module Language.Haskell.Liquid.Bare.GhcSpec (
GhcSpec(..)
, makeGhcSpec
) where
import CoreSyn hiding (Expr)
import HscTypes
import Id
import NameSet
import TyCon
import Var
import TysWiredIn
import Control.Applicative ((<$>))
import Control.Monad.Reader
import Control.Monad.State
import Data.Bifunctor
import Data.Maybe
import Data.Monoid
import qualified Control.Exception as Ex
import qualified Data.List as L
import qualified Data.HashMap.Strict as M
import qualified Data.HashSet as S
import Language.Fixpoint.Misc
import Language.Fixpoint.Names (takeWhileSym, nilName, consName)
import Language.Fixpoint.Types
import Language.Haskell.Liquid.Dictionaries
import Language.Haskell.Liquid.GhcMisc (getSourcePosE, getSourcePos, sourcePosSrcSpan)
import Language.Haskell.Liquid.PredType (makeTyConInfo)
import Language.Haskell.Liquid.RefType
import Language.Haskell.Liquid.Types
import Language.Haskell.Liquid.WiredIn
import Language.Haskell.Liquid.Visitors
import Language.Haskell.Liquid.CoreToLogic
import qualified Language.Haskell.Liquid.Measure as Ms
import Language.Haskell.Liquid.Bare.Check
import Language.Haskell.Liquid.Bare.DataType
import Language.Haskell.Liquid.Bare.Env
import Language.Haskell.Liquid.Bare.Existential
import Language.Haskell.Liquid.Bare.Measure
import Language.Haskell.Liquid.Bare.Misc (makeSymbols, mkVarExpr)
import Language.Haskell.Liquid.Bare.Plugged
import Language.Haskell.Liquid.Bare.RTEnv
import Language.Haskell.Liquid.Bare.Spec
import Language.Haskell.Liquid.Bare.SymSort
import Language.Haskell.Liquid.Bare.RefToLogic
makeGhcSpec :: Config -> ModName -> [CoreBind] -> [Var] -> [Var] -> NameSet -> HscEnv -> Either Error LogicMap
-> [(ModName,Ms.BareSpec)]
-> IO GhcSpec
makeGhcSpec cfg name cbs vars defVars exports env lmap specs
= do sp <- throwLeft =<< execBare act initEnv
let renv = ghcSpecEnv sp cbs
throwLeft $ checkGhcSpec specs renv $ postProcess cbs renv sp
where
act = makeGhcSpec' cfg cbs vars defVars exports specs
throwLeft = either Ex.throw return
initEnv = BE name mempty mempty mempty env lmap' mempty mempty
lmap' = case lmap of {Left e -> Ex.throw e; Right x -> x `mappend` listLMap}
listLMap = toLogicMap [(nilName, [], hNil),
(consName, [x, xs], hCons (EVar <$> [x,xs]))
]
where
x = symbol "x"
xs = symbol "xs"
hNil = EApp (dummyLoc $ symbol nilDataCon ) []
hCons = EApp (dummyLoc $ symbol consDataCon)
postProcess :: [CoreBind] -> SEnv SortedReft -> GhcSpec -> GhcSpec
postProcess cbs specEnv sp@(SP {..}) = sp { tySigs = tySigs', texprs = ts, asmSigs = asmSigs', dicts = dicts' }
where
(sigs, ts) = replaceLocalBinds tcEmbeds tyconEnv tySigs texprs specEnv cbs
tySigs' = mapSnd (addTyConInfo tcEmbeds tyconEnv <$>) <$> sigs
asmSigs' = mapSnd (addTyConInfo tcEmbeds tyconEnv <$>) <$> asmSigs
dicts' = dmapty (addTyConInfo tcEmbeds tyconEnv) dicts
ghcSpecEnv sp cbs = fromListSEnv binds
where
emb = tcEmbeds sp
binds = [(x, rSort t) | (x, Loc _ _ t) <- meas sp]
++ [(symbol v, rSort t) | (v, Loc _ _ t) <- ctors sp]
++ [(x, vSort v) | (x, v) <- freeSyms sp, isConLikeId v]
++ [(val x , rSort stringrSort) | Just (ELit x s) <- mkLit <$> lconsts, isString s]
rSort = rTypeSortedReft emb
vSort = rSort . varRSort
varRSort :: Var -> RSort
varRSort = ofType . varType
lconsts = literals cbs
stringrSort :: RSort
stringrSort = ofType stringTy
isString s = rTypeSort emb stringrSort == s
makeGhcSpec' :: Config -> [CoreBind] -> [Var] -> [Var] -> NameSet -> [(ModName, Ms.BareSpec)] -> BareM GhcSpec
makeGhcSpec' cfg cbs vars defVars exports specs
= do name <- modName <$> get
makeBounds name defVars cbs specs
makeRTEnv specs
(tycons, datacons, dcSs, tyi, embs) <- makeGhcSpecCHOP1 specs
modify $ \be -> be { tcEnv = tyi }
(cls, mts) <- second mconcat . unzip . mconcat <$> mapM (makeClasses name cfg vars) specs
(measures, cms', ms', cs', xs') <- makeGhcSpecCHOP2 cbs specs dcSs datacons cls embs
(invs, ialias, sigs, asms) <- makeGhcSpecCHOP3 cfg vars defVars specs name mts embs
syms <- makeSymbols (vars ++ map fst cs') xs' (sigs ++ asms ++ cs') ms' (invs ++ (snd <$> ialias))
let su = mkSubst [ (x, mkVarExpr v) | (x, v) <- syms]
return (emptySpec cfg)
>>= makeGhcSpec0 cfg defVars exports name
>>= makeGhcSpec1 vars embs tyi exports name sigs asms cs' ms' cms' su
>>= makeGhcSpec2 invs ialias measures su
>>= makeGhcSpec3 datacons tycons embs syms
>>= makeGhcSpec4 defVars specs name su
>>= makeSpecDictionaries embs vars specs
emptySpec :: Config -> GhcSpec
emptySpec cfg = SP [] [] [] [] [] [] [] [] [] mempty [] [] [] [] mempty mempty cfg mempty [] mempty mempty
makeGhcSpec0 cfg defVars exports name sp
= do targetVars <- makeTargetVars name defVars $ binders cfg
return $ sp { config = cfg
, exports = exports
, tgtVars = targetVars }
makeGhcSpec1 vars embs tyi exports name sigs asms cs' ms' cms' su sp
= do tySigs <- makePluggedSigs name embs tyi exports $ tx sigs
asmSigs <- makePluggedAsmSigs embs tyi $ tx asms
ctors <- makePluggedAsmSigs embs tyi $ tx cs'
lmap <- logicEnv <$> get
inlmap <- inlines <$> get
let ctors' = [ (x, txRefToLogic lmap inlmap <$> t) | (x, t) <- ctors ]
return $ sp { tySigs = tySigs
, asmSigs = asmSigs
, ctors = ctors'
, meas = tx' $ tx $ ms' ++ varMeasures vars ++ cms' }
where
tx = fmap . mapSnd . subst $ su
tx' = fmap (mapSnd $ fmap uRType)
makeGhcSpec2 invs ialias measures su sp
= return $ sp { invariants = subst su invs
, ialiases = subst su ialias
, measures = subst su
<$> M.elems (Ms.measMap measures)
++ Ms.imeas measures
}
makeGhcSpec3 datacons tycons embs syms sp
= do tcEnv <- gets tcEnv
lmap <- logicEnv <$> get
inlmap <- inlines <$> get
let dcons' = mapSnd (txRefToLogic lmap inlmap) <$> datacons
return $ sp { tyconEnv = tcEnv
, dconsP = dcons'
, tconsP = tycons
, tcEmbeds = embs
, freeSyms = [(symbol v, v) | (_, v) <- syms] }
makeGhcSpec4 defVars specs name su sp
= do decr' <- mconcat <$> mapM (makeHints defVars . snd) specs
texprs' <- mconcat <$> mapM (makeTExpr defVars . snd) specs
lazies <- mkThing makeLazy
lvars' <- mkThing makeLVar
hmeas <- mkThing makeHIMeas
quals <- mconcat <$> mapM makeQualifiers specs
let sigs = strengthenHaskellMeasures hmeas ++ tySigs sp
lmap <- logicEnv <$> get
inlmap <- inlines <$> get
let tx = mapSnd (fmap $ txRefToLogic lmap inlmap)
let mtx = txRefToLogic lmap inlmap
return $ sp { qualifiers = subst su quals
, decr = decr'
, texprs = texprs'
, lvars = lvars'
, lazy = lazies
, tySigs = tx <$> sigs
, asmSigs = tx <$> (asmSigs sp)
, measures = mtx <$> (measures sp)
}
where
mkThing mk = S.fromList . mconcat <$> sequence [ mk defVars s | (m, s) <- specs, m == name ]
makeGhcSpecCHOP1 specs
= do (tcs, dcs) <- mconcat <$> mapM makeConTypes specs
let tycons = tcs ++ wiredTyCons
let tyi = makeTyConInfo tycons
embs <- mconcat <$> mapM makeTyConEmbeds specs
datacons <- makePluggedDataCons embs tyi (concat dcs ++ wiredDataCons)
let dcSelectors = concat $ map makeMeasureSelectors datacons
return $ (tycons, second val <$> datacons, dcSelectors, tyi, embs)
makeGhcSpecCHOP3 cfg vars defVars specs name mts embs
= do sigs' <- mconcat <$> mapM (makeAssertSpec name cfg vars defVars) specs
asms' <- mconcat <$> mapM (makeAssumeSpec name cfg vars defVars) specs
invs <- mconcat <$> mapM makeInvariants specs
ialias <- mconcat <$> mapM makeIAliases specs
let dms = makeDefaultMethods vars mts
tyi <- gets tcEnv
let sigs = [ (x, txRefSort tyi embs . txExpToBind <$> t) | (_, x, t) <- sigs' ++ mts ++ dms ]
let asms = [ (x, txRefSort tyi embs . txExpToBind <$> t) | (_, x, t) <- asms' ]
return (invs, ialias, sigs, asms)
makeGhcSpecCHOP2 cbs specs dcSelectors datacons cls embs
= do measures' <- mconcat <$> mapM makeMeasureSpec specs
tyi <- gets tcEnv
name <- gets modName
mapM_ (makeHaskellInlines cbs name) specs
hmeans <- mapM (makeHaskellMeasures cbs name) specs
let measures = mconcat (measures':Ms.mkMSpec' dcSelectors:hmeans)
let (cs, ms) = makeMeasureSpec' measures
let cms = makeClassMeasureSpec measures
let cms' = [ (x, Loc l l' $ cSort t) | (Loc l l' x, t) <- cms ]
let ms' = [ (x, Loc l l' t) | (Loc l l' x, t) <- ms, isNothing $ lookup x cms' ]
let cs' = [ (v, Loc (getSourcePos v) (getSourcePosE v) (txRefSort tyi embs t)) | (v, t) <- meetDataConSpec cs (datacons ++ cls)]
let xs' = val . fst <$> ms
return (measures, cms', ms', cs', xs')
data ReplaceEnv = RE { _re_env :: M.HashMap Symbol Symbol
, _re_fenv :: SEnv SortedReft
, _re_emb :: TCEmb TyCon
, _re_tyi :: M.HashMap TyCon RTyCon
}
type ReplaceState = ( M.HashMap Var (Located SpecType)
, M.HashMap Var [Expr]
)
type ReplaceM = ReaderT ReplaceEnv (State ReplaceState)
replaceLocalBinds :: TCEmb TyCon
-> M.HashMap TyCon RTyCon
-> [(Var, Located SpecType)]
-> [(Var, [Expr])]
-> SEnv SortedReft
-> CoreProgram
-> ([(Var, Located SpecType)], [(Var, [Expr])])
replaceLocalBinds emb tyi sigs texprs senv cbs
= (M.toList s, M.toList t)
where
(s,t) = execState (runReaderT (mapM_ (`traverseBinds` return ()) cbs)
(RE M.empty senv emb tyi))
(M.fromList sigs, M.fromList texprs)
traverseExprs (Let b e)
= traverseBinds b (traverseExprs e)
traverseExprs (Lam b e)
= withExtendedEnv [b] (traverseExprs e)
traverseExprs (App x y)
= traverseExprs x >> traverseExprs y
traverseExprs (Case e _ _ as)
= traverseExprs e >> mapM_ (traverseExprs . thd3) as
traverseExprs (Cast e _)
= traverseExprs e
traverseExprs (Tick _ e)
= traverseExprs e
traverseExprs _
= return ()
traverseBinds b k = withExtendedEnv (bindersOf b) $ do
mapM_ traverseExprs (rhssOfBind b)
k
withExtendedEnv vs k
= do RE env' fenv' emb tyi <- ask
let env = L.foldl' (\m v -> M.insert (takeWhileSym (/='#') $ symbol v) (symbol v) m) env' vs
fenv = L.foldl' (\m v -> insertSEnv (symbol v) (rTypeSortedReft emb (ofType $ varType v :: RSort)) m) fenv' vs
withReaderT (const (RE env fenv emb tyi)) $ do
mapM_ replaceLocalBindsOne vs
k
replaceLocalBindsOne :: Var -> ReplaceM ()
replaceLocalBindsOne v
= do mt <- gets (M.lookup v . fst)
case mt of
Nothing -> return ()
Just (Loc l l' (toRTypeRep -> t@(RTypeRep {..}))) -> do
(RE env' fenv emb tyi) <- ask
let f m k = M.lookupDefault k k m
let (env,args) = L.mapAccumL (\e (v,t) -> (M.insert v v e, substa (f e) t))
env' (zip ty_binds ty_args)
let res = substa (f env) ty_res
let t' = fromRTypeRep $ t { ty_args = args, ty_res = res }
let msg = ErrTySpec (sourcePosSrcSpan l) (pprint v) t'
case checkTy msg emb tyi fenv t' of
Just err -> Ex.throw err
Nothing -> modify (first $ M.insert v (Loc l l' t'))
mes <- gets (M.lookup v . snd)
case mes of
Nothing -> return ()
Just es -> do
let es' = substa (f env) es
case checkTerminationExpr emb fenv (v, Loc l l' t', es') of
Just err -> Ex.throw err
Nothing -> modify (second $ M.insert v es')