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Rename GF.Compile.Compute.ConcreteNew to GF.Compile.Compute.Concrete

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This commit is contained in:
John J. Camilleri
2021-07-01 14:21:29 +02:00
parent d5c6aec3ec
commit 71d99b9ecb
10 changed files with 654 additions and 657 deletions
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2
gf.cabal
View File

@@ -178,7 +178,7 @@ library
GF.Command.TreeOperations
GF.Compile.CFGtoPGF
GF.Compile.CheckGrammar
GF.Compile.Compute.ConcreteNew
GF.Compile.Compute.Concrete
GF.Compile.Compute.Predef
GF.Compile.Compute.Value
GF.Compile.ExampleBased

4
src/compiler/GF/Command/SourceCommands.hs
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@@ -18,7 +18,7 @@ import GF.Grammar.Parser (runP, pExp)
import GF.Grammar.ShowTerm
import GF.Grammar.Lookup (allOpers,allOpersTo)
import GF.Compile.Rename(renameSourceTerm)
import qualified GF.Compile.Compute.ConcreteNew as CN(normalForm,resourceValues)
import GF.Compile.Compute.Concrete(normalForm,resourceValues)
import GF.Compile.TypeCheck.RConcrete as TC(inferLType,ppType)
import GF.Infra.Dependencies(depGraph)
import GF.Infra.CheckM(runCheck)
@@ -259,7 +259,7 @@ checkComputeTerm os sgr t =
((t,_),_) <- runCheck $ do t <- renameSourceTerm sgr mo t
inferLType sgr [] t
let opts = modifyFlags (\fs->fs{optTrace=isOpt "trace" os})
t1 = CN.normalForm (CN.resourceValues opts sgr) (L NoLoc identW) t
t1 = normalForm (resourceValues opts sgr) (L NoLoc identW) t
t2 = evalStr t1
checkPredefError t2
where

46
src/compiler/GF/Compile/CheckGrammar.hs
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@@ -5,7 +5,7 @@
-- Stability : (stable)
-- Portability : (portable)
--
-- > CVS $Date: 2005/11/11 23:24:33 $
-- > CVS $Date: 2005/11/11 23:24:33 $
-- > CVS $Author: aarne $
-- > CVS $Revision: 1.31 $
--
@@ -29,7 +29,7 @@ import GF.Infra.Option
import GF.Compile.TypeCheck.Abstract
import GF.Compile.TypeCheck.RConcrete
import qualified GF.Compile.TypeCheck.ConcreteNew as CN
import qualified GF.Compile.Compute.ConcreteNew as CN
import qualified GF.Compile.Compute.Concrete as CN
import GF.Grammar
import GF.Grammar.Lexer
@@ -74,9 +74,9 @@ checkRestrictedInheritance cwd sgr (name,mo) = checkInModule cwd mo NoLoc empty
let (incl,excl) = partition (isInherited mi) (Map.keys (jments m))
let incld c = Set.member c (Set.fromList incl)
let illegal c = Set.member c (Set.fromList excl)
let illegals = [(f,is) |
let illegals = [(f,is) |
(f,cs) <- allDeps, incld f, let is = filter illegal cs, not (null is)]
case illegals of
case illegals of
[] -> return ()
cs -> checkWarn ("In inherited module" <+> i <> ", dependence of excluded constants:" $$
nest 2 (vcat [f <+> "on" <+> fsep is | (f,is) <- cs]))
@@ -92,12 +92,12 @@ checkCompleteGrammar opts cwd gr (am,abs) (cm,cnc) = checkInModule cwd cnc NoLoc
-- check that all abstract constants are in concrete; build default lin and lincats
jsc <- foldM checkAbs jsc (Map.toList jsa)
return (cm,cnc{jments=jsc})
where
checkAbs js i@(c,info) =
case info of
AbsFun (Just (L loc ty)) _ _ _
AbsFun (Just (L loc ty)) _ _ _
-> do let mb_def = do
let (cxt,(_,i),_) = typeForm ty
info <- lookupIdent i js
@@ -136,11 +136,11 @@ checkCompleteGrammar opts cwd gr (am,abs) (cm,cnc) = checkInModule cwd cnc NoLoc
checkWarn ("no linearization type for" <+> c <> ", inserting default {s : Str}")
return $ Map.insert c (CncCat (Just (L NoLoc defLinType)) Nothing Nothing Nothing Nothing) js
_ -> return js
checkCnc js (c,info) =
case info of
CncFun _ d mn mf -> case lookupOrigInfo gr (am,c) of
Ok (_,AbsFun (Just (L _ ty)) _ _ _) ->
Ok (_,AbsFun (Just (L _ ty)) _ _ _) ->
do (cont,val) <- linTypeOfType gr cm ty
let linty = (snd (valCat ty),cont,val)
return $ Map.insert c (CncFun (Just linty) d mn mf) js
@@ -159,14 +159,14 @@ checkCompleteGrammar opts cwd gr (am,abs) (cm,cnc) = checkInModule cwd cnc NoLoc
_ -> return $ Map.insert c info js
-- | General Principle: only Just-values are checked.
-- | General Principle: only Just-values are checked.
-- A May-value has always been checked in its origin module.
checkInfo :: Options -> FilePath -> SourceGrammar -> SourceModule -> Ident -> Info -> Check Info
checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
checkReservedId c
case info of
AbsCat (Just (L loc cont)) ->
mkCheck loc "the category" $
AbsCat (Just (L loc cont)) ->
mkCheck loc "the category" $
checkContext gr cont
AbsFun (Just (L loc typ0)) ma md moper -> do
@@ -181,7 +181,7 @@ checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
CncCat mty mdef mref mpr mpmcfg -> do
mty <- case mty of
Just (L loc typ) -> chIn loc "linearization type of" $
Just (L loc typ) -> chIn loc "linearization type of" $
(if False --flag optNewComp opts
then do (typ,_) <- CN.checkLType (CN.resourceValues opts gr) typ typeType
typ <- computeLType gr [] typ
@@ -191,19 +191,19 @@ checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
return (Just (L loc typ)))
Nothing -> return Nothing
mdef <- case (mty,mdef) of
(Just (L _ typ),Just (L loc def)) ->
(Just (L _ typ),Just (L loc def)) ->
chIn loc "default linearization of" $ do
(def,_) <- checkLType gr [] def (mkFunType [typeStr] typ)
return (Just (L loc def))
_ -> return Nothing
mref <- case (mty,mref) of
(Just (L _ typ),Just (L loc ref)) ->
(Just (L _ typ),Just (L loc ref)) ->
chIn loc "reference linearization of" $ do
(ref,_) <- checkLType gr [] ref (mkFunType [typ] typeStr)
return (Just (L loc ref))
_ -> return Nothing
mpr <- case mpr of
(Just (L loc t)) ->
(Just (L loc t)) ->
chIn loc "print name of" $ do
(t,_) <- checkLType gr [] t typeStr
return (Just (L loc t))
@@ -212,13 +212,13 @@ checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
CncFun mty mt mpr mpmcfg -> do
mt <- case (mty,mt) of
(Just (cat,cont,val),Just (L loc trm)) ->
(Just (cat,cont,val),Just (L loc trm)) ->
chIn loc "linearization of" $ do
(trm,_) <- checkLType gr [] trm (mkFunType (map (\(_,_,ty) -> ty) cont) val) -- erases arg vars
return (Just (L loc trm))
_ -> return mt
mpr <- case mpr of
(Just (L loc t)) ->
(Just (L loc t)) ->
chIn loc "print name of" $ do
(t,_) <- checkLType gr [] t typeStr
return (Just (L loc t))
@@ -251,16 +251,16 @@ checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
ResOverload os tysts -> chIn NoLoc "overloading" $ do
tysts' <- mapM (uncurry $ flip (\(L loc1 t) (L loc2 ty) -> checkLType gr [] t ty >>= \(t,ty) -> return (L loc1 t, L loc2 ty))) tysts -- return explicit ones
tysts0 <- lookupOverload gr (m,c) -- check against inherited ones too
tysts1 <- mapM (uncurry $ flip (checkLType gr []))
tysts1 <- mapM (uncurry $ flip (checkLType gr []))
[(mkFunType args val,tr) | (args,(val,tr)) <- tysts0]
--- this can only be a partial guarantee, since matching
--- with value type is only possible if expected type is given
checkUniq $
checkUniq $
sort [let (xs,t) = typeFormCnc x in t : map (\(b,x,t) -> t) xs | (_,x) <- tysts1]
return (ResOverload os [(y,x) | (x,y) <- tysts'])
ResParam (Just (L loc pcs)) _ -> do
ts <- chIn loc "parameter type" $
ts <- chIn loc "parameter type" $
liftM concat $ mapM mkPar pcs
return (ResParam (Just (L loc pcs)) (Just ts))
@@ -274,9 +274,9 @@ checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
return $ map (mkApp (QC (m,f))) vs
checkUniq xss = case xss of
x:y:xs
x:y:xs
| x == y -> checkError $ "ambiguous for type" <+>
ppType (mkFunType (tail x) (head x))
ppType (mkFunType (tail x) (head x))
| otherwise -> checkUniq $ y:xs
_ -> return ()
@@ -294,7 +294,7 @@ checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
t' <- compAbsTyp ((x,Vr x):g) t
return $ Prod b x a' t'
Abs _ _ _ -> return t
_ -> composOp (compAbsTyp g) t
_ -> composOp (compAbsTyp g) t
-- | for grammars obtained otherwise than by parsing ---- update!!

591
src/compiler/GF/Compile/Compute/Concrete.hs
View File

@@ -1,3 +1,588 @@
module GF.Compile.Compute.Concrete{-(module M)-} where
--import GF.Compile.Compute.ConcreteLazy as M -- New
--import GF.Compile.Compute.ConcreteStrict as M -- Old, inefficient
-- | Functions for computing the values of terms in the concrete syntax, in
-- | preparation for PMCFG generation.
module GF.Compile.Compute.Concrete
(GlobalEnv, GLocation, resourceValues, geLoc, geGrammar,
normalForm,
Value(..), Bind(..), Env, value2term, eval, vapply
) where
import Prelude hiding ((<>)) -- GHC 8.4.1 clash with Text.PrettyPrint
import GF.Grammar hiding (Env, VGen, VApp, VRecType)
import GF.Grammar.Lookup(lookupResDefLoc,allParamValues)
import GF.Grammar.Predef(cPredef,cErrorType,cTok,cStr,cTrace,cPBool)
import GF.Grammar.PatternMatch(matchPattern,measurePatt)
import GF.Grammar.Lockfield(isLockLabel,lockRecType) --unlockRecord,lockLabel
import GF.Compile.Compute.Value hiding (Error)
import GF.Compile.Compute.Predef(predef,predefName,delta)
import GF.Data.Str(Str,glueStr,str2strings,str,sstr,plusStr,strTok)
import GF.Data.Operations(Err,err,errIn,maybeErr,mapPairsM)
import GF.Data.Utilities(mapFst,mapSnd)
import GF.Infra.Option
import Control.Monad(ap,liftM,liftM2) -- ,unless,mplus
import Data.List (findIndex,intersect,nub,elemIndex,(\\)) --,isInfixOf
--import Data.Char (isUpper,toUpper,toLower)
import GF.Text.Pretty
import qualified Data.Map as Map
import Debug.Trace(trace)
-- * Main entry points
normalForm :: GlobalEnv -> L Ident -> Term -> Term
normalForm (GE gr rv opts _) loc = err (bugloc loc) id . nfx (GE gr rv opts loc)
nfx env@(GE _ _ _ loc) t = do
v <- eval env [] t
case value2term loc [] v of
Left i -> fail ("variable #"++show i++" is out of scope")
Right t -> return t
eval :: GlobalEnv -> Env -> Term -> Err Value
eval (GE gr rvs opts loc) env t = ($ (map snd env)) # value cenv t
where
cenv = CE gr rvs opts loc (map fst env)
--apply env = apply' env
--------------------------------------------------------------------------------
-- * Environments
type ResourceValues = Map.Map ModuleName (Map.Map Ident (Err Value))
data GlobalEnv = GE Grammar ResourceValues Options GLocation
data CompleteEnv = CE {srcgr::Grammar,rvs::ResourceValues,
opts::Options,
gloc::GLocation,local::LocalScope}
type GLocation = L Ident
type LocalScope = [Ident]
type Stack = [Value]
type OpenValue = Stack->Value
geLoc (GE _ _ _ loc) = loc
geGrammar (GE gr _ _ _) = gr
ext b env = env{local=b:local env}
extend bs env = env{local=bs++local env}
global env = GE (srcgr env) (rvs env) (opts env) (gloc env)
var :: CompleteEnv -> Ident -> Err OpenValue
var env x = maybe unbound pick' (elemIndex x (local env))
where
unbound = fail ("Unknown variable: "++showIdent x)
pick' i = return $ \ vs -> maybe (err i vs) ok (pick i vs)
err i vs = bug $ "Stack problem: "++showIdent x++": "
++unwords (map showIdent (local env))
++" => "++show (i,length vs)
ok v = --trace ("var "++show x++" = "++show v) $
v
pick :: Int -> Stack -> Maybe Value
pick 0 (v:_) = Just v
pick i (_:vs) = pick (i-1) vs
pick i vs = Nothing -- bug $ "pick "++show (i,vs)
resource env (m,c) =
-- err bug id $
if isPredefCat c
then value0 env =<< lockRecType c defLinType -- hmm
else maybe e id $ Map.lookup c =<< Map.lookup m (rvs env)
where e = fail $ "Not found: "++render m++"."++showIdent c
-- | Convert operators once, not every time they are looked up
resourceValues :: Options -> SourceGrammar -> GlobalEnv
resourceValues opts gr = env
where
env = GE gr rvs opts (L NoLoc identW)
rvs = Map.mapWithKey moduleResources (moduleMap gr)
moduleResources m = Map.mapWithKey (moduleResource m) . jments
moduleResource m c _info = do L l t <- lookupResDefLoc gr (m,c)
let loc = L l c
qloc = L l (Q (m,c))
eval (GE gr rvs opts loc) [] (traceRes qloc t)
traceRes = if flag optTrace opts
then traceResource
else const id
-- * Tracing
-- | Insert a call to the trace function under the top-level lambdas
traceResource (L l q) t =
case termFormCnc t of
(abs,body) -> mkAbs abs (mkApp traceQ [args,body])
where
args = R $ tuple2record (K lstr:[Vr x|(bt,x)<-abs,bt==Explicit])
lstr = render (l<>":"<>ppTerm Qualified 0 q)
traceQ = Q (cPredef,cTrace)
-- * Computing values
-- | Computing the value of a top-level term
value0 :: CompleteEnv -> Term -> Err Value
value0 env = eval (global env) []
-- | Computing the value of a term
value :: CompleteEnv -> Term -> Err OpenValue
value env t0 =
-- Each terms is traversed only once by this function, using only statically
-- available information. Notably, the values of lambda bound variables
-- will be unknown during the term traversal phase.
-- The result is an OpenValue, which is a function that may be applied many
-- times to different dynamic values, but without the term traversal overhead
-- and without recomputing other statically known information.
-- For this to work, there should be no recursive calls under lambdas here.
-- Whenever we need to construct the OpenValue function with an explicit
-- lambda, we have to lift the recursive calls outside the lambda.
-- (See e.g. the rules for Let, Prod and Abs)
{-
trace (render $ text "value"<+>sep [ppL (gloc env)<>text ":",
brackets (fsep (map ppIdent (local env))),
ppTerm Unqualified 10 t0]) $
--}
errIn (render t0) $
case t0 of
Vr x -> var env x
Q x@(m,f)
| m == cPredef -> if f==cErrorType -- to be removed
then let p = identS "P"
in const # value0 env (mkProd [(Implicit,p,typeType)] (Vr p) [])
else if f==cPBool
then const # resource env x
else const . flip VApp [] # predef f
| otherwise -> const # resource env x --valueResDef (fst env) x
QC x -> return $ const (VCApp x [])
App e1 e2 -> apply' env e1 . (:[]) =<< value env e2
Let (x,(oty,t)) body -> do vb <- value (ext x env) body
vt <- value env t
return $ \ vs -> vb (vt vs:vs)
Meta i -> return $ \ vs -> VMeta i (zip (local env) vs) []
Prod bt x t1 t2 ->
do vt1 <- value env t1
vt2 <- value (ext x env) t2
return $ \ vs -> VProd bt (vt1 vs) x $ Bind $ \ vx -> vt2 (vx:vs)
Abs bt x t -> do vt <- value (ext x env) t
return $ VAbs bt x . Bind . \ vs vx -> vt (vx:vs)
EInt n -> return $ const (VInt n)
EFloat f -> return $ const (VFloat f)
K s -> return $ const (VString s)
Empty -> return $ const (VString "")
Sort s | s == cTok -> return $ const (VSort cStr) -- to be removed
| otherwise -> return $ const (VSort s)
ImplArg t -> (VImplArg.) # value env t
Table p res -> liftM2 VTblType # value env p <# value env res
RecType rs -> do lovs <- mapPairsM (value env) rs
return $ \vs->VRecType $ mapSnd ($vs) lovs
t@(ExtR t1 t2) -> ((extR t.)# both id) # both (value env) (t1,t2)
FV ts -> ((vfv .) # sequence) # mapM (value env) ts
R as -> do lovs <- mapPairsM (value env.snd) as
return $ \ vs->VRec $ mapSnd ($vs) lovs
T i cs -> valueTable env i cs
V ty ts -> do pvs <- paramValues env ty
((VV ty pvs .) . sequence) # mapM (value env) ts
C t1 t2 -> ((ok2p vconcat.) # both id) # both (value env) (t1,t2)
S t1 t2 -> ((select env.) # both id) # both (value env) (t1,t2)
P t l -> --maybe (bug $ "project "++show l++" from "++show v) id $
do ov <- value env t
return $ \ vs -> let v = ov vs
in maybe (VP v l) id (proj l v)
Alts t tts -> (\v vts -> VAlts # v <# mapM (both id) vts) # value env t <# mapM (both (value env)) tts
Strs ts -> ((VStrs.) # sequence) # mapM (value env) ts
Glue t1 t2 -> ((ok2p (glue env).) # both id) # both (value env) (t1,t2)
ELin c r -> (unlockVRec (gloc env) c.) # value env r
EPatt p -> return $ const (VPatt p) -- hmm
EPattType ty -> do vt <- value env ty
return (VPattType . vt)
Typed t ty -> value env t
t -> fail.render $ "value"<+>ppTerm Unqualified 10 t $$ show t
vconcat vv@(v1,v2) =
case vv of
(VString "",_) -> v2
(_,VString "") -> v1
(VApp NonExist _,_) -> v1
(_,VApp NonExist _) -> v2
_ -> VC v1 v2
proj l v | isLockLabel l = return (VRec [])
---- a workaround 18/2/2005: take this away and find the reason
---- why earlier compilation destroys the lock field
proj l v =
case v of
VFV vs -> liftM vfv (mapM (proj l) vs)
VRec rs -> lookup l rs
-- VExtR v1 v2 -> proj l v2 `mplus` proj l v1 -- hmm
VS (VV pty pvs rs) v2 -> flip VS v2 . VV pty pvs # mapM (proj l) rs
_ -> return (ok1 VP v l)
ok1 f v1@(VError {}) _ = v1
ok1 f v1 v2 = f v1 v2
ok2 f v1@(VError {}) _ = v1
ok2 f _ v2@(VError {}) = v2
ok2 f v1 v2 = f v1 v2
ok2p f (v1@VError {},_) = v1
ok2p f (_,v2@VError {}) = v2
ok2p f vv = f vv
unlockVRec loc c0 v0 = v0
{-
unlockVRec loc c0 v0 = unlockVRec' c0 v0
where
unlockVRec' ::Ident -> Value -> Value
unlockVRec' c v =
case v of
-- VClosure env t -> err bug (VClosure env) (unlockRecord c t)
VAbs bt x (Bind f) -> VAbs bt x (Bind $ \ v -> unlockVRec' c (f v))
VRec rs -> plusVRec rs lock
-- _ -> VExtR v (VRec lock) -- hmm
_ -> {-trace (render $ ppL loc $ "unlock non-record "++show v0)-} v -- hmm
-- _ -> bugloc loc $ "unlock non-record "++show v0
where
lock = [(lockLabel c,VRec [])]
-}
-- suspicious, but backwards compatible
plusVRec rs1 rs2 = VRec ([(l,v)|(l,v)<-rs1,l `notElem` ls2] ++ rs2)
where ls2 = map fst rs2
extR t vv =
case vv of
(VFV vs,v2) -> vfv [extR t (v1,v2)|v1<-vs]
(v1,VFV vs) -> vfv [extR t (v1,v2)|v2<-vs]
(VRecType rs1, VRecType rs2) ->
case intersect (map fst rs1) (map fst rs2) of
[] -> VRecType (rs1 ++ rs2)
ls -> error $ "clash"<+>show ls
(VRec rs1, VRec rs2) -> plusVRec rs1 rs2
(v1 , VRec [(l,_)]) | isLockLabel l -> v1 -- hmm
(VS (VV t pvs vs) s,v2) -> VS (VV t pvs [extR t (v1,v2)|v1<-vs]) s
-- (v1,v2) -> ok2 VExtR v1 v2 -- hmm
(v1,v2) -> error $ "not records" $$ show v1 $$ show v2
where
error explain = ppbug $ "The term" <+> t
<+> "is not reducible" $$ explain
glue env (v1,v2) = glu v1 v2
where
glu v1 v2 =
case (v1,v2) of
(VFV vs,v2) -> vfv [glu v1 v2|v1<-vs]
(v1,VFV vs) -> vfv [glu v1 v2|v2<-vs]
(VString s1,VString s2) -> VString (s1++s2)
(v1,VAlts d vs) -> VAlts (glx d) [(glx v,c) | (v,c) <- vs]
where glx v2 = glu v1 v2
(v1@(VAlts {}),v2) ->
--err (const (ok2 VGlue v1 v2)) id $
err bug id $
do y' <- strsFromValue v2
x' <- strsFromValue v1
return $ vfv [foldr1 VC (map VString (str2strings (glueStr v u))) | v <- x', u <- y']
(VC va vb,v2) -> VC va (glu vb v2)
(v1,VC va vb) -> VC (glu v1 va) vb
(VS (VV ty pvs vs) vb,v2) -> VS (VV ty pvs [glu v v2|v<-vs]) vb
(v1,VS (VV ty pvs vs) vb) -> VS (VV ty pvs [glu v1 v|v<-vs]) vb
(v1@(VApp NonExist _),_) -> v1
(_,v2@(VApp NonExist _)) -> v2
-- (v1,v2) -> ok2 VGlue v1 v2
(v1,v2) -> if flag optPlusAsBind (opts env)
then VC v1 (VC (VApp BIND []) v2)
else let loc = gloc env
vt v = case value2term loc (local env) v of
Left i -> Error ('#':show i)
Right t -> t
originalMsg = render $ ppL loc (hang "unsupported token gluing" 4
(Glue (vt v1) (vt v2)))
term = render $ pp $ Glue (vt v1) (vt v2)
in error $ unlines
[originalMsg
,""
,"There was a problem in the expression `"++term++"`, either:"
,"1) You are trying to use + on runtime arguments, possibly via an oper."
,"2) One of the arguments in `"++term++"` is a bound variable from pattern matching a string, but the cases are non-exhaustive."
,"For more help see https://github.com/GrammaticalFramework/gf-core/tree/master/doc/errors/gluing.md"
]
-- | to get a string from a value that represents a sequence of terminals
strsFromValue :: Value -> Err [Str]
strsFromValue t = case t of
VString s -> return [str s]
VC s t -> do
s' <- strsFromValue s
t' <- strsFromValue t
return [plusStr x y | x <- s', y <- t']
{-
VGlue s t -> do
s' <- strsFromValue s
t' <- strsFromValue t
return [glueStr x y | x <- s', y <- t']
-}
VAlts d vs -> do
d0 <- strsFromValue d
v0 <- mapM (strsFromValue . fst) vs
c0 <- mapM (strsFromValue . snd) vs
--let vs' = zip v0 c0
return [strTok (str2strings def) vars |
def <- d0,
vars <- [[(str2strings v, map sstr c) | (v,c) <- zip vv c0] |
vv <- sequence v0]
]
VFV ts -> concat # mapM strsFromValue ts
VStrs ts -> concat # mapM strsFromValue ts
_ -> fail ("cannot get Str from value " ++ show t)
vfv vs = case nub vs of
[v] -> v
vs -> VFV vs
select env vv =
case vv of
(v1,VFV vs) -> vfv [select env (v1,v2)|v2<-vs]
(VFV vs,v2) -> vfv [select env (v1,v2)|v1<-vs]
(v1@(VV pty vs rs),v2) ->
err (const (VS v1 v2)) id $
do --ats <- allParamValues (srcgr env) pty
--let vs = map (value0 env) ats
i <- maybeErr "no match" $ findIndex (==v2) vs
return (ix (gloc env) "select" rs i)
(VT _ _ [(PW,Bind b)],_) -> {-trace "eliminate wild card table" $-} b []
(v1@(VT _ _ cs),v2) ->
err (\_->ok2 VS v1 v2) (err bug id . valueMatch env) $
match (gloc env) cs v2
(VS (VV pty pvs rs) v12,v2) -> VS (VV pty pvs [select env (v11,v2)|v11<-rs]) v12
(v1,v2) -> ok2 VS v1 v2
match loc cs v =
case value2term loc [] v of
Left i -> bad ("variable #"++show i++" is out of scope")
Right t -> err bad return (matchPattern cs t)
where
bad = fail . ("In pattern matching: "++)
valueMatch :: CompleteEnv -> (Bind Env,Substitution) -> Err Value
valueMatch env (Bind f,env') = f # mapPairsM (value0 env) env'
valueTable :: CompleteEnv -> TInfo -> [Case] -> Err OpenValue
valueTable env i cs =
case i of
TComp ty -> do pvs <- paramValues env ty
((VV ty pvs .) # sequence) # mapM (value env.snd) cs
_ -> do ty <- getTableType i
cs' <- mapM valueCase cs
err (dynamic cs' ty) return (convert cs' ty)
where
dynamic cs' ty _ = cases cs' # value env ty
cases cs' vty vs = err keep ($vs) (convertv cs' (vty vs))
where
keep msg = --trace (msg++"\n"++render (ppTerm Unqualified 0 (T i cs))) $
VT wild (vty vs) (mapSnd ($vs) cs')
wild = case i of TWild _ -> True; _ -> False
convertv cs' vty =
case value2term (gloc env) [] vty of
Left i -> fail ("variable #"++show i++" is out of scope")
Right pty -> convert' cs' =<< paramValues'' env pty
convert cs' ty = convert' cs' =<< paramValues' env ty
convert' cs' ((pty,vs),pvs) =
do sts <- mapM (matchPattern cs') vs
return $ \ vs -> VV pty pvs $ map (err bug id . valueMatch env)
(mapFst ($vs) sts)
valueCase (p,t) = do p' <- measurePatt # inlinePattMacro p
pvs <- linPattVars p'
vt <- value (extend pvs env) t
return (p',\vs-> Bind $ \bs-> vt (push' p' bs pvs vs))
inlinePattMacro p =
case p of
PM qc -> do r <- resource env qc
case r of
VPatt p' -> inlinePattMacro p'
_ -> ppbug $ hang "Expected pattern macro:" 4
(show r)
_ -> composPattOp inlinePattMacro p
paramValues env ty = snd # paramValues' env ty
paramValues' env ty = paramValues'' env =<< nfx (global env) ty
paramValues'' env pty = do ats <- allParamValues (srcgr env) pty
pvs <- mapM (eval (global env) []) ats
return ((pty,ats),pvs)
push' p bs xs = if length bs/=length xs
then bug $ "push "++show (p,bs,xs)
else push bs xs
push :: Env -> LocalScope -> Stack -> Stack
push bs [] vs = vs
push bs (x:xs) vs = maybe err id (lookup x bs):push bs xs vs
where err = bug $ "Unbound pattern variable "++showIdent x
apply' :: CompleteEnv -> Term -> [OpenValue] -> Err OpenValue
apply' env t [] = value env t
apply' env t vs =
case t of
QC x -> return $ \ svs -> VCApp x (map ($svs) vs)
{-
Q x@(m,f) | m==cPredef -> return $
let constr = --trace ("predef "++show x) .
VApp x
in \ svs -> maybe constr id (Map.lookup f predefs)
$ map ($svs) vs
| otherwise -> do r <- resource env x
return $ \ svs -> vapply (gloc env) r (map ($svs) vs)
-}
App t1 t2 -> apply' env t1 . (:vs) =<< value env t2
_ -> do fv <- value env t
return $ \ svs -> vapply (gloc env) (fv svs) (map ($svs) vs)
vapply :: GLocation -> Value -> [Value] -> Value
vapply loc v [] = v
vapply loc v vs =
case v of
VError {} -> v
-- VClosure env (Abs b x t) -> beta gr env b x t vs
VAbs bt _ (Bind f) -> vbeta loc bt f vs
VApp pre vs1 -> delta' pre (vs1++vs)
where
delta' Trace (v1:v2:vs) = let vr = vapply loc v2 vs
in vtrace loc v1 vr
delta' pre vs = err msg vfv $ mapM (delta pre) (varyList vs)
--msg = const (VApp pre (vs1++vs))
msg = bug . (("Applying Predef."++showIdent (predefName pre)++": ")++)
VS (VV t pvs fs) s -> VS (VV t pvs [vapply loc f vs|f<-fs]) s
VFV fs -> vfv [vapply loc f vs|f<-fs]
VCApp f vs0 -> VCApp f (vs0++vs)
VMeta i env vs0 -> VMeta i env (vs0++vs)
VGen i vs0 -> VGen i (vs0++vs)
v -> bug $ "vapply "++show v++" "++show vs
vbeta loc bt f (v:vs) =
case (bt,v) of
(Implicit,VImplArg v) -> ap v
(Explicit, v) -> ap v
where
ap (VFV avs) = vfv [vapply loc (f v) vs|v<-avs]
ap v = vapply loc (f v) vs
vary (VFV vs) = vs
vary v = [v]
varyList = mapM vary
{-
beta env b x t (v:vs) =
case (b,v) of
(Implicit,VImplArg v) -> apply' (ext (x,v) env) t vs
(Explicit, v) -> apply' (ext (x,v) env) t vs
-}
vtrace loc arg res = trace (render (hang (pv arg) 4 ("->"<+>pv res))) res
where
pv v = case v of
VRec (f:as) -> hang (pf f) 4 (fsep (map pa as))
_ -> ppV v
pf (_,VString n) = pp n
pf (_,v) = ppV v
pa (_,v) = ppV v
ppV v = case value2term' True loc [] v of
Left i -> "variable #" <> pp i <+> "is out of scope"
Right t -> ppTerm Unqualified 10 t
-- | Convert a value back to a term
value2term :: GLocation -> [Ident] -> Value -> Either Int Term
value2term = value2term' False
value2term' stop loc xs v0 =
case v0 of
VApp pre vs -> liftM (foldl App (Q (cPredef,predefName pre))) (mapM v2t vs)
VCApp f vs -> liftM (foldl App (QC f)) (mapM v2t vs)
VGen j vs -> liftM2 (foldl App) (var j) (mapM v2t vs)
VMeta j env vs -> liftM (foldl App (Meta j)) (mapM v2t vs)
VProd bt v x f -> liftM2 (Prod bt x) (v2t v) (v2t' x f)
VAbs bt x f -> liftM (Abs bt x) (v2t' x f)
VInt n -> return (EInt n)
VFloat f -> return (EFloat f)
VString s -> return (if null s then Empty else K s)
VSort s -> return (Sort s)
VImplArg v -> liftM ImplArg (v2t v)
VTblType p res -> liftM2 Table (v2t p) (v2t res)
VRecType rs -> liftM RecType (mapM (\(l,v) -> fmap ((,) l) (v2t v)) rs)
VRec as -> liftM R (mapM (\(l,v) -> v2t v >>= \t -> return (l,(Nothing,t))) as)
VV t _ vs -> liftM (V t) (mapM v2t vs)
VT wild v cs -> v2t v >>= \t -> liftM (T ((if wild then TWild else TTyped) t)) (mapM nfcase cs)
VFV vs -> liftM FV (mapM v2t vs)
VC v1 v2 -> liftM2 C (v2t v1) (v2t v2)
VS v1 v2 -> liftM2 S (v2t v1) (v2t v2)
VP v l -> v2t v >>= \t -> return (P t l)
VPatt p -> return (EPatt p)
VPattType v -> v2t v >>= return . EPattType
VAlts v vvs -> liftM2 Alts (v2t v) (mapM (\(x,y) -> liftM2 (,) (v2t x) (v2t y)) vvs)
VStrs vs -> liftM Strs (mapM v2t vs)
-- VGlue v1 v2 -> Glue (v2t v1) (v2t v2)
-- VExtR v1 v2 -> ExtR (v2t v1) (v2t v2)
VError err -> return (Error err)
where
v2t = v2txs xs
v2txs = value2term' stop loc
v2t' x f = v2txs (x:xs) (bind f (gen xs))
var j
| j<length xs = Right (Vr (reverse xs !! j))
| otherwise = Left j
pushs xs e = foldr push e xs
push x (env,xs) = ((x,gen xs):env,x:xs)
gen xs = VGen (length xs) []
nfcase (p,f) = liftM ((,) p) (v2txs xs' (bind f env'))
where (env',xs') = pushs (pattVars p) ([],xs)
bind (Bind f) x = if stop
then VSort (identS "...") -- hmm
else f x
linPattVars p =
if null dups
then return pvs
else fail.render $ hang "Pattern is not linear. All variable names on the left-hand side must be distinct." 4 (ppPatt Unqualified 0 p)
where
allpvs = allPattVars p
pvs = nub allpvs
dups = allpvs \\ pvs
pattVars = nub . allPattVars
allPattVars p =
case p of
PV i -> [i]
PAs i p -> i:allPattVars p
_ -> collectPattOp allPattVars p
---
ix loc fn xs i =
if i<n
then xs !! i
else bugloc loc $ "(!!): index too large in "++fn++", "++show i++"<"++show n
where n = length xs
infixl 1 #,<# --,@@
f # x = fmap f x
mf <# mx = ap mf mx
--m1 @@ m2 = (m1 =<<) . m2
both f (x,y) = (,) # f x <# f y
bugloc loc s = ppbug $ ppL loc s
bug msg = ppbug msg
ppbug doc = error $ render $ hang "Internal error in Compute.Concrete:" 4 doc

588
src/compiler/GF/Compile/Compute/ConcreteNew.hs
View File

@@ -1,588 +0,0 @@
-- | Functions for computing the values of terms in the concrete syntax, in
-- | preparation for PMCFG generation.
module GF.Compile.Compute.ConcreteNew
(GlobalEnv, GLocation, resourceValues, geLoc, geGrammar,
normalForm,
Value(..), Bind(..), Env, value2term, eval, vapply
) where
import Prelude hiding ((<>)) -- GHC 8.4.1 clash with Text.PrettyPrint
import GF.Grammar hiding (Env, VGen, VApp, VRecType)
import GF.Grammar.Lookup(lookupResDefLoc,allParamValues)
import GF.Grammar.Predef(cPredef,cErrorType,cTok,cStr,cTrace,cPBool)
import GF.Grammar.PatternMatch(matchPattern,measurePatt)
import GF.Grammar.Lockfield(isLockLabel,lockRecType) --unlockRecord,lockLabel
import GF.Compile.Compute.Value hiding (Error)
import GF.Compile.Compute.Predef(predef,predefName,delta)
import GF.Data.Str(Str,glueStr,str2strings,str,sstr,plusStr,strTok)
import GF.Data.Operations(Err,err,errIn,maybeErr,mapPairsM)
import GF.Data.Utilities(mapFst,mapSnd)
import GF.Infra.Option
import Control.Monad(ap,liftM,liftM2) -- ,unless,mplus
import Data.List (findIndex,intersect,nub,elemIndex,(\\)) --,isInfixOf
--import Data.Char (isUpper,toUpper,toLower)
import GF.Text.Pretty
import qualified Data.Map as Map
import Debug.Trace(trace)
-- * Main entry points
normalForm :: GlobalEnv -> L Ident -> Term -> Term
normalForm (GE gr rv opts _) loc = err (bugloc loc) id . nfx (GE gr rv opts loc)
nfx env@(GE _ _ _ loc) t = do
v <- eval env [] t
case value2term loc [] v of
Left i -> fail ("variable #"++show i++" is out of scope")
Right t -> return t
eval :: GlobalEnv -> Env -> Term -> Err Value
eval (GE gr rvs opts loc) env t = ($ (map snd env)) # value cenv t
where
cenv = CE gr rvs opts loc (map fst env)
--apply env = apply' env
--------------------------------------------------------------------------------
-- * Environments
type ResourceValues = Map.Map ModuleName (Map.Map Ident (Err Value))
data GlobalEnv = GE Grammar ResourceValues Options GLocation
data CompleteEnv = CE {srcgr::Grammar,rvs::ResourceValues,
opts::Options,
gloc::GLocation,local::LocalScope}
type GLocation = L Ident
type LocalScope = [Ident]
type Stack = [Value]
type OpenValue = Stack->Value
geLoc (GE _ _ _ loc) = loc
geGrammar (GE gr _ _ _) = gr
ext b env = env{local=b:local env}
extend bs env = env{local=bs++local env}
global env = GE (srcgr env) (rvs env) (opts env) (gloc env)
var :: CompleteEnv -> Ident -> Err OpenValue
var env x = maybe unbound pick' (elemIndex x (local env))
where
unbound = fail ("Unknown variable: "++showIdent x)
pick' i = return $ \ vs -> maybe (err i vs) ok (pick i vs)
err i vs = bug $ "Stack problem: "++showIdent x++": "
++unwords (map showIdent (local env))
++" => "++show (i,length vs)
ok v = --trace ("var "++show x++" = "++show v) $
v
pick :: Int -> Stack -> Maybe Value
pick 0 (v:_) = Just v
pick i (_:vs) = pick (i-1) vs
pick i vs = Nothing -- bug $ "pick "++show (i,vs)
resource env (m,c) =
-- err bug id $
if isPredefCat c
then value0 env =<< lockRecType c defLinType -- hmm
else maybe e id $ Map.lookup c =<< Map.lookup m (rvs env)
where e = fail $ "Not found: "++render m++"."++showIdent c
-- | Convert operators once, not every time they are looked up
resourceValues :: Options -> SourceGrammar -> GlobalEnv
resourceValues opts gr = env
where
env = GE gr rvs opts (L NoLoc identW)
rvs = Map.mapWithKey moduleResources (moduleMap gr)
moduleResources m = Map.mapWithKey (moduleResource m) . jments
moduleResource m c _info = do L l t <- lookupResDefLoc gr (m,c)
let loc = L l c
qloc = L l (Q (m,c))
eval (GE gr rvs opts loc) [] (traceRes qloc t)
traceRes = if flag optTrace opts
then traceResource
else const id
-- * Tracing
-- | Insert a call to the trace function under the top-level lambdas
traceResource (L l q) t =
case termFormCnc t of
(abs,body) -> mkAbs abs (mkApp traceQ [args,body])
where
args = R $ tuple2record (K lstr:[Vr x|(bt,x)<-abs,bt==Explicit])
lstr = render (l<>":"<>ppTerm Qualified 0 q)
traceQ = Q (cPredef,cTrace)
-- * Computing values
-- | Computing the value of a top-level term
value0 :: CompleteEnv -> Term -> Err Value
value0 env = eval (global env) []
-- | Computing the value of a term
value :: CompleteEnv -> Term -> Err OpenValue
value env t0 =
-- Each terms is traversed only once by this function, using only statically
-- available information. Notably, the values of lambda bound variables
-- will be unknown during the term traversal phase.
-- The result is an OpenValue, which is a function that may be applied many
-- times to different dynamic values, but without the term traversal overhead
-- and without recomputing other statically known information.
-- For this to work, there should be no recursive calls under lambdas here.
-- Whenever we need to construct the OpenValue function with an explicit
-- lambda, we have to lift the recursive calls outside the lambda.
-- (See e.g. the rules for Let, Prod and Abs)
{-
trace (render $ text "value"<+>sep [ppL (gloc env)<>text ":",
brackets (fsep (map ppIdent (local env))),
ppTerm Unqualified 10 t0]) $
--}
errIn (render t0) $
case t0 of
Vr x -> var env x
Q x@(m,f)
| m == cPredef -> if f==cErrorType -- to be removed
then let p = identS "P"
in const # value0 env (mkProd [(Implicit,p,typeType)] (Vr p) [])
else if f==cPBool
then const # resource env x
else const . flip VApp [] # predef f
| otherwise -> const # resource env x --valueResDef (fst env) x
QC x -> return $ const (VCApp x [])
App e1 e2 -> apply' env e1 . (:[]) =<< value env e2
Let (x,(oty,t)) body -> do vb <- value (ext x env) body
vt <- value env t
return $ \ vs -> vb (vt vs:vs)
Meta i -> return $ \ vs -> VMeta i (zip (local env) vs) []
Prod bt x t1 t2 ->
do vt1 <- value env t1
vt2 <- value (ext x env) t2
return $ \ vs -> VProd bt (vt1 vs) x $ Bind $ \ vx -> vt2 (vx:vs)
Abs bt x t -> do vt <- value (ext x env) t
return $ VAbs bt x . Bind . \ vs vx -> vt (vx:vs)
EInt n -> return $ const (VInt n)
EFloat f -> return $ const (VFloat f)
K s -> return $ const (VString s)
Empty -> return $ const (VString "")
Sort s | s == cTok -> return $ const (VSort cStr) -- to be removed
| otherwise -> return $ const (VSort s)
ImplArg t -> (VImplArg.) # value env t
Table p res -> liftM2 VTblType # value env p <# value env res
RecType rs -> do lovs <- mapPairsM (value env) rs
return $ \vs->VRecType $ mapSnd ($vs) lovs
t@(ExtR t1 t2) -> ((extR t.)# both id) # both (value env) (t1,t2)
FV ts -> ((vfv .) # sequence) # mapM (value env) ts
R as -> do lovs <- mapPairsM (value env.snd) as
return $ \ vs->VRec $ mapSnd ($vs) lovs
T i cs -> valueTable env i cs
V ty ts -> do pvs <- paramValues env ty
((VV ty pvs .) . sequence) # mapM (value env) ts
C t1 t2 -> ((ok2p vconcat.) # both id) # both (value env) (t1,t2)
S t1 t2 -> ((select env.) # both id) # both (value env) (t1,t2)
P t l -> --maybe (bug $ "project "++show l++" from "++show v) id $
do ov <- value env t
return $ \ vs -> let v = ov vs
in maybe (VP v l) id (proj l v)
Alts t tts -> (\v vts -> VAlts # v <# mapM (both id) vts) # value env t <# mapM (both (value env)) tts
Strs ts -> ((VStrs.) # sequence) # mapM (value env) ts
Glue t1 t2 -> ((ok2p (glue env).) # both id) # both (value env) (t1,t2)
ELin c r -> (unlockVRec (gloc env) c.) # value env r
EPatt p -> return $ const (VPatt p) -- hmm
EPattType ty -> do vt <- value env ty
return (VPattType . vt)
Typed t ty -> value env t
t -> fail.render $ "value"<+>ppTerm Unqualified 10 t $$ show t
vconcat vv@(v1,v2) =
case vv of
(VString "",_) -> v2
(_,VString "") -> v1
(VApp NonExist _,_) -> v1
(_,VApp NonExist _) -> v2
_ -> VC v1 v2
proj l v | isLockLabel l = return (VRec [])
---- a workaround 18/2/2005: take this away and find the reason
---- why earlier compilation destroys the lock field
proj l v =
case v of
VFV vs -> liftM vfv (mapM (proj l) vs)
VRec rs -> lookup l rs
-- VExtR v1 v2 -> proj l v2 `mplus` proj l v1 -- hmm
VS (VV pty pvs rs) v2 -> flip VS v2 . VV pty pvs # mapM (proj l) rs
_ -> return (ok1 VP v l)
ok1 f v1@(VError {}) _ = v1
ok1 f v1 v2 = f v1 v2
ok2 f v1@(VError {}) _ = v1
ok2 f _ v2@(VError {}) = v2
ok2 f v1 v2 = f v1 v2
ok2p f (v1@VError {},_) = v1
ok2p f (_,v2@VError {}) = v2
ok2p f vv = f vv
unlockVRec loc c0 v0 = v0
{-
unlockVRec loc c0 v0 = unlockVRec' c0 v0
where
unlockVRec' ::Ident -> Value -> Value
unlockVRec' c v =
case v of
-- VClosure env t -> err bug (VClosure env) (unlockRecord c t)
VAbs bt x (Bind f) -> VAbs bt x (Bind $ \ v -> unlockVRec' c (f v))
VRec rs -> plusVRec rs lock
-- _ -> VExtR v (VRec lock) -- hmm
_ -> {-trace (render $ ppL loc $ "unlock non-record "++show v0)-} v -- hmm
-- _ -> bugloc loc $ "unlock non-record "++show v0
where
lock = [(lockLabel c,VRec [])]
-}
-- suspicious, but backwards compatible
plusVRec rs1 rs2 = VRec ([(l,v)|(l,v)<-rs1,l `notElem` ls2] ++ rs2)
where ls2 = map fst rs2
extR t vv =
case vv of
(VFV vs,v2) -> vfv [extR t (v1,v2)|v1<-vs]
(v1,VFV vs) -> vfv [extR t (v1,v2)|v2<-vs]
(VRecType rs1, VRecType rs2) ->
case intersect (map fst rs1) (map fst rs2) of
[] -> VRecType (rs1 ++ rs2)
ls -> error $ "clash"<+>show ls
(VRec rs1, VRec rs2) -> plusVRec rs1 rs2
(v1 , VRec [(l,_)]) | isLockLabel l -> v1 -- hmm
(VS (VV t pvs vs) s,v2) -> VS (VV t pvs [extR t (v1,v2)|v1<-vs]) s
-- (v1,v2) -> ok2 VExtR v1 v2 -- hmm
(v1,v2) -> error $ "not records" $$ show v1 $$ show v2
where
error explain = ppbug $ "The term" <+> t
<+> "is not reducible" $$ explain
glue env (v1,v2) = glu v1 v2
where
glu v1 v2 =
case (v1,v2) of
(VFV vs,v2) -> vfv [glu v1 v2|v1<-vs]
(v1,VFV vs) -> vfv [glu v1 v2|v2<-vs]
(VString s1,VString s2) -> VString (s1++s2)
(v1,VAlts d vs) -> VAlts (glx d) [(glx v,c) | (v,c) <- vs]
where glx v2 = glu v1 v2
(v1@(VAlts {}),v2) ->
--err (const (ok2 VGlue v1 v2)) id $
err bug id $
do y' <- strsFromValue v2
x' <- strsFromValue v1
return $ vfv [foldr1 VC (map VString (str2strings (glueStr v u))) | v <- x', u <- y']
(VC va vb,v2) -> VC va (glu vb v2)
(v1,VC va vb) -> VC (glu v1 va) vb
(VS (VV ty pvs vs) vb,v2) -> VS (VV ty pvs [glu v v2|v<-vs]) vb
(v1,VS (VV ty pvs vs) vb) -> VS (VV ty pvs [glu v1 v|v<-vs]) vb
(v1@(VApp NonExist _),_) -> v1
(_,v2@(VApp NonExist _)) -> v2
-- (v1,v2) -> ok2 VGlue v1 v2
(v1,v2) -> if flag optPlusAsBind (opts env)
then VC v1 (VC (VApp BIND []) v2)
else let loc = gloc env
vt v = case value2term loc (local env) v of
Left i -> Error ('#':show i)
Right t -> t
originalMsg = render $ ppL loc (hang "unsupported token gluing" 4
(Glue (vt v1) (vt v2)))
term = render $ pp $ Glue (vt v1) (vt v2)
in error $ unlines
[originalMsg
,""
,"There was a problem in the expression `"++term++"`, either:"
,"1) You are trying to use + on runtime arguments, possibly via an oper."
,"2) One of the arguments in `"++term++"` is a bound variable from pattern matching a string, but the cases are non-exhaustive."
,"For more help see https://github.com/GrammaticalFramework/gf-core/tree/master/doc/errors/gluing.md"
]
-- | to get a string from a value that represents a sequence of terminals
strsFromValue :: Value -> Err [Str]
strsFromValue t = case t of
VString s -> return [str s]
VC s t -> do
s' <- strsFromValue s
t' <- strsFromValue t
return [plusStr x y | x <- s', y <- t']
{-
VGlue s t -> do
s' <- strsFromValue s
t' <- strsFromValue t
return [glueStr x y | x <- s', y <- t']
-}
VAlts d vs -> do
d0 <- strsFromValue d
v0 <- mapM (strsFromValue . fst) vs
c0 <- mapM (strsFromValue . snd) vs
--let vs' = zip v0 c0
return [strTok (str2strings def) vars |
def <- d0,
vars <- [[(str2strings v, map sstr c) | (v,c) <- zip vv c0] |
vv <- sequence v0]
]
VFV ts -> concat # mapM strsFromValue ts
VStrs ts -> concat # mapM strsFromValue ts
_ -> fail ("cannot get Str from value " ++ show t)
vfv vs = case nub vs of
[v] -> v
vs -> VFV vs
select env vv =
case vv of
(v1,VFV vs) -> vfv [select env (v1,v2)|v2<-vs]
(VFV vs,v2) -> vfv [select env (v1,v2)|v1<-vs]
(v1@(VV pty vs rs),v2) ->
err (const (VS v1 v2)) id $
do --ats <- allParamValues (srcgr env) pty
--let vs = map (value0 env) ats
i <- maybeErr "no match" $ findIndex (==v2) vs
return (ix (gloc env) "select" rs i)
(VT _ _ [(PW,Bind b)],_) -> {-trace "eliminate wild card table" $-} b []
(v1@(VT _ _ cs),v2) ->
err (\_->ok2 VS v1 v2) (err bug id . valueMatch env) $
match (gloc env) cs v2
(VS (VV pty pvs rs) v12,v2) -> VS (VV pty pvs [select env (v11,v2)|v11<-rs]) v12
(v1,v2) -> ok2 VS v1 v2
match loc cs v =
case value2term loc [] v of
Left i -> bad ("variable #"++show i++" is out of scope")
Right t -> err bad return (matchPattern cs t)
where
bad = fail . ("In pattern matching: "++)
valueMatch :: CompleteEnv -> (Bind Env,Substitution) -> Err Value
valueMatch env (Bind f,env') = f # mapPairsM (value0 env) env'
valueTable :: CompleteEnv -> TInfo -> [Case] -> Err OpenValue
valueTable env i cs =
case i of
TComp ty -> do pvs <- paramValues env ty
((VV ty pvs .) # sequence) # mapM (value env.snd) cs
_ -> do ty <- getTableType i
cs' <- mapM valueCase cs
err (dynamic cs' ty) return (convert cs' ty)
where
dynamic cs' ty _ = cases cs' # value env ty
cases cs' vty vs = err keep ($vs) (convertv cs' (vty vs))
where
keep msg = --trace (msg++"\n"++render (ppTerm Unqualified 0 (T i cs))) $
VT wild (vty vs) (mapSnd ($vs) cs')
wild = case i of TWild _ -> True; _ -> False
convertv cs' vty =
case value2term (gloc env) [] vty of
Left i -> fail ("variable #"++show i++" is out of scope")
Right pty -> convert' cs' =<< paramValues'' env pty
convert cs' ty = convert' cs' =<< paramValues' env ty
convert' cs' ((pty,vs),pvs) =
do sts <- mapM (matchPattern cs') vs
return $ \ vs -> VV pty pvs $ map (err bug id . valueMatch env)
(mapFst ($vs) sts)
valueCase (p,t) = do p' <- measurePatt # inlinePattMacro p
pvs <- linPattVars p'
vt <- value (extend pvs env) t
return (p',\vs-> Bind $ \bs-> vt (push' p' bs pvs vs))
inlinePattMacro p =
case p of
PM qc -> do r <- resource env qc
case r of
VPatt p' -> inlinePattMacro p'
_ -> ppbug $ hang "Expected pattern macro:" 4
(show r)
_ -> composPattOp inlinePattMacro p
paramValues env ty = snd # paramValues' env ty
paramValues' env ty = paramValues'' env =<< nfx (global env) ty
paramValues'' env pty = do ats <- allParamValues (srcgr env) pty
pvs <- mapM (eval (global env) []) ats
return ((pty,ats),pvs)
push' p bs xs = if length bs/=length xs
then bug $ "push "++show (p,bs,xs)
else push bs xs
push :: Env -> LocalScope -> Stack -> Stack
push bs [] vs = vs
push bs (x:xs) vs = maybe err id (lookup x bs):push bs xs vs
where err = bug $ "Unbound pattern variable "++showIdent x
apply' :: CompleteEnv -> Term -> [OpenValue] -> Err OpenValue
apply' env t [] = value env t
apply' env t vs =
case t of
QC x -> return $ \ svs -> VCApp x (map ($svs) vs)
{-
Q x@(m,f) | m==cPredef -> return $
let constr = --trace ("predef "++show x) .
VApp x
in \ svs -> maybe constr id (Map.lookup f predefs)
$ map ($svs) vs
| otherwise -> do r <- resource env x
return $ \ svs -> vapply (gloc env) r (map ($svs) vs)
-}
App t1 t2 -> apply' env t1 . (:vs) =<< value env t2
_ -> do fv <- value env t
return $ \ svs -> vapply (gloc env) (fv svs) (map ($svs) vs)
vapply :: GLocation -> Value -> [Value] -> Value
vapply loc v [] = v
vapply loc v vs =
case v of
VError {} -> v
-- VClosure env (Abs b x t) -> beta gr env b x t vs
VAbs bt _ (Bind f) -> vbeta loc bt f vs
VApp pre vs1 -> delta' pre (vs1++vs)
where
delta' Trace (v1:v2:vs) = let vr = vapply loc v2 vs
in vtrace loc v1 vr
delta' pre vs = err msg vfv $ mapM (delta pre) (varyList vs)
--msg = const (VApp pre (vs1++vs))
msg = bug . (("Applying Predef."++showIdent (predefName pre)++": ")++)
VS (VV t pvs fs) s -> VS (VV t pvs [vapply loc f vs|f<-fs]) s
VFV fs -> vfv [vapply loc f vs|f<-fs]
VCApp f vs0 -> VCApp f (vs0++vs)
VMeta i env vs0 -> VMeta i env (vs0++vs)
VGen i vs0 -> VGen i (vs0++vs)
v -> bug $ "vapply "++show v++" "++show vs
vbeta loc bt f (v:vs) =
case (bt,v) of
(Implicit,VImplArg v) -> ap v
(Explicit, v) -> ap v
where
ap (VFV avs) = vfv [vapply loc (f v) vs|v<-avs]
ap v = vapply loc (f v) vs
vary (VFV vs) = vs
vary v = [v]
varyList = mapM vary
{-
beta env b x t (v:vs) =
case (b,v) of
(Implicit,VImplArg v) -> apply' (ext (x,v) env) t vs
(Explicit, v) -> apply' (ext (x,v) env) t vs
-}
vtrace loc arg res = trace (render (hang (pv arg) 4 ("->"<+>pv res))) res
where
pv v = case v of
VRec (f:as) -> hang (pf f) 4 (fsep (map pa as))
_ -> ppV v
pf (_,VString n) = pp n
pf (_,v) = ppV v
pa (_,v) = ppV v
ppV v = case value2term' True loc [] v of
Left i -> "variable #" <> pp i <+> "is out of scope"
Right t -> ppTerm Unqualified 10 t
-- | Convert a value back to a term
value2term :: GLocation -> [Ident] -> Value -> Either Int Term
value2term = value2term' False
value2term' stop loc xs v0 =
case v0 of
VApp pre vs -> liftM (foldl App (Q (cPredef,predefName pre))) (mapM v2t vs)
VCApp f vs -> liftM (foldl App (QC f)) (mapM v2t vs)
VGen j vs -> liftM2 (foldl App) (var j) (mapM v2t vs)
VMeta j env vs -> liftM (foldl App (Meta j)) (mapM v2t vs)
VProd bt v x f -> liftM2 (Prod bt x) (v2t v) (v2t' x f)
VAbs bt x f -> liftM (Abs bt x) (v2t' x f)
VInt n -> return (EInt n)
VFloat f -> return (EFloat f)
VString s -> return (if null s then Empty else K s)
VSort s -> return (Sort s)
VImplArg v -> liftM ImplArg (v2t v)
VTblType p res -> liftM2 Table (v2t p) (v2t res)
VRecType rs -> liftM RecType (mapM (\(l,v) -> fmap ((,) l) (v2t v)) rs)
VRec as -> liftM R (mapM (\(l,v) -> v2t v >>= \t -> return (l,(Nothing,t))) as)
VV t _ vs -> liftM (V t) (mapM v2t vs)
VT wild v cs -> v2t v >>= \t -> liftM (T ((if wild then TWild else TTyped) t)) (mapM nfcase cs)
VFV vs -> liftM FV (mapM v2t vs)
VC v1 v2 -> liftM2 C (v2t v1) (v2t v2)
VS v1 v2 -> liftM2 S (v2t v1) (v2t v2)
VP v l -> v2t v >>= \t -> return (P t l)
VPatt p -> return (EPatt p)
VPattType v -> v2t v >>= return . EPattType
VAlts v vvs -> liftM2 Alts (v2t v) (mapM (\(x,y) -> liftM2 (,) (v2t x) (v2t y)) vvs)
VStrs vs -> liftM Strs (mapM v2t vs)
-- VGlue v1 v2 -> Glue (v2t v1) (v2t v2)
-- VExtR v1 v2 -> ExtR (v2t v1) (v2t v2)
VError err -> return (Error err)
where
v2t = v2txs xs
v2txs = value2term' stop loc
v2t' x f = v2txs (x:xs) (bind f (gen xs))
var j
| j<length xs = Right (Vr (reverse xs !! j))
| otherwise = Left j
pushs xs e = foldr push e xs
push x (env,xs) = ((x,gen xs):env,x:xs)
gen xs = VGen (length xs) []
nfcase (p,f) = liftM ((,) p) (v2txs xs' (bind f env'))
where (env',xs') = pushs (pattVars p) ([],xs)
bind (Bind f) x = if stop
then VSort (identS "...") -- hmm
else f x
linPattVars p =
if null dups
then return pvs
else fail.render $ hang "Pattern is not linear. All variable names on the left-hand side must be distinct." 4 (ppPatt Unqualified 0 p)
where
allpvs = allPattVars p
pvs = nub allpvs
dups = allpvs \\ pvs
pattVars = nub . allPattVars
allPattVars p =
case p of
PV i -> [i]
PAs i p -> i:allPattVars p
_ -> collectPattOp allPattVars p
---
ix loc fn xs i =
if i<n
then xs !! i
else bugloc loc $ "(!!): index too large in "++fn++", "++show i++"<"++show n
where n = length xs
infixl 1 #,<# --,@@
f # x = fmap f x
mf <# mx = ap mf mx
--m1 @@ m2 = (m1 =<<) . m2
both f (x,y) = (,) # f x <# f y
bugloc loc s = ppbug $ ppL loc s
bug msg = ppbug msg
ppbug doc = error $ render $ hang "Internal error in Compute.ConcreteNew:" 4 doc

8
src/compiler/GF/Compile/Compute/Value.hs
View File

@@ -12,8 +12,8 @@ data Value
| VGen Int [Value] -- for lambda bound variables, possibly applied
| VMeta MetaId Env [Value]
-- -- | VClosure Env Term -- used in Typecheck.ConcreteNew
| VAbs BindType Ident Binding -- used in Compute.ConcreteNew
| VProd BindType Value Ident Binding -- used in Compute.ConcreteNew
| VAbs BindType Ident Binding -- used in Compute.Concrete
| VProd BindType Value Ident Binding -- used in Compute.Concrete
| VInt Int
| VFloat Double
| VString String
@@ -47,10 +47,10 @@ type Env = [(Ident,Value)]
-- | Predefined functions
data Predefined = Drop | Take | Tk | Dp | EqStr | Occur | Occurs | ToUpper
| ToLower | IsUpper | Length | Plus | EqInt | LessInt
| ToLower | IsUpper | Length | Plus | EqInt | LessInt
{- | Show | Read | ToStr | MapStr | EqVal -}
| Error | Trace
-- Canonical values below:
| PBool | PFalse | PTrue | Int | Float | Ints | NonExist
| PBool | PFalse | PTrue | Int | Float | Ints | NonExist
| BIND | SOFT_BIND | SOFT_SPACE | CAPIT | ALL_CAPIT
deriving (Show,Eq,Ord,Ix,Bounded,Enum)

12
src/compiler/GF/Compile/GeneratePMCFG.hs
View File

@@ -25,7 +25,7 @@ import GF.Data.BacktrackM
import GF.Data.Operations
import GF.Infra.UseIO (ePutStr,ePutStrLn) -- IOE,
import GF.Data.Utilities (updateNthM) --updateNth
import GF.Compile.Compute.ConcreteNew(normalForm,resourceValues)
import GF.Compile.Compute.Concrete(normalForm,resourceValues)
import qualified Data.Map as Map
import qualified Data.Set as Set
import qualified Data.List as List
@@ -82,7 +82,7 @@ addPMCFG opts gr cenv opath am cm seqs id (GF.Grammar.CncFun mty@(Just (cat,cont
(goB b1 CNil [])
(pres,pargs)
pmcfg = getPMCFG pmcfgEnv1
stats = let PMCFG prods funs = pmcfg
(s,e) = bounds funs
!prods_cnt = length prods
@@ -103,7 +103,7 @@ addPMCFG opts gr cenv opath am cm seqs id (GF.Grammar.CncFun mty@(Just (cat,cont
newArgs = map getFIds newArgs'
in addFunction env0 newCat fun newArgs
addPMCFG opts gr cenv opath am cm seqs id (GF.Grammar.CncCat mty@(Just (L _ lincat))
addPMCFG opts gr cenv opath am cm seqs id (GF.Grammar.CncCat mty@(Just (L _ lincat))
mdef@(Just (L loc1 def))
mref@(Just (L loc2 ref))
mprn
@@ -162,7 +162,7 @@ pgfCncCat :: SourceGrammar -> Type -> Int -> CncCat
pgfCncCat gr lincat index =
let ((_,size),schema) = computeCatRange gr lincat
in PGF.CncCat index (index+size-1)
(mkArray (map (renderStyle style{mode=OneLineMode} . ppPath)
(mkArray (map (renderStyle style{mode=OneLineMode} . ppPath)
(getStrPaths schema)))
where
getStrPaths :: Schema Identity s c -> [Path]
@@ -243,7 +243,7 @@ choices nr path = do (args,_) <- get
| (value,index) <- values])
descend schema path rpath = bug $ "descend "++show (schema,path,rpath)
updateEnv path value gr c (args,seq) =
updateEnv path value gr c (args,seq) =
case updateNthM (restrictProtoFCat path value) nr args of
Just args -> c value (args,seq)
Nothing -> bug "conflict in updateEnv"
@@ -606,7 +606,7 @@ restrictProtoFCat path v (PFCat cat f schema) = do
Just index -> return (CPar (m,[(v,index)]))
Nothing -> mzero
addConstraint CNil v (CStr _) = bug "restrictProtoFCat: string path"
update k0 f [] = return []
update k0 f (x@(k,Identity v):xs)
| k0 == k = do v <- f v

6
src/compiler/GF/Compile/GrammarToCanonical.hs
View File

@@ -19,7 +19,7 @@ import GF.Compile.Compute.Value(Predefined(..))
import GF.Infra.Ident(ModuleName(..),Ident,prefixIdent,showIdent,isWildIdent)
import GF.Infra.Option(optionsPGF)
import PGF.Internal(Literal(..))
import GF.Compile.Compute.ConcreteNew(normalForm,resourceValues)
import GF.Compile.Compute.Concrete(normalForm,resourceValues)
import GF.Grammar.Canonical as C
import Debug.Trace
@@ -72,7 +72,7 @@ concrete2canonical gr cenv absname cnc modinfo =
[lincat|(_,Left lincat)<-defs]
[lin|(_,Right lin)<-defs]
where
defs = concatMap (toCanonical gr absname cenv) .
defs = concatMap (toCanonical gr absname cenv) .
M.toList $
jments modinfo
@@ -189,7 +189,7 @@ convert' gr vs = ppT
_ -> VarValue (gQId cPredef n) -- hmm
where
p = PredefValue . PredefId
ppP p =
case p of
PC c ps -> ParamPattern (Param (gId c) (map ppP ps))

16
src/compiler/GF/Compile/Optimize.hs
View File

@@ -6,7 +6,7 @@
-- Stability : (stable)
-- Portability : (portable)
--
-- > CVS $Date: 2005/09/16 13:56:13 $
-- > CVS $Date: 2005/09/16 13:56:13 $
-- > CVS $Author: aarne $
-- > CVS $Revision: 1.18 $
--
@@ -21,7 +21,7 @@ import GF.Grammar.Printer
import GF.Grammar.Macros
import GF.Grammar.Lookup
import GF.Grammar.Predef
import GF.Compile.Compute.ConcreteNew(GlobalEnv,normalForm,resourceValues)
import GF.Compile.Compute.Concrete(GlobalEnv,normalForm,resourceValues)
import GF.Data.Operations
import GF.Infra.Option
@@ -90,7 +90,7 @@ evalInfo opts resenv sgr m c info = do
let ppr' = fmap (evalPrintname resenv c) ppr
return $ CncFun mt pde' ppr' mpmcfg -- only cat in type actually needed
{-
ResOper pty pde
ResOper pty pde
| not new && OptExpand `Set.member` optim -> do
pde' <- case pde of
Just (L loc de) -> do de <- computeConcrete gr de
@@ -171,13 +171,13 @@ mkLinDefault gr typ = liftM (Abs Explicit varStr) $ mkDefField typ
_ -> Bad (render ("linearization type field cannot be" <+> typ))
mkLinReference :: SourceGrammar -> Type -> Err Term
mkLinReference gr typ =
liftM (Abs Explicit varStr) $
mkLinReference gr typ =
liftM (Abs Explicit varStr) $
case mkDefField typ (Vr varStr) of
Bad "no string" -> return Empty
x -> x
where
mkDefField ty trm =
mkDefField ty trm =
case ty of
Table pty ty -> do ps <- allParamValues gr pty
case ps of
@@ -203,7 +203,7 @@ factor param c i t =
T (TComp ty) cs -> factors ty [(p, factor param c (i+1) v) | (p, v) <- cs]
_ -> composSafeOp (factor param c i) t
where
factors ty pvs0
factors ty pvs0
| not param = V ty (map snd pvs0)
factors ty [] = V ty []
factors ty pvs0@[(p,v)] = V ty [v]
@@ -224,7 +224,7 @@ factor param c i t =
replace :: Term -> Term -> Term -> Term
replace old new trm =
case trm of
-- these are the important cases, since they can correspond to patterns
-- these are the important cases, since they can correspond to patterns
QC _ | trm == old -> new
App _ _ | trm == old -> new
R _ | trm == old -> new

38
src/compiler/GF/Compile/TypeCheck/ConcreteNew.hs
View File

@@ -10,7 +10,7 @@ import GF.Grammar hiding (Env, VGen, VApp, VRecType)
import GF.Grammar.Lookup
import GF.Grammar.Predef
import GF.Grammar.Lockfield
import GF.Compile.Compute.ConcreteNew
import GF.Compile.Compute.Concrete
import GF.Compile.Compute.Predef(predef,predefName)
import GF.Infra.CheckM
import GF.Data.Operations
@@ -133,7 +133,7 @@ tcRho ge scope t@(RecType rs) (Just ty) = do
[] -> unifyVar ge scope i env vs vtypePType
_ -> return ()
ty -> do ty <- zonkTerm =<< tc_value2term (geLoc ge) (scopeVars scope) ty
tcError ("The record type" <+> ppTerm Unqualified 0 t $$
tcError ("The record type" <+> ppTerm Unqualified 0 t $$
"cannot be of type" <+> ppTerm Unqualified 0 ty)
(rs,mb_ty) <- tcRecTypeFields ge scope rs (Just ty')
return (f (RecType rs),ty)
@@ -187,7 +187,7 @@ tcRho ge scope (R rs) (Just ty) = do
case ty' of
(VRecType ltys) -> do lttys <- checkRecFields ge scope rs ltys
rs <- mapM (\(l,t,ty) -> tc_value2term (geLoc ge) (scopeVars scope) ty >>= \ty -> return (l, (Just ty, t))) lttys
return ((f . R) rs,
return ((f . R) rs,
VRecType [(l, ty) | (l,t,ty) <- lttys]
)
ty -> do lttys <- inferRecFields ge scope rs
@@ -277,11 +277,11 @@ tcApp ge scope (App fun arg) = -- APP2
varg <- liftErr (eval ge (scopeEnv scope) arg)
return (App fun arg, res_ty varg)
tcApp ge scope (Q id) = -- VAR (global)
mkTcA (lookupOverloadTypes (geGrammar ge) id) `bindTcA` \(t,ty) ->
mkTcA (lookupOverloadTypes (geGrammar ge) id) `bindTcA` \(t,ty) ->
do ty <- liftErr (eval ge [] ty)
return (t,ty)
tcApp ge scope (QC id) = -- VAR (global)
mkTcA (lookupOverloadTypes (geGrammar ge) id) `bindTcA` \(t,ty) ->
mkTcA (lookupOverloadTypes (geGrammar ge) id) `bindTcA` \(t,ty) ->
do ty <- liftErr (eval ge [] ty)
return (t,ty)
tcApp ge scope t =
@@ -350,7 +350,7 @@ tcPatt ge scope (PM q) ty0 = do
Bad err -> tcError (pp err)
tcPatt ge scope p ty = unimplemented ("tcPatt "++show p)
inferRecFields ge scope rs =
inferRecFields ge scope rs =
mapM (\(l,r) -> tcRecField ge scope l r Nothing) rs
checkRecFields ge scope [] ltys
@@ -368,7 +368,7 @@ checkRecFields ge scope ((l,t):lts) ltys =
where
takeIt l1 [] = (Nothing, [])
takeIt l1 (lty@(l2,ty):ltys)
| l1 == l2 = (Just ty,ltys)
| l1 == l2 = (Just ty,ltys)
| otherwise = let (mb_ty,ltys') = takeIt l1 ltys
in (mb_ty,lty:ltys')
@@ -390,7 +390,7 @@ tcRecTypeFields ge scope ((l,ty):rs) mb_ty = do
| s == cPType -> return mb_ty
VMeta _ _ _ -> return mb_ty
_ -> do sort <- zonkTerm =<< tc_value2term (geLoc ge) (scopeVars scope) sort
tcError ("The record type field" <+> l <+> ':' <+> ppTerm Unqualified 0 ty $$
tcError ("The record type field" <+> l <+> ':' <+> ppTerm Unqualified 0 ty $$
"cannot be of type" <+> ppTerm Unqualified 0 sort)
(rs,mb_ty) <- tcRecTypeFields ge scope rs mb_ty
return ((l,ty):rs,mb_ty)
@@ -444,11 +444,11 @@ subsCheckRho ge scope t (VApp p1 _) (VApp p2 _) -- Rule
| predefName p1 == cInts && predefName p2 == cInt = return t
subsCheckRho ge scope t (VApp p1 [VInt i]) (VApp p2 [VInt j]) -- Rule INT2
| predefName p1 == cInts && predefName p2 == cInts =
if i <= j
if i <= j
then return t
else tcError ("Ints" <+> i <+> "is not a subtype of" <+> "Ints" <+> j)
subsCheckRho ge scope t ty1@(VRecType rs1) ty2@(VRecType rs2) = do -- Rule REC
let mkAccess scope t =
let mkAccess scope t =
case t of
ExtR t1 t2 -> do (scope,mkProj1,mkWrap1) <- mkAccess scope t1
(scope,mkProj2,mkWrap2) <- mkAccess scope t2
@@ -557,7 +557,7 @@ unify ge scope v (VMeta i env vs) = unifyVar ge scope i env vs v
unify ge scope v1 v2 = do
t1 <- zonkTerm =<< tc_value2term (geLoc ge) (scopeVars scope) v1
t2 <- zonkTerm =<< tc_value2term (geLoc ge) (scopeVars scope) v2
tcError ("Cannot unify terms:" <+> (ppTerm Unqualified 0 t1 $$
tcError ("Cannot unify terms:" <+> (ppTerm Unqualified 0 t1 $$
ppTerm Unqualified 0 t2))
-- | Invariant: tv1 is a flexible type variable
@@ -609,7 +609,7 @@ quantify ge scope t tvs ty0 = do
ty <- tc_value2term (geLoc ge) (scopeVars scope) ty0
let used_bndrs = nub (bndrs ty) -- Avoid quantified type variables in use
new_bndrs = take (length tvs) (allBinders \\ used_bndrs)
mapM_ bind (tvs `zip` new_bndrs) -- 'bind' is just a cunning way
mapM_ bind (tvs `zip` new_bndrs) -- 'bind' is just a cunning way
ty <- zonkTerm ty -- of doing the substitution
vty <- liftErr (eval ge [] (foldr (\v ty -> Prod Implicit v typeType ty) ty new_bndrs))
return (foldr (Abs Implicit) t new_bndrs,vty)
@@ -619,7 +619,7 @@ quantify ge scope t tvs ty0 = do
bndrs (Prod _ x t1 t2) = [x] ++ bndrs t1 ++ bndrs t2
bndrs _ = []
allBinders :: [Ident] -- a,b,..z, a1, b1,... z1, a2, b2,...
allBinders :: [Ident] -- a,b,..z, a1, b1,... z1, a2, b2,...
allBinders = [ identS [x] | x <- ['a'..'z'] ] ++
[ identS (x : show i) | i <- [1 :: Integer ..], x <- ['a'..'z']]
@@ -688,12 +688,12 @@ runTcM f = case unTcM f IntMap.empty [] of
TcFail (msg:msgs) -> do checkWarnings msgs; checkError msg
newMeta :: Scope -> Sigma -> TcM MetaId
newMeta scope ty = TcM (\ms msgs ->
newMeta scope ty = TcM (\ms msgs ->
let i = IntMap.size ms
in TcOk i (IntMap.insert i (Unbound scope ty) ms) msgs)
getMeta :: MetaId -> TcM MetaValue
getMeta i = TcM (\ms msgs ->
getMeta i = TcM (\ms msgs ->
case IntMap.lookup i ms of
Just mv -> TcOk mv ms msgs
Nothing -> TcFail (("Unknown metavariable" <+> ppMeta i) : msgs))
@@ -702,7 +702,7 @@ setMeta :: MetaId -> MetaValue -> TcM ()
setMeta i mv = TcM (\ms msgs -> TcOk () (IntMap.insert i mv ms) msgs)
newVar :: Scope -> Ident
newVar scope = head [x | i <- [1..],
newVar scope = head [x | i <- [1..],
let x = identS ('v':show i),
isFree scope x]
where
@@ -721,7 +721,7 @@ getMetaVars loc sc_tys = do
return (foldr go [] tys)
where
-- Get the MetaIds from a term; no duplicates in result
go (Vr tv) acc = acc
go (Vr tv) acc = acc
go (App x y) acc = go x (go y acc)
go (Meta i) acc
| i `elem` acc = acc
@@ -741,7 +741,7 @@ getFreeVars loc sc_tys = do
tys <- mapM (\(scope,ty) -> zonkTerm =<< tc_value2term loc (scopeVars scope) ty) sc_tys
return (foldr (go []) [] tys)
where
go bound (Vr tv) acc
go bound (Vr tv) acc
| tv `elem` bound = acc
| tv `elem` acc = acc
| otherwise = tv : acc
@@ -771,7 +771,7 @@ tc_value2term loc xs v =
data TcA x a
data TcA x a
= TcSingle (MetaStore -> [Message] -> TcResult a)
| TcMany [x] (MetaStore -> [Message] -> [(a,MetaStore,[Message])])