/* (C) 2017 by sysmocom - s.f.m.c. GmbH * * Author: Pau Espin Pedrol * * SPDX-License-Identifier: GPL-2.0+ * * 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static struct osmo_jibuf *jb; static uint16_t rtp_next_seq; static uint32_t rtp_next_ts; #define SAMPLES_PER_PKT 160 #define TIME_RTP_PKT_MS 20 /* RTP packet with AMR payload */ static uint8_t rtp_pkt[] = { 0x80, 0x62, 0x3f, 0xcc, 0x00, 0x01, 0xa7, 0x6f, /* RTP */ 0x07, 0x09, 0x00, 0x62, 0x20, 0x14, 0xff, 0xd4, /* AMR */ 0xf9, 0xff, 0xfb, 0xe7, 0xeb, 0xf9, 0x9f, 0xf8, 0xf2, 0x26, 0x33, 0x65, 0x54, }; /* ----------------------------- */ /* Logging related stuff */ #define INT2IDX(x) (-1*(x)-1) struct log_info_cat jibuf_test_cat[] = { [INT2IDX(DLJIBUF)] = { .name = "DLJIBUF", .description = "Osmocom Jitter Buffer", .enabled = 1, .loglevel = LOGL_DEBUG, }, }; const struct log_info jibuf_test_log_info = { .filter_fn = NULL, .cat = jibuf_test_cat, .num_cat = ARRAY_SIZE(jibuf_test_cat), }; /* ----------------------------- */ static void rtp_init(uint16_t seq, uint32_t timestamp) { rtp_next_seq = seq; rtp_next_ts = timestamp; } static struct msgb *rtp_new(uint16_t seq, uint32_t timestamp) { struct msgb *msg; struct rtp_hdr *rtph; msg = msgb_alloc(1500, "test"); if (!msg) exit(EXIT_FAILURE); memcpy(msg->data, rtp_pkt, sizeof(rtp_pkt)); msgb_put(msg, sizeof(rtp_pkt)); rtph = osmo_rtp_get_hdr(msg); rtph->sequence = htons(rtp_next_seq); rtph->timestamp = htonl(rtp_next_ts); return msg; } static struct msgb *rtp_next(void) { rtp_next_seq++; rtp_next_ts += SAMPLES_PER_PKT; return rtp_new(rtp_next_seq, rtp_next_ts); } static void sigalarm_handler(int foo) { printf("FAIL: test did not run successfully\n"); exit(EXIT_FAILURE); } static void clock_debug(char* str) { struct timespec ts; struct timeval tv; osmo_clock_gettime(CLOCK_MONOTONIC, &ts); osmo_gettimeofday(&tv, NULL); printf("sys={%lu.%06lu}, mono={%lu.%06lu}: %s\n", tv.tv_sec, tv.tv_usec, ts.tv_sec, ts.tv_nsec/1000, str); } static void clock_override_enable(bool enable) { osmo_gettimeofday_override = enable; osmo_clock_override_enable(CLOCK_MONOTONIC, enable); } static void clock_override_set(long sec, long usec) { struct timespec *mono; osmo_gettimeofday_override_time.tv_sec = sec; osmo_gettimeofday_override_time.tv_usec = usec; mono = osmo_clock_override_gettimespec(CLOCK_MONOTONIC); mono->tv_sec = sec; mono->tv_nsec = usec*1000; clock_debug("clock_override_set"); } static void clock_override_add_debug(long sec, long usec, bool dbg) { osmo_gettimeofday_override_add(sec, usec); osmo_clock_override_add(CLOCK_MONOTONIC, sec, usec*1000); if (dbg) clock_debug("clock_override_add"); } #define clock_override_add(sec, usec) clock_override_add_debug(sec, usec, true) static void dequeue_cb(struct msgb *msg, void *data) { struct rtp_hdr *rtph; bool check_latest; char buf[250]; rtph = osmo_rtp_get_hdr(msg); check_latest = rtph->sequence == htons(rtp_next_seq) && rtph->timestamp == htonl(rtp_next_ts); snprintf(buf, sizeof(buf), "dequeue: seq=%"PRIu16" ts=%"PRIu32" %s", ntohs(rtph->sequence), ntohl(rtph->timestamp), check_latest ? "LATEST" : "INTERMEDIATE"); clock_debug(buf); msgb_free(msg); } #define ENQUEUE_NEXT(jb) { \ struct msgb *_msg; \ int _rc; \ _msg = rtp_next(); \ _rc = osmo_jibuf_enqueue(jb, _msg); \ OSMO_ASSERT(!_rc); \ } static void test_normal(void) { int min_delay = 60; printf("===test_normal===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ ENQUEUE_NEXT(jb); clock_override_add(0, min_delay*1000); clock_debug("first select, first dequed"); osmo_select_main(0); /* We are at t=60, if we add a new packet and wait for 20msecs (next packet), we should show it dequeued*/ ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("second select, one packet should be dequeued"); osmo_select_main(0); /* We are at t=80, and only 2 packets were introduced. Let's add 2 more, should be dequeued by 80+40: */ ENQUEUE_NEXT(jb); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*2*1000); clock_debug("third select, two more dequed"); osmo_select_main(0); /* t=120, 4 enqueued, 4 dequeued.*/ OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_delete_nonempty(void) { int min_delay = 100; printf("===test_delete_nonempty===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); ENQUEUE_NEXT(jb); /* No need to update the time, all msgs should be dequeued at this time */ OSMO_ASSERT(!osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_packet_lost(void) { int min_delay = 60; printf("===test_packet_lost===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("packet lost: 2nd"); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("packet lost: 3rd"); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("packet lost: 4th"); clock_override_add(0, TIME_RTP_PKT_MS*1000); /* We are at t=80 */ clock_debug("enqueue 5th packet"); ENQUEUE_NEXT(jb); clock_override_add(0, min_delay*1000); /* We are at t=140, all out in order */ osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_packet_drop(void) { int min_delay = 60; struct msgb *msg; printf("===test_packet_drop===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 3rd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 4th packet"); ENQUEUE_NEXT(jb); /* We are at t=60, first comes out */ osmo_select_main(0); /* We move to t=160, next packet in stream is too late:*/ clock_override_add(0, 100*1000); clock_debug("next packet should be dropped, too late"); msg = rtp_next(); OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg) < 0); msgb_free(msg); /* However, if we try to add a later one, it should work: */ clock_debug("next packet should be enqueued"); ENQUEUE_NEXT(jb); /* We are at t=160, all of them should be dequeued */ osmo_select_main(0); /* t=160, 4 enqueued, 4 dequeued.*/ OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_packet_out_of_order(void) { int min_delay = 60; struct msgb *msg2, *msg3; printf("===test_packet_out_of_order===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet"); ENQUEUE_NEXT(jb); /* 3rd packet arrives instead of 2nd one */ msg2 = rtp_next(); msg3 = rtp_next(); clock_override_add(0, TIME_RTP_PKT_MS*2*1000); clock_debug("enqueue 3rd packet"); OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg3) == 0); clock_debug("enqueue 2nd packet"); OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg2) == 0); /* We are at t=100, all out in order */ clock_override_add(0, min_delay*1000); osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_start_2nd_packet(void) { int min_delay = 60; struct msgb *msg1; printf("===test_start_2nd_packet===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("1st packet is not yet enqueued"); msg1 = rtp_next(); clock_override_add(0, TIME_RTP_PKT_MS*2*1000); /* 2nd packet arrives instead of 2nd one */ clock_debug("2nd packet is enqueuded as first"); ENQUEUE_NEXT(jb); clock_debug("1st packet is enqueuded as second, should be enqueued with preference"); OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg1) == 0); /* 1st packet is dequeued */ clock_override_add(0, (min_delay-TIME_RTP_PKT_MS)*1000); osmo_select_main(0); /* 2nst packet is dequeued */ clock_override_add(0, TIME_RTP_PKT_MS*1000); osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_buffer_threshold_change(void) { int min_delay = 60; struct msgb *msg; uint32_t threshold_delay; int i; printf("===test_buffer_threshold_change===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); OSMO_ASSERT(min_delay == jb->threshold_delay); threshold_delay = jb->threshold_delay; /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 3rd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 4th packet"); ENQUEUE_NEXT(jb); /* We are at t=60, first comes out */ osmo_select_main(0); /* We move to t=160, next packet in stream is too late:*/ clock_override_add(0, 100*1000); clock_debug("next packet should be dropped, too late"); msg = rtp_next(); OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg) < 0); msgb_free(msg); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("next packet is dropped, but buffer is increased"); msg = rtp_next(); OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg) < 0); msgb_free(msg); OSMO_ASSERT(jb->threshold_delay > threshold_delay); threshold_delay = jb->threshold_delay; clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("next packet is enqueued since the buffer increased"); ENQUEUE_NEXT(jb); /* As the last buffer was really late but still accepted, it is not delayed: */ osmo_select_main(0); clock_debug("Enqueue late packets"); for (i = 0; i<4; i++) { ENQUEUE_NEXT(jb); } clock_debug("Run perfectly for a while, buffer should decrease"); for (i = 0; i<100; i++) { clock_override_add(0, TIME_RTP_PKT_MS*1000); ENQUEUE_NEXT(jb); osmo_select_main(0); } clock_debug("Done, checking threshold and cleaning"); OSMO_ASSERT(jb->threshold_delay < threshold_delay); clock_override_add(0, jb->threshold_delay*1000); osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_seq_wraparound(void) { int min_delay = 80; printf("===test_seq_wraparound===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(65533, 400); /* seq = 2^16 -3 */ jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); clock_debug("enqueue 1st packet (seq=65534)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet (seq=65535)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 3rd packet (seq=0, wraparound)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 4th packet (seq=1)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 5th packet (seq=2)"); ENQUEUE_NEXT(jb); clock_debug("dequeue 1st packet (seq=65534)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 2nd packet (seq=65535)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 3rd packet (seq=0, wraparound)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 4th packet (seq=1)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 5th packet (seq=2)"); osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_timestamp_wraparound(void) { int min_delay = 80; unsigned int offset = 14; printf("===test_timestamp_wraparound===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 4294966816 + offset); /* timestamp = 2^32 - 3*SAMPLES_PER_PKT + offset */ jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); clock_debug("enqueue 1st packet (ts=4294966990)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet (ts=4294967150)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 3rd packet (ts=14, wraparound)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 4th packet (ts=174)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 5th packet (ts=334)"); ENQUEUE_NEXT(jb); clock_debug("dequeue 1st packet (ts=4294966990)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 2nd packet (ts=4294967150)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 3rd packet (ts=14, wraparound)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 4th packet (ts=174)"); osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("dequeue 5th packet (ts=334)"); osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_rtp_marker(void) { int min_delay = 60; struct msgb *msg; struct rtp_hdr *rtph; printf("===test_rtp_marker===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, min_delay*1000); clock_debug("2 packets dequeued"); osmo_select_main(0); clock_override_add(0, 40*1000); /* We are at t=120, next non-marked (consecutive seq) packet arriving at * this time should be dropped, but since marker establishes new ref, * it will be accepted as well an ext paket */ clock_debug("enqueue late pkt with marker=1, will be enqueued"); msg = rtp_next(); rtph = osmo_rtp_get_hdr(msg); rtph->marker = 1; OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg) == 0); clock_debug("enqueue late pkt after pkt with marker=1, will be enqueued"); clock_override_add(0, TIME_RTP_PKT_MS*1000); ENQUEUE_NEXT(jb); clock_debug("2 packets dequeued"); clock_override_add(0, min_delay*1000); osmo_select_main(0); /* t=120, 4 enqueued, 4 dequeued.*/ OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } /* This test aims at testing scenarios described in OS#3262, in which syncpoint packets can provoke a situation in which packets are stored out-of-order in the queue. */ static void test_rtp_marker_queue_order(void) { int min_delay = 60; struct msgb *msg; struct rtp_hdr *rtph; printf("===test_rtp_marker_queue_order===\n"); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 3rd packet"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); /* We then emulate an scenario in which an Osmux queue in front of us receives a new frame before expected time, which means the packets in the osmux genreated rtp queue will be flushed and sent to jibuf directly. On top, the first packet of the new frame has the RTP Marker bit set. */ clock_debug("enqueue 3 packets instantly"); ENQUEUE_NEXT(jb); /* scheduled min_delay+0 */ ENQUEUE_NEXT(jb); /* a min_delay+TIME_RTP_PKT_MS */ ENQUEUE_NEXT(jb); /* scheduled min_delay+TIME_RTP_PKT_MS*2 */ clock_debug("enqueue pkt with marker=1 instantly"); msg = rtp_next(); rtph = osmo_rtp_get_hdr(msg); rtph->marker = 1; OSMO_ASSERT(osmo_jibuf_enqueue(jb, msg) == 0); /* syncpoint, scheduled in min_delay+0 */ osmo_select_main(0); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue pkt after syncpoint"); ENQUEUE_NEXT(jb); /* scheduled min_delay+0 */ clock_debug("all packets dequeued"); clock_override_add(0, min_delay*1000); osmo_select_main(0); OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_rtp_out_of_sync(unsigned int time_inc_ms, uint16_t seq_nosync_inc, uint32_t ts_nosync_inc, bool expect_drop) { int min_delay = 60; struct msgb *msg; int rc; printf("===test_rtp_out_of_sync(%u, %"PRIu16", %"PRIu32", %d)===\n", time_inc_ms, seq_nosync_inc, ts_nosync_inc, expect_drop); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); osmo_jibuf_set_max_delay(jb, 200); /* First rtp at t=0, should be scheduled in min_delay time */ clock_debug("enqueue 1st packet (seq=33, ts=560)"); ENQUEUE_NEXT(jb); clock_override_add(0, TIME_RTP_PKT_MS*1000); clock_debug("enqueue 2nd packet (seq=34, ts=720)"); ENQUEUE_NEXT(jb); clock_override_add(0, time_inc_ms*1000); clock_debug("2 packets dequeued"); osmo_select_main(0); /* We are at t=20+time_inc_ms, next pkt would normally be dropped since it is * pretty late, but since seq and timestamp are out of sync, which * means the sender had some clock issues, the jibuf is going to take * this new tuple as reference and accept it. */ clock_debug("enqueue late pkt with possible sync change"); rtp_init(rtp_next_seq + seq_nosync_inc, rtp_next_ts + ts_nosync_inc); msg = rtp_new(rtp_next_seq, rtp_next_ts); rc = osmo_jibuf_enqueue(jb, msg); if (expect_drop) { OSMO_ASSERT(rc < 0); msgb_free(msg); } else { OSMO_ASSERT(rc == 0); } clock_debug("enqueue late pkt after possible resync"); clock_override_add(0, TIME_RTP_PKT_MS*1000); msg = rtp_next(); rc = osmo_jibuf_enqueue(jb, msg); if (expect_drop) { OSMO_ASSERT(rc < 0); msgb_free(msg); } else { OSMO_ASSERT(rc == 0); } if (!expect_drop) { clock_debug("2 packets dequeued"); clock_override_add(0, min_delay*1000); osmo_select_main(0); } OSMO_ASSERT(osmo_jibuf_empty(jb)); osmo_jibuf_delete(jb); } static void test_skew(unsigned int skew_inc_us, bool skew_compensation) { int min_delay = 40; unsigned int dropped = 0; struct msgb *msg; int i; char buf[250]; printf("===test_skew(%u, %d)===\n", skew_inc_us, skew_compensation); clock_override_enable(true); clock_override_set(0, 0); rtp_init(32, 400); jb = osmo_jibuf_alloc(NULL); osmo_jibuf_set_dequeue_cb(jb, dequeue_cb, NULL); osmo_jibuf_set_min_delay(jb, min_delay); /*set buffer static, otherwise will grow with drops and enqueue some more packets: */ osmo_jibuf_set_max_delay(jb, min_delay); osmo_jibuf_enable_skew_compensation(jb, skew_compensation); /* If no skew compensation is used, jitterbuffer should start dropping * packets (all too late) after around min_delay*1000/skew_inc_us packets. */ for (i = 0; iskew_us); } else { OSMO_ASSERT(dropped); OSMO_ASSERT(!jb->skew_us); } } int main(int argc, char **argv) { if (signal(SIGALRM, sigalarm_handler) == SIG_ERR) { perror("signal"); exit(EXIT_FAILURE); } void *tall_ctx = talloc_named_const(NULL, 1, "Root context"); msgb_talloc_ctx_init(tall_ctx, 0); osmo_init_logging2(tall_ctx, &jibuf_test_log_info); log_set_print_filename2(osmo_stderr_target, LOG_FILENAME_NONE); log_set_log_level(osmo_stderr_target, LOGL_DEBUG); log_set_category_filter(osmo_stderr_target, DLJIBUF, 1, LOGL_DEBUG); alarm(10); test_normal(); test_delete_nonempty(); test_packet_lost(); test_packet_drop(); test_packet_out_of_order(); test_start_2nd_packet(); test_buffer_threshold_change(); test_seq_wraparound(); test_timestamp_wraparound(); test_rtp_marker(); test_rtp_marker_queue_order(); test_rtp_out_of_sync(80*TIME_RTP_PKT_MS, 5, 5*SAMPLES_PER_PKT, true); test_rtp_out_of_sync(80*TIME_RTP_PKT_MS, 6, 5*SAMPLES_PER_PKT, false); test_rtp_out_of_sync(80*TIME_RTP_PKT_MS, 5, 5*SAMPLES_PER_PKT + 3, false); test_skew(100, false); test_skew(100, true); fprintf(stdout, "OK: Test passed\n"); return EXIT_SUCCESS; }