Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I have a simple task - read a bunch of lines out of a file and do something with each one of them. Except the first one - which are some headings to be ignored.

So I thought I'd try out conduits.

printFile src = runResourceT $ CB.sourceFile src =$= 
    CT.decode CT.utf8 =$= CT.lines =$= CL.mapM_ putStrLn


So now I just want to drop the first line off ... and there seems to be a function for that -

printFile src = runResourceT $ CB.sourceFile src =$= 
    CT.decode CT.utf8 =$= CT.lines =$= drop 1 =$= CL.mapM_ putStrLn

Hmm - but now I notice drop has type signature Sink a m (). Someone suggested to me that I can use the Monad instance for pipes and use drop to effectfully drop some elements - so I tried this:

drop' :: Int -> Pipe a a m ()
drop' n = do
  CL.drop n
  x <- await
  case x of 
    Just v -> yield v
    Nothing -> return ()

Which doesn't type check because the monad instance for pipes only applies to pipes of the same type - Sinks have Void as their output, so I can't use it like this.

I took a quick look at pipes and pipes-core and I notice that pipes-core has the function as I expected it to be, where as pipes is a minimal library but the documentation shows how it would be implemented.

So I'm confused - maybe there's a key concept I'm missing .. I saw the function

sequence ::  Sink input m output -> Conduit input m output

But that doesn't seem to be the right idea, as the output value is ()

CL.sequence (CL.drop 1) :: Conduit a m ()    

I'll probably just go back and use lazy-io as I don't really need any streaming - but I'd be interested to see the proper way to do it.

share|improve this question

1 Answer 1

up vote 5 down vote accepted

Firstly, the simple answer:

... =$= CT.lines =$= (CL.drop 1 >> CL.mapM_ putStrLn)

The longer explanation: there are really two different ways you can implement drop. Either way, it will first drop n elements from the input. There are two choices about what it does next:

  • Says it's done
  • Start outputting all of the remaining items from the input stream

The former behavior is what a Sink would perform (and what our drop actually does) while the latter is the behavior of a Conduit. You can in fact generate the latter from the former through monadic composition:

dropConduit n = CL.drop n >> CL.map id

Then you can use dropConduit as you describe at the beginning. This is a good way of demonstrating the difference between monadic composition and fusing; the former allows two functions to operate on the same input stream, while the latter allows one function to feed a stream to the other.

I haven't benchmarked, but I'm fairly certain that monadic composition will be a bit more efficient.

share|improve this answer
Hmm - the simple answer works well, thanks. dropConduit is Monad m => Int -> Pipe Void Void m () which I think makes it rather hard to use for anything I think? –  Oliver Jun 1 '12 at 5:24
Sorry, I'm working on a different version of the codebase where that wouldn't apply. In conduit 0.4, you'd need to have sinkToPipe (CL.drop n) >> CL.map id. The issue is that the types in Data.Conduit.List are overly restrictive. conduit 0.5 will be relaxing them. –  Michael Snoyman Jun 1 '12 at 9:06
Ahh - cheers. That makes sense. –  Oliver Jun 3 '12 at 7:46

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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