You are making exactly the same mistakes that I made when I first started writing monadic code - making it way too complicated, overusing
liftM and underusing
>>= (equivalently, underusing the
Ideally, you shouldn't have to mention
evalState inside the state monad at all. The functionality you want is as follows:
- Read the current state
- If it satisfies the predicate
f, then return
- If not, then run the computation
s and add its result to the output
You can do this quite directly as:
collectUntil f s = do
s' <- get -- Get the current state
if f s' then return  -- If it satisfies the predicate, return
else do -- Otherwise...
x <- s -- Perform the computation s
xs <- collectUntil f s -- Perform the rest of the computation
return (x:xs) -- Collect the results together and return them
Note that you can nest do statements if they are part of the same monad! This is very useful - it allows you to branch within one do block, as long as both branches of the if statement lead to something of the same monadic type.
The inferred type for this function is:
collectUntil :: MonadState t m => (t -> Bool) -> m a -> m [a]
If you wish, you can specialise that to the
State s type, although you don't have to:
collectUntil :: (s -> Bool) -> State s a -> State s [a]
It might even be preferable to keep the more general state, in case you want to use a different monad later.
What's the intuition?
s is a stateful computation and you are inside the state monad, you can do
x <- s
x will now have the result of the computation (as if you'd called
evalState and fed in an initial state). If you ever need to check the state, you can do
s' <- get
s' will have the value of the current state.