45

I'm trying to achieve a deeper understanding of lens library, so I play around with the types it offers. I have already had some experience with lenses, and know how powerful and convenient they are. So I moved on to Prisms, and I'm a bit lost. It seems that prisms allow two things:

  1. Determining if an entity belongs to a particular branch of a sum type, and if it does, capturing the underlying data in a tuple or a singleton.
  2. Destructuring and reconstructing an entity, possibly modifying it in process.

The first point seems useful, but usually one doesn't need all the data from an entity, and ^? with plain lenses allows getting Nothing if the field in question doesn't belong to the branch the entity represents, just like it does with prisms.

The second point... I don't know, might have uses?

So the question is: what can I do with a Prism that I can't with other optics?

Edit: thank you everyone for excellent answers and links for further reading! I wish I could accept them all.

1
  • I went ahead and edited the title of your question. Hope you don’t mind! Jun 19, 2018 at 10:51

3 Answers 3

45

Lenses characterise the has-a relationship; Prisms characterise the is-a relationship.

A Lens s a says "s has an a"; it has methods to get exactly one a from an s and to overwrite exactly one a in an s. A Prism s a says "a is an s"; it has methods to upcast an a to an s and to (attempt to) downcast an s to an a.

Putting that intuition into code gives you the familiar "get-set" (or "costate comonad coalgebra") formulation of lenses,

data Lens s a = Lens {
    get :: s -> a,
    set :: a -> s -> s
}

and an "upcast-downcast" representation of prisms,

data Prism s a = Prism {
    up :: a -> s,
    down :: s -> Maybe a
}

up injects an a into s (without adding any information), and down tests whether the s is an a.

In lens, up is spelled review and down is preview. There’s no Prism constructor; you use the prism' smart constructor.


What can you do with a Prism? Inject and project sum types!

_Left :: Prism (Either a b) a
_Left = Prism {
    up = Left,
    down = either Just (const Nothing)
}
_Right :: Prism (Either a b) b
_Right = Prism {
    up = Right,
    down = either (const Nothing) Just
}

Lenses don't support this - you can't write a Lens (Either a b) a because you can't implement get :: Either a b -> a. As a practical matter, you can write a Traversal (Either a b) a, but that doesn't allow you to create an Either a b from an a - it'll only let you overwrite an a which is already there.

Aside: I think this subtle point about Traversals is the source of your confusion about partial record fields.

^? with plain lenses allows getting Nothing if the field in question doesn't belong to the branch the entity represents

Using ^? with a real Lens will never return Nothing, because a Lens s a identifies exactly one a inside an s. When confronted with a partial record field,

data Wibble = Wobble { _wobble :: Int } | Wubble { _wubble :: Bool }

makeLenses will generate a Traversal, not a Lens.

wobble :: Traversal' Wibble Int
wubble :: Traversal' Wibble Bool

For an example of this how Prisms can be applied in practice, look to Control.Exception.Lens, which provides a collection of Prisms into Haskell's extensible Exception hierarchy. This lets you perform runtime type tests on SomeExceptions and inject specific exceptions into SomeException.

_ArithException :: Prism' SomeException ArithException
_AsyncException :: Prism' SomeException AsyncException
-- etc.

(These are slightly simplified versions of the actual types. In reality these prisms are overloaded class methods.)

Thinking at a higher level, certain whole programs can be thought of as being "basically a Prism". Encoding and decoding data is one example: you can always convert structured data to a String, but not every String can be parsed back:

showRead :: (Show a, Read a) => Prism String a
showRead = Prism {
    up = show,
    down = listToMaybe . fmap fst . reads
}

To summarise, Lenses and Prisms together encode the two core design tools of object-oriented programming: composition and subtyping. Lenses are a first-class version of Java's . and = operators, and Prisms are a first-class version of Java's instanceof and implicit upcasting.


One fruitful way of thinking about Lenses is that they give you a way of splitting up a composite s into a focused value a and some context c. Pseudocode:

type Lens s a = exists c. s <-> (a, c)

In this framework, a Prism gives you a way to look at an s as being either an a or some context c.

type Prism s a = exists c. s <-> Either a c

(I'll leave it to you to convince yourself that these are isomorphic to the simple representations I demonstrated above. Try implementing get/set/up/down for these types!)

In this sense a Prism is a co-Lens. Either is the categorical dual of (,); Prism is the categorical dual of Lens.

You can also observe this duality in the "profunctor optics" formulation - Strong and Choice are dual.

type Lens  s t a b = forall p. Strong p => p a b -> p s t
type Prism s t a b = forall p. Choice p => p a b -> p s t

This is more or less the representation which lens uses, because these Lenses and Prisms are very composable. You can compose Prisms to get bigger Prisms ("a is an s, which is a p") using (.); composing a Prism with a Lens gives you a Traversal.

1
  • That first line alone cleared up so much confusion. Thanks.
    – cobbal
    Dec 12, 2022 at 15:35
18

I just wrote a blog post, which might help build some intuition about Prisms: Prisms are constructors (Lenses are fields). http://oleg.fi/gists/posts/2018-06-19-prisms-are-constructors.html


Prisms could be introduced as first-class pattern matching, but that is a one-sided view. I'd say they are generalised constructors, though maybe more often used for pattern matching than for actual construction.

The important property of constructors (and lawful prisms), is their injectivity. Though the usual prism laws don't state that directly, injectivity property can be deduced.

To quote lens-library documentation, the prisms laws are:

First, if I review a value with a Prism and then preview, I will get it back:

preview l (review l b) ≡ Just b

Second, if you can extract a value a using a Prism l from a value s, then the value s is completely described by l and a:

preview l s ≡ Just a ⇒ review l a ≡ s

In fact, the first law alone is enough to prove the injectivity of construction via Prism:

review l x ≡ review l y ⇒ x ≡ y

The proof is straight-forward:

review l x ≡ review l y
  -- x ≡ y -> f x ≡ f y
preview l (review l x) ≡ preview l (review l y)
  -- rewrite both sides with the first law
Just x ≡ Just y
  -- injectivity of Just
x ≡ y

We can use injectivity property as an additional tool in the equational reasoning toolbox. Or we can use it as a easy property to check to decide whether something is a lawful Prism. The check is easy as we only the review side of Prism. Many smart constructors, which for example normalise the input data, aren't lawful prisms.

An example using case-insensitive:

-- Bad!
_CI :: FoldCase s => Prism' (CI s) s
_CI = prism' ci (Just . foldedCase)

λ> review _CI "FOO" == review _CI "foo"
True

λ> "FOO" == "foo"
False

The first law is also violated:

λ> preview _CI (review _CI "FOO")
Just "foo"
2
  • Very nice. So far if I understand correctly we've just shown that the review operation of every lawful prism is an injection. Can we also go the other way and show that every injection induces a lawful prism? Apr 25, 2021 at 18:34
  • @AsadSaeeduddin not every injection induces a prism. We need so called "decidable embedding (injection)". In fact these are equivalent: the decidability requirement is essentially asking to give the preview / match part of the prism. A non-haskell example is an injection into Type. A Haskell example of non-decidable injection could be forward :: (Integer -> Natural) -> (Integer -> Integer); forward f = toInteger . f. Given a g :: Integer -> Integer, you need to test for all n :: Integer that g n is non-negative. That is not computable.
    – phadej
    May 7, 2021 at 13:24
11

In addition to the other excellent answers, I feel Isos provide a nice vantage point for considering this matter.

  • There being some i :: Iso' s a means if you have an s value you also (virtually) have an a value, and vice versa. The Iso' gives you two conversion functions, view i :: s -> a and review i :: a -> s which are both guaranteed to succeed and lossless.

  • There being some l :: Lens' s a means if you have an s you also have an a, but not vice versa. view l :: s -> a may drop information along the way, as the conversion isn't required to be lossless, and so you can't go the other way if all you have is an a (cf. set l :: a -> s -> s, which also requires an s in addition to the a value in order to provide the missing information).

  • There being some p :: Prism' s a means if you have an s value you might also have an a, but there are no guarantees. The conversion preview p :: s -> Maybe a is not guaranteed to succeed. Still, you do have the other direction, review p :: a -> s.

In other words, an Iso is invertible and always succeeds. If you drop the invertibility requirement, you get a Lens; if you drop the success guarantee, you get a Prism. If you drop both, you get an affine traversal (which is not in lens as a separate type), and if you go a step further and give up on having at most one target you end up with a Traversal. That is reflected in one of the diamonds of the lens subtype hierarchy:

 Traversal
    / \
   /   \
  /     \
Lens   Prism
  \     /
   \   /
    \ /
    Iso

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