Prove.hs revision a6a88d8b0ca3144864bf00f12df3c1347fafda54
{- |
Module : $Header$
Description : Provers for propositional logic
Copyright : (c) Dominik Luecke, Uni Bremen 2007
License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt
Maintainer : luecke@informatik.uni-bremen.de
Stability : experimental
Portability : portable
This is the connection of the SAT-Solver minisat to Hets
-}
module Propositional.Prove
(
zchaffProver, -- the zChaff II Prover
propConsChecker
)
where
import qualified Propositional.AS_BASIC_Propositional as AS_BASIC
import qualified Propositional.Conversions as Cons
import qualified Propositional.Conversions as PC
import qualified Propositional.Morphism as PMorphism
import qualified Propositional.ProverState as PState
import qualified Propositional.Sign as Sig
import Propositional.Sublogic(PropSL,top)
import Propositional.ChildMessage
import Proofs.BatchProcessing
import qualified Logic.Prover as LP
import qualified GUI.GenericATPState as ATPState
import GUI.GenericATP
import GUI.HTkUtils
import HTk
import ChildProcess as CP
import Common.Utils (readMaybe)
import qualified Common.AS_Annotation as AS_Anno
import qualified Common.Id as Id
import qualified Common.OrderedMap as OMap
import qualified Common.Result as Result
import qualified Control.Concurrent as Concurrent
import qualified Control.Exception as Exception
import Data.Char
import Data.List
import Data.Maybe
import Data.Time (TimeOfDay,timeToTimeOfDay)
import System.Directory
import System.Cmd
import System.Exit
import System.IO
import Text.Regex
import PGIP.ProveUtils
-- * Prover implementation
zchaffHelpText :: String
zchaffHelpText = "Zchaff is a very fast SAT-Solver \n"++
"No additional Options are available"++
"for it!"
-- | the name of the inconsistent lemma for consistency checks
zchaffS :: String
zchaffS = "zchaff"
{- |
The Prover implementation.
Implemented are: a prover GUI, and both commandline prover interfaces.
-}
zchaffProver :: LP.Prover Sig.Sign AS_BASIC.FORMULA PropSL Sig.ATP_ProofTree
zchaffProver = (LP.mkProverTemplate zchaffS top zchaffProveGUI)
{ LP.proveCMDLautomatic = Just $ zchaffProveCMDLautomatic
, LP.proveCMDLautomaticBatch = Just $ zchaffProveCMDLautomaticBatch }
{- |
The Consistency Cheker.
-}
propConsChecker :: LP.ConsChecker Sig.Sign AS_BASIC.FORMULA PropSL
PMorphism.Morphism Sig.ATP_ProofTree
propConsChecker = LP.mkProverTemplate zchaffS top consCheck
consCheck :: String -> LP.TheoryMorphism Sig.Sign AS_BASIC.FORMULA
PMorphism.Morphism Sig.ATP_ProofTree
-> IO([LP.Proof_status Sig.ATP_ProofTree])
consCheck thName tm =
case LP.t_target tm of
LP.Theory sig nSens -> do
let axioms = getAxioms $ snd $ unzip $ OMap.toList nSens
tmpFile = "/tmp/" ++ (thName ++ "_cc.dimacs")
resultFile = tmpFile ++ ".result"
dimacsOutput <- PC.ioDIMACSProblem (thName ++ "_cc")
sig ( [(AS_Anno.makeNamed "myAxioms" $
AS_BASIC.Implication
(
AS_BASIC.Conjunction
(map (AS_Anno.sentence) axioms)
Id.nullRange
)
(AS_BASIC.False_atom Id.nullRange)
Id.nullRange
)
{
AS_Anno.isAxiom = True
, AS_Anno.isDef = False
, AS_Anno.wasTheorem = False
}
]
)[]
outputHf <- openFile tmpFile ReadWriteMode
hPutStr outputHf dimacsOutput
hClose outputHf
exitCode <- system ("zchaff " ++ tmpFile ++ " >> " ++ resultFile)
removeFile tmpFile
if exitCode /= ExitSuccess then
createInfoWindow "consistency checker"
("error by call zchaff " ++ thName)
else do
resultHf <- openFile resultFile ReadMode
isSAT <- searchResult resultHf
hClose resultHf
removeFile resultFile
if isSAT then
createInfoWindow "consistency checker"
("consistent.")
else
createInfoWindow "consistency checker"
("inconsistent.")
return []
where
getAxioms :: [LP.SenStatus AS_BASIC.FORMULA (LP.Proof_status Sig.ATP_ProofTree)]
-> [AS_Anno.Named AS_BASIC.FORMULA]
getAxioms f = map (AS_Anno.makeNamed "consistency" . AS_Anno.sentence) $ filter AS_Anno.isAxiom f
searchResult :: Handle -> IO Bool
searchResult hf = do
eof <- hIsEOF hf
if eof then
return False
else
do
line <- hGetLine hf
putStrLn line
if line == "RESULT:\tUNSAT" then
return True
else if line == "RESULT:\tSAT" then
return False
else searchResult hf
-- ** GUI
{- |
Invokes the generic prover GUI.
-}
zchaffProveGUI :: String -- ^ theory name
-> LP.Theory Sig.Sign AS_BASIC.FORMULA Sig.ATP_ProofTree
-> IO([LP.Proof_status Sig.ATP_ProofTree]) -- ^ proof status for each goal
zchaffProveGUI thName th =
genericATPgui (atpFun thName) True (LP.prover_name zchaffProver) thName th
$ Sig.ATP_ProofTree ""
{- |
Parses a given default tactic script into a
'GUI.GenericATPState.ATPTactic_script' if possible.
-}
parseZchaffTactic_script :: LP.Tactic_script
-> ATPState.ATPTactic_script
parseZchaffTactic_script =
parseTactic_script batchTimeLimit
{- |
Parses a given default tactic script into a
'GUI.GenericATPState.ATPTactic_script' if possible. Otherwise a default
prover's tactic script is returned.
-}
parseTactic_script :: Int -- ^ default time limit (standard:
-- 'Proofs.BatchProcessing.batchTimeLimit')
-> LP.Tactic_script
-> ATPState.ATPTactic_script
parseTactic_script tLimit (LP.Tactic_script ts) =
cParseScript tLimit [] (LP.Tactic_script ts)
-- maybe (ATPState.ATPTactic_script { ATPState.ts_timeLimit = tLimit,
-- ATPState.ts_extraOpts = [] })
-- id $ readMaybe ts
-- ** command line functions
{- |
Implementation of 'Logic.Prover.proveCMDLautomatic' which provides an
automatic command line interface for a single goal.
SPASS specific functions are omitted by data type ATPFunctions.
-}
zchaffProveCMDLautomatic ::
String -- ^ theory name
-> LP.Tactic_script -- ^ default tactic script
-> LP.Theory Sig.Sign AS_BASIC.FORMULA Sig.ATP_ProofTree -- ^ theory consisting of a
-- signature and a list of Named sentence
-> IO (Result.Result ([LP.Proof_status Sig.ATP_ProofTree]))
-- ^ Proof status for goals and lemmas
zchaffProveCMDLautomatic thName defTS th =
genericCMDLautomatic (atpFun thName) (LP.prover_name zchaffProver) thName
(parseZchaffTactic_script defTS) th (Sig.ATP_ProofTree "")
{- |
Implementation of 'Logic.Prover.proveCMDLautomaticBatch' which provides an
automatic command line interface to the zchaff prover.
zchaff specific functions are omitted by data type ATPFunctions.
-}
zchaffProveCMDLautomaticBatch ::
Bool -- ^ True means include proved theorems
-> Bool -- ^ True means save problem file
-> Concurrent.MVar (Result.Result [LP.Proof_status Sig.ATP_ProofTree])
-- ^ used to store the result of the batch run
-> String -- ^ theory name
-> LP.Tactic_script -- ^ default tactic script
-> LP.Theory Sig.Sign AS_BASIC.FORMULA Sig.ATP_ProofTree -- ^ theory consisting of a
-- 'SPASS.Sign.Sign' and a list of Named 'SPASS.Sign.Sentence'
-> IO (Concurrent.ThreadId,Concurrent.MVar ())
-- ^ fst: identifier of the batch thread for killing it
-- snd: MVar to wait for the end of the thread
zchaffProveCMDLautomaticBatch inclProvedThs saveProblem_batch resultMVar
thName defTS th =
genericCMDLautomaticBatch (atpFun thName) inclProvedThs saveProblem_batch
resultMVar (LP.prover_name zchaffProver) thName
(parseZchaffTactic_script defTS) th (Sig.ATP_ProofTree "")
{- |
Record for prover specific functions. This is used by both GUI and command
line interface.
-}
atpFun :: String -- Theory name
-> ATPState.ATPFunctions Sig.Sign AS_BASIC.FORMULA Sig.ATP_ProofTree PState.PropProverState
atpFun thName = ATPState.ATPFunctions
{
ATPState.initialProverState = PState.propProverState
, ATPState.goalOutput = Cons.goalDIMACSProblem thName
, ATPState.atpTransSenName = PState.transSenName
, ATPState.atpInsertSentence = PState.insertSentence
, ATPState.proverHelpText = zchaffHelpText
, ATPState.runProver = runZchaff
, ATPState.batchTimeEnv = "HETS_ZCHAFF_BATCH_TIME_LIMIT"
, ATPState.fileExtensions = ATPState.FileExtensions{ATPState.problemOutput = ".dimacs",
ATPState.proverOutput = ".zchaff",
ATPState.theoryConfiguration = ".czchaff"}
, ATPState.createProverOptions = createZchaffOptions
}
{- |
Runs zchaff. zchaff is assumed to reside in PATH.
-}
runZchaff :: PState.PropProverState
-- logical part containing the input Sign and
-- axioms and possibly goals that have been proved
-- earlier as additional axioms
-> ATPState.GenericConfig Sig.ATP_ProofTree
-- configuration to use
-> Bool
-- True means save DIMACS file
-> String
-- Name of the theory
-> AS_Anno.Named AS_BASIC.FORMULA
-- Goal to prove
-> IO (ATPState.ATPRetval
, ATPState.GenericConfig Sig.ATP_ProofTree
)
-- (retval, configuration with proof status and complete output)
runZchaff pState cfg saveDIMACS thName nGoal =
do
prob <- Cons.goalDIMACSProblem thName pState nGoal []
when saveDIMACS
(writeFile (thName++'_':AS_Anno.senAttr nGoal++".dimacs")
prob)
(writeFile (zFileName)
prob)
zchaff <- newChildProcess "zchaff" [CP.arguments allOptions]
Exception.catch (runZchaffReal zchaff)
(\ excep -> do
-- kill zchaff process
destroy zchaff
_ <- waitForChildProcess zchaff
deleteJunk
excepToATPResult (LP.prover_name zchaffProver) nGoal excep)
where
deleteJunk = do
catch (removeFile zFileName) (const $ return ())
catch (removeFile "resolve_trace") (const $ return ())
zFileName = "/tmp/problem_"++thName++'_':AS_Anno.senAttr nGoal++".dimacs"
allOptions = zFileName : (createZchaffOptions cfg)
runZchaffReal zchaff =
do
zchaffOut <- parseIt zchaff isEnd
(res, usedAxs, output, tUsed) <- analyzeZchaff zchaffOut pState
let (err, retval) = proof_stat res usedAxs [] (head output)
deleteJunk
return (err,
cfg{ATPState.proof_status = retval,
ATPState.resultOutput = output,
ATPState.timeUsed = tUsed})
where
proof_stat res usedAxs options out
| isJust res && elem (fromJust res) proved =
(ATPState.ATPSuccess,
(defaultProof_status options)
{LP.goalStatus = LP.Proved $ Nothing
, LP.usedAxioms = filter (/=(AS_Anno.senAttr nGoal)) usedAxs
, LP.proofTree = Sig.ATP_ProofTree $ out })
| isJust res && elem (fromJust res) disproved =
(ATPState.ATPSuccess,
(defaultProof_status options) {LP.goalStatus = LP.Disproved} )
| isJust res && elem (fromJust res) timelimit =
(ATPState.ATPTLimitExceeded, defaultProof_status options)
| isNothing res =
(ATPState.ATPError "Internal error.", defaultProof_status options)
| otherwise = (ATPState.ATPSuccess, defaultProof_status options)
defaultProof_status opts =
(LP.openProof_status (AS_Anno.senAttr nGoal) (LP.prover_name zchaffProver) $
Sig.ATP_ProofTree "")
{LP.tacticScript = LP.Tactic_script $ show $ ATPState.ATPTactic_script
{ATPState.ts_timeLimit = configTimeLimit cfg,
ATPState.ts_extraOpts = opts} }
proved :: [String]
proved = ["Proof found."]
disproved :: [String]
disproved = ["Completion found."]
timelimit :: [String]
timelimit = ["Ran out of time."]
-- | analysis of output
analyzeZchaff :: String
-> PState.PropProverState
-> IO (Maybe String, [String], [String], TimeOfDay)
analyzeZchaff str pState =
let
str' = foldr (\ch li -> if ch == '\x9'
then ""++li
else ch:li) "" str
str2 = foldr (\ch li -> if ch == '\x9'
then " "++li
else ch:li) "" str
output = [str2]
unsat = (\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_UNSAT str'
sat = (\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_SAT str'
timeLine = (\xv ->
case xv of
Just yv -> head yv
Nothing -> "0"
) $ matchRegex re_TIME str'
timeout = ((\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_end_to str')
||
((\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_end_mo str')
time = calculateTime timeLine
usedAx = map (AS_Anno.senAttr) $ PState.initialAxioms pState
in
if timeout
then
return (Just $ head timelimit, usedAx, output, time)
else
if (sat && (not unsat))
then
return (Just $ head $ disproved, usedAx, output, time)
else if ((not sat) && unsat)
then
return (Just $ head $ proved, usedAx, output, time)
else
do
return (Nothing, usedAx, output, time)
-- | Calculated the time need for the proof in seconds
calculateTime :: String -> TimeOfDay
calculateTime timeLine =
timeToTimeOfDay $ realToFrac $ (maybe
(error $ "calculateTime " ++ timeLine) id $ readMaybe timeLine
:: Double)
re_UNSAT :: Regex
re_UNSAT = mkRegex "(.*)RESULT:UNSAT(.*)"
re_SAT :: Regex
re_SAT = mkRegex "(.*)RESULT:SAT(.*)"
re_TIME :: Regex
re_TIME = mkRegex "Total Run Time(.*)"
-- | We are searching for Flotter needed to determine the end of input
isEnd :: String -> Bool
isEnd inS = ((\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_end inS)
||
((\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_end_to inS)
||
((\xv ->
case xv of
Just _ -> True
Nothing -> False
) $ matchRegex re_end_mo inS)
re_end :: Regex
re_end = mkRegex "(.*)RESULT:(.*)"
re_end_to :: Regex
re_end_to = mkRegex "(.*)TIME OUT(.*)"
re_end_mo :: Regex
re_end_mo = mkRegex "(.*)MEM OUT(.*)"
-- | Converts a thrown exception into an ATP result (ATPRetval and proof tree).
excepToATPResult :: String
-- ^ name of running prover
-> AS_Anno.Named AS_BASIC.FORMULA
-- ^ goal to prove
-> Exception.Exception
-- ^ occured exception
-> IO (ATPState.ATPRetval,
ATPState.GenericConfig Sig.ATP_ProofTree)
-- ^ (retval,
-- configuration with proof status and complete output)
excepToATPResult prName nGoal excep = return $ case excep of
-- this is supposed to distinguish "fd ... vanished"
-- errors from other exceptions
Exception.IOException e ->
(ATPState.ATPError ("Internal error communicating with " ++
prName ++ ".\n"
++ show e), emptyCfg)
Exception.AsyncException Exception.ThreadKilled ->
(ATPState.ATPBatchStopped, emptyCfg)
_ -> (ATPState.ATPError ("Error running " ++ prName ++ ".\n"
++ show excep),
emptyCfg)
where
emptyCfg = ATPState.emptyConfig prName (AS_Anno.senAttr nGoal) $
Sig.ATP_ProofTree ""
{- |
Returns the time limit from GenericConfig if available. Otherwise
guiDefaultTimeLimit is returned.
-}
configTimeLimit :: ATPState.GenericConfig Sig.ATP_ProofTree
-> Int
configTimeLimit cfg =
maybe (guiDefaultTimeLimit) id $ ATPState.timeLimit cfg
{- |
Creates a list of all options the zChaff prover runs with.
Only Option is the timelimit
-}
createZchaffOptions :: ATPState.GenericConfig Sig.ATP_ProofTree -> [String]
createZchaffOptions cfg =
[(show $ configTimeLimit cfg)]