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/********************* */
/*! \file sort_inference.h
** \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 Pre-process step for performing sort inference
**/
#include "cvc4_private.h"
#ifndef __CVC4__SORT_INFERENCE_H
#define __CVC4__SORT_INFERENCE_H
#include <iostream>
#include <string>
#include <vector>
#include <map>
#include "expr/node.h"
#include "expr/type_node.h"
namespace CVC4 {
class SortInference{
private:
//all subsorts
std::vector< int > d_sub_sorts;
std::map< int, bool > d_non_monotonic_sorts;
void recordSubsort( int s );
public:
class UnionFind {
public:
UnionFind(){}
UnionFind( UnionFind& c ){
set( c );
}
std::map< int, int > d_eqc;
//pairs that must be disequal
std::vector< std::pair< int, int > > d_deq;
void print(const char * c);
void clear() { d_eqc.clear(); d_deq.clear(); }
void set( UnionFind& c );
int getRepresentative( int t );
void setEqual( int t1, int t2 );
void setDisequal( int t1, int t2 ){ d_deq.push_back( std::pair< int, int >( t1, t2 ) ); }
bool areEqual( int t1, int t2 ) { return getRepresentative( t1 )==getRepresentative( t2 ); }
bool isValid();
};
private:
int sortCount;
int initialSortCount;
UnionFind d_type_union_find;
std::map< int, TypeNode > d_type_types;
std::map< TypeNode, int > d_id_for_types;
//for apply uf operators
std::map< Node, int > d_op_return_types;
std::map< Node, std::vector< int > > d_op_arg_types;
//for bound variables
std::map< Node, std::map< Node, int > > d_var_types;
//get representative
void setEqual( int t1, int t2 );
int getIdForType( TypeNode tn );
void printSort( const char* c, int t );
//process
int process( Node n, std::map< Node, Node >& var_bound );
//for monotonicity inference
private:
void processMonotonic( Node n, bool pol, bool hasPol, std::map< Node, Node >& var_bound );
//for rewriting
private:
//mapping from old symbols to new symbols
std::map< Node, Node > d_symbol_map;
//mapping from constants to new symbols
std::map< TypeNode, std::map< Node, Node > > d_const_map;
//number of subtypes generated
std::map< TypeNode, int > d_subtype_count;
//helper functions for simplify
TypeNode getOrCreateTypeForId( int t, TypeNode pref );
TypeNode getTypeForId( int t );
Node getNewSymbol( Node old, TypeNode tn );
//simplify
Node simplify( Node n, std::map< Node, Node >& var_bound );
public:
SortInference() : sortCount( 1 ){}
~SortInference(){}
void simplify( std::vector< Node >& assertions, bool doRewrite = false );
//get sort id for term n
int getSortId( Node n );
//get sort id for variable of quantified formula f
int getSortId( Node f, Node v );
//set that sk is the skolem variable of v for quantifier f
void setSkolemVar( Node f, Node v, Node sk );
public:
//is well sorted
bool isWellSortedFormula( Node n );
bool isWellSorted( Node n );
//get constraints for being well-typed according to computed sub-types
void getSortConstraints( Node n, SortInference::UnionFind& uf );
};
}
#endif
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