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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 "srslte/asn1/rrc_asn1.h"
#include "srslte/asn1/rrc_asn1_utils.h"
#include "srslte/common/log_filter.h"
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#include "srslte/common/mac_pcap.h"
#include "srslte/interfaces/ue_interfaces.h"
#include "srsue/hdr/stack/mac/mac.h"
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#include "srsue/hdr/stack/mac/mux.h"
#include "srsue/test/common/dummy_classes.h"
#include <assert.h>
#include <iostream>
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#include <string.h>
using namespace srsue;
using namespace srslte;
#define HAVE_PCAP 0
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static std::unique_ptr<srslte::mac_pcap> pcap_handle = nullptr;
#define TESTASSERT(cond) \
{ \
if (!(cond)) { \
std::cout << "[" << __FUNCTION__ << "][Line " << __LINE__ << "]: FAIL at " << (#cond) << std::endl; \
return SRSLTE_ERROR; \
} \
}
srslte::log_ref mac_log{"MAC"};
namespace srslte {
// fake classes
class rlc_dummy : public srsue::rlc_dummy_interface
{
public:
rlc_dummy(srslte::log_filter* log_) : received_bytes(0), log(log_) {}
bool has_data(const uint32_t lcid) final { return ul_queues[lcid] > 0; }
uint32_t get_buffer_state(const uint32_t lcid) final { return ul_queues[lcid]; }
int read_pdu(uint32_t lcid, uint8_t* payload, uint32_t nof_bytes) final
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{
if (!read_enable) {
return 0;
}
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uint32_t len = SRSLTE_MIN(ul_queues[lcid], nof_bytes);
// set payload bytes to LCID so we can check later if the scheduling was correct
memset(payload, lcid > 0 ? lcid : 0xf, len);
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// remove from UL queue
ul_queues[lcid] -= len;
return len;
};
void write_pdu(uint32_t lcid, uint8_t* payload, uint32_t nof_bytes) final
{
log->debug_hex(payload, nof_bytes, "Received %d B on LCID %d\n", nof_bytes, lcid);
received_bytes += nof_bytes;
}
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void write_sdu(uint32_t lcid, uint32_t nof_bytes) { ul_queues[lcid] += nof_bytes; }
uint32_t get_received_bytes() { return received_bytes; }
void disable_read() { read_enable = false; }
private:
bool read_enable = true;
uint32_t received_bytes;
srslte::log_filter* log;
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// UL queues where key is LCID and value the queue length
std::map<uint32_t, uint32_t> ul_queues;
};
class phy_dummy : public phy_interface_mac_lte
{
public:
phy_dummy() : scell_cmd(0){};
void set_log(srslte::log* log_h_) { log_h = log_h_; }
void reset()
{
last_preamble_idx = 0;
last_target_power = 0;
prach_delay_cnt = 0;
prach_tti = 0;
nof_rar_grants = 0;
rar_temp_rnti = 0;
rar_time_adv = 0;
last_crnti = 0;
prach_transmitted = false;
prach_info_tx = false;
}
void set_prach_tti(uint32_t tti, bool reset_transmitted = true)
{
this->prach_tti = tti;
if (reset_transmitted) {
prach_transmitted = false;
}
}
// phy_interface_mac_lte
void configure_prach_params(){};
void prach_send(uint32_t preamble_idx, int allowed_subframe, float target_power_dbm, float ta_base_sec)
{
prach_delay_cnt = 0;
last_preamble_idx = preamble_idx;
last_target_power = target_power_dbm;
prach_transmitted = true;
prach_info_tx = true;
log_h->info("PRACH will be transmitted at tti=%d, preamble_idx=%d\n", prach_tti, preamble_idx);
}
prach_info_t prach_get_info()
{
prach_info_t info = {};
if (prach_info_tx) {
prach_delay_cnt++;
if (prach_delay_cnt > prach_delay) {
info.tti_ra = prach_tti;
prach_info_tx = false;
info.is_transmitted = true;
log_h->info("PRACH has been transmitted\n");
}
}
return info;
};
void sr_send(){};
int sr_last_tx_tti() { return 0; };
void set_mch_period_stop(uint32_t stop){};
// phy_interface_mac_common
void set_crnti(uint16_t rnti) { last_crnti = rnti; }
void set_timeadv_rar(uint32_t ta_cmd) { rar_time_adv = ta_cmd; }
void set_timeadv(uint32_t ta_cmd){};
void set_activation_deactivation_scell(uint32_t cmd) { scell_cmd = cmd; };
void set_rar_grant(uint8_t grant_payload[SRSLTE_RAR_GRANT_LEN], uint16_t rnti)
{
memcpy(rar_payload, grant_payload, SRSLTE_RAR_GRANT_LEN);
rar_temp_rnti = rnti;
nof_rar_grants++;
}
uint32_t get_current_tti() { return 0; }
float get_phr() { return 0; };
float get_pathloss_db() { return 0; };
// getter for test execution
uint32_t get_scell_cmd() { return scell_cmd; }
// Testing methods
int dl_grant(mac* mac_h, bool ack, uint16_t rnti, uint32_t len, const uint8_t* payload)
{
bool ack_v[SRSLTE_MAX_CODEWORDS] = {ack, 0};
mac_interface_phy_lte::tb_action_dl_t dl_action = {};
mac_interface_phy_lte::mac_grant_dl_t dl_mac_grant = {};
// Send grant to MAC
dl_mac_grant.rnti = rnti;
dl_mac_grant.tb[0].ndi = dl_ndi;
dl_mac_grant.tb[0].ndi_present = true;
dl_mac_grant.tb[0].tbs = len;
mac_h->new_grant_dl(0, dl_mac_grant, &dl_action);
if (ack && !SRSLTE_RNTI_ISRAR(rnti)) {
dl_ndi = !dl_ndi;
}
TESTASSERT(dl_action.tb[0].enabled);
TESTASSERT((int)dl_action.tb[0].rv == dl_mac_grant.tb[0].rv);
// Copy data and send tb_decoded
memcpy(dl_action.tb[0].payload, payload, len);
// print generated PDU
log_h->info_hex(
dl_action.tb[0].payload, dl_mac_grant.tb[0].tbs, "Generated DL PDU (%d B)\n", dl_mac_grant.tb[0].tbs);
#if HAVE_PCAP
pcap_handle->write_dl_crnti(dl_action.tb[0].payload, dl_mac_grant.tb[0].tbs, rnti, true, 1);
#endif
mac_h->tb_decoded(0, dl_mac_grant, ack_v);
return 0;
}
int rar_and_check(mac* mac_h, bool preamble_matches, uint32_t temp_rnti)
{
// Generate RAR to MAC
uint8_t grant[SRSLTE_RAR_GRANT_LEN] = {1};
uint32_t rar_timeadv = 16;
srslte::rar_pdu rar_pdu_msg;
byte_buffer.clear();
rar_pdu_msg.init_tx(&byte_buffer, 7);
if (rar_pdu_msg.new_subh()) {
rar_pdu_msg.get()->set_rapid(preamble_matches ? last_preamble_idx : (last_preamble_idx + 1));
rar_pdu_msg.get()->set_ta_cmd(rar_timeadv);
rar_pdu_msg.get()->set_temp_crnti(temp_rnti);
rar_pdu_msg.get()->set_sched_grant(grant);
}
rar_pdu_msg.write_packet(byte_buffer.msg);
// Send RAR grant to MAC
dl_grant(mac_h, true, get_rar_rnti(), 7, byte_buffer.msg);
// Check MAC passes RAR grant and TA cmd to PHY
if (preamble_matches) {
TESTASSERT(!memcmp(rar_payload, grant, SRSLTE_RAR_GRANT_LEN));
TESTASSERT(rar_temp_rnti == temp_rnti);
TESTASSERT(rar_time_adv == rar_timeadv);
}
return 0;
}
int ul_grant_and_check_tv(mac* mac_h,
bool ack,
uint16_t rnti,
uint32_t len,
const uint8_t* tv,
bool is_rar = false,
bool adaptive_retx = false)
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t ul_mac_grant = {};
if (ack) {
ul_ndi = !ul_ndi;
}
// Generate UL Grant
if (!adaptive_retx) {
ul_mac_grant.phich_available = !ack;
ul_mac_grant.tb.ndi = ul_ndi;
ul_mac_grant.tb.ndi_present = ack;
} else {
ul_mac_grant.hi_value = true;
ul_mac_grant.phich_available = true;
ul_mac_grant.tb.ndi = ul_ndi;
ul_mac_grant.tb.ndi_present = true;
}
ul_mac_grant.is_rar = is_rar;
ul_mac_grant.rnti = rnti;
ul_mac_grant.tb.tbs = len;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac_h->new_grant_ul(0, ul_mac_grant, &ul_action);
// print generated PDU
log_h->info_hex(ul_action.tb.payload, ul_mac_grant.tb.tbs, "Generated UL PDU (%d B)\n", ul_mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, ul_mac_grant.tb.tbs, rnti, true, 1);
#endif
if (tv && ul_action.tb.payload) {
return memcmp(ul_action.tb.payload, tv, len);
} else {
return 0;
}
}
int get_last_preamble() { return last_preamble_idx; }
uint32_t is_prach_transmitted() { return prach_transmitted; }
uint32_t get_rar_rnti() { return (prach_tti % 10) + 1; }
uint16_t get_crnti() { return last_crnti; }
const static uint32_t prach_delay = 5;
private:
uint32_t scell_cmd = 0;
uint32_t prach_delay_cnt = 0;
uint32_t prach_tti = 0;
bool prach_info_tx = false;
bool prach_transmitted = false;
float last_target_power = 0;
int last_preamble_idx = -1;
uint16_t last_crnti = 0;
srslte::log* log_h;
bool ul_ndi = false;
bool dl_ndi = false;
byte_buffer_t byte_buffer;
uint32_t nof_rar_grants = 0;
uint32_t rar_time_adv = 0;
uint16_t rar_temp_rnti = 0;
uint8_t rar_payload[SRSLTE_RAR_GRANT_LEN];
};
class rrc_dummy : public rrc_interface_mac
{
public:
void ho_ra_completed(bool ra_successful)
{
ho_finish = true;
ho_finish_successful = ra_successful;
}
void release_pucch_srs() { printf("%s\n", __FUNCTION__); }
void run_tti(uint32_t tti) { printf("%s\n", __FUNCTION__); }
void ra_problem() { rach_problem++; }
bool ho_finish = false;
bool ho_finish_successful = false;
uint32_t rach_problem = 0;
};
class stack_dummy : public stack_dummy_interface
{
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public:
void init(mac* mac_, phy_interface_mac_lte* phy_)
{
mac_h = mac_;
phy_h = phy_;
}
bool events_exist()
{
for (int i = 0; i < pending_tasks.nof_queues(); ++i) {
if (not pending_tasks.empty(i)) {
return true;
}
}
return false;
}
void run_tti(uint32_t tti)
{
mac_h->run_tti(tti);
// flush all events
if (events_exist()) {
srslte::move_task_t task{};
if (pending_tasks.wait_pop(&task) >= 0) {
task();
}
}
timers.step_all();
}
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private:
phy_interface_mac_lte* phy_h = nullptr;
mac* mac_h = nullptr;
};
} // namespace srslte
int mac_unpack_test()
{
// This MAC PDU contains three subheaders
const uint32_t mac_header_len = 4;
// Subheader 1 is SCell Activation/Deactivation CE
// - 1 byte SDU payload 0x02
const uint32_t mac_pdu1_len = 1;
// Subheader 2 is for LCID 1
// - 2 bytes SDU payload 0x00 0x08
const uint32_t mac_pdu2_len = 2;
// Subheader 3 is for LCID 3 (RLC AM PDU with 2 B header and 54 B data)
// - 56 bytes SDU payload 0x98 .. 0x89, 0x00, 0x00
const uint32_t mac_pdu3_len = 56;
uint8_t dl_sch_pdu[] = {0x3b, 0x21, 0x02, 0x03, 0x02, 0x00, 0x08, 0x98, 0x1b, 0x45, 0x00, 0x05, 0xda,
0xc7, 0x23, 0x40, 0x00, 0x40, 0x11, 0xe6, 0x9b, 0xc0, 0xa8, 0x03, 0x01, 0xc0,
0xa8, 0x03, 0x02, 0xd8, 0x29, 0x13, 0x89, 0x05, 0xc6, 0x2b, 0x73, 0x00, 0x0d,
0xc3, 0xb3, 0x5c, 0xa3, 0x23, 0xad, 0x00, 0x03, 0x20, 0x1b, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x13, 0x89, 0x00, 0x00};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
// create dummy DL action and grant and push MAC PDU
mac_interface_phy_lte::tb_action_dl_t dl_action;
mac_interface_phy_lte::mac_grant_dl_t mac_grant;
bzero(&dl_action, sizeof(dl_action));
bzero(&mac_grant, sizeof(mac_grant));
mac_grant.rnti = 0xbeaf;
mac_grant.tb[0].tbs = sizeof(dl_sch_pdu);
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_dl(cc_idx, mac_grant, &dl_action);
// Copy PDU into provided buffer
bool dl_ack[SRSLTE_MAX_CODEWORDS] = {true, false};
memcpy(dl_action.tb[0].payload, dl_sch_pdu, sizeof(dl_sch_pdu));
dl_action.tb[0].enabled = true;
mac.tb_decoded(cc_idx, mac_grant, dl_ack);
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
mac.stop();
// check length of both received RLC PDUs
TESTASSERT(rlc.get_received_bytes() == mac_pdu2_len + mac_pdu3_len);
// check received SCell activation command
TESTASSERT(phy.get_scell_cmd() == 2);
return SRSLTE_SUCCESS;
}
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// Basic test with a single padding byte and a 10B SCH SDU
int mac_ul_sch_pdu_test1()
{
const uint8_t tv[] = {0x3f, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
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// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
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const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// write dummy data
rlc.write_sdu(1, 10);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 12; // give room for MAC subheader, SDU and one padding byte
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
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#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
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mac.stop();
return SRSLTE_SUCCESS;
}
// Basic logical channel prioritization test with 3 SCH SDUs
int mac_ul_logical_channel_prioritization_test1()
{
// PDU layout (21 B in total)
// - 2 B MAC subheader for SCH LCID=1
// - 2 B MAC subheader for SCH LCID=2
// - 1 B MAC subheader for SCH LCID=3
// - 10 B MAC SDU for LCID=1
// - 4 B MAC SDU for LCID=2
// - 2 B MAC SDU for LCID=3
const uint8_t tv[] = {0x21, 0x0a, 0x22, 0x04, 0x03, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
0x01, 0x01, 0x01, 0x01, 0x02, 0x02, 0x02, 0x02, 0x03, 0x03};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
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// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
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const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// generate configs for three LCIDs with different priority and PBR
std::vector<logical_channel_config_t> lcids;
logical_channel_config_t config = {};
config.lcid = 1;
config.lcg = 1;
config.PBR = 10;
config.BSD = 1000; // 1000ms
config.priority = 1; // highest prio
lcids.push_back(config);
config.lcid = 2;
config.lcg = 1;
config.PBR = 4;
config.priority = 2;
lcids.push_back(config);
config.lcid = 3;
config.lcg = 1;
config.PBR = 2;
config.priority = 3;
lcids.push_back(config);
// setup LCIDs in MAC
for (auto& channel : lcids) {
mac.setup_lcid(channel.lcid, channel.lcg, channel.priority, channel.PBR, channel.BSD);
}
// run TTI to setup Bj, no UL data available yet, so no BSR should be triggered
stack.run_tti(0);
usleep(200);
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// write dummy data for each LCID (except CCCH)
rlc.write_sdu(1, 50);
rlc.write_sdu(2, 40);
rlc.write_sdu(3, 20);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 21; // each LCID has more data to transmit than is available
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
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#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
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mac.stop();
return SRSLTE_SUCCESS;
}
// Similar test like above but with a much larger UL grant, we expect that each LCID is fully served
int mac_ul_logical_channel_prioritization_test2()
{
// PDU layout (120 B in total)
// - 1 B MAC subheader for Short BSR
// - 2 B MAC subheader for SCH LCID=1
// - 2 B MAC subheader for SCH LCID=2
// - 2 B MAC subheader for SCH LCID=3
// - 1 B MAC subheader for Padding
//
// - 1 B Short BSR
// - 50 B MAC SDU for LCID=1
// - 40 B MAC SDU for LCID=2
// - 20 B MAC SDU for LCID=3
// - 1 B Padding
// =120 N
const uint8_t tv[] = {0x3d, 0x21, 0x32, 0x22, 0x28, 0x23, 0x14, 0x1f, 0x51, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
6 years ago
0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01,
0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x02,
0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02,
0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02,
0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03,
0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x00};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
6 years ago
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
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const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// generate configs for three LCIDs with different priority and PBR
std::vector<logical_channel_config_t> lcids;
logical_channel_config_t config = {};
config.lcid = 1;
config.lcg = 1;
config.PBR = 10;
config.BSD = 1000; // 1000ms
config.priority = 1; // highest prio
lcids.push_back(config);
config.lcid = 2;
config.lcg = 1;
config.PBR = 4;
config.priority = 2;
lcids.push_back(config);
config.lcid = 3;
config.lcg = 1;
config.PBR = 2;
config.priority = 3;
lcids.push_back(config);
// setup LCIDs in MAC
for (auto& channel : lcids) {
mac.setup_lcid(channel.lcid, channel.lcg, channel.priority, channel.PBR, channel.BSD);
}
// write dummy data for each LCID (except CCCH)
rlc.write_sdu(1, 50);
rlc.write_sdu(2, 40);
rlc.write_sdu(3, 20);
// run TTI to setup Bj, BSR should be generated
stack.run_tti(0);
usleep(100);
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// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 120; // each LCID has more data to transmit than is available
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
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#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
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mac.stop();
return SRSLTE_SUCCESS;
}
// Basic logical channel prioritization test with 2 SCH SDUs
// Using default setting for dedicated bearer
int mac_ul_logical_channel_prioritization_test3()
{
// PDU layout (21 B in total)
// - 2 B MAC subheader for SCH LCID=4
// - 1 B MAC subheader for SCH LCID=3
// - 10 B MAC SDU for LCID=4
// - 8 B MAC SDU for LCID=3
const uint8_t tv[] = {0x24, 0x0a, 0x03, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04, 0x04,
0x04, 0x04, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03, 0x03};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
6 years ago
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
6 years ago
const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// generate configs for two LCIDs with different priority and PBR
std::vector<logical_channel_config_t> lcids;
logical_channel_config_t config = {};
// The config of DRB1
config.lcid = 3;
config.lcg = 3;
config.PBR = 8; // 8 kByte/s
config.BSD = 100; // 100ms
config.priority = 15;
6 years ago
lcids.push_back(config);
// DRB2
config.lcid = 4;
config.lcg = 1;
config.PBR = 0; // no PBR
config.priority = 7; // higher prio
6 years ago
lcids.push_back(config);
// setup LCIDs in MAC
for (auto& channel : lcids) {
mac.setup_lcid(channel.lcid, channel.lcg, channel.priority, channel.PBR, channel.BSD);
}
// run TTI to setup Bj
stack.run_tti(0);
sleep(1);
6 years ago
// write dummy data for each LCID
rlc.write_sdu(3, 50);
rlc.write_sdu(4, 50);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 21; // each LCID has more data to transmit than is available
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
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#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
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mac.stop();
return SRSLTE_SUCCESS;
}
// PDU with single SDU and short BSR
int mac_ul_sch_pdu_with_short_bsr_test()
{
const uint8_t tv[] = {0x3f, 0x3d, 0x01, 0x02, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// generate configs for two LCIDs with different priority and PBR
std::vector<logical_channel_config_t> lcids;
logical_channel_config_t config = {};
// The config of DRB1
config.lcid = 3;
config.lcg = 3;
config.PBR = 8;
config.BSD = 100; // 100ms
config.priority = 15;
lcids.push_back(config);
// DRB2
config.lcid = 4;
config.lcg = 1;
config.PBR = 0;
config.priority = 7;
lcids.push_back(config);
// setup LCIDs in MAC
for (auto& channel : lcids) {
mac.setup_lcid(channel.lcid, channel.lcg, channel.priority, channel.PBR, channel.BSD);
}
// write dummy data
rlc.write_sdu(1, 10);
// generate TTI
uint32 tti = 0;
stack.run_tti(tti++);
usleep(100);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 14; // give room for MAC subheader, SDU and short BSR
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(tti);
mac.stop();
return SRSLTE_SUCCESS;
}
// PDU with only padding BSR (long BSR) and the rest padding
int mac_ul_sch_pdu_with_padding_bsr_test()
{
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// create UL action and grant and push MAC PDU
{
const uint8_t tv[] = {0x3e, 0x1f, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 10; // give enough room for Padding BSR
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// create UL action and grant and push MAC PDU
{
const uint8_t tv[] = {0x1c, 0x42};
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.pid = 2;
mac_grant.tb.tbs = 2; // give enough room for Padding BSR
int cc_idx = 0;
// Add data to multiple LCID
mac.setup_lcid(1, 1, 1, -1, 0);
mac.setup_lcid(2, 2, 2, -1, 0);
rlc.disable_read();
rlc.write_sdu(1, 10);
rlc.write_sdu(2, 100);
stack.run_tti(1);
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
mac.stop();
return SRSLTE_SUCCESS;
}
// Single byte MAC PDU
int mac_ul_sch_pdu_one_byte_test()
{
const uint8_t tv[] = {0x1f};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// write dummy data
rlc.write_sdu(0, 10);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 1;
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
mac.stop();
return SRSLTE_SUCCESS;
}
// Two byte MAC PDU
int mac_ul_sch_pdu_two_byte_test()
{
const uint8_t tv[] = {0x01, 0x01};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// write dummy data
rlc.write_sdu(1, 10);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 2;
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
mac.stop();
return SRSLTE_SUCCESS;
}
// Three byte MAC PDU (Single byte padding, SDU header, 1 B SDU)
int mac_ul_sch_pdu_three_byte_test()
{
const uint8_t tv[] = {0x3f, 0x01, 0x01};
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// the actual MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
const uint16_t crnti = 0x1001;
mac.set_ho_rnti(crnti, 0);
// write dummy data
rlc.write_sdu(1, 1);
// create UL action and grant and push MAC PDU
{
mac_interface_phy_lte::tb_action_ul_t ul_action = {};
mac_interface_phy_lte::mac_grant_ul_t mac_grant = {};
mac_grant.rnti = crnti; // make sure MAC picks it up as valid UL grant
mac_grant.tb.ndi_present = true;
mac_grant.tb.ndi = true;
mac_grant.tb.tbs = 3;
int cc_idx = 0;
// Send grant to MAC and get action for this TB, then call tb_decoded to unlock MAC
mac.new_grant_ul(cc_idx, mac_grant, &ul_action);
// print generated PDU
mac_log->info_hex(ul_action.tb.payload, mac_grant.tb.tbs, "Generated PDU (%d B)\n", mac_grant.tb.tbs);
#if HAVE_PCAP
pcap_handle->write_ul_crnti(ul_action.tb.payload, mac_grant.tb.tbs, 0x1001, true, 1);
#endif
TESTASSERT(memcmp(ul_action.tb.payload, tv, sizeof(tv)) == 0);
}
// make sure MAC PDU thread picks up before stopping
sleep(1);
stack.run_tti(0);
mac.stop();
return SRSLTE_SUCCESS;
}
struct ra_test {
uint32_t nof_prachs;
uint32_t rar_nof_rapid; // set to zero to don't transmit RAR
uint32_t rar_nof_invalid_rapid;
uint16_t crnti;
uint16_t temp_rnti;
uint32_t nof_msg3_retx;
uint32_t preamble_idx;
int assume_prach_transmitted;
bool send_valid_ul_grant;
bool msg4_enable;
bool msg4_valid_conres;
bool check_ra_successful;
asn1::rrc::rach_cfg_common_s rach_cfg;
};
struct ra_test test;
int run_mac_ra_test(struct ra_test test, mac* mac, phy_dummy* phy, uint32_t* tti_state, srslte::stack_dummy* stack)
{
uint32_t tti = *tti_state;
6 years ago
const uint8_t tv_msg3[] = {0x3c, 0x00, 0x01, 0x0f, 0x0f, 0x0f, 0x0f, 0x0f, 0x0f};
const uint8_t tv_msg3_ce[] = {0x1b, 0x00, 0x65};
uint32_t msg4_len = 7;
const uint8_t tv_msg4_nocontres[] = {0x1f, 0x1f};
const uint8_t tv_msg4_valid[] = {0x1c, 0x0f, 0x0f, 0x0f, 0x0f, 0x0f, 0x0f};
const uint8_t tv_msg4_invalid[] = {0x1c, 0x0f, 0x0a, 0x0f, 0x0f, 0x0f, 0x0f};
uint16_t temp_rnti = test.temp_rnti;
bool new_prach = false;
for (uint32_t j = 0; j < test.nof_prachs; j++) {
// In the next TTI, a BSR shall be triggered which triggers SR which triggers PRACH
if (test.assume_prach_transmitted != (int)j) {
phy->set_prach_tti(tti + phy->prach_delay);
stack->run_tti(tti++);
}
// Check MAC instructs PHY to transmit PRACH
TESTASSERT(phy->is_prach_transmitted());
// Test preamble index
if (test.preamble_idx) {
TESTASSERT(phy->get_last_preamble() == (int)test.preamble_idx);
} else {
TESTASSERT(phy->get_last_preamble() < test.rach_cfg.preamb_info.nof_ra_preambs.to_number());
}
// TODO: Test power ramping
// Check MAC does not schedule RA-RNTI before window starts
for (uint32_t i = 0; i < phy->prach_delay + 3 - 1; i++) {
stack->run_tti(tti);
TESTASSERT(!SRSLTE_RNTI_ISRAR(mac->get_dl_sched_rnti(tti)));
tti++;
}
bool rapid_found = false;
// Check MAC schedules correct RA-RNTI during window
for (uint32_t i = 0; i < test.rach_cfg.ra_supervision_info.ra_resp_win_size.to_number() && !rapid_found; i++) {
stack->run_tti(tti);
TESTASSERT(mac->get_dl_sched_rnti(tti) == phy->get_rar_rnti());
tti++;
// Receive RAR
if (test.rar_nof_rapid > 0) {
rapid_found = i >= test.rar_nof_invalid_rapid;
if (phy->rar_and_check(mac, rapid_found, temp_rnti)) {
return -1;
}
}
}
// Run Contention Resolution if received correct RAPID
if (rapid_found) {
// Skip Contention resolution if preamble chosen by network
if (test.preamble_idx) {
break;
}
// Request Msg3 (re)-transmission
for (uint32_t i = 0; i < test.nof_msg3_retx + 1; i++) {
// Step to contention resolution. Make sure timer does not start until Msg3 is transmitted
// and restarts on every retx
for (int j = 0; j < test.rach_cfg.ra_supervision_info.mac_contention_resolution_timer.to_number() - 1; j++) {
stack->run_tti(tti);
TESTASSERT(mac->get_dl_sched_rnti(tti) == (test.crnti ? test.crnti : test.temp_rnti));
tti++;
}
if (i == test.rach_cfg.max_harq_msg3_tx) {
phy->set_prach_tti(tti + phy->prach_delay, false);
}
if (test.crnti) {
TESTASSERT(!phy->ul_grant_and_check_tv(mac, i == 0, temp_rnti, 3, tv_msg3_ce, i == 0));
} else {
TESTASSERT(!phy->ul_grant_and_check_tv(mac, i == 0, temp_rnti, 9, tv_msg3, i == 0, i == 1));
}
}
if (test.nof_msg3_retx == test.rach_cfg.max_harq_msg3_tx) {
TESTASSERT(mac->get_dl_sched_rnti(tti) != temp_rnti);
break;
}
for (int i = 0; i < test.rach_cfg.ra_supervision_info.mac_contention_resolution_timer.to_number() - 1; i++) {
stack->run_tti(tti);
TESTASSERT(mac->get_dl_sched_rnti(tti) == (test.crnti ? test.crnti : test.temp_rnti));
tti++;
if (test.msg4_enable) {
if (test.crnti) {
// Test a DL grant does not resolve the contention resolution
if (phy->dl_grant(mac, true, test.crnti, 2, tv_msg4_nocontres)) {
return -1;
}
TESTASSERT(phy->get_crnti() != test.crnti);
// UL grant is checked later
if (test.send_valid_ul_grant) {
if (phy->ul_grant_and_check_tv(mac, true, test.crnti, 2, NULL)) {
return -1;
}
break;
} else if ((int)i == test.rach_cfg.ra_supervision_info.mac_contention_resolution_timer.to_number() - 2) {
new_prach = true;
}
} else {
if (phy->dl_grant(
mac, true, temp_rnti, msg4_len, test.msg4_valid_conres ? tv_msg4_valid : tv_msg4_invalid)) {
return -1;
}
if (!test.msg4_valid_conres) {
new_prach = true;
}
break;
}
}
}
}
if (new_prach) {
test.assume_prach_transmitted = (int)j + 1;
phy->set_prach_tti(tti + phy->prach_delay, false);
TESTASSERT(mac->get_dl_sched_rnti(tti) != temp_rnti);
stack->run_tti(tti++);
}
}
// RA procedure should be completed here
if (test.check_ra_successful) {
stack->run_tti(tti);
TESTASSERT(phy->get_crnti() == (test.crnti ? test.crnti : test.temp_rnti));
TESTASSERT(mac->get_dl_sched_rnti(tti) == (test.crnti ? test.crnti : test.temp_rnti));
tti++;
}
*tti_state = tti;
return 0;
}
/* Tests MAC RA procedure specified in 5.1 of 36.321
* Currently not covered:
* - Selection of groupA/groupB sequences
* - Backoff timer
* - PDCCH order RACH initiation
* - Ignore RAR TA cmd when TA-Timer is running
*/
int mac_random_access_test()
{
uint64_t contention_id = 0xf0f0f0f0f0f;
srslte::log_filter phy_log("PHY");
phy_log.set_level(srslte::LOG_LEVEL_DEBUG);
phy_log.set_hex_limit(100000);
srslte::log_filter rlc_log("RLC");
rlc_log.set_level(srslte::LOG_LEVEL_DEBUG);
rlc_log.set_hex_limit(100000);
// dummy layers
phy_dummy phy;
phy.set_log(&phy_log);
rlc_dummy rlc(&rlc_log);
rrc_dummy rrc;
stack_dummy stack;
// Configure default RACH parameters
asn1::rrc::rach_cfg_common_s rach_cfg = {};
rach_cfg.preamb_info.nof_ra_preambs = asn1::rrc::rach_cfg_common_s::preamb_info_s_::nof_ra_preambs_opts::n12;
rach_cfg.ra_supervision_info.preamb_trans_max = asn1::rrc::preamb_trans_max_opts::n8;
rach_cfg.ra_supervision_info.ra_resp_win_size =
asn1::rrc::rach_cfg_common_s::ra_supervision_info_s_::ra_resp_win_size_e_::sf4;
rach_cfg.max_harq_msg3_tx = 2;
rach_cfg.ra_supervision_info.mac_contention_resolution_timer =
asn1::rrc::rach_cfg_common_s::ra_supervision_info_s_::mac_contention_resolution_timer_opts::sf8;
// Configure MAC
mac mac("MAC");
stack.init(&mac, &phy);
mac.init(&phy, &rlc, &rrc, &stack);
srslte::mac_cfg_t mac_cfg;
set_mac_cfg_t_rach_cfg_common(&mac_cfg, rach_cfg);
mac.set_config(mac_cfg);
// generate config for LCIDs in different LCGs than CCCH
std::vector<logical_channel_config_t> lcids;
logical_channel_config_t config = {};
// The config of DRB1
config.lcid = 3;
config.lcg = 3;
config.PBR = 8;
config.BSD = 100; // 100ms
config.priority = 15;
lcids.push_back(config);
// setup LCIDs in MAC
for (auto& channel : lcids) {
mac.setup_lcid(channel.lcid, channel.lcg, channel.priority, channel.PBR, channel.BSD);
}
// Generate Msg3
mac.set_contention_id(contention_id);
rlc.write_sdu(0, 6); // UL-CCCH with Msg3
rlc.write_sdu(3, 100); // DRB data on other LCG
uint32 tti = 0;
// Structure that defines the test to be executed
struct ra_test my_test = {};
uint32_t test_id = 1;
my_test.temp_rnti = 100;
my_test.assume_prach_transmitted = -1;
// Test 1: No RAR is received.
// According to end of 5.1.5, UE sends up to preamb_trans_max upon which indicates RA problem to higher layers
mac_log->info("\n=========== Test %d =============\n", test_id++);
my_test.rach_cfg = rach_cfg;
my_test.nof_prachs = rach_cfg.ra_supervision_info.preamb_trans_max.to_number();
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
// Make sure it triggers RRC signal
stack.run_tti(tti++);
TESTASSERT(rrc.rach_problem == 1);
// Reset MAC
mac.reset();
phy.reset();
mac.set_contention_id(contention_id);
// Test 2: RAR received but no matching RAPID
// The UE receives a RAR without a matching RAPID on every RAR response window TTI.
// According to 5.1.5, the RA procedure is considered non successful and tries again
mac_log->info("\n=========== Test %d =============\n", test_id++);
my_test.rar_nof_rapid = 1;
my_test.nof_prachs = 1;
my_test.rar_nof_invalid_rapid = rach_cfg.ra_supervision_info.ra_resp_win_size.to_number();
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
// Test 3: RAR received but no matching RAPID. Test Msg3 retransmissions
// On each HARQ retx, contention resolution timer must be restarted (5.1.5)
// When max-HARQ-msg3-retx, contention not successful
mac_log->info("\n=========== Test %d =============\n", test_id++);
my_test.rar_nof_invalid_rapid = 0;
my_test.nof_msg3_retx = rach_cfg.max_harq_msg3_tx;
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
// Test 4: RAR with valid RAPID. Msg3 transmitted, Msg4 received but invalid ConRes
// Contention resolution is defined in 5.1.5. If ConResID does not match, the ConRes is considered
// not successful and tries again
mac_log->info("\n=========== Test %d =============\n", test_id++);
phy.reset();
my_test.nof_msg3_retx = 0;
my_test.msg4_enable = true;
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
// Test 5: Msg4 received and valid ConRes. In this case a valid ConResID is received and RA procedure is successful
mac_log->info("\n=========== Test %d =============\n", test_id++);
my_test.temp_rnti++; // Temporal C-RNTI has to change to avoid duplicate
my_test.msg4_valid_conres = true;
my_test.check_ra_successful = true;
my_test.assume_prach_transmitted = 0;
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
// Test 6: RA with existing C-RNTI (Sends C-RNTI MAC CE)
// The transmission of C-RNTI MAC CE is only done if no CCCH is present (5.1.4).
// To trigger a new RA we have to either generate more data for DRB or wait until BSR-reTX is triggered
rlc.write_sdu(3, 100);
phy.set_crnti(0);
mac_log->info("\n=========== Test %d =============\n", test_id++);
my_test.crnti = my_test.temp_rnti;
my_test.temp_rnti++; // Temporal C-RNTI has to change to avoid duplicate
my_test.assume_prach_transmitted = -1;
my_test.send_valid_ul_grant = true;
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
// Test 7: Test Contention based Random Access. This is used eg in HO where preamble is chosen by UE.
// It is similar to Test 5 because C-RNTI is available to the UE when start the RA but
// In this case we will let the procedure expire the Contention Resolution window and make sure
// and RRC HO fail signal is sent to RRC.
mac_log->info("\n=========== Test %d =============\n", test_id++);
phy.set_prach_tti(tti + phy.prach_delay);
phy.set_crnti(0);
mac.start_cont_ho();
stack.run_tti(tti++);
rrc.ho_finish = false;
my_test.nof_prachs = rach_cfg.ra_supervision_info.preamb_trans_max.to_number();
my_test.temp_rnti++; // Temporal C-RNTI has to change to avoid duplicate
my_test.msg4_valid_conres = false;
my_test.assume_prach_transmitted = 0;
my_test.check_ra_successful = false;
my_test.send_valid_ul_grant = false;
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
TESTASSERT(!rrc.ho_finish_successful && rrc.ho_finish);
// Test 8: Test Contention based Random Access. Same as above but we let the procedure finish successfully.
mac_log->info("\n=========== Test %d =============\n", test_id++);
phy.set_prach_tti(tti + phy.prach_delay);
phy.set_crnti(0);
mac.start_cont_ho();
stack.run_tti(tti++);
rrc.ho_finish = false;
my_test.nof_prachs = 1;
my_test.temp_rnti++; // Temporal C-RNTI has to change to avoid duplicate
my_test.send_valid_ul_grant = true;
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
TESTASSERT(rrc.ho_finish_successful && rrc.ho_finish);
// Test 9: Test non-Contention based HO. Used in HO but preamble is given by the network. In addition to checking
// that the given preamble is correctly passed to the PHY, in this case there is no contention.
// In this first test, no RAR is received and RA procedure fails
mac_log->info("\n=========== Test %d =============\n", test_id++);
phy.set_prach_tti(tti + phy.prach_delay);
stack.run_tti(tti++);
phy.set_crnti(0);
rrc.ho_finish = false;
my_test.preamble_idx = 3;
mac.start_noncont_ho(my_test.preamble_idx, 0);
my_test.nof_prachs = rach_cfg.ra_supervision_info.preamb_trans_max.to_number();
my_test.rar_nof_invalid_rapid = rach_cfg.ra_supervision_info.ra_resp_win_size.to_number();
my_test.temp_rnti++; // Temporal C-RNTI has to change to avoid duplicate
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
stack.run_tti(tti++);
TESTASSERT(!rrc.ho_finish_successful && rrc.ho_finish);
// Test 10: Test non-Contention based HO. Used in HO but preamble is given by the network. We check that
// the procedure is considered successful without waiting for contention
mac_log->info("\n=========== Test %d =============\n", test_id++);
phy.set_prach_tti(tti + phy.prach_delay);
stack.run_tti(tti++);
phy.set_crnti(0);
rrc.ho_finish = false;
my_test.preamble_idx = 3;
mac.start_noncont_ho(my_test.preamble_idx, 0);
my_test.nof_prachs = 1;
my_test.rar_nof_invalid_rapid = 0;
my_test.check_ra_successful = true;
my_test.temp_rnti++; // Temporal C-RNTI has to change to avoid duplicate
TESTASSERT(!run_mac_ra_test(my_test, &mac, &phy, &tti, &stack));
stack.run_tti(tti++);
TESTASSERT(rrc.ho_finish_successful && rrc.ho_finish);
mac.stop();
return SRSLTE_SUCCESS;
}
int main(int argc, char** argv)
{
6 years ago
#if HAVE_PCAP
pcap_handle = std::unique_ptr<srslte::mac_pcap>(new srslte::mac_pcap());
pcap_handle->open("mac_test.pcap");
#endif
mac_log->set_level(srslte::LOG_LEVEL_DEBUG);
mac_log->set_hex_limit(100000);
if (mac_unpack_test()) {
printf("MAC PDU unpack test failed.\n");
return -1;
}
6 years ago
if (mac_ul_sch_pdu_test1()) {
printf("mac_ul_sch_pdu_test1() test failed.\n");
return -1;
}
if (mac_ul_logical_channel_prioritization_test1()) {
printf("mac_ul_logical_channel_prioritization_test1() test failed.\n");
return -1;
}
if (mac_ul_logical_channel_prioritization_test2()) {
printf("mac_ul_logical_channel_prioritization_test2() test failed.\n");
return -1;
}
if (mac_ul_logical_channel_prioritization_test3()) {
printf("mac_ul_logical_channel_prioritization_test3() test failed.\n");
return -1;
}
if (mac_ul_sch_pdu_with_short_bsr_test()) {
printf("mac_ul_sch_pdu_with_long_bsr_test() test failed.\n");
return -1;
}
if (mac_ul_sch_pdu_with_padding_bsr_test()) {
printf("mac_ul_sch_pdu_with_padding_bsr_test() test failed.\n");
return -1;
}
if (mac_ul_sch_pdu_one_byte_test()) {
printf("mac_ul_sch_pdu_one_byte_test() test failed.\n");
return -1;
}
if (mac_ul_sch_pdu_two_byte_test()) {
printf("mac_ul_sch_pdu_two_byte_test() test failed.\n");
return -1;
}
if (mac_ul_sch_pdu_three_byte_test()) {
printf("mac_ul_sch_pdu_three_byte_test() test failed.\n");
return -1;
}
if (mac_random_access_test()) {
6 years ago
printf("mac_random_access_test() test failed.\n");
return -1;
}
return 0;
}