Conduit Overview

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Updated location

Note that the most up to date version of this content is available at the conduit repo homepage. You should probably read it there.


conduit is a solution to the streaming data problem, allowing for production, transformation, and consumption of streams of data in constant memory. It can be used for processing files, dealing with network interfaces, or parsing structured data in an event-driven manner.

In addition to this tutorial, there is a set of slides on conduit which covers a number of topics.

You may wish to first check the conduit homepage, which may have more up-to-date tutorial content than here.

Synopsis

import Data.Conduit
import qualified Data.Conduit.List as CL
import qualified Data.Conduit.Binary as CB

main = do
    -- show Pure operations: summing numbers.
    result <- CL.sourceList [1..10] $$ CL.fold (+) 0
    print result
    -- /show
    
    -- show Exception safe file access: copy a file.
    writeFile "input.txt" "This is a test."
    runResourceT $ CB.sourceFile "input.txt" $$ CB.sinkFile "output.txt"
    readFile "output.txt" >>= putStrLn
    -- /show
    
    -- show Perform transformations.
    result <- CL.sourceList [1..10] $$ CL.map (+ 1) =$ CL.consume
    print result
    -- /show

Features of conduit

  • conduit allows you to deal with large- and possibly infinite- streams of data in constant memory. Chunks of data are dealt with one piece at a time instead of needing to read in the entire body at once.
  • conduit also allows for deterministic resource usage. When using scarce resources like file descriptors, conduit is designed to immediately recycle resources when they are no longer needed. Contrast this with lazy I/O, which provides for constant memory usage, but at the expense of deterministic resource usage.
  • Resource usage must also be exception safe: a file handle must be recycled even in the presence of exceptions. Most of this functionality is provided by the associated resourcet package, described below.
  • It should be easy to compose together pre-built components to build up more complex structures. Our goal is to retain the composability of pure code while dealing with the imperative world.

Basics

The main module for the conduit package is Data.Conduit, which provides the core data types and primitive operations. Another commonly used modules is Data.Conduit.List, which provides a number of helper functions for common cases, based on standard Haskell concepts like map and fold.

There are three main concepts in conduit. A Source will produce a stream of data values and send them downstream. A Sink will consume a stream of data values from upstream and produce a return value. In the first example in the synopsis, sourceList generated a stream of Integers which the fold consumed, producing a return value of 55. The third concept is the Conduit, which consumes a stream of values from upstream and produces a new stream to send downstream. In the synopsis, the call to map consumed one stream of Integers, added 1 to each value, and sent the new results downstream.

In order to combine these different components, we have connecting and fusing. The connect operator is $$, and it will combine a Source and Sink, feeding the values produced by the former into the latter, and producing a final result. Fusion, on the other hand, will take two components and generate a new component. For example, =$ can fuse a Conduit and Sink together into a new Sink, which will consume the same values as the original Conduit and produce the same result as the original Sink. The other two fusion operators are $=, which combines a Source and Conduit into a new Source, and =$=, which combines two Conduits into a new Conduit.

-- show Demonstration of connect and fuse operators
import Data.Conduit
import qualified Data.Conduit.List as CL

source :: Source IO Int -- produces a stream of Ints
source = CL.sourceList [1..4]

sink :: Sink String IO () -- consumes a stream of Strings, no result
sink = CL.mapM_ putStrLn

conduit :: Conduit Int IO String -- converts Ints into Strings
conduit = CL.map show

main = do
    source $$ conduit =$ sink
    -- alternatively, with the same meaning
    source $= conduit $$ sink

Exercise: Write a Conduit which will multiply all incoming numbers by 2, and then include it in the above code snippet. Note that there are multiple ways of using the connect and fusion operators to get the desired result, give a few of them a shot.

Unified data type

Under the surface, all three core data types are just wrappers around the same type, ConduitM. By wrapping around this single unified type, we're able to reuse a lot of code and more easily compose components in conduit.

ConduitM takes four type parameters: input received from upstream, output send downstream, the underlying monad, and the return value. Our specialized types are defined as:

type Source m a = ConduitM () a m () -- no meaningful input or return value
type Conduit a m b = ConduitM a b m () -- no meaningful return value
type Sink a m b = ConduitM a Void m b -- no meaningful output value

ConduitM is a monad transformer. As such, you can lift operations from the underlying monad (see "Lifting Operations" below), and can easily compose together multiple components. This makes it simple to build up complex mechanisms from simpler components.

You will very rarely need to interface directly with the ConduitM datatype, though it will occasionally appear in error messages.

Primitives

There are three core primitives in the conduit library.

  1. await will take a single value from upstream, if available.
  2. yield will send a single value downstream.
  3. leftover will put a single value back in the upstream queue, ready to be read by the next call to await.
-- show Using primitives
import Data.Conduit
import Control.Monad.IO.Class

source :: Source IO Int
source = do
    yield 1
    yield 2
    yield 3
    yield 4
    
conduit :: Conduit Int IO String
conduit = do
    -- Get all of the adjacent pairs from the stream
    mi1 <- await
    mi2 <- await
    case (mi1, mi2) of
        (Just i1, Just i2) -> do
            yield $ show (i1, i2)
            leftover i2
            conduit
        _ -> return ()
            
sink :: Sink String IO ()
sink = do
    mstr <- await
    case mstr of
        Nothing -> return ()
        Just str -> do
            liftIO $ putStrLn str
            sink
            
main = source $$ conduit =$ sink

Exercises

  1. Implement sourceList in terms of yield.

    import Data.Conduit
    import qualified Data.Conduit.List as CL
    
    -- show
    sourceList :: Monad m => [a] -> Source m a
    sourceList = ???
    -- /show
    
    main = sourceList [1, 2, 3] $$ CL.mapM_ print
  2. There's a helper function in the library called awaitForever. Rewrite sink above using awaitForever.

    import Data.Conduit
    import Control.Monad.IO.Class
    
    source :: Source IO Int
    source = do
        yield 1
        yield 2
        yield 3
        yield 4
        
    conduit :: Conduit Int IO String
    conduit = do
        -- Get all of the adjacent pairs from the stream
        mi1 <- await
        mi2 <- await
        case (mi1, mi2) of
            (Just i1, Just i2) -> do
                yield $ show (i1, i2)
                leftover i2
                conduit
            _ -> return ()
    
    
    -- show
    sink :: Sink String IO ()
    sink = ???
    -- /show
            
    main = source $$ conduit =$ sink
  3. Implement your own version of awaitForever.

    import Data.Conduit
    import qualified Data.Conduit.List as CL
    import Control.Monad.Trans.Class (lift)
    
    -- show
    myAwaitForever :: Monad m => (a -> Conduit a m b) -> Conduit a m b
    myAwaitForever f = ???
    -- /show
    
    main = CL.sourceList [1..10] $$ myAwaitForever (lift . print)

Monadic chaining

The above examples demonstrated how we can combine primitives together using standard monadic binding. This doesn't just apply to the primitives: you can combine larger components together as well. Consider the "triple" Conduit which will output any values it receives three times:

import Data.Conduit
import qualified Data.Conduit.List as CL

triple :: Monad m => Conduit a m a
-- show Triple conduit
triple = do
    ma <- await
    case ma of
        Nothing -> return ()
        Just a -> do
            CL.sourceList [a, a, a]
            triple
-- /show

main = CL.sourceList [1..4] $$ triple =$ CL.mapM_ print

Mini exercise: rewrite the above using awaitForever, which should be much shorter.

As you can see, it's entirely possible to combine a higher-level function like sourceList into a larger function. One question you might have is: how can we use a Source inside the body of a Conduit? We'll discuss that with Producers and Consumers in the generalizing section below.

Exercise: Write a Conduit that consumes a stream of Ints. It takes the first Int from the stream, and then multiplies all subsequent Ints by that number and sends them back downstream. You should use the Data.Conduit.List.map function for this.

Lifting operations

As monad transformers, our components can perform any operations supported by their underlying monads. We've already seen this implicitly with usage of CL.mapM_ print. However, we can also use lift or liftIO explicitly. And we're also not limited to the IO monad. Let's consider an example with the State monad.

import Control.Monad.State
import Data.Conduit
import qualified Data.Conduit.List as CL

source :: Source (State Int) Int
source = do
    x <- lift get
    if x <= 0
        then return ()
        else do
            yield x
            lift $ modify (\x -> x - 2)
            source
            
conduit :: Conduit Int (State Int) (Int, Int)
conduit = awaitForever $ \i -> do
    lift $ modify (+ 1)
    x <- lift get
    yield (i, x)

main :: IO ()
main = do
    let result :: State Int [(Int, Int)]
        result = source $$ conduit =$ CL.consume
    print $ runState result 5

Generalizing

In the triple conduit example above, why were we able to use a Source inside a Conduit? That shouldn't typecheck, should it? After all, a Source has its input type constrained to (), while a Conduit can have any input type. In our example above, the input was Int, so it certainly should not have worked.

The answer is that we have two final type synonyms to introduce. Producer is a generalized Source. Instead of stating that it consumes an input stream of () values, it can consume any input values, thus allowing it to work for both Source and Conduit. Similarly, we have Consumer which can output any values, and thus works as either a Conduit or a Sink.

In the interest of generality, most library functions will be written in terms of Producer or Consumer. As a user, you can simply use Source and Sink in most of your code, unless you need to use a function as Conduit as well.

And for the cases where you have a Source and wish to convert it to a Conduit after the fact (e.g., it comes from another person's library), you can use toProducer, or toConsumer for Sinks.

Termination

Let's talk about the lifetime of a sequence of components (we'll call it a pipeline). A pipeline is always driven from downstream. This means, for example, that if we connect a Source and a Sink, we start our execution with the Sink.

The Sink will continue processing- however that specific Sink processes- until it needs more input. Then it calls await, and processing is paused until new input is available. For the Source, it will be woken up when the downstream component asks for input, and will yield control downstream when it yields a value. As soon as the Sink completes, the entire pipeline terminates.

The following example demonstrates how the components of our pipeline interact with each other. Try modifying the parameter to sink from 2 to 4 to see how that affects the output.

import Data.Conduit
import Control.Monad.IO.Class

-- show Termination

source = do
    liftIO $ putStrLn "source: yielding 1"
    yield 1
    liftIO $ putStrLn "source: yielding 2"
    yield 2
    liftIO $ putStrLn "source: yielding 3"
    yield 3
    
conduit = do
    liftIO $ putStrLn "conduit calling await"
    mx <- await
    case mx of
        Nothing -> liftIO $ putStrLn "Nothing left, exiting"
        Just x -> do
            liftIO $ putStrLn $ "conduit yielding " ++ show x
            yield x
            conduit
            
sink 0 = liftIO $ putStrLn "sink is finished, terminating"
sink i = do
    liftIO $ putStrLn $ "sink: still waiting for " ++ show i
    mx <- await
    case mx of
        Nothing -> liftIO $ putStrLn "sink: Nothing from upstream, exiting"
        Just x -> do
            liftIO $ putStrLn $ "sink received: " ++ show x
            sink (i - 1)
            
main = source $$ conduit =$ sink 2
-- /show

Based on what we've said until now, there's a big limitation. Sources and Conduits have no way of cleaning up after themselves, since they are terminated immediately when anything downstream from them terminates. To address this, conduit supports the concept of terminators. Each time a Source or Conduit yields a value downstream, it may additionally include a clean-up function. Each time the Source yields, it overwrites the previously yielded clean-up function. Let's see a simple example:

import Data.Conduit
import qualified Data.Conduit.List as CL

source =
    loop 1
  where
    loop i = do
        yieldOr i $ putStrLn $ "Terminated when yielding: " ++ show i
        loop $ i + 1
        
main = source $$ CL.isolate 7 =$ CL.mapM_ print

While in our examples till now this isn't incredibly important, when we start dealing with scarce resources like file descriptors, we need the ability to close the descriptor as soon as we're done with it.

Manually inserting yieldOrs throughout your codebase can be very tedious. Instead, it's usually easier to use the addCleanup function, which will ensure that a certain function is called on termination. Your cleanup function is provided a Bool parameter. If True, it means that the component ran to its normal completion. If False, it means that downstream terminated first.

Let's demonstrate some simple file I/O. Note that the code below deals with characters one at a time, and is thus incredibly inefficient. It is highly recommended to use Data.Conduit.Binary for real-world use cases.

{-# START_FILE test.txt #-}
This is a test.
{-# START_FILE main.hs #-}
import System.IO
import Data.Conduit
import Control.Monad.IO.Class
import qualified Data.Conduit.List as CL

source = do
    handle <- liftIO $ openFile "test.txt" ReadMode
    addCleanup (const $ putStrLn "Closing handle" >> hClose handle) $ loop handle
  where
    loop handle = do
        eof <- liftIO $ hIsEOF handle
        if eof
            then return ()
            else do
                c <- liftIO $ hGetChar handle
                yield c
                loop handle
                
main = source $$ CL.isolate 5 =$ CL.mapM_ print

Exception Safety

There's still a major flaw in our addCleanup approach: it's not exception safe! If an exception is thrown by either our component or any other component in the pipeline, our Handle will not be closed correctly.

In order to guarantee that an action takes place even in the presence of exceptions, we need to introduce one final function: bracketP. It works very similarly to the standard bracket function: you provide it an allocate function which creates some scarce resource, a cleanup function which frees that resource, and an inside function which will perform some action with that resource.

Let's rewrite our inefficient file reader above to use bracketP.

{-# START_FILE test.txt #-}
This is a test.
{-# START_FILE main.hs #-}
import System.IO
import Data.Conduit
import Control.Monad.IO.Class
import qualified Data.Conduit.List as CL

source =
-- show Better with bracketP
    bracketP
        (openFile "test.txt" ReadMode)
        (\handle -> putStrLn "Closing handle" >> hClose handle)
        loop
-- /show
  where
    loop handle = do
        eof <- liftIO $ hIsEOF handle
        if eof
            then return ()
            else do
                c <- liftIO $ hGetChar handle
                yield c
                loop handle

-- show An exception-throwing sink.
exceptionalSink = do
    c <- await
    liftIO $ print c
    error "This throws an exception"
-- /show

-- show We also need to call runResourceT
main = runResourceT $ source $$ exceptionalSink
-- /show

Notice our call to runResourceT. At the point where execution leaves that function, all resources allocated inside that block will be freed. For more information on ResourceT, please see Control.Monad.Trans.Resource.

Connect and resume

conduit introduces a form of inversion of control. You no longer control the flow of execution of your program. Instead, you declaratively state when individual components need input and provide output, and then conduit ensures that everything is passed around correctly. For many use cases, this is sufficient. However, there are some cases where you may want to have more control over the flow of execution. Connect and resume provides you such an escape route.

Connect and resume introduces the concept of a resumable source. This is a Source which has been partially run, but can be continued by reconnecting to another Sink. To create a ResumableSource, you use the $$+ connect-and-resume operator. To reconnect a ResumableSource to a new Sink and get an updated ResumableSource, use the $$++ operator. And finally, you use the $$+- to connect a ResumableSource to its final Sink.

import Data.Conduit
import qualified Data.Conduit.List as CL

main = do
    (rsrc1, result1) <- CL.sourceList [1..10] $$+ CL.take 3
    (rsrc2, result2) <- rsrc1 $$++ CL.take 3
    result3 <- rsrc2 $$+- CL.consume
    print (result1, result2, result3)

The important thing to note about this ResumableSource is that it might have some cleanup function associated with it, so you must ultimately call $$+- or else risk delaying cleanup of those resources.

Connect and resume usually only comes up in more complicated control flow operations, so it's likely that you won't run into it in your normal usage of conduit. One library which does utilize this is http-conduit, where a ResumableSource is returned from the http function to represent the body of an HTTP response.

Further reading

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