I have a set of functions designed to construct a tree of subtasks from the Asana API. To do this I have a fairly simple module called "Asana.hs", whose most important two functions are these ones using Network.HTTP.Simple to perform the requests:

getTasksForProject :: String -> String -> IO [Task]
getTasksForProject token projectId = getFromAsana token $ "projects/" ++ projectId ++ "/tasks"

getSubtasks :: String -> String -> IO [Task]
getSubtasks token taskId = getFromAsana token $ "tasks/" ++ taskId ++ "/subtasks"

The problem is when I want to construct a graph of all the tasks I have to:

  1. get a list of tasks
  2. iterate through those tasks getting their subtasks
  3. recurse

For example, I have these functions to construct a "graph" of nodes and edges:

type TaskGraph = ([Task], [Edge])

merge :: TaskGraph -> TaskGraph -> TaskGraph
merge (aTasks, aEdges) (bTasks, bEdges) = (aTasks ++ bTasks, aEdges ++ bEdges)

makeEdge :: Relation -> Task -> Task -> Edge
makeEdge rel parent child = Edge rel (taskId parent) (taskId child)

rFetchTaskGraph :: String -> Task -> IO TaskGraph
rFetchTaskGraph token task = do
  subtasks <- getSubtasks token $ taskId task
  let edges = map (makeEdge Subtask task) subtasks
  foldr merge ([task], edges) <$> mapM (rFetchTaskGraph token) subtasks

This is extremely slow as it makes each HTTP request in sequence as far as I can tell. If I were doing this in something like Javascript, Promises would allow me to eagerly execute all the computations, but queue the requests, therefore only resolving the relevant Promise when the request is complete, but centralising the parallelism into some sort of connection pool manager.

How can I improve the efficiency of this in Haskell? I had a few thoughts:

  1. Perhaps I need to create a new Monad to represent this pooled resource access?
  2. Can I eagerly compute the whole list (insofar as I can, of course, since some of the requests will only be known once the results of others return)?
  3. Do I need to explicitly use threads?
  • Sounds like a good use-case for haxl, but I haven't used it myself. – Noughtmare Jun 10 at 21:01

Instead of

mapM (rFetchTaskGraph token) subtasks


mapConcurrently (rFetchTaskGraph token) subtasks

where mapConcurrently is from the async library.

However, when making concurrent HTTP requests, one should be careful to throttle them so as not to overwhelm the remote server—or get banned by it. One simple way of doing throttling involves gating all the invocations of rFetchTaskGraph using a semaphore, as described in this SO answer.

Because rFetchTaskGraph is recursive, it should accept the semaphore as argument in order to pass it to its sub-calls:

rFetchTaskGraph :: QSem -> String -> Task -> IO TaskGraph
rFetchTaskGraph sem token task = 
      (waitQSem sem) 
      (signalQSem sem)
        subtasks <- getSubtasks token $ taskId task
        let edges = map (makeEdge Subtask task) subtasks
        foldr merge ([task], edges) <$> mapConcurrently (rFetchTaskGraph sem token) subtasks)

More comprehensive solutions would involve thread pools and/or concurrent queues.

Edit: I think the previous code might lead to deadlocks in practice because the scope of the critical section is too big. Something like this should work better:

rFetchTaskGraph sem token task = do
       subtasks <- bracket_ (waitQSem sem) (signalQSem sem) $ getSubtasks token $ taskId task
       let edges = map (makeEdge Subtask task) subtasks
       foldr merge ([task], edges) <$> mapConcurrently (rFetchTaskGraph sem token) subtasks 

That is, limit the critical section only to the actual HTTP requests.

  • Thanks for the comprehensive answer, I'll look into all those options as throttling was an important follow-up question for me. – GTF Jun 13 at 17:14
  • Out of interest, why do you signal that the unit of QSem is available immediately after waiting for it? Wouldn't this release a resource while it's still "in use", i.e. if that do block takes a very long time, then you would have the same problem of lots of operations running simultaneously? – GTF Jun 13 at 17:18
  • 1
    Never mind, I didn't understand what bracket did but looked it up on hoogle: hackage.haskell.org/package/base-… – GTF Jun 13 at 17:37
  • @GTF I think my throttling code might have a problem. It wraps both the getSubtasks call and the recursive step. But this might lead to deadlocks. Perhaps you shold limit the scope of that bracket_ only to the getSubtasks token $ taskId task part. – danidiaz Jun 13 at 17:59
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    what I did instead to work this out was to profile the code and I can see that most of the time (I think) is spent in getFromAsana which is where the HTTP requests and deserialisation (via Aeson) happen. The cumulative time in merge is almost none. – GTF yesterday

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