/* simple test for the gsm0408 formatting functions */ /* * (C) 2008 by Holger Hans Peter Freyther * All Rights Reserved * * This program 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. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define COMPARE(result, op, value) \ if (!((result) op (value))) {\ fprintf(stderr, "Compare failed. Was %x should be %x in %s:%d\n",result, value, __FILE__, __LINE__); \ exit(-1); \ } #define COMPARE_STR(result, value) \ if (strcmp(result, value) != 0) { \ fprintf(stderr, "Compare failed. Was %s should be %s in %s:%d\n",result, value, __FILE__, __LINE__); \ exit(-1); \ } #define DBG(...) #define VERIFY(res, cmp, wanted) \ if (!(res cmp wanted)) { \ printf("ASSERT failed: %s:%d Wanted: %d %s %d\n", \ __FILE__, __LINE__, (int) res, # cmp, (int) wanted); \ } static inline void gen(struct gsm_bts *bts, const char *s) { int r; bts->si_valid = 0; bts->si_valid |= (1 << SYSINFO_TYPE_2quater); printf("generating SI2quater for %zu EARFCNs and %zu UARFCNs...\n", si2q_earfcn_count(&bts->si_common.si2quater_neigh_list), bts->si_common.uarfcn_length); r = gsm_generate_si(bts, SYSINFO_TYPE_2quater); if (r > 0) for (bts->si2q_index = 0; bts->si2q_index < bts->si2q_count + 1; bts->si2q_index++) printf("generated %s SI2quater [%02u/%02u]: [%d] %s\n", GSM_BTS_HAS_SI(bts, SYSINFO_TYPE_2quater) ? "valid" : "invalid", bts->si2q_index, bts->si2q_count, r, osmo_hexdump((void *)GSM_BTS_SI2Q(bts, bts->si2q_index), GSM_MACBLOCK_LEN)); else printf("%s() failed to generate SI2quater: %s\n", s, strerror(-r)); } static inline void del_earfcn_b(struct gsm_bts *bts, uint16_t earfcn) { struct osmo_earfcn_si2q *e = &bts->si_common.si2quater_neigh_list; int r = osmo_earfcn_del(e, earfcn); if (r) printf("failed to remove EARFCN %u: %s\n", earfcn, strerror(-r)); else printf("removed EARFCN %u - ", earfcn); gen(bts, __func__); } static inline void add_earfcn_b(struct gsm_bts *bts, uint16_t earfcn, uint8_t bw) { struct osmo_earfcn_si2q *e = &bts->si_common.si2quater_neigh_list; int r = osmo_earfcn_add(e, earfcn, bw); if (r) printf("failed to add EARFCN %u: %s\n", earfcn, strerror(-r)); else printf("added EARFCN %u - ", earfcn); gen(bts, __func__); } static inline void _bts_uarfcn_add(struct gsm_bts *bts, uint16_t arfcn, uint16_t scramble, bool diversity) { int r; bts->u_offset = 0; r = bts_uarfcn_add(bts, arfcn, scramble, diversity); if (r < 0) printf("failed to add UARFCN to SI2quater: %s\n", strerror(-r)); else { bts->si2q_count = si2q_num(bts) - 1; gen(bts, __func__); } } #define bts_init(net) _bts_init(net, __func__) static inline struct gsm_bts *_bts_init(struct gsm_network *net, const char *msg) { struct gsm_bts_sm *bts_sm = gsm_bts_sm_alloc(net, 0); struct gsm_bts *bts = bts_sm->bts[0]; if (!bts) { printf("BTS allocation failure in %s()\n", msg); exit(1); } printf("BTS allocation OK in %s()\n", msg); bts->network = net; return bts; } #define bts_del(bts) _bts_del(bts, __func__) static inline void _bts_del(struct gsm_bts *bts, const char *msg) { osmo_timer_del(&bts->acc_mgr.rotate_timer); /* no need to llist_del(&bts->list), we never registered the bts there. */ talloc_free(bts->site_mgr); printf("BTS deallocated OK in %s()\n", msg); } static inline void test_si2q_segfault(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); printf("Test SI2quater UARFCN (same scrambling code and diversity):\n"); _bts_uarfcn_add(bts, 10564, 319, 0); _bts_uarfcn_add(bts, 10612, 319, 0); gen(bts, __func__); bts_del(bts); } static inline void test_si2q_mu(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); printf("Test SI2quater multiple UARFCNs:\n"); _bts_uarfcn_add(bts, 10564, 318, 0); _bts_uarfcn_add(bts, 10612, 319, 0); _bts_uarfcn_add(bts, 10612, 31, 0); _bts_uarfcn_add(bts, 10612, 19, 0); _bts_uarfcn_add(bts, 10613, 64, 0); _bts_uarfcn_add(bts, 10613, 164, 0); _bts_uarfcn_add(bts, 10613, 14, 0); bts_del(bts); } static inline void test_si2q_u(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); printf("Testing SYSINFO_TYPE_2quater UARFCN generation:\n"); /* first generate invalid SI as no UARFCN added */ gen(bts, __func__); /* subsequent calls should produce valid SI if there's enough memory */ _bts_uarfcn_add(bts, 1982, 13, 1); _bts_uarfcn_add(bts, 1982, 44, 0); _bts_uarfcn_add(bts, 1982, 61, 1); _bts_uarfcn_add(bts, 1982, 89, 1); _bts_uarfcn_add(bts, 1982, 113, 0); _bts_uarfcn_add(bts, 1982, 123, 0); _bts_uarfcn_add(bts, 1982, 56, 1); _bts_uarfcn_add(bts, 1982, 72, 1); _bts_uarfcn_add(bts, 1982, 223, 1); _bts_uarfcn_add(bts, 1982, 14, 0); _bts_uarfcn_add(bts, 1982, 88, 0); bts_del(bts); } static inline void test_si2q_e(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); printf("Testing SYSINFO_TYPE_2quater EARFCN generation:\n"); bts->si_common.si2quater_neigh_list.arfcn = bts->si_common.data.earfcn_list; bts->si_common.si2quater_neigh_list.meas_bw = bts->si_common.data.meas_bw_list; bts->si_common.si2quater_neigh_list.length = MAX_EARFCN_LIST; bts->si_common.si2quater_neigh_list.thresh_hi = 5; osmo_earfcn_init(&bts->si_common.si2quater_neigh_list); /* first generate invalid SI as no EARFCN added */ gen(bts, __func__); /* subsequent calls should produce valid SI if there's enough memory and EARFCNs */ add_earfcn_b(bts, 1917, 5); del_earfcn_b(bts, 1917); add_earfcn_b(bts, 1917, 1); add_earfcn_b(bts, 1932, OSMO_EARFCN_MEAS_INVALID); add_earfcn_b(bts, 1937, 2); add_earfcn_b(bts, 1945, OSMO_EARFCN_MEAS_INVALID); add_earfcn_b(bts, 1965, OSMO_EARFCN_MEAS_INVALID); add_earfcn_b(bts, 1967, 4); add_earfcn_b(bts, 1982, 3); bts_del(bts); } static inline void test_si2q_long(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); printf("Testing SYSINFO_TYPE_2quater combined EARFCN & UARFCN generation:\n"); bts->si_common.si2quater_neigh_list.arfcn = bts->si_common.data.earfcn_list; bts->si_common.si2quater_neigh_list.meas_bw = bts->si_common.data.meas_bw_list; bts->si_common.si2quater_neigh_list.length = MAX_EARFCN_LIST; bts->si_common.si2quater_neigh_list.thresh_hi = 5; osmo_earfcn_init(&bts->si_common.si2quater_neigh_list); bts_earfcn_add(bts, 1922, 11, 22, 8,32, 8); bts_earfcn_add(bts, 1922, 11, 22, 8, 32, 8); bts_earfcn_add(bts, 1924, 11, 12, 6, 11, 5); bts_earfcn_add(bts, 1923, 11, 12, 6, 11, 5); bts_earfcn_add(bts, 1925, 11, 12, 6, 11, 5); bts_earfcn_add(bts, 2111, 11, 12, 6, 11, 5); bts_earfcn_add(bts, 2112, 11, 12, 6, 11, 4); bts_earfcn_add(bts, 2113, 11, 12, 6, 11, 3); bts_earfcn_add(bts, 2114, 11, 12, 6, 11, 2); bts_earfcn_add(bts, 2131, 11, 12, 6, 11, 5); bts_earfcn_add(bts, 2132, 11, 12, 6, 11, 4); bts_earfcn_add(bts, 2133, 11, 12, 6, 11, 3); bts_earfcn_add(bts, 2134, 11, 12, 6, 11, 2); bts_earfcn_add(bts, 2121, 11, 12, 6, 11, 5); bts_earfcn_add(bts, 2122, 11, 12, 6, 11, 4); bts_earfcn_add(bts, 2123, 11, 12, 6, 11, 3); bts_earfcn_add(bts, 2124, 11, 12, 6, 11, 2); _bts_uarfcn_add(bts, 1976, 13, 1); _bts_uarfcn_add(bts, 1976, 38, 1); _bts_uarfcn_add(bts, 1976, 44, 1); _bts_uarfcn_add(bts, 1976, 120, 1); _bts_uarfcn_add(bts, 1976, 140, 1); _bts_uarfcn_add(bts, 1976, 163, 1); _bts_uarfcn_add(bts, 1976, 166, 1); _bts_uarfcn_add(bts, 1976, 217, 1); _bts_uarfcn_add(bts, 1976, 224, 1); _bts_uarfcn_add(bts, 1976, 225, 1); _bts_uarfcn_add(bts, 1976, 226, 1); bts_del(bts); } static void test_si_ba_ind(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); const struct gsm48_system_information_type_2 *si2 = (struct gsm48_system_information_type_2 *) GSM_BTS_SI(bts, SYSINFO_TYPE_2); const struct gsm48_system_information_type_2bis *si2bis = (struct gsm48_system_information_type_2bis *) GSM_BTS_SI(bts, SYSINFO_TYPE_2bis); const struct gsm48_system_information_type_2ter *si2ter = (struct gsm48_system_information_type_2ter *) GSM_BTS_SI(bts, SYSINFO_TYPE_2ter); const struct gsm48_system_information_type_5 *si5 = (struct gsm48_system_information_type_5 *) GSM_BTS_SI(bts, SYSINFO_TYPE_5); const struct gsm48_system_information_type_5bis *si5bis = (struct gsm48_system_information_type_5bis *) GSM_BTS_SI(bts, SYSINFO_TYPE_5bis); const struct gsm48_system_information_type_5ter *si5ter = (struct gsm48_system_information_type_5ter *) GSM_BTS_SI(bts, SYSINFO_TYPE_5ter); int rc; bts->c0->arfcn = 23; printf("Testing if BA-IND is set as expected in SI2xxx and SI5xxx\n"); rc = gsm_generate_si(bts, SYSINFO_TYPE_2); OSMO_ASSERT(rc > 0); printf("SI2: %s\n", osmo_hexdump((uint8_t *)si2, rc)); /* Validate BA-IND == 0 */ OSMO_ASSERT(!(si2->bcch_frequency_list[0] & 0x10)); rc = gsm_generate_si(bts, SYSINFO_TYPE_2bis); OSMO_ASSERT(rc > 0); printf("SI2bis: %s\n", osmo_hexdump((uint8_t *)si2bis, rc)); /* Validate BA-IND == 0 */ OSMO_ASSERT(!(si2bis->bcch_frequency_list[0] & 0x10)); rc = gsm_generate_si(bts, SYSINFO_TYPE_2ter); OSMO_ASSERT(rc > 0); printf("SI2ter: %s\n", osmo_hexdump((uint8_t *)si2ter, rc)); /* Validate BA-IND == 0 */ OSMO_ASSERT(!(si2ter->ext_bcch_frequency_list[0] & 0x10)); rc = gsm_generate_si(bts, SYSINFO_TYPE_5); OSMO_ASSERT(rc > 0); printf("SI5: %s\n", osmo_hexdump((uint8_t *)si5, rc)); /* Validate BA-IND == 1 */ OSMO_ASSERT(si5->bcch_frequency_list[0] & 0x10); rc = gsm_generate_si(bts, SYSINFO_TYPE_5bis); OSMO_ASSERT(rc > 0); printf("SI5bis: %s\n", osmo_hexdump((uint8_t *)si5bis, rc)); /* Validate BA-IND == 1 */ OSMO_ASSERT(si5bis->bcch_frequency_list[0] & 0x10); rc = gsm_generate_si(bts, SYSINFO_TYPE_5ter); OSMO_ASSERT(rc > 0); printf("SI5ter: %s\n", osmo_hexdump((uint8_t *)si5ter, rc)); /* Validate BA-IND == 1 */ OSMO_ASSERT(si5ter->bcch_frequency_list[0] & 0x10); bts_del(bts); } struct test_gsm48_ra_id_by_bts { struct osmo_plmn_id plmn; uint16_t lac; uint8_t rac; struct gsm48_ra_id expect; }; static const struct test_gsm48_ra_id_by_bts test_gsm48_ra_id_by_bts_data[] = { { .plmn = { .mcc = 1, .mnc = 2, .mnc_3_digits = false }, .lac = 3, .rac = 4, .expect = { .digits = { 0x00, 0xf1, 0x20 }, .lac = 0x0300, /* network byte order of 3 */ .rac = 4, }, }, { .plmn = { .mcc = 1, .mnc = 2, .mnc_3_digits = true }, .lac = 3, .rac = 4, .expect = { .digits = { 0x00, 0x21, 0x00 }, .lac = 0x0300, /* network byte order of 3 */ .rac = 4, }, }, { .plmn = { .mcc = 0, .mnc = 0, .mnc_3_digits = false }, .lac = 0, .rac = 0, .expect = { .digits = { 0x00, 0xf0, 0x00 }, }, }, { .plmn = { .mcc = 0, .mnc = 0, .mnc_3_digits = true }, .lac = 0, .rac = 0, .expect = { .digits = {}, }, }, { .plmn = { .mcc = 999, .mnc = 999, .mnc_3_digits = false }, .lac = 65535, .rac = 255, .expect = { .digits = { 0x99, 0x99, 0x99 }, .lac = 0xffff, .rac = 0xff, }, }, { .plmn = { .mcc = 909, .mnc = 90, .mnc_3_digits = false }, .lac = 0xabcd, .rac = 0xab, .expect = { .digits = { 0x09, 0xf9, 0x09 }, .lac = 0xcdab, .rac = 0xab, }, }, { .plmn = { .mcc = 909, .mnc = 90, .mnc_3_digits = true }, .lac = 0xabcd, .rac = 0xab, .expect = { .digits = { 0x09, 0x09, 0x90 }, .lac = 0xcdab, .rac = 0xab, }, }, }; static void test_gsm48_ra_id_by_bts(void) { int i; bool pass = true; for (i = 0; i < ARRAY_SIZE(test_gsm48_ra_id_by_bts_data); i++) { struct gsm_network net; struct gsm_bts bts; const struct test_gsm48_ra_id_by_bts *t = &test_gsm48_ra_id_by_bts_data[i]; struct gsm48_ra_id result = {}; bool ok; net.plmn = t->plmn; bts.network = &net; bts.location_area_code = t->lac; bts.gprs.rac = t->rac; gsm48_ra_id_by_bts(&result, &bts); ok = (t->expect.digits[0] == result.digits[0]) && (t->expect.digits[1] == result.digits[1]) && (t->expect.digits[2] == result.digits[2]) && (t->expect.lac == result.lac) && (t->expect.rac == result.rac); printf("%s[%d]: digits='%02x%02x%02x' lac=0x%04x=htons(%u) rac=0x%02x=%u %s\n", __func__, i, result.digits[0], result.digits[1], result.digits[2], result.lac, osmo_ntohs(result.lac), result.rac, result.rac, ok ? "pass" : "FAIL"); pass = pass && ok; } OSMO_ASSERT(pass); } static void test_gsm48_multirate_config(void) { struct gsm48_multi_rate_conf *gsm48_ie; struct amr_multirate_conf mr; int rc; struct msgb *msg = msgb_alloc(32, "test_gsm48_multirate_config"); memset(&mr, 0, sizeof(mr)); /* Use some made up threshold and hysteresis values */ mr.ms_mode[0].threshold = 11; mr.ms_mode[1].threshold = 12; mr.ms_mode[2].threshold = 13; mr.ms_mode[0].hysteresis = 15; mr.ms_mode[1].hysteresis = 12; mr.ms_mode[2].hysteresis = 8; gsm48_ie = (struct gsm48_multi_rate_conf *)&mr.gsm48_ie; gsm48_ie->ver = 1; gsm48_ie->m5_90 = 1; gsm48_ie->m7_40 = 1; gsm48_ie->m7_95 = 1; gsm48_ie->m12_2 = 1; /* Test #1: Normal configuration with 4 active set members */ mr.ms_mode[0].mode = 2; mr.ms_mode[1].mode = 4; mr.ms_mode[2].mode = 5; mr.ms_mode[3].mode = 7; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 4); OSMO_ASSERT(rc == 0); printf("gsm48_multirate_config(): rc=%i, lv=%s\n", rc, osmo_hexdump_nospc(msg->data, msg->len)); /* Test #2: 4 active set members, but wrong mode order: */ mr.ms_mode[3].mode = 2; mr.ms_mode[2].mode = 4; mr.ms_mode[1].mode = 5; mr.ms_mode[0].mode = 7; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 4); OSMO_ASSERT(rc == -EINVAL); /* Test #3: Normal configuration with 3 active set members */ mr.ms_mode[0].mode = 2; mr.ms_mode[1].mode = 4; mr.ms_mode[2].mode = 5; mr.ms_mode[3].mode = 7; gsm48_ie->m12_2 = 0; mr.ms_mode[2].threshold = 0; mr.ms_mode[2].hysteresis = 0; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 3); OSMO_ASSERT(rc == 0); printf("gsm48_multirate_config(): rc=%i, lv=%s\n", rc, osmo_hexdump_nospc(msg->data, msg->len)); /* Test #4: 3 active set members, but wrong mode order: */ mr.ms_mode[0].mode = 2; mr.ms_mode[2].mode = 4; mr.ms_mode[1].mode = 5; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 3); OSMO_ASSERT(rc == -EINVAL); /* Test #5: Normal configuration with 2 active set members */ mr.ms_mode[0].mode = 2; mr.ms_mode[1].mode = 4; mr.ms_mode[2].mode = 5; mr.ms_mode[3].mode = 7; gsm48_ie->m7_95 = 0; mr.ms_mode[1].threshold = 0; mr.ms_mode[1].hysteresis = 0; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 2); OSMO_ASSERT(rc == 0); printf("gsm48_multirate_config(): rc=%i, lv=%s\n", rc, osmo_hexdump_nospc(msg->data, msg->len)); /* Test #6: 2 active set members, but wrong mode order: */ mr.ms_mode[1].mode = 2; mr.ms_mode[0].mode = 4; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 2); OSMO_ASSERT(rc == -EINVAL); /* Test #7: Normal configuration with 1 active set member */ mr.ms_mode[0].mode = 2; mr.ms_mode[1].mode = 4; mr.ms_mode[2].mode = 5; mr.ms_mode[3].mode = 7; gsm48_ie->m7_40 = 0; mr.ms_mode[0].threshold = 0; mr.ms_mode[0].hysteresis = 0; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 1); OSMO_ASSERT(rc == 0); printf("gsm48_multirate_config(): rc=%i, lv=%s\n", rc, osmo_hexdump_nospc(msg->data, msg->len)); /* Test #8: 0 active set members: */ mr.ms_mode[0].mode = 0; msgb_trim(msg, 0); rc = gsm48_multirate_config(msg, gsm48_ie, mr.ms_mode, 1); OSMO_ASSERT(rc == -EINVAL); msgb_free(msg); } /* Similar to list_arfcn() from system_information.c, but uses printf(). * Another difference is that the text is printed even if n is 0. */ static void print_cell_chan_desc(uint8_t *cd, const char *text) { struct gsm_sysinfo_freq freq[1024]; unsigned int n = 0, i; memset(freq, 0, sizeof(freq)); gsm48_decode_freq_list(freq, cd, 16, 0xce, 1); printf("%s:", text); for (i = 0; i < 1024; i++) { if (!freq[i].mask) continue; printf(" %u", i); n++; } if (!n) printf(" (empty set)"); printf("\n"); } static void test_cell_chan_desc(struct gsm_network *net) { struct gsm_bts *bts = bts_init(net); uint8_t cell_chan_desc[16]; printf("Testing generation of the Cell Channel Description IE:\n"); bts_model_unknown_init(); bts->type = GSM_BTS_TYPE_UNKNOWN; bts->model = bts_model_find(bts->type); OSMO_ASSERT(bts->model != NULL); bts->band = GSM_BAND_900; bts->c0->arfcn = 10; /* BCCH carrier */ /* Case a) only the BCCH carrier */ bitvec_set_bit_pos(&bts->si_common.cell_alloc, bts->c0->arfcn, ONE); OSMO_ASSERT(generate_cell_chan_list(&cell_chan_desc[0], bts) == 0); print_cell_chan_desc(&cell_chan_desc[0], "Case a) only the BCCH carrier"); /* Case b) more carriers from P-GSM band */ bitvec_set_bit_pos(&bts->si_common.cell_alloc, 1, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 3, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 64, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 99, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 124, ONE); OSMO_ASSERT(generate_cell_chan_list(&cell_chan_desc[0], bts) == 0); print_cell_chan_desc(&cell_chan_desc[0], "Case b) more carriers from P-GSM band"); /* Case c) more carriers from E-GSM band */ bitvec_set_bit_pos(&bts->si_common.cell_alloc, 0, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 975, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 1001, ONE); bitvec_set_bit_pos(&bts->si_common.cell_alloc, 1023, ONE); OSMO_ASSERT(generate_cell_chan_list(&cell_chan_desc[0], bts) == 0); print_cell_chan_desc(&cell_chan_desc[0], "Case c) more carriers from E-GSM band"); bts_del(bts); } static const struct log_info_cat log_categories[] = { }; static const struct log_info log_info = { .cat = log_categories, .num_cat = ARRAY_SIZE(log_categories), }; int main(int argc, char **argv) { struct gsm_network *net; tall_bsc_ctx = talloc_named_const(NULL, 0, "gsm0408_test"); osmo_init_logging2(tall_bsc_ctx, &log_info); log_set_log_level(osmo_stderr_target, LOGL_INFO); net = gsm_network_init(tall_bsc_ctx); if (!net) { printf("Network init failure.\n"); return EXIT_FAILURE; } bsc_gsmnet = net; test_si2q_segfault(net); test_si2q_e(net); test_si2q_u(net); test_si2q_mu(net); test_si2q_long(net); test_si_ba_ind(net); test_gsm48_ra_id_by_bts(); test_gsm48_multirate_config(); test_cell_chan_desc(net); printf("Done.\n"); return EXIT_SUCCESS; }