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/********************* */
/*! \file sat.cpp
** \verbatim
** Original author: cconway
** Major contributors: dejan, mdeters, taking
** Minor contributors (to current version): none
** This file is part of the CVC4 prototype.
** Copyright (c) 2009, 2010, 2011 The Analysis of Computer Systems Group (ACSys)
** Courant Institute of Mathematical Sciences
** New York University
** See the file COPYING in the top-level source directory for licensing
** information.\endverbatim
**
** \brief [[ Add one-line brief description here ]]
**
** [[ Add lengthier description here ]]
** \todo document this file
**/
#include "prop/cnf_stream.h"
#include "prop/prop_engine.h"
#include "prop/sat.h"
#include "context/context.h"
#include "theory/theory_engine.h"
#include "expr/expr_stream.h"
namespace CVC4 {
namespace prop {
void SatSolver::variableNotify(SatVariable var) {
d_theoryEngine->preRegister(getNode(variableToLiteral(var)));
}
void SatSolver::theoryCheck(theory::Theory::Effort effort) {
d_theoryEngine->check(effort);
}
void SatSolver::theoryPropagate(std::vector<SatLiteral>& output) {
// Propagate
d_theoryEngine->propagate();
// Get the propagated literals
const std::vector<TNode>& outputNodes = d_theoryEngine->getPropagatedLiterals();
// If any literals, make a clause
const unsigned i_end = outputNodes.size();
for (unsigned i = 0; i < i_end; ++ i) {
Debug("prop-explain") << "theoryPropagate() => " << outputNodes[i].toString() << std::endl;
SatLiteral l = d_cnfStream->getLiteral(outputNodes[i]);
output.push_back(l);
}
}
void SatSolver::explainPropagation(SatLiteral l, SatClause& explanation) {
TNode lNode = d_cnfStream->getNode(l);
Debug("prop-explain") << "explainPropagation(" << lNode << ")" << std::endl;
Node theoryExplanation = d_theoryEngine->getExplanation(lNode);
Debug("prop-explain") << "explainPropagation() => " << theoryExplanation << std::endl;
if (theoryExplanation.getKind() == kind::AND) {
Node::const_iterator it = theoryExplanation.begin();
Node::const_iterator it_end = theoryExplanation.end();
explanation.push(l);
for (; it != it_end; ++ it) {
explanation.push(~d_cnfStream->getLiteral(*it));
}
} else {
explanation.push(l);
explanation.push(~d_cnfStream->getLiteral(theoryExplanation));
}
}
void SatSolver::clearPropagatedLiterals() {
d_theoryEngine->clearPropagatedLiterals();
}
void SatSolver::enqueueTheoryLiteral(const SatLiteral& l) {
Node literalNode = d_cnfStream->getNode(l);
Debug("prop") << "enqueueing theory literal " << l << " " << literalNode << std::endl;
Assert(!literalNode.isNull());
d_theoryEngine->assertFact(literalNode);
}
void SatSolver::setCnfStream(CnfStream* cnfStream) {
d_cnfStream = cnfStream;
}
void SatSolver::removeClausesAboveLevel(int level) {
d_cnfStream->removeClausesAboveLevel(level);
}
TNode SatSolver::getNode(SatLiteral lit) {
return d_cnfStream->getNode(lit);
}
void SatSolver::notifyRestart() {
d_theoryEngine->notifyRestart();
}
SatLiteral SatSolver::getNextReplayDecision() {
#ifdef CVC4_REPLAY
if(Options::current()->replayStream != NULL) {
Expr e = Options::current()->replayStream->nextExpr();
if(!e.isNull()) { // we get null node when out of decisions to replay
// convert & return
return d_cnfStream->getLiteral(e);
}
}
#endif /* CVC4_REPLAY */
return Minisat::lit_Undef;
}
void SatSolver::logDecision(SatLiteral lit) {
#ifdef CVC4_REPLAY
if(Options::current()->replayLog != NULL) {
Assert(lit != Minisat::lit_Undef, "logging an `undef' decision ?!");
*Options::current()->replayLog << d_cnfStream->getNode(lit) << std::endl;
}
#endif /* CVC4_REPLAY */
}
}/* CVC4::prop namespace */
}/* CVC4 namespace */
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