{- A generic matcher. - - Can be used to check if a user-supplied condition, - like "foo and ( bar or not baz )" matches. The condition must already - be tokenized, and can contain arbitrary operations. - - If operations are not separated by and/or, they are defaulted to being - anded together, so "foo bar baz" all must match. - - Is forgiving about misplaced closing parens, so "foo and (bar or baz" - will be handled, as will "foo and ( bar or baz ) )" - - Copyright 2011-2013 Joey Hess - - Licensed under the GNU GPL version 3 or higher. -} {-# LANGUAGE Rank2Types, KindSignatures #-} module Utility.Matcher ( Token(..), Matcher(..), token, tokens, generate, match, matchM, matchMrun, isEmpty, prop_matcher_sane ) where import Common {- A Token can be an Operation of an arbitrary type, or one of a few - predefined peices of syntax. -} data Token op = Operation op | And | Or | Not | Open | Close deriving (Show, Eq) data Matcher op = MAny | MAnd (Matcher op) (Matcher op) | MOr (Matcher op) (Matcher op) | MNot (Matcher op) | MOp op deriving (Show, Eq) {- Converts a word of syntax into a token. Doesn't handle operations. -} token :: String -> Token op token "and" = And token "or" = Or token "not" = Not token "(" = Open token ")" = Close token t = error $ "unknown token " ++ t tokens :: [String] tokens = words "and or not ( )" {- Converts a list of Tokens into a Matcher. -} generate :: [Token op] -> Matcher op generate = simplify . process MAny . tokenGroups where process m [] = m process m ts = uncurry process $ consume m ts consume m (One And:rest) = term (m `MAnd`) rest consume m (One Or:rest) = term (m `MOr`) rest consume m (One Not:rest) = term (\p -> m `MAnd` (MNot p)) rest consume m (One (Operation o):rest) = (m `MAnd` MOp o, rest) consume m (Group g:rest) = (process m g, rest) consume m (_:rest) = consume m rest consume m [] = (m, []) term a l = let (p, l') = consume MAny l in (a p, l') simplify (MAnd MAny x) = simplify x simplify (MAnd x MAny) = simplify x simplify (MAnd x y) = MAnd (simplify x) (simplify y) simplify (MOr x y) = MOr (simplify x) (simplify y) simplify (MNot x) = MNot (simplify x) simplify x = x data TokenGroup op = One (Token op) | Group [TokenGroup op] deriving (Show, Eq) tokenGroups :: [Token op] -> [TokenGroup op] tokenGroups [] = [] tokenGroups (t:ts) = go t where go Open = let (gr, rest) = findClose ts in gr : tokenGroups rest go Close = tokenGroups ts -- not picky about missing Close go _ = One t : tokenGroups ts findClose :: [Token op] -> (TokenGroup op, [Token op]) findClose l = let (g, rest) = go [] l in (Group (reverse g), rest) where go c [] = (c, []) -- not picky about extra Close go c (t:ts) = handle t where handle Close = (c, ts) handle Open = let (c', ts') = go [] ts in go (Group (reverse c') : c) ts' handle _ = go (One t:c) ts {- Checks if a Matcher matches, using a supplied function to check - the value of Operations. -} match :: (op -> v -> Bool) -> Matcher op -> v -> Bool match a m v = go m where go MAny = True go (MAnd m1 m2) = go m1 && go m2 go (MOr m1 m2) = go m1 || go m2 go (MNot m1) = not $ go m1 go (MOp o) = a o v {- Runs a monadic Matcher, where Operations are actions in the monad. -} matchM :: Monad m => Matcher (v -> m Bool) -> v -> m Bool matchM m v = matchMrun m $ \o -> o v {- More generic running of a monadic Matcher, with full control over running - of Operations. Mostly useful in order to match on more than one - parameter. -} matchMrun :: forall o (m :: * -> *). Monad m => Matcher o -> (o -> m Bool) -> m Bool matchMrun m run = go m where go MAny = return True go (MAnd m1 m2) = go m1 <&&> go m2 go (MOr m1 m2) = go m1 <||> go m2 go (MNot m1) = liftM not (go m1) go (MOp o) = run o {- Checks if a matcher contains no limits. -} isEmpty :: Matcher a -> Bool isEmpty MAny = True isEmpty _ = False prop_matcher_sane :: Bool prop_matcher_sane = all (\m -> match dummy m ()) $ map generate [ [Operation True] , [] , [Operation False, Or, Operation True, Or, Operation False] , [Operation True, Or, Operation True] , [Operation True, And, Operation True] , [Not, Open, Operation True, And, Operation False, Close] , [Not, Open, Not, Open, Not, Operation False, Close, Close] , [Not, Open, Not, Open, Not, Open, Not, Operation True, Close, Close] , [Operation True, And, Not, Operation False] , [Operation True, Not, Operation False] , [Operation True, Not, Not, Not, Operation False] , [Operation True, Not, Not, Not, Operation False, And, Operation True] , [Operation True, Not, Not, Not, Operation False, Operation True] , [Not, Open, Operation True, And, Operation False, Close, And, Open, Open, Operation True, And, Operation False, Close, Or, Open, Operation True, And, Open, Not, Operation False, Close, Close, Close, And, Open, Not, Operation False, Close] ] where dummy b _ = b