djspiewak / shims

Seamless interop layer between cats and scalaz
Apache License 2.0
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cats compatibility scalaz typeclasses

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As of Cats 2.3.0 (and above), most major instances are included in the implicit scope without requiring extra imports. This is tremendously convenient for users, but it fundamentally breaks Shims, since any scope in which shims is imported along with instances from scalaz results in an unprioritized ambiguity. However, no one really complained about this, despite it being broken for months, which leads me to conclude that this library is no longer needed and may be archived.

This repository is left up for pedagogical reasons, as it is quite interesting to see what techniques are necessary to do something like this in Scala's type system (both Scala 2 and Scala 3). However, I will no longer be maintaining Shims going forward. I recommend everyone who was depending on it to upgrade to Cats at your earliest convenience, as it will provide a generally better experience all around within a more modern ecosystem.

Shims aims to provide a convenient, bidirectional, and transparent set of conversions between scalaz and cats, covering typeclasses (e.g. Monad) and data types (e.g. \/). By that I mean, with shims, anything that has a cats.Functor instance also has a scalaz.Functor instance, and vice versa. Additionally, every convertible scalaz datatype – such as scalaz.State – has an implicitly-added asCats function, while every convertible cats datatype – such as cats.free.Free – has an implicitly-added asScalaz function.

Only a single import is required to enable any and all functionality:

import shims._

Toss that at the top of any files which need to work with APIs written in terms of both frameworks, and everything should behave seamlessly. You can see some examples of this in the test suite, where we run the cats laws-based property tests on scalaz instances of various typeclasses.

Usage

Add the following to your SBT configuration:

libraryDependencies += "com.codecommit" %%% "shims" % "<version>"

Cross-builds are available for Scala 2.12 and 2.13, and Dotty 0.25.0 and 0.26.0-RC1. ScalaJS builds target the 1.x line. It is strongly recommended that you enable the relevant SI-2712 fix in your build if using 2.12. Details here. A large number of conversions will simply not work without partial unification.

Note that shims generally follows epoch.major.minor versioning schemes, meaning that changes in the second component may be breaking. This is mostly because maintaining strict semver with shims would be immensely difficult due to the way the conversions interact. Shims is more of a leaf-level project, anyway, so semantic versioning is somewhat less critical here. Feel free to open an issue and make your case if you disagree, though.

Once you have the dependency installed, simply add the following import to any scopes which require cats-scalaz interop:

import shims._

That's it!

Effect Types

You can also use shims to bridge the gap between the older scalaz Task hierarchy and newer frameworks which assume cats-effect typeclasses and similar:

libraryDependencies += "com.codecommit" %% "shims-effect" % "<version>"
import shims.effect._

For more information, see the shims-effect subproject readme.

Upstream Dependencies

At present, there is no complex build matrix of craziness to provide support for other major versions of each library. This will probably come in time, when I've become sad and jaded, and possibly when I have received a pull request for it.

Quick Example

In this example, we build a data structure using both scalaz's IList and cats' Eval, and then we use the cats Traverse implicit syntax, which necessitates performing multiple transparent conversions. Then, at the end, we convert the cats Eval into a scalaz Trampoline using the explicit asScalaz converter.

import shims._

import cats.Eval
import cats.syntax.traverse._
import scalaz.{IList, Trampoline}

val example: IList[Eval[Int]] = IList(Eval.now(1), Eval.now(2), Eval.now(3))

val sequenced: Eval[IList[Int]] = example.sequence
val converted: Trampoline[IList[Int]] = sequenced.asScalaz

Conversions

Typeclasses

Typeclass conversions are transparent, meaning that they will materialize fully implicitly without any syntactic interaction. Effectively, this means that all cats monads are scalaz monads and vice versa.

What follows is an alphabetized list (in terms of cats types) of typeclasses which are bidirectionally converted. In all cases except where noted, the conversion is exactly as trivial as it seems.

Note that some typeclasses exist in one framework but not in the other (e.g. Group in cats, or Split in scalaz). In these cases, no conversion is attempted, though practical conversion may be achieved through more specific instances (e.g. Arrow is a subtype of Split, and Arrow will convert).

And don't get me started on the whole Bind vs BindRec mess. I make no excuses for that conversion. Just trying to make things work as reasonably as possible, given the constraints of the upstream frameworks.

Let me know if I missed anything! Comprehensive lists of typeclasses in either framework are hard to come by.

Datatypes

Datatype conversions are explicit, meaning that users must insert syntax which triggers the conversion. In other words, there is no implicit coercion between data types: a method call is required. For example, converting between scalaz.Free and cats.free.Free is done via the following:

val f1: scalaz.Free[F, A] = ???
val f2: cats.free.Free[F, A] = f1.asCats
val f3: scalaz.Free[F, A] = f2.asScalaz
Cats Direction Scalaz
cats.Eval 👈👉 scalaz.Free.Trampoline
cats.Eval 👈 scalaz.Name
cats.Eval 👈 scalaz.Need
cats.Eval 👈 scalaz.Value
cats.arrow.FunctionK 👈👉 scalaz.~>
cats.data.Cokleisli 👈👉 scalaz.Cokleisli
cats.data.Const 👈👉 scalaz.Const
cats.data.EitherK 👈👉 scalaz.Coproduct
cats.data.EitherT 👈👉 scalaz.EitherT
cats.data.IndexedStateT 👈👉 scalaz.IndexedStateT
cats.data.Ior 👈👉 scalaz.\&/
cats.data.Kleisli 👈👉 scalaz.Kleisli
cats.data.NonEmptyList 👈👉 scalaz.NonEmptyList
cats.data.OneAnd 👈👉 scalaz.OneAnd
cats.data.OptionT 👈👉 scalaz.OptionT
cats.data.OptionT 👈 scalaz.MaybeT
cats.data.RWST 👈👉 scalaz.RWST
cats.data.Validated 👈👉 scalaz.Validation
cats.data.ValidatedNel 👈👉 scalaz.ValidationNel
cats.data.WriterT 👈👉 scalaz.WriterT
cats.free.Free 👈👉 scalaz.Free
scala.Option 👈 scalaz.Maybe
scala.util.Either 👈👉 scalaz.\/

Note that the asScalaz/asCats mechanism is open and extensible. To enable support for converting some type "cats type" A to an equivalent "scalaz type" B, define an implicit instance of type shims.conversions.AsScalaz[A, B]. Similarly, for some "scalaz type" A to an equivalent "cats type" B, define an implicit instance of type shims.conversions.AsCats[A, B]. Thus, a pair of types, A and B, for which a bijection exists would have a single implicit instance extending AsScalaz[A, B] with AsCats[B, A] (though the machinery does not require this is handled with a single instance; the ambiguity resolution here is pretty straightforward).

Wherever extra constraints are required (e.g. the various StateT conversions require a Monad[F]), the converters require the cats variant of the constraint. This should be invisible under normal circumstances since shims itself will materialize the other variant if one is available.

Nesting

At present, the asScalaz/asCats mechanism does not recursively convert nested structures. This situation most commonly occurs with monad transformer stacks. For example:

val stuff: EitherT[OptionT[Foo, *], Errs, Int] = ???

stuff.asCats

The type of the final line is cats.data.EitherT[scalaz.OptionT[Foo, *], Errs, Int], whereas you might expect that it would be cats.data.EitherT[cats.data.OptionT[Foo, *], Errs, Int]. It is technically possible to apply conversions in depth, though it require some extra functor constraints in places. The primary reason why this isn't done (now) is compile time performance, which would be adversely affected by the non-trivial inductive solution space.

It shouldn't be too much of a hindrance in any case, since the typeclass instances for the nested type will be materialized for both scalaz and cats, and so it doesn't matter as much exactly which nominal structure is in use. It would really only matter if you had a function which explicitly expected one thing or another.

The only exception to this rule is ValidationNel in scalaz and ValidatedNel in cats. Converting this composite type is a very common use case, and thus an specialized converter is defined:

val v: ValidationNel[Errs, Int] = ???

v.asCats   // => v2: ValidatedNel[Errs, Int]

Note that the scalaz.NonEmptyList within the Validation was converted to a cats.data.NonEmptyList within the resulting Validated.

In other words, under normal circumstances you will need to manually map nested structures in order to deeply convert them, but ValidationNel/ValidatedNel will Just Work™ without any explicit induction.

Contributors

None of this would have been possible without some really invaluable assistance: