Safe Haskell | None |
---|---|

Language | Haskell2010 |

## Synopsis

- class Compactable (f :: * -> *) where
- compact :: f (Maybe a) -> f a
- separate :: f (Either l r) -> (f l, f r)
- filter :: (a -> Bool) -> f a -> f a
- partition :: (a -> Bool) -> f a -> (f a, f a)
- fmapMaybe :: Functor f => (a -> Maybe b) -> f a -> f b
- fmapEither :: Functor f => (a -> Either l r) -> f a -> (f l, f r)
- applyMaybe :: Applicative f => f (a -> Maybe b) -> f a -> f b
- applyEither :: Applicative f => f (a -> Either l r) -> f a -> (f l, f r)
- bindMaybe :: Monad f => f a -> (a -> f (Maybe b)) -> f b
- bindEither :: Monad f => f a -> (a -> f (Either l r)) -> (f l, f r)
- traverseMaybe :: (Applicative g, Traversable f) => (a -> g (Maybe b)) -> f a -> g (f b)
- traverseEither :: (Applicative g, Traversable f) => (a -> g (Either l r)) -> f a -> g (f l, f r)

- class Compactable f => CompactFold (f :: * -> *) where
- compactFold :: Foldable g => f (g a) -> f a
- separateFold :: Bifoldable g => f (g a b) -> (f a, f b)
- fmapFold :: (Functor f, Foldable g) => (a -> g b) -> f a -> f b
- fmapBifold :: (Functor f, Bifoldable g) => (a -> g l r) -> f a -> (f l, f r)
- applyFold :: (Applicative f, Foldable g) => f (a -> g b) -> f a -> f b
- applyBifold :: (Applicative f, Bifoldable g) => f (a -> g l r) -> f a -> (f l, f r)
- bindFold :: (Monad f, Foldable g) => f a -> (a -> f (g b)) -> f b
- bindBifold :: (Monad f, Bifoldable g) => f a -> (a -> f (g l r)) -> (f l, f r)
- traverseFold :: (Applicative h, Foldable g, Traversable f) => (a -> h (g b)) -> f a -> h (f b)
- traverseBifold :: (Applicative h, Bifoldable g, Traversable f) => (a -> h (g l r)) -> f a -> h (f l, f r)

- fforMaybe :: (Compactable f, Functor f) => f a -> (a -> Maybe b) -> f b
- fforFold :: (CompactFold f, Functor f, Foldable g) => f a -> (a -> g b) -> f b
- fforEither :: (Compactable f, Functor f) => f a -> (a -> Either l r) -> (f l, f r)
- fforBifold :: (CompactFold f, Functor f, Bifoldable g) => f a -> (a -> g l r) -> (f l, f r)
- mfold' :: (Foldable f, Alternative m) => f a -> m a
- mlefts :: (Bifoldable f, Alternative m) => f a b -> m a
- mrights :: (Bifoldable f, Alternative m) => f a b -> m b
- fmapMaybeM :: (Compactable f, Monad f) => (a -> MaybeT f b) -> f a -> f b
- fmapEitherM :: (Compactable f, Monad f) => (a -> ExceptT l f r) -> f a -> (f l, f r)
- fforMaybeM :: (Compactable f, Monad f) => f a -> (a -> MaybeT f b) -> f b
- fforEitherM :: (Compactable f, Monad f) => f a -> (a -> ExceptT l f r) -> (f l, f r)
- applyMaybeM :: (Compactable f, Monad f) => f (a -> MaybeT f b) -> f a -> f b
- bindMaybeM :: (Compactable f, Monad f) => f a -> (a -> f (MaybeT f b)) -> f b
- traverseMaybeM :: (Monad m, Compactable t, Traversable t) => (a -> MaybeT m b) -> t a -> m (t b)
- altDefaultCompact :: (Alternative f, Monad f) => f (Maybe a) -> f a
- altDefaultSeparate :: (Alternative f, Foldable f) => f (Either l r) -> (f l, f r)

# Compact

class Compactable (f :: * -> *) where Source #

Class `Compactable`

provides two methods which can be writen in terms of each other, compact and separate.

is generalization of catMaybes as a new function. Compact has relations with Functor, Applicative, Monad, Alternative, and Traversable. In that we can use these class to provide the ability to operate on a data type by throwing away intermediate Nothings. This is useful for representing stripping out values or failure.

To be compactable alone, no laws must be satisfied other than the type signature.

If the data type is also a Functor the following should hold:

*Kleisli composition*fmapMaybe (l <=< r) = fmapMaybe l . fmapMaybe r

*Functor identity 1*compact . fmap Just = id

*Functor identity 2*fmapMaybe Just = id

*Functor relation*compact = fmapMaybe id

According to Kmett, (Compactable f, Functor f) is a functor from the
kleisli category of Maybe to the category of haskell data types.
`Kleisli Maybe -> Hask`

.

If the data type is also Applicative the following should hold:

*Applicative left identity*compact . (pure Just <*>) = id

*Applicative right identity*applyMaybe (pure Just) = id

*Applicative relation*compact = applyMaybe (pure id)

If the data type is also a Monad the following should hold:

*Monad left identity*flip bindMaybe (return . Just) = id

*Monad right identity*compact . (return . Just =<<) = id

*Monad relation*compact = flip bindMaybe return

If the data type is also Alternative the following should hold:

*Alternative identity*compact empty = empty

*Alternative annihilation*compact (const Nothing <$> xs) = empty

If the data type is also Traversable the following should hold:

*Traversable Applicative relation*traverseMaybe (pure . Just) = pure

*Traversable composition*Compose . fmap (traverseMaybe f) . traverseMaybe g = traverseMaybe (Compose . fmap (traverseMaybe f) . g)

*Traversable Functor relation*traverse f = traverseMaybe (fmap Just . f)

*Traversable naturality*t . traverseMaybe f = traverseMaybe (t . f)

# Separate and filter

have recently elevated roles in this typeclass, and is not as well explored as compact. Here are the laws known today:

*Functor identity 3*fst . separate . fmap Right = id

*Functor identity 4*snd . separate . fmap Left = id

*Applicative left identity 2*snd . separate . (pure Right <*>) = id

*Applicative right identity 2*fst . separate . (pure Left <*>) = id

*Alternative annihilation left*snd . separate . fmap (const Left) = empty

*Alternative annihilation right*fst , separate . fmap (const Right) = empty

Docs for relationships between these functions and, a cleanup of laws will happen at some point.

If you know of more useful laws, or have better names for the ones above (especially those marked "name me"). Please let me know.

Nothing

compact :: f (Maybe a) -> f a Source #

compact :: Functor f => f (Maybe a) -> f a Source #

separate :: f (Either l r) -> (f l, f r) Source #

separate :: Functor f => f (Either l r) -> (f l, f r) Source #

filter :: (a -> Bool) -> f a -> f a Source #

filter :: Functor f => (a -> Bool) -> f a -> f a Source #

partition :: (a -> Bool) -> f a -> (f a, f a) Source #

partition :: Functor f => (a -> Bool) -> f a -> (f a, f a) Source #

fmapMaybe :: Functor f => (a -> Maybe b) -> f a -> f b Source #

fmapEither :: Functor f => (a -> Either l r) -> f a -> (f l, f r) Source #

applyMaybe :: Applicative f => f (a -> Maybe b) -> f a -> f b Source #

applyEither :: Applicative f => f (a -> Either l r) -> f a -> (f l, f r) Source #

bindMaybe :: Monad f => f a -> (a -> f (Maybe b)) -> f b Source #

bindEither :: Monad f => f a -> (a -> f (Either l r)) -> (f l, f r) Source #

traverseMaybe :: (Applicative g, Traversable f) => (a -> g (Maybe b)) -> f a -> g (f b) Source #

traverseEither :: (Applicative g, Traversable f) => (a -> g (Either l r)) -> f a -> g (f l, f r) Source #

## Instances

# Compact Fold

class Compactable f => CompactFold (f :: * -> *) where Source #

class `CompactFold`

provides the same methods as `Compactable`

but generalized to work on any `Foldable`

.

When a type has Alternative (or similar) properties, we can extract the Maybe and the Either, and generalize to Foldable and Bifoldable.

Compactable can always be described in terms of CompactFold, because

compact = compactFold

and

separate = separateFold

as it's just a specialization. More exploration is needed on the relationship here.

Nothing

compactFold :: Foldable g => f (g a) -> f a Source #

compactFold :: (Monad f, Alternative f, Foldable g) => f (g a) -> f a Source #

separateFold :: Bifoldable g => f (g a b) -> (f a, f b) Source #

separateFold :: (Monad f, Alternative f, Bifoldable g) => f (g a b) -> (f a, f b) Source #

fmapFold :: (Functor f, Foldable g) => (a -> g b) -> f a -> f b Source #

fmapBifold :: (Functor f, Bifoldable g) => (a -> g l r) -> f a -> (f l, f r) Source #

applyFold :: (Applicative f, Foldable g) => f (a -> g b) -> f a -> f b Source #

applyBifold :: (Applicative f, Bifoldable g) => f (a -> g l r) -> f a -> (f l, f r) Source #

bindFold :: (Monad f, Foldable g) => f a -> (a -> f (g b)) -> f b Source #

bindBifold :: (Monad f, Bifoldable g) => f a -> (a -> f (g l r)) -> (f l, f r) Source #

traverseFold :: (Applicative h, Foldable g, Traversable f) => (a -> h (g b)) -> f a -> h (f b) Source #

traverseBifold :: (Applicative h, Bifoldable g, Traversable f) => (a -> h (g l r)) -> f a -> h (f l, f r) Source #

## Instances

# Handly flips

fforEither :: (Compactable f, Functor f) => f a -> (a -> Either l r) -> (f l, f r) Source #

fforBifold :: (CompactFold f, Functor f, Bifoldable g) => f a -> (a -> g l r) -> (f l, f r) Source #

# More general lefts and rights

mfold' :: (Foldable f, Alternative m) => f a -> m a Source #

mlefts :: (Bifoldable f, Alternative m) => f a b -> m a Source #

mrights :: (Bifoldable f, Alternative m) => f a b -> m b Source #

# Monad Transformer utils

fmapMaybeM :: (Compactable f, Monad f) => (a -> MaybeT f b) -> f a -> f b Source #

fmapEitherM :: (Compactable f, Monad f) => (a -> ExceptT l f r) -> f a -> (f l, f r) Source #

fforMaybeM :: (Compactable f, Monad f) => f a -> (a -> MaybeT f b) -> f b Source #

fforEitherM :: (Compactable f, Monad f) => f a -> (a -> ExceptT l f r) -> (f l, f r) Source #

applyMaybeM :: (Compactable f, Monad f) => f (a -> MaybeT f b) -> f a -> f b Source #

bindMaybeM :: (Compactable f, Monad f) => f a -> (a -> f (MaybeT f b)) -> f b Source #

traverseMaybeM :: (Monad m, Compactable t, Traversable t) => (a -> MaybeT m b) -> t a -> m (t b) Source #

# Alternative Defaults

altDefaultCompact :: (Alternative f, Monad f) => f (Maybe a) -> f a Source #

While more constrained, when available, this default is going to be faster than the one provided in the typeclass

altDefaultSeparate :: (Alternative f, Foldable f) => f (Either l r) -> (f l, f r) Source #

While more constrained, when available, this default is going to be faster than the one provided in the typeclass