Copyright (c) 2017 Microsoft Corporation
Module Name:
hnf_cutter.cpp
Author:
Lev Nachmanson (levnach)
--*/
#include "math/lp/int_solver.h"
#include "math/lp/lar_solver.h"
#include "math/lp/hnf_cutter.h"
namespace lp {
hnf_cutter::hnf_cutter(int_solver& lia):
lia(lia),
lra(lia.lra),
m_settings(lia.settings()),
m_abs_max(zero_of_type<mpq>()),
m_var_register(0) {}
bool hnf_cutter::is_full() const {
return
terms_count() >= lia.settings().limit_on_rows_for_hnf_cutter ||
vars().size() >= lia.settings().limit_on_columns_for_hnf_cutter;
}
void hnf_cutter::clear() {
m_var_register.clear();
m_terms.clear();
m_terms_upper.clear();
m_constraints_for_explanation.clear();
m_right_sides.clear();
m_abs_max = zero_of_type<mpq>();
m_overflow = false;
}
void hnf_cutter::add_term(const lar_term* t, const mpq &rs, constraint_index ci, bool upper_bound) {
m_terms.push_back(t);
m_terms_upper.push_back(upper_bound);
if (upper_bound)
m_right_sides.push_back(rs);
else
m_right_sides.push_back(-rs);
m_constraints_for_explanation.push_back(ci);
for (lar_term::ival p : *t) {
m_var_register.add_var(p.column().index(), true);
mpq t = abs(ceil(p.coeff()));
if (t > m_abs_max)
m_abs_max = t;
}
}
void hnf_cutter::print(std::ostream & out) {
out << "terms = " << m_terms.size() << ", var = " << m_var_register.size() << std::endl;
}
void hnf_cutter::initialize_row(unsigned i) {
mpq sign = m_terms_upper[i]? one_of_type<mpq>(): - one_of_type<mpq>();
m_A.init_row_from_container(i, * m_terms[i], [this](unsigned j) { return m_var_register.add_var(j, true);}, sign);
}
void hnf_cutter::init_matrix_A() {
m_A = general_matrix(terms_count(), vars().size());
for (unsigned i = 0; i < terms_count(); i++)
initialize_row(i);
}
void hnf_cutter::find_h_minus_1_b(const general_matrix& H, vector<mpq> & b) {
for (unsigned i = 0; i < H.row_count() ;i++) {
for (unsigned j = 0; j < i; j++) {
b[i] -= H[i][j]*b[j];
}
b[i] /= H[i][i];
}
}
vector<mpq> hnf_cutter::create_b(const svector<unsigned> & basis_rows) {
if (basis_rows.size() == m_right_sides.size())
return m_right_sides;
vector<mpq> b;
for (unsigned i : basis_rows) {
b.push_back(m_right_sides[i]);
}
return b;
}
int hnf_cutter::find_cut_row_index(const vector<mpq> & b) {
int ret = -1;
int n = 0;
for (int i = 0; i < static_cast<int>(b.size()); i++) {
if (is_integer(b[i])) continue;
if (n == 0 ) {
lp_assert(ret == -1);
n = 1;
ret = i;
} else {
if (m_settings.random_next() % (++n) == 0) {
ret = i;
}
}
}
return ret;
}
void hnf_cutter::get_ei_H_minus_1(unsigned i, const general_matrix& H, vector<mpq> & row) {
unsigned m = H.row_count();
for (unsigned k = i + 1; k < m; k++) {
row[k] = zero_of_type<mpq>();
}
row[i] = one_of_type<mpq>() / H[i][i];
for(int k = i - 1; k >= 0; k--) {
mpq t = zero_of_type<mpq>();
for (unsigned l = k + 1; l <= i; l++) {
t += H[l][k]*row[l];
}
row[k] = -t / H[k][k];
}
}
void hnf_cutter::fill_term(const vector<mpq> & row, lar_term& t) {
for (unsigned j = 0; j < row.size(); j++) {
if (!is_zero(row[j]))
t.add_monomial(row[j], m_var_register.local_to_external(j));
}
}
#ifdef Z3DEBUG
vector<mpq> hnf_cutter::transform_to_local_columns(const vector<impq> & x) const {
vector<mpq> ret;
for (unsigned j = 0; j < vars().size(); j++) {
ret.push_back(x[m_var_register.local_to_external(j)].x);
}
return ret;
}
#endif
void hnf_cutter::shrink_explanation(const svector<unsigned>& basis_rows) {
svector<unsigned> new_expl;
for (unsigned i : basis_rows) {
new_expl.push_back(m_constraints_for_explanation[i]);
}
m_constraints_for_explanation = new_expl;
}
bool hnf_cutter::overflow() const { return m_overflow; }
Here is the citation from "Cutting the Mix" by Jürgen Christ and Jochen Hoenicke.
The algorithm is based on the Simplex algorithm. The solution space
forms a polyhedron in Q^n . If the solution space is non-empty, the
Simplex algorithm returns a solution of Ax <= b . We further assume
that the returned solution x0 is a vertex of the polyhedron, i. e.,
there is a nonsingular square submatrix A′ and a corresponding
vector b′ , such that A′x0=b′ . We call A′x <=b′ the defining
constraints of the vertex. If the returned solution is not on a
vertex we introduce artificial branches on input variables into A
and use these branches as defining constraints. These branches are
rarely needed in practise.
The main idea is to bring the constraint system A′x<=b′ into a Hermite
normal form H and to compute the unimodular matrix U with A′U=H . The
Hermite normal form is uniquely defined. The constraint system A′x<=b′
is equivalent to Hy <=b′ with y:=(U−1)x . Since the solution x0 of
A′x0=b′ is not integral, the corresponding vector y0=(U−1)x0 is not
integral, either. The cuts from proofs algorithm creates an extended
branch on one of the components y_i of y , i. e., y_i <= floor(y0_i) or
y_i>=ceil(y0_i). Further on in the paper there is a lemma showing that
branch y_i >= ceil(y0_i) is impossible.
*/
lia_move hnf_cutter::create_cut(lar_term& t, mpq& k, explanation* ex, bool & upper
#ifdef Z3DEBUG
, const vector<mpq> & x0
#endif
) {
init_matrix_A();
svector<unsigned> basis_rows;
mpq big_number = m_abs_max.expt(3);
mpq d = hnf_calc::determinant_of_rectangular_matrix(m_A, basis_rows, big_number);
if (d >= big_number) {
return lia_move::undef;
}
if (m_settings.get_cancel_flag()) {
return lia_move::undef;
}
if (basis_rows.size() < m_A.row_count()) {
m_A.shrink_to_rank(basis_rows);
shrink_explanation(basis_rows);
}
hnf<general_matrix> h(m_A, d);
vector<mpq> b = create_b(basis_rows);
#ifdef Z3DEBUG
lp_assert(m_A * x0 == b);
#endif
find_h_minus_1_b(h.W(), b);
int cut_row = find_cut_row_index(b);
if (cut_row == -1) {
return lia_move::undef;
}
vector<mpq> row(m_A.column_count());
get_ei_H_minus_1(cut_row, h.W(), row);
vector<mpq> f = row * m_A;
fill_term(f, t);
k = floor(b[cut_row]);
upper = true;
return lia_move::cut;
}
svector<unsigned> hnf_cutter::vars() const { return m_var_register.vars(); }
void hnf_cutter::try_add_term_to_A_for_hnf(tv const &i) {
mpq rs;
const lar_term& t = lra.get_term(i);
constraint_index ci;
bool upper_bound;
if (!is_full() && lra.get_equality_and_right_side_for_term_on_current_x(i, rs, ci, upper_bound)) {
add_term(&t, rs, ci, upper_bound);
}
}
bool hnf_cutter::hnf_has_var_with_non_integral_value() const {
for (unsigned j : vars())
if (!lia.get_value(j).is_int())
return true;
return false;
}
bool hnf_cutter::init_terms_for_hnf_cut() {
clear();
for (unsigned i = 0; i < lra.terms().size() && !is_full(); i++) {
try_add_term_to_A_for_hnf(tv::term(i));
}
return hnf_has_var_with_non_integral_value();
}
lia_move hnf_cutter::make_hnf_cut() {
if (!init_terms_for_hnf_cut()) {
return lia_move::undef;
}
lia.settings().stats().m_hnf_cutter_calls++;
TRACE("hnf_cut", tout << "settings().stats().m_hnf_cutter_calls = " << lia.settings().stats().m_hnf_cutter_calls << "\n";
for (unsigned i : constraints_for_explanation()) {
lra.constraints().display(tout, i);
}
tout << lra.constraints();
);
#ifdef Z3DEBUG
vector<mpq> x0 = transform_to_local_columns(lra.r_x());
#endif
lia_move r = create_cut(lia.m_t, lia.m_k, lia.m_ex, lia.m_upper
#ifdef Z3DEBUG
, x0
#endif
);
if (r == lia_move::cut) {
TRACE("hnf_cut",
lra.print_term(lia.m_t, tout << "cut:");
tout << " <= " << lia.m_k << std::endl;
for (unsigned i : constraints_for_explanation()) {
lra.constraints().display(tout, i);
}
);
lp_assert(lia.current_solution_is_inf_on_cut());
lia.settings().stats().m_hnf_cuts++;
lia.m_ex->clear();
for (unsigned i : constraints_for_explanation()) {
lia.m_ex->push_back(i);
}
}
return r;
}
}