428 lines
9.9 KiB
C++
428 lines
9.9 KiB
C++
#include <cassert>
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#include "ParfactorList.h"
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ParfactorList::ParfactorList (const ParfactorList& pfList)
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{
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ParfactorList::const_iterator it = pfList.begin();
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while (it != pfList.end()) {
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addShattered (new Parfactor (**it));
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++ it;
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}
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}
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ParfactorList::ParfactorList (const Parfactors& pfs)
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{
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add (pfs);
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}
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ParfactorList::~ParfactorList (void)
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{
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ParfactorList::const_iterator it = pfList_.begin();
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while (it != pfList_.end()) {
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delete *it;
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++ it;
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}
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}
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void
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ParfactorList::add (Parfactor* pf)
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{
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pf->setNewGroups();
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addToShatteredList (pf);
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}
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void
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ParfactorList::add (const Parfactors& pfs)
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{
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for (unsigned i = 0; i < pfs.size(); i++) {
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pfs[i]->setNewGroups();
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addToShatteredList (pfs[i]);
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}
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}
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void
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ParfactorList::addShattered (Parfactor* pf)
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{
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assert (isAllShattered());
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pfList_.push_back (pf);
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assert (isAllShattered());
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}
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list<Parfactor*>::iterator
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ParfactorList::insertShattered (
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list<Parfactor*>::iterator it,
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Parfactor* pf)
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{
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return pfList_.insert (it, pf);
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assert (isAllShattered());
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}
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list<Parfactor*>::iterator
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ParfactorList::remove (list<Parfactor*>::iterator it)
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{
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return pfList_.erase (it);
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}
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list<Parfactor*>::iterator
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ParfactorList::removeAndDelete (list<Parfactor*>::iterator it)
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{
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delete *it;
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return pfList_.erase (it);
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}
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bool
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ParfactorList::isAllShattered (void) const
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{
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if (pfList_.size() <= 1) {
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return true;
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}
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vector<Parfactor*> pfs (pfList_.begin(), pfList_.end());
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for (unsigned i = 0; i < pfs.size() - 1; i++) {
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for (unsigned j = i + 1; j < pfs.size(); j++) {
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if (isShattered (pfs[i], pfs[j]) == false) {
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return false;
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}
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}
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}
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return true;
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}
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void
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ParfactorList::print (void) const
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{
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list<Parfactor*>::const_iterator it;
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for (it = pfList_.begin(); it != pfList_.end(); ++it) {
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(*it)->print();
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cout << endl;
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}
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}
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bool
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ParfactorList::isShattered (
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const Parfactor* g1,
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const Parfactor* g2) const
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{
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assert (g1 != g2);
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const ProbFormulas& fms1 = g1->arguments();
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const ProbFormulas& fms2 = g2->arguments();
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for (unsigned i = 0; i < fms1.size(); i++) {
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for (unsigned j = 0; j < fms2.size(); j++) {
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if (fms1[i].group() == fms2[j].group()) {
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if (identical (
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fms1[i], *(g1->constr()),
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fms2[j], *(g2->constr())) == false) {
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return false;
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}
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} else {
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if (disjoint (
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fms1[i], *(g1->constr()),
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fms2[j], *(g2->constr())) == false) {
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return false;
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}
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}
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}
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}
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return true;
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}
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void
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ParfactorList::addToShatteredList (Parfactor* g)
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{
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queue<Parfactor*> residuals;
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residuals.push (g);
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while (residuals.empty() == false) {
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Parfactor* pf = residuals.front();
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bool pfSplitted = false;
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list<Parfactor*>::iterator pfIter;
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pfIter = pfList_.begin();
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while (pfIter != pfList_.end()) {
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std::pair<Parfactors, Parfactors> shattRes;
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shattRes = shatter (*pfIter, pf);
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if (shattRes.first.empty() == false) {
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pfIter = removeAndDelete (pfIter);
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Util::addToQueue (residuals, shattRes.first);
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} else {
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++ pfIter;
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}
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if (shattRes.second.empty() == false) {
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delete pf;
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Util::addToQueue (residuals, shattRes.second);
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pfSplitted = true;
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break;
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}
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}
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residuals.pop();
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if (pfSplitted == false) {
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addShattered (pf);
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}
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}
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assert (isAllShattered());
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}
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std::pair<Parfactors, Parfactors>
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ParfactorList::shatter (Parfactor* g1, Parfactor* g2)
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{
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ProbFormulas& formulas1 = g1->arguments();
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ProbFormulas& formulas2 = g2->arguments();
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assert (g1 != 0 && g2 != 0 && g1 != g2);
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for (unsigned i = 0; i < formulas1.size(); i++) {
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for (unsigned j = 0; j < formulas2.size(); j++) {
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if (formulas1[i].sameSkeletonAs (formulas2[j])) {
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std::pair<Parfactors, Parfactors> res;
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res = shatter (i, g1, j, g2);
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if (res.first.empty() == false ||
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res.second.empty() == false) {
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return res;
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}
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}
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}
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}
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return make_pair (Parfactors(), Parfactors());
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}
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std::pair<Parfactors, Parfactors>
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ParfactorList::shatter (
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unsigned fIdx1, Parfactor* g1,
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unsigned fIdx2, Parfactor* g2)
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{
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ProbFormula& f1 = g1->argument (fIdx1);
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ProbFormula& f2 = g2->argument (fIdx2);
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// cout << endl;
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// Util::printDashLine();
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// cout << "-> SHATTERING (#" << g1 << ", #" << g2 << ")" << endl;
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// g1->print();
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// cout << "-> WITH" << endl;
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// g2->print();
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// cout << "-> ON: " << f1 << "|" ;
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// cout << g1->constr()->tupleSet (f1.logVars()) << endl;
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// cout << "-> ON: " << f2 << "|" ;
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// cout << g2->constr()->tupleSet (f2.logVars()) << endl;
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// Util::printDashLine();
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if (f1.isAtom()) {
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unsigned group = (f1.group() < f2.group()) ? f1.group() : f2.group();
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f1.setGroup (group);
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f2.setGroup (group);
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return { };
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}
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assert (g1->constr()->empty() == false);
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assert (g2->constr()->empty() == false);
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if (f1.group() == f2.group()) {
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assert (identical (f1, *(g1->constr()), f2, *(g2->constr())));
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return { };
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}
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g1->constr()->moveToTop (f1.logVars());
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g2->constr()->moveToTop (f2.logVars());
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std::pair<ConstraintTree*,ConstraintTree*> split1 =
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g1->constr()->split (g2->constr(), f1.arity());
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ConstraintTree* commCt1 = split1.first;
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ConstraintTree* exclCt1 = split1.second;
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if (commCt1->empty()) {
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// disjoint
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delete commCt1;
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delete exclCt1;
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return { };
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}
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std::pair<ConstraintTree*,ConstraintTree*> split2 =
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g2->constr()->split (g1->constr(), f2.arity());
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ConstraintTree* commCt2 = split2.first;
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ConstraintTree* exclCt2 = split2.second;
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assert (commCt1->tupleSet (f1.arity()) ==
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commCt2->tupleSet (f2.arity()));
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// stringstream ss1; ss1 << "" << count << "_A.dot" ;
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// stringstream ss2; ss2 << "" << count << "_B.dot" ;
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// stringstream ss3; ss3 << "" << count << "_A_comm.dot" ;
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// stringstream ss4; ss4 << "" << count << "_A_excl.dot" ;
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// stringstream ss5; ss5 << "" << count << "_B_comm.dot" ;
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// stringstream ss6; ss6 << "" << count << "_B_excl.dot" ;
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// ct1->exportToGraphViz (ss1.str().c_str(), true);
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// ct2->exportToGraphViz (ss2.str().c_str(), true);
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// commCt1->exportToGraphViz (ss3.str().c_str(), true);
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// exclCt1->exportToGraphViz (ss4.str().c_str(), true);
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// commCt2->exportToGraphViz (ss5.str().c_str(), true);
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// exclCt2->exportToGraphViz (ss6.str().c_str(), true);
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if (exclCt1->empty() && exclCt2->empty()) {
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unsigned group = (f1.group() < f2.group())
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? f1.group()
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: f2.group();
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// identical
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f1.setGroup (group);
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f2.setGroup (group);
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// unifyGroups
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delete commCt1;
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delete exclCt1;
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delete commCt2;
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delete exclCt2;
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return { };
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}
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unsigned group;
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if (exclCt1->empty()) {
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group = f1.group();
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} else if (exclCt2->empty()) {
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group = f2.group();
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} else {
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group = ProbFormula::getNewGroup();
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}
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Parfactors res1 = shatter (g1, fIdx1, commCt1, exclCt1, group);
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Parfactors res2 = shatter (g2, fIdx2, commCt2, exclCt2, group);
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return make_pair (res1, res2);
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}
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Parfactors
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ParfactorList::shatter (
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Parfactor* g,
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unsigned fIdx,
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ConstraintTree* commCt,
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ConstraintTree* exclCt,
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unsigned commGroup)
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{
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ProbFormula& f = g->argument (fIdx);
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if (exclCt->empty()) {
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delete commCt;
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delete exclCt;
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f.setGroup (commGroup);
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return { };
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}
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Parfactors result;
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if (f.isCounting()) {
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LogVar X_new1 = g->constr()->logVarSet().back() + 1;
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LogVar X_new2 = g->constr()->logVarSet().back() + 2;
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ConstraintTrees cts = g->constr()->jointCountNormalize (
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commCt, exclCt, f.countedLogVar(), X_new1, X_new2);
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for (unsigned i = 0; i < cts.size(); i++) {
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Parfactor* newPf = new Parfactor (g, cts[i]);
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if (cts[i]->nrLogVars() == g->constr()->nrLogVars() + 1) {
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newPf->expand (f.countedLogVar(), X_new1, X_new2);
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assert (g->constr()->getConditionalCount (f.countedLogVar()) ==
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cts[i]->getConditionalCount (X_new1) +
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cts[i]->getConditionalCount (X_new2));
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} else {
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assert (g->constr()->getConditionalCount (f.countedLogVar()) ==
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cts[i]->getConditionalCount (f.countedLogVar()));
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}
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newPf->setNewGroups();
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result.push_back (newPf);
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}
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delete commCt;
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delete exclCt;
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} else {
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Parfactor* newPf = new Parfactor (g, commCt);
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newPf->setNewGroups();
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newPf->argument (fIdx).setGroup (commGroup);
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result.push_back (newPf);
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newPf = new Parfactor (g, exclCt);
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newPf->setNewGroups();
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result.push_back (newPf);
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}
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return result;
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}
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void
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ParfactorList::unifyGroups (unsigned group1, unsigned group2)
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{
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unsigned newGroup = ProbFormula::getNewGroup();
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for (ParfactorList::iterator it = pfList_.begin();
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it != pfList_.end(); it++) {
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ProbFormulas& formulas = (*it)->arguments();
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for (unsigned i = 0; i < formulas.size(); i++) {
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if (formulas[i].group() == group1 ||
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formulas[i].group() == group2) {
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formulas[i].setGroup (newGroup);
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}
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}
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}
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}
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bool
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ParfactorList::proper (
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const ProbFormula& f1, ConstraintTree c1,
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const ProbFormula& f2, ConstraintTree c2) const
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{
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return disjoint (f1, c1, f2, c2)
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|| identical (f1, c1, f2, c2);
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}
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bool
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ParfactorList::identical (
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const ProbFormula& f1, ConstraintTree c1,
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const ProbFormula& f2, ConstraintTree c2) const
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{
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if (f1.sameSkeletonAs (f2) == false) {
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return false;
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}
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if (f1.isAtom()) {
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return true;
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}
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c1.moveToTop (f1.logVars());
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c2.moveToTop (f2.logVars());
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return ConstraintTree::identical (
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&c1, &c2, f1.logVars().size());
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}
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bool
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ParfactorList::disjoint (
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const ProbFormula& f1, ConstraintTree c1,
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const ProbFormula& f2, ConstraintTree c2) const
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{
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if (f1.sameSkeletonAs (f2) == false) {
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return true;
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}
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if (f1.isAtom()) {
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return true;
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}
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c1.moveToTop (f1.logVars());
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c2.moveToTop (f2.logVars());
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return ConstraintTree::overlap (
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&c1, &c2, f1.arity()) == false;
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}
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