#include #include #include "ParfactorList.h" ParfactorList::ParfactorList (const ParfactorList& pfList) { ParfactorList::const_iterator it = pfList.begin(); while (it != pfList.end()) { addShattered (new Parfactor (**it)); ++ it; } } ParfactorList::ParfactorList (const Parfactors& pfs) { add (pfs); } ParfactorList::~ParfactorList (void) { ParfactorList::const_iterator it = pfList_.begin(); while (it != pfList_.end()) { delete *it; ++ it; } } void ParfactorList::add (Parfactor* pf) { pf->setNewGroups(); addToShatteredList (pf); } void ParfactorList::add (const Parfactors& pfs) { for (size_t i = 0; i < pfs.size(); i++) { pfs[i]->setNewGroups(); addToShatteredList (pfs[i]); } } void ParfactorList::addShattered (Parfactor* pf) { assert (isAllShattered()); pfList_.push_back (pf); assert (isAllShattered()); } std::list::iterator ParfactorList::insertShattered ( std::list::iterator it, Parfactor* pf) { return pfList_.insert (it, pf); assert (isAllShattered()); } std::list::iterator ParfactorList::remove (std::list::iterator it) { return pfList_.erase (it); } std::list::iterator ParfactorList::removeAndDelete (std::list::iterator it) { delete *it; return pfList_.erase (it); } bool ParfactorList::isAllShattered (void) const { if (pfList_.size() <= 1) { return true; } Parfactors pfs (pfList_.begin(), pfList_.end()); for (size_t i = 0; i < pfs.size(); i++) { assert (isShattered (pfs[i])); } for (size_t i = 0; i < pfs.size() - 1; i++) { for (size_t j = i + 1; j < pfs.size(); j++) { if (isShattered (pfs[i], pfs[j]) == false) { return false; } } } return true; } void ParfactorList::print (void) const { Parfactors pfVec (pfList_.begin(), pfList_.end()); std::sort (pfVec.begin(), pfVec.end(), sortByParams()); for (size_t i = 0; i < pfVec.size(); i++) { pfVec[i]->print(); std::cout << std::endl; } } ParfactorList& ParfactorList::operator= (const ParfactorList& pfList) { if (this != &pfList) { ParfactorList::const_iterator it0 = pfList_.begin(); while (it0 != pfList_.end()) { delete *it0; ++ it0; } pfList_.clear(); ParfactorList::const_iterator it = pfList.begin(); while (it != pfList.end()) { addShattered (new Parfactor (**it)); ++ it; } } return *this; } bool ParfactorList::isShattered (const Parfactor* g) const { const ProbFormulas& formulas = g->arguments(); if (formulas.size() < 2) { return true; } ConstraintTree ct (*g->constr()); for (size_t i = 0; i < formulas.size() - 1; i++) { for (size_t j = i + 1; j < formulas.size(); j++) { if (formulas[i].group() == formulas[j].group()) { if (identical ( formulas[i], *(g->constr()), formulas[j], *(g->constr())) == false) { g->print(); std::cout << "-> not identical on positions " ; std::cout << i << " and " << j << std::endl; return false; } } else { if (disjoint ( formulas[i], *(g->constr()), formulas[j], *(g->constr())) == false) { g->print(); std::cout << "-> not disjoint on positions " ; std::cout << i << " and " << j << std::endl; return false; } } } } return true; } bool ParfactorList::isShattered ( const Parfactor* g1, const Parfactor* g2) const { assert (g1 != g2); const ProbFormulas& fms1 = g1->arguments(); const ProbFormulas& fms2 = g2->arguments(); for (size_t i = 0; i < fms1.size(); i++) { for (size_t j = 0; j < fms2.size(); j++) { if (fms1[i].group() == fms2[j].group()) { if (identical ( fms1[i], *(g1->constr()), fms2[j], *(g2->constr())) == false) { g1->print(); std::cout << "^" << std::endl; g2->print(); std::cout << "-> not identical on group " ; std::cout << fms1[i].group() << std::endl; return false; } } else { if (disjoint ( fms1[i], *(g1->constr()), fms2[j], *(g2->constr())) == false) { g1->print(); std::cout << "^" << std::endl; g2->print(); std::cout << "-> not disjoint on groups " << fms1[i].group(); std::cout << " and " << fms2[j].group() << std::endl; return false; } } } } return true; } void ParfactorList::addToShatteredList (Parfactor* g) { std::queue residuals; residuals.push (g); while (residuals.empty() == false) { Parfactor* pf = residuals.front(); bool pfSplitted = false; std::list::iterator pfIter; pfIter = pfList_.begin(); while (pfIter != pfList_.end()) { std::pair shattRes; shattRes = shatter (*pfIter, pf); if (shattRes.first.empty() == false) { pfIter = removeAndDelete (pfIter); Util::addToQueue (residuals, shattRes.first); } else { ++ pfIter; } if (shattRes.second.empty() == false) { delete pf; Util::addToQueue (residuals, shattRes.second); pfSplitted = true; break; } } residuals.pop(); if (pfSplitted == false) { Parfactors res = shatterAgainstMySelf (pf); if (res.empty()) { addShattered (pf); } else { Util::addToQueue (residuals, res); } } } assert (isAllShattered()); } Parfactors ParfactorList::shatterAgainstMySelf (Parfactor* g) { Parfactors pfs; std::queue residuals; residuals.push (g); bool shattered = true; while (residuals.empty() == false) { Parfactor* pf = residuals.front(); Parfactors res = shatterAgainstMySelf2 (pf); if (res.empty()) { assert (isShattered (pf)); if (shattered) { return { }; } pfs.push_back (pf); } else { shattered = false; for (size_t i = 0; i < res.size(); i++) { assert (res[i]->constr()->empty() == false); residuals.push (res[i]); } delete pf; } residuals.pop(); } return pfs; } Parfactors ParfactorList::shatterAgainstMySelf2 (Parfactor* g) { // slip a parfactor with overlapping formulas: // e.g. {s(X),s(Y)}, with (X,Y) in {(p1,p2),(p1,p3),(p4,p1)} const ProbFormulas& formulas = g->arguments(); for (size_t i = 0; i < formulas.size() - 1; i++) { for (size_t j = i + 1; j < formulas.size(); j++) { if (formulas[i].sameSkeletonAs (formulas[j])) { Parfactors res = shatterAgainstMySelf (g, i, j); if (res.empty() == false) { return res; } } } } return Parfactors(); } Parfactors ParfactorList::shatterAgainstMySelf ( Parfactor* g, size_t fIdx1, size_t fIdx2) { /* Util::printDashedLine(); std::cout << "-> SHATTERING" << std::endl; g->print(); std::cout << "-> ON: " << g->argument (fIdx1) << "|" ; std::cout << g->constr()->tupleSet (g->argument (fIdx1).logVars()); std::cout << std::endl; std::cout << "-> ON: " << g->argument (fIdx2) << "|" ; std::cout << g->constr()->tupleSet (g->argument (fIdx2).logVars()) std::cout << std::endl; Util::printDashedLine(); */ ProbFormula& f1 = g->argument (fIdx1); ProbFormula& f2 = g->argument (fIdx2); if (f1.isAtom()) { std::cerr << "Error: a ground occurs twice in the same parfactor." ; std::cerr << std::endl; std::cerr << std::endl; exit (EXIT_FAILURE); } assert (g->constr()->empty() == false); ConstraintTree ctCopy (*g->constr()); if (f1.group() == f2.group()) { assert (identical (f1, *(g->constr()), f2, ctCopy)); return { }; } g->constr()->moveToTop (f1.logVars()); ctCopy.moveToTop (f2.logVars()); std::pair split1 = g->constr()->split (f1.logVars(), &ctCopy, f2.logVars()); ConstraintTree* commCt1 = split1.first; ConstraintTree* exclCt1 = split1.second; if (commCt1->empty()) { // disjoint delete commCt1; delete exclCt1; return { }; } PrvGroup newGroup = ProbFormula::getNewGroup(); Parfactors res1 = shatter (g, fIdx1, commCt1, exclCt1, newGroup); if (res1.empty()) { res1.push_back (g); } Parfactors res; ctCopy.moveToTop (f1.logVars()); for (size_t i = 0; i < res1.size(); i++) { res1[i]->constr()->moveToTop (f2.logVars()); std::pair split2; split2 = res1[i]->constr()->split (f2.logVars(), &ctCopy, f1.logVars()); ConstraintTree* commCt2 = split2.first; ConstraintTree* exclCt2 = split2.second; if (commCt2->empty()) { if (res1[i] != g) { res.push_back (res1[i]); } delete commCt2; delete exclCt2; continue; } newGroup = ProbFormula::getNewGroup(); Parfactors res2 = shatter (res1[i], fIdx2, commCt2, exclCt2, newGroup); if (res2.empty()) { if (res1[i] != g) { res.push_back (res1[i]); } } else { Util::addToVector (res, res2); for (size_t j = 0; j < res2.size(); j++) { } if (res1[i] != g) { delete res1[i]; } } } if (res.empty()) { g->argument (fIdx2).setGroup (g->argument (fIdx1).group()); updateGroups (f2.group(), f1.group()); } return res; } std::pair ParfactorList::shatter (Parfactor* g1, Parfactor* g2) { ProbFormulas& formulas1 = g1->arguments(); ProbFormulas& formulas2 = g2->arguments(); assert (g1 && g2 && g1 != g2); for (size_t i = 0; i < formulas1.size(); i++) { for (size_t j = 0; j < formulas2.size(); j++) { if (formulas1[i].sameSkeletonAs (formulas2[j])) { std::pair res; res = shatter (i, g1, j, g2); if (res.first.empty() == false || res.second.empty() == false) { return res; } } } } return make_pair (Parfactors(), Parfactors()); } std::pair ParfactorList::shatter ( size_t fIdx1, Parfactor* g1, size_t fIdx2, Parfactor* g2) { ProbFormula& f1 = g1->argument (fIdx1); ProbFormula& f2 = g2->argument (fIdx2); /* Util::printDashedLine(); std::cout << "-> SHATTERING" << std::endl; g1->print(); std::cout << "-> WITH" << std::endl; g2->print(); std::cout << "-> ON: " << f1 << "|" ; std::cout << g1->constr()->tupleSet (f1.logVars()) << std::endl; std::cout << "-> ON: " << f2 << "|" ; std::cout << g2->constr()->tupleSet (f2.logVars()) << std::endl; Util::printDashedLine(); */ if (f1.isAtom()) { f2.setGroup (f1.group()); updateGroups (f2.group(), f1.group()); return { }; } assert (g1->constr()->empty() == false); assert (g2->constr()->empty() == false); if (f1.group() == f2.group()) { assert (identical (f1, *(g1->constr()), f2, *(g2->constr()))); return { }; } g1->constr()->moveToTop (f1.logVars()); g2->constr()->moveToTop (f2.logVars()); std::pair split1 = g1->constr()->split (f1.logVars(), g2->constr(), f2.logVars()); ConstraintTree* commCt1 = split1.first; ConstraintTree* exclCt1 = split1.second; if (commCt1->empty()) { // disjoint delete commCt1; delete exclCt1; return { }; } std::pair split2 = g2->constr()->split (f2.logVars(), g1->constr(), f1.logVars()); ConstraintTree* commCt2 = split2.first; ConstraintTree* exclCt2 = split2.second; assert (commCt1->tupleSet (f1.logVars()) == commCt2->tupleSet (f2.logVars())); // std::stringstream ss1; ss1 << "" << count << "_A.dot" ; // std::stringstream ss2; ss2 << "" << count << "_B.dot" ; // std::stringstream ss3; ss3 << "" << count << "_A_comm.dot" ; // std::stringstream ss4; ss4 << "" << count << "_A_excl.dot" ; // std::stringstream ss5; ss5 << "" << count << "_B_comm.dot" ; // std::stringstream ss6; ss6 << "" << count << "_B_excl.dot" ; // g1->constr()->exportToGraphViz (ss1.str().c_str(), true); // g2->constr()->exportToGraphViz (ss2.str().c_str(), true); // commCt1->exportToGraphViz (ss3.str().c_str(), true); // exclCt1->exportToGraphViz (ss4.str().c_str(), true); // commCt2->exportToGraphViz (ss5.str().c_str(), true); // exclCt2->exportToGraphViz (ss6.str().c_str(), true); if (exclCt1->empty() && exclCt2->empty()) { // identical f2.setGroup (f1.group()); updateGroups (f2.group(), f1.group()); delete commCt1; delete exclCt1; delete commCt2; delete exclCt2; return { }; } PrvGroup group; if (exclCt1->empty()) { group = f1.group(); } else if (exclCt2->empty()) { group = f2.group(); } else { group = ProbFormula::getNewGroup(); } Parfactors res1 = shatter (g1, fIdx1, commCt1, exclCt1, group); Parfactors res2 = shatter (g2, fIdx2, commCt2, exclCt2, group); return make_pair (res1, res2); } Parfactors ParfactorList::shatter ( Parfactor* g, size_t fIdx, ConstraintTree* commCt, ConstraintTree* exclCt, PrvGroup commGroup) { ProbFormula& f = g->argument (fIdx); if (exclCt->empty()) { delete commCt; delete exclCt; f.setGroup (commGroup); return { }; } Parfactors result; if (f.isCounting()) { LogVar X_new1 = g->constr()->logVarSet().back() + 1; LogVar X_new2 = g->constr()->logVarSet().back() + 2; ConstraintTrees cts = g->constr()->jointCountNormalize ( commCt, exclCt, f.countedLogVar(), X_new1, X_new2); for (size_t i = 0; i < cts.size(); i++) { Parfactor* newPf = new Parfactor (g, cts[i]); if (cts[i]->nrLogVars() == g->constr()->nrLogVars() + 1) { newPf->expand (f.countedLogVar(), X_new1, X_new2); assert (g->constr()->getConditionalCount (f.countedLogVar()) == cts[i]->getConditionalCount (X_new1) + cts[i]->getConditionalCount (X_new2)); } else { assert (g->constr()->getConditionalCount (f.countedLogVar()) == cts[i]->getConditionalCount (f.countedLogVar())); } newPf->setNewGroups(); result.push_back (newPf); } delete commCt; delete exclCt; } else { Parfactor* newPf = new Parfactor (g, commCt); newPf->setNewGroups(); newPf->argument (fIdx).setGroup (commGroup); result.push_back (newPf); newPf = new Parfactor (g, exclCt); newPf->setNewGroups(); result.push_back (newPf); } return result; } void ParfactorList::updateGroups (PrvGroup oldGroup, PrvGroup newGroup) { for (ParfactorList::iterator it = pfList_.begin(); it != pfList_.end(); ++it) { ProbFormulas& formulas = (*it)->arguments(); for (size_t i = 0; i < formulas.size(); i++) { if (formulas[i].group() == oldGroup) { formulas[i].setGroup (newGroup); } } } } bool ParfactorList::proper ( const ProbFormula& f1, ConstraintTree ct1, const ProbFormula& f2, ConstraintTree ct2) const { return disjoint (f1, ct1, f2, ct2) || identical (f1, ct1, f2, ct2); } bool ParfactorList::identical ( const ProbFormula& f1, ConstraintTree ct1, const ProbFormula& f2, ConstraintTree ct2) const { if (f1.sameSkeletonAs (f2) == false) { return false; } if (f1.isAtom()) { return true; } TupleSet ts1 = ct1.tupleSet (f1.logVars()); TupleSet ts2 = ct2.tupleSet (f2.logVars()); return ts1 == ts2; } bool ParfactorList::disjoint ( const ProbFormula& f1, ConstraintTree ct1, const ProbFormula& f2, ConstraintTree ct2) const { if (f1.sameSkeletonAs (f2) == false) { return true; } if (f1.isAtom()) { return false; } TupleSet ts1 = ct1.tupleSet (f1.logVars()); TupleSet ts2 = ct2.tupleSet (f2.logVars()); return (ts1 & ts2).empty(); }