OWLAnalysis.hs revision 7688e20f844fe88f75c04016841ebb5e5e3d927f
{- |
Module : $Header$
Copyright : Heng Jiang, Uni Bremen 2004-2007
License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt
Maintainer : jiang@informatik.uni-bremen.de
Stability : provisional
Portability : non-portable (imports Logic.Logic)
analyse OWL11 files by calling the external Java parser.
-}
module OWL.OWLAnalysis where
import OWL.AS
import OWL.Namespace
import OWL.Logic_OWL11
import OWL.ReadWrite()
import OWL.StaticAnalysis
import OWL.Sign
import OWL.StructureAnalysis
import Static.GTheory
import Static.DevGraph
import Common.Id
import Common.GlobalAnnotations
import Common.ExtSign
import Common.Result
import Common.Utils
import Common.AS_Annotation hiding (isAxiom,isDef)
import Common.ATerm.ReadWrite
import Common.ATerm.Unshared
import Syntax.AS_Library
import Driver.Options
import Logic.Logic
import Logic.Grothendieck
import Logic.Prover
import System.IO
import System.Time
import System.Cmd(system)
import System.Exit
import System.Environment(getEnv)
import System.Posix.Process
import qualified Data.Map as Map
import qualified Data.List as List
import Data.Graph.Inductive.Graph
import Data.Maybe(fromJust)
-- import Debug.Trace
-- | call for owl parser (env. variable $HETS_OWL_PARSER muss be defined)
parseOWL :: FilePath -- ^ local filepath or uri
-> IO OntologyMap -- ^ map: uri -> OntologyFile
parseOWL filename =
do
pwd <- getEnv "PWD"
if null filename
then
error "empty file name!"
else do
pid <- getProcessID
currTime <- getClockTime
calend <- toCalendarTime currTime
let tmpFile = "/tmp/" ++ (basename filename) ++ "-"
++ (show pid) ++ "-" ++ (buildTime calend)
++ ".term"
-- "/home/jiang/tmp/output.aterm"
if checkUri filename
then
do exitCode <-
system ("$HETS_OWL_PARSER/owl_parser "
++ filename ++
" " ++ tmpFile)
run exitCode tmpFile
else if (head filename) == '/'
then
do
exitCode <-
system ("$HETS_OWL_PARSER/owl_parser file://"
++ filename ++ " " ++ tmpFile)
run exitCode tmpFile
else do
exitCode <-
system("$HETS_OWL_PARSER/owl_parser file://"
++ pwd ++ "/" ++ filename ++
" " ++ tmpFile)
run exitCode tmpFile
where buildTime cTime =
(show $ ctYear cTime) ++ (show $ ctMonth cTime) ++
(show $ ctDay cTime) ++ (show $ ctHour cTime) ++
(show $ ctMin cTime) ++ (show $ ctSec cTime)
run :: ExitCode -> FilePath -> IO OntologyMap
run exitCode tmpFile
| exitCode == ExitSuccess =
do
putStrLn tmpFile
t <- parseProc tmpFile
-- system ("rm -f " ++ tmpFile)
return t
| otherwise = error ("process stop! " ++ (show exitCode))
-- | parse the tmp-ATerm-file from java-owl-parser
parseProc :: FilePath -> IO OntologyMap
parseProc filename =
do d <- readFile filename
let aterm = getATermFull $ readATerm d
case aterm of
AList paarList _ ->
return $ Map.fromList $ parsingAll paarList
_ -> error ("false file: " ++ show filename ++ ".")
-- | parse an ontology with all imported ontologies
parsingAll :: [ATerm] -> [(String, OntologyFile)]
parsingAll [] = []
parsingAll (aterm:res) =
(aTerm2Ontology aterm):(parsingAll res)
-- | translates ATerm to ontologyFile.
aTerm2Ontology :: ATerm -> (String, OntologyFile)
aTerm2Ontology (AAppl "UOPaar" [AAppl ouri _ _, ontoFile] _) =
(if head ouri == '"' then read ouri::String else ouri,
propagateNspaces (namespaces parsedOntologFile) parsedOntologFile)
where parsedOntologFile = fromATerm ontoFile:: OntologyFile
aTerm2Ontology _ = error "false ontology file."
-- | structure analysis bases of ontologyMap from owl parser
structureAna :: FilePath
-> HetcatsOpts
-> OntologyMap
-> IO (Maybe (LIB_NAME, -- filename
LibEnv -- DGraphs for imported modules
))
structureAna file opt ontoMap =
do
let (newOntoMap, dg) = buildDevGraph ontoMap
case (analysis opt) of
Structured -> do -- only structure analysis
printMsg $ labNodesDG dg
putStrLn $ show $ dgBody dg
return (Just (simpleLibName file,
simpleLibEnv file $ reverseGraph dg))
Skip -> return $ fail "" -- Nothing is ambiguous
_ -> staticAna file opt (newOntoMap, dg)
where -- output Analyzing messages for structured anaylsis
printMsg :: [LNode DGNodeLab] -> IO()
printMsg [] = putStrLn ""
printMsg ((_, node):rest) =
do putStrLn ("Analyzing ontology - printMsg " ++
(showName $ dgn_name node))
printMsg rest
-- simpleLibEnv and simpleLibName builded two simple lib-entities for
-- showGraph
simpleLibEnv :: FilePath -> DGraph -> LibEnv
simpleLibEnv filename dg =
Map.singleton (simpleLibName filename) dg
{ globalEnv = Map.singleton (mkSimpleId "")
(SpecEntry (ExtGenSig (JustNode nodeSig) [] g_sign nodeSig))}
where nodeSig = NodeSig 0 g_sign
g_sign = G_sign OWL11 (mkExtSign emptySign) 0
simpleLibName :: FilePath -> LIB_NAME
simpleLibName s = Lib_id $ Direct_link ("library_" ++ s) nullRange
-- | static analysis if the HetcatesOpts is not only Structured.
-- | sequence call for nodesStaticAna on the basis of topologically
-- | sort of all nodes
staticAna :: FilePath
-> HetcatsOpts
-> (OntologyMap, DGraph)
-> IO (Maybe (LIB_NAME, -- filename
LibEnv -- DGraphs for imported modules
))
staticAna file opt (ontoMap, dg) =
do let topNodes = topsortDG dg
-- putStrLn $ show ontoMap
Result diagnoses res <-
nodesStaticAna (reverse topNodes) Map.empty ontoMap Map.empty dg []
case res of
Just (_, dg', _) -> do
showDiags opt $ List.nub diagnoses
let dg'' = insEdgesDG (reverseLinks $ labEdgesDG dg')
(delEdgesDG (edgesDG dg') dg')
-- putStrLn $ show dg''
return (Just (simpleLibName file,
simpleLibEnv file dg''))
_ -> error "no devGraph..."
-- | a map to save which node has been analysed.
type SignMap = Map.Map Node (Sign, [Named Sentence])
-- | call to static analyse of all nodes
nodesStaticAna :: [Node] -- ^ topologically sort of graph
-> SignMap -- ^ an map of analyzed nodes
-> OntologyMap -- ^ an map of parsed ontology
-> Namespace -- ^ global namespaces
-> DGraph -- ^ current graph
-> [Diagnosis] -- ^ diagnosis of result
-> IO (Result (SignMap, DGraph, Namespace))
-- ^ result is tuple of new map of signs and sentences,
-- ^ new grpah, and new global namespace map.
nodesStaticAna [] signMap _ ns dg diag =
return $ Result diag (Just (signMap, dg, ns))
nodesStaticAna (h:r) signMap ontoMap globalNs dg diag = do
Result digs res <-
-- Each node must be analyzed with the associated imported nodes.
-- Those search for imported nodes is by bfs accomplished.
nodeStaticAna (reverse $ map (matchNode dg) (bfsDG h dg))
(emptySign, diag)
signMap ontoMap globalNs dg
case res of
Just (newSignMap, newDg, newGlobalNs) ->
nodesStaticAna r newSignMap ontoMap newGlobalNs newDg (diag++digs)
Prelude.Nothing ->
-- Warning or Error message
nodesStaticAna r signMap ontoMap globalNs dg (diag++digs)
-- | call to static analyse of single nodes
nodeStaticAna :: [LNode DGNodeLab] -- ^ imported nodes of one node
-- ^ (incl. itself)
-> (Sign, [Diagnosis]) -- ^ here saved incoming sign, diagnoses
-> SignMap -- ^ an map of analyzed nodes
-> OntologyMap -- ^ an map of parsed ontology
-> Namespace -- ^ global namespaces
-> DGraph -- ^ current graph
-> IO (Result (SignMap, DGraph, Namespace))
nodeStaticAna [] _ _ _ _ _ =
do return initResult -- remove warning
-- the last node in list is current top node.
nodeStaticAna
((n,topNode):[]) (inSig, oldDiags) signMap ontoMap globalNs dg =
do
let nn = dgn_name topNode
nodeName = getName nn
putStrLn ("Analyzing ontology " ++ (show nodeName))
case Map.lookup n signMap of
Just _ ->
return $ Result oldDiags (Just (signMap, dg, globalNs))
_ ->
do
-- putStrLn $ show $ ontoMap
let ontoF@(OntologyFile _ (Ontology mid _ _ _)) = fromJust $
Map.lookup (getNameFromNode nn) ontoMap
Result diag res =
-- static analysis of current ontology with all sign of
-- imported ontology.
basicOWL11Analysis (ontoF, inSig, emptyGlobalAnnos)
case res of
Just (_, ExtSign accSig _, sent) ->
do
let (newGlobalNs, tMap) =
integrateNamespaces globalNs (namespaceMap accSig)
newSent = map (renameNamespace tMap) sent
difSig = diffSig accSig inSig
newDifSig = renameNamespace tMap difSig
newSig = mkExtSign $ renameNamespace tMap accSig
-- the new node (with sign and sentence) has the sign of
-- accumulated sign with imported signs, but the sentences
-- is only of current ontology, because all sentences of
-- imported ontoloies can be automatically outputed by
-- showTheory (see GUI)
newLNode =
(n, topNode {dgn_theory =
G_theory OWL11 newSig 0 (toThSens newSent)
0})
-- by remove of an node all associated edges are also deleted
-- so the deges must be saved before remove the node, then
-- appended again.
-- The out edges (after reverse are inn edges) must
-- also with new signature be changed.
ledges = innDG dg n ++
map (changeGMorOfEdges newSig) (outDG dg n)
newG = insEdgesDG ledges (insNodeDG newLNode
(delNodeDG n dg))
return $ Result (oldDiags ++ diag)
(Just ((Map.insert n (newDifSig, newSent) signMap),
newG, newGlobalNs))
_ -> do let actDiag = mkDiag Error
("error by analysing of "
++ (show mid)) ()
putStrLn (show diag)
return $ Result (actDiag:oldDiags) Prelude.Nothing
-- The GMorphism of edge should also with new Signature be changed,
-- since with "show theory" the edges also with Sign one links
-- (see Static.DevGraph.joinG_sentences).
where changeGMorOfEdges newSign (n1, n2, edge) =
let newCMor = idComorphism (Logic OWL11)
Result _ newGMor = gEmbedComorphism newCMor
(G_sign OWL11 newSign 0)
in (n1, n2, edge {dgl_morphism = fromJust newGMor})
-- The other nodes in list are examined whether they were already analyzed.
-- if yes then signs of it for further analysis are taken out; otherwise they
-- are first analyzed (with complete part tree of this node).
nodeStaticAna ((n, _):r) (inSig, oldDiags) signMap ontoMap globalNs dg
=
do
case Map.lookup n signMap of
Just (sig, _) ->
nodeStaticAna r ((integSign sig inSig), oldDiags)
signMap ontoMap globalNs dg
Prelude.Nothing ->
do
Result digs' res' <-
nodeStaticAna (reverse $ map (matchNode dg) (bfsDG n dg))
(emptySign, [])
signMap ontoMap globalNs dg
case res' of
Just (signMap', dg', globalNs') ->
do
let (sig', _) = fromJust $ Map.lookup n signMap'
nodeStaticAna r
((integSign sig' inSig), (oldDiags ++ digs'))
signMap' ontoMap globalNs' dg'
_ -> do error "Error by analysis : nodeStaticAna"
nodeStaticAna r (inSig, oldDiags)
signMap ontoMap globalNs dg
-- | build up two sign
integSign :: Sign -> Sign -> Sign
integSign inSig totalSig =
let (newNamespace, transMap) =
integrateNamespaces (namespaceMap totalSig) (namespaceMap inSig)
in addSign (renameNamespace transMap inSig)
(totalSig {namespaceMap = newNamespace})
-- | turn edges over
reverseLinks :: [LEdge DGLinkLab] -> [LEdge DGLinkLab]
reverseLinks [] = []
reverseLinks ((source, target, edge):r) =
(target, source, edge):(reverseLinks r)
-- | turn all edges over of graph
reverseGraph :: DGraph -> DGraph
reverseGraph dg =
let newLinks = reverseLinks $ labEdgesDG dg
in insEdgesDG newLinks (delEdgesDG (edgesDG dg) dg)
-- | find a node in DevGraph
matchNode :: DGraph -> Node -> LNode DGNodeLab
matchNode dgraph node =
let (mcontext, _ ) = matchDG node dgraph
(_, _, dgNode, _) = fromJust mcontext
in (node, dgNode)