I assume that you want the steps to be displayed automatically, without having to sprinkle you code with logging statements.

The problem of doing this with monads is that they are *too* flexible: at any point, the "shape" of the rest of the computation can depend on values obtained during the computation itself. This is made explicit in the type of `(>>=)`

, which is `m a -> (a -> m b) -> m b`

.

As a consequence, there is no fixed number `N`

of total steps that you can know before running the computation.

However, Haskell offers two other abstractions which trade some of the power and flexibility of monads for the chance to perform a greater amount of "static" analysis beforehand: applicative functors and arrows.

Applicative functors, while hugely useful, are perhaps too "weak" for your needs. You can´t write a function inside an applicative functor that, when applied to a value, prints that value to console. This is explained in the paper "Idioms are oblivious, arrows are meticulous, monads are promiscuous" which contains some enlightening examples of the limits of each abstraction (applicative functors are called "idioms" in that paper.)

Arrows offer a better compromise between expressive power and amenability to static analysis. The "shape" of arrow computations is fixed in a static pipeline. Data obtained during the computation can influence effects later in the pipeline (for example, you can print a value obtained by a previous effect in the computation) but *not* change the shape of the pipeline, or the number of steps.

So, if you could express your computation using Kleisli arrows (the arrows of a monad), perhaps you could write some kind of arrow transformer (*not* monad transformer) which added automated logging capabilities.

The arrows package offers a number of arrow transformers. I think StaticArrow could be used to automatically track the total number of steps. But you would still need to write some functionality to actually emit the messages.

**Edit:** Here's an example of how to keep count of the number of steps in a computation, using arrows:

```
module Main where
import Data.Monoid
import Control.Monad
import Control.Applicative
import Control.Arrow
import Control.Arrow.Transformer
import Control.Arrow.Transformer.Static
type SteppedIO a b = StaticArrow ((,) (Sum Int)) (Kleisli IO) a b
step :: (a -> IO b) -> SteppedIO a b
step cmd = wrap (Sum 1, Kleisli cmd)
countSteps :: SteppedIO a b -> Int
countSteps = getSum . fst . unwrap
exec :: SteppedIO a b -> a -> IO b
exec = runKleisli . snd . unwrap
program :: SteppedIO () ()
program =
step (\_ -> putStrLn "What is your name?")
>>>
step (\_ -> getLine)
>>>
step (putStrLn . mappend "Hello, ")
main :: IO ()
main = do
putStrLn $ "Number of steps: " ++ show (countSteps program)
exec program ()
```

Notice that the effect of step 3 is influenced by a value produced in step 2. This can't be done using applicatives.

We do use the `(,) (Sum Int)`

applicative, required by `StaticArrow`

to encode the static information (here, just the number of steps).

Displaying the steps as they are executed would require a bit more work.

**Edit#2** If we are dealing with a sequence of commands in which no effect depends on a value produced by a previous effect, then we can avoid using arrows and count the steps using only applicative functors:

```
module Main where
import Data.Monoid
import Control.Applicative
import Data.Functor.Compose
type SteppedIO a = Compose ((,) (Sum Int)) IO a
step :: IO a -> SteppedIO a
step cmd = Compose (Sum 1, cmd)
countSteps :: SteppedIO a -> Int
countSteps = getSum . fst . getCompose
exec :: SteppedIO a -> IO a
exec = snd . getCompose
program :: SteppedIO ()
program =
step (putStrLn "aaa")
*>
step (putStrLn "bbb")
*>
step (putStrLn "ccc")
main :: IO ()
main = do
putStrLn $ "Number of steps: " ++ show (countSteps program)
exec program
```

`Data.Functor.Compose`

comes from the `transformers`

package.

**Edit#3** The following code extends the previous `Applicative`

step counting solution, using the `pipes`

package to actually emit notifications. The arrow-based solution could be adapted in a similar manner.

```
module Main where
import Data.Monoid
import Control.Applicative
import Control.Monad.State
import Data.Functor.Compose
import Pipes
import Pipes.Lift
type SteppedIO a = Compose ((,) (Sum Int)) (Producer () IO) a
step :: IO a -> SteppedIO a
step cmd = Compose (Sum 1, yield () *> lift cmd)
countSteps :: SteppedIO a -> Int
countSteps = getSum . fst . getCompose
exec :: SteppedIO a -> Producer () IO a
exec = snd . getCompose
stepper :: MonadIO m => Int -> Consumer () m a
stepper n = evalStateP 0 $ forever $ do
await
lift $ modify succ
current <- lift get
liftIO $ putStrLn $ "step " ++ show current ++ " of " ++ show n
program :: SteppedIO ()
program = *** does not change relative to the previous example ***
main :: IO ()
main = runEffect $ exec program >-> stepper (countSteps program)
```

`N`

is the main problem. I really only included the`i`

because the question would look silly without it. – lobsterism Nov 29 '13 at 20:12