----------------------------------------------------------------------------- -- | -- Module : Data.SBV.Client.BaseIO -- Copyright : (c) Brian Schroeder -- Levent Erkok -- License : BSD3 -- Maintainer: erkokl@gmail.com -- Stability : experimental -- -- Monomorphized versions of functions for simplified client use via -- @Data.SBV@, where we restrict the underlying monad to be IO. ----------------------------------------------------------------------------- {-# LANGUAGE DataKinds #-} {-# LANGUAGE DefaultSignatures #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE TypeOperators #-} {-# LANGUAGE UndecidableInstances #-} {-# OPTIONS_GHC -Wall -Werror #-} module Data.SBV.Client.BaseIO where import Data.SBV.Core.Data (HasKind, Kind, Outputtable, Penalty, SymArray, SymVal, SBool, SBV, SChar, SDouble, SFloat, SInt8, SInt16, SInt32, SInt64, SInteger, SList, SReal, SString, SV, SWord8, SWord16, SWord32, SWord64, SEither, SMaybe, SSet) import Data.SBV.Core.Sized (SInt, SWord, IntN, WordN, IsNonZero) import Data.SBV.Core.Model (Metric(..), SymTuple) import Data.SBV.Core.Symbolic (Objective, OptimizeStyle, Quantifier, Result, Symbolic, SBVRunMode, SMTConfig, SVal) import Data.SBV.Control.Types (SMTOption) import Data.SBV.Provers.Prover (Provable, SExecutable, ThmResult) import Data.SBV.SMT.SMT (AllSatResult, SafeResult, SatResult, OptimizeResult) import GHC.TypeLits import Data.Kind import Data.Int import Data.Word import qualified Data.SBV.Core.Data as Trans import qualified Data.SBV.Core.Sized as Trans import qualified Data.SBV.Core.Model as Trans import qualified Data.SBV.Core.Symbolic as Trans import qualified Data.SBV.Provers.Prover as Trans -- Data.SBV.Provers.Prover: -- | Turns a value into a universally quantified predicate, internally naming the inputs. -- In this case the sbv library will use names of the form @s1, s2@, etc. to name these variables -- Example: -- -- > forAll_ $ \(x::SWord8) y -> x `shiftL` 2 .== y -- -- is a predicate with two arguments, captured using an ordinary Haskell function. Internally, -- @x@ will be named @s0@ and @y@ will be named @s1@. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.forAll_' forAll_ :: Provable a => a -> Symbolic SBool forAll_ = Trans.forAll_ -- | Turns a value into a predicate, allowing users to provide names for the inputs. -- If the user does not provide enough number of names for the variables, the remaining ones -- will be internally generated. Note that the names are only used for printing models and has no -- other significance; in particular, we do not check that they are unique. Example: -- -- > forAll ["x", "y"] $ \(x::SWord8) y -> x `shiftL` 2 .== y -- -- This is the same as above, except the variables will be named @x@ and @y@ respectively, -- simplifying the counter-examples when they are printed. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.forAll' forAll :: Provable a => [String] -> a -> Symbolic SBool forAll = Trans.forAll -- | Turns a value into an existentially quantified predicate. (Indeed, 'exists' would have been -- a better choice here for the name, but alas it's already taken.) -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.forSome_' forSome_ :: Provable a => a -> Symbolic SBool forSome_ = Trans.forSome_ -- | Version of 'forSome' that allows user defined names. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.forSome' forSome :: Provable a => [String] -> a -> Symbolic SBool forSome = Trans.forSome -- | Prove a predicate, using the default solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.prove' prove :: Provable a => a -> IO ThmResult prove = Trans.prove -- | Prove the predicate using the given SMT-solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.proveWith' proveWith :: Provable a => SMTConfig -> a -> IO ThmResult proveWith = Trans.proveWith -- | Find a satisfying assignment for a predicate, using the default solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sat' sat :: Provable a => a -> IO SatResult sat = Trans.sat -- | Find a satisfying assignment using the given SMT-solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.satWith' satWith :: Provable a => SMTConfig -> a -> IO SatResult satWith = Trans.satWith -- | Find all satisfying assignments, using the default solver. -- Equivalent to @'allSatWith' 'Data.SBV.defaultSMTCfg'@. See 'allSatWith' for details. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.allSat' allSat :: Provable a => a -> IO AllSatResult allSat = Trans.allSat -- | Return all satisfying assignments for a predicate. -- Note that this call will block until all satisfying assignments are found. If you have a problem -- with infinitely many satisfying models (consider 'SInteger') or a very large number of them, you -- might have to wait for a long time. To avoid such cases, use the 'Data.SBV.Core.Symbolic.allSatMaxModelCount' -- parameter in the configuration. -- -- NB. Uninterpreted constant/function values and counter-examples for array values are ignored for -- the purposes of 'allSat'. That is, only the satisfying assignments modulo uninterpreted functions and -- array inputs will be returned. This is due to the limitation of not having a robust means of getting a -- function counter-example back from the SMT solver. -- Find all satisfying assignments using the given SMT-solver -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.allSatWith' allSatWith :: Provable a => SMTConfig -> a -> IO AllSatResult allSatWith = Trans.allSatWith -- | Optimize a given collection of `Objective`s. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.optimize' optimize :: Provable a => OptimizeStyle -> a -> IO OptimizeResult optimize = Trans.optimize -- | Optimizes the objectives using the given SMT-solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.optimizeWith' optimizeWith :: Provable a => SMTConfig -> OptimizeStyle -> a -> IO OptimizeResult optimizeWith = Trans.optimizeWith -- | Check if the constraints given are consistent, using the default solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.isVacuous' isVacuous :: Provable a => a -> IO Bool isVacuous = Trans.isVacuous -- | Determine if the constraints are vacuous using the given SMT-solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.isVacuousWith' isVacuousWith :: Provable a => SMTConfig -> a -> IO Bool isVacuousWith = Trans.isVacuousWith -- | Checks theoremhood using the default solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.isTheorem' isTheorem :: Provable a => a -> IO Bool isTheorem = Trans.isTheorem -- | Check whether a given property is a theorem. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.isTheoremWith' isTheoremWith :: Provable a => SMTConfig -> a -> IO Bool isTheoremWith = Trans.isTheoremWith -- | Checks satisfiability using the default solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.isSatisfiable' isSatisfiable :: Provable a => a -> IO Bool isSatisfiable = Trans.isSatisfiable -- | Check whether a given property is satisfiable. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.isSatisfiableWith' isSatisfiableWith :: Provable a => SMTConfig -> a -> IO Bool isSatisfiableWith = Trans.isSatisfiableWith -- | Run an arbitrary symbolic computation, equivalent to @'runSMTWith' 'Data.SBV.defaultSMTCfg'@ -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.runSMT' runSMT :: Symbolic a -> IO a runSMT = Trans.runSMT -- | Runs an arbitrary symbolic computation, exposed to the user in SAT mode -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.runSMTWith' runSMTWith :: SMTConfig -> Symbolic a -> IO a runSMTWith = Trans.runSMTWith -- | NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sName_' sName_ :: SExecutable IO a => a -> Symbolic () sName_ = Trans.sName_ -- | NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sName' sName :: SExecutable IO a => [String] -> a -> Symbolic () sName = Trans.sName -- | Check safety using the default solver. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.safe' safe :: SExecutable IO a => a -> IO [SafeResult] safe = Trans.safe -- | Check if any of the 'Data.SBV.sAssert' calls can be violated. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.safeWith' safeWith :: SExecutable IO a => SMTConfig -> a -> IO [SafeResult] safeWith = Trans.safeWith -- Data.SBV.Core.Data: -- | Create a symbolic variable. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.mkSymSBV' mkSymSBV :: Maybe Quantifier -> Kind -> Maybe String -> Symbolic (SBV a) mkSymSBV = Trans.mkSymSBV -- | Convert a symbolic value to an SV, inside the Symbolic monad -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sbvToSymSV' sbvToSymSV :: SBV a -> Symbolic SV sbvToSymSV = Trans.sbvToSymSV -- | Mark an interim result as an output. Useful when constructing Symbolic programs -- that return multiple values, or when the result is programmatically computed. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.output' output :: Outputtable a => a -> Symbolic a output = Trans.output -- | Create a user named input (universal) -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.forall' forall :: SymVal a => String -> Symbolic (SBV a) forall = Trans.forall -- | Create an automatically named input -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.forall_' forall_ :: SymVal a => Symbolic (SBV a) forall_ = Trans.forall_ -- | Get a bunch of new words -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.mkForallVars' mkForallVars :: SymVal a => Int -> Symbolic [SBV a] mkForallVars = Trans.mkForallVars -- | Create an existential variable -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.exists' exists :: SymVal a => String -> Symbolic (SBV a) exists = Trans.exists -- | Create an automatically named existential variable -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.exists_' exists_ :: SymVal a => Symbolic (SBV a) exists_ = Trans.exists_ -- | Create a bunch of existentials -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.mkExistVars' mkExistVars :: SymVal a => Int -> Symbolic [SBV a] mkExistVars = Trans.mkExistVars -- | Create a free variable, universal in a proof, existential in sat -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.free' free :: SymVal a => String -> Symbolic (SBV a) free = Trans.free -- | Create an unnamed free variable, universal in proof, existential in sat -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.free_' free_ :: SymVal a => Symbolic (SBV a) free_ = Trans.free_ -- | Create a bunch of free vars -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.mkFreeVars' mkFreeVars :: SymVal a => Int -> Symbolic [SBV a] mkFreeVars = Trans.mkFreeVars -- | Similar to free; Just a more convenient name -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.symbolic' symbolic :: SymVal a => String -> Symbolic (SBV a) symbolic = Trans.symbolic -- | Similar to mkFreeVars; but automatically gives names based on the strings -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.symbolics' symbolics :: SymVal a => [String] -> Symbolic [SBV a] symbolics = Trans.symbolics -- | One stop allocator -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.mkSymVal' mkSymVal :: SymVal a => Maybe Quantifier -> Maybe String -> Symbolic (SBV a) mkSymVal = Trans.mkSymVal -- | Create a new anonymous array, possibly with a default initial value. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.newArray_' newArray_ :: (SymArray array, HasKind a, HasKind b) => Maybe (SBV b) -> Symbolic (array a b) newArray_ = Trans.newArray_ -- | Create a named new array, possibly with a default initial value. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.newArray' newArray :: (SymArray array, HasKind a, HasKind b) => String -> Maybe (SBV b) -> Symbolic (array a b) newArray = Trans.newArray -- Data.SBV.Core.Model: -- | Generically make a symbolic var -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.genMkSymVar' genMkSymVar :: Kind -> Maybe Quantifier -> Maybe String -> Symbolic (SBV a) genMkSymVar = Trans.genMkSymVar -- | Declare a named 'SBool' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sBool' sBool :: String -> Symbolic SBool sBool = Trans.sBool -- | Declare an unnamed 'SBool' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sBool_' sBool_ :: Symbolic SBool sBool_ = Trans.sBool_ -- | Declare a list of 'SBool's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sBools' sBools :: [String] -> Symbolic [SBool] sBools = Trans.sBools -- | Declare a named 'SWord8' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord8' sWord8 :: String -> Symbolic SWord8 sWord8 = Trans.sWord8 -- | Declare an unnamed 'SWord8' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord8_' sWord8_ :: Symbolic SWord8 sWord8_ = Trans.sWord8_ -- | Declare a list of 'SWord8's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord8s' sWord8s :: [String] -> Symbolic [SWord8] sWord8s = Trans.sWord8s -- | Declare a named 'SWord16' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord16' sWord16 :: String -> Symbolic SWord16 sWord16 = Trans.sWord16 -- | Declare an unnamed 'SWord16' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord16_' sWord16_ :: Symbolic SWord16 sWord16_ = Trans.sWord16_ -- | Declare a list of 'SWord16's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord16s' sWord16s :: [String] -> Symbolic [SWord16] sWord16s = Trans.sWord16s -- | Declare a named 'SWord32' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord32' sWord32 :: String -> Symbolic SWord32 sWord32 = Trans.sWord32 -- | Declare an unamed 'SWord32' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord32_' sWord32_ :: Symbolic SWord32 sWord32_ = Trans.sWord32_ -- | Declare a list of 'SWord32's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord32s' sWord32s :: [String] -> Symbolic [SWord32] sWord32s = Trans.sWord32s -- | Declare a named 'SWord64' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord64' sWord64 :: String -> Symbolic SWord64 sWord64 = Trans.sWord64 -- | Declare an unnamed 'SWord64' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord64_' sWord64_ :: Symbolic SWord64 sWord64_ = Trans.sWord64_ -- | Declare a list of 'SWord64's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord64s' sWord64s :: [String] -> Symbolic [SWord64] sWord64s = Trans.sWord64s -- | Declare a named 'SWord' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord' sWord :: (KnownNat n, IsNonZero n) => String -> Symbolic (SWord n) sWord = Trans.sWord -- | Declare an unnamed 'SWord' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWord_' sWord_ :: (KnownNat n, IsNonZero n) => Symbolic (SWord n) sWord_ = Trans.sWord_ -- | Declare a list of 'SWord8's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sWords' sWords :: (KnownNat n, IsNonZero n) => [String] -> Symbolic [SWord n] sWords = Trans.sWords -- | Declare a named 'SInt8' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt8' sInt8 :: String -> Symbolic SInt8 sInt8 = Trans.sInt8 -- | Declare an unnamed 'SInt8' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt8_' sInt8_ :: Symbolic SInt8 sInt8_ = Trans.sInt8_ -- | Declare a list of 'SInt8's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt8s' sInt8s :: [String] -> Symbolic [SInt8] sInt8s = Trans.sInt8s -- | Declare a named 'SInt16' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt16' sInt16 :: String -> Symbolic SInt16 sInt16 = Trans.sInt16 -- | Declare an unnamed 'SInt16' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt16_' sInt16_ :: Symbolic SInt16 sInt16_ = Trans.sInt16_ -- | Declare a list of 'SInt16's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt16s' sInt16s :: [String] -> Symbolic [SInt16] sInt16s = Trans.sInt16s -- | Declare a named 'SInt32' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt32' sInt32 :: String -> Symbolic SInt32 sInt32 = Trans.sInt32 -- | Declare an unnamed 'SInt32' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt32_' sInt32_ :: Symbolic SInt32 sInt32_ = Trans.sInt32_ -- | Declare a list of 'SInt32's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt32s' sInt32s :: [String] -> Symbolic [SInt32] sInt32s = Trans.sInt32s -- | Declare a named 'SInt64' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt64' sInt64 :: String -> Symbolic SInt64 sInt64 = Trans.sInt64 -- | Declare an unnamed 'SInt64' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt64_' sInt64_ :: Symbolic SInt64 sInt64_ = Trans.sInt64_ -- | Declare a list of 'SInt64's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt64s' sInt64s :: [String] -> Symbolic [SInt64] sInt64s = Trans.sInt64s -- | Declare a named 'SInt' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt' sInt :: (KnownNat n, IsNonZero n) => String -> Symbolic (SInt n) sInt = Trans.sInt -- | Declare an unnamed 'SInt' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInt_' sInt_ :: (KnownNat n, IsNonZero n) => Symbolic (SInt n) sInt_ = Trans.sInt_ -- | Declare a list of 'SInt's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInts' sInts :: (KnownNat n, IsNonZero n) => [String] -> Symbolic [SInt n] sInts = Trans.sInts -- | Declare a named 'SInteger' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInteger' sInteger :: String -> Symbolic SInteger sInteger = Trans.sInteger -- | Declare an unnamed 'SInteger' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sInteger_' sInteger_ :: Symbolic SInteger sInteger_ = Trans.sInteger_ -- | Declare a list of 'SInteger's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sIntegers' sIntegers :: [String] -> Symbolic [SInteger] sIntegers = Trans.sIntegers -- | Declare a named 'SReal' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sReal' sReal :: String -> Symbolic SReal sReal = Trans.sReal -- | Declare an unnamed 'SReal' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sReal_' sReal_ :: Symbolic SReal sReal_ = Trans.sReal_ -- | Declare a list of 'SReal's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sReals' sReals :: [String] -> Symbolic [SReal] sReals = Trans.sReals -- | Declare a named 'SFloat' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sFloat' sFloat :: String -> Symbolic SFloat sFloat = Trans.sFloat -- | Declare an unnamed 'SFloat' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sFloat_' sFloat_ :: Symbolic SFloat sFloat_ = Trans.sFloat_ -- | Declare a list of 'SFloat's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sFloats' sFloats :: [String] -> Symbolic [SFloat] sFloats = Trans.sFloats -- | Declare a named 'SDouble' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sDouble' sDouble :: String -> Symbolic SDouble sDouble = Trans.sDouble -- | Declare an unnamed 'SDouble' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sDouble_' sDouble_ :: Symbolic SDouble sDouble_ = Trans.sDouble_ -- | Declare a list of 'SDouble's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sDoubles' sDoubles :: [String] -> Symbolic [SDouble] sDoubles = Trans.sDoubles -- | Declare a named 'SChar' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sChar' sChar :: String -> Symbolic SChar sChar = Trans.sChar -- | Declare an unnamed 'SChar' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sChar_' sChar_ :: Symbolic SChar sChar_ = Trans.sChar_ -- | Declare a list of 'SChar's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sChars' sChars :: [String] -> Symbolic [SChar] sChars = Trans.sChars -- | Declare a named 'SString' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sString' sString :: String -> Symbolic SString sString = Trans.sString -- | Declare an unnamed 'SString' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sString_' sString_ :: Symbolic SString sString_ = Trans.sString_ -- | Declare a list of 'SString's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sStrings' sStrings :: [String] -> Symbolic [SString] sStrings = Trans.sStrings -- | Declare a named 'SList' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sList' sList :: SymVal a => String -> Symbolic (SList a) sList = Trans.sList -- | Declare an unnamed 'SList' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sList_' sList_ :: SymVal a => Symbolic (SList a) sList_ = Trans.sList_ -- | Declare a list of 'SList's -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sLists' sLists :: SymVal a => [String] -> Symbolic [SList a] sLists = Trans.sLists -- | Declare a named tuple. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sTuple' sTuple :: (SymTuple tup, SymVal tup) => String -> Symbolic (SBV tup) sTuple = Trans.sTuple -- | Declare an unnamed tuple. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sTuple_' sTuple_ :: (SymTuple tup, SymVal tup) => Symbolic (SBV tup) sTuple_ = Trans.sTuple_ -- | Declare a list of tuples. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sTuples' sTuples :: (SymTuple tup, SymVal tup) => [String] -> Symbolic [SBV tup] sTuples = Trans.sTuples -- | Declare a named 'Data.SBV.SEither'. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sEither' sEither :: (SymVal a, SymVal b) => String -> Symbolic (SEither a b) sEither = Trans.sEither -- | Declare an unnamed 'Data.SBV.SEither'. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sEither_' sEither_ :: (SymVal a, SymVal b) => Symbolic (SEither a b) sEither_ = Trans.sEither_ -- | Declare a list of 'Data.SBV.SEither' values. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sEithers' sEithers :: (SymVal a, SymVal b) => [String] -> Symbolic [SEither a b] sEithers = Trans.sEithers -- | Declare a named 'Data.SBV.SMaybe'. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sMaybe' sMaybe :: SymVal a => String -> Symbolic (SMaybe a) sMaybe = Trans.sMaybe -- | Declare an unnamed 'Data.SBV.SMaybe'. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sMaybe_' sMaybe_ :: SymVal a => Symbolic (SMaybe a) sMaybe_ = Trans.sMaybe_ -- | Declare a list of 'Data.SBV.SMaybe' values. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sMaybes' sMaybes :: SymVal a => [String] -> Symbolic [SMaybe a] sMaybes = Trans.sMaybes -- | Declare a named 'Data.SBV.SSet'. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sSet' sSet :: (Ord a, SymVal a) => String -> Symbolic (SSet a) sSet = Trans.sSet -- | Declare an unnamed 'Data.SBV.SSet'. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sSet_' sSet_ :: (Ord a, SymVal a) => Symbolic (SSet a) sSet_ = Trans.sSet_ -- | Declare a list of 'Data.SBV.SSet' values. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.sSets' sSets :: (Ord a, SymVal a) => [String] -> Symbolic [SSet a] sSets = Trans.sSets -- | Form the symbolic conjunction of a given list of boolean conditions. Useful in expressing -- problems with constraints, like the following: -- -- @ -- sat $ do [x, y, z] <- sIntegers [\"x\", \"y\", \"z\"] -- solve [x .> 5, y + z .< x] -- @ -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.solve' solve :: [SBool] -> Symbolic SBool solve = Trans.solve -- | Introduce a soft assertion, with an optional penalty -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.assertWithPenalty' assertWithPenalty :: String -> SBool -> Penalty -> Symbolic () assertWithPenalty = Trans.assertWithPenalty -- | Minimize a named metric -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.minimize' minimize :: Metric a => String -> SBV a -> Symbolic () minimize = Trans.minimize -- | Maximize a named metric -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.maximize' maximize :: Metric a => String -> SBV a -> Symbolic () maximize = Trans.maximize -- Data.SBV.Core.Symbolic: -- | Convert a symbolic value to an SV, inside the Symbolic monad -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.svToSymSV' svToSymSV :: SVal -> Symbolic SV svToSymSV = Trans.svToSymSV -- | Run a symbolic computation, and return a extra value paired up with the 'Result' -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.runSymbolic' runSymbolic :: SBVRunMode -> Symbolic a -> IO (a, Result) runSymbolic = Trans.runSymbolic -- | Add a new option -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.addNewSMTOption' addNewSMTOption :: SMTOption -> Symbolic () addNewSMTOption = Trans.addNewSMTOption -- | Handling constraints -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.imposeConstraint' imposeConstraint :: Bool -> [(String, String)] -> SVal -> Symbolic () imposeConstraint = Trans.imposeConstraint -- | Add an optimization goal -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.addSValOptGoal' addSValOptGoal :: Objective SVal -> Symbolic () addSValOptGoal = Trans.addSValOptGoal -- | Mark an interim result as an output. Useful when constructing Symbolic programs -- that return multiple values, or when the result is programmatically computed. -- -- NB. For a version which generalizes over the underlying monad, see 'Data.SBV.Trans.outputSVal' outputSVal :: SVal -> Symbolic () outputSVal = Trans.outputSVal -- | Capturing non-matching instances for better error messages, conversions from sized type FromSizedErr (arg :: Type) = 'Text "fromSized: Cannot convert from type: " ':<>: 'ShowType arg ':$$: 'Text " Source type must be one of SInt N, SWord N, IntN N, WordN N" ':$$: 'Text " where N is 8, 16, 32, or 64." -- | Capturing non-matching instances for better error messages, conversions to sized type ToSizedErr (arg :: Type) = 'Text "toSized: Cannot convert from type: " ':<>: 'ShowType arg ':$$: 'Text " Source type must be one of Int8/16/32/64" ':$$: 'Text " OR Word8/16/32/64" ':$$: 'Text " OR their symbolic variants." -- | Capture the correspondence between sized and fixed-sized BVs type family FromSized (t :: Type) :: Type where FromSized (WordN 8) = Word8 FromSized (WordN 16) = Word16 FromSized (WordN 32) = Word32 FromSized (WordN 64) = Word64 FromSized (IntN 8) = Int8 FromSized (IntN 16) = Int16 FromSized (IntN 32) = Int32 FromSized (IntN 64) = Int64 FromSized (SWord 8) = SWord8 FromSized (SWord 16) = SWord16 FromSized (SWord 32) = SWord32 FromSized (SWord 64) = SWord64 FromSized (SInt 8) = SInt8 FromSized (SInt 16) = SInt16 FromSized (SInt 32) = SInt32 FromSized (SInt 64) = SInt64 type family FromSizedCstr (t :: Type) :: Constraint where FromSizedCstr (WordN 8) = () FromSizedCstr (WordN 16) = () FromSizedCstr (WordN 32) = () FromSizedCstr (WordN 64) = () FromSizedCstr (IntN 8) = () FromSizedCstr (IntN 16) = () FromSizedCstr (IntN 32) = () FromSizedCstr (IntN 64) = () FromSizedCstr (SWord 8) = () FromSizedCstr (SWord 16) = () FromSizedCstr (SWord 32) = () FromSizedCstr (SWord 64) = () FromSizedCstr (SInt 8) = () FromSizedCstr (SInt 16) = () FromSizedCstr (SInt 32) = () FromSizedCstr (SInt 64) = () FromSizedCstr arg = TypeError (FromSizedErr arg) -- | Conversion from a sized BV to a fixed-sized bit-vector. class FromSizedBV a where -- | Convert a sized bit-vector to the corresponding fixed-sized bit-vector, -- for instance 'SWord 16' to 'SWord16'. See also 'toSized'. fromSized :: a -> FromSized a default fromSized :: (Num (FromSized a), Integral a) => a -> FromSized a fromSized = fromIntegral instance {-# OVERLAPPING #-} FromSizedBV (WordN 8) instance {-# OVERLAPPING #-} FromSizedBV (WordN 16) instance {-# OVERLAPPING #-} FromSizedBV (WordN 32) instance {-# OVERLAPPING #-} FromSizedBV (WordN 64) instance {-# OVERLAPPING #-} FromSizedBV (IntN 8) instance {-# OVERLAPPING #-} FromSizedBV (IntN 16) instance {-# OVERLAPPING #-} FromSizedBV (IntN 32) instance {-# OVERLAPPING #-} FromSizedBV (IntN 64) instance {-# OVERLAPPING #-} FromSizedBV (SWord 8) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SWord 16) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SWord 32) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SWord 64) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SInt 8) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SInt 16) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SInt 32) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} FromSizedBV (SInt 64) where fromSized = Trans.sFromIntegral instance {-# OVERLAPPABLE #-} FromSizedCstr arg => FromSizedBV arg where fromSized = error "unreachable" -- | Capture the correspondence between fixed-sized and sized BVs type family ToSized (t :: Type) :: Type where ToSized Word8 = WordN 8 ToSized Word16 = WordN 16 ToSized Word32 = WordN 32 ToSized Word64 = WordN 64 ToSized Int8 = IntN 8 ToSized Int16 = IntN 16 ToSized Int32 = IntN 32 ToSized Int64 = IntN 64 ToSized SWord8 = SWord 8 ToSized SWord16 = SWord 16 ToSized SWord32 = SWord 32 ToSized SWord64 = SWord 64 ToSized SInt8 = SInt 8 ToSized SInt16 = SInt 16 ToSized SInt32 = SInt 32 ToSized SInt64 = SInt 64 type family ToSizedCstr (t :: Type) :: Constraint where ToSizedCstr Word8 = () ToSizedCstr Word16 = () ToSizedCstr Word32 = () ToSizedCstr Word64 = () ToSizedCstr Int8 = () ToSizedCstr Int16 = () ToSizedCstr Int32 = () ToSizedCstr Int64 = () ToSizedCstr SWord8 = () ToSizedCstr SWord16 = () ToSizedCstr SWord32 = () ToSizedCstr SWord64 = () ToSizedCstr SInt8 = () ToSizedCstr SInt16 = () ToSizedCstr SInt32 = () ToSizedCstr SInt64 = () ToSizedCstr arg = TypeError (ToSizedErr arg) -- | Conversion from a fixed-sized BV to a sized bit-vector. class ToSizedBV a where -- | Convert a fixed-sized bit-vector to the corresponding sized bit-vector, -- for instance 'SWord16' to 'SWord 16'. See also 'fromSized'. toSized :: a -> ToSized a default toSized :: (Num (ToSized a), Integral a) => (a -> ToSized a) toSized = fromIntegral instance {-# OVERLAPPING #-} ToSizedBV Word8 instance {-# OVERLAPPING #-} ToSizedBV Word16 instance {-# OVERLAPPING #-} ToSizedBV Word32 instance {-# OVERLAPPING #-} ToSizedBV Word64 instance {-# OVERLAPPING #-} ToSizedBV Int8 instance {-# OVERLAPPING #-} ToSizedBV Int16 instance {-# OVERLAPPING #-} ToSizedBV Int32 instance {-# OVERLAPPING #-} ToSizedBV Int64 instance {-# OVERLAPPING #-} ToSizedBV SWord8 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SWord16 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SWord32 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SWord64 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SInt8 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SInt16 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SInt32 where toSized = Trans.sFromIntegral instance {-# OVERLAPPING #-} ToSizedBV SInt64 where toSized = Trans.sFromIntegral instance {-# OVERLAPPABLE #-} ToSizedCstr arg => ToSizedBV arg where toSized = error "unreachable"