Copyright | (C) 2012-16 Edward Kmett |
---|---|
License | BSD-style (see the file LICENSE) |
Maintainer | Edward Kmett <ekmett@gmail.com> |
Stability | provisional |
Portability | Rank2Types |
Safe Haskell | Trustworthy |
Language | Haskell98 |
- type Iso s t a b = forall p f. (Profunctor p, Functor f) => p a (f b) -> p s (f t)
- type Iso' s a = Iso s s a a
- type AnIso s t a b = Exchange a b a (Identity b) -> Exchange a b s (Identity t)
- type AnIso' s a = AnIso s s a a
- iso :: (s -> a) -> (b -> t) -> Iso s t a b
- from :: AnIso s t a b -> Iso b a t s
- cloneIso :: AnIso s t a b -> Iso s t a b
- withIso :: AnIso s t a b -> ((s -> a) -> (b -> t) -> r) -> r
- au :: Functor f => AnIso s t a b -> ((b -> t) -> f s) -> f a
- auf :: Optic (Costar f) g s t a b -> (f a -> g b) -> f s -> g t
- under :: AnIso s t a b -> (t -> s) -> b -> a
- mapping :: (Functor f, Functor g) => AnIso s t a b -> Iso (f s) (g t) (f a) (g b)
- simple :: Equality' a a
- non :: Eq a => a -> Iso' (Maybe a) a
- non' :: APrism' a () -> Iso' (Maybe a) a
- anon :: a -> (a -> Bool) -> Iso' (Maybe a) a
- enum :: Enum a => Iso' Int a
- curried :: Iso ((a, b) -> c) ((d, e) -> f) (a -> b -> c) (d -> e -> f)
- uncurried :: Iso (a -> b -> c) (d -> e -> f) ((a, b) -> c) ((d, e) -> f)
- flipped :: Iso (a -> b -> c) (a' -> b' -> c') (b -> a -> c) (b' -> a' -> c')
- class Bifunctor p => Swapped p where
- pattern Swapped :: forall p c d. Swapped p => p d c -> p c d
- class Strict lazy strict | lazy -> strict, strict -> lazy where
- pattern Strict :: forall s t. Strict s t => t -> s
- pattern Lazy :: forall s t. Strict t s => t -> s
- lazy :: Strict lazy strict => Iso' strict lazy
- class Reversing t where
- reversed :: Reversing a => Iso' a a
- pattern Reversed :: forall t. Reversing t => t -> t
- involuted :: (a -> a) -> Iso' a a
- pattern List :: forall l. IsList l => [Item l] -> l
- magma :: LensLike (Mafic a b) s t a b -> Iso s u (Magma Int t b a) (Magma j u c c)
- imagma :: Over (Indexed i) (Molten i a b) s t a b -> Iso s t' (Magma i t b a) (Magma j t' c c)
- data Magma i t b a
- contramapping :: Contravariant f => AnIso s t a b -> Iso (f a) (f b) (f s) (f t)
- class Profunctor p where
- dimapping :: (Profunctor p, Profunctor q) => AnIso s t a b -> AnIso s' t' a' b' -> Iso (p a s') (q b t') (p s a') (q t b')
- lmapping :: (Profunctor p, Profunctor q) => AnIso s t a b -> Iso (p a x) (q b y) (p s x) (q t y)
- rmapping :: (Profunctor p, Profunctor q) => AnIso s t a b -> Iso (p x s) (q y t) (p x a) (q y b)
- bimapping :: (Bifunctor f, Bifunctor g) => AnIso s t a b -> AnIso s' t' a' b' -> Iso (f s s') (g t t') (f a a') (g b b')
- firsting :: (Bifunctor f, Bifunctor g) => AnIso s t a b -> Iso (f s x) (g t y) (f a x) (g b y)
- seconding :: (Bifunctor f, Bifunctor g) => AnIso s t a b -> Iso (f x s) (g y t) (f x a) (g y b)
- coerced :: forall s t a b. (Coercible s a, Coercible t b) => Iso s t a b
Isomorphism Lenses
type Iso s t a b = forall p f. (Profunctor p, Functor f) => p a (f b) -> p s (f t) Source #
type AnIso s t a b = Exchange a b a (Identity b) -> Exchange a b s (Identity t) Source #
When you see this as an argument to a function, it expects an Iso
.
Isomorphism Construction
Consuming Isomorphisms
cloneIso :: AnIso s t a b -> Iso s t a b Source #
Convert from AnIso
back to any Iso
.
This is useful when you need to store an isomorphism as a data type inside a container and later reconstitute it as an overloaded function.
See cloneLens
or cloneTraversal
for more information on why you might want to do this.
withIso :: AnIso s t a b -> ((s -> a) -> (b -> t) -> r) -> r Source #
Extract the two functions, one from s -> a
and
one from b -> t
that characterize an Iso
.
Working with isomorphisms
auf :: Optic (Costar f) g s t a b -> (f a -> g b) -> f s -> g t Source #
Based on ala'
from Conor McBride's work on Epigram.
This version is generalized to accept any Iso
, not just a newtype
.
For a version you pass the name of the newtype
constructor to, see alaf
.
>>>
auf (_Unwrapping Sum) (foldMapOf both) Prelude.length ("hello","world")
10
Mnemonically, the German auf plays a similar role to à la, and the combinator
is au
with an extra function argument:
auf
::Iso
s t a b -> ((r -> a) -> e -> b) -> (r -> s) -> e -> t
but the signature is general.
Common Isomorphisms
non :: Eq a => a -> Iso' (Maybe a) a Source #
If v
is an element of a type a
, and a'
is a
sans the element v
, then
is an isomorphism from
non
v
to Maybe
a'a
.
non
≡non'
.
only
Keep in mind this is only a real isomorphism if you treat the domain as being
.Maybe
(a sans v)
This is practically quite useful when you want to have a Map
where all the entries should have non-zero values.
>>>
Map.fromList [("hello",1)] & at "hello" . non 0 +~ 2
fromList [("hello",3)]
>>>
Map.fromList [("hello",1)] & at "hello" . non 0 -~ 1
fromList []
>>>
Map.fromList [("hello",1)] ^. at "hello" . non 0
1
>>>
Map.fromList [] ^. at "hello" . non 0
0
This combinator is also particularly useful when working with nested maps.
e.g. When you want to create the nested Map
when it is missing:
>>>
Map.empty & at "hello" . non Map.empty . at "world" ?~ "!!!"
fromList [("hello",fromList [("world","!!!")])]
and when have deleting the last entry from the nested Map
mean that we
should delete its entry from the surrounding one:
>>>
fromList [("hello",fromList [("world","!!!")])] & at "hello" . non Map.empty . at "world" .~ Nothing
fromList []
It can also be used in reverse to exclude a given value:
>>>
non 0 # rem 10 4
Just 2
>>>
non 0 # rem 10 5
Nothing
non' :: APrism' a () -> Iso' (Maybe a) a Source #
generalizes non'
p
to take any unit non
(p # ())Prism
This function generates an isomorphism between
and Maybe
(a | isn't
p a)a
.
>>>
Map.singleton "hello" Map.empty & at "hello" . non' _Empty . at "world" ?~ "!!!"
fromList [("hello",fromList [("world","!!!")])]
>>>
fromList [("hello",fromList [("world","!!!")])] & at "hello" . non' _Empty . at "world" .~ Nothing
fromList []
anon :: a -> (a -> Bool) -> Iso' (Maybe a) a Source #
generalizes anon
a p
to take any value and a predicate.non
a
This function assumes that p a
holds
and generates an isomorphism between True
and Maybe
(a | not
(p a))a
.
>>>
Map.empty & at "hello" . anon Map.empty Map.null . at "world" ?~ "!!!"
fromList [("hello",fromList [("world","!!!")])]
>>>
fromList [("hello",fromList [("world","!!!")])] & at "hello" . anon Map.empty Map.null . at "world" .~ Nothing
fromList []
enum :: Enum a => Iso' Int a Source #
This isomorphism can be used to convert to or from an instance of Enum
.
>>>
LT^.from enum
0
>>>
97^.enum :: Char
'a'
Note: this is only an isomorphism from the numeric range actually used
and it is a bit of a pleasant fiction, since there are questionable
Enum
instances for Double
, and Float
that exist solely for
[1.0 .. 4.0]
sugar and the instances for those and Integer
don't
cover all values in their range.
flipped :: Iso (a -> b -> c) (a' -> b' -> c') (b -> a -> c) (b' -> a' -> c') Source #
The isomorphism for flipping a function.
>>>
((,)^.flipped) 1 2
(2,1)
class Strict lazy strict | lazy -> strict, strict -> lazy where Source #
Ad hoc conversion between "strict" and "lazy" versions of a structure,
such as Text
or ByteString
.
lazy :: Strict lazy strict => Iso' strict lazy Source #
An Iso
between the strict variant of a structure and its lazy
counterpart.
lazy
=from
strict
See http://hackage.haskell.org/package/strict-base-types for an example use.
class Reversing t where Source #
This class provides a generalized notion of list reversal extended to other containers.
Reversing ByteString Source # | |
Reversing ByteString Source # | |
Reversing Text Source # | |
Reversing Text Source # | |
Reversing [a] Source # | |
Reversing (NonEmpty a) Source # | |
Reversing (Seq a) Source # | |
Reversing (Vector a) Source # | |
Unbox a => Reversing (Vector a) Source # | |
Storable a => Reversing (Vector a) Source # | |
Prim a => Reversing (Vector a) Source # | |
Reversing (Deque a) Source # | |
reversed :: Reversing a => Iso' a a Source #
An Iso
between a list, ByteString
, Text
fragment, etc. and its reversal.
>>>
"live" ^. reversed
"evil"
>>>
"live" & reversed %~ ('d':)
"lived"
Uncommon Isomorphisms
imagma :: Over (Indexed i) (Molten i a b) s t a b -> Iso s t' (Magma i t b a) (Magma j t' c c) Source #
This isomorphism can be used to inspect an IndexedTraversal
to see how it associates
the structure and it can also be used to bake the IndexedTraversal
into a Magma
so
that you can traverse over it multiple times with access to the original indices.
This provides a way to peek at the internal structure of a
Traversal
or IndexedTraversal
Contravariant functors
contramapping :: Contravariant f => AnIso s t a b -> Iso (f a) (f b) (f s) (f t) Source #
Lift an Iso
into a Contravariant
functor.
contramapping ::Contravariant
f =>Iso
s t a b ->Iso
(f a) (f b) (f s) (f t) contramapping ::Contravariant
f =>Iso'
s a ->Iso'
(f a) (f s)
Profunctors
class Profunctor p where #
Formally, the class Profunctor
represents a profunctor
from Hask
-> Hask
.
Intuitively it is a bifunctor where the first argument is contravariant and the second argument is covariant.
You can define a Profunctor
by either defining dimap
or by defining both
lmap
and rmap
.
If you supply dimap
, you should ensure that:
dimap
id
id
≡id
If you supply lmap
and rmap
, ensure:
lmap
id
≡id
rmap
id
≡id
If you supply both, you should also ensure:
dimap
f g ≡lmap
f.
rmap
g
These ensure by parametricity:
dimap
(f.
g) (h.
i) ≡dimap
g h.
dimap
f ilmap
(f.
g) ≡lmap
g.
lmap
frmap
(f.
g) ≡rmap
f.
rmap
g
dimapping :: (Profunctor p, Profunctor q) => AnIso s t a b -> AnIso s' t' a' b' -> Iso (p a s') (q b t') (p s a') (q t b') Source #
Lift two Iso
s into both arguments of a Profunctor
simultaneously.
dimapping ::Profunctor
p =>Iso
s t a b ->Iso
s' t' a' b' ->Iso
(p a s') (p b t') (p s a') (p t b') dimapping ::Profunctor
p =>Iso'
s a ->Iso'
s' a' ->Iso'
(p a s') (p s a')
lmapping :: (Profunctor p, Profunctor q) => AnIso s t a b -> Iso (p a x) (q b y) (p s x) (q t y) Source #
Lift an Iso
contravariantly into the left argument of a Profunctor
.
lmapping ::Profunctor
p =>Iso
s t a b ->Iso
(p a x) (p b y) (p s x) (p t y) lmapping ::Profunctor
p =>Iso'
s a ->Iso'
(p a x) (p s x)
rmapping :: (Profunctor p, Profunctor q) => AnIso s t a b -> Iso (p x s) (q y t) (p x a) (q y b) Source #
Lift an Iso
covariantly into the right argument of a Profunctor
.
rmapping ::Profunctor
p =>Iso
s t a b ->Iso
(p x s) (p y t) (p x a) (p y b) rmapping ::Profunctor
p =>Iso'
s a ->Iso'
(p x s) (p x a)
Bifunctors
bimapping :: (Bifunctor f, Bifunctor g) => AnIso s t a b -> AnIso s' t' a' b' -> Iso (f s s') (g t t') (f a a') (g b b') Source #
firsting :: (Bifunctor f, Bifunctor g) => AnIso s t a b -> Iso (f s x) (g t y) (f a x) (g b y) Source #
seconding :: (Bifunctor f, Bifunctor g) => AnIso s t a b -> Iso (f x s) (g y t) (f x a) (g y b) Source #
Lift an Iso
into the second argument of a Bifunctor
. This is
essentially the same as mapping
, but it takes a 'Bifunctor p'
constraint instead of a 'Functor (p a)' one.
seconding ::Bifunctor
p =>Iso
s t a b ->Iso
(p x s) (p y t) (p x a) (p y b) seconding ::Bifunctor
p =>Iso'
s a ->Iso'
(p x s) (p x a)