created class for managing neighbor cells of rrc

master
Francisco Paisana 5 years ago
parent 069dc1f751
commit 9a1f69113f

@ -131,6 +131,25 @@ private:
std::map<uint32_t, uint32_t> sib_info_map; ///< map of sib_index to index of schedInfoList in SIB1 std::map<uint32_t, uint32_t> sib_info_map; ///< map of sib_index to index of schedInfoList in SIB1
}; };
class cell_list
{
public:
const static int MAX_NEIGHBOUR_CELLS = 8;
typedef std::unique_ptr<cell_t> unique_cell_t;
bool add_neighbour(unique_cell_t cell);
void rem_last_neighbour();
cell_t* get_neighbour_cell_handle(uint32_t earfcn, uint32_t pci);
void log_neighbour_cells() const;
private:
void sort_neighbour_cells();
srslte::log_ref log_h{"RRC"};
std::vector<unique_cell_t> neighbour_cells;
};
} // namespace srsue } // namespace srsue
#endif // SRSLTE_RRC_CELL_H #endif // SRSLTE_RRC_CELL_H

@ -146,4 +146,94 @@ uint16_t cell_t::get_mnc() const
return 0; return 0;
} }
/*********************************************
* Neighbour Cell List
********************************************/
cell_t* cell_list::get_neighbour_cell_handle(uint32_t earfcn, uint32_t pci)
{
for (unique_cell_t& cell : neighbour_cells) {
if (cell->equals(earfcn, pci)) {
return cell.get();
}
}
return nullptr;
}
bool cell_list::add_neighbour(unique_cell_t new_cell)
{
// Make sure cell is valid
if (!new_cell->is_valid()) {
log_h->error("Trying to add cell %s but is not valid", new_cell->to_string().c_str());
return false;
}
// If cell exists, update RSRP value
cell_t* existing_cell = get_neighbour_cell_handle(new_cell->get_earfcn(), new_cell->get_pci());
if (existing_cell != nullptr) {
if (std::isnormal(new_cell.get()->get_rsrp())) {
existing_cell->set_rsrp(new_cell.get()->get_rsrp());
}
log_h->info("Updated neighbour cell %s rsrp=%f\n", new_cell->to_string().c_str(), new_cell.get()->get_rsrp());
return true;
}
if (neighbour_cells.size() >= MAX_NEIGHBOUR_CELLS) {
// If there isn't space, keep the strongest only
if (not new_cell->greater(neighbour_cells.back().get())) {
log_h->warning("Could not add cell %s: no space in neighbours\n", new_cell->to_string().c_str());
return false;
}
rem_last_neighbour();
}
log_h->info(
"Adding neighbour cell %s, nof_neighbours=%zd\n", new_cell->to_string().c_str(), neighbour_cells.size() + 1);
neighbour_cells.push_back(std::move(new_cell));
sort_neighbour_cells();
return true;
}
void cell_list::rem_last_neighbour()
{
if (not neighbour_cells.empty()) {
unique_cell_t& c = neighbour_cells.back();
log_h->debug("Delete cell %s from neighbor list.\n", c->to_string().c_str());
neighbour_cells.pop_back();
}
}
// Sort neighbour cells by decreasing order of RSRP
void cell_list::sort_neighbour_cells()
{
std::sort(std::begin(neighbour_cells), std::end(neighbour_cells), [](const unique_cell_t& a, const unique_cell_t& b) {
return a->greater(b.get());
});
log_neighbour_cells();
}
void cell_list::log_neighbour_cells() const
{
if (not neighbour_cells.empty()) {
const int32_t MAX_STR_LEN = 512;
char ordered[MAX_STR_LEN] = {};
int n = 0;
n += snprintf(ordered, MAX_STR_LEN, "[%s", neighbour_cells[0]->to_string().c_str());
for (uint32_t i = 1; i < neighbour_cells.size(); i++) {
if (n < MAX_STR_LEN) { // make sure there is still room left
int m = snprintf(&ordered[n], (size_t)MAX_STR_LEN - n, " | %s", neighbour_cells[i]->to_string().c_str());
if (m > 0) {
n += m;
}
}
}
log_h->debug("Neighbours: %s]\n", ordered);
} else {
log_h->debug("Neighbours: Empty\n");
}
}
} // namespace srsue } // namespace srsue

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