module Idris.Elab.Data(elabData) where
import Idris.AbsSyntax
import Idris.ASTUtils
import Idris.DSL
import Idris.Error
import Idris.Delaborate
import Idris.Imports
import Idris.Elab.Term
import Idris.Coverage
import Idris.DataOpts
import Idris.Providers
import Idris.Primitives
import Idris.Inliner
import Idris.PartialEval
import Idris.DeepSeq
import Idris.Output (iputStrLn, pshow, iWarn, sendHighlighting)
import IRTS.Lang
import Idris.Elab.Type
import Idris.Elab.Utils
import Idris.Elab.Rewrite
import Idris.Elab.Value
import Idris.Core.TT
import Idris.Core.Elaborate hiding (Tactic(..))
import Idris.Core.Evaluate
import Idris.Core.Execute
import Idris.Core.Typecheck
import Idris.Core.CaseTree
import Idris.Docstrings
import Prelude hiding (id, (.))
import Control.Category
import Control.Applicative hiding (Const)
import Control.DeepSeq
import Control.Monad
import Control.Monad.State.Strict as State
import Data.List
import Data.Maybe
import Debug.Trace
import qualified Data.Map as Map
import qualified Data.Set as S
import qualified Data.Text as T
import Data.Char(isLetter, toLower)
import Data.List.Split (splitOn)
import Util.Pretty
warnLC :: FC -> Name -> Idris ()
warnLC fc n
= iWarn fc $ annName n <+> text "has a name which may be implicitly bound."
<> line <> text "This is likely to lead to problems!"
elabData :: ElabInfo -> SyntaxInfo -> Docstring (Either Err PTerm)-> [(Name, Docstring (Either Err PTerm))] -> FC -> DataOpts -> PData -> Idris ()
elabData info syn doc argDocs fc opts (PLaterdecl n nfc t_in)
= do let codata = Codata `elem` opts
logElab 1 (show (fc, doc))
checkUndefined fc n
when (implicitable (nsroot n)) $ warnLC fc n
(cty, _, t, inacc) <- buildType info syn fc [] n t_in
addIBC (IBCDef n)
updateContext (addTyDecl n (TCon 0 0) cty)
sendHighlighting [(nfc, AnnName n Nothing Nothing Nothing)]
elabData info syn doc argDocs fc opts (PDatadecl n nfc t_in dcons)
= do let codata = Codata `elem` opts
logElab 1 (show fc)
undef <- isUndefined fc n
when (implicitable (nsroot n)) $ warnLC fc n
(cty, ckind, t, inacc) <- buildType info syn fc [] n t_in
i <- getIState
checkDefinedAs fc n cty i
when undef $ updateContext (addTyDecl n (TCon 0 0) cty)
let cnameinfo = cinfo info (map cname dcons)
unique <- case getRetTy (normalise (tt_ctxt i) [] cty) of
UType UniqueType -> return True
UType _ -> return False
TType _ -> return False
rt -> tclift $ tfail (At fc (Elaborating "type constructor " n Nothing (Msg "Not a valid type constructor")))
cons <- mapM (elabCon cnameinfo syn n codata (getRetTy cty) ckind) dcons
ttag <- getName
let as = map (const (Left (Msg ""))) (getArgTys cty)
ctxt <- getContext
let params = findParams n (normalise ctxt [] cty) (map snd cons)
logElab 2 $ "Parameters : " ++ show params
addParamConstraints fc params cty cons
i <- getIState
putIState (i { idris_datatypes =
addDef n (TI (map fst cons) codata opts params [n])
(idris_datatypes i) })
addIBC (IBCDef n)
addIBC (IBCData n)
checkDocs fc argDocs t
doc' <- elabDocTerms info doc
argDocs' <- mapM (\(n, d) -> do d' <- elabDocTerms info d
return (n, d')) argDocs
addDocStr n doc' argDocs'
addIBC (IBCDoc n)
let metainf = DataMI params
addIBC (IBCMetaInformation n metainf)
updateContext (addDatatype (Data n ttag cty unique cons))
updateContext (setMetaInformation n metainf)
mapM_ totcheck (zip (repeat fc) (map fst cons))
case cons of
[(cn,ct)] -> setDetaggable cn >> setDetaggable n
>> addIBC (IBCOpt cn) >> addIBC (IBCOpt n)
_ -> return ()
when (DefaultEliminator `elem` opts) $
evalStateT (elabCaseFun True params n t dcons info) Map.empty
when (DefaultCaseFun `elem` opts) $
evalStateT (elabCaseFun False params n t dcons info) Map.empty
when (n /= sUN "=") $
elabRewriteLemma info n cty
sendHighlighting $ [(nfc, AnnName n Nothing Nothing Nothing)] ++
map (\(_, _, n, nfc, _, _, _) ->
(nfc, AnnName n Nothing Nothing Nothing))
dcons
where
checkDefinedAs fc n t i
= let defined = tclift $ tfail (At fc (AlreadyDefined n))
ctxt = tt_ctxt i in
case lookupDef n ctxt of
[] -> return ()
[TyDecl _ ty] ->
case converts ctxt [] t ty of
OK () -> case lookupCtxtExact n (idris_datatypes i) of
Nothing -> return ()
_ -> defined
_ -> defined
_ -> defined
cname (_, _, n, _, _, _, _) = n
cinfo :: ElabInfo -> [Name] -> ElabInfo
cinfo info ds
= let newps = params info
dsParams = map (\n -> (n, [])) ds
newb = addAlist dsParams (inblock info)
l = liftname info in
info { params = newps,
inblock = newb,
liftname = id
}
elabCon :: ElabInfo -> SyntaxInfo -> Name -> Bool ->
Type ->
Type ->
(Docstring (Either Err PTerm), [(Name, Docstring (Either Err PTerm))], Name, FC, PTerm, FC, [Name]) ->
Idris (Name, Type)
elabCon info syn tn codata expkind dkind (doc, argDocs, n, nfc, t_in, fc, forcenames)
= do checkUndefined fc n
when (implicitable (nsroot n)) $ warnLC fc n
logElab 2 $ show fc ++ ":Constructor " ++ show n ++ " : " ++ show t_in
(cty, ckind, t, inacc) <- buildType info syn fc [Constructor] n (if codata then mkLazy t_in else t_in)
ctxt <- getContext
let cty' = normalise ctxt [] cty
checkUniqueKind ckind expkind
tyIs n cty'
logElab 5 $ show fc ++ ":Constructor " ++ show n ++ " elaborated : " ++ show t
logElab 5 $ "Inaccessible args: " ++ show inacc
logElab 2 $ "---> " ++ show n ++ " : " ++ show cty
updateContext (addTyDecl n (DCon 0 0 False) cty)
addIBC (IBCDef n)
checkDocs fc argDocs t
doc' <- elabDocTerms info doc
argDocs' <- mapM (\(n, d) -> do d' <- elabDocTerms info d
return (n, d')) argDocs
addDocStr n doc' argDocs'
addIBC (IBCDoc n)
fputState (opt_inaccessible . ist_optimisation n) inacc
addIBC (IBCOpt n)
return (n, cty)
where
tyIs con (Bind n b sc) = tyIs con (substV (P Bound n Erased) sc)
tyIs con t | (P Bound n' _, _) <- unApply t
= if n' /= tn then
tclift $ tfail (At fc (Elaborating "constructor " con Nothing
(Msg ("Type level variable " ++ show n' ++ " is not " ++ show tn))))
else return ()
tyIs con t | (P _ n' _, _) <- unApply t
= if n' /= tn then tclift $ tfail (At fc (Elaborating "constructor " con Nothing (Msg (show n' ++ " is not " ++ show tn))))
else return ()
tyIs con t = tclift $ tfail (At fc (Elaborating "constructor " con Nothing (Msg (show t ++ " is not " ++ show tn))))
mkLazy (PPi pl n nfc ty sc)
= let ty' = if getTyName ty
then PApp fc (PRef fc [] (sUN "Delayed"))
[pexp (PRef fc [] (sUN "Infinite")),
pexp ty]
else ty in
PPi pl n nfc ty' (mkLazy sc)
mkLazy t = t
getTyName (PApp _ (PRef _ _ n) _) = n == nsroot tn
getTyName (PRef _ _ n) = n == nsroot tn
getTyName _ = False
getNamePos :: Int -> PTerm -> Name -> Maybe Int
getNamePos i (PPi _ n _ _ sc) x | n == x = Just i
| otherwise = getNamePos (i + 1) sc x
getNamePos _ _ _ = Nothing
checkUniqueKind (UType NullType) (UType NullType) = return ()
checkUniqueKind (UType NullType) _
= tclift $ tfail (At fc (UniqueKindError NullType n))
checkUniqueKind (UType UniqueType) (UType UniqueType) = return ()
checkUniqueKind (UType UniqueType) (UType AllTypes) = return ()
checkUniqueKind (UType UniqueType) _
= tclift $ tfail (At fc (UniqueKindError UniqueType n))
checkUniqueKind (UType AllTypes) (UType AllTypes) = return ()
checkUniqueKind (UType AllTypes) (UType UniqueType) = return ()
checkUniqueKind (UType AllTypes) _
= tclift $ tfail (At fc (UniqueKindError AllTypes n))
checkUniqueKind _ _ = return ()
addParamConstraints :: FC -> [Int] -> Type -> [(Name, Type)] -> Idris ()
addParamConstraints fc ps cty cons
= case getRetTy cty of
TType cvar -> mapM_ (addConConstraint ps cvar)
(map getParamNames cons)
_ -> return ()
where
getParamNames (n, ty) = (ty, getPs ty)
getPs (Bind n (Pi _ _ _) sc)
= getPs (substV (P Ref n Erased) sc)
getPs t | (f, args) <- unApply t
= paramArgs 0 args
paramArgs i (P _ n _ : args) | i `elem` ps = n : paramArgs (i + 1) args
paramArgs i (_ : args) = paramArgs (i + 1) args
paramArgs i [] = []
addConConstraint ps cvar (ty, pnames) = constraintTy ty
where
constraintTy (Bind n (Pi _ ty _) sc)
= case getRetTy ty of
TType avar -> do tit <- typeInType
when (not tit) $ do
ctxt <- getContext
let tv = next_tvar ctxt
let con = if n `elem` pnames
then ULE avar cvar
else ULT avar cvar
addConstraints fc (tv, [con])
addIBC (IBCConstraint fc con)
_ -> return ()
constraintTy t = return ()
type EliminatorState = StateT (Map.Map String Int) Idris
elabCaseFun :: Bool -> [Int] -> Name -> PTerm ->
[(Docstring (Either Err PTerm), [(Name, Docstring (Either Err PTerm))], Name, FC, PTerm, FC, [Name])] ->
ElabInfo -> EliminatorState ()
elabCaseFun ind paramPos n ty cons info = do
elimLog "Elaborating case function"
put (Map.fromList $ zip (concatMap (\(_, p, _, _, ty, _, _) -> (map show $ boundNamesIn ty) ++ map (show . fst) p) cons ++ (map show $ boundNamesIn ty)) (repeat 0))
let (cnstrs, _) = splitPi ty
let (splittedTy@(pms, idxs)) = splitPms cnstrs
generalParams <- namePis False pms
motiveIdxs <- namePis False idxs
let motive = mkMotive n paramPos generalParams motiveIdxs
consTerms <- mapM (\(c@(_, _, cnm, _, _, _, _)) -> do
let casefunt = if ind then "elim_" else "case_"
name <- freshName $ casefunt ++ simpleName cnm
consTerm <- extractConsTerm c generalParams
return (name, expl, consTerm)) cons
scrutineeIdxs <- namePis False idxs
let motiveConstr = [(motiveName, expl, motive)]
let scrutinee = (scrutineeName, expl, applyCons n (interlievePos paramPos generalParams scrutineeIdxs 0))
let eliminatorTy = piConstr (generalParams ++ motiveConstr ++ consTerms ++ scrutineeIdxs ++ [scrutinee]) (applyMotive (map (\(n,_,_) -> PRef elimFC [] n) scrutineeIdxs) (PRef elimFC [] scrutineeName))
let eliminatorTyDecl = PTy (fmap (const (Left $ Msg "")) . parseDocstring . T.pack $ show n) [] defaultSyntax elimFC [TotalFn] elimDeclName elimFC eliminatorTy
let clauseConsElimArgs = map getPiName consTerms
let clauseGeneralArgs' = map getPiName generalParams ++ [motiveName] ++ clauseConsElimArgs
let clauseGeneralArgs = map (\arg -> pexp (PRef elimFC [] arg)) clauseGeneralArgs'
let elimSig = "-- case function signature: " ++ showTmImpls eliminatorTy
elimLog elimSig
eliminatorClauses <- mapM (\(cns, cnsElim) -> generateEliminatorClauses cns cnsElim clauseGeneralArgs generalParams) (zip cons clauseConsElimArgs)
let eliminatorDef = PClauses elimFC [TotalFn] elimDeclName eliminatorClauses
elimLog $ "-- case function definition: " ++ (show . showDeclImp verbosePPOption) eliminatorDef
State.lift $ idrisCatch (rec_elabDecl info EAll info eliminatorTyDecl)
(ierror . Elaborating "type declaration of " elimDeclName Nothing)
case eliminatorClauses of
[] -> State.lift $ solveDeferred elimFC elimDeclName
_ -> State.lift $ idrisCatch (rec_elabDecl info EAll info eliminatorDef)
(ierror . Elaborating "clauses of " elimDeclName Nothing)
where elimLog :: String -> EliminatorState ()
elimLog s = State.lift (logElab 2 s)
elimFC :: FC
elimFC = fileFC $ "(casefun " ++ show n ++ ")"
elimDeclName :: Name
elimDeclName = if ind then SN . ElimN $ n else SN . CaseN (FC' elimFC) $ n
applyNS :: Name -> [String] -> Name
applyNS n [] = n
applyNS n ns = sNS n ns
splitPi :: PTerm -> ([(Name, Plicity, PTerm)], PTerm)
splitPi = splitPi' []
where splitPi' :: [(Name, Plicity, PTerm)] -> PTerm -> ([(Name, Plicity, PTerm)], PTerm)
splitPi' acc (PPi pl n _ tyl tyr) = splitPi' ((n, pl, tyl):acc) tyr
splitPi' acc t = (reverse acc, t)
splitPms :: [(Name, Plicity, PTerm)] -> ([(Name, Plicity, PTerm)], [(Name, Plicity, PTerm)])
splitPms cnstrs = (map fst pms, map fst idxs)
where (pms, idxs) = partition (\c -> snd c `elem` paramPos) (zip cnstrs [0..])
isMachineGenerated :: Name -> Bool
isMachineGenerated (MN _ _) = True
isMachineGenerated _ = False
namePis :: Bool -> [(Name, Plicity, PTerm)] -> EliminatorState [(Name, Plicity, PTerm)]
namePis keepOld pms = do names <- mapM (mkPiName keepOld) pms
let oldNames = map fst names
let params = map snd names
return $ map (\(n, pl, ty) -> (n, pl, removeParamPis oldNames params ty)) params
mkPiName :: Bool -> (Name, Plicity, PTerm) -> EliminatorState (Name, (Name, Plicity, PTerm))
mkPiName keepOld (n, pl, piarg) | not (isMachineGenerated n) && keepOld = do return (n, (n, pl, piarg))
mkPiName _ (oldName, pl, piarg) = do name <- freshName $ keyOf piarg
return (oldName, (name, pl, piarg))
where keyOf :: PTerm -> String
keyOf (PRef _ _ name) | isLetter (nameStart name) = (toLower $ nameStart name):"__"
keyOf (PApp _ tyf _) = keyOf tyf
keyOf (PType _) = "ty__"
keyOf _ = "carg__"
nameStart :: Name -> Char
nameStart n = nameStart' (simpleName n)
where nameStart' :: String -> Char
nameStart' "" = ' '
nameStart' ns = head ns
simpleName :: Name -> String
simpleName (NS n _) = simpleName n
simpleName (MN i n) = str n ++ show i
simpleName n = show n
nameSpaces :: Name -> [String]
nameSpaces (NS _ ns) = map str ns
nameSpaces _ = []
freshName :: String -> EliminatorState Name
freshName key = do
nameMap <- get
let i = fromMaybe 0 (Map.lookup key nameMap)
let name = uniqueName (sUN (key ++ show i)) (map (\(nm, nb) -> sUN (nm ++ show nb)) $ Map.toList nameMap)
put $ Map.insert key (i+1) nameMap
return name
scrutineeName :: Name
scrutineeName = sUN "scrutinee"
scrutineeArgName :: Name
scrutineeArgName = sUN "scrutineeArg"
motiveName :: Name
motiveName = sUN "prop"
mkMotive :: Name -> [Int] -> [(Name, Plicity, PTerm)] -> [(Name, Plicity, PTerm)] -> PTerm
mkMotive n paramPos params indicies =
let scrutineeTy = (scrutineeArgName, expl, applyCons n (interlievePos paramPos params indicies 0))
in piConstr (indicies ++ [scrutineeTy]) (PType elimFC)
piConstr :: [(Name, Plicity, PTerm)] -> PTerm -> PTerm
piConstr [] ty = ty
piConstr ((n, pl, tyb):tyr) ty = PPi pl n elimFC tyb (piConstr tyr ty)
interlievePos :: [Int] -> [a] -> [a] -> Int -> [a]
interlievePos idxs [] l2 i = l2
interlievePos idxs l1 [] i = l1
interlievePos idxs (x:xs) l2 i | i `elem` idxs = x:(interlievePos idxs xs l2 (i+1))
interlievePos idxs l1 (y:ys) i = y:(interlievePos idxs l1 ys (i+1))
replaceParams :: [Int] -> [(Name, Plicity, PTerm)] -> PTerm -> PTerm
replaceParams paramPos params cns =
let (_, cnsResTy) = splitPi cns
in case cnsResTy of
PApp _ _ args ->
let oldParams = paramNamesOf 0 paramPos args
in removeParamPis oldParams params cns
_ -> cns
removeParamPis :: [Name] -> [(Name, Plicity, PTerm)] -> PTerm -> PTerm
removeParamPis oldParams params (PPi pl n fc tyb tyr) =
case findIndex (== n) oldParams of
Nothing -> (PPi pl n fc (removeParamPis oldParams params tyb) (removeParamPis oldParams params tyr))
Just i -> (removeParamPis oldParams params tyr)
removeParamPis oldParams params (PRef _ _ n) =
case findIndex (== n) oldParams of
Nothing -> (PRef elimFC [] n)
Just i -> let (newname,_,_) = params !! i in (PRef elimFC [] (newname))
removeParamPis oldParams params (PApp _ cns args) =
PApp elimFC (removeParamPis oldParams params cns) $ replaceParamArgs args
where replaceParamArgs :: [PArg] -> [PArg]
replaceParamArgs [] = []
replaceParamArgs (arg:args) =
case extractName (getTm arg) of
[] -> arg:replaceParamArgs args
[n] ->
case findIndex (== n) oldParams of
Nothing -> arg:replaceParamArgs args
Just i -> let (newname,_,_) = params !! i in arg {getTm = PRef elimFC [] newname}:replaceParamArgs args
removeParamPis oldParams params t = t
paramNamesOf :: Int -> [Int] -> [PArg] -> [Name]
paramNamesOf i paramPos [] = []
paramNamesOf i paramPos (arg:args) = (if i `elem` paramPos then extractName (getTm arg) else []) ++ paramNamesOf (i+1) paramPos args
extractName :: PTerm -> [Name]
extractName (PRef _ _ n) = [n]
extractName _ = []
splitArgPms :: PTerm -> ([PTerm], [PTerm])
splitArgPms (PApp _ f args) = splitArgPms' args
where splitArgPms' :: [PArg] -> ([PTerm], [PTerm])
splitArgPms' cnstrs = (map (getTm . fst) pms, map (getTm . fst) idxs)
where (pms, idxs) = partition (\c -> snd c `elem` paramPos) (zip cnstrs [0..])
splitArgPms _ = ([],[])
implicitIndexes :: (Docstring (Either Err PTerm), Name, PTerm, FC, [Name]) -> EliminatorState [(Name, Plicity, PTerm)]
implicitIndexes (cns@(doc, cnm, ty, fc, fs)) = do
i <- State.lift getIState
implargs' <- case lookupCtxt cnm (idris_implicits i) of
[] -> do fail $ "Error while showing implicits for " ++ show cnm
[args] -> do return args
_ -> do fail $ "Ambigous name for " ++ show cnm
let implargs = mapMaybe convertImplPi implargs'
let (_, cnsResTy) = splitPi ty
case cnsResTy of
PApp _ _ args ->
let oldParams = paramNamesOf 0 paramPos args
in return $ filter (\(n,_,_) -> not (n `elem` oldParams))implargs
_ -> return implargs
extractConsTerm :: (Docstring (Either Err PTerm), [(Name, Docstring (Either Err PTerm))], Name, FC, PTerm, FC, [Name]) -> [(Name, Plicity, PTerm)] -> EliminatorState PTerm
extractConsTerm (doc, argDocs, cnm, _, ty, fc, fs) generalParameters = do
let cons' = replaceParams paramPos generalParameters ty
let (args, resTy) = splitPi cons'
implidxs <- implicitIndexes (doc, cnm, ty, fc, fs)
consArgs <- namePis False args
let recArgs = findRecArgs consArgs
let recMotives = if ind then map applyRecMotive recArgs else []
let (_, consIdxs) = splitArgPms resTy
return $ piConstr (implidxs ++ consArgs ++ recMotives) (applyMotive consIdxs (applyCons cnm consArgs))
where applyRecMotive :: (Name, Plicity, PTerm) -> (Name, Plicity, PTerm)
applyRecMotive (n,_,ty) = (sUN $ "ih" ++ simpleName n, expl, applyMotive idxs (PRef elimFC [] n))
where (_, idxs) = splitArgPms ty
findRecArgs :: [(Name, Plicity, PTerm)] -> [(Name, Plicity, PTerm)]
findRecArgs [] = []
findRecArgs (ty@(_,_,PRef _ _ tn):rs) | simpleName tn == simpleName n = ty:findRecArgs rs
findRecArgs (ty@(_,_,PApp _ (PRef _ _ tn) _):rs) | simpleName tn == simpleName n = ty:findRecArgs rs
findRecArgs (ty:rs) = findRecArgs rs
applyCons :: Name -> [(Name, Plicity, PTerm)] -> PTerm
applyCons tn targs = PApp elimFC (PRef elimFC [] tn) (map convertArg targs)
convertArg :: (Name, Plicity, PTerm) -> PArg
convertArg (n, _, _) = pexp (PRef elimFC [] n)
applyMotive :: [PTerm] -> PTerm -> PTerm
applyMotive idxs t = PApp elimFC (PRef elimFC [] motiveName) (map pexp idxs ++ [pexp t])
getPiName :: (Name, Plicity, PTerm) -> Name
getPiName (name,_,_) = name
convertImplPi :: PArg -> Maybe (Name, Plicity, PTerm)
convertImplPi (PImp {getTm = t, pname = n}) = Just (n, expl, t)
convertImplPi _ = Nothing
generateEliminatorClauses :: (Docstring (Either Err PTerm), [(Name, Docstring (Either Err PTerm))], Name, FC, PTerm, FC, [Name]) -> Name -> [PArg] -> [(Name, Plicity, PTerm)] -> EliminatorState PClause
generateEliminatorClauses (doc, _, cnm, _, ty, fc, fs) cnsElim generalArgs generalParameters = do
let cons' = replaceParams paramPos generalParameters ty
let (args, resTy) = splitPi cons'
i <- State.lift getIState
implidxs <- implicitIndexes (doc, cnm, ty, fc, fs)
let (_, generalIdxs') = splitArgPms resTy
let generalIdxs = map pexp generalIdxs'
consArgs <- namePis False args
let lhsPattern = PApp elimFC (PRef elimFC [] elimDeclName) (generalArgs ++ generalIdxs ++ [pexp $ applyCons cnm consArgs])
let recArgs = findRecArgs consArgs
let recElims = if ind then map applyRecElim recArgs else []
let rhsExpr = PApp elimFC (PRef elimFC [] cnsElim) (map convertArg implidxs ++ map convertArg consArgs ++ recElims)
return $ PClause elimFC elimDeclName lhsPattern [] rhsExpr []
where applyRecElim :: (Name, Plicity, PTerm) -> PArg
applyRecElim (constr@(recCnm,_,recTy)) = pexp $ PApp elimFC (PRef elimFC [] elimDeclName) (generalArgs ++ map pexp idxs ++ [pexp $ PRef elimFC [] recCnm])
where (_, idxs) = splitArgPms recTy