-- |
-- Module      :  Control.Applicative.Combinators
-- Copyright   :  © 2017 Mark Karpov
-- License     :  BSD 3 clause
--
-- Maintainer  :  Mark Karpov <markkarpov92@gmail.com>
-- Stability   :  experimental
-- Portability :  portable
--
-- The module provides parser combinators defined for instances of
-- 'Applicative' and 'Alternative'. It also re-exports functions that are
-- commonly used in parsing from "Control.Applicative" with additional
-- parsing-related comments added.
--
-- Due to the nature of the 'Applicative' and 'Alternative' abstractions,
-- they are prone to memory leaks and not as efficient as their monadic
-- counterparts. Although all the combinators we provide in this module are
-- perfectly expressible in terms of 'Applicative' and 'Alternative', please
-- prefer "Control.Monad.Combinators" instead when possible.
--
-- If you wish that the combinators that cannot return empty lists return
-- values of the 'Data.List.NonEmpty.NonEmpty' data type, use the
-- "Control.Applicative.Combinators.NonEmpty" module.
--
-- === A note on backtracking
--
-- Certain parsing libraries, such as Megaparsec, do not backtrack every
-- branch of parsing automatically for the sake of performance and better
-- error messages. They typically backtrack only “atomic” parsers, e.g.
-- those that match a token or several tokens in a row. To backtrack an
-- arbitrary complex parser\/branch, a special combinator should be used,
-- typically called @try@. Combinators in this module are defined in terms
-- 'Applicative' and 'Alternative' operations. Being quite abstract, they
-- cannot know anything about inner workings of any concrete parsing
-- library, and so they cannot use @try@.
--
-- The essential feature of the 'Alternative' type class is the @('<|>')@
-- operator that allows to express choice. In libraries that do not
-- backtrack everything automatically, the choice operator and everything
-- that is build on top of it require the parser on the left hand side to
-- backtrack in order for the alternative branch of parsing to be tried.
-- Thus it is the responsibility of the programmer to wrap more complex,
-- composite parsers in @try@ to achieve correct behavior.

{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE CPP          #-}

module Control.Applicative.Combinators
  ( -- * Re-exports from "Control.Applicative"
    (<|>)
    -- $assocbo
  , many
    -- $many
  , some
    -- $some
  , optional
    -- $optional
  , empty
    -- $empty

    -- * Original combinators
  , between
  , choice
  , count
  , count'
  , eitherP
  , endBy
  , endBy1
  , manyTill
  , someTill
  , option
  , sepBy
  , sepBy1
  , sepEndBy
  , sepEndBy1
  , skipMany
  , skipSome
  , skipCount
  , skipManyTill
  , skipSomeTill )
where

import Control.Applicative
import Data.Foldable

#if MIN_VERSION_base(4,9,0)
import Control.Monad (replicateM, replicateM_)
#elif !MIN_VERSION_base(4,8,0)
import Data.Traversable (sequenceA)
#endif

----------------------------------------------------------------------------
-- Re-exports from "Control.Applicative"

-- $assocbo
--
-- This combinator implements choice. The parser @p '<|>' q@ first applies
-- @p@. If it succeeds, the value of @p@ is returned. If @p@ fails, parser
-- @q@ is tried.

-- $many
--
-- @'many' p@ applies the parser @p@ /zero/ or more times and returns a list
-- of the values returned by @p@.
--
-- > identifier = (:) <$> letter <*> many (alphaNumChar <|> char '_')

-- $some
--
-- @'some' p@ applies the parser @p@ /one/ or more times and returns a list
-- of the values returned by @p@.
--
-- > word = some letter

-- $optional
--
-- @'optional' p@ tries to apply the parser @p@. It will parse @p@ or
-- 'Nothing'. It only fails if @p@ fails after consuming input. On success
-- result of @p@ is returned inside of 'Just', on failure 'Nothing' is
-- returned.
--
-- See also: 'option'.

-- $empty
--
-- This parser fails unconditionally without providing any information about
-- the cause of the failure.
--
-- @since 0.4.0

----------------------------------------------------------------------------
-- Original combinators

-- | @'between' open close p@ parses @open@, followed by @p@ and @close@.
-- Returns the value returned by @p@.
--
-- > braces = between (symbol "{") (symbol "}")

between :: Applicative m => m open -> m close -> m a -> m a
between open close p = open *> p <* close
{-# INLINE between #-}

-- | @'choice' ps@ tries to apply the parsers in the list @ps@ in order,
-- until one of them succeeds. Returns the value of the succeeding parser.
--
-- > choice = asum

choice :: (Foldable f, Alternative m) => f (m a) -> m a
choice = asum
{-# INLINE choice #-}

-- | @'count' n p@ parses @n@ occurrences of @p@. If @n@ is smaller or equal
-- to zero, the parser equals to @'pure' []@. Returns a list of @n@ parsed
-- values.
--
-- > count = replicateM
--
-- See also: 'skipCount', 'count''.

count :: Applicative m => Int -> m a -> m [a]
#if MIN_VERSION_base(4,9,0)
count = replicateM
#else
count n p = sequenceA (replicate n p)
#endif
{-# INLINE count #-}

-- | @'count'' m n p@ parses from @m@ to @n@ occurrences of @p@. If @n@ is
-- not positive or @m > n@, the parser equals to @'pure' []@. Returns a list
-- of parsed values.
--
-- Please note that @m@ /may/ be negative, in this case effect is the same
-- as if it were equal to zero.
--
-- See also: 'skipCount', 'count'.

count' :: Alternative m => Int -> Int -> m a -> m [a]
count' m' n' p = go m' n'
  where
    go !m !n
      | n <= 0 || m > n = pure []
      | m > 0           = liftA2 (:) p (go (m - 1) (n - 1))
      | otherwise       = liftA2 (:) p (go 0 (n - 1)) <|> pure []
{-# INLINE count' #-}

-- | Combine two alternatives.
--
-- > eitherP a b = (Left <$> a) <|> (Right <$> b)

eitherP :: Alternative m => m a -> m b -> m (Either a b)
eitherP a b = (Left <$> a) <|> (Right <$> b)
{-# INLINE eitherP #-}

-- | @'endBy' p sep@ parses /zero/ or more occurrences of @p@, separated and
-- ended by @sep@. Returns a list of values returned by @p@.
--
-- > cStatements = cStatement `endBy` semicolon

endBy :: Alternative m => m a -> m sep -> m [a]
endBy p sep = many (p <* sep)
{-# INLINE endBy #-}

-- | @'endBy1' p sep@ parses /one/ or more occurrences of @p@, separated and
-- ended by @sep@. Returns a list of values returned by @p@.

endBy1 :: Alternative m => m a -> m sep -> m [a]
endBy1 p sep = some (p <* sep)
{-# INLINE endBy1 #-}

-- | @'manyTill' p end@ applies parser @p@ /zero/ or more times until parser
-- @end@ succeeds. Returns the list of values returned by @p@.
--
-- See also: 'skipMany', 'skipManyTill'.

manyTill :: Alternative m => m a -> m end -> m [a]
manyTill p end = go
  where
    go = ([] <$ end) <|> liftA2 (:) p go
{-# INLINE manyTill #-}

-- | @'someTill' p end@ works similarly to @'manyTill' p end@, but @p@
-- should succeed at least once.
--
-- See also: 'skipSome', 'skipSomeTill'.

someTill :: Alternative m => m a -> m end -> m [a]
someTill p end = liftA2 (:) p (manyTill p end)
{-# INLINE someTill #-}

-- | @'option' x p@ tries to apply the parser @p@. If @p@ fails without
-- consuming input, it returns the value @x@, otherwise the value returned
-- by @p@.
--
-- > option x p = p <|> pure x
--
-- See also: 'optional'.

option :: Alternative m => a -> m a -> m a
option x p = p <|> pure x
{-# INLINE option #-}

-- | @'sepBy' p sep@ parses /zero/ or more occurrences of @p@, separated by
-- @sep@. Returns a list of values returned by @p@.
--
-- > commaSep p = p `sepBy` comma

sepBy :: Alternative m => m a -> m sep -> m [a]
sepBy p sep = sepBy1 p sep <|> pure []
{-# INLINE sepBy #-}

-- | @'sepBy1' p sep@ parses /one/ or more occurrences of @p@, separated by
-- @sep@. Returns a list of values returned by @p@.

sepBy1 :: Alternative m => m a -> m sep -> m [a]
sepBy1 p sep = liftA2 (:) p (many (sep *> p))
{-# INLINE sepBy1 #-}

-- | @'sepEndBy' p sep@ parses /zero/ or more occurrences of @p@, separated
-- and optionally ended by @sep@. Returns a list of values returned by @p@.

sepEndBy :: Alternative m => m a -> m sep -> m [a]
sepEndBy p sep = sepEndBy1 p sep <|> pure []
{-# INLINE sepEndBy #-}

-- | @'sepEndBy1' p sep@ parses /one/ or more occurrences of @p@, separated
-- and optionally ended by @sep@. Returns a list of values returned by @p@.

sepEndBy1 :: Alternative m => m a -> m sep -> m [a]
sepEndBy1 p sep = liftA2 (:) p ((sep *> sepEndBy p sep) <|> pure [])
{-# INLINEABLE sepEndBy1 #-}

-- | @'skipMany' p@ applies the parser @p@ /zero/ or more times, skipping
-- its result.
--
-- See also: 'manyTill', 'skipManyTill'.

skipMany :: Alternative m => m a -> m ()
skipMany p = go
  where
    go = (p *> go) <|> pure ()
{-# INLINE skipMany #-}

-- | @'skipSome' p@ applies the parser @p@ /one/ or more times, skipping its
-- result.
--
-- See also: 'someTill', 'skipSomeTill'.

skipSome :: Alternative m => m a -> m ()
skipSome p = p *> skipMany p
{-# INLINE skipSome #-}

-- | @'skipCount' n p@ parses @n@ occurrences of @p@, skipping its result.
-- If @n@ is not positive, the parser equals to @'pure' []@. Returns a list
-- of @n@ values.
--
-- > skipCount = replicateM_
--
-- See also: 'count', 'count''.
--
-- @since 0.3.0

skipCount :: Applicative m => Int -> m a -> m ()
#if MIN_VERSION_base(4,9,0)
skipCount = replicateM_
#else
skipCount n p = sequenceA_ (replicate n p)
#endif
{-# INLINE skipCount #-}

-- | @'skipManyTill' p end@ applies the parser @p@ /zero/ or more times
-- skipping results until parser @end@ succeeds. Result parsed by @end@ is
-- then returned.
--
-- See also: 'manyTill', 'skipMany'.

skipManyTill :: Alternative m => m a -> m end -> m end
skipManyTill p end = go
  where
    go = end <|> (p *> go)
{-# INLINE skipManyTill #-}

-- | @'skipSomeTill' p end@ applies the parser @p@ /one/ or more times
-- skipping results until parser @end@ succeeds. Result parsed by @end@ is
-- then returned.
--
-- See also: 'someTill', 'skipSome'.

skipSomeTill :: Alternative m => m a -> m end -> m end
skipSomeTill p end = p *> skipManyTill p end
{-# INLINE skipSomeTill #-}