Is there a zipWith analogue for tuples?

Question

Preliminary note: this is a respin of a deleted question by SeanD.

Just like there is zipWith for lists...

GHCi> zipWith (+) [1,2] [3,4]
[4,6]

... it feels like there should be something analogous for tuples, in the spirit of...

tupleZipWith (+) (1,2) (3,4)

... but there doesn't seem to be anything obviously like that in base. Which options do I have?

Answer 1

One option is using the tuples-homogenous-h98 package, which provides newtype wrappers for homogeneous tuples that have appropriate Applicative instances:

GHCi> import Data.Tuple.Homogenous
GHCi> import Control.Applicative
GHCi> liftA2 (+) (Tuple2 (1,2)) (Tuple2 (3,4))
Tuple2 {untuple2 = (4,6)}
GHCi> (>) <$> Tuple3 (7,4,7) <*> Tuple3 (6,6,6)
Tuple3 {untuple3 = (True,False,True)}

If you have a favourite homogenous tuple/fixed-size vector/fixed-size list library other than tuples-homogenous-h98, odds are that it will also have suitable ZipList-like Applicative instances.

---

For a slightly different take on the matter when it comes to pairs, you might want to consider Data.Biapplicative from bifunctors:

GHCi> import Data.Biapplicative
GHCi> bimap (+) (+) (1,2) <<*>> (3,4)
(4,6)

One nice thing about this approach is that it can handle heterogeneous pairs:

GHCi> bimap (+) (+) (1,2.5) <<*>> (3,4)
(4,6.5)
GHCi> bimap (+) (++) (1,"foo") <<*>> (3,"bar")
(4,"foobar")

Answer 2

Using GHC Generics, we can define operations that only depend on the structure of a type (the number of constructor and their arities).

We want a function zipWithP that takes a function f and zips two tuples applying f between matching fields. Perhaps something with a signature matching this:

zipWithP
  :: forall c s. _
  => (forall s. c s => s -> s -> s) -> a -> a -> a

Here f :: forall s. c s => s -> s -> s is polymorphic, allowing the tuple to be heterogeneous, as long as the fields are all instances of c. That requirement will be captured by the _ constraint, which is up to the implementation, as long as it works.

There are libraries that capture common constructions, notably one-liner and generics-sop.

In increasing order of automation...

---

The classical solution is to use the GHC.Generics module. A Generic instance represents an isomorphism between a user-defined type a and an "generic representation" Rep a associated with it.

This generic representation is constructed from a fixed set of types defined in GHC.Generics. (The documentation of the module has more details about that representation.)

The standard steps are:

1. define functions on that fixed set of types (possibly a subset of it);

2. adapt them to user-defined types by using the isomorphism given by a Generic instance.

Step 1 is typically a type class. Here GZipWith is the class of generic representations that can be zipped. The type constructors handled here are, in decreasing order of importance:

• K1 represents fields (just apply f);
• (:*:) represents type products (zip the operands separately);
• the M1 newtype carries information at the type-level, that we aren't using here so we just wrap/unwrap with it;
• U1 represents nullary constructors, mostly for completeness.

Step 2 defines zipWithP by composing gZipWith with from/to where appropriate.

{-# LANGUAGE AllowAmbiguousTypes #-}
{-# LANGUAGE ConstraintKinds #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE TypeApplications #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE UndecidableInstances #-}

import GHC.Generics

class GZipWith c f where
  gZipWith :: (forall s. c s => s -> s -> s) -> f p -> f p -> f p

instance c a => GZipWith c (K1 _i a) where
  gZipWith f (K1 a) (K1 b) = K1 (f a b)

instance (GZipWith c f, GZipWith c g) => GZipWith c (f :*: g) where
  gZipWith f (a1 :*: a2) (b1 :*: b2) = gZipWith @c f a1 b1 :*: gZipWith @c f a2 b2

instance GZipWith c f => GZipWith c (M1 _i _c f) where
  gZipWith f (M1 a) (M1 b) = M1 (gZipWith @c f a b)

instance GZipWith c U1 where
  gZipWith _ _ _ = U1

zipWithP
  :: forall c a. (Generic a, GZipWith c (Rep a))
  => (forall s. c s => s -> s -> s) -> a -> a -> a
zipWithP f a b = to (gZipWith @c f (from a) (from b))

main = do
  print (zipWithP @Num (+) (1,2) (3,4) :: (Int, Integer))

---

generics-sop provides high-level combinators to program generically with operations that feel like fmap/traverse/zip...

In this case, the relevant combinator is hcliftA2, which zips generic heterogeneous tuples of fields with a binary function. More explanations after the code.

{-# LANGUAGE AllowAmbiguousTypes #-}
{-# LANGUAGE ConstraintKinds #-}
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE TypeApplications #-}
{-# LANGUAGE TypeFamilies #-}

import Control.Applicative (liftA2)
import Data.Proxy (Proxy(..))
import Generics.SOP

zipWithP
  :: forall c a k
  .  (Generic a, Code a ~ '[k], All c k)
  => (forall s. c s => s -> s -> s) -> a -> a -> a
zipWithP f x y =
  case (from x, from y) of
    (SOP (Z u), SOP (Z v)) ->
      to (SOP (Z (hcliftA2 (Proxy :: Proxy c) (liftA2 f) u v)))

main = do
  print (zipWithP @Num (+) (1,2) (3,4) :: (Int, Integer))

Starting from the top of zipWithP.

Constraints:

• Code a ~ '[k]: a must be a single-constructor type (Code a :: [[*]] is the list of constructors of a, each given as the list of its fields).
• All c k: all fields of the constructor k satisfy the constraint c.

Body:

• from maps from regular type a to a generic Sum Of Products (SOP I (Code a)).
• We assumed that the type a has a single constructor. We apply that knowledge by pattern-matching to get rid of the "sum" layer. We get u and v, whose types are products (NP I k).
• We apply hcliftA2 to zip the two tuples u and v.
• Fields are wrapped in a type constructor I/Identity (functor-functor or HKD style), hence there is also a liftA2 layer on top of f.
• We get a new tuple, and go backwards from the first two steps, by applying constructors and to (the inverse of from).

See the generics-sop documentation for more details.

---

zipWithP belongs to a class of operations that are commonly described by "do this for each field". one-liner exports operations, some of whose names may look familiar (map..., traverse...), that are essentially specializations of a single "generalized traversal" associated with any generic type.

In particular, zipWithP is called binaryOp.

{-# LANGUAGE TypeApplications #-}

import Generics.OneLiner

main = print (binaryOp @Num (+) (1,2) (3,4) :: (Int, Integer))