{-| Module : Idris.Parser.Expr Description : Parse Expressions. License : BSD3 Maintainer : The Idris Community. -} {-# LANGUAGE FlexibleContexts, TupleSections #-} module Idris.Parser.Expr where import Idris.AbsSyntax import Idris.Core.TT import Idris.DSL import Idris.Options import Idris.Parser.Helpers import Idris.Parser.Ops import Prelude hiding (pi) import Control.Applicative import Control.Arrow (left) import Control.Monad import Control.Monad.State.Strict import Data.Function (on) import Data.List import Data.Maybe import Text.Megaparsec (()) import qualified Text.Megaparsec as P import qualified Text.Megaparsec.Char as P import qualified Text.Megaparsec.Expr as P -- | Allow implicit type declarations allowImp :: SyntaxInfo -> SyntaxInfo allowImp syn = syn { implicitAllowed = True, constraintAllowed = False } -- | Disallow implicit type declarations disallowImp :: SyntaxInfo -> SyntaxInfo disallowImp = scopedImp -- | Implicits hare are scoped rather than top level scopedImp :: SyntaxInfo -> SyntaxInfo scopedImp syn = syn { implicitAllowed = False, constraintAllowed = False } -- | Allow scoped constraint arguments allowConstr :: SyntaxInfo -> SyntaxInfo allowConstr syn = syn { constraintAllowed = True } {-| Parses an expression as a whole @ FullExpr ::= Expr EOF_t; @ -} fullExpr :: SyntaxInfo -> IdrisParser PTerm fullExpr syn = do x <- expr syn P.eof i <- get return $ debindApp syn (desugar syn i x) tryFullExpr :: SyntaxInfo -> IState -> String -> Either Err PTerm tryFullExpr syn st = left (Msg . show . parseErrorDoc) . runparser (fullExpr syn) st "" {- | Parses an expression @ Expr ::= Pi @ -} expr :: SyntaxInfo -> IdrisParser PTerm expr = pi {- | Parses an expression with possible operator applied @ OpExpr ::= {- Expression Parser with Operators based on Expr' -}; @ -} opExpr :: SyntaxInfo -> IdrisParser PTerm opExpr syn = do i <- get P.makeExprParser (expr' syn) (table (idris_infixes i)) {- | Parses either an internally defined expression or a user-defined one @ Expr' ::= "External (User-defined) Syntax" | InternalExpr; @ -} expr' :: SyntaxInfo -> IdrisParser PTerm expr' syn = P.try (externalExpr syn) <|> internalExpr syn "expression" {- | Parses a user-defined expression -} externalExpr :: SyntaxInfo -> IdrisParser PTerm externalExpr syn = do i <- get (expr, outerFC@(FC fn _ _)) <- withExtent $ extensions syn (syntaxRulesList $ syntax_rules i) return (mapPTermFC (fixFC outerFC) (fixFCH fn outerFC) expr) "user-defined expression" where -- Fix non-highlighting FCs by approximating with the span of the syntax application fixFC outer inner | inner `fcIn` outer = inner | otherwise = outer -- Fix highlighting FCs by making them useless, to avoid spurious highlights fixFCH fn outer inner | inner `fcIn` outer = inner | otherwise = FileFC fn {- | Parses a simple user-defined expression -} simpleExternalExpr :: SyntaxInfo -> IdrisParser PTerm simpleExternalExpr syn = do i <- get extensions syn (filter isSimple (syntaxRulesList $ syntax_rules i)) where isSimple (Rule (Expr x:xs) _ _) = False isSimple (Rule (SimpleExpr x:xs) _ _) = False isSimple (Rule [Keyword _] _ _) = True isSimple (Rule [Symbol _] _ _) = True isSimple (Rule (_:xs) _ _) = case last xs of Keyword _ -> True Symbol _ -> True _ -> False isSimple _ = False {- | Tries to parse a user-defined expression given a list of syntactic extensions -} extensions :: SyntaxInfo -> [Syntax] -> IdrisParser PTerm extensions syn rules = extension syn [] (filter isValid rules) "user-defined expression" where isValid :: Syntax -> Bool isValid (Rule _ _ AnySyntax) = True isValid (Rule _ _ PatternSyntax) = inPattern syn isValid (Rule _ _ TermSyntax) = not (inPattern syn) isValid (DeclRule _ _) = False data SynMatch = SynTm PTerm | SynBind FC Name -- ^ the FC is for highlighting information deriving Show extension :: SyntaxInfo -> [Maybe (Name, SynMatch)] -> [Syntax] -> IdrisParser PTerm extension syn ns rules = P.choice $ flip map (groupBy (ruleGroup `on` syntaxSymbols) rules) $ \rs -> case head rs of -- can never be [] Rule (symb:_) _ _ -> P.try $ do n <- extensionSymbol symb extension syn (n : ns) [Rule ss t ctx | (Rule (_:ss) t ctx) <- rs] -- If we have more than one Rule in this bucket, our grammar is -- nondeterministic. Rule [] ptm _ -> return (flatten (updateSynMatch (mapMaybe id ns) ptm)) where ruleGroup [] [] = True ruleGroup (s1:_) (s2:_) = s1 == s2 ruleGroup _ _ = False extensionSymbol :: SSymbol -> IdrisParser (Maybe (Name, SynMatch)) extensionSymbol (Keyword n) = Nothing <$ keyword (show n) extensionSymbol (Expr n) = do tm <- expr syn return $ Just (n, SynTm tm) extensionSymbol (SimpleExpr n) = do tm <- simpleExpr syn return $ Just (n, SynTm tm) extensionSymbol (Binding n) = do (b, fc) <- withExtent name return $ Just (n, SynBind fc b) extensionSymbol (Symbol s) = Nothing <$ highlight AnnKeyword (symbol s) flatten :: PTerm -> PTerm -- flatten application flatten (PApp fc (PApp _ f as) bs) = flatten (PApp fc f (as ++ bs)) flatten t = t updateSynMatch = update where updateB :: [(Name, SynMatch)] -> (Name, FC) -> (Name, FC) updateB ns (n, fc) = case lookup n ns of Just (SynBind tfc t) -> (t, tfc) _ -> (n, fc) update :: [(Name, SynMatch)] -> PTerm -> PTerm update ns (PRef fc hls n) = case lookup n ns of Just (SynTm t) -> t _ -> PRef fc hls n update ns (PPatvar fc n) = uncurry (flip PPatvar) $ updateB ns (n, fc) update ns (PLam fc n nfc ty sc) = let (n', nfc') = updateB ns (n, nfc) in PLam fc n' nfc' (update ns ty) (update (dropn n ns) sc) update ns (PPi p n fc ty sc) = let (n', nfc') = updateB ns (n, fc) in PPi (updTacImp ns p) n' nfc' (update ns ty) (update (dropn n ns) sc) update ns (PLet fc rc n nfc ty val sc) = let (n', nfc') = updateB ns (n, nfc) in PLet fc rc n' nfc' (update ns ty) (update ns val) (update (dropn n ns) sc) update ns (PApp fc t args) = PApp fc (update ns t) (map (fmap (update ns)) args) update ns (PAppBind fc t args) = PAppBind fc (update ns t) (map (fmap (update ns)) args) update ns (PMatchApp fc n) = let (n', nfc') = updateB ns (n, fc) in PMatchApp nfc' n' update ns (PIfThenElse fc c t f) = PIfThenElse fc (update ns c) (update ns t) (update ns f) update ns (PCase fc c opts) = PCase fc (update ns c) (map (pmap (update ns)) opts) update ns (PRewrite fc by eq tm mty) = PRewrite fc by (update ns eq) (update ns tm) (fmap (update ns) mty) update ns (PPair fc hls p l r) = PPair fc hls p (update ns l) (update ns r) update ns (PDPair fc hls p l t r) = PDPair fc hls p (update ns l) (update ns t) (update ns r) update ns (PAs fc n t) = PAs fc (fst $ updateB ns (n, NoFC)) (update ns t) update ns (PAlternative ms a as) = PAlternative ms a (map (update ns) as) update ns (PHidden t) = PHidden (update ns t) update ns (PGoal fc r n sc) = PGoal fc (update ns r) n (update ns sc) update ns (PDoBlock ds) = PDoBlock $ map (upd ns) ds where upd :: [(Name, SynMatch)] -> PDo -> PDo upd ns (DoExp fc t) = DoExp fc (update ns t) upd ns (DoBind fc n nfc t) = DoBind fc n nfc (update ns t) upd ns (DoLet fc rc n nfc ty t) = DoLet fc rc n nfc (update ns ty) (update ns t) upd ns (DoBindP fc i t ts) = DoBindP fc (update ns i) (update ns t) (map (\(l,r) -> (update ns l, update ns r)) ts) upd ns (DoLetP fc i t ts) = DoLetP fc (update ns i) (update ns t) (map (\(l,r) -> (update ns l, update ns r)) ts) upd ns (DoRewrite fc h) = DoRewrite fc (update ns h) update ns (PIdiom fc t) = PIdiom fc $ update ns t update ns (PMetavar fc n) = uncurry (flip PMetavar) $ updateB ns (n, fc) update ns (PProof tacs) = PProof $ map (updTactic ns) tacs update ns (PTactics tacs) = PTactics $ map (updTactic ns) tacs update ns (PDisamb nsps t) = PDisamb nsps $ update ns t update ns (PUnifyLog t) = PUnifyLog $ update ns t update ns (PNoImplicits t) = PNoImplicits $ update ns t update ns (PQuasiquote tm mty) = PQuasiquote (update ns tm) (fmap (update ns) mty) update ns (PUnquote t) = PUnquote $ update ns t update ns (PQuoteName n res fc) = let (n', fc') = (updateB ns (n, fc)) in PQuoteName n' res fc' update ns (PRunElab fc t nsp) = PRunElab fc (update ns t) nsp update ns (PConstSugar fc t) = PConstSugar fc $ update ns t -- PConstSugar probably can't contain anything substitutable, but it's hard to track update ns t = t updTactic :: [(Name, SynMatch)] -> PTactic -> PTactic -- handle all the ones with Names explicitly, then use fmap for the rest with PTerms updTactic ns (Intro ns') = Intro $ map (fst . updateB ns . (, NoFC)) ns' updTactic ns (Focus n) = Focus . fst $ updateB ns (n, NoFC) updTactic ns (Refine n bs) = Refine (fst $ updateB ns (n, NoFC)) bs updTactic ns (Claim n t) = Claim (fst $ updateB ns (n, NoFC)) (update ns t) updTactic ns (MatchRefine n) = MatchRefine (fst $ updateB ns (n, NoFC)) updTactic ns (LetTac n t) = LetTac (fst $ updateB ns (n, NoFC)) (update ns t) updTactic ns (LetTacTy n ty tm) = LetTacTy (fst $ updateB ns (n, NoFC)) (update ns ty) (update ns tm) updTactic ns (ProofSearch rec prover depth top psns hints) = ProofSearch rec prover depth (fmap (fst . updateB ns . (, NoFC)) top) (map (fst . updateB ns . (, NoFC)) psns) (map (fst . updateB ns . (, NoFC)) hints) updTactic ns (Try l r) = Try (updTactic ns l) (updTactic ns r) updTactic ns (TSeq l r) = TSeq (updTactic ns l) (updTactic ns r) updTactic ns (GoalType s tac) = GoalType s $ updTactic ns tac updTactic ns (TDocStr (Left n)) = TDocStr . Left . fst $ updateB ns (n, NoFC) updTactic ns t = fmap (update ns) t updTacImp ns (TacImp o st scr r) = TacImp o st (update ns scr) r updTacImp _ x = x dropn :: Name -> [(Name, a)] -> [(Name, a)] dropn n [] = [] dropn n ((x,t) : xs) | n == x = xs | otherwise = (x,t):dropn n xs {- | Parses a (normal) built-in expression @ InternalExpr ::= UnifyLog | RecordType | SimpleExpr | Lambda | QuoteGoal | Let | If | RewriteTerm | CaseExpr | DoBlock | App ; @ -} internalExpr :: SyntaxInfo -> IdrisParser PTerm internalExpr syn = unifyLog syn <|> runElab syn <|> disamb syn <|> noImplicits syn <|> recordType syn <|> if_ syn <|> lambda syn <|> quoteGoal syn <|> let_ syn <|> rewriteTerm syn <|> doBlock syn <|> caseExpr syn <|> app syn "expression" {- | Parses the "impossible" keyword @ Impossible ::= 'impossible' @ -} impossible :: IdrisParser PTerm impossible = PImpossible <$ keyword "impossible" {- | Parses a case expression @ CaseExpr ::= 'case' Expr 'of' OpenBlock CaseOption+ CloseBlock; @ -} caseExpr :: SyntaxInfo -> IdrisParser PTerm caseExpr syn = do keyword "case" (scr, fc) <- withExtent $ expr syn keyword "of" opts <- indentedBlock1 (caseOption syn) return (PCase fc scr opts) "case expression" {- | Parses a case in a case expression @ CaseOption ::= Expr (Impossible | '=>' Expr) Terminator ; @ -} caseOption :: SyntaxInfo -> IdrisParser (PTerm, PTerm) caseOption syn = do lhs <- expr (disallowImp (syn { inPattern = True })) r <- impossible <|> symbol "=>" *> expr syn return (lhs, r) "case option" warnTacticDeprecation :: FC -> IdrisParser () warnTacticDeprecation fc = parserWarning fc (Just NoOldTacticDeprecationWarnings) (Msg "This style of tactic proof is deprecated. See %runElab for the replacement.") {- | Parses a proof block @ ProofExpr ::= 'proof' OpenBlock Tactic'* CloseBlock ; @ -} proofExpr :: SyntaxInfo -> IdrisParser PTerm proofExpr syn = do kw <- extent $ keyword "proof" ts <- indentedBlock1 (tactic syn) warnTacticDeprecation kw return $ PProof ts "proof block" {- | Parses a tactics block @ TacticsExpr := 'tactics' OpenBlock Tactic'* CloseBlock ; @ -} tacticsExpr :: SyntaxInfo -> IdrisParser PTerm tacticsExpr syn = do kw <- extent $ keyword "tactics" ts <- indentedBlock1 (tactic syn) warnTacticDeprecation kw return $ PTactics ts "tactics block" {- | Parses a simple expression @ SimpleExpr ::= {- External (User-defined) Simple Expression -} | '?' Name | % 'implementation' | 'Refl' ('{' Expr '}')? | ProofExpr | TacticsExpr | FnName | Idiom | List | Alt | Bracketed | Constant | Type | 'Void' | Quasiquote | NameQuote | Unquote | '_' ; @ -} simpleExpr :: SyntaxInfo -> IdrisParser PTerm simpleExpr syn = P.try (simpleExternalExpr syn) <|> do (x, FC f (l, c) end) <- P.try (lchar '?' *> withExtent name) return (PMetavar (FC f (l, c-1) end) x) <|> do lchar '%'; fc <- extent $ reserved "implementation"; return (PResolveTC fc) <|> do lchar '%'; fc <- extent $ reserved "instance" parserWarning fc Nothing $ Msg "The use of %instance is deprecated, use %implementation instead." return (PResolveTC fc) <|> do reserved "elim_for"; (t, fc) <- withExtent $ fnName; return (PRef fc [] (SN $ ElimN t)) <|> proofExpr syn <|> tacticsExpr syn <|> P.try (do fc <- extent (reserved "Type*"); return $ PUniverse fc AllTypes) <|> do fc <- extent $ reserved "AnyType"; return $ PUniverse fc AllTypes <|> PType <$> extent (reserved "Type") <|> do fc <- extent $ reserved "UniqueType"; return $ PUniverse fc UniqueType <|> do fc <- extent $ reserved "NullType"; return $ PUniverse fc NullType <|> do (c, cfc) <- withExtent constant return (modifyConst syn cfc (PConstant cfc c)) <|> do symbol "'"; (str, fc) <- withExtent name return (PApp fc (PRef fc [] (sUN "Symbol_")) [pexp (PConstant NoFC (Str (show str)))]) <|> do (x, fc) <- withExtent fnName if inPattern syn then P.option (PRef fc [fc] x) (do reservedOp "@" (s, fcIn) <- withExtent $ simpleExpr syn return (PAs fcIn x s)) else return (PRef fc [fc] x) <|> idiom syn <|> listExpr syn <|> alt syn <|> do reservedOp "!" (s, fc) <- withExtent $ simpleExpr syn return (PAppBind fc s []) <|> bracketed (disallowImp syn) <|> quasiquote syn <|> namequote syn <|> unquote syn <|> do lchar '_'; return Placeholder "expression" {- |Parses an expression in parentheses @ Bracketed ::= '(' Bracketed' @ -} bracketed :: SyntaxInfo -> IdrisParser PTerm bracketed syn = do (FC fn (sl, sc) _) <- extent (lchar '(') "parenthesized expression" bracketed' (FC fn (sl, sc) (sl, sc+1)) (syn { withAppAllowed = True }) {- |Parses the rest of an expression in braces @ Bracketed' ::= ')' | Expr ')' | ExprList ')' | DependentPair ')' | Operator Expr ')' | Expr Operator ')' ; @ -} bracketed' :: FC -> SyntaxInfo -> IdrisParser PTerm bracketed' open syn = do fc <- extent (addExtent open *> lchar ')') return $ PTrue fc TypeOrTerm <|> P.try (dependentPair TypeOrTerm [] open syn) <|> P.try (do (opName, fc) <- withExtent operatorName guardNotPrefix opName e <- expr syn lchar ')' return $ PLam fc (sMN 1000 "ARG") NoFC Placeholder (PApp fc (PRef fc [] opName) [pexp (PRef fc [] (sMN 1000 "ARG")), pexp e])) <|> P.try (simpleExpr syn >>= \l -> P.try (do (opName, fc) <- withExtent operatorName lchar ')' return $ PLam fc (sMN 1000 "ARG") NoFC Placeholder (PApp fc (PRef fc [] opName) [pexp l, pexp (PRef fc [] (sMN 1000 "ARG"))])) <|> bracketedExpr syn open l) <|> do l <- expr (allowConstr syn) bracketedExpr (allowConstr syn) open l where justPrefix :: FixDecl -> Maybe Name justPrefix (Fix (PrefixN _) opName) = Just (sUN opName) justPrefix _ = Nothing guardNotPrefix :: Name -> IdrisParser () guardNotPrefix opName = do guard $ opName /= sUN "-" guard $ opName /= sUN "!" ops <- idris_infixes <$> get guard . not . (opName `elem`) . mapMaybe justPrefix $ ops {-| Parses the rest of a dependent pair after '(' or '(Expr **' -} dependentPair :: PunInfo -> [(PTerm, Maybe (FC, PTerm), FC)] -> FC -> SyntaxInfo -> IdrisParser PTerm dependentPair pun prev openFC syn = if null prev then nametypePart <|> namePart else case pun of IsType -> nametypePart <|> namePart <|> exprPart True IsTerm -> exprPart False TypeOrTerm -> nametypePart <|> namePart <|> exprPart False where nametypePart = do (ln, lnfc, colonFC) <- P.try $ do (ln, lnfc) <- withExtent name colonFC <- extent (lchar ':') return (ln, lnfc, colonFC) lty <- expr' syn starsFC <- extent $ reservedOp "**" dependentPair IsType ((PRef lnfc [] ln, Just (colonFC, lty), starsFC):prev) openFC syn namePart = P.try $ do (ln, lnfc) <- withExtent name starsFC <- extent $ reservedOp "**" dependentPair pun ((PRef lnfc [] ln, Nothing, starsFC):prev) openFC syn exprPart isEnd = do e <- expr syn sepFCE <- let stars = (Left <$> extent (reservedOp "**")) ending = (Right <$> extent (lchar ')')) in if isEnd then ending else stars <|> ending case sepFCE of Left starsFC -> dependentPair IsTerm ((e, Nothing, starsFC):prev) openFC syn Right closeFC -> return (mkPDPairs pun openFC closeFC (reverse prev) e) mkPDPairs pun openFC closeFC ((e, cfclty, starsFC):bnds) r = (PDPair openFC ([openFC] ++ maybe [] ((: []) . fst) cfclty ++ [starsFC, closeFC] ++ (=<<) (\(_,cfclty,sfc) -> maybe [] ((: []) . fst) cfclty ++ [sfc]) bnds) pun e (maybe Placeholder snd cfclty) (mergePDPairs pun starsFC bnds r)) mergePDPairs pun starsFC' [] r = r mergePDPairs pun starsFC' ((e, cfclty, starsFC):bnds) r = PDPair starsFC' [] pun e (maybe Placeholder snd cfclty) (mergePDPairs pun starsFC bnds r) -- | Parse the contents of parentheses, after an expression has been parsed. bracketedExpr :: SyntaxInfo -> FC -> PTerm -> IdrisParser PTerm bracketedExpr syn openParenFC e = do lchar ')'; return e <|> do exprs <- some (do comma <- extent (lchar ',') r <- expr syn return (r, comma)) closeParenFC <- extent (lchar ')') let hilite = [openParenFC, closeParenFC] ++ map snd exprs return $ PPair openParenFC hilite TypeOrTerm e (mergePairs exprs) <|> do starsFC <- extent $ reservedOp "**" dependentPair IsTerm [(e, Nothing, starsFC)] openParenFC syn "end of bracketed expression" where mergePairs :: [(PTerm, FC)] -> PTerm mergePairs [(t, fc)] = t mergePairs ((t, fc):rs) = PPair fc [] TypeOrTerm t (mergePairs rs) -- bit of a hack here. If the integer doesn't fit in an Int, treat it as a -- big integer, otherwise try fromInteger and the constants as alternatives. -- a better solution would be to fix fromInteger to work with Integer, as the -- name suggests, rather than Int {-| Finds optimal type for integer constant -} modifyConst :: SyntaxInfo -> FC -> PTerm -> PTerm modifyConst syn fc (PConstant inFC (BI x)) | not (inPattern syn) = PConstSugar inFC $ -- wrap in original span for highlighting PAlternative [] FirstSuccess (PApp fc (PRef fc [] (sUN "fromInteger")) [pexp (PConstant NoFC (BI (fromInteger x)))] : consts) | otherwise = PConstSugar inFC $ PAlternative [] FirstSuccess consts where consts = [ PConstant inFC (BI x) , PConstant inFC (I (fromInteger x)) , PConstant inFC (B8 (fromInteger x)) , PConstant inFC (B16 (fromInteger x)) , PConstant inFC (B32 (fromInteger x)) , PConstant inFC (B64 (fromInteger x)) ] modifyConst syn fc x = x {- | Parses an alternative expression @ Alt ::= '(|' Expr_List '|)'; Expr_List ::= Expr' | Expr' ',' Expr_List ; @ -} alt :: SyntaxInfo -> IdrisParser PTerm alt syn = do symbol "(|"; alts <- P.sepBy1 (expr' (syn { withAppAllowed = False })) (lchar ','); symbol "|)" return (PAlternative [] FirstSuccess alts) {- | Parses a possibly hidden simple expression @ HSimpleExpr ::= '.' SimpleExpr | SimpleExpr ; @ -} hsimpleExpr :: SyntaxInfo -> IdrisParser PTerm hsimpleExpr syn = do lchar '.' e <- simpleExpr syn return $ PHidden e <|> simpleExpr syn "expression" {- | Parses a unification log expression UnifyLog ::= '%' 'unifyLog' SimpleExpr ; -} unifyLog :: SyntaxInfo -> IdrisParser PTerm unifyLog syn = do P.try $ highlight AnnKeyword $ lchar '%' *> reserved "unifyLog" PUnifyLog <$> simpleExpr syn "unification log expression" {- | Parses a new-style tactics expression RunTactics ::= '%' 'runElab' SimpleExpr ; -} runElab :: SyntaxInfo -> IdrisParser PTerm runElab syn = do P.try $ highlight AnnKeyword $ lchar '%' *> reserved "runElab" (tm, fc) <- withExtent $ simpleExpr syn return $ PRunElab fc tm (syn_namespace syn) "new-style tactics expression" {- | Parses a disambiguation expression Disamb ::= 'with' NameList Expr ; -} disamb :: SyntaxInfo -> IdrisParser PTerm disamb syn = do keyword "with" ns <- P.sepBy1 name (lchar ',') tm <- expr' syn return (PDisamb (map tons ns) tm) "namespace disambiguation expression" where tons (NS n s) = txt (show n) : s tons n = [txt (show n)] {- | Parses a no implicits expression @ NoImplicits ::= '%' 'noImplicits' SimpleExpr ; @ -} noImplicits :: SyntaxInfo -> IdrisParser PTerm noImplicits syn = do P.try (lchar '%' *> reserved "noImplicits") tm <- simpleExpr syn return (PNoImplicits tm) "no implicits expression" {- | Parses a function application expression @ App ::= 'mkForeign' Arg Arg* | MatchApp | SimpleExpr Arg* ; MatchApp ::= SimpleExpr '<==' FnName ; @ -} app :: SyntaxInfo -> IdrisParser PTerm app syn = (appExtent $ do f <- simpleExpr syn (do P.try $ reservedOp "<==" ff <- fnName return (\fc -> (PLet fc RigW (sMN 0 "match") NoFC f (PMatchApp fc ff) (PRef fc [] (sMN 0 "match")))) "matching application expression") <|> (do args <- many (do notEndApp; arg syn) wargs <- if withAppAllowed syn && not (inPattern syn) then many (do notEndApp; reservedOp "|"; expr' syn) else return [] case args of [] -> return $ \fc -> f _ -> return $ \fc -> (withApp fc (flattenFromInt fc f args) wargs))) "function application" where -- bit of a hack to deal with the situation where we're applying a -- literal to an argument, which we may want for obscure applications -- of fromInteger, and this will help disambiguate better. -- We know, at least, it won't be one of the constants! flattenFromInt fc (PAlternative _ x alts) args | Just i <- getFromInt alts = PApp fc (PRef fc [] (sUN "fromInteger")) (i : args) flattenFromInt fc f args = PApp fc f args withApp fc tm [] = tm withApp fc tm (a : as) = withApp fc (PWithApp fc tm a) as getFromInt ((PApp _ (PRef _ _ n) [a]) : _) | n == sUN "fromInteger" = Just a getFromInt (_ : xs) = getFromInt xs getFromInt _ = Nothing {-| Parses a function argument @ Arg ::= ImplicitArg | ConstraintArg | SimpleExpr ; @ -} arg :: SyntaxInfo -> IdrisParser PArg arg syn = implicitArg syn <|> constraintArg syn <|> do e <- simpleExpr syn return (pexp e) "function argument" {-| Parses an implicit function argument @ ImplicitArg ::= '{' Name ('=' Expr)? '}' ; @ -} implicitArg :: SyntaxInfo -> IdrisParser PArg implicitArg syn = do lchar '{' (n, nfc) <- withExtent name v <- P.option (PRef nfc [nfc] n) (do lchar '=' expr syn) lchar '}' return (pimp n v True) "implicit function argument" {-| Parses a constraint argument (for selecting a named interface implementation) > ConstraintArg ::= > '@{' Expr '}' > ; -} constraintArg :: SyntaxInfo -> IdrisParser PArg constraintArg syn = do symbol "@{" e <- expr syn symbol "}" return (pconst e) "constraint argument" {-| Parses a quasiquote expression (for building reflected terms using the elaborator) > Quasiquote ::= '`(' Expr ')' -} quasiquote :: SyntaxInfo -> IdrisParser PTerm quasiquote syn = (highlight AnnQuasiquote $ do highlight AnnKeyword $ symbol "`(" e <- expr syn { syn_in_quasiquote = (syn_in_quasiquote syn) + 1 , inPattern = False } g <- optional $ do highlight AnnKeyword $ symbol ":" expr syn { inPattern = False } -- don't allow antiquotes highlight AnnKeyword $ symbol ")" return $ PQuasiquote e g) "quasiquotation" {-| Parses an unquoting inside a quasiquotation (for building reflected terms using the elaborator) > Unquote ::= ',' Expr -} unquote :: SyntaxInfo -> IdrisParser PTerm unquote syn = (highlight AnnAntiquote $ do guard (syn_in_quasiquote syn > 0) highlight AnnKeyword $ symbol "~" e <- simpleExpr syn { syn_in_quasiquote = syn_in_quasiquote syn - 1 } return $ PUnquote e) "unquotation" {-| Parses a quotation of a name (for using the elaborator to resolve boring details) > NameQuote ::= '`{' Name '}' -} namequote :: SyntaxInfo -> IdrisParser PTerm namequote syn = highlight AnnQuasiquote ((P.try $ do highlight AnnKeyword $ symbol "`{{" (n, nfc) <- withExtent fnName highlight AnnKeyword $ symbol "}}" return (PQuoteName n False nfc)) <|> (do highlight AnnKeyword $ symbol "`{" (n, nfc) <- withExtent fnName highlight AnnKeyword $ symbol "}" return (PQuoteName n True nfc))) "quoted name" {-| Parses a record field setter expression @ RecordType ::= 'record' '{' FieldTypeList '}'; @ @ FieldTypeList ::= FieldType | FieldType ',' FieldTypeList ; @ @ FieldType ::= FnName '=' Expr ; @ -} data SetOrUpdate = FieldSet PTerm | FieldUpdate PTerm recordType :: SyntaxInfo -> IdrisParser PTerm recordType syn = do ((fgs, rec), fc) <- withExtent $ do keyword "record" lchar '{' fgs <- fieldGetOrSet lchar '}' rec <- optional (do notEndApp; simpleExpr syn) return (fgs, rec) case fgs of Left fields -> case rec of Nothing -> return (PLam fc (sMN 0 "fldx") NoFC Placeholder (applyAll fc fields (PRef fc [] (sMN 0 "fldx")))) Just v -> return (applyAll fc fields v) Right fields -> case rec of Nothing -> return (PLam fc (sMN 0 "fldx") NoFC Placeholder (getAll fc (reverse fields) (PRef fc [] (sMN 0 "fldx")))) Just v -> return (getAll fc (reverse fields) v) "record setting expression" where fieldSet :: IdrisParser ([Name], SetOrUpdate) fieldSet = do ns <- fieldGet (do lchar '=' e <- expr syn return (ns, FieldSet e)) <|> do symbol "$=" e <- expr syn return (ns, FieldUpdate e) "field setter" fieldGet :: IdrisParser [Name] fieldGet = P.sepBy1 fnName (symbol "->") fieldGetOrSet :: IdrisParser (Either [([Name], SetOrUpdate)] [Name]) fieldGetOrSet = P.try (Left <$> P.sepBy1 fieldSet (lchar ',')) <|> do f <- fieldGet return (Right f) applyAll :: FC -> [([Name], SetOrUpdate)] -> PTerm -> PTerm applyAll fc [] x = x applyAll fc ((ns, e) : es) x = applyAll fc es (doUpdate fc ns e x) doUpdate fc ns (FieldUpdate e) get = let get' = getAll fc (reverse ns) get in doUpdate fc ns (FieldSet (PApp fc e [pexp get'])) get doUpdate fc [n] (FieldSet e) get = PApp fc (PRef fc [] (mkType n)) [pexp e, pexp get] doUpdate fc (n : ns) e get = PApp fc (PRef fc [] (mkType n)) [pexp (doUpdate fc ns e (PApp fc (PRef fc [] n) [pexp get])), pexp get] getAll :: FC -> [Name] -> PTerm -> PTerm getAll fc [n] e = PApp fc (PRef fc [] n) [pexp e] getAll fc (n:ns) e = PApp fc (PRef fc [] n) [pexp (getAll fc ns e)] -- | Creates setters for record types on necessary functions mkType :: Name -> Name mkType (UN n) = sUN ("set_" ++ str n) mkType (MN 0 n) = sMN 0 ("set_" ++ str n) mkType (NS n s) = NS (mkType n) s {- | Parses a type signature @ TypeSig ::= ':' Expr ; @ @ TypeExpr ::= ConstraintList? Expr; @ -} typeExpr :: SyntaxInfo -> IdrisParser PTerm typeExpr syn = do cs <- if implicitAllowed syn then constraintList syn else return [] sc <- expr (allowConstr syn) return (bindList (\r -> PPi (constraint { pcount = r })) cs sc) "type signature" {- | Parses a lambda expression @ Lambda ::= '\\' TypeOptDeclList LambdaTail | '\\' SimpleExprList LambdaTail ; @ @ SimpleExprList ::= SimpleExpr | SimpleExpr ',' SimpleExprList ; @ @ LambdaTail ::= Impossible | '=>' Expr @ -} lambda :: SyntaxInfo -> IdrisParser PTerm lambda syn = do lchar '\\' "lambda expression" ((do xt <- P.try $ tyOptDeclList (disallowImp syn) (sc, fc) <- withExtent lambdaTail return (bindList (\r -> PLam fc) xt sc)) <|> (do ps <- P.sepBy (do (e, fc) <- withExtent $ simpleExpr (disallowImp (syn { inPattern = True })) return (fc, e)) (lchar ',') sc <- lambdaTail return (pmList (zip [0..] ps) sc))) "lambda expression" where pmList :: [(Int, (FC, PTerm))] -> PTerm -> PTerm pmList [] sc = sc pmList ((i, (fc, x)) : xs) sc = PLam fc (sMN i "lamp") NoFC Placeholder (PCase fc (PRef fc [] (sMN i "lamp")) [(x, pmList xs sc)]) lambdaTail :: IdrisParser PTerm lambdaTail = impossible <|> symbol "=>" *> expr syn {- | Parses a term rewrite expression @ RewriteTerm ::= 'rewrite' Expr ('==>' Expr)? 'in' Expr ; @ -} rewriteTerm :: SyntaxInfo -> IdrisParser PTerm rewriteTerm syn = do keyword "rewrite" (prf, fc) <- withExtent $ expr syn giving <- optional (do symbol "==>"; expr' syn) using <- optional (do reserved "using" n <- name return n) keyword "in"; sc <- expr syn return (PRewrite fc using prf sc giving) "term rewrite expression" {- |Parses a let binding @ Let ::= 'let' Name TypeSig'? '=' Expr 'in' Expr | 'let' Expr' '=' Expr' 'in' Expr TypeSig' ::= ':' Expr' ; @ -} let_ :: SyntaxInfo -> IdrisParser PTerm let_ syn = P.try (do keyword "let" ls <- indentedBlock (let_binding syn) keyword "in"; sc <- expr syn return (buildLets ls sc)) "let binding" where buildLets [] sc = sc buildLets ((fc, PRef nfc _ n, ty, v, []) : ls) sc = PLet fc RigW n nfc ty v (buildLets ls sc) buildLets ((fc, pat, ty, v, alts) : ls) sc = PCase fc v ((pat, buildLets ls sc) : alts) let_binding syn = do (pat, fc) <- withExtent $ expr' (syn { inPattern = True }) ty <- P.option Placeholder (do lchar ':'; expr' syn) lchar '=' v <- expr (syn { withAppAllowed = isVar pat }) ts <- P.option [] (do lchar '|' P.sepBy1 (do_alt syn) (lchar '|')) return (fc,pat,ty,v,ts) where isVar (PRef _ _ _) = True isVar _ = False {- | Parses a conditional expression @ If ::= 'if' Expr 'then' Expr 'else' Expr @ -} if_ :: SyntaxInfo -> IdrisParser PTerm if_ syn = (do keyword "if" (c, fc) <- withExtent $ expr syn keyword "then" t <- expr syn keyword "else" f <- expr syn return (PIfThenElse fc c t f)) "conditional expression" {- | Parses a quote goal @ QuoteGoal ::= 'quoteGoal' Name 'by' Expr 'in' Expr ; @ -} quoteGoal :: SyntaxInfo -> IdrisParser PTerm quoteGoal syn = do keyword "quoteGoal"; n <- name; keyword "by" r <- expr syn keyword "in" (sc, fc) <- withExtent $ expr syn return (PGoal fc r n sc) "quote goal expression" {- | Parses a dependent type signature @ Pi ::= PiOpts Static? Pi' @ @ Pi' ::= OpExpr ('->' Pi)? | '(' TypeDeclList ')' '->' Pi | '{' TypeDeclList '}' '->' Pi | '{' 'auto' TypeDeclList '}' '->' Pi | '{' 'default' SimpleExpr TypeDeclList '}' '->' Pi ; @ -} bindsymbol opts st syn = do symbol "->" return (Exp opts st False RigW) explicitPi opts st syn = do xt <- P.try (lchar '(' *> typeDeclList syn <* lchar ')') binder <- bindsymbol opts st syn sc <- expr (allowConstr syn) return (bindList (\r -> PPi (binder { pcount = r })) xt sc) autoImplicit opts st syn = do keyword "auto" when (st == Static) $ fail "auto implicits can not be static" xt <- typeDeclList syn lchar '}' symbol "->" sc <- expr (allowConstr syn) return (bindList (\r -> PPi (TacImp [] Dynamic (PTactics [ProofSearch True True 100 Nothing [] []]) r)) xt sc) defaultImplicit opts st syn = do keyword "default" when (st == Static) $ fail "default implicits can not be static" ist <- get script' <- simpleExpr syn let script = debindApp syn . desugar syn ist $ script' xt <- typeDeclList syn lchar '}' symbol "->" sc <- expr (allowConstr syn) return (bindList (\r -> PPi (TacImp [] Dynamic script r)) xt sc) normalImplicit opts st syn = do xt <- typeDeclList syn <* lchar '}' symbol "->" cs <- constraintList syn sc <- expr syn let (im,cl) = if implicitAllowed syn then (Imp opts st False (Just (Impl False True False)) True RigW, constraint) else (Imp opts st False (Just (Impl False False False)) True RigW, Imp opts st False (Just (Impl True False False)) True RigW) return (bindList (\r -> PPi (im { pcount = r })) xt (bindList (\r -> PPi (cl { pcount = r })) cs sc)) constraintPi opts st syn = do cs <- constraintList1 syn sc <- expr syn if implicitAllowed syn then return (bindList (\r -> PPi constraint { pcount = r }) cs sc) else return (bindList (\r -> PPi (Imp opts st False (Just (Impl True False False)) True r)) cs sc) implicitPi opts st syn = autoImplicit opts st syn <|> defaultImplicit opts st syn <|> normalImplicit opts st syn unboundPi opts st syn = do x <- opExpr syn (do binder <- bindsymbol opts st syn sc <- expr syn return (PPi binder (sUN "__pi_arg") NoFC x sc)) <|> return x -- This is used when we need to disambiguate from a constraint list unboundPiNoConstraint opts st syn = do x <- opExpr syn (do binder <- bindsymbol opts st syn sc <- expr syn P.notFollowedBy $ reservedOp "=>" return (PPi binder (sUN "__pi_arg") NoFC x sc)) <|> do P.notFollowedBy $ reservedOp "=>" return x pi :: SyntaxInfo -> IdrisParser PTerm pi syn = do opts <- piOpts syn st <- static explicitPi opts st syn <|> P.try (do lchar '{'; implicitPi opts st syn) <|> if constraintAllowed syn then P.try (unboundPiNoConstraint opts st syn) <|> constraintPi opts st syn else unboundPi opts st syn "dependent type signature" {- | Parses Possible Options for Pi Expressions @ PiOpts ::= '.'? @ -} piOpts :: SyntaxInfo -> IdrisParser [ArgOpt] piOpts syn | implicitAllowed syn = lchar '.' *> return [InaccessibleArg] <|> return [] piOpts syn = return [] {- | Parses a type constraint list @ ConstraintList ::= '(' Expr_List ')' '=>' | Expr '=>' ; @ -} constraintList :: SyntaxInfo -> IdrisParser [(RigCount, Name, FC, PTerm)] constraintList syn = P.try (constraintList1 syn) <|> return [] constraintList1 :: SyntaxInfo -> IdrisParser [(RigCount, Name, FC, PTerm)] constraintList1 syn = P.try (do lchar '(' tys <- P.sepBy1 nexpr (lchar ',') lchar ')' reservedOp "=>" return tys) <|> P.try (do t <- opExpr (disallowImp syn) reservedOp "=>" return [(RigW, defname, NoFC, t)]) "type constraint list" where nexpr = P.try (do (n, fc) <- withExtent name; lchar ':' e <- expr (disallowImp syn) return (RigW, n, fc, e)) <|> do e <- expr (disallowImp syn) return (RigW, defname, NoFC, e) defname = sMN 0 "constraint" {- | Parses a type declaration list @ TypeDeclList ::= FunctionSignatureList | NameList TypeSig ; @ @ FunctionSignatureList ::= Name TypeSig | Name TypeSig ',' FunctionSignatureList ; @ -} typeDeclList :: SyntaxInfo -> IdrisParser [(RigCount, Name, FC, PTerm)] typeDeclList syn = P.try (P.sepBy1 (do rig <- P.option RigW rigCount (x, xfc) <- withExtent fnName lchar ':' t <- typeExpr (disallowImp syn) return (rig, x, xfc, t)) (lchar ',')) <|> do ns <- P.sepBy1 (withExtent name) (lchar ',') lchar ':' t <- typeExpr (disallowImp syn) return (map (\(x, xfc) -> (RigW, x, xfc, t)) ns) "type declaration list" where rigCount = do lchar '1'; return Rig1 <|> do lchar '0'; return Rig0 {- | Parses a type declaration list with optional parameters @ TypeOptDeclList ::= NameOrPlaceholder TypeSig? | NameOrPlaceholder TypeSig? ',' TypeOptDeclList ; @ @ NameOrPlaceHolder ::= Name | '_'; @ -} tyOptDeclList :: SyntaxInfo -> IdrisParser [(RigCount, Name, FC, PTerm)] tyOptDeclList syn = P.sepBy1 (do (x, fc) <- withExtent nameOrPlaceholder t <- P.option Placeholder (do lchar ':' expr syn) return (RigW, x, fc, t)) (lchar ',') "type declaration list" where nameOrPlaceholder :: IdrisParser Name nameOrPlaceholder = fnName <|> sMN 0 "underscore" <$ reservedOp "_" "name or placeholder" {- | Parses a list literal expression e.g. [1,2,3] or a comprehension [ (x, y) | x <- xs , y <- ys ] @ ListExpr ::= '[' ']' | '[' Expr '|' DoList ']' | '[' ExprList ']' ; @ @ DoList ::= Do | Do ',' DoList ; @ @ ExprList ::= Expr | Expr ',' ExprList ; @ -} listExpr :: SyntaxInfo -> IdrisParser PTerm listExpr syn = do (FC f (l, c) _) <- extent (lchar '[') (do (FC _ _ (l', c')) <- extent (lchar ']') "end of list expression" return (mkNil (FC f (l, c) (l', c')))) <|> (do (x, fc) <- withExtent (expr (syn { withAppAllowed = False })) "expression" (do P.try (lchar '|') "list comprehension" qs <- P.sepBy1 (do_ syn) (lchar ',') lchar ']' return (PDoBlock (map addGuard qs ++ [DoExp fc (PApp fc (PRef fc [] (sUN "pure")) [pexp x])]))) <|> (do xs <- many (do commaFC <- extent (lchar ',') "list element" elt <- expr syn return (elt, commaFC)) rbrackFC <- extent (lchar ']') "end of list expression" return (mkList fc rbrackFC ((x, (FC f (l, c) (l, c+1))) : xs)))) "list expression" where mkNil :: FC -> PTerm mkNil fc = PRef fc [fc] (sUN "Nil") mkList :: FC -> FC -> [(PTerm, FC)] -> PTerm mkList errFC nilFC [] = PRef nilFC [nilFC] (sUN "Nil") mkList errFC nilFC ((x, fc) : xs) = PApp errFC (PRef fc [fc] (sUN "::")) [pexp x, pexp (mkList errFC nilFC xs)] addGuard :: PDo -> PDo addGuard (DoExp fc e) = DoExp fc (PApp fc (PRef fc [] (sUN "guard")) [pexp e]) addGuard x = x {- | Parses a do-block @ Do' ::= Do KeepTerminator; @ @ DoBlock ::= 'do' OpenBlock Do'+ CloseBlock ; @ -} doBlock :: SyntaxInfo -> IdrisParser PTerm doBlock syn = do keyword "do" PDoBlock <$> indentedBlock1 (do_ syn) "do block" {- | Parses an expression inside a do block @ Do ::= 'let' Name TypeSig'? '=' Expr | 'let' Expr' '=' Expr | 'rewrite Expr | Name '<-' Expr | Expr' '<-' Expr | Expr ; @ -} do_ :: SyntaxInfo -> IdrisParser PDo do_ syn = P.try (do keyword "let" (i, ifc) <- withExtent name ty' <- P.optional (do lchar ':' expr' syn) reservedOp "=" (e, fc) <- withExtent $ expr (syn { withAppAllowed = False }) -- If there is an explicit type, this can’t be a pattern-matching let, so do not parse alternatives P.option (DoLet fc RigW i ifc (fromMaybe Placeholder ty') e) (do lchar '|' when (isJust ty') $ fail "a pattern-matching let may not have an explicit type annotation" ts <- P.sepBy1 (do_alt (syn { withAppAllowed = False })) (lchar '|') return (DoLetP fc (PRef ifc [ifc] i) e ts))) <|> P.try (do keyword "let" i <- expr' syn reservedOp "=" (e, fc) <- withExtent $ expr (syn { withAppAllowed = False }) P.option (DoLetP fc i e []) (do lchar '|' ts <- P.sepBy1 (do_alt (syn { withAppAllowed = False })) (lchar '|') return (DoLetP fc i e ts))) <|> P.try (do (sc, fc) <- withExtent (keyword "rewrite" *> expr syn) return (DoRewrite fc sc)) <|> P.try (do (i, ifc) <- withExtent name symbol "<-" (e, fc) <- withExtent $ expr (syn { withAppAllowed = False }); P.option (DoBind fc i ifc e) (do lchar '|' ts <- P.sepBy1 (do_alt (syn { withAppAllowed = False })) (lchar '|') return (DoBindP fc (PRef ifc [ifc] i) e ts))) <|> P.try (do i <- expr' syn symbol "<-" (e, fc) <- withExtent $ expr (syn { withAppAllowed = False }); P.option (DoBindP fc i e []) (do lchar '|' ts <- P.sepBy1 (do_alt (syn { withAppAllowed = False })) (lchar '|') return (DoBindP fc i e ts))) <|> do (e, fc) <- withExtent $ expr syn return (DoExp fc e) "do block expression" do_alt syn = do l <- expr' syn P.option (Placeholder, l) (do symbol "=>" r <- expr' syn return (l, r)) {- | Parses an expression in idiom brackets @ Idiom ::= '[|' Expr '|]'; @ -} idiom :: SyntaxInfo -> IdrisParser PTerm idiom syn = do symbol "[|" (e, fc) <- withExtent $ expr (syn { withAppAllowed = False }) symbol "|]" return (PIdiom fc e) "expression in idiom brackets" {- |Parses a constant or literal expression @ Constant ::= 'Integer' | 'Int' | 'Char' | 'Double' | 'String' | 'Bits8' | 'Bits16' | 'Bits32' | 'Bits64' | Float_t | Natural_t | VerbatimString_t | String_t | Char_t ; @ -} constants :: [(String, Idris.Core.TT.Const)] constants = [ ("Integer", AType (ATInt ITBig)) , ("Int", AType (ATInt ITNative)) , ("Char", AType (ATInt ITChar)) , ("Double", AType ATFloat) , ("String", StrType) , ("prim__WorldType", WorldType) , ("prim__TheWorld", TheWorld) , ("Bits8", AType (ATInt (ITFixed IT8))) , ("Bits16", AType (ATInt (ITFixed IT16))) , ("Bits32", AType (ATInt (ITFixed IT32))) , ("Bits64", AType (ATInt (ITFixed IT64))) ] -- | Parse a constant and its source span constant :: Parsing m => m Idris.Core.TT.Const constant = P.choice [ ty <$ reserved name | (name, ty) <- constants ] <|> P.try (Fl <$> float) <|> BI <$> natural <|> Str <$> verbatimStringLiteral <|> Str <$> stringLiteral <|> P.try (Ch <$> charLiteral) --Currently ambigous with symbols "constant or literal" {- | Parses a verbatim multi-line string literal (triple-quoted) @ VerbatimString_t ::= '\"\"\"' ~'\"\"\"' '\"'* '\"\"\"' ; @ -} verbatimStringLiteral :: Parsing m => m String verbatimStringLiteral = token $ do P.try $ string "\"\"\"" str <- P.manyTill P.anyChar $ P.try (string "\"\"\"") moreQuotes <- P.many $ P.char '"' return $ str ++ moreQuotes {- | Parses a static modifier @ Static ::= '%static' ; @ -} static :: IdrisParser Static static = Static <$ reserved "%static" <|> return Dynamic "static modifier" {- | Parses a tactic script @ Tactic ::= 'intro' NameList? | 'intros' | 'refine' Name Imp+ | 'mrefine' Name | 'rewrite' Expr | 'induction' Expr | 'equiv' Expr | 'let' Name ':' Expr' '=' Expr | 'let' Name '=' Expr | 'focus' Name | 'exact' Expr | 'applyTactic' Expr | 'reflect' Expr | 'fill' Expr | 'try' Tactic '|' Tactic | '{' TacticSeq '}' | 'compute' | 'trivial' | 'solve' | 'attack' | 'state' | 'term' | 'undo' | 'qed' | 'abandon' | ':' 'q' ; Imp ::= '?' | '_'; TacticSeq ::= Tactic ';' Tactic | Tactic ';' TacticSeq ; @ -} -- | A specification of the arguments that tactics can take data TacticArg = NameTArg -- ^ Names: n1, n2, n3, ... n | ExprTArg | AltsTArg | StringLitTArg -- The FIXMEs are Issue #1766 in the issue tracker. -- https://github.com/idris-lang/Idris-dev/issues/1766 -- | A list of available tactics and their argument requirements tactics :: [([String], Maybe TacticArg, SyntaxInfo -> IdrisParser PTactic)] tactics = [ (["intro"], Nothing, const $ -- FIXME syntax for intro (fresh name) do ns <- P.sepBy (spaced name) (lchar ','); return $ Intro ns) , noArgs ["intros"] Intros , noArgs ["unfocus"] Unfocus , (["refine"], Just ExprTArg, const $ do n <- spaced fnName imps <- many imp return $ Refine n imps) , (["claim"], Nothing, \syn -> do n <- indentGt *> name goal <- indentGt *> expr syn return $ Claim n goal) , (["mrefine"], Just ExprTArg, const $ do n <- spaced fnName return $ MatchRefine n) , expressionTactic ["rewrite"] Rewrite , expressionTactic ["case"] CaseTac , expressionTactic ["induction"] Induction , expressionTactic ["equiv"] Equiv , (["let"], Nothing, \syn -> -- FIXME syntax for let do n <- (indentGt *> name) (do indentGt *> lchar ':' ty <- indentGt *> expr' syn indentGt *> lchar '=' t <- indentGt *> expr syn i <- get return $ LetTacTy n (desugar syn i ty) (desugar syn i t)) <|> (do indentGt *> lchar '=' t <- indentGt *> expr syn i <- get return $ LetTac n (desugar syn i t))) , (["focus"], Just ExprTArg, const $ do n <- spaced name return $ Focus n) , expressionTactic ["exact"] Exact , expressionTactic ["applyTactic"] ApplyTactic , expressionTactic ["byReflection"] ByReflection , expressionTactic ["reflect"] Reflect , expressionTactic ["fill"] Fill , (["try"], Just AltsTArg, \syn -> do t <- spaced (tactic syn) lchar '|' t1 <- spaced (tactic syn) return $ Try t t1) , noArgs ["compute"] Compute , noArgs ["trivial"] Trivial , noArgs ["unify"] DoUnify , (["search"], Nothing, const $ do depth <- P.option 10 natural return (ProofSearch True True (fromInteger depth) Nothing [] [])) , noArgs ["implementation"] TCImplementation , noArgs ["solve"] Solve , noArgs ["attack"] Attack , noArgs ["state", ":state"] ProofState , noArgs ["term", ":term"] ProofTerm , noArgs ["undo", ":undo"] Undo , noArgs ["qed", ":qed"] Qed , noArgs ["abandon", ":q"] Abandon , noArgs ["skip"] Skip , noArgs ["sourceLocation"] SourceFC , expressionTactic [":e", ":eval"] TEval , expressionTactic [":t", ":type"] TCheck , expressionTactic [":search"] TSearch , (["fail"], Just StringLitTArg, const $ do msg <- stringLiteral return $ TFail [Idris.Core.TT.TextPart msg]) , ([":doc"], Just ExprTArg, const $ do whiteSpace doc <- (Right <$> constant) <|> (Left <$> fnName) P.eof return (TDocStr doc)) ] where expressionTactic names tactic = (names, Just ExprTArg, \syn -> do t <- spaced (expr syn) i <- get return $ tactic (desugar syn i t)) noArgs names tactic = (names, Nothing, const (return tactic)) spaced parser = indentGt *> parser imp :: IdrisParser Bool imp = do lchar '?'; return False <|> do lchar '_'; return True tactic :: SyntaxInfo -> IdrisParser PTactic tactic syn = P.choice [ do P.choice (map reserved names); parser syn | (names, _, parser) <- tactics ] <|> do lchar '{' t <- tactic syn; lchar ';'; ts <- P.sepBy1 (tactic syn) (lchar ';') lchar '}' return $ TSeq t (mergeSeq ts) <|> ((lchar ':' >> empty) "prover command") "tactic" where mergeSeq :: [PTactic] -> PTactic mergeSeq [t] = t mergeSeq (t:ts) = TSeq t (mergeSeq ts) -- | Parses a tactic as a whole fullTactic :: SyntaxInfo -> IdrisParser PTactic fullTactic syn = do t <- tactic syn P.eof return t