In `pipes`

, you typically wouldn't use effects in the base monad `m`

of your overall `Effect`

to model the **internal** state of a `Producer`

. If you really wanted to use `State`

for this purpose, it would be an internal implementation detail of the `Producer`

in question (discharged by a `runStateP`

or `evalStateP`

inside the `Producer`

, as explained below), and the `State`

would not appear in the `Producer`

's type.

It's also important to emphasize that a `Producer`

, even when it's operating in the `Identity`

base monad without any "effects" at its disposal, isn't some sort of pure function that would keep producing the same value over and over without monadic help. A `Producer`

is basically a stream, and it can maintain state using the usual functional mechanisms (e.g., recursion, for one). So, you definitely don't *need* a `State`

for a `Producer`

to be stateful.

The upshot is that the usual model of a Python `Generator[int, None, None]`

in `Pipes`

is just a `Monad m => Producer Int m ()`

polymorphic in an unspecified base monad `m`

. Only if the `Producer`

needs some external effects (e.g., `IO`

to access the filesystem) would you require more of `m`

(e.g., a `MonadIO m`

constraint or something).

To give you a concrete example, a `Producer`

that generates pseudorandom numbers obviously has "state", but a typical implementation would be a "pure" `Producer`

:

```
randoms :: (Monad m) => Word32 -> Producer Int m ()
randoms seed = do
let seed' = 1664525 * seed + 1013904223
yield $ fromIntegral seed'
randoms seed'
```

with the state maintained via recursion.

If you *really* decided to maintain this state via the `State`

monad, the type of the `Producer`

wouldn't change. You'd just use a `State`

internally. The `Pipes.Lift`

module provides some helpers (like `evalStateP`

used here) to locally add a monad layer to facilitate this:

```
randoms' :: (Monad m) => Word32 -> Producer Int m ()
randoms' seed = evalStateP seed $ forever $ do
x <- get
let x' = 1664525 * x + 1013904223
yield $ fromIntegral x'
put x'
```

Oleg's simple generators are entirely different. His producers and consumers produce and consume values *only* through monadic effects, and "monad changing" is central to the implementation. In particular, I believe his consumers and transducers can *only* maintain state via a monadic effect, like a `State`

monad, though I'd have to look a little more carefully to be sure.

In contrast, `pipes`

proxies can produce and consume values and maintain internal state independent of the underlying base monad.

Ultimately, the analog of Oleg's transducers in `pipes`

are simply the `Pipe`

s. Both consume values from a producer and yield values to a consumer. The monad changing in Oleg's transducers is just an implementation detail.