----------------------------------------------------------------------------- -- | -- Module : Data.SBV.Provers.Prover -- Copyright : (c) Levent Erkok -- License : BSD3 -- Maintainer: erkokl@gmail.com -- Stability : experimental -- -- Provable abstraction and the connection to SMT solvers ----------------------------------------------------------------------------- {-# LANGUAGE CPP #-} {-# LANGUAGE ConstraintKinds #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE NamedFieldPuns #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TupleSections #-} {-# LANGUAGE UndecidableInstances #-} {-# OPTIONS_GHC -Wall -Werror #-} module Data.SBV.Provers.Prover ( SMTSolver(..), SMTConfig(..), Predicate , ProvableM(..), Provable, SatisfiableM(..), Satisfiable , generateSMTBenchmarkSat, generateSMTBenchmarkProof, ConstraintSet , ThmResult(..), SatResult(..), AllSatResult(..), SafeResult(..), OptimizeResult(..), SMTResult(..) , SExecutable(..), isSafe , runSMT, runSMTWith , SatModel(..), Modelable(..), displayModels, extractModels , getModelDictionaries, getModelValues, getModelUninterpretedValues , abc, boolector, bitwuzla, cvc4, cvc5, dReal, mathSAT, yices, z3, defaultSMTCfg, defaultDeltaSMTCfg , proveWithAny, proveWithAll, proveConcurrentWithAny, proveConcurrentWithAll , satWithAny, satWithAll, satConcurrentWithAny, satConcurrentWithAll ) where import Control.Monad (when, unless) import Control.Monad.IO.Class (MonadIO, liftIO) import Control.DeepSeq (rnf, NFData(..)) import Control.Concurrent.Async (async, waitAny, asyncThreadId, Async, mapConcurrently) import Control.Exception (finally, throwTo) import System.Exit (ExitCode(ExitSuccess)) import System.IO.Unsafe (unsafeInterleaveIO) -- only used safely! import System.Directory (getCurrentDirectory) import Data.Time (getZonedTime, NominalDiffTime, UTCTime, getCurrentTime, diffUTCTime) import Data.List (intercalate, isPrefixOf) import Data.Maybe (mapMaybe, listToMaybe) import qualified Data.Foldable as S (toList) import qualified Data.Text as T import Data.SBV.Core.Data import Data.SBV.Core.Symbolic import Data.SBV.SMT.SMT import Data.SBV.SMT.Utils (debug, alignPlain) import Data.SBV.Utils.ExtractIO import Data.SBV.Utils.TDiff import qualified Data.SBV.Trans.Control as Control import qualified Data.SBV.Control.Query as Control import qualified Data.SBV.Control.Utils as Control import GHC.Stack import qualified Data.SBV.Provers.ABC as ABC import qualified Data.SBV.Provers.Boolector as Boolector import qualified Data.SBV.Provers.Bitwuzla as Bitwuzla import qualified Data.SBV.Provers.CVC4 as CVC4 import qualified Data.SBV.Provers.CVC5 as CVC5 import qualified Data.SBV.Provers.DReal as DReal import qualified Data.SBV.Provers.MathSAT as MathSAT import qualified Data.SBV.Provers.Yices as Yices import qualified Data.SBV.Provers.Z3 as Z3 import GHC.TypeLits mkConfig :: SMTSolver -> SMTLibVersion -> [Control.SMTOption] -> SMTConfig mkConfig s smtVersion startOpts = SMTConfig { verbose = False , timing = NoTiming , printBase = 10 , printRealPrec = 16 , crackNum = False , transcript = Nothing , solver = s , smtLibVersion = smtVersion , dsatPrecision = Nothing , extraArgs = [] , satCmd = "(check-sat)" , allSatTrackUFs = True -- i.e., yes, do extract UI function values , allSatMaxModelCount = Nothing -- i.e., return all satisfying models , allSatPrintAlong = False -- i.e., do not print models as they are found , isNonModelVar = const False -- i.e., everything is a model-variable by default , validateModel = False , optimizeValidateConstraints = False , roundingMode = RoundNearestTiesToEven , solverSetOptions = startOpts , ignoreExitCode = False , redirectVerbose = Nothing } -- | If supported, this makes all output go to stdout, which works better with SBV -- Alas, not all solvers support it.. allOnStdOut :: Control.SMTOption allOnStdOut = Control.DiagnosticOutputChannel "stdout" -- | Default configuration for the ABC synthesis and verification tool. abc :: SMTConfig abc = mkConfig ABC.abc SMTLib2 [allOnStdOut] -- | Default configuration for the Boolector SMT solver boolector :: SMTConfig boolector = mkConfig Boolector.boolector SMTLib2 [] -- | Default configuration for the Bitwuzla SMT solver bitwuzla :: SMTConfig bitwuzla = mkConfig Bitwuzla.bitwuzla SMTLib2 [] -- | Default configuration for the CVC4 SMT Solver. cvc4 :: SMTConfig cvc4 = mkConfig CVC4.cvc4 SMTLib2 [allOnStdOut] -- | Default configuration for the CVC5 SMT Solver. cvc5 :: SMTConfig cvc5 = mkConfig CVC5.cvc5 SMTLib2 [allOnStdOut] -- | Default configuration for the Yices SMT Solver. dReal :: SMTConfig dReal = mkConfig DReal.dReal SMTLib2 [ Control.OptionKeyword ":smtlib2_compliant" ["true"] ] -- | Default configuration for the MathSAT SMT solver mathSAT :: SMTConfig mathSAT = mkConfig MathSAT.mathSAT SMTLib2 [allOnStdOut] -- | Default configuration for the Yices SMT Solver. yices :: SMTConfig yices = mkConfig Yices.yices SMTLib2 [] -- | Default configuration for the Z3 SMT solver z3 :: SMTConfig z3 = mkConfig Z3.z3 SMTLib2 [ Control.OptionKeyword ":smtlib2_compliant" ["true"] , allOnStdOut ] -- | The default solver used by SBV. This is currently set to z3. defaultSMTCfg :: SMTConfig defaultSMTCfg = z3 -- | The default solver used by SBV for delta-satisfiability problems. This is currently set to dReal, -- which is also the only solver that supports delta-satisfiability. defaultDeltaSMTCfg :: SMTConfig defaultDeltaSMTCfg = dReal -- | A predicate is a symbolic program that returns a (symbolic) boolean value. For all intents and -- purposes, it can be treated as an n-ary function from symbolic-values to a boolean. The 'Symbolic' -- monad captures the underlying representation, and can/should be ignored by the users of the library, -- unless you are building further utilities on top of SBV itself. Instead, simply use the 'Predicate' -- type when necessary. type Predicate = Symbolic SBool -- | A constraint set is a symbolic program that returns no values. The idea is that the constraints/min-max -- goals will serve as the collection of constraints that will be used for sat/optimize calls. type ConstraintSet = Symbolic () -- | `Provable` is specialization of `ProvableM` to the `IO` monad. Unless you are using -- transformers explicitly, this is the type you should prefer. type Provable = ProvableM IO -- | `Data.SBV.Provers.Satisfiable` is specialization of `SatisfiableM` to the `IO` monad. Unless you are using -- transformers explicitly, this is the type you should prefer. type Satisfiable = SatisfiableM IO -- | A type @a@ is satisfiable if it has constraints, potentially returning a boolean. This class -- captures essentially sat and optimize calls. class ExtractIO m => SatisfiableM m a where -- | Reduce an arg, for sat purposes. satArgReduce :: a -> SymbolicT m SBool -- | Generalization of 'Data.SBV.sat' sat :: a -> m SatResult sat = satWith defaultSMTCfg -- | Generalization of 'Data.SBV.satWith' satWith :: SMTConfig -> a -> m SatResult satWith cfg a = do r <- runWithQuery satArgReduce True (checkNoOptimizations >> Control.getSMTResult) cfg a SatResult <$> if validationRequested cfg then validate satArgReduce True cfg a r else return r -- | Generalization of 'Data.SBV.sat' dsat :: a -> m SatResult dsat = dsatWith defaultDeltaSMTCfg -- | Generalization of 'Data.SBV.satWith' dsatWith :: SMTConfig -> a -> m SatResult dsatWith cfg a = do r <- runWithQuery satArgReduce True (checkNoOptimizations >> Control.getSMTResult) cfg a SatResult <$> if validationRequested cfg then validate satArgReduce True cfg a r else return r -- | Generalization of 'Data.SBV.allSat' allSat :: a -> m AllSatResult allSat = allSatWith defaultSMTCfg -- | Generalization of 'Data.SBV.allSatWith' allSatWith :: SMTConfig -> a -> m AllSatResult allSatWith cfg a = do asr <- runWithQuery satArgReduce True (checkNoOptimizations >> Control.getAllSatResult) cfg a if validationRequested cfg then do rs' <- mapM (validate satArgReduce True cfg a) (allSatResults asr) return asr{allSatResults = rs'} else return asr -- | Generalization of 'Data.SBV.isSatisfiable' isSatisfiable :: a -> m Bool isSatisfiable = isSatisfiableWith defaultSMTCfg -- | Generalization of 'Data.SBV.isSatisfiableWith' isSatisfiableWith :: SMTConfig -> a -> m Bool isSatisfiableWith cfg p = do r <- satWith cfg p case r of SatResult Satisfiable{} -> return True SatResult Unsatisfiable{} -> return False _ -> error $ "SBV.isSatisfiable: Received: " ++ show r -- | Generalization of 'Data.SBV.optimize' optimize :: OptimizeStyle -> a -> m OptimizeResult optimize = optimizeWith defaultSMTCfg -- | Generalization of 'Data.SBV.optimizeWith' optimizeWith :: SMTConfig -> OptimizeStyle -> a -> m OptimizeResult optimizeWith config style optGoal = do res <- runWithQuery satArgReduce True opt config optGoal if not (optimizeValidateConstraints config) then return res else let v :: SMTResult -> m SMTResult v = validate satArgReduce True config optGoal in case res of LexicographicResult m -> LexicographicResult <$> v m IndependentResult xs -> let w [] sofar = return (reverse sofar) w ((n, m):rest) sofar = v m >>= \m' -> w rest ((n, m') : sofar) in IndependentResult <$> w xs [] ParetoResult (b, rs) -> ParetoResult . (b, ) <$> mapM v rs where opt = do objectives <- Control.getObjectives when (null objectives) $ error $ unlines [ "" , "*** Data.SBV: Unsupported call to optimize when no objectives are present." , "*** Use \"sat\" for plain satisfaction" ] unless (supportsOptimization (capabilities (solver config))) $ error $ unlines [ "" , "*** Data.SBV: The backend solver " ++ show (name (solver config)) ++ "does not support optimization goals." , "*** Please use a solver that has support, such as z3" ] when (validateModel config && not (optimizeValidateConstraints config)) $ error $ unlines [ "" , "*** Data.SBV: Model validation is not supported in optimization calls." , "***" , "*** Instead, use `cfg{optimizeValidateConstraints = True}`" , "***" , "*** which checks that the results satisfy the constraints but does" , "*** NOT ensure that they are optimal." ] let optimizerDirectives = concatMap minmax objectives ++ priority style where mkEq (x, y) = "(assert (= " ++ show x ++ " " ++ show y ++ "))" minmax (Minimize _ xy@(_, v)) = [mkEq xy, "(minimize " ++ show v ++ ")"] minmax (Maximize _ xy@(_, v)) = [mkEq xy, "(maximize " ++ show v ++ ")"] minmax (AssertWithPenalty nm xy@(_, v) mbp) = [mkEq xy, "(assert-soft " ++ show v ++ penalize mbp ++ ")"] where penalize DefaultPenalty = "" penalize (Penalty w mbGrp) | w <= 0 = error $ unlines [ "SBV.AssertWithPenalty: Goal " ++ show nm ++ " is assigned a non-positive penalty: " ++ shw , "All soft goals must have > 0 penalties associated." ] | True = " :weight " ++ shw ++ maybe "" group mbGrp where shw = show (fromRational w :: Double) group g = " :id " ++ g priority Lexicographic = [] -- default, no option needed priority Independent = ["(set-option :opt.priority box)"] priority (Pareto _) = ["(set-option :opt.priority pareto)"] mapM_ (Control.send True) optimizerDirectives case style of Lexicographic -> LexicographicResult <$> Control.getLexicographicOptResults Independent -> IndependentResult <$> Control.getIndependentOptResults (map objectiveName objectives) Pareto mbN -> ParetoResult <$> Control.getParetoOptResults mbN -- | Find a satisfying assignment to a property with multiple solvers, running them in separate threads. The -- results will be returned in the order produced. satWithAll :: Satisfiable a => [SMTConfig] -> a -> IO [(Solver, NominalDiffTime, SatResult)] satWithAll = (`sbvWithAll` satWith) -- | Find a satisfying assignment to a property with multiple solvers, running them in separate threads. Only -- the result of the first one to finish will be returned, remaining threads will be killed. -- Note that we send an exception to the losing processes, but we do *not* actually wait for them -- to finish. In rare cases this can lead to zombie processes. In previous experiments, we found -- that some processes take their time to terminate. So, this solution favors quick turnaround. satWithAny :: Satisfiable a => [SMTConfig] -> a -> IO (Solver, NominalDiffTime, SatResult) satWithAny = (`sbvWithAny` satWith) -- | Find a satisfying assignment to a property using a single solver, but -- providing several query problems of interest, with each query running in a -- separate thread and return the first one that returns. This can be useful to -- use symbolic mode to drive to a location in the search space of the solver -- and then refine the problem in query mode. If the computation is very hard to -- solve for the solver than running in concurrent mode may provide a large -- performance benefit. satConcurrentWithAny :: Satisfiable a => SMTConfig -> [Query b] -> a -> IO (Solver, NominalDiffTime, SatResult) satConcurrentWithAny solver qs a = do (slvr,time,result) <- sbvConcurrentWithAny solver go qs a return (slvr, time, SatResult result) where go cfg a' q = runWithQuery satArgReduce True (do _ <- q; checkNoOptimizations >> Control.getSMTResult) cfg a' -- | Find a satisfying assignment to a property using a single solver, but run -- each query problem in a separate isolated thread and wait for each thread to -- finish. See 'satConcurrentWithAny' for more details. satConcurrentWithAll :: Satisfiable a => SMTConfig -> [Query b] -> a -> IO [(Solver, NominalDiffTime, SatResult)] satConcurrentWithAll solver qs a = do results <- sbvConcurrentWithAll solver go qs a return $ (\(a',b,c) -> (a',b,SatResult c)) <$> results where go cfg a' q = runWithQuery satArgReduce True (do _ <- q; checkNoOptimizations >> Control.getSMTResult) cfg a' -- | A type @a@ is provable if we can turn it into a predicate, i.e., it has to return a boolean. -- This class captures essentially prove calls. class ExtractIO m => ProvableM m a where -- | Reduce an arg, for proof purposes. proofArgReduce :: a -> SymbolicT m SBool -- | Generalization of 'Data.SBV.prove' prove :: a -> m ThmResult prove = proveWith defaultSMTCfg -- | Generalization of 'Data.SBV.proveWith' proveWith :: SMTConfig -> a -> m ThmResult proveWith cfg a = do r <- runWithQuery proofArgReduce False (checkNoOptimizations >> Control.getSMTResult) cfg a ThmResult <$> if validationRequested cfg then validate proofArgReduce False cfg a r else return r -- | Generalization of 'Data.SBV.dprove' dprove :: a -> m ThmResult dprove = dproveWith defaultDeltaSMTCfg -- | Generalization of 'Data.SBV.dproveWith' dproveWith :: SMTConfig -> a -> m ThmResult dproveWith cfg a = do r <- runWithQuery proofArgReduce False (checkNoOptimizations >> Control.getSMTResult) cfg a ThmResult <$> if validationRequested cfg then validate proofArgReduce False cfg a r else return r -- | Generalization of 'Data.SBV.isVacuousProof' isVacuousProof :: a -> m Bool isVacuousProof = isVacuousProofWith defaultSMTCfg -- | Generalization of 'Data.SBV.isVacuousProofWith' isVacuousProofWith :: SMTConfig -> a -> m Bool isVacuousProofWith cfg a = -- NB. Can't call runWithQuery since last constraint would become the implication! fst <$> runSymbolic cfg (SMTMode QueryInternal ISetup True cfg) (proofArgReduce a >> Control.executeQuery QueryInternal check) where check = do cs <- Control.checkSat case cs of Control.Unsat -> return True Control.Sat -> return False Control.DSat{} -> return False Control.Unk -> error "SBV: isVacuous: Solver returned unknown!" -- | Generalization of 'Data.SBV.isTheorem' isTheorem :: a -> m Bool isTheorem = isTheoremWith defaultSMTCfg -- | Generalization of 'Data.SBV.isTheoremWith' isTheoremWith :: SMTConfig -> a -> m Bool isTheoremWith cfg p = do r <- proveWith cfg p let bad = error $ "SBV.isTheorem: Received:\n" ++ show r case r of ThmResult Unsatisfiable{} -> return True ThmResult Satisfiable{} -> return False ThmResult DeltaSat{} -> return False ThmResult SatExtField{} -> return False ThmResult Unknown{} -> bad ThmResult ProofError{} -> bad -- | Prove a property with multiple solvers, running them in separate threads. Only -- the result of the first one to finish will be returned, remaining threads will be killed. -- Note that we send an exception to the losing processes, but we do *not* actually wait for them -- to finish. In rare cases this can lead to zombie processes. In previous experiments, we found -- that some processes take their time to terminate. So, this solution favors quick turnaround. proveWithAny :: Provable a => [SMTConfig] -> a -> IO (Solver, NominalDiffTime, ThmResult) proveWithAny = (`sbvWithAny` proveWith) -- | Prove a property with multiple solvers, running them in separate threads. The -- results will be returned in the order produced. proveWithAll :: Provable a => [SMTConfig] -> a -> IO [(Solver, NominalDiffTime, ThmResult)] proveWithAll = (`sbvWithAll` proveWith) -- | Prove a property by running many queries each isolated to their own thread -- concurrently and return the first that finishes, killing the others proveConcurrentWithAny :: Provable a => SMTConfig -> [Query b] -> a -> IO (Solver, NominalDiffTime, ThmResult) proveConcurrentWithAny solver qs a = do (slvr,time,result) <- sbvConcurrentWithAny solver go qs a return (slvr, time, ThmResult result) where go cfg a' q = runWithQuery proofArgReduce False (do _ <- q; checkNoOptimizations >> Control.getSMTResult) cfg a' -- | Prove a property by running many queries each isolated to their own thread -- concurrently and wait for each to finish returning all results proveConcurrentWithAll :: Provable a => SMTConfig -> [Query b] -> a -> IO [(Solver, NominalDiffTime, ThmResult)] proveConcurrentWithAll solver qs a = do results <- sbvConcurrentWithAll solver go qs a return $ (\(a',b,c) -> (a',b,ThmResult c)) <$> results where go cfg a' q = runWithQuery proofArgReduce False (do _ <- q; checkNoOptimizations >> Control.getSMTResult) cfg a' -- | Validate a model obtained from the solver validate :: MonadIO m => (a -> SymbolicT m SBool) -> Bool -> SMTConfig -> a -> SMTResult -> m SMTResult validate reducer isSAT cfg p res = case res of Unsatisfiable{} -> return res Satisfiable _ m -> case modelBindings m of Nothing -> error "Data.SBV.validate: Impossible happened; no bindings generated during model validation." Just env -> check env DeltaSat {} -> cant [ "The model is delta-satisfiable." , "Cannot validate delta-satisfiable models." ] SatExtField{} -> cant [ "The model requires an extension field value." , "Cannot validate models with infinities/epsilons produced during optimization." , "" , "To turn validation off, use `cfg{optimizeValidateConstraints = False}`" ] Unknown{} -> return res ProofError{} -> return res where cant msg = return $ ProofError cfg (msg ++ [ "" , "Unable to validate the produced model." ]) (Just res) check env = do let envShown = showModelDictionary True True cfg modelBinds where modelBinds = [(T.unpack n, RegularCV v) | (NamedSymVar _ n, v) <- env] notify s | not (verbose cfg) = return () | True = debug cfg ["[VALIDATE] " `alignPlain` s] notify $ "Validating the model. " ++ if null env then "There are no assignments." else "Assignment:" mapM_ notify [" " ++ l | l <- lines envShown] result <- snd <$> runSymbolic cfg (Concrete (Just (isSAT, env))) (reducer p >>= output) let explain = [ "" , "Assignment:" ++ if null env then " " else "" ] ++ [ "" | not (null env)] ++ [ " " ++ l | l <- lines envShown] ++ [ "" ] wrap tag extras = return $ ProofError cfg (tag : explain ++ extras) (Just res) giveUp s = wrap ("Data.SBV: Cannot validate the model: " ++ s) [ "SBV's model validator is incomplete, and cannot handle this particular case." , "Please report this as a feature request or possibly a bug!" ] badModel s = wrap ("Data.SBV: Model validation failure: " ++ s) [ "Backend solver returned a model that does not satisfy the constraints." , "This could indicate a bug in the backend solver, or SBV itself. Please report." ] notConcrete sv = wrap ("Data.SBV: Cannot validate the model, since " ++ show sv ++ " is not concretely computable.") ( perhaps (why sv) ++ [ "SBV's model validator is incomplete, and cannot handle this particular case." , "Please report this as a feature request or possibly a bug!" ] ) where perhaps Nothing = [] perhaps (Just x) = [x, ""] -- This is incomplete, but should capture the most common cases why s = case s `lookup` S.toList (pgmAssignments (resAsgns result)) of Nothing -> Nothing Just (SBVApp o as) -> case o of Uninterpreted v -> Just $ "The value depends on the uninterpreted constant " ++ show v ++ "." QuantifiedBool _ -> Just "The value depends on a quantified variable." IEEEFP FP_FMA -> Just "Floating point FMA operation is not supported concretely." IEEEFP _ -> Just "Not all floating point operations are supported concretely." OverflowOp _ -> Just "Overflow-checking is not done concretely." _ -> listToMaybe $ mapMaybe why as cstrs = S.toList $ resConstraints result walkConstraints [] cont = do unless (null cstrs) $ notify "Validated all constraints." cont walkConstraints ((isSoft, attrs, sv) : rest) cont | kindOf sv /= KBool = giveUp $ "Constraint tied to " ++ show sv ++ " is non-boolean." | isSoft || sv == trueSV = walkConstraints rest cont | sv == falseSV = case mbName of Just nm -> badModel $ "Named constraint " ++ show nm ++ " evaluated to False." Nothing -> badModel "A constraint was violated." | True = notConcrete sv where mbName = listToMaybe [n | (":named", n) <- attrs] -- SAT: All outputs must be true satLoop [] = do notify "All outputs are satisfied. Validation complete." return res satLoop (sv:svs) | kindOf sv /= KBool = giveUp $ "Output tied to " ++ show sv ++ " is non-boolean." | sv == trueSV = satLoop svs | sv == falseSV = badModel "Final output evaluated to False." | True = notConcrete sv -- Proof: At least one output must be false proveLoop [] somethingFailed | somethingFailed = do notify "Counterexample is validated." return res | True = do notify "Counterexample violates none of the outputs." badModel "Counter-example violates no constraints." proveLoop (sv:svs) somethingFailed | kindOf sv /= KBool = giveUp $ "Output tied to " ++ show sv ++ " is non-boolean." | sv == trueSV = proveLoop svs somethingFailed | sv == falseSV = proveLoop svs True | True = notConcrete sv -- Output checking is tricky, since we behave differently for different modes checkOutputs [] | null cstrs = giveUp "Impossible happened: There are no outputs nor any constraints to check." checkOutputs os = do notify "Validating outputs." if isSAT then satLoop os else proveLoop os False notify $ if null cstrs then "There are no constraints to check." else "Validating " ++ show (length cstrs) ++ " constraint(s)." walkConstraints cstrs (checkOutputs (resOutputs result)) -- | Create an SMT-Lib2 benchmark, for a SAT query. generateSMTBenchmarkSat :: SatisfiableM m a => a -> m String generateSMTBenchmarkSat = generateSMTBenchMarkGen True satArgReduce -- | Create an SMT-Lib2 benchmark, for a Proof query. generateSMTBenchmarkProof :: ProvableM m a => a -> m String generateSMTBenchmarkProof = generateSMTBenchMarkGen False proofArgReduce -- | Generic benchmark creator generateSMTBenchMarkGen :: MonadIO m => Bool -> (a -> SymbolicT m SBool) -> a -> m String generateSMTBenchMarkGen isSat reduce a = do t <- liftIO getZonedTime let comments = ["Automatically created by SBV on " ++ show t] cfg = defaultSMTCfg { smtLibVersion = SMTLib2 } (_, res) <- runSymbolic cfg (SMTMode QueryInternal ISetup isSat cfg) $ reduce a >>= output let SMTProblem{smtLibPgm} = Control.runProofOn (SMTMode QueryInternal IRun isSat cfg) QueryInternal comments res out = show (smtLibPgm cfg) return $ out ++ "\n(check-sat)\n" checkNoOptimizations :: MonadIO m => QueryT m () checkNoOptimizations = do objectives <- Control.getObjectives unless (null objectives) $ error $ unlines [ "" , "*** Data.SBV: Unsupported call sat/prove when optimization objectives are present." , "*** Use \"optimize\"/\"optimizeWith\" to calculate optimal satisfaction!" ] instance ExtractIO m => SatisfiableM m (SymbolicT m ()) where satArgReduce a = satArgReduce ((a >> pure sTrue) :: SymbolicT m SBool) -- instance ExtractIO m => ProvableM m (SymbolicT m ()) -- NO INSTANCE ON PURPOSE; don't want to prove goals instance ExtractIO m => SatisfiableM m (SymbolicT m SBool) where satArgReduce = id instance ExtractIO m => ProvableM m (SymbolicT m SBool) where proofArgReduce = id instance ExtractIO m => SatisfiableM m SBool where satArgReduce = return instance ExtractIO m => ProvableM m SBool where proofArgReduce = return instance (ExtractIO m, SymVal a, Constraint Symbolic r, SatisfiableM m r) => SatisfiableM m (Forall nm a -> r) where satArgReduce = satArgReduce . quantifiedBool instance (ExtractIO m, SymVal a, Constraint Symbolic r, ProvableM m r) => ProvableM m (Forall nm a -> r) where proofArgReduce = proofArgReduce . quantifiedBool instance (ExtractIO m, SymVal a, Constraint Symbolic r, SatisfiableM m r) => SatisfiableM m (Exists nm a -> r) where satArgReduce = satArgReduce . quantifiedBool instance (ExtractIO m, SymVal a, Constraint Symbolic r, SatisfiableM m r, EqSymbolic (SBV a)) => SatisfiableM m (ExistsUnique nm a -> r) where satArgReduce = satArgReduce . quantifiedBool instance (KnownNat n, ExtractIO m, SymVal a, Constraint Symbolic r, ProvableM m r) => ProvableM m (ForallN n nm a -> r) where proofArgReduce = proofArgReduce . quantifiedBool instance (KnownNat n, ExtractIO m, SymVal a, Constraint Symbolic r, SatisfiableM m r) => SatisfiableM m (ExistsN n nm a -> r) where satArgReduce = satArgReduce . quantifiedBool instance (ExtractIO m, SymVal a, Constraint Symbolic r, ProvableM m r) => ProvableM m (Exists nm a -> r) where proofArgReduce = proofArgReduce . quantifiedBool instance (ExtractIO m, SymVal a, Constraint Symbolic r, ProvableM m r, EqSymbolic (SBV a)) => ProvableM m (ExistsUnique nm a -> r) where proofArgReduce = proofArgReduce . quantifiedBool instance (KnownNat n, ExtractIO m, SymVal a, Constraint Symbolic r, SatisfiableM m r) => SatisfiableM m (ForallN n nm a -> r) where satArgReduce = satArgReduce . quantifiedBool instance (KnownNat n, ExtractIO m, SymVal a, Constraint Symbolic r, ProvableM m r) => ProvableM m (ExistsN n nm a -> r) where proofArgReduce = proofArgReduce . quantifiedBool {- -- The following is a possible definition, but it lets us write properties that -- are not useful.. Such as: prove $ \x y -> (x::SInt8) == y -- Running that will throw an exception since Haskell's equality is not be supported by symbolic things. (Needs .==). -- So, we avoid these insteances. instance ExtractIO m => ProvableM m Bool where proofArgReduce x = proofArgReduce (if x then sTrue else sFalse :: SBool) instance ExtractIO m => SatisfiableM m Bool where satArgReduce x = satArgReduce (if x then sTrue else sFalse :: SBool) -} -- | Create an argument mkArg :: (SymVal a, MonadSymbolic m) => m (SBV a) mkArg = mkSymVal (NonQueryVar Nothing) Nothing -- Functions instance (SymVal a, SatisfiableM m p) => SatisfiableM m (SBV a -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ k a instance (SymVal a, ProvableM m p) => ProvableM m (SBV a -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ k a -- Arrays instance (HasKind a, HasKind b, SatisfiableM m p) => SatisfiableM m (SArray a b -> p) where satArgReduce k = newArray_ Nothing >>= \a -> satArgReduce $ k a instance (HasKind a, HasKind b, ProvableM m p) => ProvableM m (SArray a b -> p) where proofArgReduce k = newArray_ Nothing >>= \a -> proofArgReduce $ k a -- 2 Tuple instance (SymVal a, SymVal b, SatisfiableM m p) => SatisfiableM m ((SBV a, SBV b) -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ \b -> k (a, b) instance (SymVal a, SymVal b, ProvableM m p) => ProvableM m ((SBV a, SBV b) -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ \b -> k (a, b) -- 3 Tuple instance (SymVal a, SymVal b, SymVal c, SatisfiableM m p) => SatisfiableM m ((SBV a, SBV b, SBV c) -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ \b c -> k (a, b, c) instance (SymVal a, SymVal b, SymVal c, ProvableM m p) => ProvableM m ((SBV a, SBV b, SBV c) -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ \b c -> k (a, b, c) -- 4 Tuple instance (SymVal a, SymVal b, SymVal c, SymVal d, SatisfiableM m p) => SatisfiableM m ((SBV a, SBV b, SBV c, SBV d) -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ \b c d -> k (a, b, c, d) instance (SymVal a, SymVal b, SymVal c, SymVal d, ProvableM m p) => ProvableM m ((SBV a, SBV b, SBV c, SBV d) -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ \b c d -> k (a, b, c, d) -- 5 Tuple instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SatisfiableM m p) => SatisfiableM m ((SBV a, SBV b, SBV c, SBV d, SBV e) -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ \b c d e -> k (a, b, c, d, e) instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, ProvableM m p) => ProvableM m ((SBV a, SBV b, SBV c, SBV d, SBV e) -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ \b c d e -> k (a, b, c, d, e) -- 6 Tuple instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SymVal f, SatisfiableM m p) => SatisfiableM m ((SBV a, SBV b, SBV c, SBV d, SBV e, SBV f) -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ \b c d e f -> k (a, b, c, d, e, f) instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SymVal f, ProvableM m p) => ProvableM m ((SBV a, SBV b, SBV c, SBV d, SBV e, SBV f) -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ \b c d e f -> k (a, b, c, d, e, f) -- 7 Tuple instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SymVal f, SymVal g, SatisfiableM m p) => SatisfiableM m ((SBV a, SBV b, SBV c, SBV d, SBV e, SBV f, SBV g) -> p) where satArgReduce k = mkArg >>= \a -> satArgReduce $ \b c d e f g -> k (a, b, c, d, e, f, g) instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SymVal f, SymVal g, ProvableM m p) => ProvableM m ((SBV a, SBV b, SBV c, SBV d, SBV e, SBV f, SBV g) -> p) where proofArgReduce k = mkArg >>= \a -> proofArgReduce $ \b c d e f g -> k (a, b, c, d, e, f, g) -- | Generalization of 'Data.SBV.runSMT' runSMT :: MonadIO m => SymbolicT m a -> m a runSMT = runSMTWith defaultSMTCfg -- | Generalization of 'Data.SBV.runSMTWith' runSMTWith :: MonadIO m => SMTConfig -> SymbolicT m a -> m a runSMTWith cfg a = fst <$> runSymbolic cfg (SMTMode QueryExternal ISetup True cfg) a -- | Runs with a query. runWithQuery :: ExtractIO m => (a -> SymbolicT m SBool) -> Bool -> QueryT m b -> SMTConfig -> a -> m b runWithQuery reducer isSAT q cfg a = fst <$> runSymbolic cfg (SMTMode QueryInternal ISetup isSAT cfg) comp where comp = do _ <- reducer a >>= output Control.executeQuery QueryInternal q -- | Check if a safe-call was safe or not, turning a 'SafeResult' to a Bool. isSafe :: SafeResult -> Bool isSafe (SafeResult (_, _, result)) = case result of Unsatisfiable{} -> True Satisfiable{} -> False DeltaSat{} -> False -- conservative SatExtField{} -> False -- conservative Unknown{} -> False -- conservative ProofError{} -> False -- conservative -- | Perform an action asynchronously, returning results together with diff-time. runInThread :: NFData b => UTCTime -> (SMTConfig -> IO b) -> SMTConfig -> IO (Async (Solver, NominalDiffTime, b)) runInThread beginTime action config = async $ do result <- action config endTime <- rnf result `seq` getCurrentTime return (name (solver config), endTime `diffUTCTime` beginTime, result) -- | Perform action for all given configs, return the first one that wins. Note that we do -- not wait for the other asyncs to terminate; hopefully they'll do so quickly. sbvWithAny :: NFData b => [SMTConfig] -> (SMTConfig -> a -> IO b) -> a -> IO (Solver, NominalDiffTime, b) sbvWithAny [] _ _ = error "SBV.withAny: No solvers given!" sbvWithAny solvers what a = do beginTime <- getCurrentTime snd `fmap` (mapM (runInThread beginTime (`what` a)) solvers >>= waitAnyFastCancel) where -- Async's `waitAnyCancel` nicely blocks; so we use this variant to ignore the -- wait part for killed threads. waitAnyFastCancel asyncs = waitAny asyncs `finally` mapM_ cancelFast asyncs cancelFast other = throwTo (asyncThreadId other) ExitSuccess sbvConcurrentWithAny :: NFData c => SMTConfig -> (SMTConfig -> a -> QueryT m b -> IO c) -> [QueryT m b] -> a -> IO (Solver, NominalDiffTime, c) sbvConcurrentWithAny solver what queries a = snd `fmap` (mapM runQueryInThread queries >>= waitAnyFastCancel) where -- Async's `waitAnyCancel` nicely blocks; so we use this variant to ignore the -- wait part for killed threads. waitAnyFastCancel asyncs = waitAny asyncs `finally` mapM_ cancelFast asyncs cancelFast other = throwTo (asyncThreadId other) ExitSuccess runQueryInThread q = do beginTime <- getCurrentTime runInThread beginTime (\cfg -> what cfg a q) solver sbvConcurrentWithAll :: NFData c => SMTConfig -> (SMTConfig -> a -> QueryT m b -> IO c) -> [QueryT m b] -> a -> IO [(Solver, NominalDiffTime, c)] sbvConcurrentWithAll solver what queries a = mapConcurrently runQueryInThread queries >>= unsafeInterleaveIO . go where runQueryInThread q = do beginTime <- getCurrentTime runInThread beginTime (\cfg -> what cfg a q) solver go [] = return [] go as = do (d, r) <- waitAny as -- The following filter works because the Eq instance on Async -- checks the thread-id; so we know that we're removing the -- correct solver from the list. This also allows for -- running the same-solver (with different options), since -- they will get different thread-ids. rs <- unsafeInterleaveIO $ go (filter (/= d) as) return (r : rs) -- | Perform action for all given configs, return all the results. sbvWithAll :: NFData b => [SMTConfig] -> (SMTConfig -> a -> IO b) -> a -> IO [(Solver, NominalDiffTime, b)] sbvWithAll solvers what a = do beginTime <- getCurrentTime mapM (runInThread beginTime (`what` a)) solvers >>= (unsafeInterleaveIO . go) where go [] = return [] go as = do (d, r) <- waitAny as -- The following filter works because the Eq instance on Async -- checks the thread-id; so we know that we're removing the -- correct solver from the list. This also allows for -- running the same-solver (with different options), since -- they will get different thread-ids. rs <- unsafeInterleaveIO $ go (filter (/= d) as) return (r : rs) -- | Symbolically executable program fragments. This class is mainly used for 'safe' calls, and is sufficiently populated internally to cover most use -- cases. Users can extend it as they wish to allow 'safe' checks for SBV programs that return/take types that are user-defined. class ExtractIO m => SExecutable m a where -- | Generalization of 'Data.SBV.sName' sName :: a -> SymbolicT m () -- | Generalization of 'Data.SBV.safe' safe :: a -> m [SafeResult] safe = safeWith defaultSMTCfg -- | Generalization of 'Data.SBV.safeWith' safeWith :: SMTConfig -> a -> m [SafeResult] safeWith cfg a = do cwd <- (++ "/") <$> liftIO getCurrentDirectory let mkRelative path | cwd `isPrefixOf` path = drop (length cwd) path | True = path fst <$> runSymbolic cfg (SMTMode QueryInternal ISafe True cfg) (sName a >> check mkRelative) where check :: (FilePath -> FilePath) -> SymbolicT m [SafeResult] check mkRelative = Control.executeQuery QueryInternal $ Control.getSBVAssertions >>= mapM (verify mkRelative) -- check that the cond is unsatisfiable. If satisfiable, that would -- indicate the assignment under which the 'Data.SBV.sAssert' would fail verify :: (FilePath -> FilePath) -> (String, Maybe CallStack, SV) -> QueryT m SafeResult verify mkRelative (msg, cs, cond) = do let locInfo ps = let loc (f, sl) = concat [mkRelative (srcLocFile sl), ":", show (srcLocStartLine sl), ":", show (srcLocStartCol sl), ":", f] in intercalate ",\n " (map loc ps) location = (locInfo . getCallStack) `fmap` cs result <- do Control.push 1 Control.send True $ "(assert " ++ show cond ++ ")" r <- Control.getSMTResult Control.pop 1 return r return $ SafeResult (location, msg, result) instance (ExtractIO m, NFData a) => SExecutable m (SymbolicT m a) where sName a = a >>= \r -> rnf r `seq` return () instance ExtractIO m => SExecutable m (SBV a) where sName v = sName (output v :: SymbolicT m (SBV a)) -- Unit output instance ExtractIO m => SExecutable m () where sName () = sName (output () :: SymbolicT m ()) -- List output instance ExtractIO m => SExecutable m [SBV a] where sName vs = sName (output vs :: SymbolicT m [SBV a]) -- 2 Tuple output instance (ExtractIO m, NFData a, SymVal a, NFData b, SymVal b) => SExecutable m (SBV a, SBV b) where sName (a, b) = sName (output a >> output b :: SymbolicT m (SBV b)) -- 3 Tuple output instance (ExtractIO m, NFData a, SymVal a, NFData b, SymVal b, NFData c, SymVal c) => SExecutable m (SBV a, SBV b, SBV c) where sName (a, b, c) = sName (output a >> output b >> output c :: SymbolicT m (SBV c)) -- 4 Tuple output instance (ExtractIO m, NFData a, SymVal a, NFData b, SymVal b, NFData c, SymVal c, NFData d, SymVal d) => SExecutable m (SBV a, SBV b, SBV c, SBV d) where sName (a, b, c, d) = sName (output a >> output b >> output c >> output c >> output d :: SymbolicT m (SBV d)) -- 5 Tuple output instance (ExtractIO m, NFData a, SymVal a, NFData b, SymVal b, NFData c, SymVal c, NFData d, SymVal d, NFData e, SymVal e) => SExecutable m (SBV a, SBV b, SBV c, SBV d, SBV e) where sName (a, b, c, d, e) = sName (output a >> output b >> output c >> output d >> output e :: SymbolicT m (SBV e)) -- 6 Tuple output instance (ExtractIO m, NFData a, SymVal a, NFData b, SymVal b, NFData c, SymVal c, NFData d, SymVal d, NFData e, SymVal e, NFData f, SymVal f) => SExecutable m (SBV a, SBV b, SBV c, SBV d, SBV e, SBV f) where sName (a, b, c, d, e, f) = sName (output a >> output b >> output c >> output d >> output e >> output f :: SymbolicT m (SBV f)) -- 7 Tuple output instance (ExtractIO m, NFData a, SymVal a, NFData b, SymVal b, NFData c, SymVal c, NFData d, SymVal d, NFData e, SymVal e, NFData f, SymVal f, NFData g, SymVal g) => SExecutable m (SBV a, SBV b, SBV c, SBV d, SBV e, SBV f, SBV g) where sName (a, b, c, d, e, f, g) = sName (output a >> output b >> output c >> output d >> output e >> output f >> output g :: SymbolicT m (SBV g)) -- Functions instance (SymVal a, SExecutable m p) => SExecutable m (SBV a -> p) where sName k = mkArg >>= \a -> sName $ k a -- 2 Tuple input instance (SymVal a, SymVal b, SExecutable m p) => SExecutable m ((SBV a, SBV b) -> p) where sName k = mkArg >>= \a -> sName $ \b -> k (a, b) -- 3 Tuple input instance (SymVal a, SymVal b, SymVal c, SExecutable m p) => SExecutable m ((SBV a, SBV b, SBV c) -> p) where sName k = mkArg >>= \a -> sName $ \b c -> k (a, b, c) -- 4 Tuple input instance (SymVal a, SymVal b, SymVal c, SymVal d, SExecutable m p) => SExecutable m ((SBV a, SBV b, SBV c, SBV d) -> p) where sName k = mkArg >>= \a -> sName $ \b c d -> k (a, b, c, d) -- 5 Tuple input instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SExecutable m p) => SExecutable m ((SBV a, SBV b, SBV c, SBV d, SBV e) -> p) where sName k = mkArg >>= \a -> sName $ \b c d e -> k (a, b, c, d, e) -- 6 Tuple input instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SymVal f, SExecutable m p) => SExecutable m ((SBV a, SBV b, SBV c, SBV d, SBV e, SBV f) -> p) where sName k = mkArg >>= \a -> sName $ \b c d e f -> k (a, b, c, d, e, f) -- 7 Tuple input instance (SymVal a, SymVal b, SymVal c, SymVal d, SymVal e, SymVal f, SymVal g, SExecutable m p) => SExecutable m ((SBV a, SBV b, SBV c, SBV d, SBV e, SBV f, SBV g) -> p) where sName k = mkArg >>= \a -> sName $ \b c d e f g -> k (a, b, c, d, e, f, g) {- HLint ignore module "Reduce duplication" -}