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srsRAN_4G/srsenb/test/upper/rrc_mobility_test.cc

665 lines
30 KiB
C++

/*
* Copyright 2013-2020 Software Radio Systems Limited
*
* This file is part of srsLTE.
*
* srsLTE is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as
* published by the Free Software Foundation, either version 3 of
* the License, or (at your option) any later version.
*
* srsLTE is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Affero General Public License for more details.
*
* A copy of the GNU Affero General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#include "srsenb/hdr/enb.h"
#include "srsenb/hdr/stack/rrc/rrc_mobility.h"
#include "srsenb/src/enb_cfg_parser.h"
#include "srsenb/test/common/dummy_classes.h"
#include "srslte/asn1/rrc_asn1_utils.h"
#include "srslte/common/test_common.h"
#include "test_helpers.h"
#include <iostream>
#include <srslte/common/log_filter.h>
meas_cell_cfg_t generate_cell1()
{
meas_cell_cfg_t cell1{};
cell1.earfcn = 3400;
cell1.pci = 1;
cell1.q_offset = 0;
cell1.eci = 0x19C01;
return cell1;
}
report_cfg_eutra_s generate_rep1()
{
report_cfg_eutra_s rep{};
rep.report_amount.value = report_cfg_eutra_s::report_amount_opts::r16;
rep.report_interv.value = report_interv_opts::ms240;
rep.max_report_cells = 2;
rep.report_quant.value = report_cfg_eutra_s::report_quant_opts::both;
rep.trigger_quant.value = report_cfg_eutra_s::trigger_quant_opts::rsrp;
rep.trigger_type.set_event().event_id.set_event_a3();
rep.trigger_type.event().time_to_trigger.value = time_to_trigger_opts::ms100;
rep.trigger_type.event().hysteresis = 0;
rep.trigger_type.event().event_id.event_a3().a3_offset = 5;
rep.trigger_type.event().event_id.event_a3().report_on_leave = true;
return rep;
}
bool is_cell_cfg_equal(const meas_cell_cfg_t& cfg, const cells_to_add_mod_s& cell)
{
return cfg.pci == cell.pci and cell.cell_individual_offset.to_number() == (int8_t)round(cfg.q_offset) and
cell.cell_idx == (cfg.eci & 0xFFu);
}
int test_correct_insertion()
{
meas_cell_cfg_t cell1 = generate_cell1(), cell2{}, cell3{}, cell4{};
cell2 = cell1;
cell2.pci = 2;
cell2.eci = 0x19C02;
cell3 = cell1;
cell3.earfcn = 2850;
cell4 = cell1;
cell4.q_offset = 1;
report_cfg_eutra_s rep1 = generate_rep1();
// TEST 1: cell/rep insertion in empty varMeasCfg
{
var_meas_cfg_t var_cfg;
auto ret = var_cfg.add_cell_cfg(cell1);
TESTASSERT(std::get<0>(ret) and std::get<1>(ret) != nullptr);
const auto& objs = var_cfg.meas_objs();
TESTASSERT(objs.size() == 1 and objs[0].meas_obj_id == 1);
TESTASSERT(objs[0].meas_obj.type().value ==
asn1::rrc::meas_obj_to_add_mod_s::meas_obj_c_::types_opts::meas_obj_eutra);
auto& eutra = objs[0].meas_obj.meas_obj_eutra();
TESTASSERT(eutra.carrier_freq == cell1.earfcn);
TESTASSERT(eutra.cells_to_add_mod_list.size() == 1);
TESTASSERT(is_cell_cfg_equal(cell1, eutra.cells_to_add_mod_list[0]));
auto ret2 = var_cfg.add_report_cfg(rep1);
TESTASSERT(ret2->report_cfg_id == 1);
TESTASSERT(ret2->report_cfg.report_cfg_eutra() == rep1);
}
{
var_meas_cfg_t var_cfg;
const auto& objs = var_cfg.meas_objs();
// TEST 2: insertion of out-of-order cell ids in same earfcn
var_cfg.add_cell_cfg(cell2);
var_cfg.add_cell_cfg(cell1);
TESTASSERT(objs.size() == 1 and objs[0].meas_obj_id == 1);
auto& eutra = objs[0].meas_obj.meas_obj_eutra();
TESTASSERT(eutra.carrier_freq == cell1.earfcn);
TESTASSERT(eutra.cells_to_add_mod_list.size() == 2);
const cells_to_add_mod_s* cell_it = eutra.cells_to_add_mod_list.begin();
TESTASSERT(cell_it[0].cell_idx == (cell1.eci & 0xFFu));
TESTASSERT(cell_it[1].cell_idx == (cell2.eci & 0xFFu));
TESTASSERT(cell_it[1].pci == cell2.pci);
// TEST 3: insertion of cell in another frequency
auto ret1 = var_cfg.add_cell_cfg(cell3);
TESTASSERT(std::get<0>(ret1) and std::get<1>(ret1)->meas_obj_id == 2);
TESTASSERT(objs.size() == 2 and objs[1].meas_obj_id == 2);
const auto& eutra2 = objs[1].meas_obj.meas_obj_eutra();
TESTASSERT(eutra2.carrier_freq == cell3.earfcn);
TESTASSERT(eutra2.cells_to_add_mod_list.size() == 1);
// TEST 4: update of existing cell
auto ret2 = var_cfg.add_cell_cfg(cell4);
TESTASSERT(std::get<0>(ret2) and std::get<1>(ret2)->meas_obj_id == 1);
auto& eutra3 = objs[0].meas_obj.meas_obj_eutra();
TESTASSERT(objs.size() == 2 and objs[0].meas_obj_id == 1);
TESTASSERT(eutra3.carrier_freq == cell4.earfcn);
TESTASSERT(eutra3.cells_to_add_mod_list.size() == 2);
TESTASSERT(eutra3.cells_to_add_mod_list[0].cell_idx == (cell1.eci & 0xFFu));
TESTASSERT(eutra3.cells_to_add_mod_list[0].cell_individual_offset.to_number() == 1);
}
return 0;
}
int test_correct_meascfg_calculation()
{
var_meas_cfg_t src_var, target_var;
meas_cell_cfg_t cell1{}, cell2{};
cell1.earfcn = 3400;
cell1.pci = 1;
cell1.q_offset = 0;
cell1.eci = 0x19C01;
cell2 = cell1;
cell2.pci = 2;
cell2.eci = 0x19C02;
report_cfg_eutra_s rep1 = generate_rep1(), rep2{}, rep3{};
rep2 = rep1;
rep2.trigger_quant.value = report_cfg_eutra_s::trigger_quant_opts::rsrq;
rep3 = rep2;
rep3.report_quant.value = report_cfg_eutra_s::report_quant_opts::same_as_trigger_quant;
{
meas_cfg_s result_meascfg;
// TEST 1: Insertion of two cells in var_meas propagates to the resulting meas_cfg_s cellsToAddMod list
target_var.add_cell_cfg(cell1);
target_var.add_cell_cfg(cell2);
target_var.add_report_cfg(rep1);
target_var.add_report_cfg(rep2);
target_var.add_measid_cfg(1, 1);
target_var.add_measid_cfg(1, 2);
src_var.compute_diff_meas_cfg(target_var, &result_meascfg);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list_present);
TESTASSERT(not result_meascfg.meas_obj_to_rem_list_present);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list.size() == 1);
auto* item = &result_meascfg.meas_obj_to_add_mod_list[0];
TESTASSERT(item->meas_obj_id == 1 and
item->meas_obj.type().value == meas_obj_to_add_mod_s::meas_obj_c_::types_opts::meas_obj_eutra);
auto& eutra = item->meas_obj.meas_obj_eutra();
TESTASSERT(eutra.cells_to_add_mod_list_present and not eutra.cells_to_rem_list_present);
TESTASSERT(eutra.cells_to_add_mod_list.size() == 2);
auto* cell_item = &eutra.cells_to_add_mod_list[0];
TESTASSERT(is_cell_cfg_equal(cell1, *cell_item));
cell_item++;
TESTASSERT(is_cell_cfg_equal(cell2, *cell_item));
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list_present and not result_meascfg.report_cfg_to_rem_list_present);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list.size() == 2);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list[0].report_cfg_id == 1);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list[0].report_cfg.report_cfg_eutra() == rep1);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list[1].report_cfg_id == 2);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list[1].report_cfg.report_cfg_eutra() == rep2);
TESTASSERT(result_meascfg.meas_id_to_add_mod_list_present and not result_meascfg.meas_id_to_rem_list_present);
TESTASSERT(result_meascfg.meas_id_to_add_mod_list.size() == 2);
auto* measid_item = &result_meascfg.meas_id_to_add_mod_list[0];
TESTASSERT(measid_item->meas_id == 1 and measid_item->meas_obj_id == 1 and measid_item->report_cfg_id == 1);
measid_item++;
TESTASSERT(measid_item->meas_id == 2 and measid_item->meas_obj_id == 1 and measid_item->report_cfg_id == 2);
// TEST 2: measConfig is empty if nothing was updated
src_var = target_var;
src_var.compute_diff_meas_cfg(target_var, &result_meascfg);
TESTASSERT(not result_meascfg.meas_obj_to_add_mod_list_present and not result_meascfg.meas_obj_to_rem_list_present);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list.size() == 0);
TESTASSERT(not result_meascfg.report_cfg_to_add_mod_list_present and
not result_meascfg.report_cfg_to_rem_list_present);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list.size() == 0);
// TEST 3: Cell is added to cellsToAddModList if just a field was updated
cell1.pci = 3;
src_var = target_var;
target_var.add_cell_cfg(cell1);
src_var.compute_diff_meas_cfg(target_var, &result_meascfg);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list_present);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list.size() == 1);
item = &result_meascfg.meas_obj_to_add_mod_list[0];
TESTASSERT(item->meas_obj_id == 1 and
item->meas_obj.type().value == meas_obj_to_add_mod_s::meas_obj_c_::types_opts::meas_obj_eutra);
eutra = item->meas_obj.meas_obj_eutra();
TESTASSERT(eutra.cells_to_add_mod_list_present and not eutra.cells_to_rem_list_present);
TESTASSERT(eutra.cells_to_add_mod_list.size() == 1);
cell_item = &eutra.cells_to_add_mod_list[0];
TESTASSERT(is_cell_cfg_equal(cell1, *cell_item));
// TEST 4: Removal of cell/rep from target propagates to the resulting meas_cfg_s
src_var = target_var;
target_var = var_meas_cfg_t{};
target_var.add_cell_cfg(cell2);
target_var.add_report_cfg(rep1);
target_var.add_report_cfg(rep3);
src_var.compute_diff_meas_cfg(target_var, &result_meascfg);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list_present);
TESTASSERT(result_meascfg.meas_obj_to_add_mod_list.size() == 1);
item = &result_meascfg.meas_obj_to_add_mod_list[0];
TESTASSERT(item->meas_obj_id == 1 and
item->meas_obj.type().value == meas_obj_to_add_mod_s::meas_obj_c_::types_opts::meas_obj_eutra);
eutra = item->meas_obj.meas_obj_eutra();
TESTASSERT(not eutra.cells_to_add_mod_list_present and eutra.cells_to_rem_list_present);
TESTASSERT(eutra.cells_to_rem_list.size() == 1);
TESTASSERT(eutra.cells_to_rem_list[0] == (cell1.eci & 0xFFu));
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list_present and not result_meascfg.report_cfg_to_rem_list_present);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list.size() == 1);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list[0].report_cfg_id == 2);
TESTASSERT(result_meascfg.report_cfg_to_add_mod_list[0].report_cfg.report_cfg_eutra() == rep3);
}
return SRSLTE_SUCCESS;
}
struct mobility_test_params {
enum class test_event {
success,
wrong_measreport,
concurrent_ho,
ho_prep_failure,
duplicate_crnti_ce,
recover
} fail_at;
const char* to_string()
{
switch (fail_at) {
case test_event::success:
return "success";
case test_event::wrong_measreport:
return "wrong measreport";
case test_event::concurrent_ho:
return "measreport while in handover";
case test_event::ho_prep_failure:
return "ho preparation failure";
case test_event::recover:
return "fail and success";
case test_event::duplicate_crnti_ce:
return "duplicate CRNTI CE";
default:
return "none";
}
}
};
struct mobility_tester {
explicit mobility_tester(const mobility_test_params& args_) : args(args_), rrc(&task_sched)
{
rrc_log->set_level(srslte::LOG_LEVEL_INFO);
rrc_log->set_hex_limit(1024);
}
virtual int generate_rrc_cfg() = 0;
virtual int setup_rrc() { return setup_rrc_common(); }
int run_preamble()
{
rrc_log->set_level(srslte::LOG_LEVEL_NONE); // mute all the startup log
// add user
sched_interface::ue_cfg_t ue_cfg{};
ue_cfg.supported_cc_list.resize(1);
ue_cfg.supported_cc_list[0].enb_cc_idx = 0;
ue_cfg.supported_cc_list[0].active = true;
rrc.add_user(rnti, ue_cfg);
// Do all the handshaking until the first RRC Connection Reconf
test_helpers::bring_rrc_to_reconf_state(rrc, *task_sched.get_timer_handler(), rnti);
rrc_log->set_level(srslte::LOG_LEVEL_INFO);
return SRSLTE_SUCCESS;
}
mobility_test_params args;
srslte::scoped_log<srslte::test_log_filter> rrc_log{"RRC"};
srslte::task_scheduler task_sched;
rrc_cfg_t cfg;
srsenb::rrc rrc;
test_dummies::mac_mobility_dummy mac;
test_dummies::rlc_mobility_dummy rlc;
test_dummies::pdcp_mobility_dummy pdcp;
test_dummies::phy_mobility_dummy phy;
test_dummies::s1ap_mobility_dummy s1ap;
gtpu_dummy gtpu;
void tic()
{
task_sched.tic();
rrc.tti_clock();
task_sched.run_pending_tasks();
};
const uint16_t rnti = 0x46;
protected:
int generate_rrc_cfg_common()
{
srsenb::all_args_t all_args;
TESTASSERT(test_helpers::parse_default_cfg(&cfg, all_args) == SRSLTE_SUCCESS);
cfg.meas_cfg_present = true;
report_cfg_eutra_s rep = generate_rep1();
cfg.cell_list[0].meas_cfg.meas_reports.push_back(rep);
cfg.cell_list[0].meas_cfg.meas_cells.resize(1);
cfg.cell_list[0].meas_cfg.meas_cells[0] = generate_cell1();
cfg.cell_list[0].meas_cfg.meas_cells[0].pci = 2;
return SRSLTE_SUCCESS;
}
int setup_rrc_common()
{
rrc.init(cfg, &phy, &mac, &rlc, &pdcp, &s1ap, &gtpu);
return SRSLTE_SUCCESS;
}
};
struct s1ap_mobility_tester : public mobility_tester {
explicit s1ap_mobility_tester(const mobility_test_params& args_) : mobility_tester(args_) {}
int generate_rrc_cfg() final
{
TESTASSERT(generate_rrc_cfg_common() == SRSLTE_SUCCESS);
cfg.cell_list[0].meas_cfg.meas_cells[0].eci = 0x19C02;
return SRSLTE_SUCCESS;
}
};
struct intraenb_mobility_tester : public mobility_tester {
explicit intraenb_mobility_tester(const mobility_test_params& args_) : mobility_tester(args_) {}
int generate_rrc_cfg() final
{
TESTASSERT(generate_rrc_cfg_common() == SRSLTE_SUCCESS);
cfg.cell_list[0].meas_cfg.meas_cells[0].eci = 0x19B02;
cell_cfg_t cell2 = cfg.cell_list[0];
cell2.pci = 2;
cell2.cell_id = 2;
cell2.meas_cfg.meas_cells[0].pci = 1;
cell2.meas_cfg.meas_cells[0].eci = 0x19B01;
cfg.cell_list.push_back(cell2);
return SRSLTE_SUCCESS;
}
};
int test_s1ap_mobility(mobility_test_params test_params)
{
printf("\n===== TEST: test_s1ap_mobility() for event %s =====\n", test_params.to_string());
s1ap_mobility_tester tester{test_params};
srslte::unique_byte_buffer_t pdu;
TESTASSERT(tester.generate_rrc_cfg() == SRSLTE_SUCCESS);
TESTASSERT(tester.setup_rrc() == SRSLTE_SUCCESS);
TESTASSERT(tester.run_preamble() == SRSLTE_SUCCESS);
test_dummies::s1ap_mobility_dummy& s1ap = tester.s1ap;
/* Receive MeasReport from UE (correct if PCI=2) */
if (test_params.fail_at == mobility_test_params::test_event::wrong_measreport) {
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x0D, 0xBC, 0x80}; // PCI == 3
test_helpers::copy_msg_to_buffer(pdu, meas_report);
} else {
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x09, 0xBC, 0x80}; // PCI == 2
test_helpers::copy_msg_to_buffer(pdu, meas_report);
}
tester.rrc.write_pdu(tester.rnti, 1, std::move(pdu));
tester.tic();
/* Test Case: the MeasReport is not valid */
if (test_params.fail_at == mobility_test_params::test_event::wrong_measreport) {
TESTASSERT(s1ap.last_ho_required.rrc_container == nullptr);
TESTASSERT(tester.rrc_log->warn_counter == 1);
return SRSLTE_SUCCESS;
}
TESTASSERT(s1ap.last_ho_required.rrc_container != nullptr);
/* Test Case: Multiple concurrent MeasReports arrived. Only one HO procedure should be running */
if (test_params.fail_at == mobility_test_params::test_event::concurrent_ho) {
s1ap.last_ho_required = {};
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x09, 0xBC, 0x80}; // PCI == 2
test_helpers::copy_msg_to_buffer(pdu, meas_report);
tester.rrc.write_pdu(tester.rnti, 1, std::move(pdu));
tester.tic();
TESTASSERT(s1ap.last_ho_required.rrc_container == nullptr);
return SRSLTE_SUCCESS;
}
/* Test Case: Check HO Required was sent to S1AP */
TESTASSERT(s1ap.last_ho_required.rnti == tester.rnti);
TESTASSERT(s1ap.last_ho_required.target_eci == tester.cfg.cell_list[0].meas_cfg.meas_cells[0].eci);
TESTASSERT(s1ap.last_ho_required.target_plmn.to_string() == "00101");
{
asn1::cbit_ref bref(s1ap.last_ho_required.rrc_container->msg, s1ap.last_ho_required.rrc_container->N_bytes);
asn1::rrc::ho_prep_info_s hoprep;
TESTASSERT(hoprep.unpack(bref) == asn1::SRSASN_SUCCESS);
ho_prep_info_r8_ies_s& hoprepr8 = hoprep.crit_exts.c1().ho_prep_info_r8();
TESTASSERT(hoprepr8.as_cfg_present);
// Check if RRC sends the current active bearers
TESTASSERT(hoprepr8.as_cfg.source_rr_cfg.srb_to_add_mod_list_present);
TESTASSERT(hoprepr8.as_cfg.source_rr_cfg.srb_to_add_mod_list[0].srb_id == 1);
TESTASSERT(hoprepr8.as_cfg.source_rr_cfg.srb_to_add_mod_list[1].srb_id == 2);
TESTASSERT(hoprepr8.as_cfg.source_rr_cfg.drb_to_add_mod_list_present);
TESTASSERT(hoprepr8.as_cfg.source_rr_cfg.drb_to_add_mod_list[0].drb_id == 1);
}
/* Test Case: HandoverPreparation has failed */
if (test_params.fail_at == mobility_test_params::test_event::ho_prep_failure) {
tester.rrc.ho_preparation_complete(tester.rnti, false, nullptr);
// TESTASSERT(rrc_log->error_counter == 1);
TESTASSERT(not s1ap.last_enb_status.status_present);
return SRSLTE_SUCCESS;
}
/* MME returns back an HandoverCommand, S1AP unwraps the RRC container */
uint8_t ho_cmd_rrc_container[] = {0x01, 0xa9, 0x00, 0xd9, 0xfc, 0x00, 0x00, 0x00, 0x00, 0x0b, 0x22, 0x04, 0x00, 0x00,
0x01, 0x48, 0x04, 0xbc, 0x00, 0x00, 0x00, 0x00, 0x08, 0x00, 0x02, 0xa0, 0x07, 0xa0,
0x10, 0x00, 0x01, 0x00, 0x05, 0x00, 0xa7, 0xd0, 0xc1, 0xf6, 0xaf, 0x3e, 0x12, 0xcc,
0x86, 0x0d, 0x30, 0x00, 0x0b, 0x5a, 0x02, 0x17, 0x86, 0x00, 0x05, 0xa0, 0x20};
test_helpers::copy_msg_to_buffer(pdu, ho_cmd_rrc_container);
TESTASSERT(s1ap.last_enb_status.rnti != tester.rnti);
tester.rrc.ho_preparation_complete(tester.rnti, true, std::move(pdu));
TESTASSERT(s1ap.last_enb_status.status_present);
TESTASSERT(tester.rrc_log->error_counter == 0);
asn1::rrc::dl_dcch_msg_s ho_cmd;
TESTASSERT(test_helpers::unpack_asn1(ho_cmd, srslte::make_span(tester.pdcp.last_sdu.sdu)));
auto& recfg_r8 = ho_cmd.msg.c1().rrc_conn_recfg().crit_exts.c1().rrc_conn_recfg_r8();
TESTASSERT(recfg_r8.mob_ctrl_info_present);
return SRSLTE_SUCCESS;
}
int test_s1ap_tenb_mobility(mobility_test_params test_params)
{
printf("\n===== TEST: test_s1ap_tenb_mobility() for event %s =====\n", test_params.to_string());
s1ap_mobility_tester tester{test_params};
srslte::unique_byte_buffer_t pdu;
TESTASSERT(tester.generate_rrc_cfg() == SRSLTE_SUCCESS);
tester.cfg.cell_list[0].meas_cfg.meas_cells[0].eci = 0x19B01;
tester.cfg.enb_id = 0x19C;
tester.cfg.cell.id = 0x02;
tester.cfg.cell_list[0].cell_id = 0x02;
tester.cfg.cell_list[0].pci = 2;
TESTASSERT(tester.setup_rrc() == SRSLTE_SUCCESS);
/* Receive S1AP Handover Request */
asn1::s1ap::ho_request_s ho_req;
ho_req.protocol_ies.erab_to_be_setup_list_ho_req.value.resize(1);
auto& erab = ho_req.protocol_ies.erab_to_be_setup_list_ho_req.value[0].value.erab_to_be_setup_item_ho_req();
erab.erab_id = 5;
erab.erab_level_qos_params.qci = 9;
asn1::s1ap::sourceenb_to_targetenb_transparent_container_s container;
container.target_cell_id.cell_id.from_number(0x19C02);
uint8_t ho_prep_container[] = {
0x0a, 0x10, 0x0b, 0x81, 0x80, 0x00, 0x01, 0x80, 0x00, 0xf3, 0x02, 0x08, 0x00, 0x00, 0x15, 0x80, 0x00, 0x14,
0x06, 0xa4, 0x02, 0xf0, 0x04, 0x04, 0xf0, 0x00, 0x14, 0x80, 0x4a, 0x00, 0x00, 0x00, 0x02, 0x12, 0x31, 0xb6,
0xf8, 0x3e, 0xa0, 0x6f, 0x05, 0xe4, 0x65, 0x14, 0x1d, 0x39, 0xd0, 0x54, 0x4c, 0x00, 0x02, 0x54, 0x00, 0x20,
0x04, 0x60, 0x00, 0x00, 0x00, 0x10, 0x01, 0x00, 0xc0, 0x00, 0x00, 0x00, 0x00, 0x02, 0x05, 0x00, 0x04, 0x14,
0x00, 0x67, 0x0d, 0xfb, 0xc4, 0x66, 0x06, 0x50, 0x0f, 0x00, 0x08, 0x00, 0x20, 0x80, 0x0c, 0x14, 0xca, 0x2d,
0x5c, 0xe1, 0x86, 0x35, 0x39, 0x80, 0x0e, 0x06, 0xa4, 0x40, 0x0f, 0x22, 0x78};
// 0a100b818000018000f3020800001580001406a402f00404f00014804a000000021231b6f83ea06f05e465141d39d0544c00025400200460000000100100c000000000020500041400670dfbc46606500f00080020800c14ca2d5ce1863539800e06a4400f2278
container.rrc_container.resize(sizeof(ho_prep_container));
memcpy(container.rrc_container.data(), ho_prep_container, sizeof(ho_prep_container));
pdu = srslte::allocate_unique_buffer(*srslte::byte_buffer_pool::get_instance());
std::vector<asn1::fixed_octstring<4, true> > admitted_erabs;
tester.rrc.start_ho_ue_resource_alloc(ho_req, container, *pdu, admitted_erabs);
tester.tic();
TESTASSERT(tester.rrc.get_nof_users() == 1);
TESTASSERT(tester.mac.ue_db.count(0x46));
auto& mac_ue = tester.mac.ue_db[0x46];
TESTASSERT(mac_ue.supported_cc_list[0].active);
TESTASSERT(mac_ue.supported_cc_list[0].enb_cc_idx == 0);
TESTASSERT(mac_ue.ue_bearers[rb_id_t::RB_ID_SRB0].direction == sched_interface::ue_bearer_cfg_t::BOTH);
ho_cmd_s ho_cmd;
asn1::cbit_ref bref{pdu->msg, pdu->N_bytes};
TESTASSERT(ho_cmd.unpack(bref) == asn1::SRSASN_SUCCESS);
bref = asn1::cbit_ref{ho_cmd.crit_exts.c1().ho_cmd_r8().ho_cmd_msg.data(),
ho_cmd.crit_exts.c1().ho_cmd_r8().ho_cmd_msg.size()};
dl_dcch_msg_s dl_dcch_msg;
TESTASSERT(dl_dcch_msg.unpack(bref) == asn1::SRSASN_SUCCESS);
auto& recfg_r8 = dl_dcch_msg.msg.c1().rrc_conn_recfg().crit_exts.c1().rrc_conn_recfg_r8();
TESTASSERT(recfg_r8.rr_cfg_ded.phys_cfg_ded.sched_request_cfg.setup().sr_cfg_idx == 15);
TESTASSERT(recfg_r8.rr_cfg_ded.phys_cfg_ded.sched_request_cfg.setup().sr_pucch_res_idx == 0);
// user PRACHs and sends C-RNTI CE
sched_interface::ue_cfg_t ue_cfg{};
ue_cfg.supported_cc_list.resize(1);
ue_cfg.supported_cc_list[0].enb_cc_idx = 0;
ue_cfg.supported_cc_list[0].active = true;
tester.rrc.add_user(0x47, ue_cfg);
tester.rrc.upd_user(0x47, 0x46);
uint8_t recfg_complete[] = {0x10, 0x00};
test_helpers::copy_msg_to_buffer(pdu, recfg_complete);
tester.rrc.write_pdu(0x46, rb_id_t::RB_ID_SRB1, std::move(pdu));
tester.tic();
TESTASSERT(mac_ue.ue_bearers[rb_id_t::RB_ID_SRB1].direction == sched_interface::ue_bearer_cfg_t::BOTH);
TESTASSERT(mac_ue.ue_bearers[rb_id_t::RB_ID_SRB2].direction == sched_interface::ue_bearer_cfg_t::BOTH);
TESTASSERT(mac_ue.ue_bearers[rb_id_t::RB_ID_DRB1].direction == sched_interface::ue_bearer_cfg_t::BOTH);
TESTASSERT(mac_ue.pucch_cfg.I_sr == recfg_r8.rr_cfg_ded.phys_cfg_ded.sched_request_cfg.setup().sr_cfg_idx);
TESTASSERT(mac_ue.pucch_cfg.n_pucch_sr ==
recfg_r8.rr_cfg_ded.phys_cfg_ded.sched_request_cfg.setup().sr_pucch_res_idx);
return SRSLTE_SUCCESS;
}
int test_intraenb_mobility(mobility_test_params test_params)
{
printf("\n===== TEST: test_intraenb_mobility() for event %s =====\n", test_params.to_string());
intraenb_mobility_tester tester{test_params};
srslte::unique_byte_buffer_t pdu;
TESTASSERT(tester.generate_rrc_cfg() == SRSLTE_SUCCESS);
TESTASSERT(tester.setup_rrc() == SRSLTE_SUCCESS);
TESTASSERT(tester.run_preamble() == SRSLTE_SUCCESS);
tester.pdcp.last_sdu.sdu = nullptr;
tester.rlc.test_reset_all();
/* Receive MeasReport from UE (correct if PCI=2) */
if (test_params.fail_at == mobility_test_params::test_event::wrong_measreport) {
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x0D, 0xBC, 0x80}; // PCI == 3
test_helpers::copy_msg_to_buffer(pdu, meas_report);
} else {
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x09, 0xBC, 0x80}; // PCI == 2
test_helpers::copy_msg_to_buffer(pdu, meas_report);
}
tester.rrc.write_pdu(tester.rnti, 1, std::move(pdu));
tester.tic();
TESTASSERT(tester.s1ap.last_ho_required.rrc_container == nullptr);
/* Test Case: the MeasReport is not valid */
if (test_params.fail_at == mobility_test_params::test_event::wrong_measreport) {
TESTASSERT(tester.rrc_log->warn_counter == 1);
TESTASSERT(tester.pdcp.last_sdu.sdu == nullptr);
return SRSLTE_SUCCESS;
}
TESTASSERT(tester.pdcp.last_sdu.sdu != nullptr);
TESTASSERT(tester.s1ap.last_ho_required.rrc_container == nullptr);
TESTASSERT(not tester.s1ap.last_enb_status.status_present);
/* Test Case: Multiple concurrent MeasReports arrived. Only one HO procedure should be running */
if (test_params.fail_at == mobility_test_params::test_event::concurrent_ho) {
tester.pdcp.last_sdu = {};
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x09, 0xBC, 0x80}; // PCI == 2
test_helpers::copy_msg_to_buffer(pdu, meas_report);
tester.rrc.write_pdu(tester.rnti, 1, std::move(pdu));
tester.tic();
TESTASSERT(tester.pdcp.last_sdu.sdu == nullptr);
return SRSLTE_SUCCESS;
}
/* Test Case: the HandoverCommand was sent to the lower layers */
TESTASSERT(tester.rrc_log->error_counter == 0);
TESTASSERT(tester.pdcp.last_sdu.rnti == tester.rnti);
TESTASSERT(tester.pdcp.last_sdu.lcid == 1); // SRB1
asn1::rrc::dl_dcch_msg_s ho_cmd;
TESTASSERT(test_helpers::unpack_asn1(ho_cmd, srslte::make_span(tester.pdcp.last_sdu.sdu)));
auto& recfg_r8 = ho_cmd.msg.c1().rrc_conn_recfg().crit_exts.c1().rrc_conn_recfg_r8();
TESTASSERT(recfg_r8.mob_ctrl_info_present);
TESTASSERT(recfg_r8.mob_ctrl_info.new_ue_id.to_number() == tester.rnti);
TESTASSERT(recfg_r8.mob_ctrl_info.target_pci == 2);
TESTASSERT(recfg_r8.rr_cfg_ded_present);
TESTASSERT(recfg_r8.rr_cfg_ded.phys_cfg_ded_present);
const asn1::rrc::phys_cfg_ded_s& phy_cfg_ded = recfg_r8.rr_cfg_ded.phys_cfg_ded;
TESTASSERT(phy_cfg_ded.sched_request_cfg_present);
TESTASSERT(phy_cfg_ded.cqi_report_cfg_present);
/* Test Case: The UE sends a C-RNTI CE. Bearers are reestablished */
tester.pdcp.last_sdu.sdu = nullptr;
tester.rrc.upd_user(tester.rnti + 1, tester.rnti);
TESTASSERT(tester.rlc.ue_db[tester.rnti].reest_sdu_counter == 0);
TESTASSERT(tester.pdcp.last_sdu.sdu == nullptr);
TESTASSERT(tester.phy.last_cfg.size() == 1 and tester.mac.ue_db[tester.rnti].supported_cc_list.size() == 1);
TESTASSERT(tester.phy.last_cfg[0].enb_cc_idx == tester.mac.ue_db[tester.rnti].supported_cc_list[0].enb_cc_idx);
/* Test Case: The UE receives a duplicate C-RNTI CE. Nothing should happen */
if (test_params.fail_at == mobility_test_params::test_event::duplicate_crnti_ce) {
TESTASSERT(tester.rlc.ue_db[tester.rnti].reest_sdu_counter == 0);
tester.rrc.upd_user(tester.rnti + 2, tester.rnti);
TESTASSERT(tester.rlc.ue_db[tester.rnti].reest_sdu_counter == 0);
TESTASSERT(tester.pdcp.last_sdu.sdu == nullptr);
TESTASSERT(tester.rlc.ue_db[tester.rnti].last_sdu == nullptr); // No Reject sent
}
/* Test Case: Terminate first Handover. No extra messages should be sent DL. SR/CQI resources match recfg message */
uint8_t recfg_complete[] = {0x10, 0x00};
test_helpers::copy_msg_to_buffer(pdu, recfg_complete);
tester.rrc.write_pdu(tester.rnti, rb_id_t::RB_ID_SRB2, std::move(pdu));
TESTASSERT(tester.pdcp.last_sdu.sdu == nullptr);
sched_interface::ue_cfg_t& ue_cfg = tester.mac.ue_db[tester.rnti];
TESTASSERT(ue_cfg.pucch_cfg.sr_configured);
TESTASSERT(ue_cfg.pucch_cfg.n_pucch_sr == phy_cfg_ded.sched_request_cfg.setup().sr_pucch_res_idx);
TESTASSERT(ue_cfg.pucch_cfg.I_sr == phy_cfg_ded.sched_request_cfg.setup().sr_cfg_idx);
TESTASSERT(ue_cfg.supported_cc_list[0].dl_cfg.cqi_report.pmi_idx ==
phy_cfg_ded.cqi_report_cfg.cqi_report_periodic.setup().cqi_pmi_cfg_idx);
TESTASSERT(ue_cfg.pucch_cfg.n_pucch == phy_cfg_ded.cqi_report_cfg.cqi_report_periodic.setup().cqi_pucch_res_idx);
/* Test Case: The RRC should be able to start a new handover */
uint8_t meas_report[] = {0x08, 0x10, 0x38, 0x74, 0x00, 0x05, 0xBC, 0x80}; // PCI == 1
test_helpers::copy_msg_to_buffer(pdu, meas_report);
tester.rrc.write_pdu(tester.rnti, 1, std::move(pdu));
tester.tic();
TESTASSERT(tester.s1ap.last_ho_required.rrc_container == nullptr);
TESTASSERT(tester.pdcp.last_sdu.sdu != nullptr);
TESTASSERT(tester.s1ap.last_ho_required.rrc_container == nullptr);
TESTASSERT(not tester.s1ap.last_enb_status.status_present);
TESTASSERT(test_helpers::unpack_asn1(ho_cmd, srslte::make_span(tester.pdcp.last_sdu.sdu)));
recfg_r8 = ho_cmd.msg.c1().rrc_conn_recfg().crit_exts.c1().rrc_conn_recfg_r8();
TESTASSERT(recfg_r8.mob_ctrl_info_present);
TESTASSERT(recfg_r8.mob_ctrl_info.new_ue_id.to_number() == tester.rnti);
TESTASSERT(recfg_r8.mob_ctrl_info.target_pci == 1);
return SRSLTE_SUCCESS;
}
int main(int argc, char** argv)
{
srslte::logmap::set_default_log_level(srslte::LOG_LEVEL_INFO);
using event = mobility_test_params::test_event;
if (argc < 3) {
argparse::usage(argv[0]);
return -1;
}
argparse::parse_args(argc, argv);
TESTASSERT(test_correct_insertion() == 0);
TESTASSERT(test_correct_meascfg_calculation() == 0);
// S1AP Handover
TESTASSERT(test_s1ap_mobility(mobility_test_params{event::wrong_measreport}) == 0);
TESTASSERT(test_s1ap_mobility(mobility_test_params{event::concurrent_ho}) == 0);
TESTASSERT(test_s1ap_mobility(mobility_test_params{event::ho_prep_failure}) == 0);
TESTASSERT(test_s1ap_mobility(mobility_test_params{event::success}) == 0);
TESTASSERT(test_s1ap_tenb_mobility(mobility_test_params{event::success}) == 0);
// intraeNB Handover
TESTASSERT(test_intraenb_mobility(mobility_test_params{event::wrong_measreport}) == 0);
TESTASSERT(test_intraenb_mobility(mobility_test_params{event::concurrent_ho}) == 0);
TESTASSERT(test_intraenb_mobility(mobility_test_params{event::duplicate_crnti_ce}) == 0);
TESTASSERT(test_intraenb_mobility(mobility_test_params{event::success}) == 0);
printf("\nSuccess\n");
return SRSLTE_SUCCESS;
}