Exemple #1
0
Clauses Term::getClauses(Assigment a) {
	Clauses cs;
	for (unsigned int i = 0; i < clauses.size(); i++)
	{
		Clause c;
		auto addClause = true;
		for (auto it : clauses[i])
		{
			auto var = abs(it);
			if (!a.isSet(var))
			{
				c.insert(it);
				continue;
			}
			if (it > 0 && a.isTrue(var) || it < 0 && a.isFalse(var))
			{
				addClause = false;
				break;
			}
			if (it > 0 && a.isFalse(var) || it < 0 && a.isTrue(var))
				continue;
			c.insert(it);
		}
		if (addClause)
			cs.push_back(c);
		else
		{
			c.clear();
			c.insert(0);
			cs.push_back(c);
		}
	}

	return cs;
}
Exemple #2
0
Clause Term::getClause(Assigment a, int i) {
	Clause c;
	auto addClause = true;
	for (auto it:clauses[i])
	{
		auto var = abs(it);
		if (!a.isSet(var))
		{
			c.insert(it);
			continue;
		}
		if (it > 0 && a.isTrue(var) || it < 0 && a.isFalse(var))
		{
			addClause = false;
			break;
		}
		else if (it > 0 && a.isFalse(var) || it < 0 && a.isTrue(var))
			continue;
		else
			c.insert(it);
	}
	if (addClause)
		return c;

	c.clear();
	c.insert(0);

	return c;
}
Exemple #3
0
Clause CDCL::resolve(Clause c1, Clause c2, Variable v)
{
	Clause c;

	for (auto it : c1)
		if (it != v && it != -v)
			c.insert(it);

	for (auto it : c2)
		if (it != v && it != -v)
			c.insert(it);

	return c;
}
Exemple #4
0
// get clause data
int
Atomic::getClauses(ombt::Set_List<Clause> &clist, Clause &c, 
		int storeClause, int negated, int concluded) const
{
	Atom atom;
	switch (type)
	{
	case Constant:
		atom = Atom(value);
		if (negated)
		{
			if (atom == Atom("true"))
				atom = Atom("false");
			else
				atom = Atom("true");
		}
		break;
	case Variable:
		if (negated)
			atom = ~Atom(name);
		else
			atom = Atom(name);
		break;
	default:
		MustBeTrue(0);
		return(NOTOK);
	}
	c.setPartOfConclusion(concluded);
	c.insert(atom);
	return(OK);
}
Exemple #5
0
// rename variables in clause
int
Clause::renameVariables()
{
	Clause newcl;
	Map<String, String> nvs;

	// rename variables in positive clause
	BinaryTreeIterator_InOrder<Tuple<Literal, List<Literal> > >
		pclIter(positiveClause);
	for ( ; !pclIter.done(); pclIter++)
	{
		ListIterator<Literal> dataIter(pclIter().data);
		for ( ; !dataIter.done(); dataIter++)
		{
			Literal literal(dataIter());
			if (literal.renameVariables(nvs) != OK)
				return(NOTOK);
			if (newcl.insert(literal) != OK)
				return(NOTOK);
		}
	}

	// rename variables in negative clause
	BinaryTreeIterator_InOrder<Tuple<Literal, List<Literal> > >
		nclIter(negativeClause);
	for ( ; !nclIter.done(); nclIter++)
	{
		ListIterator<Literal> dataIter(nclIter().data);
		for ( ; !dataIter.done(); dataIter++)
		{
			Literal literal(dataIter());
			if (literal.renameVariables(nvs) != OK)
				return(NOTOK);
			if (newcl.insert(literal) != OK)
				return(NOTOK);
		}
	}

	// overwrite existing clauses
	*this = newcl;

	// all done
	return(OK);
}
bool CNFGenerator::OnePersonOneTable()
{
	Clause onePersonAtLeastOneTable;
	Clause onePersonAtMaxOneTable;
	for (int i =0;i<people;i++)
	{
		onePersonAtLeastOneTable.clear();
		onePersonAtMaxOneTable.clear();
		//cout <<"atleast 1 =";
		for (int j=0;j<tables;j++)
		{
			Literal newLiteral(i,j,false);
			//cout <<newLiteral;
			onePersonAtLeastOneTable.insert(newLiteral);
			
		}
		//cout<<endl;

		//sort(onePersonAtLeastOneTable.begin(),onePersonAtLeastOneTable.end());
		SetOfClauses.insert(pair<Clause,int> (onePersonAtLeastOneTable,++CNFGenerator::globalClauseCount));
		
		for (int j=0;j<tables;j++)
		{
			for (int k=j+1;k<tables;k++)
			{
				onePersonAtMaxOneTable.clear();
				Literal newLiteral1(i,j,true);
				Literal newLiteral2(i,k,true);
				onePersonAtMaxOneTable.insert(newLiteral1);
				onePersonAtMaxOneTable.insert(newLiteral2);
				//sort(onePersonAtMaxOneTable.begin(),onePersonAtMaxOneTable.end());
				SetOfClauses.insert(pair<Clause,int> (onePersonAtMaxOneTable,++CNFGenerator::globalClauseCount));
			}
		}
		
	}

	return true;
}
bool CNFGenerator::EnemiesGenerator()
{
	Clause newEnemyClause;
	for (vector<pair <short,short> >::iterator it = Enemies.begin();it!=Enemies.end();it++)
	{
		for (int i =0; i< tables;i++)
		{
			newEnemyClause.clear();
			Literal newLiteral1(it->first,i,true);
			Literal newLiteral2(it->second,i,true);
			newEnemyClause.insert(newLiteral1);
			newEnemyClause.insert(newLiteral2);
			//sort(newEnemyClause.begin(),newEnemyClause.end());
			SetOfClauses.insert(pair<Clause,int>(newEnemyClause,++CNFGenerator::globalClauseCount));
		}
		
	}

	return true;

}
Exemple #8
0
Clause CDCL::solver(int decisionLevel)
{
	while (true)
	{
		auto clauses = statement.getClauses(conclusion);

		satisfiable = true;
		for (unsigned int i = 0; i < clauses.size(); i++)
		{
			if (clauses[i].count(0) == 0)
				satisfiable = false;


			if (clauses[i].size() == 0)
			{
				// start learning

				return statement.getClauses()[i];
			}
		}
		if (satisfiable)
		{
			Clause c;
			c.insert(0);
			return c;
		}

		auto p = unitPropagation();
		if (p.first != -1)
		{
			auto c = solver(decisionLevel);
			if (c.size() == 0)
			{ // UNSAT
				conclusion.unset(p.first);
				return c;
			}
			if (c.count(0) > 0)
			{ // SAT
				return c;
			}


			conclusion.unset(p.first);

			auto c2 = statement.getClauses()[p.second];

			if (c.count(p.first) > 0 || c.count(-p.first) > 0)
				return resolve(c, c2, p.first);
			return c;
		}


		auto var = 0;
		unsigned int clause_length = 100000;

		for (auto c:clauses)
		{
			if (c.count(0) > 0) continue; // true

			if (c.size() > 0 && c.size() < clause_length)
			{
				clause_length = c.size();
				var = abs(*c.begin());
			}
		}


		bool value = rand() % 2;
		conclusion.set(var, value);

		auto c = solver(decisionLevel + 1);


		if (c.count(0) != 0)
		{ // SAT
			return c;
		}
		if (c.count(var) == 0 && c.count(-var) == 0)

		{
			conclusion.unset(var);
			return c;
		}

		conclusion.unset(var);

		statement.add(c);
	}
}
Exemple #9
0
// rename variables in clause
int
Clause::renameVariables()
{
	Clause newcl;
	Map<String, String> nvs;

	// rename variables in positive clause
	BinaryTree_AVL_Iterator_InOrder<Literal> pclIter(positiveClause);
	for ( ; !pclIter.done(); pclIter++)
	{
		Literal literal(pclIter());
		if (literal.renameVariables(nvs) != OK)
		{
			ERROR("renameVariables failed.", errno);
			return(NOTOK);
		}
		if (newcl.insert(literal) != OK)
		{
			ERROR("insert failed.", errno);
			return(NOTOK);
		}
	}

	// rename variables in negative clause
	BinaryTree_AVL_Iterator_InOrder<Literal> nclIter(negativeClause);
	for ( ; !nclIter.done(); nclIter++)
	{
		Literal literal(nclIter());
		if (literal.renameVariables(nvs) != OK)
		{
			ERROR("renameVariables failed.", errno);
			return(NOTOK);
		}
		if (newcl.insert(literal) != OK)
		{
			ERROR("insert failed.", errno);
			return(NOTOK);
		}
	}

	// rename variables in answers clause
	ListIterator<Literal> ansIter(answers);
	for ( ; !ansIter.done(); ansIter++)
	{
		Literal literal(ansIter());
		if (literal.renameVariables(nvs) != OK)
		{
			ERROR("renameVariables failed.", errno);
			return(NOTOK);
		}
		if (newcl.insertAnswer(literal) != OK)
		{
			ERROR("insert failed.", errno);
			return(NOTOK);
		}
	}

#if 0
	// update table of renamed variables
	if (updateVariableNames(nvs) != OK)
		return(NOTOK);
#endif

	// overwrite existing clauses
	newcl.setDepth(getDepth());
	newcl.setNumber(getNumber());
	newcl.setConclusion(getConclusion());
	newcl.setQuery(getQuery());
	newcl.setSOS(getSOS());
	*this = newcl;

	// all done
	return(OK);
}
Exemple #10
0
 ClauseSets::CLS operator()() const {
   ClauseSets::CLS G;
   // Non-triviality clause:
   {Clause C;
    for (Encoding::clause_index_t i = 0; i < enc.ncs; ++i)
      C.insert(Lit(enc.csvar(i), Pol::p));
    assert(C.size() == enc.ncs);
    G.push_back(std::move(C)); ++c_cs; litocc += enc.ncs;
   }
   // Defining the pass's:
   {for (auto it = enc.all_solutions.first.begin(); it != enc.all_solutions.first.end(); ++it) {
     const Encoding::Pass_p phi_p = &*it;
     const ClauseSets::Pass& phi = *it;
     const Var tphi = enc.pavar(phi_p);
     // from left to right, i.e., t(phi) -> and_{v in var(phi)} t(v,phi(v)):
     {const Lit negtphi = Lit(tphi, Pol::n);
      for (const auto& pair : phi) {
        Clause C; C.insert(negtphi);
        C.insert(Lit(enc.bfvar(pair.first, pair.second), Pol::p));
        assert(C.size() == 2);
        G.push_back(std::move(C)); ++c_palr; litocc += 2;
      }
     }
     // from right to left, i.e., (and_{v in var(phi)} t(v,phi(v))) -> t(phi):
     {Clause C; C.insert(Lit(tphi,Pol::p));
      for (const auto& pair : phi)
        C.insert(Lit(enc.bfvar(pair.first, pair.second), Pol::n));
      assert(C.size() ==  1 + phi.size());
      G.push_back(std::move(C)); ++c_parl; litocc += 1 + phi.size();
     }
    }
   }
   {for (Encoding::clause_index_t i = 0; i < enc.ncs; ++i) {
      // t(C) -> P(C):
      const Var tc = enc.csvar(i);
      {Clause C; C.insert(Lit(tc,Pol::n));
       const auto& S = enc.all_solutions.second[i];
       for (const Encoding::Pass_p& phi_p : S)
         C.insert(Lit(enc.pavar(phi_p),Pol::p));
       assert(C.size() == 1 + S.size());
       G.push_back(std::move(C)); ++c_P; litocc += 1 + S.size();
      }
      // -t(C) -> N(C):
      for (const Lit x : enc.dclauses[i]->P.second) {
        const Var v = enc.E_index[var(x)];
        assert(v < F.ne);
        for (Var bfi = enc.bfvar_indices[v]; bfi < enc.bfvar_indices[v+1]; ++bfi) {
          Clause C; C.insert(Lit(tc,Pol::p)); C.insert(Lit(bfi,Pol::n));
          assert(C.size() == 2);
          G.push_back(std::move(C)); ++c_N; litocc += 2;
        }
      }
    }
   }
   // Amo-clauses for bf-variables:
   {for (Var i = 0; i < F.ne; ++i) {
      const Var beg = enc.bfvar_indices[i], end = enc.bfvar_indices[i+1];
      for (Var v = beg; v < end; ++v)
        for (Var w = v+1; w < end; ++w) {
          Clause C; C.insert(Lit(v,Pol::n)), C.insert(Lit(w,Pol::n));
          assert(C.size() == 2);
          G.push_back(std::move(C)); ++c_amo; litocc += 2;
        }
    }
   }
   return G;
 }