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My context is bioinformatics, next-generation sequencing in particular, but the problem is generic; so I will use a log file as an example.

The file is very large (Gigabytes large, compressed, so it will not fit in memory), but is easy to parse (each line is an entry), so we can easily write something like:

parse :: Lazy.ByteString -> [LogEntry]

Now, I have a lot of statistics that I would like to compute from the log file. It is easiest to write separate functions such as:

totalEntries = length
nrBots = sum . map fromEnum . map isBotEntry
averageTimeOfDay = histogram . map extractHour

All of these are of the form foldl' k z . map f.

The problem is that if I try to use them in the most natural way, like

main = do
    input <- Lazy.readFile "input.txt"
    let logEntries = parse input
        totalEntries' = totalEntries logEntries
        nrBots' = nrBots logEntries
        avgTOD = averageTimeOfDay logEntries
    print totalEntries'
    print nrBots'
    print avgTOD

This will allocate the whole list in memory, which is not what I want. I want the folds to be done synchronously, so that the cons cells can be garbage collected. If I compute only a single statistic, this is what happens.

I can write a single big function that does this, but it is non-composable code.

Alternatively, which is what I have been doing, I run each pass separately, but this reloads & uncompresses the file each time.

share|improve this question
Why don't you make logAnalysers :: [(K, Z, F)] where K, Z, F are the types of the functions k, z, f in your example? Then it becomes "composable" code, in a way, if you have a single fold that uses the list. – dflemstr May 29 '12 at 16:55
@dflemstr the intermediate types are not always the same :( – luispedro May 29 '12 at 17:30
You could do logAnalysers :: [forall a b c . (b -> c -> b, c, a -> b)], which would allow for different types... – dflemstr May 29 '12 at 18:15
up vote 11 down vote accepted

This a comment on the comment of sdcvvc referring to this 'beautiful folding' essay It was so cool -- beautiful, as he says -- I couldn't resist adding Functor and Applicative instances and a few other bits of modernization. Simultaneous folding of, say, x y and z is a straightforward product: (,,) <$> x <*> y <*> z. I made a half-gigabyte file of small random ints and it took 10 seconds to give the -- admittedly trivial -- calculation of length, sum and maximum on my rusty laptop. It doesn't seem to be helped by further annotations, but the compiler could see Int was all I was interested in; the obvious map read . lines as a parser led to a hopeless space and time catastrophe so I unfolded with a crude use of ByteString.readInt; otherwise it is basically a Data.List process.

{-# LANGUAGE GADTs, BangPatterns #-}

import Data.List (foldl', unfoldr)
import Control.Applicative 
import qualified Data.ByteString.Lazy.Char8 as B

main = fmap readInts (B.readFile "int.txt") >>= print . fold allThree
  where allThree = (,,) <$> length_ <*> sum_ <*> maximum_

data Fold b c where  F ::  (a -> b -> a) -> a -> (a -> c) -> Fold b c
data Pair a b = P !a !b

instance Functor (Fold b) where  fmap f (F op x g) = F op x (f . g)

instance Applicative (Fold b) where
  pure c = F const () (const c)
  (F f x c) <*> (F g y c') = F (comb f g) (P x y) (c *** c')
    where comb f g (P a a') b = P (f a b) (g a' b)
          (***) f g (P x y) = f x ( g y)

fold :: Fold b c -> [b] -> c
fold (F f x c) bs = c $ (foldl' f x bs)

sum_, product_ :: Num a => Fold a a
length_ :: Fold a Int
sum_     = F (+) 0 id
product_ = F (*) 1 id
length_  = F (const . (+1)) 0 id
maximum_ = F max 0 id
readInts  = unfoldr $ \bs -> case B.readInt bs of
  Nothing      -> Nothing
  Just (n,bs2) -> if not (B.null bs2) then Just (n,B.tail bs2) 
                                      else Just (n,B.empty)

Edit: unsurprisingly, since we have to do with an unboxed type above, and an unboxed vector derived from e.g. a 2G file can fit in memory, this is all twice as fast and somewhat better behaved if it is given the obvious relettering for Data.Vector.Uboxed Of course this isn't relevant where one has types like LogEntry Note though that the Fold type and Fold 'multiplication' generalizes over sequential types without revision, thus e.g. the Folds associated with operations on Chars or Word8s can be simultaneously folded directly over a ByteString. One must first define a foldB, by relettering fold to use the foldl's in the various ByteString modules. But the Folds and products of Folds are the same ones you would fold a list or vector of Chars or Word8s

share|improve this answer
see also – sdcvvc Jun 1 '12 at 21:44

To process lazy data muiltiple times, in constant space, you can do three things:

  • re-build the lazy list from scratch n times
  • fuse n passes into a single sequential fold that does each step, in lock step.
  • use par to do n parallel traversals at the same time

Those are your options. The last one is the coolest :)

share|improve this answer
It the last one guaranteed, though? What if one thread is much more computationally intensive? – luispedro May 29 '12 at 16:48
It's not guaranteed. You have n threads racing along the spine of a shared structure as it is being unfolded. IF one is slow, you may retain more of the structure than you planned. – Don Stewart May 29 '12 at 16:51
Option 2 is the one I'd choose, if possible. (I think it's even doable generically, regardless of the details of the folds...) – Louis Wasserman May 29 '12 at 17:33
for option 2, see also – sdcvvc May 29 '12 at 17:41
Note that the iteratee/enumerator style is squarely aimed at this issue, using option 2. – John L May 30 '12 at 2:29

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