First of all, let's think about a few things.

- Does
`function1`

have side effects?
- Does
`function2`

have side effects?
- Does
`function3`

have side effects?

The answer to all of these is a resoundingly obvious YES, because they take no inputs, and presumably there are circumstances which cause you to go around the while loop more than once (rather than `def function3(): return false`

). Now let's remodel these functions with explicit state.

```
s = initialState
sentinel = true
while(sentinel):
a,b,s,sentinel = function1(a,b,s,sentinel)
a,b,s,sentinel = function2(a,b,s,sentinel)
a,b,s,sentinel = function3(a,b,s,sentinel)
return a,b,s
```

Well that's rather ugly. We know absolutely nothing about what inputs each function draws from, nor do we know anything about how these functions might affect the variables `a`

, `b`

, and `sentinel`

, nor "any other state" which I have simply modeled as `s`

.

So let's make a few assumptions. Firstly, I am going to assume that these functions do not directly depend on nor affect in any way the values of `a`

, `b`

, and `sentinel`

. They might, however, change the "other state". So here's what we get:

```
s = initState
sentinel = true
while (sentinel):
a,s2 = function1(s)
b,s3 = function2(s2)
sentinel,s4 = function(s3)
s = s4
return a,b,s
```

Notice I've used temporary variables `s2`

, `s3`

, and `s4`

to indicate the changes that the "other state" goes through. Haskell time. We need a control function to behave like a `while`

loop.

```
myWhile :: s -- an initial state
-> (s -> (Bool, a, s)) -- given a state, produces a sentinel, a current result, and the next state
-> (a, s) -- the result, plus resultant state
myWhile s f = case f s of
(False, a, s') -> (a, s')
(True, _, s') -> myWhile s' f
```

Now how would one use such a function? Well, given we have the functions:

```
function1 :: MyState -> (AType, MyState)
function2 :: MyState -> (BType, MyState)
function3 :: MyState -> (Bool, MyState)
```

We would construct the desired code as follows:

```
thatCodeBlockWeAreTryingToSimulate :: MyState -> ((AType, BType), MyState)
thatCodeBlockWeAreTryingToSimulate initState = myWhile initState f
where f :: MyState -> (Bool, (AType, BType), MyState)
f s = let (a, s2) = function1 s
(b, s3) = function2 s2
(sentinel, s4) = function3 s3
in (sentinel, (a, b), s4)
```

Notice how similar this is to the non-ugly python-like code given above.

You can verify that the code I have presented is well-typed by adding `function1 = undefined`

etc for the three functions, as well as the following at the top of the file:

```
{-# LANGUAGE EmptyDataDecls #-}
data MyState
data AType
data BType
```

So the takeaway message is this: in Haskell, you must explicitly model the changes in state. You can use the "State Monad" to make things a little prettier, but you should first understand the idea of passing state around.

actuallytrying to do here so we can help you rework it into a functional solution. – Louis Wasserman Feb 14 '12 at 19:57