ask further questions about this.
    – chepner
    Jul 24, 2018 at 14:44
  • 1
    Use loop :: Handle -> Handle -> Int -> IO Int as the type instead, and pass 0 as the initial integer accumulator. In the recursive call, you can use loop ioIn ioOut (accu+1)
    – chi
    Jul 24, 2018 at 18:01
  • 1
    You cannot create a new binding with >>=. >>= is just a function (so its arguments must already exist). In a do block, you can only create a new binding with let or <- Jul 24, 2018 at 18:48
  • 1
    inHandle>>= \a ->outHandle>>= \b ->loop a b 0>>=print . show is really inHandle >>= (\a -> outHandle >>= (\b ->loop a b 0 >>= (print . show))) so when we get to the (print . show) both b and a are in scope -- the second ( \b -> ...) lambda is nested inside the first ( \a -> ... ) lambda.
    – Will Ness
    Jul 28, 2018 at 9:52

1 Answer 1

6

It looks like the answer to your last question still left you confused.

tl;dr: stop using >>= and =<< until you master the do-block notation which you can do by Googling "understanding haskell io" and working through lots of examples from tutorials.

Long answer...

First, I would suggest avoiding the >>= and =<< operators for now. Even though they are sometimes named "bind", they don't bind variables or bind parameters to methods or anything else like that, and they seem to be tripping you up. You may also find the section about IO from "A Gentle Introduction to Haskell" helpful as a quick introduction to how IO works.

Here's a very short explanation of IO that may help you, and it'll provide a basis for answering your question. Google for "understanding haskell io" to get a more in-depth explanation:

Super short IO explanation in three paragraphs:

(1) In Haskell, any value of type IO a is an IO action. An IO action is like a recipe that can be used (by executing the action) to perform some actual input/output and then produce a value of type a. So, a value of type IO String is an action that, if executed, will perform some input/output and produce a value of type String, while an IO () is an action that, if executed, will perform some input/output and produce a value of type (). In the latter case, because values of type () are useless, actions of type IO () are normally executed for their I/O side effects, such as printing a line of output.

(2) The only way to execute an IO action in a Haskell program is to give it the special name main. (The interactive interpreter GHCi provides more ways to execute IO actions, but let's ignore that.)

(3) IO actions can be combined using do-notation into a larger IO action. A do block consists of lines of the following form:

act             -- action to be executed, with the result
                -- thrown away (unless it's the last line)

x <- act        -- action to be executed, with the result
                -- named @x@ for later lines

let y = expr    -- add a name @y@ for the value of @expr@
                -- for later lines, but this has nothing to
                -- do with executing actions

In the above templates, act can be any expression that evaluates to an IO action (i.e., a value of type IO a for some a). It's important to understand that the do-block does not itself execute any IO actions. Instead, it builds a new IO action that -- when executed -- will execute the given set of IO actions in the order they appear in the do-block, either throwing away or naming the values produced by executing these actions. The value produced by executing the whole do-block will be the value produced by the last line of the do-block (which has to be a line of the first form above).

A simple exmple

Therefore, if a Haskell program includes:

myAction :: IO ()
myAction = do
  putStrLn "Your name?"
  x <- getLine
  let stars = "***"
  putStrLn (stars ++ x ++ stars)

then this defines a value myAction of type IO (), an IO action. By itself, it does nothing, but if it is ever executed, then it will execute each of the IO actions (values of type IO a for various types a) in the do-block in the order they appear. The value produced by executing myAction will be the value produced by the last line (in this case, the value () of type ()).

Applied to the problem of copying lines

Armed with this explanation, let's tackle your question. First, how do we write a Haskell program to copy lines from one file to another using a loop, ignoring the problem of counting lines? Here's one way that's fairly similar to your code example:

import System.IO

myAction :: IO ()
myAction = do
  inHandle <- openFile "in.txt" ReadMode
  outHandle <- openFile "out.txt" WriteMode
  loop inHandle outHandle
  hClose outHandle
  hClose inHandle

Here, if we check the type of one of these openFile calls in GHCi:

> :t openFile "in.txt" ReadMode
openFile "in.txt" ReadMode :: IO Handle
>

we see that it has type IO Handle. That is, this is an IO action that, when executed, performs some actual I/O (namely an operating system call to open a file) and then produces a value of type Handle, which is the Haskell value representing the open file handle. In your original version, when you wrote:

let inHandle = openFile "in.txt" ReadMode

all this did was assign a name inHandle to an IO action -- it didn't actually execute the IO action and so didn't actually open the file. In particular, the value of inHandle of type IO Handle was not itself a file handle, just an IO action (or "recipe") for producing a file handle.

In the version of myAction above, we've used the notation:

inHandle <- openFile "in.txt" ReadMode

to indicate that, if and when the IO action named by myAction is ever executed, it will start by executing the IO action openFile "in.txt" ReadMode" (that is, the value of that expression which has type IO Handle), and that execution will produce a Handle which will be named inHandle. Ditto for the next line to produce and name an open outHandle. We will then pass these open handles to loop in the expression loop inHandle outHandle.

Now, loop can be defined like so:

loop :: Handle -> Handle -> IO ()
loop inHandle outHandle = do
  end <- hIsEOF inHandle
  if end
    then return ()
    else do
      line <- hGetLine inHandle
      hPutStrLn outHandle line
      loop inHandle outHandle

It's worth taking a moment to explain this. loop is a fuction that takes two arguments, each Handle. When it's applied to two handles, as in the expression loop inHandle outHandle, the resulting value is of type IO (). That means it's an IO action, specifically, the IO action created by the outer do-block in the definition of loop. This do-block creates an IO action that -- when it is executed -- executes two IO actions in order, as given by the lines of the outer do-block. The first line is:

end <- hIsEOF inHandle

which takes the IO action hEof inHandle (a value of type IO Bool), executes it (which consists of asking the operating system if we've reached the end of file for the file represented by handle inHandle), and names the result end -- note that end will be a value of type Bool.

The second line of the do-block is the entire if statement. It produces a value of type IO (), so a second IO action. The IO action depends on the value of end. If end is true, the IO action will be the value of return () which, if executed, will perform no actual I/O and will produce a value () of type (). If end is false, the IO action will be the value of the inner do-block. This inner do-block is an IO action (a value of type IO ()) which, if executed, will execute three IO actions in order:

  1. The IO action hGetLine inHandle, a value of type IO String that, when executed, will read a line from inHandle and produce the resulting String. As per the do-block, this result will be given the name line.

  2. The IO action hPutStrLn outHandle line, a value of type IO () that, when exectued, will write line to outHandle.

  3. The IO action loop inHandle outHandle, a recursive use of the IO action produced by the outer do-block, which -- when executed -- starts the whole process over again, starting with the EOF check.

If you put these two definitions (for myAction and loop) in a program, they won't do anything, because they're just definitions of IO actions. The only way to have them execute is to name one of them main, like so:

main :: IO ()
main = myAction

Of course, we could have just used the name main in place of myAction to get the same effect, as in the whole program:

import System.IO

main :: IO ()
main = do
  inHandle <- openFile "in.txt" ReadMode
  outHandle <- openFile "out.txt" WriteMode
  loop inHandle outHandle
  hClose inHandle
  hClose outHandle

loop :: Handle -> Handle -> IO ()
loop inHandle outHandle = do
  end <- hIsEOF inHandle
  if end
    then return ()
    else do
      line <- hGetLine inHandle
      hPutStrLn outHandle line
      loop inHandle outHandle

Take some time to compare this to your "concrete example" above, and see where it's different and where it's simliar. In particular, can you figure out why I wrote:

end <- hIsEOF inHandle
if end
  then ...

instead of:

if hIsEOF inHandle
  then ...

Copying lines with a line count

To modify this program to count lines, a fairly standard way to do it would be to make the count a parameter to the loop function, and have loop produce the final value of the count. Since the expression loop inHandle outHandle is an IO action (above, it's of type IO ()), to have it produce a count we need to give it type IO Int, as you've done in your example. It will still be an IO action but now -- when it is executed -- it'll produce a useful Int value instead of a useless () value.

To make this change, main will have to invoke loop with a starting counter, name the value it produces, and output that value to the user.

To make it absolutely clear: main's value is still an IO action created by a do-block. We're just modifying one of the lines of the do-block. It used to be:

loop inHandle outHandle

which evaluated to a value of type IO () representing an IO action that -- when the whole do-block was executed -- would be executed when its turn came to copy the lines from one file to the other before producing a () value to be thrown away. Now, it's going to be:

count <- loop inHandle outHandle 0

where the right-hand side will evaluate to a value of type IO Int representing an IO action that -- when the whole do-block is executed -- will be executed when its turn comes to copy the lines from one file to the other before producing a count value of type Int to be named count for later do-block steps.

Anyway, the modified main looks like this:

main :: IO ()
main = do
  inHandle <- openFile "in.txt" ReadMode
  outHandle <- openFile "out.txt" WriteMode
  count <- loop inHandle outHandle 0
  hClose inHandle
  hClose outHandle
  putStrLn (show count)    -- could just write @print count@

Now, we rewrite loop to maintain a count (taking the running count as a parameter through recursive calls and producing the final value when the IO action is executed):

loop :: Handle -> Handle -> Int -> IO Int
loop inHandle outHandle count = do
  end <- hIsEOF inHandle
  if end
    then return count
    else do
      line <- hGetLine inHandle
      hPutStrLn outHandle line
      loop inHandle outHandle (count + 1)

The whole program is:

import System.IO

main :: IO ()
main = do
  inHandle <- openFile "in.txt" ReadMode
  outHandle <- openFile "out.txt" WriteMode
  count <- loop inHandle outHandle 0
  hClose inHandle
  hClose outHandle
  putStrLn (show count)    -- could just write @print count@

loop :: Handle -> Handle -> Int -> IO Int
loop inHandle outHandle count = do
  end <- hIsEOF inHandle
  if end
    then return count
    else do
      line <- hGetLine inHandle
      hPutStrLn outHandle line
      loop inHandle outHandle (count + 1)

The rest of your question

Now, you asked about how to use an accumulator within a do-block without using another function. I don't know if you meant without using another function besides loop (in which case the answer above satisfies the requirement) or if you meant without using any explicit loop at all.

If the latter, there are a couple of approaches. First, there are monadic loop combinators available in the monad-loops package that can allow you to do the following (to copy without counting). I've also switched to using withFile in place of explicit open/close calls:

import Control.Monad.Loops
import System.IO
main :: IO ()
main =
  withFile "in.txt" ReadMode $ \inHandle ->
  withFile "out.txt" WriteMode $ \outHandle ->
    whileM_ (not <$> hIsEOF inHandle) $ do
      line <- hGetLine inHandle
      hPutStrLn outHandle line

and you can count lines with a state monad:

import Control.Monad.State
import Control.Monad.Loops
import System.IO
main :: IO ()
main = do
  n <- withFile "in.txt" ReadMode $ \inHandle ->
       withFile "out.txt" WriteMode $ \outHandle ->
       flip execStateT 0 $
         whileM_ (not <$> liftIO (hIsEOF inHandle)) $ do
           line <- liftIO (hGetLine inHandle)
           liftIO (hPutStrLn outHandle line)
           modify succ
  print n

With respect to removing the last do block from the definition of loop above, there's no good reason to do this. It's not like do blocks have overhead or introduce some extra processing pipeline or something. They're just ways of constructing IO action values. So, you could replace:

else do
  line <- hGetLine inHandle
  hPutStrLn outHandle line
  loop inHandle outHandle (count + 1)

with

else hGetLine inHandle >>= hPutStrLn outHandle >> loop inHandle outHandle (count + 1)

but this is a purely syntactic change. The two are otherwise identical (and will almost certainly compile to equivalent code).

5
  • IORef would be easier for a beginner to handle than StateT imo, but otherwise this is an excellent answer
    – Jon Purdy
    Jul 25, 2018 at 22:02
  • I find the "is an IO action" language extremely confusing, even with the immediate qualifier about it being a "recipe". I think just saying "is an IO action recipe" right away is much much clearer. Could not agree more about starting with the do notation. (just thought of something -- what about using "Doable" for Monads, as the parallel of "Mappable" for Functors...? as hints for the newbies of course, not as a serious naming proposal.)
    – Will Ness
    Jul 26, 2018 at 16:54
  • contd. so, it would read as "(1) In Haskell, any value of type IO a is an I/O actions recipe. This recipe describes some I/O actions that can be executed to perform some actual input/output resulting in producing some value of type a. So, a value of type IO String is an I/O actions recipe that, if executed, will perform those input/output actions and produce a value of type String as a result. ... (3) Several I/O actions recipes can be combined using do-notation into a single combined I/O actions recipe" .... For your consideration. :) (haven't yet read the rest...)
    – Will Ness
    Jul 26, 2018 at 17:17
  • (cf. a related answer by Conor McBride, with a picture).
    – Will Ness
    Jul 26, 2018 at 17:24
  • but, having read through more of your excellent answer, I see that this change would necessitate a pretty extensive re-write, so, never mind. :) (to clarify: "action" is confusing to me because, for me, "action" is something that is already being executed, is already being performed).
    – Will Ness
    Jul 26, 2018 at 17:39

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