178 lines
5.1 KiB
Haskell
178 lines
5.1 KiB
Haskell
{- A generic matcher.
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-
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- Can be used to check if a user-supplied condition,
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- like "foo and ( bar or not baz )" matches. The condition must already
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- be tokenized, and can contain arbitrary operations.
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-
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- If operations are not separated by and/or, they are defaulted to being
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- anded together, so "foo bar baz" all must match.
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-
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- Is forgiving about misplaced closing parens, so "foo and (bar or baz"
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- will be handled, as will "foo and ( bar or baz ) )"
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-
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- Copyright 2011-2013 Joey Hess <id@joeyh.name>
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-
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- License: BSD-2-clause
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-}
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{-# LANGUAGE Rank2Types, KindSignatures #-}
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module Utility.Matcher (
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Token(..),
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Matcher(..),
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token,
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tokens,
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generate,
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match,
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matchM,
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matchMrun,
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isEmpty,
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combineMatchers,
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prop_matcher_sane
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) where
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import Common
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{- A Token can be an Operation of an arbitrary type, or one of a few
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- predefined peices of syntax. -}
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data Token op = Operation op | And | Or | Not | Open | Close
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deriving (Show, Eq)
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data Matcher op = MAny
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| MAnd (Matcher op) (Matcher op)
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| MOr (Matcher op) (Matcher op)
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| MNot (Matcher op)
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| MOp op
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deriving (Show, Eq)
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{- Converts a word of syntax into a token. Doesn't handle operations. -}
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token :: String -> Token op
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token "and" = And
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token "or" = Or
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token "not" = Not
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token "(" = Open
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token ")" = Close
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token t = error $ "unknown token " ++ t
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tokens :: [String]
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tokens = words "and or not ( )"
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{- Converts a list of Tokens into a Matcher. -}
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generate :: [Token op] -> Matcher op
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generate = simplify . process MAny . tokenGroups
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where
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process m [] = m
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process m ts = uncurry process $ consume m ts
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consume m (One And:rest) = term (m `MAnd`) rest
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consume m (One Or:rest) = term (m `MOr`) rest
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consume m (One Not:rest) = term (\p -> m `MAnd` (MNot p)) rest
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consume m (One (Operation o):rest) = (m `MAnd` MOp o, rest)
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consume m (Group g:rest) = (process m g, rest)
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consume m (_:rest) = consume m rest
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consume m [] = (m, [])
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term a l =
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let (p, l') = consume MAny l
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in (a p, l')
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simplify (MAnd MAny x) = simplify x
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simplify (MAnd x MAny) = simplify x
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simplify (MAnd x y) = MAnd (simplify x) (simplify y)
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simplify (MOr x y) = MOr (simplify x) (simplify y)
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simplify (MNot x) = MNot (simplify x)
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simplify x = x
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data TokenGroup op = One (Token op) | Group [TokenGroup op]
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deriving (Show, Eq)
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tokenGroups :: [Token op] -> [TokenGroup op]
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tokenGroups [] = []
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tokenGroups (t:ts) = go t
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where
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go Open =
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let (gr, rest) = findClose ts
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in gr : tokenGroups rest
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go Close = tokenGroups ts -- not picky about missing Close
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go _ = One t : tokenGroups ts
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findClose :: [Token op] -> (TokenGroup op, [Token op])
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findClose l =
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let (g, rest) = go [] l
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in (Group (reverse g), rest)
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where
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go c [] = (c, []) -- not picky about extra Close
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go c (t:ts) = dispatch t
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where
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dispatch Close = (c, ts)
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dispatch Open =
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let (c', ts') = go [] ts
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in go (Group (reverse c') : c) ts'
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dispatch _ = go (One t:c) ts
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{- Checks if a Matcher matches, using a supplied function to check
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- the value of Operations. -}
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match :: (op -> v -> Bool) -> Matcher op -> v -> Bool
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match a m v = go m
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where
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go MAny = True
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go (MAnd m1 m2) = go m1 && go m2
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go (MOr m1 m2) = go m1 || go m2
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go (MNot m1) = not $ go m1
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go (MOp o) = a o v
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{- Runs a monadic Matcher, where Operations are actions in the monad. -}
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matchM :: Monad m => Matcher (v -> m Bool) -> v -> m Bool
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matchM m v = matchMrun m $ \o -> o v
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{- More generic running of a monadic Matcher, with full control over running
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- of Operations. Mostly useful in order to match on more than one
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- parameter. -}
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matchMrun :: forall o (m :: * -> *). Monad m => Matcher o -> (o -> m Bool) -> m Bool
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matchMrun m run = go m
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where
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go MAny = return True
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go (MAnd m1 m2) = go m1 <&&> go m2
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go (MOr m1 m2) = go m1 <||> go m2
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go (MNot m1) = liftM not (go m1)
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go (MOp o) = run o
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{- Checks if a matcher contains no limits. -}
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isEmpty :: Matcher a -> Bool
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isEmpty MAny = True
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isEmpty _ = False
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{- Combines two matchers, yielding a matcher that will match anything
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- both do. But, if one matcher contains no limits, yield the other one. -}
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combineMatchers :: Matcher a -> Matcher a -> Matcher a
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combineMatchers a b
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| isEmpty a = b
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| isEmpty b = a
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| otherwise = a `MOr` b
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prop_matcher_sane :: Bool
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prop_matcher_sane = all (\m -> match dummy m ()) $ map generate
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[ [Operation True]
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, []
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, [Operation False, Or, Operation True, Or, Operation False]
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, [Operation True, Or, Operation True]
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, [Operation True, And, Operation True]
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, [Not, Open, Operation True, And, Operation False, Close]
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, [Not, Open, Not, Open, Not, Operation False, Close, Close]
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, [Not, Open, Not, Open, Not, Open, Not, Operation True, Close, Close]
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, [Operation True, And, Not, Operation False]
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, [Operation True, Not, Operation False]
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, [Operation True, Not, Not, Not, Operation False]
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, [Operation True, Not, Not, Not, Operation False, And, Operation True]
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, [Operation True, Not, Not, Not, Operation False, Operation True]
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, [Not, Open, Operation True, And, Operation False, Close,
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And, Open,
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Open, Operation True, And, Operation False, Close,
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Or,
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Open, Operation True, And, Open, Not, Operation False, Close, Close,
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Close, And,
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Open, Not, Operation False, Close]
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]
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where
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dummy b _ = b
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