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z3/src/sat/smt/sat_th.h
Nikolaj Bjorner 72d407a49f
mbp (#4741) 
* adding dt-solver

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* dt

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* move mbp to self-contained module

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* files

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* Create CMakeLists.txt

* dt

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* rename to bool_var2expr to indicate type class

* mbp

* na

* add projection

* na

* na

* na

* na

* na

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* deps

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>

* testing arith/q

* na

* newline for model printing

Signed-off-by: Nikolaj Bjorner <nbjorner@microsoft.com>
2020-10-21 15:48:40 -07:00

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/*++
Copyright (c) 2020 Microsoft Corporation
Module Name:
sat_th.h
Abstract:
Theory plugins
Author:
Nikolaj Bjorner (nbjorner) 2020-08-25
--*/
#pragma once
#include "util/top_sort.h"
#include "sat/smt/sat_smt.h"
#include "ast/euf/euf_egraph.h"
#include "model/model.h"
#include "smt/params/smt_params.h"
namespace euf {
class solver;
class th_internalizer {
protected:
euf::enode_vector m_args;
svector<sat::eframe> m_stack;
bool m_is_redundant{ false };
bool visit_rec(ast_manager& m, expr* e, bool sign, bool root, bool redundant);
virtual bool visit(expr* e) { return false; }
virtual bool visited(expr* e) { return false; }
virtual bool post_visit(expr* e, bool sign, bool root) { return false; }
public:
virtual ~th_internalizer() {}
virtual sat::literal internalize(expr* e, bool sign, bool root, bool redundant) = 0;
virtual void internalize(expr* e, bool redundant) = 0;
/**
\brief Apply (interpreted) sort constraints on the given enode.
*/
virtual void apply_sort_cnstr(enode* n, sort* s) {}
/**
\record that an equality has been internalized.
*/
virtual void eq_internalized(enode* n) {}
};
class th_decompile {
public:
virtual ~th_decompile() {}
virtual bool to_formulas(std::function<expr_ref(sat::literal)>& lit2expr, expr_ref_vector& fmls) { return false; }
};
class th_model_builder {
public:
virtual ~th_model_builder() {}
/**
\brief compute the value for enode \c n and store the value in \c values
for the root of the class of \c n.
*/
virtual void add_value(euf::enode* n, model& mdl, expr_ref_vector& values) {}
/**
\brief compute dependencies for node n
*/
virtual void add_dep(euf::enode* n, top_sort<euf::enode>& dep) { dep.insert(n, nullptr); }
/**
\brief should function be included in model.
*/
virtual bool include_func_interp(func_decl* f) const { return false; }
/**
\brief initialize model building
*/
virtual void init_model() {}
/**
\brief conclude model building
*/
virtual void finalize_model(model& mdl) {}
};
class th_solver : public sat::extension, public th_model_builder, public th_decompile, public th_internalizer {
protected:
ast_manager& m;
public:
th_solver(ast_manager& m, symbol const& name, euf::theory_id id) : extension(name, id), m(m) {}
virtual th_solver* clone(euf::solver& ctx) = 0;
virtual void new_eq_eh(euf::th_eq const& eq) {}
virtual bool use_diseqs() const { return false; }
virtual void new_diseq_eh(euf::th_eq const& eq) {}
/**
\brief Parametric theories (e.g. Arrays) should implement this method.
*/
virtual bool is_shared(theory_var v) const { return false; }
sat::status status() const { return sat::status::th(m_is_redundant, get_id()); }
};
class th_euf_solver : public th_solver {
protected:
solver& ctx;
euf::enode_vector m_var2enode;
unsigned_vector m_var2enode_lim;
unsigned m_num_scopes{ 0 };
smt_params const& get_config() const;
sat::literal expr2literal(expr* e) const;
region& get_region();
sat::status mk_status();
bool add_unit(sat::literal lit);
bool add_units(sat::literal_vector const& lits);
bool add_clause(sat::literal lit) { return add_unit(lit); }
bool add_clause(sat::literal a, sat::literal b);
bool add_clause(sat::literal a, sat::literal b, sat::literal c);
bool add_clause(sat::literal a, sat::literal b, sat::literal c, sat::literal d);
bool add_clause(sat::literal_vector const& lits);
void add_equiv(sat::literal a, sat::literal b);
void add_equiv_and(sat::literal a, sat::literal_vector const& bs);
bool is_true(sat::literal lit);
bool is_true(sat::literal a, sat::literal b) { return is_true(a) || is_true(b); }
bool is_true(sat::literal a, sat::literal b, sat::literal c) { return is_true(a) || is_true(b, c); }
bool is_true(sat::literal a, sat::literal b, sat::literal c, sat::literal d) { return is_true(a) || is_true(b, c, c); }
sat::literal eq_internalize(expr* a, expr* b);
euf::enode* e_internalize(expr* e);
euf::enode* mk_enode(expr* e, bool suppress_args = false);
expr_ref mk_eq(expr* e1, expr* e2);
expr_ref mk_var_eq(theory_var v1, theory_var v2) { return mk_eq(var2expr(v1), var2expr(v2)); }
void rewrite(expr_ref& a);
virtual void push_core();
virtual void pop_core(unsigned n);
void force_push() {
CTRACE("euf", m_num_scopes > 0, tout << "push-core " << m_num_scopes << "\n";);
for (; m_num_scopes > 0; --m_num_scopes) push_core();
}
friend class th_propagation;
public:
th_euf_solver(euf::solver& ctx, symbol const& name, euf::theory_id id);
virtual ~th_euf_solver() {}
virtual theory_var mk_var(enode* n);
unsigned get_num_vars() const { return m_var2enode.size(); }
enode* expr2enode(expr* e) const;
enode* var2enode(theory_var v) const { return m_var2enode[v]; }
expr* var2expr(theory_var v) const { return var2enode(v)->get_expr(); }
expr* bool_var2expr(sat::bool_var v) const;
enode* bool_var2enode(sat::bool_var v) const { expr* e = bool_var2expr(v); return e ? expr2enode(e) : nullptr; }
expr_ref literal2expr(sat::literal lit) const { expr* e = bool_var2expr(lit.var()); return lit.sign() ? expr_ref(m.mk_not(e), m) : expr_ref(e, m); }
sat::literal mk_literal(expr* e) const;
theory_var get_th_var(enode* n) const { return n->get_th_var(get_id()); }
theory_var get_th_var(expr* e) const;
trail_stack<euf::solver>& get_trail_stack();
bool is_attached_to_var(enode* n) const;
bool is_root(theory_var v) const { return var2enode(v)->is_root(); }
void push() override { m_num_scopes++; }
void pop(unsigned n) override;
};
class th_propagation {
unsigned m_num_literals;
unsigned m_num_eqs;
sat::literal* m_literals;
enode_pair* m_eqs;
static unsigned get_obj_size(unsigned num_lits, unsigned num_eqs);
th_propagation(unsigned n_lits, sat::literal const* lits, unsigned n_eqs, enode_pair const* eqs);
public:
static th_propagation* mk(th_euf_solver& th, sat::literal_vector const& lits, enode_pair_vector const& eqs);
static th_propagation* mk(th_euf_solver& th, unsigned n_lits, sat::literal const* lits, unsigned n_eqs, enode_pair const* eqs);
static th_propagation* mk(th_euf_solver& th, enode_pair_vector const& eqs);
static th_propagation* mk(th_euf_solver& th, sat::literal lit);
static th_propagation* mk(th_euf_solver& th, sat::literal lit, euf::enode* x, euf::enode* y);
static th_propagation* mk(th_euf_solver& th, euf::enode* x, euf::enode* y);
sat::ext_constraint_idx to_index() const {
return sat::constraint_base::mem2base(this);
}
static th_propagation& from_index(size_t idx) {
return *reinterpret_cast<th_propagation*>(sat::constraint_base::from_index(idx)->mem());
}
sat::extension& ext() const {
return *sat::constraint_base::to_extension(to_index());
}
std::ostream& display(std::ostream& out) const;
class lits {
th_propagation const& th;
public:
lits(th_propagation const& th) : th(th) {}
sat::literal const* begin() const { return th.m_literals; }
sat::literal const* end() const { return th.m_literals + th.m_num_literals; }
};
class eqs {
th_propagation const& th;
public:
eqs(th_propagation const& th) : th(th) {}
enode_pair const* begin() const { return th.m_eqs; }
enode_pair const* end() const { return th.m_eqs + th.m_num_eqs; }
};
};
}
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