{-# LANGUAGE FlexibleContexts #-} -------------------------------------------------------------------------------- -- | Solve a system of horn-clause constraints --------------------------------- -------------------------------------------------------------------------------- module Language.Fixpoint.Solver.GradualSolve (solveGradual) where {- COMMENTING OUT AS IT DOESNT BUILD! import Control.Monad (when, filterM, foldM) import Control.Monad.State.Strict (lift) import Language.Fixpoint.Misc import qualified Language.Fixpoint.Types.Solutions as Sol import qualified Language.Fixpoint.SortCheck as So import Language.Fixpoint.Types.PrettyPrint import qualified Language.Fixpoint.Solver.GradualSolution as S import qualified Language.Fixpoint.Solver.Worklist as W import qualified Language.Fixpoint.Solver.Eliminate as E import Language.Fixpoint.Solver.Monad import Language.Fixpoint.Utils.Progress import Language.Fixpoint.Graph import Text.PrettyPrint.HughesPJ import Text.Printf import System.Console.CmdArgs.Verbosity (whenNormal, whenLoud) import qualified Data.HashMap.Strict as M import qualified Data.HashSet as S -} import Control.DeepSeq import qualified Language.Fixpoint.Types as F import Language.Fixpoint.Types.Config hiding (stats) solveGradual :: (NFData a, F.Fixpoint a) => Config -> F.SInfo a -> IO (F.Result (Integer, a)) solveGradual :: forall a. (NFData a, Fixpoint a) => Config -> SInfo a -> IO (Result (Integer, a)) solveGradual = Config -> SInfo a -> IO (Result (Integer, a)) forall a. HasCallStack => a undefined {- COMMENTING OUT AS IT DOESNT BUILD! -------------------------------------------------------------------------------- -- | Progress Bar -------------------------------------------------------------------------------- withProgressFI :: SolverInfo a b -> IO b -> IO b withProgressFI = withProgress . fromIntegral . cNumScc . siDeps -------------------------------------------------------------------------------- printStats :: F.SInfo a -> W.Worklist a -> Stats -> IO () printStats fi w s = putStrLn "\n" >> ppTs [ ptable fi, ptable s, ptable w ] where ppTs = putStrLn . showpp . mconcat -------------------------------------------------------------------------------- solverInfo :: Config -> F.SInfo a -> SolverInfo a b -------------------------------------------------------------------------------- solverInfo cfg fI | useElim cfg = E.solverInfo cfg fI | otherwise = SI mempty fI cD (siKvars fI) where cD = elimDeps fI (kvEdges fI) mempty siKvars :: F.SInfo a -> S.HashSet F.KVar siKvars = S.fromList . M.keys . F.ws -------------------------------------------------------------------------------- -- | tidyResult ensures we replace the temporary kVarArg names introduced to -- ensure uniqueness with the original names in the given WF constraints. -------------------------------------------------------------------------------- tidyResult :: F.Result a -> F.Result a tidyResult r = r { F.resSolution = tidySolution (F.resSolution r) , F.gresSolution = gtidySolution (F.gresSolution r) } tidySolution :: F.FixSolution -> F.FixSolution tidySolution = fmap tidyPred gtidySolution :: F.GFixSolution -> F.GFixSolution gtidySolution = fmap tidyPred -- (\(e, es) -> (tidyPred e, tidyPred <$> es)) tidyPred :: F.Expr -> F.Expr tidyPred = F.substf (F.eVar . F.tidySymbol) predKs :: F.Expr -> [(F.KVar, F.Subst)] predKs (F.PAnd ps) = concatMap predKs ps predKs (F.PKVar k su) = [(k, su)] predKs _ = [] -------------------------------------------------------------------------------- minimizeResult :: Config -> M.HashMap F.KVar F.Expr -> SolveM (M.HashMap F.KVar F.Expr) -------------------------------------------------------------------------------- minimizeResult cfg s | minimalSol cfg = mapM minimizeConjuncts s | otherwise = return s minimizeConjuncts :: F.Expr -> SolveM F.Expr minimizeConjuncts p = F.pAnd <$> go (F.conjuncts p) [] where go [] acc = return acc go (p:ps) acc = do b <- isValid (F.pAnd (acc ++ ps)) p if b then go ps acc else go ps (p:acc) showUnsat :: Bool -> Integer -> F.Pred -> F.Pred -> IO () showUnsat u i lP rP = {- when u $ -} do putStrLn $ printf "UNSAT id %s %s" (show i) (show u) putStrLn $ showpp $ "LHS:" <+> pprint lP putStrLn $ showpp $ "RHS:" <+> pprint rP -------------------------------------------------------------------------------- -- | Predicate corresponding to RHS of constraint in current solution -------------------------------------------------------------------------------- rhsPred :: F.SimpC a -> F.Expr -------------------------------------------------------------------------------- rhsPred c | isTarget c = F.crhs c | otherwise = errorstar $ "rhsPred on non-target: " ++ show (F.sid c) isValid :: F.Expr -> F.Expr -> SolveM Bool isValid p q = (not . null) <$> filterValid p [(q, ())] ------------------------------------------------------------------------------- -- | solve with edits to allow Gradual types ---------------------------------- ------------------------------------------------------------------------------- solveGradual :: (NFData a, F.Fixpoint a) => Config -> F.SInfo a -> IO (F.Result (Integer, a)) -- solveGradual = undefined solveGradual cfg fi = do (res, stat) <- withProgressFI sI $ runSolverM cfg sI n act when (solverStats cfg) $ printStats fi wkl stat return res where act = solveGradual_ cfg fi s0 ks wkl sI = solverInfo cfg fi wkl = W.init sI n = fromIntegral $ W.wRanks wkl s0 = siSol sI ks = siVars sI -------------------------------------------------------------------------------- solveGradual_ :: (NFData a, F.Fixpoint a) => Config -> F.SInfo a -> Sol.GSolution -> S.HashSet F.KVar -> W.Worklist a -> SolveM (F.Result (Integer, a), Stats) -------------------------------------------------------------------------------- solveGradual_ cfg fi s0 ks wkl = do let s1 = mappend s0 $ {- SCC "sol-init" #-} S.init cfg fi ks s2 <- {- SCC "sol-local" #-} filterLocal s1 s <- {- SCC "sol-refine" #-} refine s2 wkl res <- {- SCC "sol-result" #-} result cfg wkl s st <- stats let res' = {- SCC "sol-tidy" #-} tidyResult res return $!! (res', st) filterLocal :: Sol.GSolution -> SolveM Sol.GSolution filterLocal sol = do gs' <- mapM (initGBind sol) gs return $ Sol.updateGMap sol $ M.fromList gs' where gs = M.toList $ Sol.gMap sol initGBind :: Sol.GSolution -> (F.KVar, (((F.Symbol, F.Sort), F.Expr), Sol.GBind)) -> SolveM (F.KVar, (((F.Symbol, F.Sort), F.Expr), Sol.GBind)) initGBind sol (k, (e, gb)) = do elems0 <- filterM (isLocal e) (Sol.gbEquals gb) elems <- sortEquals elems0 lattice <- makeLattice [] (map (:[]) elems) elems return $ ((k,) . (e,) . Sol.equalsGb) lattice where makeLattice acc new elems | null new = return acc | otherwise = do let cands = [e:es |e<-elems, es<-new] localCans <- filterM (isLocal e) cands newElems <- filterM (notTrivial (new ++ acc)) localCans makeLattice (acc ++ new) newElems elems notTrivial [] _ = return True notTrivial (x:xs) p = do v <- isValid (mkPred x) (mkPred p) if v then return False else notTrivial xs p mkPred eq = So.elaborate "initBGind.mkPred" (Sol.sEnv sol) (F.pAnd (Sol.eqPred <$> eq)) isLocal (v, e) eqs = do let pp = So.elaborate "filterLocal" (Sol.sEnv sol) $ F.PExist [v] $ F.pAnd (e:(Sol.eqPred <$> eqs)) isValid mempty pp root = Sol.trueEqual sortEquals xs = (bfs [0]) <$> makeEdges vs [] vs where vs = zip [0..] (root:(head <$> xs)) bfs [] _ = [] bfs (i:is) es = (snd $ (vs!!i)) : bfs (is++map snd (filter (\(j,k) -> (j==i && notElem k is)) es)) es makeEdges _ acc [] = return acc makeEdges vs acc (x:xs) = do ves <- concat <$> mapM (makeEdgesOne x) vs if any (\(i,j) -> elem (j,i) acc) ves then makeEdges (filter ((/= fst x) . fst) vs) (filter (\(i,j) -> ((i /= fst x) && (j /= fst x))) acc) xs else makeEdges vs (mergeEdges (ves ++ acc)) xs makeEdgesOne (i,_) (j,_) | i == j = return [] makeEdgesOne (i,x) (j,y) = do ij <- isValid (mkPred [x]) (mkPred [y]) return (if ij then [(j,i)] else []) mergeEdges es = filter (\(i,j) -> (not (any (\k -> ((i,k) `elem` es && (k,j) `elem` es)) (fst <$> es)))) es -------------------------------------------------------------------------------- refine :: Sol.GSolution -> W.Worklist a -> SolveM Sol.GSolution -------------------------------------------------------------------------------- refine s w | Just (c, w', newScc, rnk) <- W.pop w = do i <- tickIter newScc (b, s') <- refineC i s c lift $ writeLoud $ refineMsg i c b rnk let w'' = if b then W.push c w' else w' refine s' w'' | otherwise = return s where -- DEBUG refineMsg i c b rnk = printf "\niter=%d id=%d change=%s rank=%d\n" i (F.subcId c) (show b) rnk --------------------------------------------------------------------------- -- | Single Step Refinement ----------------------------------------------- --------------------------------------------------------------------------- refineC :: Int -> Sol.GSolution -> F.SimpC a -> SolveM (Bool, Sol.GSolution) --------------------------------------------------------------------------- refineC _i s c | null rhs = return (False, s) | otherwise = do be <- getBinds let lhss = snd <$> S.lhsPred be s c kqs <- filterValidGradual lhss rhs return $ S.update s ks kqs where _ci = F.subcId c (ks, rhs) = rhsCands s c -- msg = printf "refineC: iter = %d, sid = %s, soln = \n%s\n" -- _i (show (F.sid c)) (showpp s) _msg ks xs ys = printf "refineC: iter = %d, sid = %s, s = %s, rhs = %d, rhs' = %d \n" _i (show _ci) (showpp ks) (length xs) (length ys) rhsCands :: Sol.GSolution -> F.SimpC a -> ([F.KVar], Sol.Cand (F.KVar, Sol.EQual)) rhsCands s c = (fst <$> ks, kqs) where kqs = [ (p, (k, q)) | (k, su) <- ks, (p, q) <- cnd k su ] ks = predKs . F.crhs $ c cnd k su = Sol.qbPreds msg s su (Sol.lookupQBind s k) msg = "rhsCands: " ++ show (F.sid c) -------------------------------------------------------------------------------- -- | Gradual Convert Solution into Result ---------------------------------------------- -------------------------------------------------------------------------------- result :: (F.Fixpoint a) => Config -> W.Worklist a -> Sol.GSolution -> SolveM (F.Result (Integer, a)) -------------------------------------------------------------------------------- result cfg wkl s = do lift $ writeLoud "Computing Result" stat <- result_ wkl s lift $ whenNormal $ putStrLn $ "RESULT: " ++ show (F.sid <$> stat) F.Result (ci <$> stat) <$> solResult cfg s <*> solResultGradual wkl cfg s where ci c = (F.subcId c, F.sinfo c) result_ :: Fixpoint a => W.Worklist a -> Sol.GSolution -> SolveM (F.FixResult (F.SimpC a)) result_ w s = res <$> filterM (isUnsat s) cs where cs = W.unsatCandidates w res [] = F.Safe res cs' = F.Unsafe cs' solResult :: Config -> Sol.GSolution -> SolveM (M.HashMap F.KVar F.Expr) solResult cfg = minimizeResult cfg . Sol.result solResultGradual :: W.Worklist a -> Config -> Sol.GSolution -> SolveM F.GFixSolution solResultGradual w _cfg sol = F.toGFixSol . Sol.resultGradual <$> updateGradualSolution (W.unsatCandidates w) sol -------------------------------------------------------------------------------- updateGradualSolution :: [F.SimpC a] -> Sol.GSolution -> SolveM (Sol.GSolution) -------------------------------------------------------------------------------- updateGradualSolution cs sol = foldM f (Sol.emptyGMap sol) cs where f s c = do be <- getBinds let lpi = S.lhsPred be sol c let rp = rhsPred c gbs <- firstValid rp lpi return $ Sol.updateGMapWithKey gbs s firstValid :: Monoid a => F.Expr -> [(a, F.Expr)] -> SolveM a firstValid _ [] = return mempty firstValid rhs ((y,lhs):xs) = do v <- isValid lhs rhs if v then return y else firstValid rhs xs -------------------------------------------------------------------------------- isUnsat :: Fixpoint a => Sol.GSolution -> F.SimpC a -> SolveM Bool -------------------------------------------------------------------------------- isUnsat s c = do -- lift $ printf "isUnsat %s" (show (F.subcId c)) _ <- tickIter True -- newScc be <- getBinds let lpi = S.lhsPred be s c let rp = rhsPred c res <- (not . or) <$> mapM (`isValid` rp) (snd <$> lpi) lift $ whenLoud $ showUnsat res (F.subcId c) (F.pOr (snd <$> lpi)) rp return res -}