toysolver-0.7.0: app/toysolver.hs
{-# LANGUAGE CPP #-}
{-# OPTIONS_GHC -Wall #-}
-----------------------------------------------------------------------------
-- |
-- Module : toysolver
-- Copyright : (c) Masahiro Sakai 2011-2019
-- License : BSD-style
--
-- Maintainer : masahiro.sakai@gmail.com
-- Stability : experimental
-- Portability : non-portable
--
-----------------------------------------------------------------------------
module Main where
import Control.Monad
import Control.Concurrent
import Data.Array.IArray
import Data.Char
import Data.Default.Class
import Data.List
import Data.Maybe
#if !MIN_VERSION_base(4,11,0)
import Data.Monoid
#endif
import Data.Scientific (Scientific)
import qualified Data.Scientific as Scientific
import Data.String
import qualified Data.Version as V
import qualified Data.Set as Set
import Data.Map (Map)
import qualified Data.Map as Map
import qualified Data.IntMap as IntMap
import qualified Data.IntSet as IntSet
import qualified Data.Traversable as T
import Options.Applicative hiding (Const)
import System.Exit
import System.IO
import Text.Printf
import GHC.Conc (getNumProcessors)
import qualified Numeric.Optimization.MIP as MIP
import qualified Numeric.Optimization.MIP.Solution.Gurobi as GurobiSol
import ToySolver.Data.OrdRel
import ToySolver.Data.FOL.Arith as FOL
import qualified ToySolver.Data.LA.FOL as LAFOL
import qualified ToySolver.Data.Polynomial as P
import qualified ToySolver.Data.AlgebraicNumber.Real as AReal
import qualified ToySolver.Arith.OmegaTest as OmegaTest
import qualified ToySolver.Arith.Cooper as Cooper
import qualified ToySolver.Arith.Simplex.Textbook.MIPSolver.Simple as TextbookMIP
import qualified ToySolver.Arith.Simplex as Simplex
import qualified ToySolver.Arith.MIP as MIPSolver
import qualified ToySolver.Arith.CAD as CAD
import qualified ToySolver.Arith.ContiTraverso as ContiTraverso
import qualified ToySolver.FileFormat as FF
import ToySolver.Converter
import ToySolver.SAT.Printer
import qualified ToySolver.SAT.Types as SAT
import ToySolver.Version
import ToySolver.Internal.Util
-- ---------------------------------------------------------------------------
data Mode = ModeSAT | ModePB | ModeWBO | ModeMaxSAT | ModeMIP
deriving (Eq, Ord, Show)
data Options = Options
{ optInput :: FilePath
, optMode :: Maybe Mode
, optSolver :: String
, optPrintRational :: Bool
, optWriteFile :: Maybe FilePath
, optNoMIP :: Bool
, optPivotStrategy :: Simplex.PivotStrategy -- String
, optBoundTightening :: Bool
, optNThread :: Int
, optOmegaReal :: String
, optFileEncoding :: Maybe String
} deriving (Eq, Show)
optionsParser :: Parser Options
optionsParser = Options
<$> fileInput
<*> modeOption
<*> solverOption
<*> printRationalOption
<*> writeFileOption
<*> noMIPOption
<*> pivotStrategyOption
<*> boundTighteningOption
<*> nThreadOption
<*> omegaRealOption
<*> fileEncodingOption
where
fileInput :: Parser FilePath
fileInput = argument str (metavar "FILE")
modeOption :: Parser (Maybe Mode)
modeOption = optional $
flag' ModeSAT (long "sat" <> help "solve boolean satisfiability problem in .cnf file")
<|> flag' ModePB (long "pb" <> help "solve pseudo boolean problem in .opb file")
<|> flag' ModeWBO (long "wbo" <> help "solve weighted boolean optimization problem in .wbo file")
<|> flag' ModeMaxSAT (long "maxsat" <> help "solve MaxSAT problem in .cnf or .wcnf file")
<|> flag' ModeMIP (long "lp" <> help "solve LP/MIP problem in .lp or .mps file")
solverOption :: Parser String
solverOption = strOption
$ long "solver"
<> metavar "SOLVER"
<> help "Solver algorithm: mip, omega-test, cooper, cad, old-mip, ct"
<> value "mip"
<> showDefaultWith id
printRationalOption :: Parser Bool
printRationalOption = switch
$ long "print-rational"
<> help "print rational numbers instead of decimals"
writeFileOption :: Parser (Maybe FilePath)
writeFileOption = optional $ strOption
$ short 'w'
<> metavar "FILE"
<> help "write solution to filename in Gurobi .sol format"
noMIPOption :: Parser Bool
noMIPOption = switch
$ long "nomip"
<> help "consider all integer variables as continuous"
pivotStrategyOption :: Parser Simplex.PivotStrategy
pivotStrategyOption = option (maybeReader Simplex.parsePivotStrategy)
$ long "pivot-strategy"
<> metavar "NAME"
<> help ("pivot strategy for simplex: " ++ intercalate ", " [Simplex.showPivotStrategy ps | ps <- [minBound..maxBound]])
<> value (Simplex.configPivotStrategy def)
<> showDefaultWith Simplex.showPivotStrategy
boundTighteningOption :: Parser Bool
boundTighteningOption = switch
$ long "bound-tightening"
<> help "enable bound tightening in simplex algorithm"
nThreadOption :: Parser Int
nThreadOption = option auto
$ long "threads"
<> metavar "INT"
<> help "number of threads to use (0: auto)"
<> value 0
<> showDefault
omegaRealOption :: Parser String
omegaRealOption = strOption
$ long "omega-real"
<> metavar "SOLVER"
<> help "fourier-motzkin, virtual-substitution (or vs), cad, simplex, none"
<> value "fourier-motzkin"
<> showDefaultWith id
fileEncodingOption :: Parser (Maybe String)
fileEncodingOption = optional $ strOption
$ long "encoding"
<> metavar "ENCODING"
<> help "file encoding for LP/MPS files"
parserInfo :: ParserInfo Options
parserInfo = info (helper <*> versionOption <*> optionsParser)
$ fullDesc
<> header "toysolver - a solver for arithmetic problems"
where
versionOption :: Parser (a -> a)
versionOption = infoOption (V.showVersion version)
$ hidden
<> long "version"
<> help "Show version"
-- ---------------------------------------------------------------------------
run
:: String
-> Options
-> MIP.Problem Rational
-> (Map MIP.Var Rational -> IO ())
-> IO ()
run solver opt prob printModel = do
unless (Set.null (MIP.semiContinuousVariables prob)) $ do
hPutStrLn stderr "semi-continuous variables are not supported."
exitFailure
case map toLower solver of
s | s `elem` ["omega", "omega-test", "cooper"] -> solveByQE
s | s `elem` ["old-mip"] -> solveByMIP
s | s `elem` ["cad"] -> solveByCAD
s | s `elem` ["ct", "conti-traverso"] -> solveByContiTraverso
_ -> solveByMIP2
where
vs = MIP.variables prob
vsAssoc = zip (Set.toList vs) [0..]
nameToVar = Map.fromList vsAssoc
varToName = IntMap.fromList [(v,name) | (name,v) <- vsAssoc]
compileE :: MIP.Expr Rational -> Expr Rational
compileE = foldr (+) (Const 0) . map compileT . MIP.terms
compileT :: MIP.Term Rational -> Expr Rational
compileT (MIP.Term c vs3) =
foldr (*) (Const c) [Var (nameToVar Map.! v) | v <- vs3]
obj = compileE $ MIP.objExpr $ MIP.objectiveFunction prob
cs1 = do
v <- Set.toList vs
let v2 = Var (nameToVar Map.! v)
let (l,u) = MIP.getBounds prob v
[Const x .<=. v2 | MIP.Finite x <- return l] ++
[v2 .<=. Const x | MIP.Finite x <- return u]
cs2 = do
MIP.Constraint
{ MIP.constrIndicator = ind
, MIP.constrExpr = e
, MIP.constrLB = lb
, MIP.constrUB = ub
} <- MIP.constraints prob
case ind of
Nothing -> do
let e2 = compileE e
msum
[ case lb of
MIP.NegInf -> []
MIP.PosInf -> [OrdRel 1 Le 0] -- False
MIP.Finite x -> [OrdRel e2 Ge (Const x)]
, case ub of
MIP.NegInf -> [OrdRel 1 Le 0] -- False
MIP.PosInf -> []
MIP.Finite x -> [OrdRel e2 Le (Const x)]
]
Just _ -> error "indicator constraint is not supported yet"
ivs
| optNoMIP opt = Set.empty
| otherwise = MIP.integerVariables prob
vs2 = IntMap.keysSet varToName
ivs2 = IntSet.fromList . map (nameToVar Map.!) . Set.toList $ ivs
solveByQE =
case mapM LAFOL.fromFOLAtom (cs1 ++ cs2) of
Nothing -> do
putSLine "UNKNOWN"
exitFailure
Just cs ->
case f vs2 cs ivs2 of
Nothing -> do
putSLine "UNSATISFIABLE"
exitFailure
Just m -> do
putOLine $ showValue (FOL.evalExpr m obj)
putSLine "SATISFIABLE"
let m2 = Map.fromAscList [(v, m IntMap.! (nameToVar Map.! v)) | v <- Set.toList vs]
printModel m2
where
f = case solver of
"omega" -> OmegaTest.solveQFLIRAConj omegaOpt
"omega-test" -> OmegaTest.solveQFLIRAConj omegaOpt
"cooper" -> Cooper.solveQFLIRAConj
_ -> error "unknown solver"
omegaOpt =
def
{ OmegaTest.optCheckReal = realSolver
}
where
realSolver =
case optOmegaReal opt of
"fourier-motzkin" -> OmegaTest.checkRealByFM
"virtual-substitution" -> OmegaTest.checkRealByVS
"vs" -> OmegaTest.checkRealByVS
"cad" -> OmegaTest.checkRealByCAD
"simplex" -> OmegaTest.checkRealBySimplex
"none" -> OmegaTest.checkRealNoCheck
s -> error ("unknown solver: " ++ s)
solveByMIP = do
let prob2 = do
cs' <- mapM LAFOL.fromFOLAtom (cs1 ++ cs2)
obj' <- LAFOL.fromFOLExpr obj
return (cs',obj')
case prob2 of
Nothing -> do
putSLine "UNKNOWN"
exitFailure
Just (cs',obj') ->
case TextbookMIP.optimize (MIP.objDir $ MIP.objectiveFunction prob) obj' cs' ivs2 of
TextbookMIP.OptUnsat -> do
putSLine "UNSATISFIABLE"
exitFailure
TextbookMIP.Unbounded -> do
putSLine "UNBOUNDED"
exitFailure
TextbookMIP.Optimum r m -> do
putOLine $ showValue r
putSLine "OPTIMUM FOUND"
let m2 = Map.fromAscList [(v, m IntMap.! (nameToVar Map.! v)) | v <- Set.toList vs]
printModel m2
solveByMIP2 = do
simplex <- Simplex.newSolver
let config =
def
{ Simplex.configPivotStrategy = optPivotStrategy opt
, Simplex.configEnableBoundTightening = optBoundTightening opt
}
nthreads = optNThread opt
Simplex.setConfig simplex config
Simplex.setLogger simplex putCommentLine
Simplex.enableTimeRecording simplex
replicateM_ (length vsAssoc) (Simplex.newVar simplex) -- XXX
Simplex.setOptDir simplex $ MIP.objDir $ MIP.objectiveFunction prob
Simplex.setObj simplex $ fromJust (LAFOL.fromFOLExpr obj)
putCommentLine "Loading constraints... "
forM_ (cs1 ++ cs2) $ \c ->
Simplex.assertAtom simplex $ fromJust (LAFOL.fromFOLAtom c)
putCommentLine "Loading constraints finished"
mip <- MIPSolver.newSolver simplex ivs2
MIPSolver.setShowRational mip printRat
MIPSolver.setLogger mip putCommentLine
MIPSolver.setOnUpdateBestSolution mip $ \_m val -> putOLine (showValue val)
procs <-
if nthreads >= 1
then return nthreads
else do
ncap <- getNumCapabilities
procs <- getNumProcessors
return $ max (procs - 1) ncap
setNumCapabilities procs
MIPSolver.setNThread mip procs
ret <- MIPSolver.optimize mip
case ret of
Simplex.Unsat -> do
putSLine "UNSATISFIABLE"
exitFailure
Simplex.Unbounded -> do
putSLine "UNBOUNDED"
Just m <- MIPSolver.getBestModel mip
let m2 = Map.fromAscList [(v, m IntMap.! (nameToVar Map.! v)) | v <- Set.toList vs]
printModel m2
exitFailure
Simplex.Optimum -> do
Just m <- MIPSolver.getBestModel mip
putSLine "OPTIMUM FOUND"
let m2 = Map.fromAscList [(v, m IntMap.! (nameToVar Map.! v)) | v <- Set.toList vs]
printModel m2
Simplex.ObjLimit -> do
error "should not happen"
solveByCAD
| not (IntSet.null ivs2) = do
putSLine "UNKNOWN"
putCommentLine "integer variables are not supported by CAD"
exitFailure
| otherwise = do
let cs = map (fmap f) $ cs1 ++ cs2
vs3 = Set.fromAscList $ IntSet.toAscList vs2
case CAD.solve vs3 cs of
Nothing -> do
putSLine "UNSATISFIABLE"
exitFailure
Just m -> do
let m2 = IntMap.map (\x -> AReal.approx x (2^^(-64::Int))) $
IntMap.fromAscList $ Map.toAscList $ m
putOLine $ showValue (FOL.evalExpr m2 obj)
putSLine "SATISFIABLE"
let m3 = Map.fromAscList [(v, m2 IntMap.! (nameToVar Map.! v)) | v <- Set.toList vs]
printModel m3
where
f (Const r) = P.constant r
f (Var v) = P.var v
f (e1 :+: e2) = f e1 + f e2
f (e1 :*: e2) = f e1 * f e2
f (e1 :/: e2)
| P.deg p > 0 = error "can't handle rational expression"
| otherwise = P.mapCoeff (/ c) $ f e1
where
p = f e2
c = P.coeff P.mone p
solveByContiTraverso
| not (vs `Set.isSubsetOf` ivs) = do
putSLine "UNKNOWN"
putCommentLine "continuous variables are not supported by Conti-Traverso algorithm"
exitFailure
| otherwise = do
let tmp = do
linObj <- LAFOL.fromFOLExpr obj
linCon <- mapM LAFOL.fromFOLAtom (cs1 ++ cs2)
return (linObj, linCon)
case tmp of
Nothing -> do
putSLine "UNKNOWN"
putCommentLine "non-linear expressions are not supported by Conti-Traverso algorithm"
exitFailure
Just (linObj, linCon) ->
case ContiTraverso.solve P.grlex vs2 (MIP.objDir $ MIP.objectiveFunction prob) linObj linCon of
Nothing -> do
putSLine "UNSATISFIABLE"
exitFailure
Just m -> do
let m2 = IntMap.map fromInteger m
putOLine $ showValue (FOL.evalExpr m2 obj)
putSLine "OPTIMUM FOUND"
let m3 = Map.fromAscList [(v, m2 IntMap.! (nameToVar Map.! v)) | v <- Set.toList vs]
printModel m3
printRat :: Bool
printRat = optPrintRational opt
showValue :: Rational -> String
showValue = showRational printRat
mipPrintModel :: Handle -> Bool -> Map MIP.Var Rational -> IO ()
mipPrintModel h asRat m =
forM_ (Map.toList m) $ \(v, val) ->
hPrintf h "v %s = %s\n" (MIP.fromVar v) (showRational asRat val)
putCommentLine :: String -> IO ()
putCommentLine s = do
putStr "c "
putStrLn s
hFlush stdout
putSLine :: String -> IO ()
putSLine s = do
putStr "s "
putStrLn s
hFlush stdout
putOLine :: String -> IO ()
putOLine s = do
putStr "o "
putStrLn s
hFlush stdout
-- ---------------------------------------------------------------------------
main :: IO ()
main = do
#ifdef FORCE_CHAR8
setEncodingChar8
#endif
o <- execParser parserInfo
case fromMaybe ModeMIP (optMode o) of
ModeSAT -> do
cnf <- FF.readFile (optInput o)
let (mip,info2) = sat2ip cnf
run (optSolver o) o (fmap fromInteger mip) $ \m -> do
let m2 = transformBackward info2 m
satPrintModel stdout m2 0
writeSOLFileSAT o m2
ModePB -> do
pb <- FF.readFile (optInput o)
let (mip,info2) = pb2ip pb
run (optSolver o) o (fmap fromInteger mip) $ \m -> do
let m2 = transformBackward info2 m
pbPrintModel stdout m2 0
writeSOLFileSAT o m2
ModeWBO -> do
wbo <- FF.readFile (optInput o)
let (mip,info2) = wbo2ip False wbo
run (optSolver o) o (fmap fromInteger mip) $ \m -> do
let m2 = transformBackward info2 m
pbPrintModel stdout m2 0
writeSOLFileSAT o m2
ModeMaxSAT -> do
wcnf <- FF.readFile (optInput o)
let (mip,info2) = maxsat2ip False wcnf
run (optSolver o) o (fmap fromInteger mip) $ \m -> do
let m2 = transformBackward info2 m
maxsatPrintModel stdout m2 0
writeSOLFileSAT o m2
ModeMIP -> do
enc <- T.mapM mkTextEncoding $ optFileEncoding o
mip <- MIP.readFile def{ MIP.optFileEncoding = enc } (optInput o)
run (optSolver o) o (fmap toRational mip) $ \m -> do
mipPrintModel stdout (optPrintRational o) m
writeSOLFileMIP o m
-- FIXME: 目的関数値を表示するように
writeSOLFileMIP :: Options -> Map MIP.Var Rational -> IO ()
writeSOLFileMIP opt m = do
let sol = MIP.Solution
{ MIP.solStatus = MIP.StatusUnknown
, MIP.solObjectiveValue = Nothing
, MIP.solVariables = Map.fromList [(v, Scientific.fromFloatDigits (fromRational val :: Double)) | (v,val) <- Map.toList m]
}
writeSOLFileRaw opt sol
-- FIXME: 目的関数値を表示するように
writeSOLFileSAT :: Options -> SAT.Model -> IO ()
writeSOLFileSAT opt m = do
let sol = MIP.Solution
{ MIP.solStatus = MIP.StatusUnknown
, MIP.solObjectiveValue = Nothing
, MIP.solVariables = Map.fromList [(fromString ("x" ++ show x), if b then 1 else 0) | (x,b) <- assocs m]
}
writeSOLFileRaw opt sol
writeSOLFileRaw :: Options -> MIP.Solution Scientific -> IO ()
writeSOLFileRaw opt sol =
case optWriteFile opt of
Just fname -> GurobiSol.writeFile fname sol
Nothing -> return ()