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I'm making several API calls that are encapsulated in a type alias:

type ConnectT a = EitherT String (RWST ConnectReader ConnectWriter ConnectState IO) a

Here's a simplified version of a function which connects to two separate APIs:

connectBoth :: ConnectT ()
connectBoth = do
    a <- connectAPI SomeAPI someFunction
    b <- connectAPI OtherAPI otherFunction
    connectAPI OtherAPI (b `sendTo` a)

The final call in connectBoth is very time sensitive (and the transactions are of a financial nature). I figure a and b could be evaluated in parallel, and with lazy IO I should be able to do this:

    b <- a `par` connectAPI OtherAPI otherFunction

The documentation for par says that it Indicates that it may be beneficial to evaluate the first argument in parallel with the second.

  • Does this work with IO?
  • Can I get any more guaranteed than "it may be beneficial?"
  • Or if I want greater guarantees will I need to use an MVar and liftIO . forkIO?

If I evaluate a first, I think I can use eitherT to check if a succeeded. But if I evaluate both at the same time I get confused. Here is the situation:

  • If only a failed, I will retry a, if that fails I will run a function that manually reverses b
  • If only b failed, I will retry b, write to the log in RWS and return left
  • if both fail write to the log in RWS and return left
  • if both succeed process c (which is not as time sensitive as a or b)

But if I evaluate both in parallel, then how can I identify which one failed? If I use eitherT immediately after a then a will evaluate first. If I use it after b then I won't be able to tell which one failed.

Is there a way I can evaluate the IO calls in parallel but respond differently depending on which one (if any) fails? Or am I left with a choice of parallelism vs failure mitigation?

3
  • It's usually a good idea to log when something important starts (or needs to be done), since, when it fails, it might be in some catastrophic manner such that logging is no longer possible. If it fails, you can easily (and automatically) find those things that were started whose outcomes are uncertain. If you only log when they fail you may have failures or partial successes that you never knew about.
    – Cirdec
    Mar 12, 2015 at 6:15
  • Each of the API calls do their own pre/post logging. But because I don't want to waste too much time writing to the file system the log is just kept in memory until certain checkpoints. So if there's a critical failure I'd lose a chunk of the logs anyway. Mar 12, 2015 at 7:00
  • 1
    Have you considered using the Concurrently applicative from the async package, or its generalized version from lifted-async that can work with RWST IO? Unwrap the actions using eitherT, execute them concurrently putting the results in a tuple, and then pattern-match on the tuple of Either values to decide what to do.
    – danidiaz
    Mar 12, 2015 at 7:27

1 Answer 1

2

The solution you are looking for will use forkIO and MVars.

par

par is for multiprocessor parallelism, it helps evaluate terms in parallel. It doesn't help with IO. If you do

do
  a <- (someProcess :: IO a)
  ...

By the time you reach ... everything from the IO action has happened (if we ignore evil lazy IO) to a point that a can be determined entirely by ordinary evaluation. This means that by the time you do b <- someOtherProcess, all of someProcess is already done. It's too late to do anything in parallel.

EitherT

You can explicitly examine the Either e a result of an EitherT e m a. runEitherT :: EitherT e m a -> m (Either e a) makes the success or failure explicit in the underlying monad. We can lift that right back into EitherT to make a computation that always succeeds (sometimes with an error) from one that sometimes fails.

import Control.Monad.Trans.Class

examine :: (MonadTrans t, Monad m) => EitherT e m a -> t m (Either e a)
examine = lift . runEitherT

forkIO

The simplest solution for doing two things in IO is forkIO. It starts another lightweight thread that you can forget about.

If you run a value with your transformer stack, there will be four pieces of data when you are done. The state ConnectState, the written ConnectWriter log, whether the computation was successful, and, depending on whether or not it was successful, either the value or the error.

EitherT String (RWST ConnectReader ConnectWriter ConnectState IO) a
^       ^                          ^             ^                ^

If we write out the structure of this, it looks like

(RWST ConnectReader ConnectWriter ConnectState IO) (Either String a)
                    ^             ^                 ^      ^      ^
ConnectReader -> ConnectState -> IO (Either String a, ConnectState, ConnectWriter)
                                     ^      ^      ^  ^             ^

All four of those pieces of information end up in the result of the IO action. If you fork your stack, you need to decide what to do with all of them when you join the results back together. You have already decided that you want to explicitly handle the Either String a. The ConnectWriters can probably be combined together with <>. You will need to decide what to do with ConnectState.

We'll make a fork that returns all four of these pieces of data by shoving them into an MVar.

import Control.Concurrent
import Control.Concurrent.MVar
import Control.Monad.IO.Class

forkConnectT :: ConnectT a -> ConnectT (MVar (Either String a, ConnectState, ConnectWriter))
forkConnectT cta = do
    result <- liftIO newEmptyMVar
    r <- lift ask
    s <- lift get
    liftIO $ forkIO $ do
        state <- runRWST (runEitherT cta) r s
        putMVar result state
    return result

Later, when we want the result, we can try and see if it is ready. We'll handle the Either for success and failure explicitly, while handling the state and writer behind the scenes.

import Data.Traversable

tryJoinConnectT :: MVar (Either String a, ConnectState, ConnectWriter) -> ConnectT (Maybe (Either String a))
tryJoinConnectT result = liftIO (tryTakeMVar result) >>= traverse reintegrate

Behind the scenes we reintegrate the ConnectWriter by telling this ConnectT to write what was accumulated in the other thread. You will need to decide what to do to combine the two states.

reintegrate :: (a, ConnectState, ConnectWriter) -> ConnectT a
reintegrate (a, s, w) = do
    -- Whatever needs to be done with the state.
    -- stateHere <- lift get
    lift $ tell w
    return a

If we want to wait until the result is ready, we can block reading the MVar. This offers less opportunity for handling errors such as timeouts.

joinConnectT :: MVar (Either String a, ConnectState, ConnectWriter) -> ConnectT (Either String a)
joinConnectT result = liftIO (takeMVar result) >>= reintegrate

Example

Putting it all together, we can fork a task in parallel, do something in this thread explicitly examining the success or failure, join with the result from the other thread, and reason about what to do next with explicit Eithers representing success or failure from each process.

connectBoth :: ConnectT ()
connectBoth = do
    bVar <- forkConnectT $ connectAPI OtherAPI otherFunction
    a <- examine $ connectAPI SomeAPI someFunction
    b <- joinConnectT bVar 
    ...

Going farther

If you are paranoid, you will also want to handle exceptions (some of which can be handled by forkFinally) and asynchronous exceptions. You will need to decide whether to bundle these exceptions into your stack or treat IO like it can always throw exceptions.

Consider using async instead of forkIO and MVars.

monad-control (which you already have dependencies on via either) provides mechanisms for building up, one transformer at a time, the type that represents the state of a monad transformer stack. We wrote this by hand as (Either String a, ConnectState, ConnectWriter). If you are going to grow your transformer stack, you might want to get this from MonadTransControl instead. You can restore the state from the forked thread(see MonadBaseControl section) in the parent to inspect it. You will still need to decide how to deal with the data from the two states..

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