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/********************* */
/*! \file theory.cpp
** \verbatim
** Original author: mdeters
** Major contributors: 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 Base for theory interface.
**
** Base for theory interface.
**/
#include "theory/theory.h"
#include "util/Assert.h"
#include "theory/quantifiers_engine.h"
#include "theory/instantiator_default.h"
#include <vector>
using namespace std;
namespace CVC4 {
namespace theory {
/** Default value for the uninterpreted sorts is the UF theory */
TheoryId Theory::s_uninterpretedSortOwner = THEORY_UF;
/** By default, we use the type based theoryOf */
TheoryOfMode Theory::s_theoryOfMode = THEORY_OF_TYPE_BASED;
std::ostream& operator<<(std::ostream& os, Theory::Effort level){
switch(level){
case Theory::EFFORT_STANDARD:
os << "EFFORT_STANDARD"; break;
case Theory::EFFORT_FULL:
os << "EFFORT_FULL"; break;
case Theory::EFFORT_COMBINATION:
os << "EFFORT_COMBINATION"; break;
case Theory::EFFORT_LAST_CALL:
os << "EFFORT_LAST_CALL"; break;
default:
Unreachable();
}
return os;
}/* ostream& operator<<(ostream&, Theory::Effort) */
Theory::~Theory() {
if(d_inst != NULL) {
delete d_inst;
d_inst = NULL;
}
StatisticsRegistry::unregisterStat(&d_computeCareGraphTime);
}
TheoryId Theory::theoryOf(TheoryOfMode mode, TNode node) {
Trace("theory::internal") << "theoryOf(" << node << ")" << std::endl;
switch(mode) {
case THEORY_OF_TYPE_BASED:
// Constants, variables, 0-ary constructors
if (node.getMetaKind() == kind::metakind::VARIABLE || node.getMetaKind() == kind::metakind::CONSTANT) {
return theoryOf(node.getType());
}
// Equality is owned by the theory that owns the domain
if (node.getKind() == kind::EQUAL) {
return theoryOf(node[0].getType());
}
// Regular nodes are owned by the kind
return kindToTheoryId(node.getKind());
break;
case THEORY_OF_TERM_BASED:
// Variables
if (node.getMetaKind() == kind::metakind::VARIABLE) {
if (theoryOf(node.getType()) != theory::THEORY_BOOL) {
// We treat the varibables as uninterpreted
return s_uninterpretedSortOwner;
} else {
// Except for the Boolean ones, which we just ignore anyhow
return theory::THEORY_BOOL;
}
}
// Constants
if (node.getMetaKind() == kind::metakind::CONSTANT) {
// Constants go to the theory of the type
return theoryOf(node.getType());
}
// Equality
if (node.getKind() == kind::EQUAL) {
// If one of them is an ITE, it's irelevant, since they will get replaced out anyhow
if (node[0].getKind() == kind::ITE) {
return theoryOf(node[0].getType());
}
if (node[1].getKind() == kind::ITE) {
return theoryOf(node[1].getType());
}
// If both sides belong to the same theory the choice is easy
TheoryId T1 = theoryOf(node[0]);
TheoryId T2 = theoryOf(node[1]);
if (T1 == T2) {
return T1;
}
TheoryId T3 = theoryOf(node[0].getType());
// This is a case of
// * x*y = f(z) -> UF
// * x = c -> UF
// * f(x) = read(a, y) -> either UF or ARRAY
// at least one of the theories has to be parametric, i.e. theory of the type is different
// from the theory of the term
if (T1 == T3) {
return T2;
}
if (T2 == T3) {
return T1;
}
// If both are parametric, we take the smaller one (arbitraty)
return T1 < T2 ? T1 : T2;
}
// Regular nodes are owned by the kind
return kindToTheoryId(node.getKind());
break;
default:
Unreachable();
}
}
void Theory::addSharedTermInternal(TNode n) {
Debug("sharing") << "Theory::addSharedTerm<" << getId() << ">(" << n << ")" << endl;
Debug("theory::assertions") << "Theory::addSharedTerm<" << getId() << ">(" << n << ")" << endl;
d_sharedTerms.push_back(n);
addSharedTerm(n);
}
void Theory::computeCareGraph() {
Debug("sharing") << "Theory::computeCareGraph<" << getId() << ">()" << endl;
for (unsigned i = 0; i < d_sharedTerms.size(); ++ i) {
TNode a = d_sharedTerms[i];
TypeNode aType = a.getType();
for (unsigned j = i + 1; j < d_sharedTerms.size(); ++ j) {
TNode b = d_sharedTerms[j];
if (b.getType() != aType) {
// We don't care about the terms of different types
continue;
}
switch (d_valuation.getEqualityStatus(a, b)) {
case EQUALITY_TRUE_AND_PROPAGATED:
case EQUALITY_FALSE_AND_PROPAGATED:
// If we know about it, we should have propagated it, so we can skip
break;
default:
// Let's split on it
addCarePair(a, b);
break;
}
}
}
}
void Theory::printFacts(std::ostream& os) const {
unsigned i, n = d_facts.size();
for(i = 0; i < n; i++){
const Assertion& a_i = d_facts[i];
Node assertion = a_i;
os << d_id << '[' << i << ']' << " " << assertion << endl;
}
}
void Theory::debugPrintFacts() const{
DebugChannel.getStream() << "Theory::debugPrintFacts()" << endl;
printFacts(DebugChannel.getStream());
}
Instantiator::Instantiator(context::Context* c, QuantifiersEngine* qe, Theory* th) :
d_quantEngine(qe),
d_th(th) {
}
Instantiator::~Instantiator() {
}
void Instantiator::resetInstantiationRound(Theory::Effort effort) {
for(int i = 0; i < (int) d_instStrategies.size(); ++i) {
if(isActiveStrategy(d_instStrategies[i])) {
d_instStrategies[i]->resetInstantiationRound(effort);
}
}
processResetInstantiationRound(effort);
}
int Instantiator::doInstantiation(Node f, Theory::Effort effort, int e, int limitInst) {
if(hasConstraintsFrom(f)) {
int origLemmas = d_quantEngine->getNumLemmasWaiting();
int status = process(f, effort, e, limitInst);
if(limitInst <= 0 || (d_quantEngine->getNumLemmasWaiting()-origLemmas) < limitInst) {
if(d_instStrategies.empty()) {
Debug("inst-engine-inst") << "There are no instantiation strategies allocated." << endl;
} else {
for(int i = 0; i < (int) d_instStrategies.size(); ++i) {
if(isActiveStrategy(d_instStrategies[i])) {
Debug("inst-engine-inst") << d_instStrategies[i]->identify() << " process " << effort << endl;
//call the instantiation strategy's process method
int s_limitInst = limitInst > 0 ? limitInst - (d_quantEngine->getNumLemmasWaiting() - origLemmas) : 0;
int s_status = d_instStrategies[i]->doInstantiation(f, effort, e, s_limitInst);
Debug("inst-engine-inst") << " -> status is " << s_status << endl;
if(limitInst > 0 && (d_quantEngine->getNumLemmasWaiting() - origLemmas) >= limitInst) {
Assert( (d_quantEngine->getNumLemmasWaiting() - origLemmas) == limitInst );
i = (int) d_instStrategies.size();
status = InstStrategy::STATUS_UNKNOWN;
} else {
InstStrategy::updateStatus(status, s_status);
}
} else {
Debug("inst-engine-inst") << d_instStrategies[i]->identify() << " is not active." << endl;
}
}
}
}
return status;
} else {
Debug("inst-engine-inst") << "We have no constraints from this quantifier." << endl;
return InstStrategy::STATUS_SAT;
}
}
//void Instantiator::doInstantiation(int effort) {
// d_status = InstStrategy::STATUS_SAT;
// for( int q = 0; q < d_quantEngine->getNumQuantifiers(); ++q ) {
// Node f = d_quantEngine->getQuantifier(q);
// if( d_quantEngine->getActive(f) && hasConstraintsFrom(f) ) {
// int d_quantStatus = process( f, effort );
// InstStrategy::updateStatus( d_status, d_quantStatus );
// for( int i = 0; i < (int)d_instStrategies.size(); ++i ) {
// if( isActiveStrategy( d_instStrategies[i] ) ) {
// Debug("inst-engine-inst") << d_instStrategies[i]->identify() << " process " << effort << endl;
// //call the instantiation strategy's process method
// d_quantStatus = d_instStrategies[i]->process( f, effort );
// Debug("inst-engine-inst") << " -> status is " << d_quantStatus << endl;
// InstStrategy::updateStatus( d_status, d_quantStatus );
// }
// }
// }
// }
//}
void Instantiator::setHasConstraintsFrom(Node f) {
d_hasConstraints[f] = true;
if(! d_quantEngine->hasOwner(f)) {
d_quantEngine->setOwner(f, getTheory());
} else if(d_quantEngine->getOwner(f) != getTheory()) {
d_quantEngine->setOwner(f, NULL);
}
}
bool Instantiator::hasConstraintsFrom(Node f) {
return d_hasConstraints.find(f) != d_hasConstraints.end() && d_hasConstraints[f];
}
bool Instantiator::isOwnerOf(Node f) {
return d_quantEngine->hasOwner(f) && d_quantEngine->getOwner(f) == getTheory();
}
}/* CVC4::theory namespace */
}/* CVC4 namespace */
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