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/********************* */
/*! \file rep_set.cpp
** \verbatim
** Original author: Andrew Reynolds
** Major contributors: Morgan Deters
** Minor contributors (to current version): none
** This file is part of the CVC4 project.
** Copyright (c) 2009-2013 New York University and The University of Iowa
** See the file COPYING in the top-level source directory for licensing
** information.\endverbatim
**
** \brief Implementation of representative set
**/
#include "theory/rep_set.h"
#include "theory/type_enumerator.h"
using namespace std;
using namespace CVC4;
using namespace CVC4::kind;
using namespace CVC4::context;
using namespace CVC4::theory;
void RepSet::clear(){
d_type_reps.clear();
d_type_complete.clear();
d_tmap.clear();
}
int RepSet::getNumRepresentatives( TypeNode tn ) const{
std::map< TypeNode, std::vector< Node > >::const_iterator it = d_type_reps.find( tn );
if( it!=d_type_reps.end() ){
return (int)it->second.size();
}else{
return 0;
}
}
void RepSet::add( Node n ){
TypeNode t = n.getType();
d_tmap[ n ] = (int)d_type_reps[t].size();
d_type_reps[t].push_back( n );
}
int RepSet::getIndexFor( Node n ) const {
std::map< Node, int >::const_iterator it = d_tmap.find( n );
if( it!=d_tmap.end() ){
return it->second;
}else{
return -1;
}
}
void RepSet::complete( TypeNode t ){
if( d_type_complete.find( t )==d_type_complete.end() ){
d_type_complete[t] = true;
TypeEnumerator te(t);
while( !te.isFinished() ){
Node n = *te;
if( std::find( d_type_reps[t].begin(), d_type_reps[t].end(), n )==d_type_reps[t].end() ){
add( n );
}
++te;
}
for( size_t i=0; i<d_type_reps[t].size(); i++ ){
Trace("reps-complete") << d_type_reps[t][i] << " ";
}
Trace("reps-complete") << std::endl;
}
}
void RepSet::toStream(std::ostream& out){
#if 0
for( std::map< TypeNode, std::vector< Node > >::iterator it = d_type_reps.begin(); it != d_type_reps.end(); ++it ){
out << it->first << " : " << std::endl;
for( int i=0; i<(int)it->second.size(); i++ ){
out << " " << i << ": " << it->second[i] << std::endl;
}
}
#else
for( std::map< TypeNode, std::vector< Node > >::iterator it = d_type_reps.begin(); it != d_type_reps.end(); ++it ){
if( !it->first.isFunction() && !it->first.isPredicate() ){
out << "(" << it->first << " " << it->second.size();
out << " (";
for( int i=0; i<(int)it->second.size(); i++ ){
if( i>0 ){ out << " "; }
out << it->second[i];
}
out << ")";
out << ")" << std::endl;
}
}
#endif
}
RepSetIterator::RepSetIterator( RepSet* rs ) : d_rep_set( rs ){
d_incomplete = false;
}
bool RepSetIterator::setQuantifier( Node f ){
Assert( d_types.empty() );
//store indicies
for( size_t i=0; i<f[0].getNumChildren(); i++ ){
d_types.push_back( f[0][i].getType() );
}
return initialize();
}
bool RepSetIterator::setFunctionDomain( Node op ){
Assert( d_types.empty() );
TypeNode tn = op.getType();
for( size_t i=0; i<tn.getNumChildren()-1; i++ ){
d_types.push_back( tn[i] );
}
return initialize();
}
bool RepSetIterator::initialize(){
for( size_t i=0; i<d_types.size(); i++ ){
d_index.push_back( 0 );
//store default index order
d_index_order.push_back( i );
d_var_order[i] = i;
//store default domain
d_domain.push_back( RepDomain() );
TypeNode tn = d_types[i];
if( tn.isSort() ){
if( !d_rep_set->hasType( tn ) ){
Node var = NodeManager::currentNM()->mkSkolem( "repSet_$$", tn, "is a variable created by the RepSetIterator" );
Trace("mkVar") << "RepSetIterator:: Make variable " << var << " : " << tn << std::endl;
d_rep_set->add( var );
}
}else if( tn.isInteger() || tn.isReal() ){
Trace("fmf-incomplete") << "Incomplete because of infinite type " << tn << std::endl;
d_incomplete = true;
//enumerate if the sort is reasonably small, the upper bound of 128 is chosen arbitrarily for now
}else if( tn.getCardinality().isFinite() && tn.getCardinality().getFiniteCardinality().toUnsignedInt()<=128 ){
d_rep_set->complete( tn );
}else{
Trace("fmf-incomplete") << "Incomplete because of unknown type " << tn << std::endl;
d_incomplete = true;
}
if( d_rep_set->hasType( tn ) ){
for( size_t j=0; j<d_rep_set->d_type_reps[tn].size(); j++ ){
d_domain[i].push_back( j );
}
}else{
return false;
}
}
return true;
}
void RepSetIterator::setIndexOrder( std::vector< int >& indexOrder ){
d_index_order.clear();
d_index_order.insert( d_index_order.begin(), indexOrder.begin(), indexOrder.end() );
//make the d_var_order mapping
for( int i=0; i<(int)d_index_order.size(); i++ ){
d_var_order[d_index_order[i]] = i;
}
}
void RepSetIterator::setDomain( std::vector< RepDomain >& domain ){
d_domain.clear();
d_domain.insert( d_domain.begin(), domain.begin(), domain.end() );
//we are done if a domain is empty
for( int i=0; i<(int)d_domain.size(); i++ ){
if( d_domain[i].empty() ){
d_index.clear();
}
}
}
void RepSetIterator::increment2( int counter ){
Assert( !isFinished() );
#ifdef DISABLE_EVAL_SKIP_MULTIPLE
counter = (int)d_index.size()-1;
#endif
//increment d_index
while( counter>=0 && d_index[counter]==(int)(d_domain[counter].size()-1) ){
counter--;
}
if( counter==-1 ){
d_index.clear();
}else{
for( int i=(int)d_index.size()-1; i>counter; i-- ){
d_index[i] = 0;
}
d_index[counter]++;
}
}
void RepSetIterator::increment(){
if( !isFinished() ){
increment2( (int)d_index.size()-1 );
}
}
bool RepSetIterator::isFinished(){
return d_index.empty();
}
Node RepSetIterator::getTerm( int i ){
TypeNode tn = d_types[d_index_order[i]];
Assert( d_rep_set->d_type_reps.find( tn )!=d_rep_set->d_type_reps.end() );
int index = d_index_order[i];
return d_rep_set->d_type_reps[tn][d_domain[index][d_index[index]]];
}
void RepSetIterator::debugPrint( const char* c ){
for( int i=0; i<(int)d_index.size(); i++ ){
Debug( c ) << i << " : " << d_index[i] << " : " << getTerm( i ) << std::endl;
}
}
void RepSetIterator::debugPrintSmall( const char* c ){
Debug( c ) << "RI: ";
for( int i=0; i<(int)d_index.size(); i++ ){
Debug( c ) << d_index[i] << ": " << getTerm( i ) << " ";
}
Debug( c ) << std::endl;
}
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