/usr/share/pyshared/swap/pycwmko.py is in python-swap 1.2.1-5.
This file is owned by root:root, with mode 0o644.
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"""
from pychinko import terms, interpreter
#from pychinko import N3Loader
from pychinko.helpers import removedups, convertBNodeToFact
from swap import term, formula
from swap.set_importer import Set
import time
#from rdflib import BNode, Store
# from rdflib.constants import TYPE, FIRST, REST, LIST, NIL, OWLNS
LOG_IMPLIES = 'http://www.w3.org/2000/10/swap/log#'
try:
reversed
except NameError:
def reversed(l):
ll = [a for a in l]
b = len(l)
while b > 0:
b -= 1
yield ll[b]
from pychinko import nodes, rete
class fullSet(object):
def __contains__(self, other):
return True
from sys import stderr
class directPychinkoQuery(object):
def __init__(self, workingContext, rulesFormula=None, target=None):
self.extra = []
self.store = workingContext.store
self.workingContext = workingContext
if rulesFormula is None:
rulesFormula = workingContext
if target is None:
target = workingContext
t = time.time()
self.rules = self.buildRules(rulesFormula)
self.interp = interpreter.Interpreter(self.rules)
#print "rules"
#print self.rules
self.facts = self.buildFacts(rulesFormula)
print "converting and adding time:", time.time() - t
t = time.time()
# self.interp.addFacts(Set(self.facts), initialSet=True)
#print self.rules
#print "add facts time:", time.time() - t
t = time.time()
self.interp.run()
print "interp.run() time:", time.time() - t
print len(self.interp.inferredFacts), ' inferred fact(s)'
#print "size of inferred facts:", len(self.interp.inferredFacts)
# print self.interp.inferredFacts
# add the inferred facts back to cwm store
t = time.time()
for i in self.interp.inferredFacts:
# convertFromPystore();
# if isinstance(i.o, str):
# print type(i.o)
# elif isinstance(i.o, unicode):
# print('unicode')
# convert them to term.Symbols
# cannot convert to term.Symbol if it's a literal
# print i.s, i.p, i.o
# print self.convFromRete(i.s), self.convFromRete(i.p), self.convFromRete(i.o)
newTriple = self.convFromRete(i.s), self.convFromRete(i.p), self.convFromRete(i.o)
self.workingContext.add(*newTriple)
# if not self.workingContext.contains(newTriple):
# self.workingContext.add(*newTriple)
# else:
# print "contains!"
print "add facts time to cwm:", time.time() - t
"""
print "facts"
print self.facts
self.workingContext = workingContext
self.target = target
if workingContext is target:
self.loop = True
else:
self.loop = False"""
def convFromRete(self, t):
if not t:
return None
# print "cnv:", t, type(t)
if isinstance(t,unicode):
return self.workingContext.newSymbol(t)
elif isinstance(t,str):
return self.workingContext.newLiteral(t)
return term.Symbol(t, self.store)
def convType(self, t, F, K=None):
# print "type:",t, type(t)
"""print "t:", t
print type(t)
print "f unis:", F.universals()
if (K): print "k exis:", K.existentials()"""
if isinstance(t, term.NonEmptyList):
#convert the name of the list to an exivar and return it
#self.convertListToRDF(t, listId, self.extra)
#return terms.Exivar('_:' + str(t))
return '_:' + str(t)
#raise RuntimeError
if t in F.universals():
return terms.Variable(t)
if K is not None and t in K.existentials():
# print "returning existential:", t
return terms.Exivar(t)
if isinstance(t, term.Symbol):
return terms.URIRef(t.uri)
if isinstance(t, term.BuiltIn):
return t.uriref()
if isinstance(t, term.Fragment):
# print "uriref:",terms.URIRef(t.uriref())
# print type(t.uriref())
return terms.URIRef(t.uriref())
# print type(t)
# print "returning URI",t
return str(t)
"""def processBetaNode(self, betaNode):
retVal = False
inferences = betaNode.join()
self.joinedBetaNodes.add(betaNode)
if inferences:
if betaNode.rule:
#self.rulesThatFired.add(betaNode.rule)
#######this test will be moved into `matchingFacts'
for rhsPattern in betaNode.rule.rhs:
results = betaNode.matchingFacts(rhsPattern, inferences)
### @@@ here we need to add to the workingcontext
for triple in results:
addedResult = self.workingContext.add(*triple.t)
if addedResult:
retVal = True
self.newStatements.add(
self.workingContext.statementsMatching(
subj=triple.s, pred=triple.p, obj=triple.o)[0])
# retVal = retVal or addedResult
else:
for child in betaNode.children:
#process children of BetaNode..
betaNodeProcessed = self.processBetaNode(child)
retVal = retVal or betaNodeProcessed
return retVal"""
def _listsWithinLists(self, L, lists):
if L not in lists:
lists.append(L)
for i in L:
if isinstance(i, term.NonEmptyList):
self._listsWithinLists(i, lists)
def dumpLists(self, context):
"Dump lists out as first and rest. Not used in pretty."
listList = {}
result = []
#context = self.workingContext
#sink = self.sink
lists = []
for s in context.statements:
#print "s:", s
for x in s.predicate(), s.subject(), s.object():
if isinstance(x, term.NonEmptyList):
self._listsWithinLists(x, lists)
for l in lists:
list = l
while not isinstance(list, term.EmptyList):
if list not in listList:
#print list, " rdf:type rdf:list"
#self._outputStatement(sink, (context, self.store.forSome, context, list))
listList[list] = 1
list = list.rest
listList = {}
for l in lists:
list = l
while (not isinstance(list, term.EmptyList)) and list not in listList:
result.append(terms.Pattern(terms.Exivar("_:" + str(list)), "http://www.w3.org/1999/02/22-rdf-syntax-ns#first", self.convType(list.first, self.workingContext, context)))
if isinstance(list.rest, term.EmptyList):
#print "_:", list, " rdf:rest rdf:nil"
result.append(terms.Pattern(terms.Exivar("_:" + str(list)), "http://www.w3.org/1999/02/22-rdf-syntax-ns#rest", "http://www.w3.org/1999/02/22-rdf-syntax-ns#nil"))
else:
result.append(terms.Pattern(terms.Exivar("_:" + str(list)), "http://www.w3.org/1999/02/22-rdf-syntax-ns#rest", self.convType(list.rest, self.workingContext, context)))
#print list, " rdf:rest ", list.rest
#self._outputStatement(sink, (context, self.store.first, list, list.first))
#self._outputStatement(sink, (context, self.store.rest, list, list.rest))
listList[list] = 1
list = list.rest
return result
def buildRules(self, indexedFormula):
rules = []
for rule in indexedFormula.statementsMatching(pred=indexedFormula.store.implies):
subj, predi, obj = rule.spo()
if not isinstance(subj, formula.Formula) or \
not isinstance(obj, formula.Formula):
continue
head = []
tail = []
for fr, to in (subj, tail), (obj, head):
self.extra = self.dumpLists(fr) #use extra for the list-related triples
for quad in fr:
#if not isinstance(quad.subject(), term.NonEmptyList):
s, p, o = [self.convType(x, indexedFormula, fr)
for x in quad.spo()] #to get variables.
#Not good enough for Lists
# print "spo:", s,p,o
for f in (self.extra + [(s,p,o)]):
to.append(terms.Pattern(*f))
rules.append(terms.Rule(tail, head, (subj, predi, obj) ))
return rules
def buildFacts(self, indexedFormula):
facts = []
for f in self.dumpLists(indexedFormula):
facts.append(terms.Fact(convertBNodeToFact(f.s),f.p, convertBNodeToFact(f.o)))
# for alphaNode in self.interp.rete.alphaNodeStore:
# print alphaNode
# i = alphaNode.pattern.noneBasedPattern()
# pattern = self.convFromRete(i[0]), self.convFromRete(i[1]), self.convFromRete(i[2])
# print "pattern:", pattern
# for quad in indexedFormula.statementsMatching(
# subj=pattern[0],
# pred=pattern[1],
# obj =pattern[2]):
## print "quad:", quad
# if isinstance(subj, formula.Formula) or isinstance(obj, formula.Formula):
# print "The RETE engine cannot process nested formulas currently"
# continue
#
# s, p, o = [self.convType(x, indexedFormula, None) for x in quad.spo()]
#
# alphaNode.add(terms.Fact(s,p,o))
for fact in indexedFormula.statements:
subj, predi, obj = fact.spo()
# ignore formulas for now
if isinstance(subj, formula.Formula) or \
isinstance(obj, formula.Formula):
print "The RETE cannot process nested formulas at the time - use it for ntriples only"
# raise NotImplementedError
continue
# only get top level facts
head = []
tail = []
s, p, o = [self.convType(x, indexedFormula, None)
for x in fact.spo()] #to get variables.
#Not good enough for Lists, but they're taken care of earlier
facts.append(terms.Fact(s, p, o))
self.interp.addFacts(Set(facts), initialSet=True)
return facts
def add(self, triple):
t = triple.t
status = False
if self.workingContext.add(*t):
alphaMatches = self.rete.alphaIndex.match(f)
for anode in alphaMatches:
if anode.add(f):
status = True
return Status
"""
def __call__(self):
#convert it to a set of facts (simply take all triples in a formula and add them as facts)
#as first cut
rules = self.rules
indexedFormula = self.workingContext
self.newStatements = fullSet()
self.rete = rete.RuleCompiler().compile(rules)
newStuff = True
first = True
while newStuff and (first or self.loop):
#print >> stderr, "starting loop"
first = False
newStuff = False
needToRun = False
for alphaNode in self.rete.alphaNodeStore:
pattern = alphaNode.pattern.noneBasedPattern()
for quad in indexedFormula.statementsMatching(
subj=pattern[0],
pred=pattern[1],
obj =pattern[2]):
self.extra = []
if quad in self.newStatements:
s, p, o = [self.convType(x, indexedFormula)
for x in quad.spo()]
for f in (self.extra + [(s,p,o)]):
if alphaNode.add(terms.Fact(*f)):
needToRun = True
self.newStatements = Set()
self.joinedBetaNodes = Set()
if needToRun:
for alphaNode in self.rete.alphaNodeStore:
for betaNode in alphaNode.betaNodes:
if betaNode in self.joinedBetaNodes:
continue
newNewStuff = self.processBetaNode(betaNode)
newStuff = newStuff or newNewStuff
print self.newStatements
# self.rete.printNetwork()
class ToPyStore(object):
def __init__(self, pyStore):
self.pyStore = pyStore
self.lists = {}
self.typeConvertors = [
(formula.Formula , self.formula),
(formula.StoredStatement, self.triple),
(term.LabelledNode, self.URI),
(term.Fragment, self.URI),
(term.AnonymousNode, self.BNode),
(term.Literal, self.literal),
(term.List, self.list),
(term.N3Set, self.set)]
def lookup(self, node):
for theType, function in self.typeConvertors:
if isinstance(node, theType):
return function(node)
raise RuntimeError(`node` + ' ' + `node.__class__`)
def formula(self, node):
subFormulaRef = self.pyStore.create_clause()
subFormula = self.pyStore.get_clause(subFormulaRef)
subConvertor = self.__class__(subFormula)
subConvertor.statements(node)
return subFormulaRef
def URI(self, node):
return terms.URI(node.uriref())
def BNode(self, node):
return BNode.BNode(node.uriref())
def literal(self, node):
string = node.string
dt = node.datatype
if not dt:
dt = ''
lang = node.lang
if not lang:
lang = ''
return terms.Literal(string, lang, dt)
def list(self, node):
if node in self.lists:
return self.lists[node]
newList = [].__class__
next = NIL
for item in reversed(newList(node)):
bNode = BNode.BNode()
self.pyStore.add((bNode, REST, next))
self.pyStore.add((bNode, FIRST, self.lookup(item)))
next = bNode
self.lists[node] = next
return next
def set(self, node):
bNode = BNode.BNode()
l = self.list(node)
self.pyStore.add((bNode, OWLNS['oneOf'], l))
return bNode
def statements(self, formula):
for var in formula.universals():
self.pyStore.add_universal(self.lookup(var))
for var in formula.existentials():
if not isinstance(var, term.AnonymousNode):
self.pyStore.add_existential(self.lookup(var))
for statement in formula:
self.triple(statement)
def triple(self, statement):
try:
self.pyStore.add([self.lookup(item) for item in statement.spo()])
except:
raise
class FromPyStore(object):
def __init__(self, formula, pyStore, parent=None):
self.parent = parent
self.formula = formula
self.store = formula.store
self.pyStore = pyStore
self.bNodes = {}
self.typeConvertors = [
(Store.Store, self.subStore),
(terms.Exivar, self.existential),
(terms.Variable, self.variable),
(terms.URIRef, self.URI),
(BNode.BNode, self.BNode),
(terms.Literal, self.literal)]
self.stores = [
(N3Loader.ClauseLoader, self.patterns),
(N3Loader.N3Loader, self.facts_and_rules),
(Store.Store, self.triples)]
def lookup(self, node):
for theType, function in self.typeConvertors:
if isinstance(node, theType):
return function(node)
raise RuntimeError(`node` + ' ' + `node.__class__`)
def run(self):
node = self.pyStore
for theType, function in self.stores:
if isinstance(node, theType):
return function(node)
raise RuntimeError(`node` + ' ' + `node.__class__`)
def URI(self, node):
return self.formula.newSymbol(node)
def variable(self, node):
if self.pyStore.get_clause(node.name) is not None:
return self.subStore(self.pyStore.get_clause(node.name))
v = self.URI(node.name)
self.parent.declareUniversal(v)
return v
def existential(self, node):
if self.pyStore.get_clause(node.name) is not None:
return self.subStore(self.pyStore.get_clause(node.name))
v = self.URI(node.name)
self.formula.declareExistential(v)
return v
def BNode(self, node):
if self.pyStore.get_clause(node) is not None:
return self.subStore(self.pyStore.get_clause(node))
bNodes = self.bNodes
if node not in bNodes:
bNodes[node] = self.formula.newBlankNode(node)
return bNodes[node]
def literal(self, node):
return self.formula.newLiteral(node, node.datatype or None, node.language or None)
def subStore(self, node):
f = self.formula.newFormula()
self.__class__(f, node, self.formula).run()
return f.close()
def facts_and_rules(self, pyStore):
patternMap = {}
for nodeID in pyStore.list_clauses():
patternMap[tuple(removedups(pyStore.get_clause(nodeID).patterns))] = pyStore.get_clause(nodeID)
for fact in pyStore.facts:
self.formula.add(
self.lookup(fact.s),
self.lookup(fact.p),
self.lookup(fact.o))
for rule in pyStore.rules:
self.formula.add(
self.subStore(patternMap[tuple(removedups(rule.lhs))]),
self.store.implies,
self.subStore(patternMap[tuple(removedups(rule.rhs))]))
def patterns(self, pyStore):
patternMap = {}
for nodeID in pyStore.list_clauses():
patternMap[tuple(removedups(pyStore.get_clause(nodeID).patterns))] = pyStore.get_clause(nodeID)
for pattern in pyStore.patterns:
if isinstance(pattern.s, terms.Rule):
rule = pattern.s
self.formula.add(
self.subStore(patternMap[tuple(removedups(rule.lhs))]),
self.store.implies,
self.subStore(patternMap[tuple(removedups(rule.rhs))]))
else:
self.formula.add(
self.lookup(pattern.s),
self.lookup(pattern.p),
self.lookup(pattern.o))
def triples(self, pyStore):
pass
if __name__ == '__main__':
import sys
#sys.path.append('/home/syosi')
from swap import llyn
#from pychinko.N3Loader import N3Loader
store = llyn.RDFStore()
from swap import webAccess
f = webAccess.load(store, sys.argv[1])
pyf = N3Loader.N3Loader()
conv = ToPyStore(pyf)
conv.statements(f)
print "facts = " + ',\n'.join([repr(a) for a in pyf.facts])
print "rules = " + ',\n'.join([repr(a) for a in pyf.rules])
print '----'
g = store.newFormula()
reConv = FromPyStore(g, pyf)
reConv.run()
print g.close().n3String()
"""
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