/* AllocTest.cpp * * Copyright (C) 2013 by Holger Hans Peter Freyther * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * 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. */ #include "gprs_rlcmac.h" #include "gprs_debug.h" #include "tbf.h" #include "tbf_ul.h" #include "tbf_dl.h" #include "bts.h" #include "gprs_ms.h" #include "bts_pch_timer.h" #include #include extern "C" { #include "mslot_class.h" #include #include #include #include #include } /* globals used by the code */ void *tall_pcu_ctx; int16_t spoof_mnc = 0, spoof_mcc = 0; bool spoof_mnc_3_digits = false; static gprs_rlcmac_tbf *tbf_alloc(struct gprs_rlcmac_bts *bts, GprsMs *ms, gprs_rlcmac_tbf_direction dir, uint8_t use_trx, bool single_slot) { OSMO_ASSERT(ms != NULL); if (dir == GPRS_RLCMAC_UL_TBF) return tbf_alloc_ul_tbf(bts, ms, use_trx, single_slot); else return tbf_alloc_dl_tbf(bts, ms, use_trx, single_slot); } static void check_tfi_usage(struct gprs_rlcmac_bts *bts) { int pdch_no; struct gprs_rlcmac_tbf *tfi_usage[8][8][2][32] = {{{{NULL}}}}; struct llist_head *tbf_lists[2] = { &bts->trx[0].ul_tbfs, &bts->trx[0].dl_tbfs }; struct llist_item *pos; gprs_rlcmac_tbf *tbf; unsigned list_idx; struct gprs_rlcmac_tbf **tbf_var; for (list_idx = 0; list_idx < ARRAY_SIZE(tbf_lists); list_idx += 1) { llist_for_each_entry(pos, tbf_lists[list_idx], list) { tbf = (struct gprs_rlcmac_tbf *)pos->entry; for (pdch_no = 0; pdch_no < 8; pdch_no += 1) { struct gprs_rlcmac_pdch *pdch = tbf->pdch[pdch_no]; if (pdch == NULL) continue; tbf_var = &tfi_usage [tbf->trx->trx_no] [pdch_no] [tbf->direction] [tbf->tfi()]; OSMO_ASSERT(*tbf_var == NULL); if (tbf->direction == GPRS_RLCMAC_DL_TBF) { OSMO_ASSERT(pdch->dl_tbf_by_tfi( tbf->tfi()) == tbf); OSMO_ASSERT(bts_dl_tbf_by_tfi(bts, tbf->tfi(), tbf->trx->trx_no, pdch_no) == tbf); } else { OSMO_ASSERT(pdch->ul_tbf_by_tfi( tbf->tfi()) == tbf); OSMO_ASSERT(bts_ul_tbf_by_tfi(bts, tbf->tfi(), tbf->trx->trx_no, pdch_no) == tbf); } *tbf_var = tbf; OSMO_ASSERT(pdch->assigned_tfi(tbf->direction) & (1 << tbf->tfi())); } } } } static void test_alloc_a(gprs_rlcmac_tbf_direction dir, uint8_t slots, const int count) { int tfi; int i; uint8_t used_trx, tmp_trx; struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); GprsMs *ms; struct gprs_rlcmac_tbf *tbfs[32*8+1] = { 0, }; printf("Testing alloc_a direction(%d)\n", dir); the_pcu->alloc_algorithm = alloc_algorithm_a; struct gprs_rlcmac_trx *trx = &bts->trx[0]; for (i = 0; i < 8; i += 1) if (slots & (1 << i)) trx->pdch[i].enable(); OSMO_ASSERT(count >= 0 && count <= (int)ARRAY_SIZE(tbfs)); /** * Currently alloc_a will only allocate from the first * PDCH and all possible usf's. We run out of usf's before * we are out of tfi's. Observe this and make sure that at * least this part is working okay. */ for (i = 0; i < (int)ARRAY_SIZE(tbfs); ++i) { ms = bts_alloc_ms(bts, 0, 0); tbfs[i] = tbf_alloc(bts, ms, dir, -1, 0); if (tbfs[i] == NULL) break; used_trx = tbfs[i]->trx->trx_no; tfi = bts_tfi_find_free(bts, dir, &tmp_trx, used_trx); OSMO_ASSERT(tbfs[i]->tfi() != tfi); } check_tfi_usage(bts); OSMO_ASSERT(i == count); OSMO_ASSERT(bts_all_pdch_allocated(bts)); for (i = 0; i < count; ++i) if (tbfs[i]) tbf_free(tbfs[i]); ms = bts_alloc_ms(bts, 0, 0); tbfs[0] = tbf_alloc(bts, ms, dir, -1, 0); OSMO_ASSERT(tbfs[0]); tbf_free(tbfs[0]); talloc_free(bts); } static void test_alloc_a() { /* slots 2 - 3 */ test_alloc_a(GPRS_RLCMAC_DL_TBF, 0x0c, 32*2); test_alloc_a(GPRS_RLCMAC_UL_TBF, 0x0c, 14); /* slots 1 - 5 */ test_alloc_a(GPRS_RLCMAC_DL_TBF, 0x1e, 32*4); test_alloc_a(GPRS_RLCMAC_UL_TBF, 0x1e, 28); } static void dump_assignment(struct gprs_rlcmac_tbf *tbf, const char *dir, bool verbose) { if (!verbose) return; for (size_t i = 0; i < ARRAY_SIZE(tbf->pdch); ++i) if (tbf->pdch[i]) printf("PDCH[%zu] is used for %s\n", i, dir); printf("PDCH[%d] is control_ts for %s\n", tbf->control_ts, dir); printf("PDCH[%d] is first common for %s\n", tbf->first_common_ts, dir); } #define ENABLE_PDCH(ts_no, enable_flag, trx) \ if (enable_flag) \ trx->pdch[ts_no].enable(); static inline void enable_ts_on_bts(struct gprs_rlcmac_bts *bts, bool ts0, bool ts1, bool ts2, bool ts3, bool ts4, bool ts5, bool ts6, bool ts7) { struct gprs_rlcmac_trx *trx = &bts->trx[0]; ENABLE_PDCH(0, ts0, trx); ENABLE_PDCH(1, ts1, trx); ENABLE_PDCH(2, ts2, trx); ENABLE_PDCH(3, ts3, trx); ENABLE_PDCH(4, ts4, trx); ENABLE_PDCH(5, ts5, trx); ENABLE_PDCH(6, ts6, trx); ENABLE_PDCH(7, ts7, trx); } static inline bool test_alloc_b_ul_dl(bool ts0, bool ts1, bool ts2, bool ts3, bool ts4, bool ts5, bool ts6, bool ts7, uint8_t ms_class, bool verbose) { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); GprsMs *ms; gprs_rlcmac_ul_tbf *ul_tbf; gprs_rlcmac_dl_tbf *dl_tbf; if (verbose) printf("Testing UL then DL assignment.\n"); the_pcu->alloc_algorithm = alloc_algorithm_b; enable_ts_on_bts(bts, ts0, ts1, ts2, ts3, ts4, ts5, ts6, ts7); ms = bts_alloc_ms(bts, ms_class, 0); /* Avoid delaying free to avoid tons of to-be-freed ms objects queuing */ ms_set_timeout(ms, 0); ul_tbf = tbf_alloc_ul_tbf(bts, ms, -1, true); if (!ul_tbf) return false; OSMO_ASSERT(ul_tbf->ms()); OSMO_ASSERT(ms_current_trx(ul_tbf->ms())); dump_assignment(ul_tbf, "UL", verbose); /* assume final ack has not been sent */ dl_tbf = tbf_alloc_dl_tbf(bts, ms, ms_current_trx(ms)->trx_no, false); if (!dl_tbf) return false; dump_assignment(dl_tbf, "DL", verbose); OSMO_ASSERT(dl_tbf->first_common_ts == ul_tbf->first_common_ts); check_tfi_usage(bts); tbf_free(dl_tbf); tbf_free(ul_tbf); talloc_free(bts); return true; } static inline bool test_alloc_b_dl_ul(bool ts0, bool ts1, bool ts2, bool ts3, bool ts4, bool ts5, bool ts6, bool ts7, uint8_t ms_class, bool verbose) { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); GprsMs *ms; gprs_rlcmac_ul_tbf *ul_tbf; gprs_rlcmac_dl_tbf *dl_tbf; if (verbose) printf("Testing DL then UL assignment followed by update\n"); the_pcu->alloc_algorithm = alloc_algorithm_b; enable_ts_on_bts(bts, ts0, ts1, ts2, ts3, ts4, ts5, ts6, ts7); ms = bts_alloc_ms(bts, ms_class, 0); /* Avoid delaying free to avoid tons of to-be-freed ms objects queuing */ ms_set_timeout(ms, 0); dl_tbf = tbf_alloc_dl_tbf(bts, ms, -1, true); if (!dl_tbf) return false; dl_tbf->update_ms(0x23, GPRS_RLCMAC_DL_TBF); OSMO_ASSERT(dl_tbf->ms() == ms); OSMO_ASSERT(ms_current_trx(dl_tbf->ms())); dump_assignment(dl_tbf, "DL", verbose); ul_tbf = tbf_alloc_ul_tbf(bts, ms, ms_current_trx(ms)->trx_no, false); if (!ul_tbf) return false; ul_tbf->update_ms(0x23, GPRS_RLCMAC_UL_TBF); ul_tbf->m_contention_resolution_done = 1; dump_assignment(ul_tbf, "UL", verbose); OSMO_ASSERT(dl_tbf->first_common_ts == ul_tbf->first_common_ts); /* now update the dl_tbf */ dl_tbf->update(); dump_assignment(dl_tbf, "DL", verbose); OSMO_ASSERT(dl_tbf->first_common_ts == ul_tbf->first_common_ts); check_tfi_usage(bts); tbf_free(dl_tbf); tbf_free(ul_tbf); talloc_free(bts); return true; } static inline bool test_alloc_b_jolly(uint8_t ms_class) { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); GprsMs *ms; int tfi; uint8_t trx_no; gprs_rlcmac_tbf *ul_tbf, *dl_tbf; printf("Testing jolly example\n"); the_pcu->alloc_algorithm = alloc_algorithm_b; enable_ts_on_bts(bts, false, true, true, true, true, false, false, false); tfi = bts_tfi_find_free(bts, GPRS_RLCMAC_UL_TBF, &trx_no, -1); OSMO_ASSERT(tfi >= 0); ms = bts_alloc_ms(bts, ms_class, 0); /* Avoid delaying free to avoid tons of to-be-freed ms objects queuing */ ms_set_timeout(ms, 0); ul_tbf = tbf_alloc_ul_tbf(bts, ms, -1, false); if (!ul_tbf) return false; OSMO_ASSERT(ul_tbf->ms() == ms); OSMO_ASSERT(ms_current_trx(ul_tbf->ms())); trx_no = ms_current_trx(ms)->trx_no; dump_assignment(ul_tbf, "UL", true); /* assume final ack has not been sent */ dl_tbf = tbf_alloc_dl_tbf(bts, ms, trx_no, false); if (!dl_tbf) return false; dump_assignment(dl_tbf, "DL", true); OSMO_ASSERT(dl_tbf->first_common_ts == ul_tbf->first_common_ts); check_tfi_usage(bts); tbf_free(dl_tbf); tbf_free(ul_tbf); talloc_free(bts); return true; } static void test_alloc_b_for_ms(uint8_t ms_class) { bool rc; printf("Going to test multislot assignment MS_CLASS=%d\n", ms_class); /* * PDCH is on TS 6,7,8 and we start with a UL allocation and * then follow two DL allocations (once single, once normal). * * Uplink assigned and still available.. */ rc = test_alloc_b_ul_dl(false, false, false, false, false, true, true, true, ms_class, true); if (!rc) return; /** * Test with the other order.. first DL and then UL */ rc = test_alloc_b_dl_ul(false, false, false, false, false, true, true, true, ms_class, true); if (!rc) return; /* Andreas osmocom-pcu example */ test_alloc_b_jolly(ms_class); } static void test_alloc_mass(bool ts0, bool ts1, bool ts2, bool ts3, bool ts4, bool ts5, bool ts6, bool ts7, int ms_class) { bool rc; /* we can test the allocation failures differently */ if (!ts0 && !ts1 && !ts2 && !ts3 && !ts4 && !ts5 && !ts6 && !ts7) return; printf("Mass test: TS0(%c%c%c%c%c%c%c%c)TS7 MS_Class=%d\n", ts0 ? 'O' : 'x', ts1 ? 'O' : 'x', ts2 ? 'O' : 'x', ts3 ? 'O' : 'x', ts4 ? 'O' : 'x', ts5 ? 'O' : 'x', ts6 ? 'O' : 'x', ts7 ? 'O' : 'x', ms_class); fflush(stdout); rc = test_alloc_b_ul_dl(ts0, ts1, ts2, ts3, ts4, ts5, ts6, ts7, ms_class, false); if (!rc) return; /** * Test with the other order.. first DL and then UL */ test_alloc_b_dl_ul(ts0, ts1, ts2, ts3, ts4, ts5, ts6, ts7, ms_class, false); } static void test_all_alloc_b() { /* it is a bit crazy... */ for (uint8_t ts0 = 0; ts0 < 2; ++ts0) for (uint8_t ts1 = 0; ts1 < 2; ++ts1) for (uint8_t ts2 = 0; ts2 < 2; ++ts2) for (uint8_t ts3 = 0; ts3 < 2; ++ts3) for (uint8_t ts4 = 0; ts4 < 2; ++ts4) for (uint8_t ts5 = 0; ts5 < 2; ++ts5) for (uint8_t ts6 = 0; ts6 < 2; ++ts6) for (uint8_t ts7 = 0; ts7 < 2; ++ts7) for (int ms_class = 0; ms_class < mslot_class_max(); ++ms_class) test_alloc_mass(ts0, ts1, ts2, ts3, ts4, ts5, ts6, ts7, ms_class); } static void test_alloc_b() { for (int i = 0; i < mslot_class_max(); ++i) test_alloc_b_for_ms(i); test_all_alloc_b(); } static char get_dir_char(uint8_t mask, uint8_t tx, uint8_t rx, uint8_t busy) { int offs = busy ? 32 : 0; return (mask & tx & rx) ? 'C' + offs : (mask & tx) ? 'U' + offs : (mask & rx) ? 'D' + offs : '.'; } enum test_mode { TEST_MODE_UL_ONLY, TEST_MODE_DL_ONLY, TEST_MODE_UL_AND_DL, TEST_MODE_DL_AND_UL, TEST_MODE_DL_AFTER_UL, TEST_MODE_UL_AFTER_DL, }; static inline char *test_mode_descr(enum test_mode t) { switch (t) { case TEST_MODE_UL_ONLY: return (char*)"UL only"; case TEST_MODE_DL_ONLY: return (char*)"DL only"; case TEST_MODE_UL_AND_DL: return (char*)"UL and DL"; case TEST_MODE_DL_AND_UL: return (char*)"DL and UL"; case TEST_MODE_DL_AFTER_UL: return (char*)"DL after UL"; case TEST_MODE_UL_AFTER_DL: return (char*)"UL after DL"; default: return NULL; } } static GprsMs *alloc_tbfs(struct gprs_rlcmac_bts *bts, struct GprsMs *old_ms, enum test_mode mode) { struct GprsMs *ms, *new_ms; uint8_t trx_no = -1; OSMO_ASSERT(old_ms != NULL); gprs_rlcmac_tbf *tbf = NULL; if (ms_current_trx(old_ms)) trx_no = ms_current_trx(old_ms)->trx_no; ms_ref(old_ms); /* Allocate what is needed first */ switch (mode) { case TEST_MODE_UL_ONLY: case TEST_MODE_DL_AFTER_UL: case TEST_MODE_UL_AND_DL: if (ms_ul_tbf(old_ms)) tbf_free(ms_ul_tbf(old_ms)); tbf = tbf_alloc_ul_tbf(bts, old_ms, trx_no, false); if (tbf == NULL) { OSMO_ASSERT(trx_no != -1 || bts_all_pdch_allocated(bts)); ms_unref(old_ms); return NULL; } break; case TEST_MODE_DL_ONLY: case TEST_MODE_UL_AFTER_DL: case TEST_MODE_DL_AND_UL: if (ms_dl_tbf(old_ms)) tbf_free(ms_dl_tbf(old_ms)); tbf = tbf_alloc_dl_tbf(bts, old_ms, trx_no, false); if (tbf == NULL) { OSMO_ASSERT(trx_no != -1 || bts_all_pdch_allocated(bts)); ms_unref(old_ms); return NULL; } } OSMO_ASSERT(tbf); OSMO_ASSERT(tbf->ms()); OSMO_ASSERT(old_ms == tbf->ms()); ms = tbf->ms(); ms_ref(ms); new_ms = ms; /* Continue with what is needed next */ switch (mode) { case TEST_MODE_UL_ONLY: case TEST_MODE_DL_ONLY: /* We are done */ break; case TEST_MODE_DL_AFTER_UL: case TEST_MODE_UL_AND_DL: new_ms = alloc_tbfs(bts, ms, TEST_MODE_DL_ONLY); break; case TEST_MODE_UL_AFTER_DL: case TEST_MODE_DL_AND_UL: new_ms = alloc_tbfs(bts, ms, TEST_MODE_UL_ONLY); break; } /* Optionally delete the TBF */ switch (mode) { case TEST_MODE_DL_AFTER_UL: case TEST_MODE_UL_AFTER_DL: tbf_free(tbf); tbf = NULL; break; default: break; } if (!new_ms && tbf) tbf_free(tbf); ms_unref(old_ms); ms_unref(ms); return new_ms; } static unsigned alloc_many_tbfs(struct gprs_rlcmac_bts *bts, unsigned min_class, unsigned max_class, enum test_mode mode) { unsigned counter; unsigned ms_class = min_class; for (counter = 0; 1; counter += 1) { gprs_rlcmac_tbf *ul_tbf, *dl_tbf; uint8_t ul_slots = 0; uint8_t dl_slots = 0; uint8_t busy_slots = 0; unsigned i; int tfi = -1; int tfi2; uint8_t trx_no2; struct gprs_rlcmac_trx *trx; GprsMs *ms; enum gprs_rlcmac_tbf_direction dir; uint32_t tlli = counter + 0xc0000000; ms = bts_ms_by_tlli(bts, tlli, GSM_RESERVED_TMSI); if (!ms) ms = bts_alloc_ms(bts, 0, 0); ms_set_ms_class(ms, ms_class); ms = alloc_tbfs(bts, ms, mode); if (!ms) break; ms_set_tlli(ms, tlli); ul_tbf = ms_ul_tbf(ms); dl_tbf = ms_dl_tbf(ms); trx = ms_current_trx(ms); OSMO_ASSERT(ul_tbf || dl_tbf); if (ul_tbf) { ul_slots = 1 << ul_tbf->first_common_ts; tfi = ul_tbf->tfi(); dir = GPRS_RLCMAC_UL_TBF; } else { ul_slots = 1 << dl_tbf->first_common_ts; tfi = dl_tbf->tfi(); dir = GPRS_RLCMAC_DL_TBF; } for (i = 0; dl_tbf && i < ARRAY_SIZE(dl_tbf->pdch); i += 1) if (dl_tbf->pdch[i]) dl_slots |= 1 << i; for (i = 0; ul_tbf && i < ARRAY_SIZE(ul_tbf->pdch); i += 1) if (ul_tbf->pdch[i]) ul_slots |= 1 << i; for (i = 0; trx && i < ARRAY_SIZE(trx->pdch); i += 1) { struct gprs_rlcmac_pdch *pdch = &trx->pdch[i]; if (ul_tbf && dl_tbf) continue; if (ul_tbf && pdch->assigned_tfi(GPRS_RLCMAC_DL_TBF) != NO_FREE_TFI) continue; if (dl_tbf && pdch->assigned_tfi(GPRS_RLCMAC_UL_TBF) != NO_FREE_TFI) continue; busy_slots |= 1 << i; } printf(" TBF[%d] class %d reserves " OSMO_BIT_SPEC "\n", tfi, ms_class, get_dir_char(0x01, ul_slots, dl_slots, busy_slots), get_dir_char(0x02, ul_slots, dl_slots, busy_slots), get_dir_char(0x04, ul_slots, dl_slots, busy_slots), get_dir_char(0x08, ul_slots, dl_slots, busy_slots), get_dir_char(0x10, ul_slots, dl_slots, busy_slots), get_dir_char(0x20, ul_slots, dl_slots, busy_slots), get_dir_char(0x40, ul_slots, dl_slots, busy_slots), get_dir_char(0x80, ul_slots, dl_slots, busy_slots)); if (tfi >= 0) { OSMO_ASSERT(ms_current_trx(ms)); tfi2 = bts_tfi_find_free(bts, dir, &trx_no2, ms_current_trx(ms)->trx_no); OSMO_ASSERT(tfi != tfi2); OSMO_ASSERT(tfi2 < 0 || trx_no2 == ms_current_trx(ms)->trx_no); } ms_class += 1; if (ms_class > max_class) ms_class = min_class; } return counter; } static void test_successive_allocation(alloc_algorithm_func_t algo, unsigned min_class, unsigned max_class, enum test_mode mode, unsigned expect_num, const char *text) { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); struct gprs_rlcmac_trx *trx; unsigned counter; printf("Going to test assignment with many TBF, algorithm %s class %u..%u (%s)\n", text, min_class, max_class, test_mode_descr(mode)); the_pcu->alloc_algorithm = algo; trx = &bts->trx[0]; trx->pdch[3].enable(); trx->pdch[4].enable(); trx->pdch[5].enable(); trx->pdch[6].enable(); trx->pdch[7].enable(); counter = alloc_many_tbfs(bts, min_class, max_class, mode); printf(" Successfully allocated %u UL TBFs, algorithm %s class %u..%u (%s)\n", counter, text, min_class, max_class, test_mode_descr(mode)); if (counter != expect_num) fprintf(stderr, " Expected %u TBFs (got %u), algorithm %s class %u..%u (%s)\n", expect_num, counter, text, min_class, max_class, test_mode_descr(mode)); OSMO_ASSERT(counter == expect_num); check_tfi_usage(bts); talloc_free(bts); } static void test_many_connections(alloc_algorithm_func_t algo, unsigned expect_num, const char *text) { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); struct gprs_rlcmac_trx *trx; int counter1, counter2 = -1; unsigned i; enum test_mode mode_seq[] = { TEST_MODE_DL_AFTER_UL, TEST_MODE_UL_ONLY, TEST_MODE_DL_AFTER_UL, TEST_MODE_DL_ONLY, }; printf("Going to test assignment with many connections, algorithm %s\n", text); the_pcu->alloc_algorithm = algo; trx = &bts->trx[0]; trx->pdch[3].enable(); trx->pdch[4].enable(); trx->pdch[5].enable(); trx->pdch[6].enable(); trx->pdch[7].enable(); for (i = 0; i < ARRAY_SIZE(mode_seq); i += 1) { counter1 = alloc_many_tbfs(bts, 1, mslot_class_max(), mode_seq[i]); fprintf(stderr, " Allocated %d TBFs (previously %d)\n", counter1, counter2); check_tfi_usage(bts); /* This will stop earlier due to USF shortage */ if (mode_seq[i] == TEST_MODE_UL_ONLY) continue; if (counter2 >= 0) { if (counter1 < counter2) fprintf(stderr, " Expected %d >= %d in %s\n", counter1, counter2, text); OSMO_ASSERT(counter1 >= counter2); } counter2 = counter1; } printf(" Successfully allocated %d TBFs\n", counter1); if (counter1 != (int)expect_num) fprintf(stderr, " Expected %d TBFs (got %d) for algorithm %s\n", expect_num, counter1, text); OSMO_ASSERT(expect_num == (unsigned)counter1); talloc_free(bts); } static inline void test_a_b_dyn(enum test_mode mode, uint8_t exp_A, uint8_t exp_B, uint8_t exp_dyn) { test_successive_allocation(alloc_algorithm_a, 1, 1, mode, exp_A, "A"); test_successive_allocation(alloc_algorithm_b, 10, 10, mode, exp_B, "B"); test_successive_allocation(alloc_algorithm_dynamic, 10, 10, mode, exp_dyn, "dynamic"); } static void test_successive_allocations() { test_successive_allocation(alloc_algorithm_a, 1, 1, TEST_MODE_UL_AND_DL, 35, "A"); test_successive_allocation(alloc_algorithm_b, 10, 10, TEST_MODE_UL_AND_DL, 15, "B"); test_successive_allocation(alloc_algorithm_b, 12, 12, TEST_MODE_UL_AND_DL, 15, "B"); test_successive_allocation(alloc_algorithm_b, 1, 12, TEST_MODE_UL_AND_DL, 23, "B"); test_successive_allocation(alloc_algorithm_b, 1, mslot_class_max(), TEST_MODE_UL_AND_DL, 17, "B"); test_successive_allocation(alloc_algorithm_dynamic, 1, mslot_class_max(), TEST_MODE_UL_AND_DL, 17, "dynamic"); test_a_b_dyn(TEST_MODE_DL_AND_UL, 35, 15, 15); test_a_b_dyn(TEST_MODE_DL_AFTER_UL, 160, 32, 101); test_a_b_dyn(TEST_MODE_UL_AFTER_DL, 35, 15, 15); test_a_b_dyn(TEST_MODE_UL_ONLY, 35, 15, 21); test_a_b_dyn(TEST_MODE_DL_ONLY, 160, 32, 101); } static void test_2_consecutive_dl_tbfs() { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); GprsMs *ms; struct gprs_rlcmac_trx *trx; uint8_t ms_class = 11; uint8_t egprs_ms_class = 11; gprs_rlcmac_tbf *dl_tbf1, *dl_tbf2; uint8_t numTs1 = 0, numTs2 = 0; printf("Testing DL TS allocation for Multi UEs\n"); the_pcu->alloc_algorithm = alloc_algorithm_b; trx = &bts->trx[0]; trx->pdch[4].enable(); trx->pdch[5].enable(); trx->pdch[6].enable(); trx->pdch[7].enable(); ms = bts_alloc_ms(bts, ms_class, egprs_ms_class); dl_tbf1 = tbf_alloc_dl_tbf(bts, ms, 0, false); OSMO_ASSERT(dl_tbf1); for (int i = 0; i < 8; i++) { if (dl_tbf1->pdch[i]) numTs1++; } OSMO_ASSERT(numTs1 == 4); printf("TBF1: numTs(%d)\n", numTs1); ms = bts_alloc_ms(bts, ms_class, egprs_ms_class); dl_tbf2 = tbf_alloc_dl_tbf(bts, ms, 0, false); OSMO_ASSERT(dl_tbf2); for (int i = 0; i < 8; i++) { if (dl_tbf2->pdch[i]) numTs2++; } /* * TODO: currently 2nd DL TBF gets 3 TS * This behaviour will be fixed in subsequent patch */ printf("TBF2: numTs(%d)\n", numTs2); OSMO_ASSERT(numTs2 == 3); tbf_free(dl_tbf1); tbf_free(dl_tbf2); talloc_free(bts); } static void test_bts_pch_timer(void) { struct gprs_rlcmac_bts *bts = bts_alloc(the_pcu, 0); struct osmo_mobile_identity mi_imsi1, mi_imsi2; struct osmo_mobile_identity mi_tmsi1; mi_imsi1.type = mi_imsi2.type = GSM_MI_TYPE_IMSI; mi_tmsi1.type = GSM_MI_TYPE_TMSI; OSMO_STRLCPY_ARRAY(mi_imsi1.imsi, "1234"); OSMO_STRLCPY_ARRAY(mi_imsi2.imsi, "5678"); mi_tmsi1.tmsi = 987654321; fprintf(stderr, "Testing bts_pch_timer dealloc on bts dealloc\n"); log_set_category_filter(osmo_stderr_target, DPCU, 1, LOGL_DEBUG); fprintf(stderr, "Starting PCH timer for 2 IMSI\n"); bts_pch_timer_start(bts, &mi_imsi1, mi_imsi1.imsi); bts_pch_timer_start(bts, &mi_imsi2, mi_imsi2.imsi); fprintf(stderr, "Starting PCH timer for 1 TMSI\n"); bts_pch_timer_start(bts, &mi_tmsi1, "6666"); fprintf(stderr, "Deallocating BTS, expecting the PCH timer to be stopped and deallocated\n"); talloc_free(bts); } int main(int argc, char **argv) { tall_pcu_ctx = talloc_named_const(NULL, 1, "moiji-mobile AllocTest context"); if (!tall_pcu_ctx) abort(); msgb_talloc_ctx_init(tall_pcu_ctx, 0); osmo_init_logging2(tall_pcu_ctx, &gprs_log_info); log_set_use_color(osmo_stderr_target, 0); log_set_print_filename2(osmo_stderr_target, LOG_FILENAME_NONE); log_set_print_category(osmo_stderr_target, 0); log_set_print_category_hex(osmo_stderr_target, 0); log_set_category_filter(osmo_stderr_target, DTBF, 1, LOGL_INFO); if (getenv("LOGL_DEBUG")) log_set_log_level(osmo_stderr_target, LOGL_DEBUG); osmo_fsm_log_addr(false); the_pcu = gprs_pcu_alloc(tall_pcu_ctx); test_alloc_a(); test_alloc_b(); test_successive_allocations(); test_many_connections(alloc_algorithm_a, 160, "A"); test_many_connections(alloc_algorithm_b, 32, "B"); test_many_connections(alloc_algorithm_dynamic, 160, "dynamic"); test_2_consecutive_dl_tbfs(); test_bts_pch_timer(); talloc_free(the_pcu); return EXIT_SUCCESS; } /* * stubs that should not be reached */ extern "C" { void l1if_pdch_req() { abort(); } void l1if_connect_pdch() { abort(); } void l1if_close_pdch() { abort(); } void l1if_open_pdch() { abort(); } }