Copyright | (C) 2013-2016 Edward Kmett 2015-2016 Artyom |
---|---|

License | BSD-style (see the file LICENSE) |

Safe Haskell | Unsafe |

Language | Haskell2010 |

This module is needed to give other packages from the microlens family (like microlens-ghc) access to functions and classes that don't need to be exported from Lens.Micro (because they just clutter the namespace). Also:

`traversed`

is here because otherwise there'd be a dependency cycle`sets`

is here because it's used in RULEs

Classes like `Each`

, `Ixed`

, etc are provided for convenience – you're not supposed to export functions that work on all members of `Ixed`

, for instance. Only microlens can do that. You mustn't declare instances of those classes for other types, either; these classes are incompatible with lens's classes, and by doing so you would divide the ecosystem.

If you absolutely need to define an instance (e.g. for internal use), only do it for your own types, because otherwise I might add an instance to one of the microlens packages later and if our instances are different it might lead to subtle bugs.

- traversed :: Traversable f => Traversal (f a) (f b) a b
- folded :: Foldable f => SimpleFold (f a) a
- foldring :: Monoid r => ((a -> Const r a -> Const r a) -> Const r a -> s -> Const r a) -> (a -> Const r b) -> s -> Const r t
- foldrOf :: Getting (Endo r) s a -> (a -> r -> r) -> r -> s -> r
- foldMapOf :: Getting r s a -> (a -> r) -> s -> r
- sets :: ((a -> b) -> s -> t) -> ASetter s t a b
- (#.) :: Coercible c b => (b -> c) -> (a -> b) -> a -> c
- (.#) :: Coercible b a => (b -> c) -> (a -> b) -> a -> c
- phantom :: Const r a -> Const r b
- class Each s t a b | s -> a, t -> b, s b -> t, t a -> s where
- type family Index (s :: *) :: *
- type family IxValue (m :: *) :: *
- class Ixed m where
- class Ixed m => At m where
- ixAt :: At m => Index m -> Traversal' m (IxValue m)
- class Field1 s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Field2 s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Field3 s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Field4 s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Field5 s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Cons s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Snoc s t a b | s -> a, t -> b, s b -> t, t a -> s where
- class Strict lazy strict | lazy -> strict, strict -> lazy where
- type HasCallStack = ?callStack :: CallStack

# Documentation

traversed :: Traversable f => Traversal (f a) (f b) a b Source #

`traversed`

traverses any `Traversable`

container (list, vector, `Map`

, `Maybe`

, you name it):

`>>>`

[1]`Just 1 ^.. traversed`

`traversed`

is the same as `traverse`

, but can be faster thanks to magic rewrite rules.

folded :: Foldable f => SimpleFold (f a) a Source #

foldring :: Monoid r => ((a -> Const r a -> Const r a) -> Const r a -> s -> Const r a) -> (a -> Const r b) -> s -> Const r t Source #

class Each s t a b | s -> a, t -> b, s b -> t, t a -> s where Source #

each :: Traversal s t a b Source #

`each`

tries to be a universal `Traversal`

– it behaves like `traversed`

in most situations, but also adds support for e.g. tuples with same-typed values:

`>>>`

(2,3)`(1,2) & each %~ succ`

`>>>`

"xyz"`["x", "y", "z"] ^. each`

However, note that `each`

doesn't work on *every* instance of `Traversable`

. If you have a `Traversable`

which isn't supported by `each`

, you can use `traversed`

instead. Personally, I like using `each`

instead of `traversed`

whenever possible – it's shorter and more descriptive.

You can use `each`

with these things:

`each`

::`Traversal`

[a] [b] a b`each`

::`Traversal`

(`Maybe`

a) (`Maybe`

b) a b`each`

::`Traversal`

(a,a) (b,b) a b`each`

::`Traversal`

(a,a,a) (b,b,b) a b`each`

::`Traversal`

(a,a,a,a) (b,b,b,b) a b`each`

::`Traversal`

(a,a,a,a,a) (b,b,b,b,b) a b`each`

:: (`RealFloat`

a,`RealFloat`

b) =>`Traversal`

(`Complex`

a) (`Complex`

b) a b

You can also use `each`

with types from array, bytestring, and containers by using microlens-ghc, or additionally with types from vector, text, and unordered-containers by using microlens-platform.

Each [a] [b] a b Source # | |

Each (Maybe a) (Maybe b) a b Source # | |

Each (Complex a) (Complex b) a b Source # | |

Each (NonEmpty a) (NonEmpty b) a b Source # | |

((~) * a b, (~) * q r) => Each (a, b) (q, r) a q Source # | |

((~) * a b, (~) * a c, (~) * q r, (~) * q s) => Each (a, b, c) (q, r, s) a q Source # | |

((~) * a b, (~) * a c, (~) * a d, (~) * q r, (~) * q s, (~) * q t) => Each (a, b, c, d) (q, r, s, t) a q Source # | |

((~) * a b, (~) * a c, (~) * a d, (~) * a e, (~) * q r, (~) * q s, (~) * q t, (~) * q u) => Each (a, b, c, d, e) (q, r, s, t, u) a q Source # | |

ix :: Index m -> Traversal' m (IxValue m) Source #

This traversal lets you access (and update) an arbitrary element in a list, array, `Map`

, etc. (If you want to insert or delete elements as well, look at `at`

.)

An example for lists:

`>>>`

[0,1,2,10,4,5]`[0..5] & ix 3 .~ 10`

You can use it for getting, too:

`>>>`

Just 3`[0..5] ^? ix 3`

Of course, the element may not be present (which means that you can use `ix`

as a safe variant of (`!!`

)):

`>>>`

Nothing`[0..5] ^? ix 10`

Another useful instance is the one for functions – it lets you modify their outputs for specific inputs. For instance, here's `maximum`

that returns 0 when the list is empty (instead of throwing an exception):

maximum0 =`maximum`

`&`

`ix`

[]`.~`

0

The following instances are provided in this package:

`ix`

::`Int`

->`Traversal'`

[a] a`ix`

:: (`Eq`

e) => e ->`Traversal'`

(e -> a) a

You can also use `ix`

with types from array, bytestring, and containers by using microlens-ghc, or additionally with types from vector, text, and unordered-containers by using microlens-platform.

class Ixed m => At m where Source #

at :: Index m -> Lens' m (Maybe (IxValue m)) Source #

This lens lets you read, write, or delete elements in `Map`

-like structures. It returns `Nothing`

when the value isn't found, just like `lookup`

:

`Data.Map.lookup k m = m ``^.`

at k

However, it also lets you insert and delete values by setting the value to

or `Just`

value`Nothing`

:

Data.Map.insert k a m = m`&`

at k`.~`

Just a Data.Map.delete k m = m`&`

at k`.~`

Nothing

Or you could use (`?~`

) instead of (`.~`

):

Data.Map.insert k a m = m`&`

at k`?~`

a

Note that `at`

doesn't work for arrays or lists. You can't delete an arbitrary element from an array (what would be left in its place?), and you can't set an arbitrary element in a list because if the index is out of list's bounds, you'd have to somehow fill the stretch between the last element and the element you just inserted (i.e. `[1,2,3] & at 10 .~ 5`

is undefined). If you want to modify an already existing value in an array or list, you should use `ix`

instead.

`at`

is often used with `non`

. See the documentation of `non`

for examples.

Note that `at`

isn't strict for `Map`

, even if you're using `Data.Map.Strict`

:

`>>>`

1`Data.Map.Strict.size (Data.Map.Strict.empty & at 1 .~ Just undefined)`

The reason for such behavior is that there's actually no “strict `Map`

” type; `Data.Map.Strict`

just provides some strict functions for ordinary `Map`

s.

This package doesn't actually provide any instances for `at`

, but there are instances for `Map`

and `IntMap`

in microlens-ghc and an instance for `HashMap`

in microlens-platform.

class Field1 s t a b | s -> a, t -> b, s b -> t, t a -> s where Source #

Gives access to the 1st field of a tuple (up to 5-tuples).

Getting the 1st component:

`>>>`

1`(1,2,3,4,5) ^. _1`

Setting the 1st component:

`>>>`

(10,2,3)`(1,2,3) & _1 .~ 10`

Note that this lens is lazy, and can set fields even of `undefined`

:

`>>>`

(10,*** Exception: Prelude.undefined`set _1 10 undefined :: (Int, Int)`

This is done to avoid violating a lens law stating that you can get back what you put:

`>>>`

10`view _1 . set _1 10 $ (undefined :: (Int, Int))`

The implementation (for 2-tuples) is:

`_1`

f t = (,)`<$>`

f (`fst`

t)`<*>`

`pure`

(`snd`

t)

or, alternatively,

`_1`

f ~(a,b) = (\a' -> (a',b))`<$>`

f a

(where `~`

means a lazy pattern).

class Strict lazy strict | lazy -> strict, strict -> lazy where Source #

strict :: Lens' lazy strict Source #

`strict`

lets you convert between strict and lazy versions of a datatype:

`>>>`

`let someText = "hello" :: Lazy.Text`

`>>>`

"hello" :: Strict.Text`someText ^. strict`

It can also be useful if you have a function that works on a strict type but your type is lazy:

stripDiacritics :: Strict.Text -> Strict.Text stripDiacritics = ...

`>>>`

`let someText = "Paul Erdős" :: Lazy.Text`

`>>>`

"Paul Erdos" :: Lazy.Text`someText & strict %~ stripDiacritics`

`strict`

works on `ByteString`

and `StateT`

/`WriterT`

/`RWST`

if you use microlens-ghc, and additionally on `Text`

if you use microlens-platform.

# CallStack

type HasCallStack = ?callStack :: CallStack #

Request a CallStack.

NOTE: The implicit parameter `?callStack :: CallStack`

is an
implementation detail and **should not** be considered part of the
`CallStack`

API, we may decide to change the implementation in the
future.

*Since: 4.9.0.0*