z3-z3-4.13.0.src.math.lp.nla_solver.cpp Maven / Gradle / Ivy

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A self-unpacking, standalone Z3 distribution that ships all required native support code and automatically unpacks it at runtime.

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/*++
  Copyright (c) 2017 Microsoft Corporation

  Author:
    Lev Nachmanson (levnach)
    Nikolaj Bjorner (nbjorner)
  --*/
#include "math/lp/nla_solver.h"
#include 
#include "math/lp/monic.h"
#include "math/lp/lp_utils.h"
#include "math/lp/var_eqs.h"
#include "math/lp/factorization.h"
#include "math/lp/nla_solver.h"
#include "math/lp/nla_core.h"
#include "math/polynomial/algebraic_numbers.h"

namespace nla {
    void solver::add_monic(lpvar v, unsigned sz, lpvar const* vs) {
        m_core->add_monic(v, sz, vs);
    }

    void solver::add_idivision(lpvar q, lpvar x, lpvar y) {
        m_core->add_idivision(q, x, y);
    }

    void solver::add_rdivision(lpvar q, lpvar x, lpvar y) {
        m_core->add_rdivision(q, x, y);
    }

    void solver::add_bounded_division(lpvar q, lpvar x, lpvar y) {
        m_core->add_bounded_division(q, x, y);
    }

    void solver::set_relevant(std::function& is_relevant) {
        m_core->set_relevant(is_relevant);
    }
    
    bool solver::is_monic_var(lpvar v) const {
        return m_core->is_monic_var(v);
    }
    
    bool solver::need_check() { return m_core->has_relevant_monomial(); }
    
    lbool solver::check() {
        return m_core->check();
    }

    void solver::propagate() {
        m_core->propagate();
    }
    
    void solver::push(){
        m_core->push();
    }
    
    void solver::pop(unsigned n) {
        m_core->pop(n);
    }
    
    solver::solver(lp::lar_solver& s, params_ref const& p, reslimit& limit): 
        m_core(alloc(core, s, p, limit)) {
    }
    
    bool solver::influences_nl_var(lpvar j) const {    
        return m_core->influences_nl_var(j);
    }
    
    solver::~solver() {
        dealloc(m_core);
    }
    
    std::ostream& solver::display(std::ostream& out) const {    
        m_core->print_monics(out);
        if (use_nra_model()) 
            m_core->m_nra.display(out);
        return out;
    }
    
    bool solver::use_nra_model() const { return m_core->use_nra_model(); }

    core& solver::get_core() { return *m_core; }

    nlsat::anum_manager& solver::am() { return m_core->m_nra.am(); }

    nlsat::anum const& solver::am_value(lp::lpvar v) const {
        SASSERT(use_nra_model());
        return m_core->m_nra.value(v);
    }
    
    scoped_anum& solver::tmp1() {
        SASSERT(use_nra_model());
        return m_core->m_nra.tmp1();
    }

    scoped_anum& solver::tmp2() {
        SASSERT(use_nra_model());
        return m_core->m_nra.tmp2();
    }

    
    // ensure r = x^y, add abstraction/refinement lemmas
    lbool solver::check_power(lpvar r, lpvar x, lpvar y) {
        return m_core->check_power(r, x, y);
    }

    void solver::check_bounded_divisions() {
        m_core->check_bounded_divisions();
    }

    vector const& solver::lemmas() const {
        return m_core->lemmas();
    }
    
    vector const& solver::literals() const {
        return m_core->literals();
    }

    vector const& solver::equalities() const {
        return m_core->equalities();
    }

    vector const& solver::fixed_equalities() const {
        return m_core->fixed_equalities();
    }

}