heftia/heftia-effects
2024-10-29 11:12:23 +09:00
..
bench [WIP] composable streaming pipe using first-order async effects (though this idea might not be good...) 2024-10-22 11:12:52 +09:00
Example [fix] Add display of each file size for clarity in NonDet example. 2024-10-29 11:12:23 +09:00
src/Control/Monad/Hefty [add] NonDet example. 2024-10-28 15:40:13 +09:00
test [fix] naming conventions in Parallel interpreters. 2024-10-27 13:49:31 +09:00
.gitignore [add] handlers for the Reader effect. 2023-09-01 21:59:56 +09:00
ChangeLog.md [fix] Generalize runUnliftIO to use any monad that is an instance of MonadUnliftIO. 2024-10-17 15:51:37 +09:00
heftia-effects.cabal [add] NonDet example. 2024-10-28 15:40:13 +09:00
LICENSE [add] handlers for the Reader effect. 2023-09-01 21:59:56 +09:00
NOTICE [fix] Clarify NOTICE. 2023-09-17 15:34:05 +09:00
README.md [fix] Rewrote the operation functions for the Effectful types using the 'Decomp*' constraints approach. 2024-01-05 14:30:14 +09:00

Heftia: higher-order algebraic effects done right

Hackage Hackage Stackage Build status

Heftia is an extensible effects library for Haskell that generalizes "Algebraic Effects and Handlers" to higher-order effects, providing users with maximum flexibility and delivering standard and reasonable speed. In its generalization, the focus is on ensuring predictable results based on simple, consistent semantics, while preserving soundness.

Please refer to the Haddock documentation for usage and semantics. For information on performance, please refer to performance.md.

This library is inspired by the paper:

  • Casper Bach Poulsen and Cas van der Rest. 2023. Hefty Algebras: Modular Elaboration of Higher-Order Algebraic Effects. Proc. ACM Program. Lang. 7, POPL, Article 62 (January 2023), 31 pages. https://doi.org/10.1145/3571255

The elaboration approach proposed in the above paper allows for a straightforward treatment of higher-order effects.

Heftia's data structure is an extension of the Freer monad, designed to be theoretically straightforward by eliminating ad-hoc elements.

Why choose this library over others?

This library is based on algebraic effects. Currently, none of the practical effect libraries other than this one are "algebraic." So, why is being algebraic important?

For example, algebraic effects are essential for managing coroutines, generators, streaming, concurrency, non-deterministic computations, and more in a highly elegant and concise manner.

Algebraic effects provide a consistent and predictable framework for handling side effects, enhancing modularity and flexibility in your code. Research in cutting-edge languages like Koka, Eff lang, and OCaml 5 is advancing the understanding and implementation of algebraic effects, establishing them as the programming paradigm of the future.

Heftia extends this by supporting higher-order algebraic effects, allowing for more expressive and modular effect management. This leads to more maintainable and extensible applications compared to non-algebraic effect libraries, positioning Heftia at the forefront of modern effect handling techniques.

Furthermore, Heftia is functionally a superset of other effect libraries, especially those based on ReaderT over IO. In other words, anything that is possible with other libraries is also possible with this library. This is because Heftia supports MonadUnliftIO in the form of higher-order effects.

Heftia should be a good substitute for mtl, polysemy, fused-effects, and freer-simple. Additionally, if performance is not a top priority, it should also be a good alternative for effectful. If performance is particularly important, effectful would be the best alternative to this library.

Key Features

  • Correct Semantics for Higher-Order Effects & Continuations

    This library provides the following features simultaneously, which existing libraries could not support together:

    All of these interact through a simple, consistent, and predictable semantics based on algebraic effects.

  • Easy and Concise Implementation for Custom Effect Interpreters

    As you can see from the implementations of basic effect interpreters such as State, Throw/Catch, Writer, NonDet, and Coroutine, they can be implemented in just a few lines, or even a single line. Even for effects like NonDet and Coroutine, which involve continuations and might seem difficult to implement at first glance, this is exactly how simple it can be. This is the power of algebraic effects. Users can quickly define experimental and innovative custom effects using continuations.

  • Standard and Reasonable Performance

    It operates at a speed positioned roughly in the middle between faster libraries (like effectful or eveff) and relatively slower ones (like polysemy or fused-effects): performance.md.

  • Purity

    • Does not depend on the IO monad and can use any monad as the base monad.
    • Semantics are isolated from the IO monad, meaning that aspects like asynchronous exceptions and threads do not affect the behavior of effects.
    • The constructors of the Eff monad are exposed, and users can manipulate them directly without any safety concerns. Still, the semantics remain intact.
    • These are in contrast to libraries like effectful and eff, making this library more Haskell-ish and purely functional.

Downsides

This library has notable semantic differences, particularly compared to libraries like effectful, polysemy, and fused-effects. The semantics of this library are almost equivalent to those of freer-simple and are also similar to Alexis King's eff library. This type of semantics is often referred to as continuation-based semantics. Additionally, unlike recent libraries such as effectful, which have an IO-fused effect system, the semantics of this library are separated from IO. Due to these differences, people who are already familiar with the semantics of other major libraries may find it challenging to transition to this library due to the mental model differences.

For those who have not used an extensible effects library in Haskell before, this should not be a problem. Particularly, if you are already somewhat familiar with the semantics of algebraic effects through languages like koka or eff-lang, you likely already have the mental model needed for this library, and everything should go smoothly.

Status

This library is currently in the beta stage. There may be significant changes and potential bugs.

We are looking forward to your feedback!

Getting Started

  1. $ cabal update
    
  2. Add heftia-effects ^>= 0.4 and ghc-typelits-knownnat ^>= 0.7 to the build dependencies. Enable the ghc-typelits-knownnat plugin, GHC2021, and the following language extensions as needed:

    • LambdaCase
    • DerivingStrategies
    • DataKinds
    • TypeFamilies
    • BlockArguments
    • FunctionalDependencies
    • RecordWildCards
    • DefaultSignatures
    • PatternSynonyms

Example .cabal:

...
    build-depends:
        ...
        heftia-effects ^>= 0.4,
        ghc-typelits-knownnat ^>= 0.7,

    default-language: GHC2021

    default-extensions:
        ...
        LambdaCase,
        DerivingStrategies,
        DataKinds,
        TypeFamilies,
        BlockArguments,
        FunctionalDependencies,
        RecordWildCards,
        DefaultSignatures,
        PatternSynonyms,
        TemplateHaskell,
        PartialTypeSignatures,
        AllowAmbiguousTypes
...

If you encounter an error like the following, add the pragma:

{-# OPTIONS_GHC -fplugin GHC.TypeLits.KnownNat.Solver #-}

to the header of your source file.

Could not deduce GHC.TypeNats.KnownNat (1 GHC.TypeNats.+ ...)

The supported versions are GHC 9.4.1 and later. This library has been tested with GHC 9.8.2 and 9.4.1.

Example

Coroutine-based Composable Concurrent Stream (since v0.5)

Below is an example of using concurrent streams (pipes).

{-# OPTIONS_GHC -fplugin GHC.TypeLits.KnownNat.Solver #-}

import Control.Monad.Hefty
import Control.Monad.Hefty.Concurrent.Stream
import Control.Monad.Hefty.Concurrent.Timer
import Control.Monad.Hefty.Except
import Control.Monad.Hefty.Unlift
import Control.Arrow ((>>>))
import Control.Monad (forever, void, when)
import Data.Foldable (for_)
import UnliftIO (bracket_)

-- | Generates a sequence of 1, 2, 3, 4 at 0.5-second intervals.
produce :: (Output Int <| ef, Timer <| ef) => Eff '[] ef ()
produce = void . runThrow @() $
    for_ [1 ..] \(i :: Int) -> do
        when (i == 5) $ throw ()
        output i
        sleep 0.5

-- | Receives the sequence at 0.5-second intervals and prints it.
consume :: (Input Int <| ef, Timer <| ef, IO <| ef) => Eff eh ef ()
consume = forever do
    liftIO . print =<< input @Int
    sleep 0.5

-- | Transforms by receiving the sequence as input at 0.5-second intervals,
--   adds 100, and outputs it.
plus100 :: (Input Int <| ef, Output Int <| ef, Timer <| ef, IO <| ef) => Eff eh ef ()
plus100 = forever do
    i <- input @Int
    let o = i + 100
    liftIO $ putStrLn $ "Transform " <> show i <> " to " <> show o
    output o
    sleep 0.5

main :: IO ()
main = runUnliftIO . runTimerIO $ do
    let produceWithBracket =
            bracket_
                (liftIO $ putStrLn "Start")
                (liftIO $ putStrLn "End")
                (raiseAllH produce)

    runMachineryIO_ $
        Unit @() @Int do
            produceWithBracket
            produceWithBracket
            >>> Unit @Int @Int plus100
            >>> Unit @Int @() consume
>>> main
Start
Transform 1 to 101
101
Transform 2 to 102
102
Transform 3 to 103
103
Transform 4 to 104
104
End
Start
Transform 1 to 101
101
Transform 2 to 102
102
Transform 3 to 103
103
Transform 4 to 104
104
End
  • Each function (machine unit) produce, consume, and plus100 operates with input/output at 0.5-second intervals, but note that the composed stream also maintains operation intervals at 0.5 seconds (not 1.5 seconds!). This means that each unit operates concurrently based on threads.

  • End is displayed just after the first sequence ends and before the second sequence starts. This demonstrates that the bracket_ function based on MonadUnliftIO for safe resource release works in such a way that resources are released immediately at the correct timing—even if the stream is still in progress—rather than waiting until the entire stream (including the second sequence) has completed. Existing stream libraries like pipes and conduit have the issue that immediate resource release like this is not possible. This problem was first addressed by the effect system library bluefin. For more details, please refer to Bluefin streams finalize promptly.

The complete code example can be found at heftia-effects/Example/Stream/Main.hs.

Aggregating File Sizes Using Non-Deterministic Computation

The following is an extract of the main parts from an example of non-deterministic computation. For the full code, please refer to heftia-effects/Example/NonDet/Main.hs.

-- | Aggregate the sizes of all files under the given path
totalFileSize
    :: (Choose <| ef, Empty <| ef, FileSystem <| ef, Throw NotADir <| ef, IO <| ef)
    => FilePath
    -> Eff '[] ef (Sum Integer)
totalFileSize path = do
    entities :: [FilePath] <- listDirectory path & joinEither

    -- Non-deterministically *pick* one item from the list
    entity :: FilePath <- choice entities

    let path' = path </> entity

    liftIO $ putStrLn $ "Found " <> path'

    getFileSize path' >>= \case
        Right size -> do
            liftIO $ putStrLn $ " ... " <> show size <> " bytes"
            pure $ Sum size
        Left NotAFile -> do
            totalFileSize path'

main :: IO ()
main = runEff
    . runThrowIO @EntryNotFound
    . runThrowIO @NotADir
    . runDummyFS exampleRoot
    $ do
        total <- runNonDetMonoid pure (totalFileSize ".")
        liftIO $ print total

-- | Effect for file system operations
data FileSystem a where
    ListDirectory :: FilePath -> FileSystem (Either NotADir [FilePath])
    GetFileSize :: FilePath -> FileSystem (Either NotAFile Integer)

{- |
Interpreter for the FileSystem effect that virtualizes the file system in memory
based on a given FSTree, instead of performing actual IO.
-}
runDummyFS
    :: (Throw EntryNotFound <| ef, Throw NotADir <| ef)
    => FSTree
    -> Eff eh (FileSystem ': ef) ~> Eff eh ef
runDummyFS root = interpret \case
    ListDirectory path ->
        lookupFS path root <&> \case
            Dir entries -> Right $ Map.keys entries
            File _ -> Left NotADir
    GetFileSize path ->
        lookupFS path root <&> \case
            File size -> Right size
            Dir _ -> Left NotAFile
>>> main
Found ./README.md
 ... 4000 bytes
Found ./src
Found ./src/Bar.hs
 ... 1000 bytes
Found ./src/Foo.hs
 ... 2000 bytes
Found ./test
Found ./test/Baz.hs
 ... 3000 bytes
Sum {getSum = 10000}

Documentation

A detailed explanation of usage and semantics is available in Haddock. The example codes are located in the heftia-effects/Example/ directory. Also, the following HeftWorld example (outdated): https://github.com/sayo-hs/HeftWorld

About the internal elaboration mechanism: https://sayo-hs.github.io/jekyll/update/2024/09/04/how-the-heftia-extensible-effects-library-works.html

Comparison

  • Higher-Order Effects: Does it support higher-order effects?

  • Delimited Continuation: The ability to manipulate delimited continuations.

  • Effect System: For a term representing an effectful program, is it possible to statically decidable a type that enumerates all the effects the program may produce?

  • Purely Monadic: Is an effectful program represented as a transparent data structure that is a monad, and can it be interpreted into other data types using only pure operations without side effects or unsafePerformIO?

  • Dynamic Effect Rewriting: Can an effectful program have its internal effects altered afterwards (by functions typically referred to as handle with, intercept, interpose, transform, translate, or rewrite) ?

    For example, would it be possible to apply interpose as many times as the number of values input by the user at runtime?

  • Semantics: Classification of behaviors resulting from the interpretation of effects.

    • Algebraic Effects: The same as Algebraic Effects and Handlers.
    • IO-fused: IO + ReaderT pattern.
    • Carrier dependent: The behavior depends on the specific type inference result of the monad. Tagless-final style.
Library or Language Higher-Order Effects Delimited Continuation Effect System Purely Monadic Dynamic Effect Rewriting Semantics
heftia Yes Multi-shot Yes Yes Yes Algebraic Effects
freer-simple No Multi-shot Yes Yes Yes Algebraic Effects
polysemy Yes No Yes Yes Yes Weaving-based (functorial state)
effectful Yes No Yes No (based on the IO monad) Yes IO-fused
bluefin Yes No Yes No (based on the IO monad) Yes IO-fused
eff Yes Multi-shot Yes No (based on the IO monad) Yes Algebraic Effects & IO-fused 1
speff Yes Multi-shot (restriction: 2) Yes No (based on the IO monad) Yes Algebraic Effects & IO-fused
in-other-words Yes Multi-shot? Yes Yes No? Carrier dependent
mtl Yes Multi-shot (ContT) Yes Yes No Carrier dependent
fused-effects Yes No? Yes Yes No Carrier dependent & Weaving-based (functorial state)
Koka-lang No Multi-shot Yes No (language built-in) Yes Algebraic Effects
Eff-lang No Multi-shot Yes No (language built-in) Yes Algebraic Effects
OCaml-lang 5 ? One-shot No 3 No (language built-in) ? Algebraic Effects

Heftia can simply be described as a higher-order version of freer-simple. This is indeed true in terms of its internal mechanisms as well.

Additionally, this library provides a consistent algebraic effects semantics that is independent of carriers and effects. On the other hand, in libraries like in-other-words, mtl, and fused-effects, the semantics of the code depend on the effect and, in part, the carrier inferred by type inference. Fixing the semantics to a algebraic effects model helps improve the predictability of the behavior (interpretation result) of the code without losing flexibility.

Carrier-dependent semantics can lead to unexpected behavior for code readers, particularly in situations where the types become implicit. Particularly, attention should be given to the fact that due to type inference, semantic changes may propagate beyond the blocks enclosed by interpret or interpose. In the case of carrier-independent semantics, especially with Freer-based effects, interpret and interpose do not alter the semantics by intervening in type inference or instance resolution of the carrier. Instead, they function as traditional functions, simply transforming the content of the data structure. This results in minimal surprise to the mental model of the code reader.

Performance

Overall, the performance of this library is positioned roughly in the middle between the fast (effectful, eveff, etc.) and slow (polysemy, fused-effects, etc.) libraries, and can be considered average. In all benchmarks, the speed is nearly equivalent to freer-simple, only slightly slower.

For more details, please refer to performance.md.

Interoperability with other libraries

About mtl

  • Since the representation of effectful programs in Heftia is simply a monad (Eff), it can be used as the base monad for transformers. This means you can stack any transformer on top of it.

  • The Eff monad is an instance of MonadIO, MonadError, MonadRWS, MonadUnliftIO, Alternative, etc., and these behave as the senders for the embedded IO or the effect GADTs defined in data-effects.

About effectful

  • In Heftia, since any monad can be used as the base monad of Eff, by setting the Eff monad from effectful as the base monad of Heftia, you can stack any effect in Heftia on top of effectful. In other words, the Eff of Heftia itself can be used like a monad transformer. This is not limited to effectful.

  • By using Control.Monad.Hefty.Unlift.runUnliftIO instead of Control.Monad.Hefty.runEff, you can inherit and use the MonadUnliftIO functionality of effectful's Eff as a higher-order UnliftIO effect within Heftia.

Representation of effects

  • Heftia relies on data-effects for the definitions of standard effects such as Reader, Writer, and State.

  • It is generally recommended to use effects defined with automatic derivation provided by data-effects-th.

  • The representation of first-order effects is compatible with freer-simple. Therefore, effects defined for freer-simple can be used as is in this library. However, to avoid confusion between redundantly defined effects, it is recommended to use the effects defined in data-effects.

  • GADTs for higher-order effects are formally similar to polysemy and fused-effects, but they need to be instances of the HFunctor type class. While it's not impossible to manually derive HFunctor for effect types based on these libraries and use them, it's inconvenient, so it's better to use data-effects. Also, it is not compatible with effectful and eff.

Future Plans

  • Increase effects and nurture the ecosystem
    • concurrent/parallel programming, streaming, co-log: to be released in v0.5
    • file system, Subprocesses, POSIX, and so on...
  • Write practical software using Heftia
  • Support for Applicative effects
  • (Support for Linear effects?)

License

The license is MPL 2.0. Please refer to the NOTICE. Additionally, the code from freer-simple has been modified and used internally within this library. Therefore, some modules are licensed under both MPL-2.0 AND BSD-3-Clause. For details on licenses and copyrights, please refer to the module's Haddock documentation.

Your contributions are welcome!

Please see CONTRIBUTING.md.

The following is a non-exhaustive list of people and works that have had a significant impact, directly or indirectly, on Heftias design and implementation:


  1. https://github.com/hasura/eff/issues/12 ↩︎

  2. Scoped Resumption only. e.g. Coroutines are not supported. ↩︎

  3. Effects do not appear in the type signature and can potentially cause unhandled errors at runtime ↩︎