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Derivation
In order to derive the type signatures used in this package and to motivate generalizing these combinators to work on a much wider menagerie of types, we'll take a bit of an excursion through other types and typeclasses you may already be familiar with.
From here, we'll assume that you are acquainted with the types for Functor
, Foldable
and Traversable
and can at least hand-wave the laws for them (see Typeclassopedia).
There is a common folklore pattern for composing (.)
in Haskell, to compose with a function that takes more and more arguments (see this gist if it isn't obvious).
(.) :: (a -> b) -> (c -> a) -> c -> b
(.).(.) :: (a -> b) -> (d -> c -> a) -> d -> c -> b
(.).(.).(.) :: (a -> b) -> (e -> d -> c -> a) -> e -> d -> c -> b
It generalizes to fmap
from Functor
:
fmap :: Functor f
=> (a -> b) -> f a -> f b
fmap.fmap :: (Functor f, Functor g)
=> (a -> b) -> g (f a) -> g (f b)
fmap.fmap.fmap :: (Functor f, Functor g, Functor h)
=> (a -> b) -> h (g (f a)) -> h (g (f b))
It also generalizes to foldMap
from Foldable
:
foldMap :: (Foldable f, Monoid m)
=> (a -> m) -> f a -> m
foldMap.foldMap :: (Foldable f, Foldable g, Monoid m)
=> (a -> m) -> g (f a) -> m
foldMap.foldMap.foldMap :: (Foldable f, Foldable g, Foldable h, Monoid m)
=> (a -> m) -> h (g (f a)) -> m
And finally (for now) it generalizes to traverse
from Traversable
:
traverse :: (Traversable f, Applicative m)
=> (a -> m b) -> f a -> m (f b)
traverse.traverse :: (Traversable f, Traversable g, Applicative m)
=> (a -> m b) -> g (f a) -> m (g (f b))
traverse.traverse.traverse :: (Traversable f, Traversable g, Traversable h, Applicative m)
=> (a -> m b) -> h (g (f a)) -> m (h (g (f b)))
These functions are similar, but slightly different in signature, and provide very different capabilities.
We gain power as we upgrade from Functor
or Foldable
to Traversable
, as evidenced by the fact that we can define fmap
and foldMap
given traverse
. This is done for us directly by Data.Traversable
, as follows:
-- | This function may be used as a value for `fmap` in a `Functor`
-- instance, provided that 'traverse' is defined. (Using
-- `fmapDefault` with a `Traversable` instance defined only by
-- 'sequenceA' will result in infinite recursion.)
fmapDefault :: Traversable t => (a -> b) -> t a -> t b
fmapDefault f = runIdentity . traverse (Identity . f)
-- | This function may be used as a value for `Data.Foldable.foldMap`
-- in a `Foldable` instance.
foldMapDefault :: (Traversable t, Monoid m) => (a -> m) -> t a -> m
foldMapDefault f = getConst . traverse (Const . f)
If we rip traverse
out of their definitions and pass it in as an argument, we can find out exactly what
properties are needed of traverse
to make those definitions typecheck. We'll deal with fmapDefault
first.
ghci> let over l f = runIdentity . l (Identity . f)
ghci> :t over
over :: ((a -> Identity b) -> s -> Identity t) -> (a -> b) -> s -> t
So lets define a type alias for that:
type Setter s t a b = (a -> Identity b) -> s -> Identity t
which lets us write this as:
over :: Setter s t a b -> (a -> b) -> s -> t
-- or
over :: ((a -> Identity b) -> s -> Identity t)
-> (a -> b) -> s -> t
over l f = runIdentity . l (Identity . f)
Setter Laws
We can write an inverse of over
fairly mechanically:
sets :: ((a -> b) -> s -> t) -> Setter s t a b
-- or
sets :: ((a -> b) -> s -> t)
-> (a -> Identity b) -> s -> Identity t
sets l f = Identity . l (runIdentity . f)
It is trivial to verify that
sets . over = id
over . sets = id
but if we want the Setter
to act like a Functor
, the argument the user supplies to sets
should satisfy a version of the Functor
laws. In particular, we'd like:
over l id = id
over l f . over l g = over l (f . g)
so the function m
you supply to sets
must satisfy
m id = id
m f . m g = m (f . g)
(Note: Unlike with fmap
we have to actually check both laws, because parametricity doesn't help
us derive the second for free from the first.)
So, what satisfies the functor laws out of the box? fmap
!
mapped :: Functor f => Setter (f a) (f b) a b
-- or
mapped :: Functor f => (a -> Identity b) -> f a -> Identity (f b)
mapped = sets fmap
It is trivial then to check that
fmap = over mapped
Now we can write a number of combinators that are parameterized on the Functor
-like construction they work over.
Lets consider the limited form of mapping allowed on the arrays provided by Data.Array.IArray
:
amap :: (IArray a e', IArray a e, Ix i) => (e' -> e) -> a i e' -> a i e
Given this, we can derive:
amapped :: (IArray a c, IArray a d, Ix i) => Setter (a i c) (a i d) c d
-- or
amapped :: (IArray a c, IArray a d, Ix i)
=> (c -> Identity d) -> a i c -> Identity (a i d)
amapped = sets amap
Then we can use
over amapped :: (IArray a c, IArray a d, Ix i) => (c -> d) -> a i c -> a i d
instead of amap
.
We can also pass in the type of map
provided by, say, Data.Text.map
tmapped :: Setter Text Text Char Char
-- or
tmapped :: (Char -> Identity Char) -> Text -> Identity Text
tmapped = sets Data.Text.map
And it follows that:
over tmapped :: (Char -> Char) -> Text -> Text
We haven't gained much power over just passing in the functions amap
or Data.Text.map
directly, yet, but we have gained two things:
-
The composition of two setters, such as:
mapped.mapped :: (Functor f, Functor g) => (a -> Identity b) -> f (g a) -> Identity (f (g b))
is still a valid
Setter
!mapped.mapped :: (Functor f, Functor g) => Setter (f (g a)) (f (g b)) a b
So you can use
over (mapped.mapped)
to recover the originalfmap.fmap
above. This lets you get away without usingCompose
to manually bolt functors to meet the shape requirements. -
Another thing that we have won is that if we have a
Traversable
container, we can pass itstraverse
in toover
instead of aSetter
for the container.
Setters form a category, using (.)
and id
for composition and identity, but you can use the existing (.)
and id
from the Prelude
for them (though they compose backwards).
However, to gain that power we traded in other functionality. Knowing f
is a Functor
lets us instantiate the type arguments a
and b
to anything we want, over and over again, we also need to manually check any of the formerly free theorems we want to use with our Setter
.
Many combinators for these are provided in Control.Lens.Setter
.
As an aside, we can now define the (.~)
(and set
) combinators we used during the introduction:
(.~), set :: Setter s t a b -> b -> s -> t
l .~ d = runIdentity . l (Identity . const d)
set = (.~)
In a few moments we'll see how they can be applied to a Lens
, but first:
Now lets apply the same treatment to the other default definition supplied by Data.Traversable
:
foldMapDefault :: (Traversable t, Monoid m) => (a -> m) -> t a -> m
foldMapDefault f = getConst . traverse (Const . f)
If we plug in an argument for traverse
and rip off the type signature, we get
ghci> let foldMapOf l f = getConst . l (Const . f)
ghci> :t foldMapOf
foldMapOf :: ((a -> Const r b) -> s -> Const r t) -> (a -> r) -> s -> r
The second argument to Const
is polymorphic in each case, but to avoid dangling type variables we'll eliminate them by making them match.
Writing it out, and making up a type alias:
type Getting r s a = (a -> Const r a) -> s -> Const r s
we can make the slightly nicer looking type
foldMapOf :: Getting r s a -> (a -> r) -> s -> r
-- or
foldMapOf :: ((a -> Const r a) -> s -> Const r s)
-> (a -> r) -> s -> r
foldMapOf l f = getConst . l (Const . f)
It follows by substitution that
foldMapDefault = foldMapOf traverse
we could define an inverse of foldMapOf
as we did with over
, above, etc.
folds :: ((a -> r) -> s -> r) -> Getting r s a
-- or
folds :: ((a -> r) -> s -> r)
-> (a -> Const r a) -> s -> Const r s
folds l f = Const . l (getConst . f)
If follows very easily that
folds . foldMapOf = id
foldMapOf . folds = id
and so we can see that we can pass something other than traverse
to foldMapOf
:
type Fold s t a b = forall m. Monoid m => (a -> Const m b) -> s -> Const m t
folded :: Foldable f => Fold (f a) (f a) a a
-- or
folded :: (Foldable f, Monoid m) => (a -> Const m a) -> f a -> Const m (f a)
folded = folds foldMap
And we can mechanically verify that foldMap = foldMapOf folded
by:
foldMap = (foldMapOf . folds) foldMap = foldMapOf (folds foldMap) = foldMapOf folded
There are no laws for Foldable
that do not follow directly from the types, and the same
holds for a Fold
.
We can define all of the combinators in Data.Foldable
in terms of foldMap
, so we in turn
define them in terms of an arbitrary Fold
in Control.Lens.Fold
.
(In the actual implementation the type of Fold
is changed to use a typeclass constraint rather
than an explicit Const m
to yield nicer error messages when you attempt to use a Setter
as
a Fold
and to permit the use of certain Applicative
transformers as Monoid
transformers.)
As with Setter
, the composition of two folds using (.)
is a valid Fold
, and id
is the identity fold that returns the container itself as its only result.
Given the signatures of Fold
and Setter
, we can derive something that can be used as both -- after all
traverse
from Traversal
served this function originally!
Given the Monoid
m, Const m
forms an Applicative
, and Identity
is also Applicative
.
So substituting back in to the definitions above, we find:
type SimpleTraversal s a = forall f. Applicative f => (a -> f a) -> s -> f s
But this is weaker than what we started with, since
traverse :: (Traversable t, Applicative f) => (a -> f b) -> t a -> f (t b)
Picking
type Traversal s t a b = forall f. Applicative f => (a -> f b) -> s -> f t
we get something that subsumes
traverse :: Traversable t => Traversal (t a) (t b) a b
-- or
traverse :: (Traversable t, Applicative f) => (a -> f b) -> t a -> f (t b)
We'll still be dealing with those 2-argument traversals a lot, along with their Setter
equivalents, so we'll define
type Simple f a b = f a a b b
(Note: 'Simple' 'Traversal' partially applies a type synonym. This is only legal with the LiberalTypeSynonyms
extension turned on, but
GHC allows it so long as the type synonym contains a higher-rank type, even without LiberalTypeSynonyms
.)
But, what happened?
When I picked the type for Getting
, I only used two type arguments.
type Getting r s a = (a -> Const r a) -> s -> Const r s
This hints that for something to be a valid Traversal
it should be possible to choose s ~ t
, and a ~ b
and get a meaningful traversal. In fact the Traversable
laws, which we still want to have hold for a Traversal
, tell us that:
l pure = pure
Compose . fmap (l f) . l g = l (Compose . fmap f . g)
And the first of those laws requires s ~ t
, a ~ b
to be a possible choice of the type arguments to your Traversal
. We implement this polymorphic overloading of traversals in a fairly ad hoc way, by just making the user provide the "family structure" for us.
Given that our Traversal
satisfies the Traversable
laws, the laws for Setter
immediately follow, and Fold
had no extra laws to check.
So what else can we build a Traversal
for?
We can traverse both elements in a tuple:
both :: Traversal (a,a) (b,b) a b
-- or
both :: Applicative f => (a -> f b) -> (a,a) -> f (b,b)
both f (a,b) = (,) <$> f a <*> f b
The left side of an Either
:
traverseLeft :: Traversal (Either a c) (Either b c) a b
-- or
traverseLeft :: Applicative f => (a -> f b) -> Either a c -> f (Either b c)
traverseLeft f (Left a) = Left <$> f a
traverseLeft f (Right b) = pure $ Right b
And we can use a Traversal
to update element (if it exists) at a given position in a Map
, etc.
We can compose two traversals with each other using (.)
as we did at the very start, but now the composition forms a valid Traversal
.
traverse.traverse :: (Traversable f, Traversable g) => Traversal (f (g a)) (f (g b)) a b
but we can also compose them with a Setter
or Fold
, yielding a Setter
or Fold
in turn.
Unlike with mapped and folded, we will often want to use the Traversal
directly as a combinator.
Moreover, all the intuition you have for how to write Traversable
instances transfers immediately to how to write a Traversal
.
There are a number of combinators for working with traversals in Control.Lens.Traversal
We're almost ready for lenses, but first we have one more diversion.
If we convert a function from (a -> c)
to continuation passing style, we get
cps :: (a -> c) -> (c -> r) -> a -> r
cps f g = g . f
That is to say, rather than return a result c
, it takes a function from (c -> r)
and calls it with the answer instead.
If we have a CPS'd function that is polymorphic in its return type, we can get the original function back out:
uncps :: (forall r. (c -> r) -> a -> r) -> a -> c
uncps f = f id
Finally, we can prove a number of properties:
uncps . cps = id
cps . uncps = id
cps id = id
cps f . cps g = cps (g . f)
Now, we can relax the type of uncps slightly to
uncps' :: ((c -> c) -> a -> c) -> a -> c
uncps' f = f id
but now we no longer know that our function f :: (c -> c) -> a -> c
can't be doing something
to combine the results of the function you pass it. We lose the cps . uncps = id
law and only have:
uncps' . cps = id
Now, let's compose them like we did for fmap
, traverse
and foldMap
at the start:
If we start with 3 functions:
f :: A -> B
g :: B -> C
h :: C -> D
Then
cps f :: (B -> r) -> (A -> r)
cps g :: (C -> r) -> (B -> r)
cps h :: (D -> r) -> (C -> r)
And when we compose these functions between functions, we obtain:
cps f :: (B -> r) -> (A -> r)
cps f . cps g :: (C -> r) -> (A -> r)
cps f . cps g . cps h :: (D -> r) -> (A -> r)
Earlier we provided a type for consuming a Fold
:
type Getting r s a = (a -> Const r a) -> s -> Const r s
What we want (so that uncps can work) is something completely polymorphic in r
.
type Getter s a = forall r. (a -> Const r a) -> s -> Const r s
Along the way, we get an interesting result: a Getter
is just a Fold
that doesn't use the Monoid
! Recall:
type Fold s a = forall r. Monoid r => (a -> Const r a) -> s -> Const r s
We can go back and define (^.)
now, and empower it to consume either a Fold
or Getter
or Traversal
.
(^.) :: s -> Getting a s a -> a
s ^. l = getConst (l Const s)
Remember, we can consume a Traversal
because every Traversal
is a valid Fold
, just like every Getter
is a valid Fold
.
Also note that (^.)
doesn't require anything of a
!
When it gets applied, the argument l
will demand the properties of a
that it needs:
For instance when we apply (^.)
to a Fold
, it will demand a Monoid
instance for a
:
(^.folded) :: (Foldable f, Monoid m) => f m -> m
Also, since, a Monoid m
is needed to satisfy the Applicative
for Const m
,
(^.traverse) :: (Traversable t, Monoid m) => t m -> m
But we can use (^.)
to access a Getter
, without any restrictions!
There are a number of combinators for working with getters in Control.Lens.Getter
.
We can use a Getter
as a Fold
, but it is not a valid Traversal
or Setter
, nor is a Traversal
or Setter
a Getter
.
With all of that we're finally ready to define
A Lens
is a Traversal
that can also be used as a Getter
. This means it can be used as a Setter
and a Fold
as well.
Recall that a Getter was a Fold
that can't use the Monoid
.
Without the Monoid
, all that Const
and Identity
have in common is that each is a Functor
.
type Lens s t a b = forall f. Functor f => (a -> f b) -> s -> f t
We inherit the Traversal
laws, so we know for a Lens
l
l pure = pure
Compose . fmap (l f) . l g = l (Compose . fmap f . g)
and we also know that a Lens s t a b
can be used as a function from (s -> a)
.