.github/workflows | ||
bench | ||
examples | ||
src | ||
tests | ||
.gitignore | ||
cabal.haskell-ci | ||
CHANGELOG.md | ||
effective.cabal | ||
LICENSE | ||
README.md |
effective
Note: this is a pre-release.
A performant, easy to reason about extensible effects library with seamless integration with the existing Haskell ecosystem.
Main features:
-
Very fast.
-
Internals of the library are easy to reason about.
-
Correct semantics in presence of runtime exceptions (no more lost or discarded state).
-
Seamless integration with the existing ecosystem (
exceptions
,monad-control
,unliftio-core
,resourcet
). -
Effects can be defined for either
-
static dispatch (as fast as it gets, single interpretation) or
-
dynamic dispatch (slower, multiple interpretations are possible),
depending on your needs.
-
Motivation
Do we really need yet another library for handling effects? There's freer-simple, fused-effects, polysemy, eff and probably a few more.
Unfortunately, of all of them only eff
is a promising proposition because
of reasonable performance characteristics (see the talk "Effects for Less"
linked below for more information) and potential for good interoperability with
the existing ecosystem.
The second point is arguably the most important, because it allows focusing on things that matter instead of reinventing all kinds of wheels and is crucial for adoption of the library.
However, eff
uses delimited continuations underneath, which:
-
Are not yet supported by GHC (though the proposal for including support for them has been accepted).
-
Are somewhat hard to understand.
-
Make the space of possible effects "too big", i.e. some of their interactions might no longer make sense. For example, there is no
MonadWriter
instance for theContT
transformer in themtl
library, because it can't be properly implemented. It's not clear howeff
can detect and prevent such interactions.
On the other hand, if support for continuations is excluded from the handler
monad, then the ability to define effects with non-linear control flow (such as
NonDet
) is lost. Arguably it's a small price to pay for predictability,
because such specialized effects are needed rarely and locally, at which point a
dedicated, well established solution such as
conduit,
list-t or
logict can be used.
This is where effective
comes in. The Eff
monad it uses is essentially a
ReaderT
over IO
on steroids, allowing us to dynamically extend its
environment with data types that represent effects.
Because this concept is so simple:
-
It's reasonably easy to understand what is going on under the hood.
-
The
Eff
monad being a reader allows for seamless interoperability with ubiquitous classes such asMonadBaseControl
andMonadUnliftIO
as well as support for handling runtime exceptions without worrying about lost or discarded state (see the talk "Monad Transformer State" linked below for more information).
What is more:
-
The
Eff
monad is concrete, so GHC has many possibilities for optimization, which results in a very fast code at a default optimization level. There is no need to mark every functionINLINE
or enable additional optimization passes, it just works. -
If an advanced effect with non-linear control flow is needed, you can always stick a transformer that implements it on top of
Eff
in a local context.
In conclusion, effective
aims to reduce duplication and bring back performance
to "boring" transformer stacks, most of which are a dozen of newtype'd StateT
or ReaderT
transformers, each with a few associated operations (usually tied
to a type class), not to replace monad transformers altogether.
Example
A Filesystem
effect with two handlers, one that runs in IO
and another that
uses an in-memory virtual file system can be found
here.
Resources
Resources that inspired the rise of this library and had a lot of impact on its design.
Talks:
-
Monad Transformer State by Michael Snoyman.
-
Effects for Less by Alexis King.
Blog posts:
-
ReaderT design pattern by Michael Snoyman.
-
Exceptions Best Practices by Michael Snoyman.