/* * 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/common/common.h" #include "srslte/common/interfaces_common.h" #include "srslte/common/logmap.h" #include "srslte/common/mac_pcap.h" #include "srslte/common/test_common.h" #include "srslte/interfaces/ue_interfaces.h" #include "srslte/mac/pdu.h" #include #include #include #include #define HAVE_PCAP 0 std::random_device rd; std::mt19937 rand_gen(rd()); std::uniform_int_distribution uniform_dist_u8(0, 255); static std::unique_ptr pcap_handle = nullptr; using namespace srslte; #define CRNTI (0x1001) // TV1 contains a RAR PDU for a single RAPID and no backoff indication #define RAPID_TV1 (42) #define TA_CMD_TV1 (8) uint8_t rar_pdu_tv1[] = {0x6a, 0x00, 0x80, 0x00, 0x0c, 0x10, 0x01}; // TV2 contains a RAR PDU for a single RAPID and also includes a backoff indication subheader #define RAPID_TV2 (22) #define BACKOFF_IND_TV2 (2) #define TA_CMD_TV2 (0) uint8_t rar_pdu_tv2[] = {0x82, 0x56, 0x00, 0x00, 0x00, 0x0c, 0x10, 0x01}; int mac_rar_pdu_unpack_test1() { srslte::rar_pdu rar_pdu_msg; rar_pdu_msg.init_rx(sizeof(rar_pdu_tv1)); rar_pdu_msg.parse_packet(rar_pdu_tv1); rar_pdu_msg.fprint(stdout); TESTASSERT(not rar_pdu_msg.has_backoff()); while (rar_pdu_msg.next()) { TESTASSERT(rar_pdu_msg.get()->get_rapid() == RAPID_TV1); TESTASSERT(rar_pdu_msg.get()->get_ta_cmd() == TA_CMD_TV1); TESTASSERT(rar_pdu_msg.get()->get_temp_crnti() == CRNTI); } return SRSLTE_SUCCESS; } int mac_rar_pdu_unpack_test2() { srslte::rar_pdu rar_pdu_msg; rar_pdu_msg.init_rx(sizeof(rar_pdu_tv2)); rar_pdu_msg.parse_packet(rar_pdu_tv2); rar_pdu_msg.fprint(stdout); TESTASSERT(rar_pdu_msg.has_backoff()); TESTASSERT(rar_pdu_msg.get_backoff() == BACKOFF_IND_TV2); while (rar_pdu_msg.next()) { if (rar_pdu_msg.get()->has_rapid()) { TESTASSERT(rar_pdu_msg.get()->get_rapid() == RAPID_TV2); TESTASSERT(rar_pdu_msg.get()->get_ta_cmd() == TA_CMD_TV2); TESTASSERT(rar_pdu_msg.get()->get_temp_crnti() == CRNTI); } } return SRSLTE_SUCCESS; } int mac_rar_pdu_pack_test1() { // Prepare RAR grant uint8_t grant_buffer[64] = {}; srslte_dci_rar_grant_t rar_grant = {}; rar_grant.tpc_pusch = 3; srslte_dci_rar_pack(&rar_grant, grant_buffer); // Create MAC PDU and add RAR subheader srslte::rar_pdu rar_pdu; byte_buffer_t tx_buffer; rar_pdu.init_tx(&tx_buffer, 64); if (rar_pdu.new_subh()) { rar_pdu.get()->set_rapid(RAPID_TV1); rar_pdu.get()->set_ta_cmd(TA_CMD_TV1); rar_pdu.get()->set_temp_crnti(CRNTI); rar_pdu.get()->set_sched_grant(grant_buffer); } rar_pdu.write_packet(tx_buffer.msg); // compare with TV1 TESTASSERT(memcmp(tx_buffer.msg, rar_pdu_tv1, sizeof(rar_pdu_tv1)) == 0); return SRSLTE_SUCCESS; } int mac_rar_pdu_pack_test2() { // Prepare RAR grant uint8_t grant_buffer[64] = {}; srslte_dci_rar_grant_t rar_grant = {}; rar_grant.tpc_pusch = 3; srslte_dci_rar_pack(&rar_grant, grant_buffer); // Create MAC PDU and add RAR subheader srslte::rar_pdu rar_pdu; byte_buffer_t tx_buffer; rar_pdu.init_tx(&tx_buffer, 64); rar_pdu.set_backoff(BACKOFF_IND_TV2); if (rar_pdu.new_subh()) { rar_pdu.get()->set_rapid(RAPID_TV2); rar_pdu.get()->set_ta_cmd(TA_CMD_TV2); rar_pdu.get()->set_temp_crnti(CRNTI); rar_pdu.get()->set_sched_grant(grant_buffer); } rar_pdu.write_packet(tx_buffer.msg); // compare with TV2 TESTASSERT(memcmp(tx_buffer.msg, rar_pdu_tv2, sizeof(rar_pdu_tv2)) == 0); return SRSLTE_SUCCESS; } // Helper class to provide read_pdu_interface class rlc_dummy : public srslte::read_pdu_interface { public: int read_pdu(uint32_t lcid, uint8_t* payload, uint32_t nof_bytes) { 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, len); // remove from UL queue ul_queues[lcid] -= len; return len; }; void write_sdu(uint32_t lcid, uint32_t nof_bytes) { ul_queues[lcid] += nof_bytes; } private: // UL queues where key is LCID and value the queue length std::map ul_queues; }; // Basic test to pack a MAC PDU with a two SDUs of short length (i.e < 128B for short length header) and multi-byte // padding int mac_sch_pdu_pack_test1() { static uint8_t tv[] = {0x21, 0x08, 0x22, 0x08, 0x1f, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x00, 0x00, 0x00, 0x00}; srslte::log_filter rlc_log("RLC"); rlc_log.set_level(srslte::LOG_LEVEL_DEBUG); rlc_log.set_hex_limit(100000); rlc_dummy rlc; srslte::log_ref mac_log = srslte::logmap::get("MAC"); mac_log->set_level(srslte::LOG_LEVEL_DEBUG); mac_log->set_hex_limit(100000); // create RLC SDUs const uint32_t sdu_len = 8; rlc.write_sdu(1, sdu_len); rlc.write_sdu(2, sdu_len); const uint32_t pdu_size = 25; srslte::sch_pdu pdu(10, mac_log); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Add first subheader and SDU TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(1, sdu_len, &rlc) == sdu_len); // Have used 8 B SDU plus 1 B subheader TESTASSERT(pdu.rem_size() == pdu_size - 8 - 1); // Add second SCH TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(2, sdu_len, &rlc) == sdu_len); TESTASSERT(pdu.rem_size() == pdu_size - 16 - 3); // write PDU TESTASSERT(pdu.write_packet(mac_log) == buffer.msg); TESTASSERT(buffer.N_bytes == pdu_size); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif // compare with TV TESTASSERT(memcmp(buffer.msg, tv, sizeof(tv)) == 0); return SRSLTE_SUCCESS; } // Basic test to pack a MAC PDU with a two SDUs of short length (i.e < 128B for short length header) and 2x single-byte // padding int mac_sch_pdu_pack_test2() { static uint8_t tv[] = {0x3f, 0x3f, 0x21, 0x08, 0x02, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02}; srslte::log_filter rlc_log("RLC"); rlc_log.set_level(srslte::LOG_LEVEL_DEBUG); rlc_log.set_hex_limit(100000); rlc_dummy rlc; srslte::log_ref mac_log = srslte::logmap::get("MAC"); mac_log->set_level(srslte::LOG_LEVEL_DEBUG); mac_log->set_hex_limit(100000); // create RLC SDUs const uint32_t sdu_len = 8; rlc.write_sdu(1, sdu_len); rlc.write_sdu(2, sdu_len); const uint32_t pdu_size = 21; srslte::sch_pdu pdu(10, mac_log); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Add first subheader and SDU TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(1, sdu_len, &rlc) == sdu_len); // Have used 8 B SDU plus 1 B subheader TESTASSERT(pdu.rem_size() == pdu_size - 8 - 1); // Add second SCH TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(2, sdu_len, &rlc) == sdu_len); TESTASSERT(pdu.rem_size() == pdu_size - 16 - 3); // write PDU pdu.write_packet(mac_log); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif // compare with TV TESTASSERT(memcmp(buffer.msg, tv, sizeof(tv)) == 0); return SRSLTE_SUCCESS; } // Basic test to pack a MAC PDU with one short and one long SDU (i.e >= 128 B for 16bit length header) int mac_sch_pdu_pack_test3() { static uint8_t tv[] = { 0x21, 0x08, 0x22, 0x80, 0x82, 0x1f, 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, 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, 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, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; srslte::log_filter rlc_log("RLC"); rlc_log.set_level(srslte::LOG_LEVEL_DEBUG); rlc_log.set_hex_limit(100000); rlc_dummy rlc; srslte::log_ref mac_log("MAC"); // create RLC SDUs // const uint32_t sdu_len = 130; rlc.write_sdu(1, 8); rlc.write_sdu(2, 130); const uint32_t pdu_size = 150; srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(1, 8, &rlc)); // Have used 8 B SDU plus 1 B subheader TESTASSERT(pdu.rem_size() == pdu_size - 8 - 1); TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(2, 130, &rlc)); // Have used 138 B SDU plus 3 B subheader TESTASSERT(pdu.rem_size() == pdu_size - 138 - 3); // write PDU pdu.write_packet(srslte::log_ref{"MAC"}); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif // compare with TV TESTASSERT(memcmp(buffer.msg, tv, sizeof(tv)) == 0); return SRSLTE_SUCCESS; } // Test for padding-only MAC PDU int mac_sch_pdu_pack_test4() { static uint8_t tv[] = {0x1f, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; srslte::log_filter rlc_log("RLC"); rlc_log.set_level(srslte::LOG_LEVEL_DEBUG); rlc_log.set_hex_limit(100000); rlc_dummy rlc; srslte::log_ref mac_log("MAC"); const uint32_t pdu_size = 10; srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Try to add SDU TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(2, 5, &rlc) == 0); // Adding SDU failed, remove subheader again pdu.del_subh(); // write PDU pdu.write_packet(srslte::log_ref{"MAC"}); // make sure full PDU has been written TESTASSERT(buffer.N_bytes == pdu_size); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif // compare with TV TESTASSERT(memcmp(buffer.msg, tv, sizeof(tv)) == 0); return SRSLTE_SUCCESS; } // Test for max. TBS MAC PDU int mac_sch_pdu_pack_test5() { rlc_dummy rlc; srslte::log_ref mac_log("MAC"); // write big SDU rlc.write_sdu(2, 20000); const uint32_t pdu_size = SRSLTE_MAX_TBSIZE_BITS / 8; // Max. DL allocation for a single TB using 256 QAM srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Try to add SDU TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_sdu(2, pdu_size - 1, &rlc) != 0); // write PDU pdu.write_packet(srslte::log_ref{"MAC"}); // make sure full PDU has been written TESTASSERT(buffer.N_bytes == pdu_size); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } // Test for BSR CE int mac_sch_pdu_pack_test6() { srslte::log_ref mac_log("MAC"); const uint32_t pdu_size = 8; srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); uint8_t tv[pdu_size] = {0x3e, 0x1f, 0x01, 0xfa, 0x7f, 0x00, 0x00, 0x00}; byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Try to Long BSR CE uint32_t buff_size[4] = {0, 1000, 5000, 19200000}; TESTASSERT(pdu.new_subh()); TESTASSERT(pdu.get()->set_bsr(buff_size, srslte::ul_sch_lcid::LONG_BSR)); // write PDU pdu.write_packet(srslte::log_ref{"MAC"}); // compare with tv TESTASSERT(memcmp(buffer.msg, tv, buffer.N_bytes) == 0); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } // Test for short MAC PDU containing padding only int mac_sch_pdu_pack_test7() { srslte::log_ref mac_log("MAC"); rlc_dummy rlc; rlc.write_sdu(1, 8); const uint32_t pdu_size = 2; srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); uint8_t tv[pdu_size] = {0x1f, 0x1f}; byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Try to add SDU, subheader is ok TESTASSERT(pdu.new_subh()); // adding SDU fails TESTASSERT(pdu.get()->set_sdu(2, 8, &rlc) == SRSLTE_ERROR); // remove subheader again pdu.del_subh(); // write PDU pdu.write_packet(srslte::log_ref{"MAC"}); // compare with tv TESTASSERT(memcmp(buffer.msg, tv, buffer.N_bytes) == 0); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } // Test Packing of SCell Activation CE command int mac_sch_pdu_pack_test8() { srslte::log_ref log_h{"MAC"}; const uint32_t pdu_size = 2; srslte::sch_pdu pdu(10, log_h); std::bitset<8> cc_mask(uniform_dist_u8(rand_gen)); // subheader: R|F2|E|LCID = 0|0|0|11011 uint8_t tv[pdu_size] = {0b00011011, (uint8_t)cc_mask.to_ulong()}; // ensure reserved bit tv[1] &= ~(0x1u); // limit to max carriers tv[1] &= ((1u << (uint32_t)SRSLTE_MAX_CARRIERS) - 1u); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // Try SCell activation CE TESTASSERT(pdu.new_subh()); std::array cc_activ_list = {}; for (uint8_t i = 1; i < SRSLTE_MAX_CARRIERS; ++i) { cc_activ_list[i] = cc_mask.test(i); } TESTASSERT(pdu.get()->set_scell_activation_cmd(cc_activ_list)); // write PDU pdu.write_packet(log_h); // compare with tv TESTASSERT(memcmp(buffer.msg, tv, buffer.N_bytes) == 0); // log log_h->info("Activation mask chosen was 0x%x", tv[1]); log_h->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU with SCell Activation CE (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_dl_crnti(tv, sizeof(tv), 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } // Test for checking error cases int mac_sch_pdu_pack_error_test() { srslte::log_filter rlc_log("RLC"); rlc_log.set_level(srslte::LOG_LEVEL_DEBUG); rlc_log.set_hex_limit(100000); rlc_dummy rlc; srslte::log_ref mac_log("MAC"); // create RLC SDUs rlc.write_sdu(1, 8); const uint32_t pdu_size = 150; srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); byte_buffer_t buffer; pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(pdu.rem_size() == pdu_size); TESTASSERT(pdu.get_pdu_len() == pdu_size); TESTASSERT(pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(pdu.get_current_sdu_ptr() == buffer.msg); // set msg pointer almost to end of byte buffer int buffer_space = buffer.get_tailroom(); buffer.msg += buffer_space - 2; // subheader can be added TESTASSERT(pdu.new_subh()); // adding SDU fails TESTASSERT(pdu.get()->set_sdu(1, 8, &rlc) == SRSLTE_ERROR); // writing PDU fails TESTASSERT(pdu.write_packet(srslte::log_ref{"MAC"}) == nullptr); // reset buffer buffer.clear(); // write SDU again TESTASSERT(pdu.get() != nullptr); TESTASSERT(pdu.get()->set_sdu(1, 100, &rlc) == 8); // only 8 bytes in RLC buffer // writing PDU fails TESTASSERT(pdu.write_packet(srslte::log_ref{"MAC"})); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } int mac_mch_pdu_pack_test1() { static uint8_t tv[] = {0x3e, 0x02, 0x20, 0x05, 0x21, 0x0a, 0x1f, 0x0f, 0xff, 0x01, 0x02, 0x03, 0x04, 0x05, 0x02, 0x04, 0x06, 0x08, 0x0a, 0x0c, 0x0e, 0x10, 0x12, 0x14, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; srslte::log_ref mac_log("MAC"); const uint32_t pdu_size = 30; srslte::mch_pdu mch_pdu(10, srslte::log_ref{"MAC"}); byte_buffer_t buffer; mch_pdu.init_tx(&buffer, pdu_size, true); TESTASSERT(mch_pdu.rem_size() == pdu_size); TESTASSERT(mch_pdu.get_pdu_len() == pdu_size); TESTASSERT(mch_pdu.get_sdu_space() == pdu_size - 1); TESTASSERT(mch_pdu.get_current_sdu_ptr() == buffer.msg); // Add first subheader and SDU TESTASSERT(mch_pdu.new_subh()); TESTASSERT(mch_pdu.get()->set_next_mch_sched_info(1, 0)); // Add second SCH TESTASSERT(mch_pdu.new_subh()); uint8_t sdu[5] = {1, 2, 3, 4, 5}; TESTASSERT(mch_pdu.get()->set_sdu(0, 5, sdu) == 5); TESTASSERT(mch_pdu.new_subh()); uint8_t sdu1[10] = {2, 4, 6, 8, 10, 12, 14, 16, 18, 20}; mch_pdu.get()->set_sdu(1, 10, sdu1); // write PDU TESTASSERT(mch_pdu.write_packet(srslte::log_ref{"MAC"}) == buffer.msg); // log mac_log->info_hex(buffer.msg, buffer.N_bytes, "MAC PDU (%d B):\n", buffer.N_bytes); #if HAVE_PCAP pcap_handle->write_ul_crnti(buffer.msg, buffer.N_bytes, 0x1001, true, 1); #endif // compare with TV TESTASSERT(memcmp(buffer.msg, tv, buffer.N_bytes) == 0); #if HAVE_PCAP pcap_handle->write_ul_crnti(tv, sizeof(tv), 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } // Parsing a corrupted MAC PDU and making sure the PDU is reset and not further processed int mac_sch_pdu_unpack_test1() { static uint8_t tv[] = {0x3f, 0x3f, 0x21, 0x3f, 0x03, 0x00, 0x04, 0x00, 0x04}; srslte::sch_pdu pdu(10, srslte::log_ref{"MAC"}); pdu.init_rx(sizeof(tv), false); pdu.parse_packet(tv); // make sure this PDU is reset and will not be further processed TESTASSERT(pdu.nof_subh() == 0); TESTASSERT(pdu.next() == false); #if HAVE_PCAP pcap_handle->write_ul_crnti(tv, sizeof(tv), 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } // Parsing a (corrupted) MAC PDU that only contains padding int mac_sch_pdu_unpack_test2() { static uint8_t tv[] = {0x3f, 0x3f}; srslte::sch_pdu pdu(20, srslte::log_ref{"MAC"}); pdu.init_rx(sizeof(tv), false); pdu.parse_packet(tv); // make sure this PDU is reset and will not be further processed TESTASSERT(pdu.nof_subh() == 0); TESTASSERT(pdu.next() == false); #if HAVE_PCAP pcap_handle->write_ul_crnti(tv, sizeof(tv), 0x1001, true, 1); #endif return SRSLTE_SUCCESS; } int main(int argc, char** argv) { #if HAVE_PCAP pcap_handle = std::unique_ptr(new srslte::mac_pcap()); pcap_handle->open("mac_pdu_test.pcap"); #endif logmap::set_default_hex_limit(100000); logmap::set_default_log_level(LOG_LEVEL_DEBUG); srslte::log_ref mac_log{"MAC"}; mac_log->set_level(srslte::LOG_LEVEL_DEBUG); mac_log->set_hex_limit(100000); if (mac_rar_pdu_unpack_test1()) { fprintf(stderr, "mac_rar_pdu_unpack_test1 failed.\n"); return SRSLTE_ERROR; } if (mac_rar_pdu_unpack_test2()) { fprintf(stderr, "mac_rar_pdu_unpack_test2 failed.\n"); return SRSLTE_ERROR; } if (mac_rar_pdu_pack_test1()) { fprintf(stderr, "mac_rar_pdu_pack_test1 failed.\n"); return SRSLTE_ERROR; } if (mac_rar_pdu_pack_test2()) { fprintf(stderr, "mac_rar_pdu_pack_test2 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test1()) { fprintf(stderr, "mac_sch_pdu_pack_test1 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test2()) { fprintf(stderr, "mac_sch_pdu_pack_test2 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test3()) { fprintf(stderr, "mac_sch_pdu_pack_test3 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test4()) { fprintf(stderr, "mac_sch_pdu_pack_test4 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test5()) { fprintf(stderr, "mac_sch_pdu_pack_test5 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test6()) { fprintf(stderr, "mac_sch_pdu_pack_test6 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_test7()) { fprintf(stderr, "mac_sch_pdu_pack_test7 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_pack_error_test()) { fprintf(stderr, "mac_sch_pdu_pack_error_test failed.\n"); return SRSLTE_ERROR; } if (mac_mch_pdu_pack_test1()) { fprintf(stderr, "mac_mch_pdu_pack_test1 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_unpack_test1()) { fprintf(stderr, "mac_sch_pdu_unpack_test1 failed.\n"); return SRSLTE_ERROR; } if (mac_sch_pdu_unpack_test2()) { fprintf(stderr, "mac_sch_pdu_unpack_test2 failed.\n"); return SRSLTE_ERROR; } TESTASSERT(mac_sch_pdu_pack_test8() == SRSLTE_SUCCESS); return SRSLTE_SUCCESS; }