Safe Haskell | Safe-Inferred |
---|---|
Language | Haskell2010 |
A capability is a type class over a monad which specifies the effects that a function is allowed to perform. Capabilities differ from traditional monad transformer type classes in that they are completely independent of the way the monad is constructed. A state capability can for instance be implemented as a lens on a field in a larger state monad, or an error capability could provide for throwing only a subset of the errors of an error monad.
This library defines several standard, reusable capabilities that replace the mtl's monad-transformer type classes. Because capabilities are not tied to a particular implementation of the monad, they cannot be discharged by instance resolution. Instead this library provides combinators in the form of newtypes with instances, to be used with deriving-via. To learn about deriving via, watch Baldur Blondal's introductory video https://skillsmatter.com/skillscasts/10934-lightning-talk-stolen-instances-taste-just-fine.
By way of comparison, with the mtl you would write something like
foo :: (MonadReader E, MonadState S) => a -> m ()
You can use foo
at type a -> ReaderT E (State S)
. But you can't use foo
with the ReaderT
pattern
https://www.fpcomplete.com/blog/2017/06/readert-design-pattern. With this
library, you would instead have:
foo :: (HasReader "conf" E, HasState "st" S) => a -> m ()
Where "conf"
and "st"
are the names (also referred to as tags) of the
capabilities demanded by foo. Contrary to the mtl, capabilities are named,
rather than disambiguated by the type of their implied state, or exception.
This makes it easy to have multiple state capabilities.
To provide these capabilities, for instance with the ReaderT pattern, do as follows (for a longer form tutorial, check the README):
newtype MyM a = MyM (ReaderT (E, IORef s)) deriving (Functor, Applicative, Monad) deriving (HasState "st" Int) via ReaderIORef (Rename 2 (Pos 2 () (MonadReader (ReaderT (E, IORef s) IO)))) deriving (HasReader "conf" Int) via (Rename 1 (Pos 1 () (MonadReader (ReaderT (E, IORef s) IO))))
Then you can use foo
at type MyM
. Or any other type which can provide
these capabilites.
Functional capabilities
When writing applications, as opposed to libraries, a capability name often determines its type parameters. It can be tiresome to write
f :: HasReader "config" Config m => …
over and over again.
To avoid this, each capability comes with a functional—here
HasReader'
—variant (in this terminology HasReader
is
relational). Where the type is deduced from the capability's name. The
mapping from name to type is done with the
family, which is re-exported by every capability module.TypeOf
type instance TypeOf Symbol "config" = Config f :: HasReader' "config" m => …
Module structure
Each module introduces a capability type class (or several related type classes). Each class comes with a number of instances on newtypes (each newtype should be seen as a combinator to be used with deriving-via to provide the capability). Many newtypes come from the common Capability.Accessors module (re-exported by each of the other modules), which in particular contains a number of ways to address components of a data type using the generic-lens library.
- Capability.Reader reader effects
- Capability.State state effects
- Capability.Writer writer effects
- Capability.Error throw and catch errors
- Capability.Source streaming in effect
- Capability.Sink streaming out effect (aka generators)
The effects are not all independent:
Source Sink / \ / \ / \ / \ Reader State Writer
Capability.Source and Capability.Sink have just a method each, and no laws.
The bottom three, familiar from mtl, add methods and laws relating them.
The use of tags allows one to have independent effects that share a superclass.
E.g. HasState "foo" Int
and HasWriter "bar" String
.
Some of the capability modules have a “discouraged” companion (such as Capability.Writer.Discouraged). These modules contain deriving-via combinators which you can use if you absolutely must: they are correct, but inefficient, so we recommend that you do not.
Finally there are
- Capability.Derive
Which exports a (still experimental)
derive
function, which lets you run a computation which requires capabilities which are not directly provided by the ambient monad, but can be derived from the capabilities provided by the ambient monad. - Capability.Reflection
Which exports
interpret_
andinterpret
, which let you define an ad-hoc interpretation of a capability based on the capabilities provided by the ambient monad.
Further considerations
The tags of capabilities can be of any kind, they are not restricted to symbols. When exporting functions demanding capabilities in libraries, it is recommended to use a type as follows:
data Conf foo :: HasReader Conf C => m ()
This way, Conf
can be qualified in case of a name conflict with another
library.