# Managing state - chapter 3 of SICP

I've been working through in Structure and Interpretation of Computer Programs and completing the exercises in Haskell. The first two chapters were fine (code at github) but Chapter 3 is making me think harder.

It starts by talking about managing state, with the example of a bank account. They define a function `make-withdraw` by

``````(define (make-withdraw balance)
(lambda (amount)
(if (>= balance amount)
(begin (set! balance (- balance amount))
balance)
"Insufficient funds")))
``````

so that you can execute the following code:

``````(define w1 (make-withdraw 100))
(define w2 (make-withdraw 100))

(w1 50)
50

(w2 70)
30

(w2 40)
"Insufficient funds"

(w1 40)
10
``````

I'm not sure how I can emulate this in Haskell. I first thought to a some simple function using the State monad:

``````import Control.Monad.State

type Cash    = Float
type Account = State Cash

withdraw :: Cash -> Account (Either String Cash)
withdraw amount = state makewithdrawal where
makewithdrawal balance = if balance >= amount
then (Right amount, balance - amount)
else (Left "Insufficient funds", balance)
``````

which allows me to run the code

``````ghci> runState (do { withdraw 50; withdraw 40 }) 100
(Left "Insufficient funds",30.0)
``````

but that does something different to the scheme code. Ideally I'd be able to run something like

``````do
w1 <- makeWithdraw 100
w2 <- makeWithdraw 100
x1 <- w1 50
y1 <- w2 70
y2 <- w2 40
x2 <- w1 40
return [x1,y1,y2,x2]

[Right 50,Right 70,Left "Insufficient funds",Right 40]
``````

but I'm not sure how to write the function `makeWithdraw`. Any advice?

-

The Scheme code is sneakily using two bits of state: one is the (implicit) association between variables `w1` and `w2` and a ref-cell; the other is the (explicit) state stored in a ref-cell. There's a couple different ways to model this in Haskell. For example, we might pull a similar ref-cell trick with `ST`:

``````makeWithdraw :: Float -> ST s (Float -> ST s (Either String Float))
makeWithdraw initialBalance = do
refBalance <- newSTRef initialBalance
return \$ \amount -> do
let balance' = balance - amount
if balance' < 0
then return (Left "insufficient funds")
else writeSTRef refBalance balance' >> return (Right balance')
``````

Which lets us do this:

``````*Main> :{
*Main| runST \$ do
*Main|   w1 <- makeWithdraw 100
*Main|   w2 <- makeWithdraw 100
*Main|   x1 <- w1 50
*Main|   y1 <- w2 70
*Main|   y2 <- w2 40
*Main|   x2 <- w1 40
*Main|   return [x1,y1,y2,x2]
*Main| :}
[Right 50.0,Right 30.0,Left "insufficient funds",Right 10.0]
``````

Another option is to make both pieces of the state explicit, for example by associating each account with a unique `Int` id.

``````type AccountNumber = Int
type Balance = Float
data BankState = BankState
{ nextAccountNumber :: AccountNumber
, accountBalance :: Map AccountNumber Balance
}
``````

Of course, we would then basically be re-implementing the ref-cell operations:

``````newAccount :: Balance -> State BankState AccountNumber
newAccount balance = do
next <- gets nextAccountNumber
modify \$ \bs -> bs
{ nextAccountNumber = next + 1
, accountBalance = insert next balance (accountBalance bs)
}
return next

withdraw :: Account -> Balance -> State BankState (Either String Balance)
withdraw account amount = do
balance <- gets (fromMaybe 0 . lookup account . accountBalance)
let balance' = balance - amount
if balance' < 0
then return (Left "insufficient funds")
else modify (\bs -> bs { accountBalance = insert account balance' (accountBalance bs) }) >> return (Right balance')
``````

Which would then let us write `makeWithdraw`:

``````makeWithDraw :: Balance -> State BankState (Balance -> State BankState (Either String Balance))
makeWithdraw balance = withdraw <\$> newAccount balance
``````
-
Thanks, this is a great answer. –  Chris Taylor Apr 6 '12 at 21:04

Well, you have multiple pieces of independent, mutable state here: one for each "account" in the system. The `State` monad only lets you have one piece of state. You could store something like `(Int, Map Int Cash)` in the state, incrementing the `Int` to get a fresh key into the map each time, and use that to store the balance... but that's so ugly, isn't it?

Thankfully, however, Haskell has a monad for multiple pieces of independent, mutable state: `ST`.

``````type Account = ST

makeWithdraw :: Cash -> Account s (Cash -> Account s (Either String Cash))
makeWithdraw amount = do
cash <- newSTRef amount
return withdraw
where
withdraw balance
| balance >= amount = do
modifySTRef cash (subtract amount)
return \$ Right amount
| otherwise = return \$ Left "Insufficient funds"
``````

With this, your code example should work fine; just apply `runST` and you should get the list you want. The `ST` monad is pretty simple: you can just create and modify `STRef`s, which act just like regular mutable variables; in fact, their interface is basically identical to that of `IORef`s.

The only tricky bit is the extra `s` type parameter, referred to as the state thread. This is used to associate each `STRef` with the `ST` context it's created in. It would be very bad if you could return an `STRef` from an `ST` action, and carry it across to another `ST` context — the whole point of `ST` is that you can run it as pure code, outside of `IO`, but if the `STRef`s could escape, you'd have impure, mutable state outside of the monadic context, just by wrapping all your operations in `runST`! So, each `ST` and `STRef` carries around the same `s` type parameter, and `runST` has the type `runST :: (forall s. ST s a) -> a`. This stops you choosing any particular value for `s`: your code has to work with all possible values of `s`. It's never assigned any particular type; just used as a trick to keep the state threads isolated.

-
Thanks, the explanation of ST is really helpful! –  Chris Taylor Apr 6 '12 at 21:04