# What are Alternative's “some” and “many” useful for?

`Alternative`, an extension of `Applicative`, declares `empty`, `<|>` and these two functions:

One or more:

``````some :: f a -> f [a]
``````

Zero or more:

``````many :: f a -> f [a]
``````

If defined, `some` and `many` should be the least solutions of the equations:

``````some v = (:) <\$> v <*> many v

many v = some v <|> pure []
``````

I couldn't find an instance for which `some` and `many` are defined. What is their meaning and practical use? Are they used at all? I've been unable to grasp their purpose just from this definition.

Update: I'm not asking what is `Alternative`, just what are `some` and `many`

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Although there are some nice answers here, however this question is a possible duplicate of this, this and this –  is7s Aug 7 '13 at 19:18
they are what it says: combinators for multiple application of (e.g.) a parser, collecting the results in a list. I provided the elementary example where the definitions are easily followed. –  Will Ness Aug 7 '13 at 19:22
@WillNess Thank, I didn't think about parsers. Still what puzzles me is why they're included in `Alternative`, when these functions are undefined for the basic classes. –  Petr Pudlák Aug 7 '13 at 19:26
for bare-metal parsers? there's also "optional" defined there... –  Will Ness Aug 7 '13 at 19:30

I tend to see them in `Applicative` parser combinator libraries.

``````a :: Parser [String]
a = some (string "hello")
``````

and I see `many` used for purpose in the default definitions of `Parsing` in `parsers`.

I think Parsec being the primary example of a parser combinator library hides the use of `some`/`many` since it redefines things like `(<|>)`.

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An elementary example instance:

``````import Control.Monad(Functor(..))
import Control.Applicative
import Data.Char

-- char string parser
newtype P a = P { unP :: String -> [(a,String)] }

runP (P p) s = p s

instance Functor P where
-- fmap :: (a -> b) -> f a -> f b
fmap f (P q) = P (\s -> [ (f y,ys) | (y,ys) <- q s])

instance Applicative P where
-- pure :: a -> f a
pure x = P (\s -> [(x,s)])
-- (<*>) :: f (a -> b) -> f a -> f b
P p <*> P q = P (\s -> [(x y, ys) | (x,xs) <- p s, (y,ys) <- q xs])

letter = P p where      -- sample parser
p (x:xs) | isAlpha x = [(x,xs)]
p _ = []
{-
*Main Data.Char> runP letter "123"
[]
*Main Data.Char> runP letter "a123"
[('a',"123")]
*Main Data.Char> runP ( (:) <\$> letter <*> pure []) "a123"
[("a","123")]
*Main Data.Char> runP ( (:) <\$> letter <*> ((:)<\$>letter <*> pure []) ) "a123"
[]
*Main Data.Char> runP ( (:) <\$> letter <*> ((:)<\$>letter <*> pure []) ) "ab123"
[("ab","123")]   -- NOT NICE ^^^^^^^^^^^^^^^^^^^^ -}
``````

then,

``````instance Alternative P where
-- (<|>) :: f a -> f a -> f a
P p <|> P q = P (\s-> p s ++ q s)
-- empty :: f a   -- the identity of <|>
empty = P (\s-> [])

{-
*Main Data.Char> runP (many letter) "ab123"
[("ab","123"),("a","b123"),("","ab123")]
*Main Data.Char> runP (some letter) "ab123"
[("ab","123"),("a","b123")]

*Main Data.Char> runP (optional letter) "ab123"
[(Just 'a',"b123"),(Nothing,"ab123")]
*Main Data.Char> runP (optional letter) "123"
[(Nothing,"123")]

-- and also
Prelude Main Data.Traversable> runP (sequenceA \$ replicate 2 letter) "ab123"
[("ab","123")]               --  NICE  ^^^^^^^^^^^^^^^^^^^
-}
``````
-

Will provided a good example motivating the use of those methods, but you seem to still have a misunderstanding about type classes.

A type class definition lists the type signatures for the methods that exist for all instances of the type class. It may also provide default implementations of those methods, which is what is happening with Alternative's some and many methods.

In order to be valid instances, all of the methods have to be defined for the instance. So the ones that you found that did not specifically define instances for some or many used the default implementations, and the code for them is exactly as listed in your question.

So, just to be clear, some and many are indeed defined and can be used with all Alternative instances thanks to the default definitions given with the type class definition.

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I understand all that. To clarify, the definitions of `some` and `many` for the most basic types such as `[]` and `Maybe` just loop. So although the definition of `some` and `many` for them is valid, it has no meaning. –  Petr Pudlák Aug 7 '13 at 20:13
@PetrPudlák I really liked this answer (thanks, is7s). –  Will Ness Aug 7 '13 at 22:54
@WillNess Indeed, this answer is very nice. –  Petr Pudlák Aug 8 '13 at 5:25
In the STM Applicative, `some` would mean: Keep trying until it succeeds at least once, and then keep doing it until it fails. `many` would mean: Do this as many times as you can until failure.