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move GF.Devel.GrammarToGFCC to GF.Compile.GrammarToGFCC

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kr.angelov
2008-05-22 14:46:18 +00:00
parent d8cabf0263
commit fd01ba1b68
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src-3.0/GF/Compile/GrammarToGFCC.hs Normal file
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{-# LANGUAGE PatternGuards #-}
module GF.Compile.GrammarToGFCC (prGrammar2gfcc,mkCanon2gfcc,addParsers) where
import GF.Devel.OptimizeGF (unshareModule)
import GF.Grammar.Grammar
import qualified GF.Grammar.Lookup as Look
import qualified GF.GFCC.Macros as CM
import qualified GF.GFCC.DataGFCC as C
import qualified GF.GFCC.DataGFCC as D
import GF.GFCC.CId
import GF.Grammar.Predef
import qualified GF.Grammar.Abstract as A
import qualified GF.Grammar.Macros as GM
import qualified GF.Infra.Modules as M
import qualified GF.Infra.Option as O
import GF.Conversion.SimpleToFCFG (convertConcrete)
import GF.Parsing.FCFG.PInfo (buildFCFPInfo)
import GF.Devel.PrGrammar
import GF.Devel.PrintGFCC
import GF.Devel.ModDeps
import GF.Infra.Ident
import GF.Infra.Option
import GF.Data.Operations
import GF.Text.UTF8
import Data.List
import Data.Char (isDigit,isSpace)
import qualified Data.Map as Map
import qualified Data.ByteString.Char8 as BS
import Debug.Trace ----
-- when developing, swap commenting
--traceD s t = trace s t
traceD s t = t
-- the main function: generate GFCC from GF.
prGrammar2gfcc :: Options -> String -> SourceGrammar -> (String,String)
prGrammar2gfcc opts cnc gr = (abs,printGFCC gc) where
(abs,gc) = mkCanon2gfcc opts cnc gr
mkCanon2gfcc :: Options -> String -> SourceGrammar -> (String,D.GFCC)
mkCanon2gfcc opts cnc gr =
(prIdent abs, (canon2gfcc opts pars . reorder abs . canon2canon abs) gr)
where
abs = err error id $ M.abstractOfConcrete gr (identC (BS.pack cnc))
pars = mkParamLincat gr
-- Adds parsers for all concretes
addParsers :: D.GFCC -> D.GFCC
addParsers gfcc = gfcc { D.concretes = Map.map conv (D.concretes gfcc) }
where
conv cnc = cnc { D.parser = Just (buildFCFPInfo (convertConcrete (D.abstract gfcc) cnc)) }
-- Generate GFCC from GFCM.
-- this assumes a grammar translated by canon2canon
canon2gfcc :: Options -> (Ident -> Ident -> C.Term) -> SourceGrammar -> D.GFCC
canon2gfcc opts pars cgr@(M.MGrammar ((a,M.ModMod abm):cms)) =
(if (oElem (iOpt "show_canon") opts) then trace (prGrammar cgr) else id) $
D.GFCC an cns gflags abs cncs
where
-- abstract
an = (i2i a)
cns = map (i2i . fst) cms
abs = D.Abstr aflags funs cats catfuns
gflags = Map.fromList [(mkCId fg,x) | Just x <- [getOptVal opts (aOpt fg)]]
where fg = "firstlang"
aflags = Map.fromList [(mkCId f,x) | Opt (f,[x]) <- M.flags abm]
mkDef pty = case pty of
Yes t -> mkExp t
_ -> CM.primNotion
-- concretes
lfuns = [(f', (mkType ty, mkDef pty)) |
(f,AbsFun (Yes ty) pty) <- tree2list (M.jments abm), let f' = i2i f]
funs = Map.fromAscList lfuns
lcats = [(i2i c, mkContext cont) |
(c,AbsCat (Yes cont) _) <- tree2list (M.jments abm)]
cats = Map.fromAscList lcats
catfuns = Map.fromList
[(cat,[f | (f, (C.DTyp _ c _,_)) <- lfuns, c==cat]) | (cat,_) <- lcats]
cncs = Map.fromList [mkConcr lang (i2i lang) mo | (lang,M.ModMod mo) <- cms]
mkConcr lang0 lang mo =
(lang,D.Concr flags lins opers lincats lindefs printnames params fcfg)
where
js = tree2list (M.jments mo)
flags = Map.fromList [(mkCId f,x) | Opt (f,[x]) <- M.flags mo]
opers = Map.fromAscList [] -- opers will be created as optimization
utf = if elem (Opt ("coding",["utf8"])) (M.flags mo)
then D.convertStringsInTerm decodeUTF8 else id
lins = Map.fromAscList
[(i2i f, utf (mkTerm tr)) | (f,CncFun _ (Yes tr) _) <- js]
lincats = Map.fromAscList
[(i2i c, mkCType ty) | (c,CncCat (Yes ty) _ _) <- js]
lindefs = Map.fromAscList
[(i2i c, mkTerm tr) | (c,CncCat _ (Yes tr) _) <- js]
printnames = Map.union
(Map.fromAscList [(i2i f, mkTerm tr) | (f,CncFun _ _ (Yes tr)) <- js])
(Map.fromAscList [(i2i f, mkTerm tr) | (f,CncCat _ _ (Yes tr)) <- js])
params = Map.fromAscList
[(i2i c, pars lang0 c) | (c,CncCat (Yes ty) _ _) <- js]
fcfg = Nothing
i2i :: Ident -> CId
i2i = CId . ident2bs
mkType :: A.Type -> C.Type
mkType t = case GM.typeForm t of
Ok (hyps,(_,cat),args) -> C.DTyp (mkContext hyps) (i2i cat) (map mkExp args)
mkExp :: A.Term -> C.Exp
mkExp t = case t of
A.Eqs eqs -> C.EEq [C.Equ (map mkPatt ps) (mkExp e) | (ps,e) <- eqs]
_ -> case GM.termForm t of
Ok (xx,c,args) -> C.DTr [i2i x | x <- xx] (mkAt c) (map mkExp args)
where
mkAt c = case c of
Q _ c -> C.AC $ i2i c
QC _ c -> C.AC $ i2i c
Vr x -> C.AV $ i2i x
EInt i -> C.AI i
EFloat f -> C.AF f
K s -> C.AS s
Meta (MetaSymb i) -> C.AM $ toInteger i
_ -> C.AM 0
mkPatt p = uncurry CM.tree $ case p of
A.PP _ c ps -> (C.AC (i2i c), map mkPatt ps)
A.PV x -> (C.AV (i2i x), [])
A.PW -> (C.AV wildCId, [])
A.PInt i -> (C.AI i, [])
mkContext :: A.Context -> [C.Hypo]
mkContext hyps = [C.Hyp (i2i x) (mkType ty) | (x,ty) <- hyps]
mkTerm :: Term -> C.Term
mkTerm tr = case tr of
Vr (IA _ i) -> C.V i
Vr (IAV _ _ i) -> C.V i
Vr (IC s) | isDigit (BS.last s) ->
C.V ((read . BS.unpack . snd . BS.spanEnd isDigit) s)
---- from gf parser of gfc
EInt i -> C.C $ fromInteger i
R rs -> C.R [mkTerm t | (_, (_,t)) <- rs]
P t l -> C.P (mkTerm t) (C.C (mkLab l))
TSh _ _ -> error $ show tr
T _ cs -> C.R [mkTerm t | (_,t) <- cs] ------
V _ cs -> C.R [mkTerm t | t <- cs]
S t p -> C.P (mkTerm t) (mkTerm p)
C s t -> C.S $ concatMap flats [mkTerm x | x <- [s,t]]
FV ts -> C.FV [mkTerm t | t <- ts]
K s -> C.K (C.KS s)
----- K (KP ss _) -> C.K (C.KP ss []) ---- TODO: prefix variants
Empty -> C.S []
App _ _ -> prtTrace tr $ C.C 66661 ---- for debugging
Abs _ t -> mkTerm t ---- only on toplevel
Alts (td,tvs) ->
C.K (C.KP (strings td) [C.Var (strings u) (strings v) | (u,v) <- tvs])
_ -> prtTrace tr $ C.S [C.K (C.KS (A.prt tr +++ "66662"))] ---- for debugging
where
mkLab (LIdent l) = case BS.unpack l of
'_':ds -> (read ds) :: Int
_ -> prtTrace tr $ 66663
strings t = case t of
K s -> [s]
C u v -> strings u ++ strings v
Strs ss -> concatMap strings ss
_ -> prtTrace tr $ ["66660"]
flats t = case t of
C.S ts -> concatMap flats ts
_ -> [t]
-- encoding GFCC-internal lincats as terms
mkCType :: Type -> C.Term
mkCType t = case t of
EInt i -> C.C $ fromInteger i
RecType rs -> C.R [mkCType t | (_, t) <- rs]
Table pt vt -> case pt of
EInt i -> C.R $ replicate (1 + fromInteger i) $ mkCType vt
RecType rs -> mkCType $ foldr Table vt (map snd rs)
Sort s | s == cStr -> C.S [] --- Str only
_ | Just i <- GM.isTypeInts t -> C.C $ fromInteger i
_ -> error $ "mkCType " ++ show t
-- encoding showable lincats (as in source gf) as terms
mkParamLincat :: SourceGrammar -> Ident -> Ident -> C.Term
mkParamLincat sgr lang cat = errVal (C.R [C.S []]) $ do
typ <- Look.lookupLincat sgr lang cat
mkPType typ
where
mkPType typ = case typ of
RecType lts -> do
ts <- mapM (mkPType . snd) lts
return $ C.R [ C.P (kks $ prt_ l) t | ((l,_),t) <- zip lts ts]
Table (RecType lts) v -> do
ps <- mapM (mkPType . snd) lts
v' <- mkPType v
return $ foldr (\p v -> C.S [p,v]) v' ps
Table p v -> do
p' <- mkPType p
v' <- mkPType v
return $ C.S [p',v']
Sort s | s == cStr -> return $ C.S []
_ -> return $
C.FV $ map (kks . filter showable . prt_) $
errVal [] $ Look.allParamValues sgr typ
showable c = not (isSpace c) ---- || (c == ' ') -- to eliminate \n in records
kks = C.K . C.KS
-- return just one module per language
reorder :: Ident -> SourceGrammar -> SourceGrammar
reorder abs cg = M.MGrammar $
(abs, M.ModMod $
M.Module M.MTAbstract M.MSComplete aflags [] [] adefs):
[(c, M.ModMod $
M.Module (M.MTConcrete abs) M.MSComplete fs [] [] (sorted2tree js))
| (c,(fs,js)) <- cncs]
where
mos = M.allModMod cg
adefs = sorted2tree $ sortIds $
predefADefs ++ Look.allOrigInfos cg abs
predefADefs =
[(c, AbsCat (Yes []) Nope) | c <- [cFloat,cInt,cString]]
aflags = nubFlags $
concat [M.flags mo | (_,mo) <- M.allModMod cg, M.isModAbs mo]
cncs = sortIds [(lang, concr lang) | lang <- M.allConcretes cg abs]
concr la = (nubFlags flags,
sortIds (predefCDefs ++ jments)) where
jments = Look.allOrigInfos cg la
flags = concat [M.flags mo |
(i,mo) <- mos, M.isModCnc mo,
Just r <- [lookup i (M.allExtendSpecs cg la)]]
predefCDefs =
[(c, CncCat (Yes GM.defLinType) Nope Nope) | c <- [cInt,cFloat,cString]]
sortIds = sortBy (\ (f,_) (g,_) -> compare f g)
nubFlags = nubBy (\ (Opt (f,_)) (Opt (g,_)) -> f == g)
-- one grammar per language - needed for symtab generation
repartition :: Ident -> SourceGrammar -> [SourceGrammar]
repartition abs cg = [M.partOfGrammar cg (lang,mo) |
let mos = M.allModMod cg,
lang <- M.allConcretes cg abs,
let mo = errVal
(error ("no module found for " ++ A.prt lang)) $ M.lookupModule cg lang
]
-- translate tables and records to arrays, parameters and labels to indices
canon2canon :: Ident -> SourceGrammar -> SourceGrammar
canon2canon abs =
recollect . map cl2cl . repartition abs . purgeGrammar abs
where
recollect = M.MGrammar . nubBy (\ (i,_) (j,_) -> i==j) . concatMap M.modules
cl2cl = M.MGrammar . js2js . map (c2c p2p) . M.modules
js2js ms = map (c2c (j2j (M.MGrammar ms))) ms
c2c f2 (c,m) = case m of
M.ModMod mo@(M.Module _ _ _ _ _ js) ->
(c, M.ModMod $ M.replaceJudgements mo $ mapTree f2 js)
_ -> (c,m)
j2j cg (f,j) = case j of
CncFun x (Yes tr) z -> (f,CncFun x (Yes (t2t tr)) z)
CncCat (Yes ty) (Yes x) y -> (f,CncCat (Yes (ty2ty ty)) (Yes (t2t x)) y)
_ -> (f,j)
where
t2t = term2term cg pv
ty2ty = type2type cg pv
pv@(labels,untyps,typs) = trs $ paramValues cg
-- flatten record arguments of param constructors
p2p (f,j) = case j of
ResParam (Yes (ps,v)) ->
(f,ResParam (Yes ([(c,concatMap unRec cont) | (c,cont) <- ps],Nothing)))
_ -> (f,j)
unRec (x,ty) = case ty of
RecType fs -> [ity | (_,typ) <- fs, ity <- unRec (identW,typ)]
_ -> [(x,ty)]
----
trs v = traceD (tr v) v
tr (labels,untyps,typs) =
("LABELS:" ++++
unlines [A.prt c ++ "." ++ unwords (map A.prt l) +++ "=" +++ show i |
((c,l),i) <- Map.toList labels]) ++++
("UNTYPS:" ++++ unlines [A.prt t +++ "=" +++ show i |
(t,i) <- Map.toList untyps]) ++++
("TYPS:" ++++ unlines [A.prt t +++ "=" +++ show (Map.assocs i) |
(t,i) <- Map.toList typs])
----
purgeGrammar :: Ident -> SourceGrammar -> SourceGrammar
purgeGrammar abstr gr =
(M.MGrammar . list . map unopt . filter complete . purge . M.modules) gr
where
list ms = traceD ("MODULES" +++ unwords (map (prt . fst) ms)) ms
purge = nubBy (\x y -> fst x == fst y) . filter (flip elem needed . fst)
needed = nub $ concatMap (requiredCanModules isSingle gr) acncs
acncs = abstr : M.allConcretes gr abstr
isSingle = True
complete (i,M.ModMod m) = M.isCompleteModule m --- not . isIncompleteCanon
unopt = unshareModule gr -- subexp elim undone when compiled
type ParamEnv =
(Map.Map (Ident,[Label]) (Type,Integer), -- numbered labels
Map.Map Term Integer, -- untyped terms to values
Map.Map Type (Map.Map Term Integer)) -- types to their terms to values
--- gathers those param types that are actually used in lincats and lin terms
paramValues :: SourceGrammar -> ParamEnv
paramValues cgr = (labels,untyps,typs) where
partyps = nub $
--- [App (Q (IC "Predef") (IC "Ints")) (EInt i) | i <- [1,9]] ---linTypeInt
{-
[ty |
(_,(_,CncCat (Yes (RecType ls)) _ _)) <- jments,
ty0 <- [ty | (_, ty) <- unlockTyp ls],
ty <- typsFrom ty0
-}
[ty |
(_,(_,CncCat (Yes ty0) _ _)) <- jments,
ty <- typsFrom ty0
] ++ [
Q m ty |
(m,(ty,ResParam _)) <- jments
] ++ [ty |
(_,(_,CncFun _ (Yes tr) _)) <- jments,
ty <- err (const []) snd $ appSTM (typsFromTrm tr) []
]
params = [(ty, errVal (traceD ("UNKNOWN PARAM TYPE" +++ show ty) []) $
Look.allParamValues cgr ty) | ty <- partyps]
typsFrom ty = unlockTy ty : case ty of
Table p t -> typsFrom p ++ typsFrom t
RecType ls -> concat [typsFrom t | (_, t) <- ls]
_ -> []
typsFromTrm :: Term -> STM [Type] Term
typsFromTrm tr = case tr of
R fs -> mapM_ (typsFromField . snd) fs >> return tr
where
typsFromField (mty, t) = case mty of
Just x -> updateSTM (x:) >> typsFromTrm t
_ -> typsFromTrm t
V ty ts -> updateSTM (ty:) >> mapM_ typsFromTrm ts >> return tr
T (TTyped ty) cs ->
updateSTM (ty:) >> mapM_ typsFromTrm [t | (_, t) <- cs] >> return tr
T (TComp ty) cs ->
updateSTM (ty:) >> mapM_ typsFromTrm [t | (_, t) <- cs] >> return tr
_ -> GM.composOp typsFromTrm tr
jments =
[(m,j) | (m,mo) <- M.allModMod cgr, j <- tree2list $ M.jments mo]
typs =
Map.fromList [(ci,Map.fromList (zip vs [0..])) | (ci,vs) <- params]
untyps =
Map.fromList $ concatMap Map.toList [typ | (_,typ) <- Map.toList typs]
lincats =
[(cat,[f | let RecType fs = GM.defLinType, f <- fs]) | cat <- [cInt,cFloat, cString]] ++
reverse ---- TODO: really those lincats that are reached
---- reverse is enough to expel overshadowed ones...
[(cat,ls) | (_,(cat,CncCat (Yes ty) _ _)) <- jments,
RecType ls <- [unlockTy ty]]
labels = Map.fromList $ concat
[((cat,[lab]),(typ,i)):
[((cat,[LVar v]),(typ,toInteger (mx + v))) | v <- [0,1]] ++ ---- 1 or 2 vars
[((cat,[lab,lab2]),(ty,j)) |
rs <- getRec typ, ((lab2, ty),j) <- zip rs [0..]]
|
(cat,ls) <- lincats, ((lab, typ),i) <- zip ls [0..], let mx = length ls]
-- go to tables recursively
---- TODO: even go to deeper records
where
getRec typ = case typ of
RecType rs -> [rs] ---- [unlockTyp rs] -- (sort (unlockTyp ls))
Table _ t -> getRec t
_ -> []
type2type :: SourceGrammar -> ParamEnv -> Type -> Type
type2type cgr env@(labels,untyps,typs) ty = case ty of
RecType rs ->
RecType [(mkLab i, t2t t) | (i,(l, t)) <- zip [0..] (unlockTyp rs)]
Table pt vt -> Table (t2t pt) (t2t vt)
QC _ _ -> look ty
_ -> ty
where
t2t = type2type cgr env
look ty = EInt $ (+ (-1)) $ toInteger $ case Map.lookup ty typs of
Just vs -> length $ Map.assocs vs
_ -> trace ("unknown partype " ++ show ty) 66669
term2term :: SourceGrammar -> ParamEnv -> Term -> Term
term2term cgr env@(labels,untyps,typs) tr = case tr of
App _ _ -> mkValCase (unrec tr)
QC _ _ -> mkValCase tr
R rs -> R [(mkLab i, (Nothing, t2t t)) |
(i,(l,(_,t))) <- zip [0..] (sort (unlock rs))]
P t l -> r2r tr
PI t l i -> EInt $ toInteger i
T (TWild _) _ -> error $ "wild" +++ prt tr
T (TComp ty) cs -> t2t $ V ty $ map snd cs ---- should be elim'ed in tc
T (TTyped ty) cs -> t2t $ V ty $ map snd cs ---- should be elim'ed in tc
V ty ts -> mkCurry $ V ty [t2t t | t <- ts]
S t p -> mkCurrySel (t2t t) (t2t p)
_ -> GM.composSafeOp t2t tr
where
t2t = term2term cgr env
unrec t = case t of
App f (R fs) -> GM.mkApp (unrec f) [unrec u | (_,(_,u)) <- fs]
_ -> GM.composSafeOp unrec t
mkValCase tr = case appSTM (doVar tr) [] of
Ok (tr', st@(_:_)) -> t2t $ comp $ foldr mkCase tr' st
_ -> valNum $ comp tr
--- this is mainly needed for parameter record projections
---- was: errVal t $ Compute.computeConcreteRec cgr t
comp t = case t of
T (TComp typ) ts -> comp $ V typ (map (comp . snd) ts) ---- should...
T (TTyped typ) ts -> comp $ V typ (map (comp . snd) ts) ---- should
V typ ts -> V typ (map comp ts)
S tb (FV ts) -> FV $ map (comp . S tb) ts
S (V typ ts) v0 -> err error id $ do
let v = comp v0
return $ maybe t (comp . (ts !!) . fromInteger) $ Map.lookup v untyps
R r -> R [(l,(ty,comp t)) | (l,(ty,t)) <- r]
P (R r) l -> maybe t (comp . snd) $ lookup l r
_ -> GM.composSafeOp comp t
doVar :: Term -> STM [((Type,[Term]),(Term,Term))] Term
doVar tr = case getLab tr of
Ok (cat, lab) -> do
k <- readSTM >>= return . length
let tr' = Vr $ identC $ (BS.pack (show k)) -----
let tyvs = case Map.lookup (cat,lab) labels of
Just (ty,_) -> case Map.lookup ty typs of
Just vs -> (ty,[t |
(t,_) <- sortBy (\x y -> compare (snd x) (snd y))
(Map.assocs vs)])
_ -> error $ "doVar1" +++ A.prt ty
_ -> error $ "doVar2" +++ A.prt tr +++ show (cat,lab) ---- debug
updateSTM ((tyvs, (tr', tr)):)
return tr'
_ -> GM.composOp doVar tr
r2r tr@(P (S (V ty ts) v) l) = t2t $ S (V ty [comp (P t l) | t <- ts]) v
r2r tr@(P p _) = case getLab tr of
Ok (cat,labs) -> P (t2t p) . mkLab $
maybe (prtTrace tr $ 66664) snd $
Map.lookup (cat,labs) labels
_ -> K ((A.prt tr +++ prtTrace tr "66665"))
-- this goes recursively into tables (ignored) and records (accumulated)
getLab tr = case tr of
Vr (IA cat _) -> return (identC cat,[])
Vr (IAV cat _ _) -> return (identC cat,[])
Vr (IC s) -> return (identC cat,[]) where
cat = BS.takeWhile (/='_') s ---- also to match IAVs; no _ in a cat tolerated
---- init (reverse (dropWhile (/='_') (reverse s))) ---- from gf parser
---- Vr _ -> error $ "getLab " ++ show tr
P p lab2 -> do
(cat,labs) <- getLab p
return (cat,labs++[lab2])
S p _ -> getLab p
_ -> Bad "getLab"
mkCase ((ty,vs),(x,p)) tr =
S (V ty [mkBranch x v tr | v <- vs]) p
mkBranch x t tr = case tr of
_ | tr == x -> t
_ -> GM.composSafeOp (mkBranch x t) tr
valNum tr = maybe (valNumFV $ tryFV tr) EInt $ Map.lookup tr untyps
where
tryFV tr = case GM.appForm tr of
(c@(QC _ _), ts) -> [GM.mkApp c ts' | ts' <- combinations (map tryFV ts)]
(FV ts,_) -> ts
_ -> [tr]
valNumFV ts = case ts of
[tr] -> prtTrace tr $ K "66667"
_ -> FV $ map valNum ts
mkCurry trm = case trm of
V (RecType [(_,ty)]) ts -> V ty ts
V (RecType ((_,ty):ltys)) ts ->
V ty [mkCurry (V (RecType ltys) cs) |
cs <- chop (product (map (lengthtyp . snd) ltys)) ts]
_ -> trm
lengthtyp ty = case Map.lookup ty typs of
Just m -> length (Map.assocs m)
_ -> error $ "length of type " ++ show ty
chop i xs = case splitAt i xs of
(xs1,[]) -> [xs1]
(xs1,xs2) -> xs1:chop i xs2
mkCurrySel t p = S t p -- done properly in CheckGFCC
mkLab k = LIdent (BS.pack ("_" ++ show k))
-- remove lock fields; in fact, any empty records and record types
unlock = filter notlock where
notlock (l,(_, t)) = case t of --- need not look at l
R [] -> False
RecType [] -> False
_ -> True
unlockTyp = filter notlock
notlock (l, t) = case t of --- need not look at l
RecType [] -> False
_ -> True
unlockTy ty = case ty of
RecType ls -> RecType $ sort [(l, unlockTy t) | (l,t) <- ls, notlock (l,t)]
_ -> GM.composSafeOp unlockTy ty
prtTrace tr n =
trace ("-- INTERNAL COMPILER ERROR" +++ A.prt tr ++++ show n) n
prTrace tr n = trace ("-- OBSERVE" +++ A.prt tr +++ show n +++ show tr) n