Difference between revisions of "Continuation"

General or introductory materials

Powerful metaphors, images

Here is a collection of short descriptions, analogies or metaphors, that illustrate this difficult concept, or an aspect of it.

Imperative metaphors

• In computing, a continuation is a representation of the execution state of a program (for example, the call stack) at a certain point in time (Wikipedia's Continuation).
• At its heart, call/cc is something like the goto instruction (or rather, like a label for a goto instruction); but a Grand High Exalted goto instruction... The point about call/cc is that it is not a static (lexical) goto instruction but a dynamic one (David Madore's A page about call/cc)

Functional metaphors

• Continuations represent the future of a computation, as a function from an intermediate result to the final result (Continuation monad section in Jeff Newbern's All About Monads)
• The idea behind CPS is to pass around as a function argument what to do next (Yet Another Haskell Tutorial written by Hal Daume III, 4.6 Continuation Passing Style, pp 53-56). It can be read also in wikified format.
• Rather than return the result of a function, pass one or more HigherOrderFunctions to determine what to do with the result (HaWiki's ContinuationPassingStyle). Yes, direct sum like things (or in generally, case analysis, managing cases, alternatives) can be implemented in CPS by passing more continuations.

External links

• The approriate section of Haskell: Functional Programming with Types.
• Wikipedia's Continuation is a surprisingly good introductory material on this topic. See also Continuation-passing style.
• Yet Another Haskell Tutorial written by Hal Daume III contains a section on continuation passing style (4.6 Continuation Passing Style, pp 53-56). It can be read also in wikified format, thanks to Eric Kow.
• HaWiki has a page on ContinuationPassingStyle, and some related pages linked from there, too.
• David Madore's A page about call/cc describes the concept, and his The Unlambda Programming Language page shows how he implemented this construct in an esoteric functional programming language.
• Continuations section of article Functional Programming For The Rest of Us, an introductory material to functional programming.

Examples

Citing haskellized Scheme examples from Wikipedia

Quoting the Scheme examples (with their explanatory texts) from Wikipedia's Continuation-passing style article, but Scheme examples are translated to Haskell, and some straightforward modifications are made to the explanations (e.g. replacing word Scheme with Haskell, or using abbreviated name fac instead of factorial).

In the Haskell programming language, the simplest of direct-style functions is the identity function:

 id :: a -> a
 id a = a

 idCPS :: a -> (a -> r) -> r
 idCPS a ret = ret a

 mysqrt :: Floating a => a -> a
 mysqrt a = sqrt a
 print (mysqrt 4) :: IO ()

 mysqrtCPS :: a -> (a -> r) -> r
 mysqrtCPS a k = k (sqrt a)
 mysqrtCPS 4 print :: IO ()

 mysqrt 4 + 2 :: Floating a => a

 mysqrtCPS 4 (+ 2) :: Floating a => a

 fac :: Integral a => a -> a
 fac 0 = 1
 fac n'@(n + 1) = n' * fac n
 fac 4 + 2 :: Integral a => a

 facCPS :: a -> (a -> r) -> r
 facCPS 0 k = k 1
 facCPS n'@(n + 1) k = facCPS n $ \ret -> k (n' * ret)
 facCPS 4 (+ 2) :: Integral a => a

 newSentence :: Char -> Bool
 newSentence = flip elem ".?!"

 newSentenceCPS :: Char -> (Bool -> r) -> r
 newSentenceCPS c k = k (elem c ".?!")

 mylength :: [a] -> Integer
 mylength [] = 0
 mylength (_ : as) = succ (mylength as)

 mylengthCPS :: [a] -> (Integer -> r) -> r
 mylengthCPS [] k = k 0
 mylengthCPS (_ : as) k = mylengthCPS as (k . succ)

 test8 :: Integer
 test8 = mylengthCPS [1..2006] id

 test9 :: IO ()
 test9 = mylengthCPS [1..2006] print