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/********************* */
/*! \file model_builder.h
** \verbatim
** Original author: ajreynol
** Major contributors: mdeters
** Minor contributors (to current version): none
** This file is part of the CVC4 prototype.
** Copyright (c) 2009-2012 New York University and The University of Iowa
** See the file COPYING in the top-level source directory for licensing
** information.\endverbatim
**
** \brief Model Builder class
**/
#include "cvc4_private.h"
#ifndef __CVC4__THEORY__QUANTIFIERS__MODEL_BUILDER_H
#define __CVC4__THEORY__QUANTIFIERS__MODEL_BUILDER_H
#include "theory/quantifiers_engine.h"
#include "theory/model.h"
#include "theory/uf/theory_uf_model.h"
namespace CVC4 {
namespace theory {
/** Attribute true for nodes that should not be used when considered for inst-gen basis */
struct BasisNoMatchAttributeId {};
/** use the special for boolean flag */
typedef expr::Attribute< BasisNoMatchAttributeId,
bool,
expr::attr::NullCleanupStrategy,
true // context dependent
> BasisNoMatchAttribute;
class TermArgBasisTrie {
private:
bool addTerm2( QuantifiersEngine* qe, Node n, int argIndex );
public:
/** the data */
std::map< Node, TermArgBasisTrie > d_data;
public:
bool addTerm( QuantifiersEngine* qe, Node n ) { return addTerm2( qe, n, 0 ); }
};/* class TermArgBasisTrie */
namespace quantifiers {
/** model builder class
* This class is capable of building candidate models based on the current quantified formulas
* that are asserted. Use:
* (1) call ModelEngineBuilder::buildModel( m, false );, where m is a FirstOrderModel
* (2) if candidate model is determined to be a real model,
then call ModelEngineBuilder::buildModel( m, true );
*/
class ModelEngineBuilder : public TheoryEngineModelBuilder
{
protected:
//quantifiers engine
QuantifiersEngine* d_qe;
//the model we are working with
context::CDO< FirstOrderModel* > d_curr_model;
//map from operators to model preference data
std::map< Node, uf::UfModelPreferenceData > d_uf_prefs;
//built model uf
std::map< Node, bool > d_uf_model_constructed;
/** process build model */
virtual void processBuildModel( TheoryModel* m, bool fullModel );
protected:
//reset
virtual void reset( FirstOrderModel* fm ) = 0;
//initialize quantifiers, return number of lemmas produced, fp is the parent of quantifier f
virtual int initializeQuantifier( Node f, Node fp );
//analyze model
virtual void analyzeModel( FirstOrderModel* fm );
//analyze quantifiers
virtual void analyzeQuantifier( FirstOrderModel* fm, Node f ) = 0;
//do InstGen techniques for quantifier, return number of lemmas produced
virtual int doInstGen( FirstOrderModel* fm, Node f ) = 0;
//theory-specific build models
virtual void constructModelUf( FirstOrderModel* fm, Node op ) = 0;
protected:
//map from quantifiers to if are SAT
std::map< Node, bool > d_quant_sat;
//which quantifiers have been initialized
std::map< Node, bool > d_quant_basis_match_added;
//map from quantifiers to model basis match
std::map< Node, InstMatch > d_quant_basis_match;
public:
ModelEngineBuilder( context::Context* c, QuantifiersEngine* qe );
virtual ~ModelEngineBuilder(){}
/** number of lemmas generated while building model */
int d_addedLemmas;
//consider axioms
bool d_considerAxioms;
// set effort
void setEffort( int effort );
protected: //helper functions
/** term has constant definition */
bool hasConstantDefinition( Node n );
public:
//options
virtual bool optUseModel();
virtual bool optInstGen();
virtual bool optOneQuantPerRoundInstGen();
/** statistics class */
class Statistics {
public:
IntStat d_pre_sat_quant;
IntStat d_pre_nsat_quant;
IntStat d_num_quants_init;
IntStat d_num_quants_init_success;
Statistics();
~Statistics();
};
Statistics d_statistics;
// is quantifier active?
bool isQuantifierActive( Node f );
// is term active
bool isTermActive( Node n );
// is term selected
virtual bool isTermSelected( Node n ) { return false; }
};/* class ModelEngineBuilder */
class ModelEngineBuilderDefault : public ModelEngineBuilder
{
private: ///information for (old) InstGen
//map from quantifiers to their selection literals
std::map< Node, Node > d_quant_selection_lit;
std::map< Node, std::vector< Node > > d_quant_selection_lit_candidates;
//map from quantifiers to their selection literal terms
std::map< Node, std::vector< Node > > d_quant_selection_lit_terms;
//map from terms to the selection literals they exist in
std::map< Node, Node > d_term_selection_lit;
//map from operators to terms that appear in selection literals
std::map< Node, std::vector< Node > > d_op_selection_terms;
protected:
//reset
void reset( FirstOrderModel* fm );
//analyze quantifier
void analyzeQuantifier( FirstOrderModel* fm, Node f );
//do InstGen techniques for quantifier, return number of lemmas produced
int doInstGen( FirstOrderModel* fm, Node f );
//theory-specific build models
void constructModelUf( FirstOrderModel* fm, Node op );
public:
ModelEngineBuilderDefault( context::Context* c, QuantifiersEngine* qe ) : ModelEngineBuilder( c, qe ){}
~ModelEngineBuilderDefault(){}
//options
bool optReconsiderFuncConstants() { return true; }
};
class ModelEngineBuilderInstGen : public ModelEngineBuilder
{
private: ///information for (new) InstGen
//map from quantifiers to their selection literals
std::map< Node, Node > d_quant_selection_formula;
//map of terms that are selected
std::map< Node, bool > d_term_selected;
//a collection of InstMatch structures produced for each quantifier
std::map< Node, inst::InstMatchTrie > d_sub_quant_inst_trie;
//children quantifiers for each quantifier, each is an instance
std::map< Node, std::vector< Node > > d_sub_quants;
//instances of each partial instantiation with respect to the root
std::map< Node, InstMatch > d_sub_quant_inst;
//*root* parent of each partial instantiation
std::map< Node, Node > d_sub_quant_parent;
protected:
//reset
void reset( FirstOrderModel* fm );
//initialize quantifiers, return number of lemmas produced, fp is the parent of quantifier f
int initializeQuantifier( Node f, Node fp );
//analyze quantifier
void analyzeQuantifier( FirstOrderModel* fm, Node f );
//do InstGen techniques for quantifier, return number of lemmas produced
int doInstGen( FirstOrderModel* fm, Node f );
//theory-specific build models
void constructModelUf( FirstOrderModel* fm, Node op );
private:
//get selection formula for quantifier body
Node getSelectionFormula( Node fn, Node n, bool polarity, int useOption );
//get a heuristic score for a selection formula
int getSelectionFormulaScore( Node fn );
//set selected terms in term
void setSelectedTerms( Node s );
//is usable selection literal
bool isUsableSelectionLiteral( Node n, int useOption );
//get parent quantifier match
void getParentQuantifierMatch( InstMatch& mp, Node fp, InstMatch& m, Node f );
public:
ModelEngineBuilderInstGen( context::Context* c, QuantifiersEngine* qe ) : ModelEngineBuilder( c, qe ){}
~ModelEngineBuilderInstGen(){}
// is term selected
bool isTermSelected( Node n ) { return d_term_selected.find( n )!=d_term_selected.end(); }
};
}/* CVC4::theory::quantifiers namespace */
}/* CVC4::theory namespace */
}/* CVC4 namespace */
#endif /* __CVC4__THEORY__QUANTIFIERS__MODEL_BUILDER_H */
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