module Text.Parser.Core import public Control.Delayed import Data.List ||| Description of a language's grammar. The `tok` parameter is the type ||| of tokens, and the `consumes` flag is True if the language is guaranteed ||| to be non-empty - that is, successfully parsing the language is guaranteed ||| to consume some input. public export data Grammar : (tok : Type) -> (consumes : Bool) -> Type -> Type where Empty : (val : ty) -> Grammar tok False ty Terminal : String -> (tok -> Maybe a) -> Grammar tok True a NextIs : String -> (tok -> Bool) -> Grammar tok False tok EOF : Grammar tok False () Fail : Bool -> String -> Grammar tok c ty Commit : Grammar tok False () MustWork : Grammar tok c a -> Grammar tok c a SeqEat : {c2 : _} -> Grammar tok True a -> Inf (a -> Grammar tok c2 b) -> Grammar tok True b SeqEmpty : {c1, c2 : _} -> Grammar tok c1 a -> (a -> Grammar tok c2 b) -> Grammar tok (c1 || c2) b ThenEat : {c2 : _} -> Grammar tok True () -> Inf (Grammar tok c2 b) -> Grammar tok True b ThenEmpty : {c1, c2 : _} -> Grammar tok c1 () -> Grammar tok c2 b -> Grammar tok (c1 || c2) b Alt : {c1, c2 : _} -> Grammar tok c1 ty -> Grammar tok c2 ty -> Grammar tok (c1 && c2) ty ||| Sequence two grammars. If either consumes some input, the sequence is ||| guaranteed to consume some input. If the first one consumes input, the ||| second is allowed to be recursive (because it means some input has been ||| consumed and therefore the input is smaller) public export %inline %tcinline (>>=) : {c1, c2 : Bool} -> Grammar tok c1 a -> inf c1 (a -> Grammar tok c2 b) -> Grammar tok (c1 || c2) b (>>=) {c1 = False} = SeqEmpty (>>=) {c1 = True} = SeqEat ||| Sequence two grammars. If either consumes some input, the sequence is ||| guaranteed to consume some input. If the first one consumes input, the ||| second is allowed to be recursive (because it means some input has been ||| consumed and therefore the input is smaller) public export %inline %tcinline (>>) : {c1, c2 : Bool} -> Grammar tok c1 () -> inf c1 (Grammar tok c2 a) -> Grammar tok (c1 || c2) a (>>) {c1 = False} = ThenEmpty (>>) {c1 = True} = ThenEat ||| Sequence two grammars. If either consumes some input, the sequence is ||| guaranteed to consume input. This is an explicitly non-infinite version ||| of `>>=`. export seq : {c1, c2 : _} -> Grammar tok c1 a -> (a -> Grammar tok c2 b) -> Grammar tok (c1 || c2) b seq = SeqEmpty ||| Sequence a grammar followed by the grammar it returns. export join : {c1, c2 : Bool} -> Grammar tok c1 (Grammar tok c2 a) -> Grammar tok (c1 || c2) a join {c1 = False} p = SeqEmpty p id join {c1 = True} p = SeqEat p id ||| Give two alternative grammars. If both consume, the combination is ||| guaranteed to consume. export (<|>) : {c1, c2 : _} -> Grammar tok c1 ty -> Grammar tok c2 ty -> Grammar tok (c1 && c2) ty (<|>) = Alt ||| Allows the result of a grammar to be mapped to a different value. export {c : _} -> Functor (Grammar tok c) where map f (Empty val) = Empty (f val) map f (Fail fatal msg) = Fail fatal msg map f (MustWork g) = MustWork (map f g) map f (Terminal msg g) = Terminal msg (\t => map f (g t)) map f (Alt x y) = Alt (map f x) (map f y) map f (SeqEat act next) = SeqEat act (\val => map f (next val)) map f (SeqEmpty act next) = SeqEmpty act (\val => map f (next val)) map f (ThenEat act next) = ThenEat act (map f next) map f (ThenEmpty act next) = ThenEmpty act (map f next) -- The remaining constructors (NextIs, EOF, Commit) have a fixed type, -- so a sequence must be used. map {c = False} f p = SeqEmpty p (Empty . f) ||| Sequence a grammar with value type `a -> b` and a grammar ||| with value type `a`. If both succeed, apply the function ||| from the first grammar to the value from the second grammar. ||| Guaranteed to consume if either grammar consumes. export (<*>) : {c1, c2 : _} -> Grammar tok c1 (a -> b) -> Inf (Grammar tok c2 a) -> Grammar tok (c1 || c2) b (<*>) {c1 = False} x y = SeqEmpty x (\f => map f y) (<*>) {c1 = True } x y = SeqEmpty x (\f => map f (Force y)) ||| Sequence two grammars. If both succeed, use the value of the first one. ||| Guaranteed to consume if either grammar consumes. export (<*) : {c1, c2 : _} -> Grammar tok c1 a -> Inf (Grammar tok c2 b) -> Grammar tok (c1 || c2) a (<*) x y = map const x <*> y ||| Sequence two grammars. If both succeed, use the value of the second one. ||| Guaranteed to consume if either grammar consumes. export (*>) : {c1, c2 : _} -> Grammar tok c1 a -> Inf (Grammar tok c2 b) -> Grammar tok (c1 || c2) b (*>) x y = map (const id) x <*> y ||| Produce a grammar that can parse a different type of token by providing a ||| function converting the new token type into the original one. export mapToken : (a -> b) -> Grammar b c ty -> Grammar a c ty mapToken f (Empty val) = Empty val mapToken f (Terminal msg g) = Terminal msg (g . f) mapToken f (NextIs msg g) = SeqEmpty (NextIs msg (g . f)) (Empty . f) mapToken f EOF = EOF mapToken f (Fail fatal msg) = Fail fatal msg mapToken f (MustWork g) = MustWork (mapToken f g) mapToken f Commit = Commit mapToken f (SeqEat act next) = SeqEat (mapToken f act) (\x => mapToken f (next x)) mapToken f (SeqEmpty act next) = SeqEmpty (mapToken f act) (\x => mapToken f (next x)) mapToken f (ThenEat act next) = ThenEat (mapToken f act) (mapToken f next) mapToken f (ThenEmpty act next) = ThenEmpty (mapToken f act) (mapToken f next) mapToken f (Alt x y) = Alt (mapToken f x) (mapToken f y) ||| Always succeed with the given value. export pure : (val : ty) -> Grammar tok False ty pure = Empty ||| Check whether the next token satisfies a predicate export nextIs : String -> (tok -> Bool) -> Grammar tok False tok nextIs = NextIs ||| Look at the next token in the input export peek : Grammar tok False tok peek = nextIs "Unrecognised token" (const True) ||| Succeeds if running the predicate on the next token returns Just x, ||| returning x. Otherwise fails. export terminal : String -> (tok -> Maybe a) -> Grammar tok True a terminal = Terminal ||| Always fail with a message export fail : String -> Grammar tok c ty fail = Fail False export fatalError : String -> Grammar tok c ty fatalError = Fail True ||| Succeed if the input is empty export eof : Grammar tok False () eof = EOF ||| Commit to an alternative; if the current branch of an alternative ||| fails to parse, no more branches will be tried export commit : Grammar tok False () commit = Commit ||| If the parser fails, treat it as a fatal error export mustWork : Grammar tok c ty -> Grammar tok c ty mustWork = MustWork data ParseResult : List tok -> (consumes : Bool) -> Type -> Type where Failure : {xs : List tok} -> (committed : Bool) -> (fatal : Bool) -> (err : String) -> (rest : List tok) -> ParseResult xs c ty EmptyRes : (committed : Bool) -> (val : ty) -> (more : List tok) -> ParseResult more False ty NonEmptyRes : {xs : List tok} -> (committed : Bool) -> (val : ty) -> (more : List tok) -> ParseResult (x :: xs ++ more) c ty -- Take the result of an alternative branch, reset the commit flag to -- the commit flag from the outer alternative, and weaken the 'consumes' -- flag to take both alternatives into account weakenRes : {whatever, c : Bool} -> {xs : List tok} -> (com' : Bool) -> ParseResult xs c ty -> ParseResult xs (whatever && c) ty weakenRes com' (Failure com fatal msg ts) = Failure com' fatal msg ts weakenRes {whatever=True} com' (EmptyRes com val xs) = EmptyRes com' val xs weakenRes {whatever=False} com' (EmptyRes com val xs) = EmptyRes com' val xs weakenRes com' (NonEmptyRes {xs} com val more) = NonEmptyRes {xs} com' val more doParse : (commit : Bool) -> (act : Grammar tok c ty) -> (xs : List tok) -> ParseResult xs c ty -- doParse com xs act with (sizeAccessible xs) doParse com (Empty val) xs = EmptyRes com val xs doParse com (Fail fatal str) [] = Failure com fatal str [] doParse com (Fail fatal str) (x :: xs) = Failure com fatal str (x :: xs) doParse com Commit xs = EmptyRes True () xs doParse com (MustWork g) xs = let p' = doParse com g xs in case p' of Failure com' _ msg ts => Failure com' True msg ts res => res doParse com (Terminal err f) [] = Failure com False "End of input" [] doParse com (Terminal err f) (x :: xs) = maybe (Failure com False err (x :: xs)) (\a => NonEmptyRes com {xs=[]} a xs) (f x) doParse com EOF [] = EmptyRes com () [] doParse com EOF (x :: xs) = Failure com False "Expected end of input" (x :: xs) doParse com (NextIs err f) [] = Failure com False "End of input" [] doParse com (NextIs err f) (x :: xs) = if f x then EmptyRes com x (x :: xs) else Failure com False err (x :: xs) doParse com (Alt {c1} {c2} x y) xs = let p' = doParse False x xs in case p' of Failure com' fatal msg ts => if com' || fatal -- If the alternative had committed, don't try the -- other branch (and reset commit flag) then Failure com fatal msg ts else weakenRes {whatever = c1} com (doParse False y xs) -- Successfully parsed the first option, so use the outer commit flag EmptyRes _ val xs => EmptyRes com val xs NonEmptyRes {xs=xs'} _ val more => NonEmptyRes {xs=xs'} com val more doParse com (SeqEmpty {c1} {c2} act next) xs = let p' = assert_total (doParse {c = c1} com act xs) in case p' of Failure com fatal msg ts => Failure com fatal msg ts EmptyRes com val xs => assert_total (doParse com (next val) xs) NonEmptyRes {x} {xs=ys} com val more => case (assert_total (doParse com (next val) more)) of Failure com' fatal msg ts => Failure com' fatal msg ts EmptyRes com' val _ => NonEmptyRes {xs=ys} com' val more NonEmptyRes {x=x1} {xs=xs1} com' val more' => rewrite appendAssociative (x :: ys) (x1 :: xs1) more' in NonEmptyRes {xs = ys ++ (x1 :: xs1)} com' val more' doParse com (SeqEat act next) xs with (doParse com act xs) doParse com (SeqEat act next) xs | Failure com' fatal msg ts = Failure com' fatal msg ts doParse com (SeqEat act next) (x :: (ys ++ more)) | (NonEmptyRes {xs=ys} com' val more) = let p' = assert_total (doParse com' (next val) more) in case p' of Failure com' fatal msg ts => Failure com' fatal msg ts EmptyRes com' val _ => NonEmptyRes {xs=ys} com' val more NonEmptyRes {x=x1} {xs=xs1} com' val more' => rewrite appendAssociative (x :: ys) (x1 :: xs1) more' in NonEmptyRes {xs = ys ++ (x1 :: xs1)} com' val more' doParse com (ThenEmpty {c1} {c2} act next) xs = let p' = assert_total (doParse {c = c1} com act xs) in case p' of Failure com fatal msg ts => Failure com fatal msg ts EmptyRes com val xs => assert_total (doParse com next xs) NonEmptyRes {x} {xs=ys} com val more => case (assert_total (doParse com next more)) of Failure com' fatal msg ts => Failure com' fatal msg ts EmptyRes com' val _ => NonEmptyRes {xs=ys} com' val more NonEmptyRes {x=x1} {xs=xs1} com' val more' => rewrite appendAssociative (x :: ys) (x1 :: xs1) more' in NonEmptyRes {xs = ys ++ (x1 :: xs1)} com' val more' doParse com (ThenEat act next) xs with (doParse com act xs) doParse com (ThenEat act next) xs | Failure com' fatal msg ts = Failure com' fatal msg ts doParse com (ThenEat act next) (x :: (ys ++ more)) | (NonEmptyRes {xs=ys} com' val more) = let p' = assert_total (doParse com' next more) in case p' of Failure com' fatal msg ts => Failure com' fatal msg ts EmptyRes com' val _ => NonEmptyRes {xs=ys} com' val more NonEmptyRes {x=x1} {xs=xs1} com' val more' => rewrite appendAssociative (x :: ys) (x1 :: xs1) more' in NonEmptyRes {xs = ys ++ (x1 :: xs1)} com' val more' -- This next line is not strictly necessary, but it stops the coverage -- checker taking a really long time and eating lots of memory... -- doParse _ _ _ = Failure True True "Help the coverage checker!" [] public export data ParseError tok = Error String (List tok) ||| Parse a list of tokens according to the given grammar. If successful, ||| returns a pair of the parse result and the unparsed tokens (the remaining ||| input). export parse : {c : _} -> (act : Grammar tok c ty) -> (xs : List tok) -> Either (ParseError tok) (ty, List tok) parse act xs = case doParse False act xs of Failure _ _ msg ts => Left (Error msg ts) EmptyRes _ val rest => pure (val, rest) NonEmptyRes _ val rest => pure (val, rest)