----------------------------------------------------------------------------- -- | -- Module : Data.SBV.Control -- Copyright : (c) Levent Erkok -- License : BSD3 -- Maintainer: erkokl@gmail.com -- Stability : experimental -- -- Control sublanguage for interacting with SMT solvers. ----------------------------------------------------------------------------- {-# LANGUAGE ConstraintKinds #-} {-# OPTIONS_GHC -Wall -Werror #-} module Data.SBV.Control ( -- $queryIntro -- * User queries ExtractIO(..), MonadQuery(..), Queriable(..), Fresh(..), Query, query -- * Create a fresh variable , freshVar_, freshVar -- * Create a fresh array , freshArray_, freshArray -- * Checking satisfiability , CheckSatResult(..), checkSat, ensureSat, checkSatUsing, checkSatAssuming, checkSatAssumingWithUnsatisfiableSet -- * Querying the solver -- ** Extracting values , getValue, registerUISMTFunction, getFunction, getUninterpretedValue, getModel, getAssignment, getSMTResult, getUnknownReason, getObservables -- ** Extracting the unsat core , getUnsatCore -- ** Extracting a proof , getProof -- ** Extracting interpolants , getInterpolantMathSAT, getInterpolantZ3 -- ** Extracting assertions , getAssertions -- * Getting solver information , SMTInfoFlag(..), SMTErrorBehavior(..), SMTInfoResponse(..) , getInfo, getOption -- * Entering and exiting assertion stack , getAssertionStackDepth, push, pop, inNewAssertionStack -- * Higher level tactics , caseSplit -- * Resetting the solver state , resetAssertions -- * Constructing assignments , (|->) -- * Terminating the query , mkSMTResult , exit -- * Controlling the solver behavior , ignoreExitCode, timeout -- * Miscellaneous , queryDebug , echo , io -- * Solver options , SMTOption(..) ) where import Data.SBV.Core.Symbolic (MonadQuery(..), Query, Queriable(..), Fresh(..), Symbolic, QueryContext(..)) import Data.SBV.Control.BaseIO import Data.SBV.Control.Query hiding ( getInfo, getOption, getUnknownReason, getObservables , getSMTResult, getLexicographicOptResults , getIndependentOptResults , getParetoOptResults, getModel , checkSatAssuming , checkSatAssumingWithUnsatisfiableSet , getAssertionStackDepth , inNewAssertionStack, push, pop , caseSplit, resetAssertions, echo, exit , getUnsatCore, getProof, getInterpolantMathSAT, getInterpolantZ3 , getAssertions, getAssignment , mkSMTResult, freshVar_, freshVar , freshArray, freshArray_, checkSat, ensureSat , checkSatUsing, getValue , getUninterpretedValue, timeout, io) import Data.SBV.Control.Utils (registerUISMTFunction) import Data.SBV.Utils.ExtractIO (ExtractIO(..)) import qualified Data.SBV.Control.Utils as Trans -- | Run a custom query query :: Query a -> Symbolic a query :: Query a -> Symbolic a query = QueryContext -> Query a -> Symbolic a forall (m :: * -> *) a. ExtractIO m => QueryContext -> QueryT m a -> SymbolicT m a Trans.executeQuery QueryContext QueryExternal {- $queryIntro In certain cases, the user might want to take over the communication with the solver, programmatically querying the engine and issuing commands accordingly. Queries can be extremely powerful as they allow direct control of the solver. Here's a simple example: @ module Test where import Data.SBV import Data.SBV.Control -- queries require this module to be imported! test :: Symbolic (Maybe (Integer, Integer)) test = do x <- sInteger "x" -- a free variable named "x" y <- sInteger "y" -- a free variable named "y" -- require the sum to be 10 constrain $ x + y .== 10 -- Go into the Query mode query $ do -- Query the solver: Are the constraints satisfiable? cs <- checkSat case cs of Unk -> error "Solver said unknown!" Unsat -> return Nothing -- no solution! Sat -> -- Query the values: do xv <- getValue x yv <- getValue y io $ putStrLn $ "Solver returned: " ++ show (xv, yv) -- We can now add new constraints, -- Or perform arbitrary computations and tell -- the solver anything we want! constrain $ x .> literal xv + literal yv -- call checkSat again csNew <- checkSat case csNew of Unk -> error "Solver said unknown!" Unsat -> return Nothing Sat -> do xv2 <- getValue x yv2 <- getValue y return $ Just (xv2, yv2) @ Note the type of @test@: it returns an optional pair of integers in the 'Symbolic' monad. We turn it into an IO value with the 'Data.SBV.Control.runSMT' function: (There's also 'Data.SBV.Control.runSMTWith' that uses a user specified solver instead of the default. Note that 'Data.SBV.Provers.z3' is best supported (and tested), if you use another solver your results may vary!) @ pair :: IO (Maybe (Integer, Integer)) pair = runSMT test @ When run, this can return: @ *Test> pair Solver returned: (10,0) Just (11,-1) @ demonstrating that the user has full contact with the solver and can guide it as the program executes. SBV provides access to many SMTLib features in the query mode, as exported from this very module. For other examples see: - "Documentation.SBV.Examples.Queries.AllSat": Simulating SBV's 'Data.SBV.allSat' using queries. - "Documentation.SBV.Examples.Queries.CaseSplit": Performing a case-split during a query. - "Documentation.SBV.Examples.Queries.Enums": Using enumerations in queries. - "Documentation.SBV.Examples.Queries.FourFours": Solution to a fun arithmetic puzzle, coded using queries. - "Documentation.SBV.Examples.Queries.GuessNumber": The famous number guessing game. - "Documentation.SBV.Examples.Queries.UnsatCore": Extracting unsat-cores using queries. - "Documentation.SBV.Examples.Queries.Interpolants": Extracting interpolants using queries. -}