I'm interested in the problem of resumable (and serializable) processes and saw that there is a Haskell package ("Workflow") that seems to do just that: take an existing computation (of type IO ()) and wrap it in a monad that make the computation resumable.

My rough idea of how that should work is that you consider an element of type IO () as an expression built-up from "binds", and that the monad transformer (i.e. lift) should map binds to binds, thus allowing you to insert some pre- or post-processing steps into your expression. However so far I have not been able to make this work.

So my I guess my question would be, is my idea reasonable? If not, how does the Workflow package do its magic?

To fix ideas, below is what I've tried:

-- Instance of MonadTrans for WorkflowT
{-# LANGUAGE FlexibleContexts #-}

import Control.Monad.Trans.Class (MonadTrans, lift)
import Control.Monad.IO.Class (MonadIO, liftIO)

-- Definition of the Workflow monad transformer
newtype WorkflowT m a = WorkflowT { runWorkflowT :: m a }

instance MonadTrans WorkflowT where
    lift = WorkflowT

-- Instance of Functor for WorkflowT
instance Functor m => Functor (WorkflowT m) where
    fmap f (WorkflowT ma) = WorkflowT $ fmap f ma

-- Instance of Applicative for WorkflowT
instance Applicative m => Applicative (WorkflowT m) where
    pure = WorkflowT . pure
    (WorkflowT mf) <*> (WorkflowT ma) = WorkflowT $ mf <*> ma

-- Instance of MonadIO for WorkflowT
instance MonadIO m => MonadIO (WorkflowT m) where
    liftIO = WorkflowT . liftIO

-- Instance of Monad for WorkflowT
instance MonadIO m => Monad (WorkflowT m) where
    return = pure
    WorkflowT ma >>= f = WorkflowT $ do
        a <- ma
        let WorkflowT mb = f a
        b <- mb
        liftIO $ putStrLn "Checkpointing after executing step..."
        return b

-- Example computation representing multiple steps
compositeComputation :: IO ()
compositeComputation = do
    putStrLn "Executing step 1..."
    putStrLn "Executing step 2..."
    putStrLn "Executing step 3..."

-- Lift the composite computation into the WorkflowT monad             
liftedComputation :: MonadIO m => WorkflowT m ()
liftedComputation = liftIO compositeComputation

main :: IO ()
main = do
    -- Run the lifted computation in the base monad
    runWorkflowT liftedComputation

My expectation (hope) would have been that the line "Checkpointing..." would be printed after every "step", but it is not.

  • Expand your question with what you've tried and what didn't work? As it is it is very difficult for me to understand what you mean. In particular I don't understand how inserting pre- or post-processing steps follows from a lift that maps binds to binds.
    – Noughtmare
    Feb 7 at 9:33
  • Do you know the Workflow package? What it does is what I try to reproduce. Feb 7 at 10:13
  • 1
    It seems like WorkflowT is not a lawful MonadIO, because indeed do liftIO a; liftIO b === liftIO (do a; b) should hold.
    – Noughtmare
    Feb 7 at 17:16
  • This law is precisely why I thought such an "intrusive lifting" should be possible, i.e. if you interpret this as a definition you could (perhaps) recursively define lifting. Feb 7 at 18:02
  • If a law abiding Workflow-like monad would exist then that would indeed mean you should be able to do such intrusive lifting, but I doubt that it exists.
    – Noughtmare
    Feb 8 at 12:15

1 Answer 1


Nothing in your code ever uses the bind of WorkflowT. compositeComputation may be composite in the IO monad but it's wrapped in a single WorkflowT.

If you do something like this it works.

runWorkflowT (do liftIO (putStrLn "a")
                 liftIO (putStrLn "b")
                 liftIO (putStrLn "c"))

The Workflow package requires you to do something similar - if you look at the example here it wraps each individual IO action with step, not all of them together.

(Maybe you also want to move the logging before b <- mb. It seems weird for it to come after both actions rather than in between.)

  • Yes, you are right: I just realized that in the examples the "Workflows" are really constructed as such, using the "bind" of Workflow explicitly, as in your code above. I thought it was able to do that automatically, i.e. lift a term of type IO () which is constructed using binds to a term of type WorkflowT IO () in such a way that the resulting expression has the same binding structure, and I couldn't understand how it was able to do that. My bad! Feb 7 at 12:29
  • My "idea" of how that was supposed to work is that you could use the transformer law lift (m >>= f) = lift m >>= (lift . f) to compute what the lift of a bind should be and kind of "pattern match" on bind expressions. But that doesn't seem possible, I think. And you are right about the placement of b <- mb, that was a mistake. Feb 7 at 12:34
  • But maybe it is possible to achieve something like that using rewrite-rules... Feb 7 at 12:48
  • @BlenderBender The meaning of the transformer law you quote is that those two forms are supposed to be indistinguishable from the outside; it isn't supposed to matter whether you bind and then lift the result or whether you lift the separate elements and then bind the results. Either way should have exactly the same observable outcome. So if your idea depends on using the transformer to compute from one expression to the other because they have different effects, you are by-definition violating the law.
    – Ben
    Feb 7 at 23:59
  • How am I violating the law if I use the law to define the lifiting? Feb 8 at 6:54

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