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What is the Comonad typeclass in Haskell? As in Comonad from Control.Comonad in the comonad package (explanations of any other packages that provide a Comonad typeclass are also welcome). I've vaguely heard about Comonad, but all I really know about it is that is provides extract :: w a -> a, sort of a parallel to Monad's return :: a -> m a.

Bonus points for noting "real life" uses of Comonad in "real" code.

  • I would really like to see what the difference between “co” and normal is. I know what a monad is. So if I know what the “co” means, I can conclude myself, what a comonad is, and understand it deeply. Alexey Romanov’s answer did nothing in that aspect. – Evi1M4chine Mar 1 '16 at 7:51
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    @Evi1M4chine: "co" (loosely) means "flip the arrows". Here's a rough visual of that. Consider the monadic operations: return :: a ~> m a, flip bind :: (a ~> m b) -> (m a ~> m b). Reverse the squiggly arrows and you get the comonadic operations: extract :: a <~ w a, extend :: (a <~ w b) -> (w a <~ w b) (extract :: w a -> a, extend :: (w a -> b) -> w a -> w b) – Dan Burton Mar 3 '16 at 19:47
  • Thank you @Dan Burton… so while with a monad, you work on the “inside” (stuffing new and altered things in), with a comonad, you work on the “outside” (taking things out finally or just to alter them). Is that view correct? Because it certainly helps a lot with the deep understanding. – Evi1M4chine Mar 4 '16 at 21:06
  • comonads can be used to model co-effects. Here is a great introduction to coeffects: tomasp.net/coeffects – zeronone Jul 8 '16 at 2:07
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These links may be helpful:

  1. Evaluating cellular automata is comonadic. In particular, "whenever you see large datastructures pieced together from lots of small but similar computations there's a good chance that we're dealing with a comonad".
  2. Sequences, streams, and segments
  3. Comonads in everyday life
  • +1 The first link was the one that really brought it together for me. – luqui Dec 8 '11 at 17:31
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    Link-only answer should at least contain a summary of the linked contents. Currently this answer isn't fit for being a good SO answer. Consider expanding it a bit, so that it can stand on its own without the linked articles. – Bakuriu Aug 28 '14 at 18:15
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    "whenever you see large datastructures pieced together from lots of small but similar computations there's a good chance that we're dealing with a comonad" .... So does that mean that fragment shaders are comonadic? – Sam Kellett Mar 17 '15 at 12:12
  • I found this example of extend to be helpful. – Chris Penner Jan 13 '17 at 19:20
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This doesn't fully answer my question, but I wanted to put some relevant information in answer format:

"co" (loosely) means "flip the arrows". Here's a rough visual of that.

Consider the monadic operations:

return :: a ~> m a
flip (>>=) :: (a ~> m b) -> (m a ~> m b)

Reverse the squiggly arrows and you get the comonadic operations:

extract :: a <~ w a
extend :: (a <~ w b) -> (w a <~ w b)

(Written with normal arrows)

extract :: w a -> a
extend :: (w a -> b) -> w a -> w b

Notice how in this format, return is an arrow that just so happens to fit in the argument slot for flip (>>=), and the same is true of extract and extend. Monad/comonad laws say that when you put return or extract into that slot, the result is the identity arrow. The laws are the same, "just with the arrows flipped". That's a super handwavey answer but hopefully it provides some insight.

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    Your answer goes well with avoiding the monad tutorial fallacy. Monads (and comonads) are just an interface. Although it would indeed be great to know how they were intended. As in: The idea behind them. – Evi1M4chine Mar 4 '16 at 21:10

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