Why are mutable data structures and other mutability represented using IO in functional languages? I'm looking at e.g. Haskell's IORef or Idris' IOArray.
I don't think I mean this as a historical or design question. I don't quite understand why IO is suitable for mutation - or rather, why mutation becomes pure when encapsulated in IO.
You don't need to represent them with IO. It's possible to do them in ST instead. But you can obviously represent them with IO, where any dirty side effect can be achieved. So if you're working in IO anyway, it's easiest to just do the mutations there too, this way you don't need to put any worry on welding different monads together. If you're not already working in IO, you should use ST however.
ST docs it looks like this is primarily a "mutation" monad. Is it any different from a state monad that's compiled to in-place mutation?
ST monad supports compiler primitives that mutate memory locations (see the code for STRef). As far as I know, the State monad is never compiled to code that mutates state in memory, at least not with GHC. It would be better to think of ST as "real" mutation, with IO = ST + I/O operations.
Nov 16 at 23:01
newSTRef using State instead of ST (i.e. newStateRef :: YourChoiceOfContextIDon'tMind s => State s (StateRef a)) and you will see that they are quite different indeed.
Nov 16 at 23:05
State computation were sometimes optimised to execute by mutation in place, that would be almost accidental. The API of State just deals in values, and indeed it's quite valid for earlier state values to still have references after "changes", so it obviously can't always be implemented as mutation. ST has an API that explicitly deals in references to mutable storage; you specify the mutations, they're not an accidental effect of optimisations.
ST. runST is supposed to be a pure function.
IOis suitable for mutation - or rather, why mutation becomes pure when encapsulated inIO. Historical/design suggests that there was also a choice in the matter, which I wasn't aware ofdata Op = Assign Int | Outputand aprogram = [Assign 1, Assign 2, Output, Assign 42, Output]then you could undoubtedly create a function that takesprogramand outputs[2,42]. Does that meanAssign 2has a side effect? No. Does it meanOutputreturns a different value every time? No. But still, if you create a list of them you can still somehow kinda-sorta program as if you have mutable state. Monads are basically fancy ways of creating (potentially infinite) sequences of such steps.