generic-data-functions
A small Haskell library providing some funky generics that work over arbitrary
Haskell data types. We handle the sums of products representation; you only need
to pass a handful of definitions. Obtain simple, type-safe generic
serializers/reducers and parsers for almost zero effort.
Well, OK, so really this is a generic binary serialization library. It just so
happens that the generics look like foldMap and traverse.
Really?
Kind of. We only handle sequential concatenation, being cleanly represented by
builtin type classes. Weirder cases like JSON parsing/serialization have more
going on, and aren't sensibly discussed generically. So you are probably only
going to use this with bytestrings and simple binary formats.
Why?
It is 2023. There are a number of competing parsing and serialization Haskell
libraries, recently some notable high-performance ones. These are often fairly
experimental. Maybe you want some generics to benchmark some real-world use case
against popular libraries like binary and cereal. But maybe generics aren't
provided. Shucks.
That's a shame, because a binary/cereal-esque generic binary parser or
serializer doesn't have much work to do:
- traverse the generic sum-of-products tree of the given type left to right
- defer to the appropriate type class for base cases
Sum types necessitate a little more work. Otherwise, most such parsers and
serializers look fairly comparable to each other. Why are we rewriting this
stuff over and over again?
generic-data-functions provides reusable generics which have holes in for your
favorite parsers and serializers. Fill out a few definitions to receive a fresh
new generic instance for your own library, without all the boilerplate.
Functions
foldMap (L->R)
foldMap :: (Foldable t, Monoid m) => (a -> m) -> t a -> m
The user provides the a -> m dictionary via a special type class instance.
Constructor fields are mapped and combined left-to-right. Sum representations
are handled by mappending the constructor via a user-supplied String -> m
first.
Useful for:
- simple binary serializers which just concatenate fields together
- reducing to a numeric value
traverse (L->R)
traverse :: (Traversable t, Applicative f) => (a -> f b) -> t a -> f (t b)
The user provides the f a dictionary via a special type class instance.
Constructor field actions are run left-to-right.
Sum representations are handled by running a constructor action first (thus
requiring Monad f).
Useful for:
- simple binary parsers which can parse generic
foldMap output
Notes
Orphan instances
This library is designed to work with and around existing libraries and type
classes. Thus, you will likely be dealing in orphans. Instances, that is. That's
life, Jim.
Funky generics
I have made some weird design choices in this library. Here are some rationales.
Handling badness on type & term levels
I don't like silently erroring on badly-configured generics usage, e.g. asking
for a function via generics for an empty data type. Originally, I made those
type error, and that was that. But it meant I would write the same instance over
and over again. And that requirement was hidden in a type class implementation.
Really, it'd be nice if I could put such requirements directly in the types of
the functions that have them.
I've done that. Now, on certain representation errors, e.g. you tried to use
non-sum generics on a sum type, we runtime error instead. However, there's a
separate layer for making assertions about generic representation on the type
level, the use of which is highly suggested.
Note that if you like to write wrappers over generic functions to fill in
certain bits of info, your job just got a lot uglier. Soz. Anything for type
safety my sweet.
License
Provided under the MIT license. See LICENSE for license text.
