## Summary: Different Stack Orders Yield Different Business Logic

That is to say, different monad transformer orders of the stack do not only affect the evaluation orders, but also the functionalities of programs.

When demonstrating the impact of orders, people usually use the simplest transformers such as `ReaderT`

, `WriterT`

, `StateT`

, `MaybeT`

, `ExceptT`

. Different orders of them do not give dramatically different business logic, so it is hard to understand the impact clearly. In addition, some subsets of them are commutative, i.e., there is no functionality differences.

For demonstration purpose, I suggest to use `StateT`

and `ListT`

, which reveal the dramatic difference between transformer orders on monad stacks.

## Background: `StateT`

and `ListT`

`StateT`

: `State`

monad is well explained in For a Few Monads More. `StateT`

just gives you a little bit more power -- using the monadic operations of its underlying `m`

. It is sufficient if you know `evalStateT`

, `put`

, `get`

, and `modify`

, which are explained in many `State`

monad tutorials.
`ListT`

: `List`

, a.k.a, `[]`

, is a monad (explained in A Fistful of Monads). `ListT m a`

(in package `list-t`

) gives you something similar to `[a]`

plus all monadic operations of the underlying monad `m`

. The tricky part is the execution of `ListT`

(something comparable to `evalStateT`

): there are lots of ways of execution. Think about different outcomes you care when using `evalStateT`

, `runStateT`

, and `execState`

, the context of `List`

monad has lots of potential consumers such as *just go over them*, i.e., `traverse_`

, *fold them*, i.e., `fold`

, and more.

## Experiment: Understand the Monad Transformer Order Impact

We will construct a simple two-layer monad tranformers stack using `StateT`

and `ListT`

on top of `IO`

to fulfill some functionalities for demonstration.

### Task Description

*Summing up numbers in a stream*

The stream will be abstracted as a list of `Integer`

s, so our `ListT`

comes in. To sum them up, we need to keep a state of the sum while processing each item in the stream, where our `StateT`

comes.

### Two Stacks

We have a simple state as `Int`

to keep the sum

`ListT (StateT Int IO) a`

`StateT Int (ListT IO) a`

### Full Program

```
#!/usr/bin/env stack
-- stack script --resolver lts-11.14 --package list-t --package transformers
import ListT (ListT, traverse_, fromFoldable)
import Control.Monad.Trans.Class (lift)
import Control.Monad.IO.Class (liftIO)
import Control.Monad.Trans.State (StateT, evalStateT, get, modify)
main :: IO()
main = putStrLn "#### Task: summing up numbers in a stream"
>> putStrLn "#### stateful (StateT) stream (ListT) processing"
>> putStrLn "#### StateT at the base: expected result"
>> ltst
>> putStrLn "#### ListT at the base: broken states"
>> stlt
-- (ListT (StateT IO)) stack
ltst :: IO ()
ltst = evalStateT (traverse_ (\_ -> return ()) ltstOps) 10
ltstOps :: ListT (StateT Int IO) ()
ltstOps = genLTST >>= processLTST >>= printLTST
genLTST :: ListT (StateT Int IO) Int
genLTST = fromFoldable [6,7,8]
processLTST :: Int -> ListT (StateT Int IO) Int
processLTST x = do
liftIO $ putStrLn "process iteration LTST"
lift $ modify (+x)
lift get
printLTST :: Int -> ListT (StateT Int IO) ()
printLTST = liftIO . print
-- (StateT (ListT IO)) stack
stlt :: IO ()
stlt = traverse_ (\_ -> return ())
$ evalStateT (genSTLT >>= processSTLT >>= printSTLT) 10
genSTLT :: StateT Int (ListT IO) Int
genSTLT = lift $ fromFoldable [6,7,8]
processSTLT :: Int -> StateT Int (ListT IO) Int
processSTLT x = do
liftIO $ putStrLn "process iteration STLT"
modify (+x)
get
printSTLT :: Int -> StateT Int (ListT IO) ()
printSTLT = liftIO . print
```

### Results And Explanation

```
$ ./order.hs
#### Task: summing up numbers in a stream
#### stateful (StateT) stream (ListT) processing
#### StateT at the base: expected result
process iteration LTST
16
process iteration LTST
23
process iteration LTST
31
#### ListT at the base: broken states
process iteration STLT
16
process iteration STLT
17
process iteration STLT
18
```

The first stack `ListT (StateT Int IO) a`

yields the correct result since `StateT`

is evaluated after `ListT`

. When evaluating `StateT`

, the runtime system already evaluated all operations of `ListT`

-- feeding the stack with a stream `[6,7,8]`

, going through them with `traverse_`

. The word *evaluated* here means effects of `ListT`

are gone and `ListT`

is transparent to `StateT`

now.

The second stack `StateT Int (ListT IO) a`

does not have the correct result since `StateT`

is too short-lived. In every iteration of `ListT`

evaluation, a.k.a., `traverse_`

, the state is created, evaluated and vanished. The `StateT`

in this stack structure does not achieve its purpose to keep states between list/stream item operations.