mirrors/z3
3
0
Fork 0
mirror of https://github.com/Z3Prover/z3 synced 2025-04-15 21:38:44 +00:00
Code Activity

use a simpler encoding for term indices

Browse source 
Signed-off-by: Lev Nachmanson <levnach@hotmail.com>
This commit is contained in:
Lev Nachmanson 2020-03-14 19:55:14 -07:00
parent 1c0e583abc
commit 8af245a410
10 changed files with 117 additions and 143 deletions
Show stats Download patch file Download diff file Expand all files Collapse all files

7
src/math/dd/pdd_interval.h
View file

@ -60,13 +60,6 @@ public:
m_dep_intervals.add(t, lo, ret);
}
}
// f meant to be called when the separation happens
template <typename T>
bool separated_from_zero(pdd const& p, u_dependency*& dep, std::function<void (const T)>& f) {
scoped_dep_interval i(m());
get_interval<w_dep::with_deps>(p, i);
return m_dep_intervals.check_interval_for_conflict_on_zero(i, dep, f);
}
};
}

1
src/math/lp/emonics.cpp
View file

@ -150,7 +150,6 @@ monic const* emonics::find_canonical(svector<lpvar> const& vars) const {
return result;
}
void emonics::remove_cg(lpvar v) {
cell* c = m_use_lists[v].m_head;
if (c == nullptr) {

2
src/math/lp/gomory.cpp
View file

@ -222,7 +222,7 @@ class create_cut {
}
for (const auto& p : m_t) {
unsigned v = p.var();
if (lia.lra.is_term(v)) {
if (lp::is_term(v)) {
dump_declaration(out, v);
}
}

3
src/math/lp/int_cube.cpp
View file

@ -57,8 +57,7 @@ namespace lp {
}
bool int_cube::tighten_term_for_cube(unsigned i) {
unsigned ti = i + lra.terms_start_index();
if (!lra.term_is_used_as_row(ti))
if (!lra.term_is_used_as_row(i))
return true;
const lar_term* t = lra.terms()[i];
impq delta = get_cube_delta_for_term(*t);

76
src/math/lp/lar_solver.cpp
View file

@ -25,9 +25,8 @@ lar_solver::lar_solver() : m_status(lp_status::UNKNOWN),
m_mpq_lar_core_solver(m_settings, *this),
m_int_solver(nullptr),
m_need_register_terms(false),
m_terms_start_index(1000000),
m_var_register(0),
m_term_register(m_terms_start_index),
m_var_register(false),
m_term_register(true),
m_constraints(*this)
{}
@ -46,16 +45,6 @@ lar_solver::~lar_solver(){
delete t;
}
bool lar_solver::is_term(var_index j) const {
return j >= m_terms_start_index && j - m_terms_start_index < m_terms.size();
}
unsigned lar_solver::adjust_term_index(unsigned j) const {
lp_assert(is_term(j));
return j - m_terms_start_index;
}
bool lar_solver::use_lu() const { return m_settings.simplex_strategy() == simplex_strategy_enum::lu; }
bool lar_solver::sizes_are_correct() const {
@ -72,7 +61,7 @@ std::ostream& lar_solver::print_implied_bound(const implied_bound& be, std::ostr
unsigned v = be.m_j;
if (is_term(v)) {
out << "it is a term number " << be.m_j << std::endl;
print_term(*m_terms[be.m_j - m_terms_start_index], out);
print_term(*m_terms[unmask_term(v)], out);
}
else {
out << get_variable_name(v);
@ -124,7 +113,7 @@ bool lar_solver::implied_bound_is_correctly_explained(implied_bound const & be,
}
rs_of_evidence /= ratio;
} else {
lar_term & t = *m_terms[adjust_term_index(be.m_j)];
lar_term & t = *m_terms[unmask_term(be.m_j)];
auto first_coeff = t.begin();
unsigned j = (*first_coeff).var();
auto it = coeff_map.find(j);
@ -206,7 +195,7 @@ unsigned lar_solver::adjust_column_index_to_term_index(unsigned j) const {
if (is_term(j))
return j;
unsigned ext_var_or_term = m_var_register.local_to_external(j);
return ext_var_or_term < m_terms_start_index ? j : ext_var_or_term;
return !is_term(ext_var_or_term) ? j : ext_var_or_term;
}
unsigned lar_solver::map_term_index_to_column_index(unsigned j) const {
@ -240,10 +229,10 @@ void lar_solver::explain_implied_bound(implied_bound & ib, lp_bound_propagator &
}
// lp_assert(implied_bound_is_correctly_explained(ib, explanation));
}
bool lar_solver::term_is_used_as_row(unsigned term) const {
lp_assert(is_term(term));
return m_var_register.external_is_used(term);
// here i is just the term index
bool lar_solver::term_is_used_as_row(unsigned i) const {
SASSERT(i < m_terms.size());
return m_var_register.external_is_used(mask_term(i));
}
void lar_solver::propagate_bounds_on_terms(lp_bound_propagator & bp) {
@ -640,8 +629,8 @@ lp_status lar_solver::maximize_term(unsigned j_or_term,
const lar_term & lar_solver::get_term(unsigned j) const {
lp_assert(j >= m_terms_start_index);
return *m_terms[j - m_terms_start_index];
lp_assert(is_term(j));
return *m_terms[unmask_term(j)];
}
void lar_solver::pop_core_solver_params() {
@ -684,7 +673,7 @@ void lar_solver::substitute_terms_in_linear_expression(const vector<std::pair<mp
if (!is_term(j)) {
register_monoid_in_map(coeffs, t.first, j);
} else {
const lar_term & term = * m_terms[adjust_term_index(t.second)];
const lar_term & term = * m_terms[unmask_term(t.second)];
for (auto p : term){
register_monoid_in_map(coeffs, t.first * p.coeff() , p.var());
@ -908,13 +897,10 @@ bool lar_solver::x_is_correct() const {
}
bool lar_solver::var_is_registered(var_index vj) const {
if (vj >= m_terms_start_index) {
if (vj - m_terms_start_index >= m_terms.size())
return false;
} else if ( vj >= A_r().column_count()) {
return false;
if (is_term(vj)) {
return unmask_term(vj) < m_terms.size();
}
return true;
return vj < A_r().column_count();
}
@ -1266,7 +1252,7 @@ void lar_solver::set_variable_name(var_index vi, std::string name) {
}
std::string lar_solver::get_variable_name(var_index j) const {
if (j >= m_terms_start_index)
if (is_term(j))
return std::string("_t") + T_to_string(j);
if (j >= m_var_register.size())
return std::string("_s") + T_to_string(j);
@ -1338,8 +1324,8 @@ mpq lar_solver::get_left_side_val(const lar_base_constraint & cns, const std::u
void lar_solver::fill_var_set_for_random_update(unsigned sz, var_index const * vars, vector<unsigned>& column_list) {
for (unsigned i = 0; i < sz; i++) {
var_index var = vars[i];
if (var >= m_terms_start_index) { // handle the term
for (auto it : *m_terms[var - m_terms_start_index]) {
if (is_term(var)) { // handle the term
for (auto it : *m_terms[unmask_term(var)]) {
column_list.push_back(it.var());
}
} else {
@ -1584,7 +1570,7 @@ var_index lar_solver::add_named_var(unsigned ext_j, bool is_int, const std::stri
var_index lar_solver::add_var(unsigned ext_j, bool is_int) {
TRACE("add_var", tout << "adding var " << ext_j << (is_int? " int" : " nonint") << std::endl;);
var_index local_j;
lp_assert(ext_j < m_terms_start_index);
lp_assert(!is_term(ext_j));
if (m_var_register.external_is_used(ext_j, local_j))
return local_j;
lp_assert(m_columns_to_ul_pairs.size() == A_r().column_count());
@ -1662,7 +1648,7 @@ void lar_solver::add_new_var_to_core_fields_for_mpq(bool register_in_basis) {
var_index lar_solver::add_term_undecided(const vector<std::pair<mpq, var_index>> & coeffs) {
push_term(new lar_term(coeffs));
return m_terms_start_index + m_terms.size() - 1;
return mask_term(m_terms.size() - 1);
}
#if Z3DEBUG_CHECK_UNIQUE_TERMS
@ -1718,7 +1704,7 @@ var_index lar_solver::add_term(const vector<std::pair<mpq, var_index>> & coeffs,
push_term(t);
SASSERT(m_terms.size() == m_term_register.size());
unsigned adjusted_term_index = m_terms.size() - 1;
var_index ret = m_terms_start_index + adjusted_term_index;
var_index ret = mask_term(adjusted_term_index);
if (use_tableau() && !coeffs.empty()) {
add_row_from_term_no_constraint(m_terms.back(), ret);
if (m_settings.bound_propagation())
@ -1852,7 +1838,7 @@ void lar_solver::update_column_type_and_bound(var_index j, lconstraint_kind kind
constraint_index lar_solver::add_var_bound_on_constraint_for_term(var_index j, lconstraint_kind kind, const mpq & right_side) {
lp_assert(is_term(j));
unsigned adjusted_term_index = adjust_term_index(j);
unsigned adjusted_term_index = unmask_term(j);
// lp_assert(!term_is_int(m_terms[adjusted_term_index]) || right_side.is_int());
unsigned term_j;
lar_term const* term = m_terms[adjusted_term_index];
@ -1932,9 +1918,9 @@ void lar_solver::adjust_initial_state_for_lu() {
void lar_solver::adjust_initial_state_for_tableau_rows() {
for (unsigned i = 0; i < m_terms.size(); i++) {
if (m_var_register.external_is_used(i + m_terms_start_index))
if (m_var_register.external_is_used(mask_term(i)))
continue;
add_row_from_term_no_constraint(m_terms[i], i + m_terms_start_index);
add_row_from_term_no_constraint(m_terms[i], mask_term(i));
}
}
@ -2176,7 +2162,7 @@ void lar_solver::update_bound_with_no_ub_no_lb(var_index j, lconstraint_kind kin
}
bool lar_solver::column_corresponds_to_term(unsigned j) const {
return m_var_register.local_to_external(j) >= m_terms_start_index;
return is_term(m_var_register.local_to_external(j));
}
var_index lar_solver::to_column(unsigned ext_j) const {
@ -2184,7 +2170,8 @@ var_index lar_solver::to_column(unsigned ext_j) const {
}
bool lar_solver::tighten_term_bounds_by_delta(unsigned term_index, const impq& delta) {
unsigned tj = term_index + m_terms_start_index;
SASSERT(!is_term(term_index));
unsigned tj = mask_term(term_index);
unsigned j;
if (m_var_register.external_is_used(tj, j) == false)
return true; // the term is not a column so it has no bounds
@ -2242,8 +2229,7 @@ void lar_solver::round_to_integer_solution() {
void lar_solver::fix_terms_with_rounded_columns() {
for (unsigned i = 0; i < m_terms.size(); i++) {
unsigned ti = i + terms_start_index();
if (!term_is_used_as_row(ti))
if (!term_is_used_as_row(i))
continue;
bool need_to_fix = false;
const lar_term & t = *m_terms[i];
@ -2254,7 +2240,7 @@ void lar_solver::fix_terms_with_rounded_columns() {
}
}
if (need_to_fix) {
lpvar j = external_to_local(ti);
lpvar j = m_var_register.external_to_local(mask_term(i));
impq v = t.apply(m_mpq_lar_core_solver.m_r_x);
m_mpq_lar_core_solver.m_r_solver.update_x(j, v);
}
@ -2274,7 +2260,7 @@ bool lar_solver::sum_first_coords(const lar_term& t, mpq & val) const {
}
bool lar_solver::get_equality_and_right_side_for_term_on_current_x(unsigned term_index, mpq & rs, constraint_index& ci, bool &upper_bound) const {
unsigned tj = term_index + m_terms_start_index;
unsigned tj = mask_term(term_index);
unsigned j;
bool is_int;
if (m_var_register.external_is_used(tj, j, is_int) == false)
@ -2349,7 +2335,7 @@ void lar_solver::register_existing_terms() {
if (!m_need_register_terms) {
TRACE("nla_solver", tout << "registering " << m_terms.size() << " terms\n";);
for (unsigned k = 0; k < m_terms.size(); k++) {
lpvar j = m_var_register.external_to_local(k + m_terms_start_index);
lpvar j = m_var_register.external_to_local(mask_term(k));
register_normalized_term(*m_terms[k], j);
}
}

12
src/math/lp/lar_solver.h
View file

@ -89,7 +89,6 @@ private:
int_solver * m_int_solver;
bool m_need_register_terms;
public:
const var_index m_terms_start_index;
var_register m_var_register;
var_register m_term_register;
stacked_vector<ul_pair> m_columns_to_ul_pairs;
@ -109,7 +108,6 @@ public:
m_normalized_terms_to_columns;
// end of fields
unsigned terms_start_index() const { return m_terms_start_index; }
const vector<lar_term*> & terms() const { return m_terms; }
lar_term const& term(unsigned i) const { return *m_terms[i]; }
constraint_set const& constraints() const { return m_constraints; }
@ -144,7 +142,6 @@ public:
return m_mpq_lar_core_solver.m_r_x[j].x;
}
bool is_term(var_index j) const;
bool column_is_fixed(unsigned j) const;
bool column_is_free(unsigned j) const;
public:
@ -246,9 +243,6 @@ public:
virtual ~lar_solver();
unsigned adjust_term_index(unsigned j) const;
bool use_lu() const;
bool sizes_are_correct() const;
@ -591,15 +585,15 @@ public:
t.subst_index(p.first, p.second);
}
}
std::ostream& print_column_info(unsigned j, std::ostream& out) const {
m_mpq_lar_core_solver.m_r_solver.print_column_info(j, out);
if (is_term(j)) {
const lar_term& t = * m_terms[j - m_terms_start_index];
const lar_term& t = * m_terms[unmask_term(j)];
print_term_as_indices(t, out) << "\n";
} else if(column_corresponds_to_term(j)) {
const lar_term& t = * m_terms[m_var_register.local_to_external(j) - m_terms_start_index];
const lar_term& t = * m_terms[unmask_term(m_var_register.local_to_external(j))];
print_term_as_indices(t, out) << "\n";
}
return out;

17
src/math/lp/nla_core.cpp
View file

@ -66,7 +66,7 @@ lp::lar_term core::subs_terms_to_columns(const lp::lar_term& t) const {
lp::lar_term r;
for (const auto& p : t) {
lpvar j = p.var();
if (m_lar_solver.is_term(j))
if (lp::is_term(j))
j = m_lar_solver.map_term_index_to_column_index(j);
r.add_monomial(p.coeff(), j);
}
@ -133,7 +133,7 @@ void core::add_monic(lpvar v, unsigned sz, lpvar const* vs) {
m_add_buffer.resize(sz);
for (unsigned i = 0; i < sz; i++) {
lpvar j = vs[i];
if (m_lar_solver.is_term(j))
if (lp::is_term(j))
j = m_lar_solver.map_term_index_to_column_index(j);
m_add_buffer[i] = j;
}
@ -840,10 +840,9 @@ void core::collect_equivs() {
const lp::lar_solver& s = m_lar_solver;
for (unsigned i = 0; i < s.terms().size(); i++) {
unsigned ti = i + s.terms_start_index();
if (!s.term_is_used_as_row(ti))
if (!s.term_is_used_as_row(i))
continue;
lpvar j = s.external_to_local(ti);
lpvar j = s.external_to_local(lp::mask_term(i));
if (var_is_fixed_to_zero(j)) {
TRACE("nla_solver_eq", tout << "term = "; s.print_term_as_indices(*s.terms()[i], tout););
add_equivalence_maybe(s.terms()[i], s.get_column_upper_bound_witness(j), s.get_column_lower_bound_witness(j));
@ -1364,8 +1363,8 @@ lbool core::test_check(
}
std::ostream& core::print_terms(std::ostream& out) const {
for (unsigned i=0; i< m_lar_solver.m_terms.size(); i++) {
unsigned ext = i + m_lar_solver.terms_start_index();
for (unsigned i = 0; i< m_lar_solver.m_terms.size(); i++) {
unsigned ext = lp::mask_term(i);
if (!m_lar_solver.var_is_registered(ext)) {
out << "term is not registered\n";
continue;
@ -1716,8 +1715,8 @@ bool core::is_nl_var(lpvar j) const {
bool core::influences_nl_var(lpvar j) const {
if (m_lar_solver.is_term(j))
j = m_lar_solver.adjust_term_index(j);
if (lp::is_term(j))
j = lp::unmask_term(j);
if (is_nl_var(j))
return true;
for (const auto & c : m_lar_solver.A_r().m_columns[j]) {

30
src/math/lp/var_register.h
View file

@ -18,6 +18,15 @@ Revision History:
--*/
#pragma once
namespace lp {
const unsigned EF = UINT_MAX >> 1;
const unsigned left_most_bit = ~EF;
inline unsigned unmask_term(unsigned j) { return j & EF; }
inline bool is_term(unsigned j) { return j & left_most_bit; }
inline unsigned mask_term(unsigned j) { return j | left_most_bit; }
class ext_var_info {
unsigned m_external_j;
bool m_is_integer;
@ -37,9 +46,10 @@ public:
class var_register {
svector<ext_var_info> m_local_to_external;
std::unordered_map<unsigned, unsigned> m_external_to_local;
unsigned m_local_offset;
unsigned m_locals_mask;
unsigned m_locals_mask_inverted;
public:
var_register(unsigned offset) : m_local_offset(offset) {}
var_register(bool mask_locals): m_locals_mask(mask_locals? left_most_bit: 0), m_locals_mask_inverted(~m_locals_mask) {}
void set_name(unsigned j, std::string name) {
m_local_to_external[j].set_name(name);
@ -58,7 +68,7 @@ public:
}
m_local_to_external.push_back(ext_var_info(user_var, is_int));
unsigned local = size() - 1 + m_local_offset;
unsigned local = ( size() - 1 ) | m_locals_mask;
if (user_var != UINT_MAX)
m_external_to_local[user_var] = local;
@ -75,11 +85,7 @@ public:
// returns UINT_MAX if
unsigned local_to_external(unsigned local_var) const {
if (local_var == UINT_MAX)
return UINT_MAX;
if (local_var < m_local_offset)
return UINT_MAX;
unsigned k = local_var - m_local_offset;
unsigned k = local_var & m_locals_mask_inverted;
if (k >= m_local_to_external.size())
return UINT_MAX;
return m_local_to_external[k].external_j();
@ -119,16 +125,14 @@ public:
local_j = UINT_MAX;
return false;
}
local_j = it->second;
SASSERT(local_j >= m_local_offset);
is_int = m_local_to_external[local_j - m_local_offset].is_integer();
local_j = it->second & m_locals_mask_inverted;
is_int = m_local_to_external[local_j].is_integer();
return true;
}
bool local_is_int(unsigned j) const {
SASSERT(j >= m_local_offset);
return m_local_to_external[j - m_local_offset].is_integer();
return m_local_to_external[j & m_locals_mask_inverted].is_integer();
}
void shrink(unsigned shrunk_size) {

44
src/smt/theory_lra.cpp
View file

@ -965,7 +965,7 @@ class theory_lra::imp {
}
SASSERT(!m_left_side.empty());
vi = lp().add_term(m_left_side, v);
SASSERT (lp().is_term(vi));
SASSERT (lp::is_term(vi));
TRACE("arith_verbose", tout << "v" << v << " := " << mk_pp(term, m) << " slack: " << vi << " scopes: " << m_scopes.size() << "\n";
lp().print_term(lp().get_term(vi), tout) << "\n";);
}
@ -1480,7 +1480,7 @@ public:
lp::impq get_ivalue(theory_var v) const {
SASSERT(can_get_ivalue(v));
lpvar vi = get_lpvar(v);
if (!lp().is_term(vi))
if (!lp::is_term(vi))
return lp().get_column_value(vi);
m_todo_terms.push_back(std::make_pair(vi, rational::one()));
lp::impq result(0);
@ -1488,7 +1488,7 @@ public:
vi = m_todo_terms.back().first;
rational coeff = m_todo_terms.back().second;
m_todo_terms.pop_back();
if (lp().is_term(vi)) {
if (lp::is_term(vi)) {
const lp::lar_term& term = lp().get_term(vi);
for (const auto & i: term) {
m_todo_terms.push_back(std::make_pair(i.var(), coeff * i.coeff()));
@ -1510,7 +1510,7 @@ public:
if (m_variable_values.count(vi) > 0)
return m_variable_values[vi];
if (!lp().is_term(vi)) {
if (!lp::is_term(vi)) {
return rational::zero();
}
@ -1520,7 +1520,7 @@ public:
lpvar wi = m_todo_terms.back().first;
rational coeff = m_todo_terms.back().second;
m_todo_terms.pop_back();
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
const lp::lar_term& term = lp().get_term(wi);
for (const auto & i : term) {
if (m_variable_values.count(i.var()) > 0) {
@ -1921,7 +1921,7 @@ public:
expr_ref_vector ts(m);
for (auto const& p : term) {
lpvar wi = p.var();
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
ts.push_back(multerm(p.coeff(), term2expr(lp().get_term(wi))));
}
else {
@ -1964,7 +1964,7 @@ public:
for (auto const& p : term) {
lpvar wi = p.var();
out << p.coeff() << " * ";
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
lp().print_term(lp().get_term(wi), out) << "\n";
}
else {
@ -2755,7 +2755,7 @@ public:
void add_use_lists(lp_api::bound* b) {
theory_var v = b->get_var();
lpvar vi = register_theory_var_in_lar_solver(v);
if (!lp().is_term(vi)) {
if (!lp::is_term(vi)) {
return;
}
m_todo_vars.push_back(vi);
@ -2765,7 +2765,7 @@ public:
lp::lar_term const& term = lp().get_term(vi);
for (auto const& p : term) {
lpvar wi = p.var();
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
m_todo_vars.push_back(wi);
}
else {
@ -2780,7 +2780,7 @@ public:
void del_use_lists(lp_api::bound* b) {
theory_var v = b->get_var();
lpvar vi = get_lpvar(v);
if (!lp().is_term(vi)) {
if (!lp::is_term(vi)) {
return;
}
m_todo_vars.push_back(vi);
@ -2790,7 +2790,7 @@ public:
lp::lar_term const& term = lp().get_term(vi);
for (auto const& coeff : term) {
lpvar wi = coeff.var();
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
m_todo_vars.push_back(wi);
}
else {
@ -2877,14 +2877,14 @@ public:
r.reset();
theory_var v = b.get_var();
lpvar vi = get_lpvar(v);
SASSERT(m_solver->is_term(vi));
SASSERT(lp::is_term(vi));
lp::lar_term const& term = m_solver->get_term(vi);
for (auto const mono : term) {
lp::var_index wi = mono.var();
lp::constraint_index ci;
rational value;
bool is_strict;
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
return false;
}
if (mono.coeff().is_neg() == is_lub) {
@ -3033,8 +3033,8 @@ public:
bool set_bound(lpvar vi, lp::constraint_index ci, rational const& v, bool is_lower) {
if (lp().is_term(vi)) {
lpvar ti = lp().adjust_term_index(vi);
if (lp::is_term(vi)) {
lpvar ti = lp::unmask_term(vi);
auto& vec = is_lower ? m_lower_terms : m_upper_terms;
if (vec.size() <= ti) {
vec.resize(ti + 1, constraint_bound(UINT_MAX, rational()));
@ -3081,7 +3081,7 @@ public:
bool has_lower_bound(lpvar vi, lp::constraint_index& ci, rational const& bound) { return has_bound(vi, ci, bound, true); }
bool has_bound(lpvar vi, lp::constraint_index& ci, rational const& bound, bool is_lower) {
if (lp().is_term(vi)) {
if (lp::is_term(vi)) {
theory_var v = lp().local_to_external(vi);
rational val;
TRACE("arith", tout << vi << " " << v << "\n";);
@ -3091,7 +3091,7 @@ public:
}
auto& vec = is_lower ? m_lower_terms : m_upper_terms;
lpvar ti = lp().adjust_term_index(vi);
lpvar ti = lp::unmask_term(vi);
if (vec.size() > ti) {
constraint_bound& b = vec[ti];
ci = b.first;
@ -3327,7 +3327,7 @@ public:
SASSERT(m_nra);
SASSERT(m_use_nra_model);
lpvar vi = get_lpvar(v);
if (lp().is_term(vi)) {
if (lp::is_term(vi)) {
m_todo_terms.push_back(std::make_pair(vi, rational::one()));
@ -3348,7 +3348,7 @@ public:
for (auto const & arg : term) {
lpvar wi = arg.var();
c1 = arg.coeff() * wcoeff;
if (lp().is_term(wi)) {
if (lp::is_term(wi)) {
m_todo_terms.push_back(std::make_pair(wi, c1));
}
else {
@ -3616,8 +3616,8 @@ public:
void term2coeffs(lp::lar_term const& term, u_map<rational>& coeffs, rational const& coeff) {
for (const auto & ti : term) {
theory_var w;
if (lp().is_term(ti.var())) {
//w = m_term_index2theory_var.get(lp().adjust_term_index(ti.m_key), null_theory_var);
if (lp::is_term(ti.var())) {
//w = m_term_index2theory_var.get(lp::unmask_term(ti.m_key), null_theory_var);
//if (w == null_theory_var) // if extracting expressions directly from nested term
lp::lar_term const& term1 = lp().get_term(ti.var());
rational coeff2 = coeff * ti.coeff();
@ -3685,7 +3685,7 @@ public:
app_ref mk_obj(theory_var v) {
lpvar vi = get_lpvar(v);
bool is_int = a.is_int(get_enode(v)->get_owner());
if (lp().is_term(vi)) {
if (lp::is_term(vi)) {
return mk_term(lp().get_term(vi), is_int);
}
else {

68
src/test/lp/nla_solver_test.cpp
View file

@ -193,9 +193,9 @@ void test_basic_lemma_for_mon_neutral_from_factors_to_monomial_0() {
s.set_column_value(lp_bde, lp::impq(rational(16)));
SASSERT(nla.get_core()->test_check(lv) == l_false);
SASSERT(nla.get_core().test_check(lv) == l_false);
nla.get_core()->print_lemma(std::cout);
nla.get_core().print_lemma(std::cout);
ineq i0(llc::NE, lp::lar_term(), rational(1));
i0.m_term.add_var(lp_ac);
@ -259,9 +259,9 @@ void test_basic_lemma_for_mon_neutral_from_factors_to_monomial_1() {
s_set_column_value(s, lp_e, rational(1));
s_set_column_value(s, lp_bde, rational(3));
SASSERT(nla.get_core()->test_check(lemma) == l_false);
SASSERT(nla.get_core().test_check(lemma) == l_false);
SASSERT(lemma[0].size() == 4);
nla.get_core()->print_lemma(std::cout);
nla.get_core().print_lemma(std::cout);
ineq i0(llc::NE, lp::lar_term(), rational(1));
i0.m_term.add_var(lp_b);
@ -343,8 +343,8 @@ void test_basic_lemma_for_mon_zero_from_factors_to_monomial() {
s_set_column_value(s, lp_acd, rational(1));
s_set_column_value(s, lp_be, rational(1));
SASSERT(nla.get_core()->test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core().print_lemma(std::cout);
SASSERT(lemma.size() == 1 && lemma[0].size() == 2);
ineq i0(llc::NE, lp::lar_term(), rational(0));
i0.m_term.add_var(lp_b);
@ -392,9 +392,9 @@ void test_basic_lemma_for_mon_zero_from_monomial_to_factors() {
s_set_column_value(s, lp_d, rational(1));
s_set_column_value(s, lp_acd, rational(0));
SASSERT(nla.get_core()->test_check(lemma) == l_false);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
nla.get_core().print_lemma(std::cout);
ineq i0(llc::EQ, lp::lar_term(), rational(0));
i0.m_term.add_var(lp_a);
@ -471,10 +471,10 @@ void test_basic_lemma_for_mon_neutral_from_monomial_to_factors() {
s_set_column_value(s, lp_b, - rational(2));
// we have bde = -b, therefore d = +-1 and e = +-1
s_set_column_value(s, lp_d, rational(3));
SASSERT(nla.get_core()->test_check(lemma) == l_false);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
nla.get_core().print_lemma(std::cout);
ineq i0(llc::EQ, lp::lar_term(), rational(1));
i0.m_term.add_var(lp_d);
ineq i1(llc::EQ, lp::lar_term(), -rational(1));
@ -587,14 +587,14 @@ void test_basic_sign_lemma() {
s_set_column_value(s, lp_acd, rational(3));
vector<lemma> lemmas;
SASSERT(nla.get_core()->test_check(lemmas) == l_false);
SASSERT(nla.get_core().test_check(lemmas) == l_false);
lp::lar_term t;
t.add_var(lp_bde);
t.add_var(lp_acd);
ineq q(llc::EQ, t, rational(0));
nla.get_core()->print_lemma(std::cout);
nla.get_core().print_lemma(std::cout);
}
void test_order_lemma_params(bool var_equiv, int sign) {
@ -686,10 +686,10 @@ void test_order_lemma_params(bool var_equiv, int sign) {
s_set_column_value(s, lp_k, s.get_column_value(lp_j));
}
// set the values of ab, ef, cd, and ij correctly
s_set_column_value(s, lp_ab, nla.get_core()->mon_value_by_vars(mon_ab));
s_set_column_value(s, lp_ef, nla.get_core()->mon_value_by_vars(mon_ef));
s_set_column_value(s, lp_cd, nla.get_core()->mon_value_by_vars(mon_cd));
s_set_column_value(s, lp_ij, nla.get_core()->mon_value_by_vars(mon_ij));
s_set_column_value(s, lp_ab, nla.get_core().mon_value_by_vars(mon_ab));
s_set_column_value(s, lp_ef, nla.get_core().mon_value_by_vars(mon_ef));
s_set_column_value(s, lp_cd, nla.get_core().mon_value_by_vars(mon_cd));
s_set_column_value(s, lp_ij, nla.get_core().mon_value_by_vars(mon_ij));
// set abef = cdij, while it has to be abef < cdij
if (sign > 0) {
@ -697,27 +697,27 @@ void test_order_lemma_params(bool var_equiv, int sign) {
// we have ab < cd
// we need to have ab*ef < cd*ij, so let us make ab*ef > cd*ij
s_set_column_value(s, lp_cdij, nla.get_core()->mon_value_by_vars(mon_cdij));
s_set_column_value(s, lp_abef, nla.get_core()->mon_value_by_vars(mon_cdij)
s_set_column_value(s, lp_cdij, nla.get_core().mon_value_by_vars(mon_cdij));
s_set_column_value(s, lp_abef, nla.get_core().mon_value_by_vars(mon_cdij)
+ rational(1));
}
else {
SASSERT(-s.get_column_value(lp_ab) < s.get_column_value(lp_cd));
// we need to have abef < cdij, so let us make abef < cdij
s_set_column_value(s, lp_cdij, nla.get_core()->mon_value_by_vars(mon_cdij));
s_set_column_value(s, lp_abef, nla.get_core()->mon_value_by_vars(mon_cdij)
s_set_column_value(s, lp_cdij, nla.get_core().mon_value_by_vars(mon_cdij));
s_set_column_value(s, lp_abef, nla.get_core().mon_value_by_vars(mon_cdij)
+ rational(1));
}
vector<lemma> lemma;
SASSERT(nla.get_core()->test_check(lemma) == l_false);
SASSERT(nla.get_core().test_check(lemma) == l_false);
// lp::lar_term t;
// t.add_monomial(lp_bde);
// t.add_monomial(lp_acd);
// ineq q(llc::EQ, t, rational(0));
nla.get_core()->print_lemma(std::cout);
nla.get_core().print_lemma(std::cout);
// SASSERT(q == lemma.back());
// ineq i0(llc::EQ, lp::lar_term(), rational(0));
// i0.m_term.add_monomial(lp_bde);
@ -787,16 +787,16 @@ void test_monotone_lemma() {
s_set_column_value(s, lp_f, s.get_column_value(lp_j) +lp::impq( rational(1)));
// set the values of ab, ef, cd, and ij correctly
s_set_column_value(s, lp_ab, nla.get_core()->mon_value_by_vars(mon_ab));
s_set_column_value(s, lp_cd, nla.get_core()->mon_value_by_vars(mon_cd));
s_set_column_value(s, lp_ij, nla.get_core()->mon_value_by_vars(mon_ij));
s_set_column_value(s, lp_ab, nla.get_core().mon_value_by_vars(mon_ab));
s_set_column_value(s, lp_cd, nla.get_core().mon_value_by_vars(mon_cd));
s_set_column_value(s, lp_ij, nla.get_core().mon_value_by_vars(mon_ij));
// set ef = ij while it has to be ef > ij
s_set_column_value(s, lp_ef, s.get_column_value(lp_ij));
vector<lemma> lemma;
SASSERT(nla.get_core()->test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core().print_lemma(std::cout);
*/
}
@ -824,8 +824,8 @@ void test_tangent_lemma_rat() {
nla.add_monic(lp_ab, vec.size(), vec.begin());
vector<lemma> lemma;
SASSERT(nla.get_core()->test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core().print_lemma(std::cout);
}
void test_tangent_lemma_reg() {
@ -851,8 +851,8 @@ void test_tangent_lemma_reg() {
nla.add_monic(lp_ab, vec.size(), vec.begin());
vector<lemma> lemma;
SASSERT(nla.get_core()->test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core().print_lemma(std::cout);
}
void test_tangent_lemma_equiv() {
@ -894,11 +894,11 @@ void test_tangent_lemma_equiv() {
vec.push_back(lp_b);
int mon_ab = nla.add_monic(lp_ab, vec.size(), vec.begin());
s_set_column_value(s, lp_ab, nla.get_core()->mon_value_by_vars(mon_ab) + rational(10)); // greater by ten than the correct value
s_set_column_value(s, lp_ab, nla.get_core().mon_value_by_vars(mon_ab) + rational(10)); // greater by ten than the correct value
vector<lemma> lemma;
SASSERT(nla.get_core()->test_check(lemma) == l_false);
nla.get_core()->print_lemma(std::cout);
SASSERT(nla.get_core().test_check(lemma) == l_false);
nla.get_core().print_lemma(std::cout);
*/
}