The beauty of functional programming is that there doesn't have to be a conflict between those who prefer explicit and those who prefer implicit recursion. Think of them as different views on the same functions - just as with graphical visualizations, pick the view best suited to your purpose and use equational reasoning to transform one view into another, as needed.
Improving your experience in reasoning about code is going to help at every level of abstraction, and since you've already paid the price (using a pure language, to make reasoning easier) you might as well avail yourself of the facilities;-) While developing, I might prefer abstraction, as fewer details mean that I can hold more of the problem in my head at any point, increasing my chances of seeing all the way to a solution; if optimizing, or when I haven't found the right abstractions yet, I might have to resort to less abstract code until I've sorted out those details or until GHC deals with the more abstract forms as well as with the less abstract ones. Fine, you say, but I'd never would have thought of abstract views like splitAt as a state transformer. Okay, before this thread, I might not have thought of using that, either. But after this thread, I'd hope for it to become part of my thinking about Haskell code. And the way I do that is by taking the abstract code and unfold it (replacing instances of left-hand sides with instances of right-hand sides of definitions - the source links in the Haddock documentation are very useful for that) until I get to some less abstract code that I might have come up with. That doesn't mean that I'd have had the insights to play the derivation backwards, but by breaking the transformation from less abstract to more abstract view into smaller steps, starting from the abstract form that incorporates the additional insights I was missing, I can increase my understanding of what is going on, and my chances of noticing the opportunities next time. It also confirms whether or not the two solutions really are the same (as has been pointed out, that wasn't the case here). Paraphrasing and tweaking Sjur Gjøstein Karevoll's remark a little: clever Perl code is what you hope you understood in the past, when you wrote it; clever Haskell code is what you hope you'll understand in the future, when you'll write it yourself!-) The derivation below is best followed by replaying it yourself in your editor, but I hope you'll find it helpful anyway. Claus -- view transformation: reducing the level of abstraction -- by turning implicit to explict recursion takeList = evalState . mapM (State . splitAt) -- unfold 'mapM' takeList = evalState . sequence . map (State . splitAt) -- unfold 'sequence' takeList = evalState . foldr k (return []) . map (State . splitAt) where k m m' = do x<-m; xs<-m'; return (x:xs) foldr op n [] = n foldr op n (h:t) = h `op` foldr op n t -- specialize 'foldr' for the call paramenters 'k' and 'return []' takeList = evalState . foldrkn . map (State . splitAt) where k m m' = do x<-m; xs<-m'; return (x:xs) foldrkn [] = return [] foldrkn (h:t) = h `k` foldrkn t -- unfold 'k' takeList = evalState . foldrkn . map (State . splitAt) where foldrkn [] = return [] foldrkn (h:t) = do x<-h; xs<-foldrkn t; return (x:xs) -- foldr op n . map f = foldr (op.f) n takeList = evalState . foldrkn where foldrkn [] = return [] foldrkn (h:t) = do x<-State (splitAt h); xs<-foldrkn t; return (x:xs) -- unfold 'return' for 'State', eta-expand 'splitAt h' takeList = evalState . foldrkn where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = do x<-State (\s->splitAt h s); xs<-foldrkn t; State (\s->(x:xs,s)) -- eta-expand body of 'takeList' takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = do x<-State (\s->splitAt h s); xs<-foldrkn t; State (\s->(x:xs,s)) -- unfold the second '>>=' for 'State' takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = do x<-State (\s->splitAt h s) State (\s->let (xs,s') = runState (foldrkn t) s in runState (State (\s->(x:xs,s))) s') -- runState . State = id takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = do x<-State (\s->splitAt h s) State (\s->let (xs,s') = runState (foldrkn t) s in (\s->(x:xs,s)) s') -- beta-reduce takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = do x<-State (\s->splitAt h s) State (\s->let (xs,s') = runState (foldrkn t) s in (x:xs,s')) -- unfold the remainign '>>=' for 'State' takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = State (\s->let (x,s') = runState (State (\s->splitAt h s)) s in runState (State (\s->let (xs,s') = runState (foldrkn t) s in (x:xs,s'))) s') -- runState . State = id (2x) takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = State (\s->let (x,s') = (\s->splitAt h s) s in (\s->let (xs,s') = runState (foldrkn t) s in (x:xs,s')) s') -- beta-reduce (2x) takeList ns xs = evalState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = State (\s->let (x,s') = splitAt h s in let (xs,s'') = runState (foldrkn t) s' in (x:xs,s'')) -- unfold 'evalState' takeList ns xs = fst $ runState (foldrkn ns) xs where foldrkn [] = State (\s->([],s)) foldrkn (h:t) = State (\s->let (x,s') = splitAt h s in let (xs,s'') = runState (foldrkn t) s' in (x:xs,s'')) -- all calls to 'foldrkn' are wrapped in 'runState', bring it into the definition takeList ns xs = fst $ (foldrkn ns) xs where foldrkn [] = runState $ State (\s->([],s)) foldrkn (h:t) = runState $ State (\s->let (x,s') = splitAt h s in let (xs,s'') = (foldrkn t) s' in (x:xs,s'')) -- runState . State = id (2x) takeList ns xs = fst $ (foldrkn ns) xs where foldrkn [] = \s->([],s) foldrkn (h:t) = \s->let (x,s') = splitAt h s in let (xs,s'') = (foldrkn t) s' in (x:xs,s'') -- clean up takeList ns xs = fst (foldrkn ns xs) where foldrkn [] s = ([],s) foldrkn (h:t) s = let (x,s') = splitAt h s (xs,s'') = foldrkn t s' in (x:xs,s'') -- 'snd (foldrkn _ _)' is never used, remove it takeList ns xs = foldrkn ns xs where foldrkn [] s = [] foldrkn (h:t) s = let (x,s') = splitAt h s xs = foldrkn t s' in x:xs -- remove indirection takeList [] s = [] takeList (h:t) s = x : takeList t s' where (x,s') = splitAt h s _______________________________________________ Haskell-Cafe mailing list Haskell-Cafe@haskell.org http://www.haskell.org/mailman/listinfo/haskell-cafe