/* GStreamer * * Copyright (C) 2009 Nokia Corporation and its subsidary(-ies) * contact: * Copyright (C) 2012 Cisco Systems, Inc * Authors: Kelley Rogers * Havard Graff * Copyright (C) 2013-2016 Pexip AS * Stian Selnes * Havard Graff * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, * Boston, MA 02110-1301, USA. */ #include #include #include #include /* For ease of programming we use globals to keep refs for our floating * src and sink pads we create; otherwise we always have to do get_pad, * get_peer, and then remove references in every test function */ static GstPad *mysrcpad, *mysinkpad; /* we also have a list of src buffers */ static GList *inbuffers = NULL; static gint num_dropped = 0; #define RTP_CAPS_STRING \ "application/x-rtp, " \ "media = (string)audio, " \ "payload = (int) 0, " \ "clock-rate = (int) 8000, " \ "encoding-name = (string)PCMU" #define RTP_FRAME_SIZE 20 static GstStaticPadTemplate sinktemplate = GST_STATIC_PAD_TEMPLATE ("sink", GST_PAD_SINK, GST_PAD_ALWAYS, GST_STATIC_CAPS ("application/x-rtp") ); static GstStaticPadTemplate srctemplate = GST_STATIC_PAD_TEMPLATE ("src", GST_PAD_SRC, GST_PAD_ALWAYS, GST_STATIC_CAPS ("application/x-rtp, " "clock-rate = (int) [ 1, 2147483647 ]") ); static void buffer_dropped (gpointer data, GstMiniObject * obj) { GST_DEBUG ("dropping buffer %p", obj); num_dropped++; } static GstElement * setup_jitterbuffer (gint num_buffers) { GstElement *jitterbuffer; GstClock *clock; GstBuffer *buffer; GstCaps *caps; /* a 20 sample audio block (2,5 ms) generated with * gst-launch audiotestsrc wave=silence blocksize=40 num-buffers=3 ! * "audio/x-raw,channels=1,rate=8000" ! mulawenc ! rtppcmupay ! * fakesink dump=1 */ guint8 in[] = { /* first 4 bytes are rtp-header, next 4 bytes are timestamp */ 0x80, 0x80, 0x1c, 0x24, 0x46, 0xcd, 0xb7, 0x11, 0x3c, 0x3a, 0x7c, 0x5b, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }; GstClockTime ts = G_GUINT64_CONSTANT (0); GstClockTime tso = gst_util_uint64_scale (RTP_FRAME_SIZE, GST_SECOND, 8000); /*guint latency = GST_TIME_AS_MSECONDS (num_buffers * tso); */ gint i; GST_DEBUG ("setup_jitterbuffer"); jitterbuffer = gst_check_setup_element ("rtpjitterbuffer"); /* we need a clock here */ clock = gst_system_clock_obtain (); gst_element_set_clock (jitterbuffer, clock); gst_object_unref (clock); /* setup latency */ /* latency would be 7 for 3 buffers here, default is 200 g_object_set (G_OBJECT (jitterbuffer), "latency", latency, NULL); GST_INFO_OBJECT (jitterbuffer, "set latency to %u ms", latency); */ mysrcpad = gst_check_setup_src_pad (jitterbuffer, &srctemplate); mysinkpad = gst_check_setup_sink_pad (jitterbuffer, &sinktemplate); gst_pad_set_active (mysrcpad, TRUE); gst_pad_set_active (mysinkpad, TRUE); /* create n buffers */ caps = gst_caps_from_string (RTP_CAPS_STRING); gst_check_setup_events (mysrcpad, jitterbuffer, caps, GST_FORMAT_TIME); gst_caps_unref (caps); for (i = 0; i < num_buffers; i++) { buffer = gst_buffer_new_and_alloc (sizeof (in)); gst_buffer_fill (buffer, 0, in, sizeof (in)); GST_BUFFER_DTS (buffer) = ts; GST_BUFFER_PTS (buffer) = ts; GST_BUFFER_DURATION (buffer) = tso; gst_mini_object_weak_ref (GST_MINI_OBJECT (buffer), buffer_dropped, NULL); GST_DEBUG ("created buffer: %p", buffer); if (!i) GST_BUFFER_FLAG_SET (buffer, GST_BUFFER_FLAG_DISCONT); inbuffers = g_list_append (inbuffers, buffer); /* hackish way to update the rtp header */ in[1] = 0x00; in[3]++; /* seqnumber */ in[7] += RTP_FRAME_SIZE; /* inc. timestamp with framesize */ ts += tso; } num_dropped = 0; return jitterbuffer; } static GstStateChangeReturn start_jitterbuffer (GstElement * jitterbuffer) { GstStateChangeReturn ret; GstClockTime now; GstClock *clock; clock = gst_element_get_clock (jitterbuffer); now = gst_clock_get_time (clock); gst_object_unref (clock); gst_element_set_base_time (jitterbuffer, now); ret = gst_element_set_state (jitterbuffer, GST_STATE_PLAYING); return ret; } static void cleanup_jitterbuffer (GstElement * jitterbuffer) { GST_DEBUG ("cleanup_jitterbuffer"); g_list_foreach (buffers, (GFunc) gst_mini_object_unref, NULL); g_list_free (buffers); buffers = NULL; g_list_free (inbuffers); inbuffers = NULL; gst_pad_set_active (mysrcpad, FALSE); gst_pad_set_active (mysinkpad, FALSE); gst_check_teardown_src_pad (jitterbuffer); gst_check_teardown_sink_pad (jitterbuffer); gst_check_teardown_element (jitterbuffer); } static void check_jitterbuffer_results (GstElement * jitterbuffer, gint num_buffers) { GstBuffer *buffer; GList *node; GstClockTime ts = G_GUINT64_CONSTANT (0); GstClockTime tso = gst_util_uint64_scale (RTP_FRAME_SIZE, GST_SECOND, 8000); GstMapInfo map; guint16 prev_sn = 0, cur_sn; guint32 prev_ts = 0, cur_ts; /* sleep for twice the latency */ g_usleep (400 * 1000); GST_INFO ("of %d buffer %d/%d received/dropped", num_buffers, g_list_length (buffers), num_dropped); /* if this fails, not all buffers have been processed */ fail_unless_equals_int ((g_list_length (buffers) + num_dropped), num_buffers); /* check the buffer list */ fail_unless_equals_int (g_list_length (buffers), num_buffers); for (node = buffers; node; node = g_list_next (node)) { fail_if ((buffer = (GstBuffer *) node->data) == NULL); fail_if (GST_BUFFER_PTS (buffer) != ts); fail_if (GST_BUFFER_DTS (buffer) != ts); gst_buffer_map (buffer, &map, GST_MAP_READ); cur_sn = ((guint16) map.data[2] << 8) | map.data[3]; cur_ts = ((guint32) map.data[4] << 24) | ((guint32) map.data[5] << 16) | ((guint32) map.data[6] << 8) | map.data[7]; gst_buffer_unmap (buffer, &map); if (node != buffers) { fail_unless (cur_sn > prev_sn); fail_unless (cur_ts > prev_ts); prev_sn = cur_sn; prev_ts = cur_ts; } ts += tso; } } GST_START_TEST (test_push_forward_seq) { GstElement *jitterbuffer; const guint num_buffers = 3; GstBuffer *buffer; GList *node; jitterbuffer = setup_jitterbuffer (num_buffers); fail_unless (start_jitterbuffer (jitterbuffer) == GST_STATE_CHANGE_SUCCESS, "could not set to playing"); /* push buffers: 0,1,2, */ for (node = inbuffers; node; node = g_list_next (node)) { buffer = (GstBuffer *) node->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); } /* check the buffer list */ check_jitterbuffer_results (jitterbuffer, num_buffers); /* cleanup */ cleanup_jitterbuffer (jitterbuffer); } GST_END_TEST; GST_START_TEST (test_push_backward_seq) { GstElement *jitterbuffer; const guint num_buffers = 4; GstBuffer *buffer; GList *node; jitterbuffer = setup_jitterbuffer (num_buffers); fail_unless (start_jitterbuffer (jitterbuffer) == GST_STATE_CHANGE_SUCCESS, "could not set to playing"); /* push buffers: 0,3,2,1 */ buffer = (GstBuffer *) inbuffers->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); for (node = g_list_last (inbuffers); node != inbuffers; node = g_list_previous (node)) { buffer = (GstBuffer *) node->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); } /* check the buffer list */ check_jitterbuffer_results (jitterbuffer, num_buffers); /* cleanup */ cleanup_jitterbuffer (jitterbuffer); } GST_END_TEST; GST_START_TEST (test_push_unordered) { GstElement *jitterbuffer; const guint num_buffers = 4; GstBuffer *buffer; jitterbuffer = setup_jitterbuffer (num_buffers); fail_unless (start_jitterbuffer (jitterbuffer) == GST_STATE_CHANGE_SUCCESS, "could not set to playing"); /* push buffers; 0,2,1,3 */ buffer = (GstBuffer *) inbuffers->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); buffer = g_list_nth_data (inbuffers, 2); fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); buffer = g_list_nth_data (inbuffers, 1); fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); buffer = g_list_nth_data (inbuffers, 3); fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); /* check the buffer list */ check_jitterbuffer_results (jitterbuffer, num_buffers); /* cleanup */ cleanup_jitterbuffer (jitterbuffer); } GST_END_TEST; GST_START_TEST (test_basetime) { GstElement *jitterbuffer; const guint num_buffers = 3; GstBuffer *buffer; GList *node; GstClockTime tso = gst_util_uint64_scale (RTP_FRAME_SIZE, GST_SECOND, 8000); jitterbuffer = setup_jitterbuffer (num_buffers); fail_unless (start_jitterbuffer (jitterbuffer) == GST_STATE_CHANGE_SUCCESS, "could not set to playing"); /* push buffers: 2,1,0 */ for (node = g_list_last (inbuffers); node; node = g_list_previous (node)) { buffer = (GstBuffer *) node->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); } /* sleep for twice the latency */ g_usleep (400 * 1000); /* if this fails, not all buffers have been processed */ fail_unless_equals_int ((g_list_length (buffers) + num_dropped), num_buffers); buffer = (GstBuffer *) buffers->data; fail_unless (GST_BUFFER_DTS (buffer) != (num_buffers * tso)); fail_unless (GST_BUFFER_PTS (buffer) != (num_buffers * tso)); /* cleanup */ cleanup_jitterbuffer (jitterbuffer); } GST_END_TEST; static GstCaps * request_pt_map (GstElement * jitterbuffer, guint pt) { fail_unless (pt == 0); return gst_caps_from_string (RTP_CAPS_STRING); } GST_START_TEST (test_clear_pt_map) { GstElement *jitterbuffer; const guint num_buffers = 10; gint i; GstBuffer *buffer; GList *node; jitterbuffer = setup_jitterbuffer (num_buffers); fail_unless (start_jitterbuffer (jitterbuffer) == GST_STATE_CHANGE_SUCCESS, "could not set to playing"); g_signal_connect (jitterbuffer, "request-pt-map", (GCallback) request_pt_map, NULL); /* push buffers: 0,1,2, */ for (node = inbuffers, i = 0; node && i < 3; node = g_list_next (node), i++) { buffer = (GstBuffer *) node->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); } g_usleep (400 * 1000); g_signal_emit_by_name (jitterbuffer, "clear-pt-map", NULL); for (; node && i < 10; node = g_list_next (node), i++) { buffer = (GstBuffer *) node->data; fail_unless (gst_pad_push (mysrcpad, buffer) == GST_FLOW_OK); } /* check the buffer list */ check_jitterbuffer_results (jitterbuffer, num_buffers); /* cleanup */ cleanup_jitterbuffer (jitterbuffer); } GST_END_TEST; #define TEST_BUF_CLOCK_RATE 8000 #define TEST_BUF_PT 0 #define TEST_BUF_SSRC 0x01BADBAD #define TEST_BUF_MS 20 #define TEST_BUF_DURATION (TEST_BUF_MS * GST_MSECOND) #define TEST_BUF_SIZE (64000 * TEST_BUF_MS / 1000) #define TEST_RTP_TS_DURATION (TEST_BUF_CLOCK_RATE * TEST_BUF_MS / 1000) static GstCaps * generate_caps (void) { return gst_caps_new_simple ("application/x-rtp", "media", G_TYPE_STRING, "audio", "clock-rate", G_TYPE_INT, TEST_BUF_CLOCK_RATE, "encoding-name", G_TYPE_STRING, "TEST", "payload", G_TYPE_INT, TEST_BUF_PT, "ssrc", G_TYPE_UINT, TEST_BUF_SSRC, NULL); } static GstBuffer * generate_test_buffer_full (GstClockTime dts, guint seq_num, guint32 rtp_ts) { GstBuffer *buf; guint8 *payload; guint i; GstRTPBuffer rtp = GST_RTP_BUFFER_INIT; buf = gst_rtp_buffer_new_allocate (TEST_BUF_SIZE, 0, 0); GST_BUFFER_DTS (buf) = dts; gst_rtp_buffer_map (buf, GST_MAP_READWRITE, &rtp); gst_rtp_buffer_set_payload_type (&rtp, TEST_BUF_PT); gst_rtp_buffer_set_seq (&rtp, seq_num); gst_rtp_buffer_set_timestamp (&rtp, rtp_ts); gst_rtp_buffer_set_ssrc (&rtp, TEST_BUF_SSRC); payload = gst_rtp_buffer_get_payload (&rtp); for (i = 0; i < TEST_BUF_SIZE; i++) payload[i] = 0xff; gst_rtp_buffer_unmap (&rtp); return buf; } static GstBuffer * generate_test_buffer (guint seq_num) { return generate_test_buffer_full (seq_num * TEST_BUF_DURATION, seq_num, seq_num * TEST_RTP_TS_DURATION); } static GstBuffer * generate_test_buffer_rtx (GstClockTime dts, guint seq_num) { GstBuffer *buffer = generate_test_buffer_full (dts, seq_num, seq_num * TEST_RTP_TS_DURATION); GST_BUFFER_FLAG_SET (buffer, GST_RTP_BUFFER_FLAG_RETRANSMISSION); return buffer; } static void push_test_buffer (GstHarness * h, guint seq_num) { gst_harness_set_time (h, seq_num * TEST_BUF_DURATION); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (seq_num))); } static gint get_rtp_seq_num (GstBuffer * buf) { GstRTPBuffer rtp = GST_RTP_BUFFER_INIT; gint seq; gst_rtp_buffer_map (buf, GST_MAP_READ, &rtp); seq = gst_rtp_buffer_get_seq (&rtp); gst_rtp_buffer_unmap (&rtp); return seq; } #define verify_lost_event(h, exp_seq, exp_ts, exp_dur) \ G_STMT_START { \ GstEvent *_event; \ const GstStructure *_s; \ const GValue *_value; \ guint _seq; \ GstClockTime _ts; \ GstClockTime _dur; \ _event = gst_harness_pull_event (h); \ fail_unless (_event != NULL); \ _s = gst_event_get_structure (_event); \ fail_unless (_s != NULL); \ fail_unless (gst_structure_get_uint (_s, "seqnum", &_seq)); \ _value = gst_structure_get_value (_s, "timestamp"); \ fail_unless (_value && G_VALUE_HOLDS_UINT64 (_value)); \ _ts = g_value_get_uint64 (_value); \ _value = gst_structure_get_value (_s, "duration"); \ fail_unless (_value && G_VALUE_HOLDS_UINT64 (_value)); \ _dur = g_value_get_uint64 (_value); \ fail_unless_equals_int ((guint16)(exp_seq), _seq); \ fail_unless_equals_uint64 (exp_ts, _ts); \ fail_unless_equals_uint64 (exp_dur, _dur); \ gst_event_unref (_event); \ } G_STMT_END #define verify_rtx_event(h, exp_seq, exp_ts, exp_delay, exp_spacing) \ G_STMT_START { \ GstEvent *_event; \ const GstStructure *_s; \ const GValue *_value; \ guint _seq; \ GstClockTime _ts; \ guint _delay; \ GstClockTime _spacing; \ _event = gst_harness_pull_upstream_event (h); \ fail_unless (_event != NULL); \ _s = gst_event_get_structure (_event); \ fail_unless (_s != NULL); \ fail_unless (gst_structure_get_uint (_s, "seqnum", &_seq)); \ _value = gst_structure_get_value (_s, "running-time"); \ fail_unless (_value && G_VALUE_HOLDS_UINT64 (_value)); \ _ts = g_value_get_uint64 (_value); \ fail_unless (gst_structure_get_uint (_s, "delay", &_delay)); \ _value = gst_structure_get_value (_s, "packet-spacing"); \ fail_unless (_value && G_VALUE_HOLDS_UINT64 (_value)); \ _spacing = g_value_get_uint64 (_value); \ fail_unless_equals_int ((guint16)(exp_seq), _seq); \ fail_unless_equals_uint64 (exp_ts, _ts); \ fail_unless_equals_int (exp_delay, _delay); \ fail_unless_equals_uint64 (exp_spacing, _spacing); \ gst_event_unref (_event); \ } G_STMT_END static gboolean verify_jb_stats (GstElement * jb, GstStructure * expected) { gboolean ret; GstStructure *actual; g_object_get (jb, "stats", &actual, NULL); ret = gst_structure_is_subset (actual, expected); if (!ret) { gchar *e_str = gst_structure_to_string (expected); gchar *a_str = gst_structure_to_string (actual); fail_unless (ret, "%s is not a subset of %s", e_str, a_str); g_free (e_str); g_free (a_str); } gst_structure_free (expected); gst_structure_free (actual); return ret; } static guint construct_deterministic_initial_state (GstHarness * h, gint latency_ms) { guint next_seqnum = latency_ms / TEST_BUF_MS + 1; guint seqnum; gint i; g_assert (latency_ms % TEST_BUF_MS == 0); gst_harness_set_src_caps (h, generate_caps ()); g_object_set (h->element, "latency", latency_ms, NULL); /* When the first packet arrives in the jitterbuffer, it will create a * timeout for this packet equal to the latency of the jitterbuffer. * This is known as DEADLINE internally, and is meant to allow the stream * to buffer a bit before starting to push it out, to get some ideas about * the nature of the stream. (packetspacing, jitter etc.) * * When writing tests using the test-clock, it it hence important to know * that by simply advancing the clock to this timeout, you are basically * describing a stream that had one initial packet, and then nothing at all * for the duration of the latency (100ms in this test), which is not a very * usual scenario. * * Instead, a pattern used throughout this test-suite, is to keep the buffers * arriving at their optimal time, until the DEADLINE is reached, and that * then becomes the "starting-point" for the test, because at this time * there should now be no waiting timers (unless using rtx) and we have * a "clean" state to craft the test from. */ /* Packet 0 arrives at time 0ms, Packet 5 arrives at time 100ms */ for (seqnum = 0; seqnum < next_seqnum; seqnum++) { push_test_buffer (h, seqnum); gst_harness_wait_for_clock_id_waits (h, 1, 60); } /* We release the DEADLINE timer for packet 0, verify the time is indeed * @latency_ms (100ms) and pull out all the buffers that have been released, * and verify their PTS and sequence numbers. */ gst_harness_crank_single_clock_wait (h); fail_unless_equals_int64 (latency_ms * GST_MSECOND, gst_clock_get_time (GST_ELEMENT_CLOCK (h->element))); for (seqnum = 0; seqnum < next_seqnum; seqnum++) { GstBuffer *buf = gst_harness_pull (h); fail_unless_equals_uint64 (seqnum * TEST_BUF_DURATION, GST_BUFFER_PTS (buf)); fail_unless_equals_int (seqnum, get_rtp_seq_num (buf)); gst_buffer_unref (buf); } /* drop GstEventStreamStart & GstEventCaps & GstEventSegment */ for (i = 0; i < 3; i++) gst_event_unref (gst_harness_pull_event (h)); /* drop reconfigure event */ gst_event_unref (gst_harness_pull_upstream_event (h)); /* Verify that at this point our queues are empty */ fail_unless_equals_int (0, gst_harness_buffers_in_queue (h)); fail_unless_equals_int (0, gst_harness_events_in_queue (h)); return next_seqnum; } GST_START_TEST (test_lost_event) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstBuffer *buf; gint latency_ms = 100; guint next_seqnum; guint missing_seqnum; g_object_set (h->element, "do-lost", TRUE, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* We will now create a gap in the stream, by skipping one sequence-number, * and push the following packet. */ missing_seqnum = next_seqnum; next_seqnum += 1; push_test_buffer (h, next_seqnum); /* This packet (@next_seqnum) will now be held back, awaiting the missing one, * verify that this is the case: */ fail_unless_equals_int (0, gst_harness_buffers_in_queue (h)); fail_unless_equals_int (0, gst_harness_events_in_queue (h)); /* The lost-timeout for the missing packet will now be its pts + latency, so * now we will simply crank the clock to advance to this point in time, and * check that we get a lost-event, as well as the last packet we pushed in. */ gst_harness_crank_single_clock_wait (h); verify_lost_event (h, missing_seqnum, missing_seqnum * TEST_BUF_DURATION, TEST_BUF_DURATION); buf = gst_harness_pull (h); fail_unless_equals_uint64 (next_seqnum * TEST_BUF_DURATION, GST_BUFFER_PTS (buf)); fail_unless_equals_int (next_seqnum, get_rtp_seq_num (buf)); gst_buffer_unref (buf); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 1, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_only_one_lost_event_on_large_gaps) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstTestClock *testclock; GstBuffer *out_buf; guint next_seqnum; gint latency_ms = 200; gint num_lost_events = latency_ms / TEST_BUF_MS; gint i; testclock = gst_harness_get_testclock (h); /* Need to set max-misorder-time and max-dropout-time to 0 so the * jitterbuffer does not base them on packet rate calculations. * If it does, out gap is big enough to be considered a new stream and * we wait for a few consecutive packets just to be sure */ g_object_set (h->element, "do-lost", TRUE, "max-misorder-time", 0, "max-dropout-time", 0, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* move time ahead to just before 10 seconds */ gst_harness_set_time (h, 10 * GST_SECOND - 1); /* check that we have no pending waits */ fail_unless_equals_int (0, gst_test_clock_peek_id_count (testclock)); /* a buffer now arrives perfectly on time */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (500))); /* release the wait, advancing the clock to 10 sec */ fail_unless (gst_harness_crank_single_clock_wait (h)); /* we should now receive a packet-lost-event for buffers 11 through 489 ... */ verify_lost_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, TEST_BUF_DURATION * (490 - next_seqnum)); /* ... as well as 490 (since at 10 sec 490 is too late) */ verify_lost_event (h, 490, 490 * TEST_BUF_DURATION, TEST_BUF_DURATION); /* we get as many lost events as the the number of * * buffers the jitterbuffer is able to wait for */ for (i = 1; i < num_lost_events; i++) { fail_unless (gst_harness_crank_single_clock_wait (h)); verify_lost_event (h, 490 + i, (490 + i) * TEST_BUF_DURATION, TEST_BUF_DURATION); } /* and then the buffer is released */ out_buf = gst_harness_pull (h); fail_unless (GST_BUFFER_FLAG_IS_SET (out_buf, GST_BUFFER_FLAG_DISCONT)); fail_unless_equals_int (500, get_rtp_seq_num (out_buf)); fail_unless_equals_uint64 (10 * GST_SECOND, GST_BUFFER_DTS (out_buf)); fail_unless_equals_uint64 (10 * GST_SECOND, GST_BUFFER_PTS (out_buf)); gst_buffer_unref (out_buf); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-lost", G_TYPE_UINT64, (guint64) 489, NULL))); gst_object_unref (testclock); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_two_lost_one_arrives_in_time) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstTestClock *testclock; GstClockID id; GstBuffer *buf; gint latency_ms = 100; guint next_seqnum; guint first_missing; guint second_missing; guint current_arrived; testclock = gst_harness_get_testclock (h); g_object_set (h->element, "do-lost", TRUE, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* hop over 2 packets and make another one (gap of 2) */ first_missing = next_seqnum; second_missing = next_seqnum + 1; current_arrived = next_seqnum + 2; push_test_buffer (h, current_arrived); /* verify that the jitterbuffer now wait for the latest moment it can push the * @first_missing packet out. */ gst_test_clock_wait_for_next_pending_id (testclock, &id); fail_unless_equals_uint64 (first_missing * TEST_BUF_DURATION + latency_ms * GST_MSECOND, gst_clock_id_get_time (id)); gst_clock_id_unref (id); /* let the time expire... */ fail_unless (gst_harness_crank_single_clock_wait (h)); /* we should now receive a packet-lost-event */ verify_lost_event (h, first_missing, first_missing * TEST_BUF_DURATION, TEST_BUF_DURATION); /* @second_missing now arrives just in time */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (second_missing))); /* verify that @second_missing made it through! */ buf = gst_harness_pull (h); fail_unless (GST_BUFFER_FLAG_IS_SET (buf, GST_BUFFER_FLAG_DISCONT)); fail_unless_equals_int (second_missing, get_rtp_seq_num (buf)); gst_buffer_unref (buf); /* and see that @current_arrived now also is pushed */ buf = gst_harness_pull (h); fail_unless (!GST_BUFFER_FLAG_IS_SET (buf, GST_BUFFER_FLAG_DISCONT)); fail_unless_equals_int (current_arrived, get_rtp_seq_num (buf)); gst_buffer_unref (buf); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 2, "num-lost", G_TYPE_UINT64, (guint64) 1, NULL))); gst_object_unref (testclock); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_late_packets_still_makes_lost_events) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstBuffer *out_buf; gint latency_ms = 100; guint next_seqnum; guint seqnum; GstClockTime now; g_object_set (h->element, "do-lost", TRUE, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* jump 10 seconds forward in time */ now = 10 * GST_SECOND; gst_harness_set_time (h, now); /* push a packet with a gap of 2, that now is very late */ seqnum = next_seqnum + 2; fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (now, seqnum, seqnum * TEST_RTP_TS_DURATION))); /* we should now receive packet-lost-events for the gap * FIXME: The timeout and duration here are a bit crap... */ verify_lost_event (h, next_seqnum, 3400 * GST_MSECOND, 6500 * GST_MSECOND); verify_lost_event (h, next_seqnum + 1, 9900 * GST_MSECOND, 3300 * GST_MSECOND); /* verify that packet @seqnum made it through! */ out_buf = gst_harness_pull (h); fail_unless (GST_BUFFER_FLAG_IS_SET (out_buf, GST_BUFFER_FLAG_DISCONT)); fail_unless_equals_int (seqnum, get_rtp_seq_num (out_buf)); gst_buffer_unref (out_buf); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 1, "num-lost", G_TYPE_UINT64, (guint64) 2, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_num_late_when_considered_lost_arrives) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gboolean do_lost = __i__ != 0; gint latency_ms = 100; guint next_seqnum; g_object_set (h->element, "do-lost", do_lost, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* gap of 1 */ push_test_buffer (h, next_seqnum + 1); /* crank to trigger lost-event */ gst_harness_crank_single_clock_wait (h); if (do_lost) { /* we should now receive packet-lost-events for the missing packet */ verify_lost_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, TEST_BUF_DURATION); } /* pull out the pushed packet */ gst_buffer_unref (gst_harness_pull (h)); /* we have one lost packet in the stats */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 1, "num-lost", G_TYPE_UINT64, (guint64) 1, "num-late", G_TYPE_UINT64, (guint64) 0, NULL))); /* the missing packet now arrives (too late) */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (next_seqnum))); /* and this increments num-late */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 1, "num-lost", G_TYPE_UINT64, (guint64) 1, "num-late", G_TYPE_UINT64, (guint64) 1, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_lost_event_uses_pts) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstClockTime now; gint latency_ms = 100; guint next_seqnum; guint lost_seqnum; g_object_set (h->element, "do-lost", TRUE, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* hop over 1 packets and make another one (gap of 1), but due to network delays, this packets is also grossly late */ lost_seqnum = next_seqnum; next_seqnum += 1; /* advance the clock to the latest time packet @next_seqnum could arrive */ now = next_seqnum * TEST_BUF_DURATION + latency_ms * GST_MSECOND; gst_harness_set_time (h, now); gst_harness_push (h, generate_test_buffer_full (now, next_seqnum, next_seqnum * TEST_RTP_TS_DURATION)); /* we should now have received a packet-lost-event for buffer 3 */ verify_lost_event (h, lost_seqnum, lost_seqnum * TEST_BUF_DURATION, TEST_BUF_DURATION); /* and pull out packet 4 */ gst_buffer_unref (gst_harness_pull (h)); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 1, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_lost_event_with_backwards_rtptime) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 40; g_object_set (h->element, "do-lost", TRUE, NULL); construct_deterministic_initial_state (h, latency_ms); /* * For video using B-frames, an expected sequence * could be like this: * (I = I-frame, P = P-frame, B = B-frame) * ___ ___ ___ ___ ___ * ... | 3 | | 4 | | 5 | | 6 | | 7 | * ––– ––– ––– ––– ––– * rtptime: 3(I) 5(P) 5(P) 4(B) 6(P) * arrival(dts): 3 5 5 5 6 * * Notice here that packet 6 (the B frame) make * the rtptime go backwards. * * But we get this: * ___ ___ _ _ ___ ___ * ... | 3 | | 4 | | | | 6 | | 7 | * ––– ––– - - ––– ––– * rtptime: 3(I) 5(P) 4(B) 6(P) * arrival(dts): 3 5 5 6 * */ /* seqnum 3 */ push_test_buffer (h, 3); gst_buffer_unref (gst_harness_pull (h)); /* seqnum 4, arriving at time 5 with rtptime 5 */ gst_harness_push (h, generate_test_buffer_full (5 * TEST_BUF_DURATION, 4, 5 * TEST_RTP_TS_DURATION)); gst_buffer_unref (gst_harness_pull (h)); /* seqnum 6, arriving at time 5 with rtptime 4, making a gap for missing seqnum 5 */ gst_harness_push (h, generate_test_buffer_full (5 * TEST_BUF_DURATION, 6, 4 * TEST_RTP_TS_DURATION)); /* seqnum 7, arriving at time 6 with rtptime 6 */ gst_harness_push (h, generate_test_buffer_full (6 * TEST_BUF_DURATION, 7, 6 * TEST_RTP_TS_DURATION)); /* we should now have received a packet-lost-event for seqnum 5, with time 5 and 0 duration */ gst_harness_crank_single_clock_wait (h); verify_lost_event (h, 5, 5 * TEST_BUF_DURATION, 0); /* and pull out 6 and 7 */ gst_buffer_unref (gst_harness_pull (h)); gst_buffer_unref (gst_harness_pull (h)); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) 7, "num-lost", G_TYPE_UINT64, (guint64) 1, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_all_packets_are_timestamped_zero) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstBuffer *out_buf; gint jb_latency_ms = 100; gint i, b; gst_harness_set_src_caps (h, generate_caps ()); g_object_set (h->element, "do-lost", TRUE, "latency", jb_latency_ms, NULL); /* advance the clock with 10 seconds */ gst_harness_set_time (h, 10 * GST_SECOND); /* push the first buffer through */ gst_buffer_unref (gst_harness_push_and_pull (h, generate_test_buffer (0))); /* push some buffers in, all timestamped 0 */ for (b = 1; b < 3; b++) { fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (0 * GST_MSECOND, b, 0))); /* check for the buffer coming out that was pushed in */ out_buf = gst_harness_pull (h); fail_unless_equals_uint64 (0, GST_BUFFER_DTS (out_buf)); fail_unless_equals_uint64 (0, GST_BUFFER_PTS (out_buf)); gst_buffer_unref (out_buf); } /* hop over 2 packets and make another one (gap of 2) */ b = 5; fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (0 * GST_MSECOND, b, 0))); /* drop GstEventStreamStart & GstEventCaps & GstEventSegment */ for (i = 0; i < 3; i++) gst_event_unref (gst_harness_pull_event (h)); /* we should now receive packet-lost-events for buffer 3 and 4 */ verify_lost_event (h, 3, 0, 0); verify_lost_event (h, 4, 0, 0); /* verify that buffer 5 made it through! */ out_buf = gst_harness_pull (h); fail_unless (GST_BUFFER_FLAG_IS_SET (out_buf, GST_BUFFER_FLAG_DISCONT)); fail_unless_equals_int (5, get_rtp_seq_num (out_buf)); gst_buffer_unref (out_buf); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) 4, "num-lost", G_TYPE_UINT64, (guint64) 2, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_reorder_of_non_equidistant_packets) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstTestClock *testclock; gint latency_ms = 5; GstClockID pending_id; GstClockTime time; gint seq, frame; gint num_init_frames = 1; const GstClockTime frame_dur = TEST_BUF_DURATION; const guint32 frame_rtp_ts_dur = TEST_RTP_TS_DURATION; gst_harness_set_src_caps (h, generate_caps ()); testclock = gst_harness_get_testclock (h); g_object_set (h->element, "do-lost", TRUE, "latency", latency_ms, NULL); for (frame = 0, seq = 0; frame < num_init_frames; frame++, seq += 2) { /* Push a couple of packets with identical timestamp, typical for a video * stream where one frame generates multiple packets. */ gst_harness_set_time (h, frame * frame_dur); gst_harness_push (h, generate_test_buffer_full (frame * frame_dur, seq, frame * frame_rtp_ts_dur)); gst_harness_push (h, generate_test_buffer_full (frame * frame_dur, seq + 1, frame * frame_rtp_ts_dur)); if (frame == 0) /* deadline for buffer 0 expires */ gst_harness_crank_single_clock_wait (h); gst_buffer_unref (gst_harness_pull (h)); gst_buffer_unref (gst_harness_pull (h)); } /* Finally push the last frame reordered */ gst_harness_set_time (h, frame * frame_dur); gst_harness_push (h, generate_test_buffer_full (frame * frame_dur, seq + 1, frame * frame_rtp_ts_dur)); /* Check the scheduled lost timer. The expected arrival of this packet * should be assumed to be the same as the last packet received since we * don't know wether the missing packet belonged to this or previous * frame. */ gst_test_clock_wait_for_next_pending_id (testclock, &pending_id); time = gst_clock_id_get_time (pending_id); fail_unless_equals_int64 (time, frame * frame_dur + latency_ms * GST_MSECOND); gst_clock_id_unref (pending_id); /* And then missing packet arrives just in time */ gst_harness_set_time (h, time - 1); gst_harness_push (h, generate_test_buffer_full (time - 1, seq, frame * frame_rtp_ts_dur)); gst_buffer_unref (gst_harness_pull (h)); gst_buffer_unref (gst_harness_pull (h)); gst_object_unref (testclock); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_loss_equidistant_spacing_with_parameter_packets) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 5; gint seq, frame; gint num_init_frames = 10; gint i; gst_harness_set_src_caps (h, generate_caps ()); g_object_set (h->element, "do-lost", TRUE, "latency", latency_ms, NULL); /* drop stream-start, caps, segment */ for (i = 0; i < 3; i++) gst_event_unref (gst_harness_pull_event (h)); for (frame = 0, seq = 0; frame < num_init_frames; frame++, seq++) { gst_harness_set_time (h, frame * TEST_BUF_DURATION); gst_harness_push (h, generate_test_buffer_full (frame * TEST_BUF_DURATION, seq, frame * TEST_RTP_TS_DURATION)); if (frame == 0) /* deadline for buffer 0 expires */ gst_harness_crank_single_clock_wait (h); gst_buffer_unref (gst_harness_pull (h)); } /* Push three packets with same rtptime, simulating parameter packets + * frame. This should not disable equidistant mode as it is common for * certain audio codecs. */ for (i = 0; i < 3; i++) { gst_harness_set_time (h, frame * TEST_BUF_DURATION); gst_harness_push (h, generate_test_buffer_full (frame * TEST_BUF_DURATION, seq++, frame * TEST_RTP_TS_DURATION)); gst_buffer_unref (gst_harness_pull (h)); } frame++; /* Finally push the last packet introducing a gap */ gst_harness_set_time (h, frame * TEST_BUF_DURATION); gst_harness_push (h, generate_test_buffer_full (frame * TEST_BUF_DURATION, seq + 1, frame * TEST_RTP_TS_DURATION)); /* Check that the lost event has been generated assuming equidistant * spacing. */ verify_lost_event (h, seq, frame * TEST_BUF_DURATION - TEST_BUF_DURATION / 2, TEST_BUF_DURATION / 2); gst_buffer_unref (gst_harness_pull (h)); gst_harness_teardown (h); } GST_END_TEST; static void gst_test_clock_set_time_and_process (GstTestClock * testclock, GstClockTime time) { GstClockID id, tid; gst_test_clock_wait_for_next_pending_id (testclock, &id); gst_test_clock_set_time (testclock, time); tid = gst_test_clock_process_next_clock_id (testclock); g_assert (tid == id); gst_clock_id_unref (tid); gst_clock_id_unref (id); } GST_START_TEST (test_rtx_expected_next) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 200; guint next_seqnum; GstClockTime timeout; gint rtx_delay_ms; const GstClockTime rtx_retry_timeout_ms = 40; g_object_set (h->element, "do-lost", TRUE, NULL); g_object_set (h->element, "do-retransmission", TRUE, NULL); g_object_set (h->element, "rtx-retry-period", 120, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* At this point there is already existing a rtx-timer for @next_seqnum, * that will have a timeout of the expected arrival-time for that seqnum, * and a delay equal to 2*jitter==0 and 0.5*packet_spacing==10ms */ timeout = next_seqnum * TEST_BUF_DURATION; rtx_delay_ms = 0.5 * TEST_BUF_MS; /* We crank the clock to time-out the next scheduled timer */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, timeout, rtx_delay_ms, TEST_BUF_DURATION); /* now we wait for the next timeout, all following timeouts 40ms in the * future because this is rtx-retry-timeout */ rtx_delay_ms += rtx_retry_timeout_ms; gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, timeout, rtx_delay_ms, TEST_BUF_DURATION); /* And a third time... */ rtx_delay_ms += rtx_retry_timeout_ms; gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, timeout, rtx_delay_ms, TEST_BUF_DURATION); /* we should now receive a packet-lost-event for packet @next_seqnum */ gst_harness_crank_single_clock_wait (h); verify_lost_event (h, next_seqnum, timeout, TEST_BUF_DURATION); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_two_missing) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 200; guint next_seqnum; GstClockTime last_rtx_request, now; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; g_object_set (h->element, "do-retransmission", TRUE, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); fail_unless_equals_int (11, next_seqnum); /* * The expected sequence of buffers is this: * ____ ____ ____ ____ * ... | 10 | | 11 | | 12 | | 13 | * –––– –––– –––– –––– * 200ms 220ms 240ms 260ms * * But instead we get this: * ____ _ _ _ _ ____ * ... | 10 | | | | | | 13 | * –––– - - - - –––– * 200ms 260ms * * Now it is important to note that the next thing that happens is that * the RTX timeout for packet 11 will happen at time 230ms, so we crank * the timer thread to advance the time to this: */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, 11, 11 * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, 11 * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); gst_harness_wait_for_clock_id_waits (h, 1, 60); /* The next scheduled RTX for packet 11 is now at 230 + 40 = 270ms, so the next thing that happens is that buffer 13 arrives in perfect time: */ now = 13 * TEST_BUF_DURATION; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (now, 13, 13 * TEST_RTP_TS_DURATION))); /* * * This will estimate the dts on the two missing packets to: * ____ ____ * ... | 11 | | 12 | ... * –––– –––– * 220ms 240ms * * And given their regular interspacing of 20ms, it will schedule two RTX * timers for them like so: * * ____ ____ * ... | 11 | | 12 | ... * –––– –––– * 230ms 250ms * * There are however two problems, packet 11 we have already sent one RTX for * and its timeout is currently at 270ms, so we should not tamper with that, * and as for packet 12, 250ms has already expired, so we now expect to see * an rtx-event being sent for packet 12 immediately: */ verify_rtx_event (h, 12, 12 * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); /* and another crank will see the second RTX event being sent for packet 11 */ gst_harness_crank_single_clock_wait (h); rtx_delay_ms += 40; verify_rtx_event (h, 11, 11 * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, 11 * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_buffer_arrives_just_in_time) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 5 * TEST_BUF_MS; gint next_seqnum; GstBuffer *buffer; GstClockTime now, last_rtx_request; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; g_object_set (h->element, "do-retransmission", TRUE, "rtx-max-retries", 1, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* Crank clock to send retransmission events requesting seqnum 6 which has * not arrived yet. */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* seqnum 6 arrives just before it times out and is considered lost */ now = 200 * GST_MSECOND; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, next_seqnum))); buffer = gst_harness_pull (h); fail_unless_equals_int (next_seqnum, get_rtp_seq_num (buffer)); gst_buffer_unref (buffer); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 1, "num-lost", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 1, "rtx-success-count", G_TYPE_UINT64, (guint64) 1, "rtx-per-packet", G_TYPE_DOUBLE, 1.0, "rtx-rtt", G_TYPE_UINT64, (guint64) (now - last_rtx_request), NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_buffer_arrives_too_late) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 5 * TEST_BUF_MS; gint next_seqnum; GstClockTime now, last_rtx_request; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; g_object_set (h->element, "do-retransmission", TRUE, "do-lost", TRUE, "rtx-max-retries", 1, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* Crank clock to send retransmission events requesting seqnum 6 which has * not arrived yet. */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* packet @next_seqnum is considered lost */ gst_harness_crank_single_clock_wait (h); verify_lost_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, TEST_BUF_DURATION); /* packet @next_seqnum arrives too late */ now = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, next_seqnum))); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 1, "num-late", G_TYPE_UINT64, (guint64) 1, "num-duplicates", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 1, "rtx-success-count", G_TYPE_UINT64, (guint64) 0, "rtx-per-packet", G_TYPE_DOUBLE, 1.0, "rtx-rtt", G_TYPE_UINT64, (guint64) (now - last_rtx_request), NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_original_buffer_does_not_update_rtx_stats) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 100; gint next_seqnum; GstBuffer *buffer; GstClockTime now, last_rtx_request; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; g_object_set (h->element, "do-retransmission", TRUE, "rtx-max-retries", 1, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); fail_unless_equals_int (6, next_seqnum); /* Crank clock to send retransmission events requesting @next_seqnum which has * not arrived yet. */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* ORIGINAL seqnum 6 arrives just before it times out and is considered * lost. */ now = 200 * GST_MSECOND; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (now, next_seqnum, next_seqnum * TEST_RTP_TS_DURATION))); buffer = gst_harness_pull (h); fail_unless_equals_int (next_seqnum, get_rtp_seq_num (buffer)); gst_buffer_unref (buffer); /* due to the advance in time, we will now also have sent an rtx-request for 7 */ next_seqnum++; verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); /* The original buffer does not count in the RTX stats. */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 0, "rtx-per-packet", G_TYPE_DOUBLE, 0.0, "rtx-rtt", G_TYPE_UINT64, (guint64) 0, NULL))); /* Now the retransmitted packet arrives and stats should be updated. Note * that the buffer arrives in time and should not be considered late, but * a duplicate. */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, 6))); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 1, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 0, "rtx-per-packet", G_TYPE_DOUBLE, 1.0, "rtx-rtt", G_TYPE_UINT64, (guint64) (now - last_rtx_request), NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_duplicate_packet_updates_rtx_stats) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 100; gint next_seqnum; GstClockTime now, rtx_request_6, rtx_request_7; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; gint i; g_object_set (h->element, "do-retransmission", TRUE, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); fail_unless_equals_int (6, next_seqnum); /* Push packet 8 so that 6 and 7 is missing */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (8))); /* Wait for NACKs on 6 and 7 */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, 6, 6 * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); rtx_request_6 = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (rtx_request_6, 6 * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, 7, 7 * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); rtx_request_7 = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (rtx_request_7, 7 * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* Original packet 7 arrives */ now = 150 * GST_MSECOND; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (now, 7, 7 * TEST_RTP_TS_DURATION))); /* We're still waiting for packet 6, so 7 should not be pushed */ gst_harness_wait_for_clock_id_waits (h, 1, 60); fail_unless_equals_int (gst_harness_buffers_in_queue (h), 0); /* The original buffer does not count in the RTX stats. */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 0, "rtx-per-packet", G_TYPE_DOUBLE, 0.0, "rtx-rtt", G_TYPE_UINT64, (guint64) 0, NULL))); /* Push RTX packet 7. Should be dropped as duplicate but update RTX stats. */ now = 160 * GST_MSECOND; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, 7))); gst_harness_wait_for_clock_id_waits (h, 1, 60); fail_unless_equals_int (gst_harness_buffers_in_queue (h), 0); /* Check RTX stats with updated num-duplicates and rtx-rtt fields */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 1, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 0, "rtx-per-packet", G_TYPE_DOUBLE, 1.0, "rtx-rtt", G_TYPE_UINT64, (guint64) (now - rtx_request_7), NULL))); /* RTX packet 6 arrives, both 6, 7 and 8 is ready to be pulled */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, 6))); for (i = 6; i <= 8; i++) { GstBuffer *buf = gst_harness_pull (h); fail_unless_equals_int (i, get_rtp_seq_num (buf)); gst_buffer_unref (buf); } /* RTX stats is updated with success count increased. */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 3, "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 1, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 1, "rtx-per-packet", G_TYPE_DOUBLE, 1.0, "rtx-rtt", G_TYPE_UINT64, (guint64) /* Use the rtx-rtt formula. Can be subject to change though. */ ((now - rtx_request_6) + 47 * (now - rtx_request_7)) / 48, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_buffer_arrives_after_lost_updates_rtx_stats) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 100; gint next_seqnum; GstClockTime now, last_rtx_request; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; g_object_set (h->element, "do-retransmission", TRUE, "do-lost", TRUE, "rtx-max-retries", 1, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* Crank clock to send retransmission events requesting seqnum 6 which has * not arrived yet. */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* seqnum 6 is considered lost */ gst_harness_crank_single_clock_wait (h); verify_lost_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, TEST_BUF_DURATION); /* seqnum 6 arrives too late */ now = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, next_seqnum))); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 1, "num-late", G_TYPE_UINT64, (guint64) 1, "num-duplicates", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 1, "rtx-success-count", G_TYPE_UINT64, (guint64) 0, "rtx-per-packet", G_TYPE_DOUBLE, 1.0, "rtx-rtt", G_TYPE_UINT64, (guint64) (now - last_rtx_request), NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_rtt_larger_than_retry_timeout) { /* When RTT is larger than retry period we will send two or more requests * before receiving any retransmission packets */ GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 100; gint next_seqnum; gint rtx_retry_timeout_ms = 20; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; gint rtt = rtx_retry_timeout_ms * GST_MSECOND + 1; GstClockTime now, first_request, second_request; g_object_set (h->element, "do-retransmission", TRUE, "rtx-retry-timeout", rtx_retry_timeout_ms, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* Wait for first NACK on 6 */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); first_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (first_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* Packet @next_seqnum + 1 arrives in time (so that we avoid its EXPECTED * timers to interfer with our test) */ push_test_buffer (h, next_seqnum + 1); /* Simulating RTT > rtx-retry-timeout, we send a new NACK before receiving * the RTX packet. Wait for second NACK on @next_seqnum */ gst_harness_crank_single_clock_wait (h); rtx_delay_ms += rtx_retry_timeout_ms; verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); second_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (second_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* The first retransmitted packet arrives */ now = first_request + rtt; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, next_seqnum))); /* Pull packets @next_seqnum and @next_seqnum + 1 */ gst_buffer_unref (gst_harness_pull (h)); gst_buffer_unref (gst_harness_pull (h)); /* Stats should be updated. Note that RTT is not updated since we cannot be * sure whether the RTX packet is in response to the first or second NACK. */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 2, "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 1, "rtx-per-packet", G_TYPE_DOUBLE, 2.0, "rtx-rtt", G_TYPE_UINT64, (guint64) 0, NULL))); /* Packet @next_seqnum + 2 arrives in time */ push_test_buffer (h, next_seqnum + 2); gst_buffer_unref (gst_harness_pull (h)); /* Now the second retransmitted packet arrives */ now = second_request + rtt; gst_harness_set_time (h, now); fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_rtx (now, next_seqnum))); /* The stats is updated with the correct RTT. */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum + 3, "num-lost", G_TYPE_UINT64, (guint64) 0, "num-late", G_TYPE_UINT64, (guint64) 0, "num-duplicates", G_TYPE_UINT64, (guint64) 1, "rtx-count", G_TYPE_UINT64, (guint64) 2, "rtx-success-count", G_TYPE_UINT64, (guint64) 1, "rtx-per-packet", G_TYPE_DOUBLE, 2.0, "rtx-rtt", G_TYPE_UINT64, (guint64) rtt, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_no_request_if_time_past_retry_period) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); const gint latency_ms = 200; const gint retry_period_ms = 120; GstTestClock *testclock; GstClockID pending_id; GstClockTime time; gint i; gst_harness_set_src_caps (h, generate_caps ()); testclock = gst_harness_get_testclock (h); g_object_set (h->element, "do-lost", TRUE, NULL); g_object_set (h->element, "do-retransmission", TRUE, NULL); g_object_set (h->element, "latency", latency_ms, NULL); g_object_set (h->element, "rtx-retry-period", retry_period_ms, NULL); /* push the first couple of buffers */ push_test_buffer (h, 0); push_test_buffer (h, 1); /* drop reconfigure event */ gst_event_unref (gst_harness_pull_upstream_event (h)); /* drop GstEventStreamStart & GstEventCaps & GstEventSegment */ for (i = 0; i < 3; i++) gst_event_unref (gst_harness_pull_event (h)); /* Wait for the first EXPECTED timer to be scheduled */ gst_test_clock_wait_for_next_pending_id (testclock, &pending_id); time = gst_clock_id_get_time (pending_id); gst_clock_id_unref (pending_id); fail_unless_equals_int64 (time, 2 * TEST_BUF_DURATION + 10 * GST_MSECOND); /* Let the first EXPECTED timer time out and be sent. However, set the 'now' * time to be past the retry-period simulating that the jitterbuffer has too * much to do and is not able to process all timers in real-time. In this * case the jitterbuffer should not schedule a new EXPECTED timer as that * would just make matters worse (more unnecessary processing of a request * that is already too late to be valuable). In practice this typically * happens for high loss networks with low RTT. */ gst_test_clock_set_time_and_process (testclock, 2 * TEST_BUF_DURATION + retry_period_ms * GST_MSECOND + 1); /* Verify the event. It could be argued that this request is already too * late and unnecessary. However, in order to keep things simple (for now) * we just keep the already scehduled EXPECTED timer, but refrain from * scheduled another EXPECTED timer */ verify_rtx_event (h, 2, 2 * TEST_BUF_DURATION, 10, TEST_BUF_DURATION); /* "crank" to reach the DEADLINE for packet 0 */ gst_harness_crank_single_clock_wait (h); gst_buffer_unref (gst_harness_pull (h)); gst_buffer_unref (gst_harness_pull (h)); fail_unless_equals_int (0, gst_harness_upstream_events_in_queue (h)); fail_unless_equals_int (0, gst_harness_events_in_queue (h)); /* "crank" to time out the LOST event */ gst_harness_crank_single_clock_wait (h); verify_lost_event (h, 2, 2 * TEST_BUF_DURATION, TEST_BUF_DURATION); gst_object_unref (testclock); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_same_delay_and_retry_timeout) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 5 * TEST_BUF_MS; gint next_seqnum; gint rtx_delay_ms = 20; GstClockTime last_rtx_request; g_object_set (h->element, "do-retransmission", TRUE, "rtx-max-retries", 3, "rtx-delay", rtx_delay_ms, "rtx-retry-timeout", rtx_delay_ms, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* Crank clock to send retransmission events requesting seqnum 6 which has * not arrived yet. */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); /* first rtx for packet @next_seqnum should arrive at the right time */ last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * GST_MSECOND); /* verify we have pulled out all rtx-events */ fail_unless_equals_int (0, gst_harness_upstream_events_in_queue (h)); /* now crank to get the second attempt at packet @next_seqnum */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms * 2, TEST_BUF_DURATION); /* second rtx for seqnum 6 should arrive at 140 + 20ms */ last_rtx_request = gst_clock_get_time (GST_ELEMENT_CLOCK (h->element)); fail_unless_equals_int64 (last_rtx_request, next_seqnum * TEST_BUF_DURATION + rtx_delay_ms * 2 * GST_MSECOND); /* verify we have pulled out all rtx-events */ fail_unless_equals_int (0, gst_harness_upstream_events_in_queue (h)); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) next_seqnum, "num-lost", G_TYPE_UINT64, (guint64) 0, "rtx-count", G_TYPE_UINT64, (guint64) 2, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_with_backwards_rtptime) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 40; g_object_set (h->element, "do-retransmission", TRUE, NULL); construct_deterministic_initial_state (h, latency_ms); /* * For video using B-frames, an expected sequence * could be like this: * (I = I-frame, P = P-frame, B = B-frame) * ___ ___ ___ * ... | 3 | | 4 | | 5 | * ––– ––– ––– * rtptime: 3(I) 5(P) 4(B) * arrival(dts): 3 5 5 * * Notice here that packet 5 (the B frame) make * the rtptime go backwards. */ /* seqnum 3, arriving at time 3 with rtptime 3 */ push_test_buffer (h, 3); gst_buffer_unref (gst_harness_pull (h)); /* seqnum 4, arriving at time 5 with rtptime 5 */ gst_harness_push (h, generate_test_buffer_full (5 * TEST_BUF_DURATION, 4, 5 * TEST_RTP_TS_DURATION)); gst_buffer_unref (gst_harness_pull (h)); /* seqnum 5, arriving at time 5 with rtptime 4 */ gst_harness_push (h, generate_test_buffer_full (5 * TEST_BUF_DURATION, 5, 4 * TEST_RTP_TS_DURATION)); gst_buffer_unref (gst_harness_pull (h)); /* crank to time-out the rtx-request for seqnum 6, the point here being that the backwards rtptime did not mess up the timeout for the rtx event */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, 6, 5 * TEST_BUF_DURATION + 15 * GST_MSECOND, 17, 35 * GST_MSECOND); fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) 6, "rtx-count", G_TYPE_UINT64, (guint64) 1, "num-lost", G_TYPE_UINT64, (guint64) 0, NULL))); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_rtx_timer_reuse) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); gint latency_ms = 5 * TEST_BUF_MS; gint rtx_delay_ms = 0.5 * TEST_BUF_MS; guint next_seqnum; g_object_set (h->element, "do-retransmission", TRUE, "do-lost", TRUE, "rtx-max-retries", 1, NULL); next_seqnum = construct_deterministic_initial_state (h, latency_ms); /* crank to timeout the only rtx-request, and the timer will * now reschedule as a lost-timer internally */ gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); /* but now buffer 6 arrives, and this should now reuse the lost-timer * for 6, as an expected-timer for 7 */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (next_seqnum))); /* now crank to timeout the expected-timer for 7 and verify */ next_seqnum++; gst_harness_crank_single_clock_wait (h); verify_rtx_event (h, next_seqnum, next_seqnum * TEST_BUF_DURATION, rtx_delay_ms, TEST_BUF_DURATION); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_deadline_ts_offset) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstTestClock *testclock; GstClockID id; const gint jb_latency_ms = 10; gst_harness_set_src_caps (h, generate_caps ()); testclock = gst_harness_get_testclock (h); g_object_set (h->element, "latency", jb_latency_ms, NULL); /* push the first buffer in */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (0))); /* wait_next_timeout() syncs on the deadline timer */ gst_test_clock_wait_for_next_pending_id (testclock, &id); fail_unless_equals_uint64 (jb_latency_ms * GST_MSECOND, gst_clock_id_get_time (id)); gst_clock_id_unref (id); /* add ts-offset while waiting */ g_object_set (h->element, "ts-offset", 20 * GST_MSECOND, NULL); gst_test_clock_set_time_and_process (testclock, jb_latency_ms * GST_MSECOND); /* wait_next_timeout() syncs on the new deadline timer */ gst_test_clock_wait_for_next_pending_id (testclock, &id); fail_unless_equals_uint64 ((20 + jb_latency_ms) * GST_MSECOND, gst_clock_id_get_time (id)); gst_clock_id_unref (id); /* now make deadline timer timeout */ gst_test_clock_set_time_and_process (testclock, (20 + jb_latency_ms) * GST_MSECOND); gst_buffer_unref (gst_harness_pull (h)); gst_object_unref (testclock); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_push_big_gap) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstBuffer *buf; const gint num_consecutive = 5; gint i; gst_harness_set_src_caps (h, generate_caps ()); for (i = 0; i < num_consecutive; i++) fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (1000 + i))); fail_unless (gst_harness_crank_single_clock_wait (h)); for (i = 0; i < num_consecutive; i++) { GstBuffer *buf = gst_harness_pull (h); fail_unless_equals_int (1000 + i, get_rtp_seq_num (buf)); gst_buffer_unref (buf); } /* Push more packets from a different sequence number domain * to trigger "big gap" logic. */ for (i = 0; i < num_consecutive; i++) fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (20000 + i))); fail_unless (gst_harness_crank_single_clock_wait (h)); for (i = 0; i < num_consecutive; i++) { GstBuffer *buf = gst_harness_pull (h); fail_unless_equals_int (20000 + i, get_rtp_seq_num (buf)); gst_buffer_unref (buf); } /* Final buffer should be pushed straight through */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer (20000 + num_consecutive))); buf = gst_harness_pull (h); fail_unless_equals_int (20000 + num_consecutive, get_rtp_seq_num (buf)); gst_buffer_unref (buf); gst_harness_teardown (h); } GST_END_TEST; typedef struct { guint seqnum_offset; guint late_buffer; } TestLateArrivalInput; static const TestLateArrivalInput test_considered_lost_packet_in_large_gap_arrives_input[] = { {0, 1}, {0, 2}, {65535, 1}, {65535, 2}, {65534, 1}, {65534, 2} }; GST_START_TEST (test_considered_lost_packet_in_large_gap_arrives) { GstHarness *h = gst_harness_new ("rtpjitterbuffer"); GstTestClock *testclock; GstClockID id; GstBuffer *buffer; gint jb_latency_ms = 20; const TestLateArrivalInput *test_input = &test_considered_lost_packet_in_large_gap_arrives_input[__i__]; guint seq_offset = test_input->seqnum_offset; guint late_buffer = test_input->late_buffer; gint i; gst_harness_set_src_caps (h, generate_caps ()); testclock = gst_harness_get_testclock (h); g_object_set (h->element, "do-lost", TRUE, "latency", jb_latency_ms, NULL); /* first push buffer 0 */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (0 * TEST_BUF_DURATION, 0 + seq_offset, 0 * TEST_RTP_TS_DURATION))); fail_unless (gst_harness_crank_single_clock_wait (h)); gst_buffer_unref (gst_harness_pull (h)); /* drop GstEventStreamStart & GstEventCaps & GstEventSegment */ for (i = 0; i < 3; i++) gst_event_unref (gst_harness_pull_event (h)); /* hop over 3 packets, and push buffer 4 (gap of 3) */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (4 * TEST_BUF_DURATION, 4 + seq_offset, 4 * TEST_RTP_TS_DURATION))); /* the jitterbuffer should be waiting for the timeout of a "large gap timer" * for buffer 1 and 2 */ gst_test_clock_wait_for_next_pending_id (testclock, &id); fail_unless_equals_uint64 (1 * TEST_BUF_DURATION + jb_latency_ms * GST_MSECOND, gst_clock_id_get_time (id)); gst_clock_id_unref (id); /* now buffer 1 sneaks in before the lost event for buffer 1 and 2 is * processed */ fail_unless_equals_int (GST_FLOW_OK, gst_harness_push (h, generate_test_buffer_full (late_buffer * TEST_BUF_DURATION, late_buffer + seq_offset, late_buffer * TEST_RTP_TS_DURATION))); /* time out for lost packets 1 and 2 (one event, double duration) */ fail_unless (gst_harness_crank_single_clock_wait (h)); verify_lost_event (h, 1 + seq_offset, 1 * TEST_BUF_DURATION, 2 * TEST_BUF_DURATION); /* time out for lost packets 3 */ fail_unless (gst_harness_crank_single_clock_wait (h)); verify_lost_event (h, 3 + seq_offset, 3 * TEST_BUF_DURATION, 1 * TEST_BUF_DURATION); /* buffer 4 is pushed as normal */ buffer = gst_harness_pull (h); fail_unless_equals_int ((4 + seq_offset) & 0xffff, get_rtp_seq_num (buffer)); gst_buffer_unref (buffer); /* we have lost 3, and one of them arrived eventually, but too late */ fail_unless (verify_jb_stats (h->element, gst_structure_new ("application/x-rtp-jitterbuffer-stats", "num-pushed", G_TYPE_UINT64, (guint64) 2, "num-lost", G_TYPE_UINT64, (guint64) 3, "num-late", G_TYPE_UINT64, (guint64) 1, NULL))); gst_object_unref (testclock); gst_harness_teardown (h); } GST_END_TEST; GST_START_TEST (test_performance) { GstHarness *h = gst_harness_new_parse ("rtpjitterbuffer do-lost=1 do-retransmission=1 latency=1000"); GTimer *timer = g_timer_new (); const gdouble test_duration = 2.0; guint buffers_pushed = 0; guint buffers_received; gst_harness_set_src_caps (h, generate_caps ()); gst_harness_use_systemclock (h); while (g_timer_elapsed (timer, NULL) < test_duration) { /* Simulate 1ms packets */ guint n = buffers_pushed * 2; // every packet also produces a gap guint16 seqnum = n & 0xffff; guint32 rtp_ts = n * 8; GstClockTime dts = n * GST_MSECOND; gst_harness_push (h, generate_test_buffer_full (dts, seqnum, rtp_ts)); buffers_pushed++; g_usleep (G_USEC_PER_SEC / 10000); } g_timer_destroy (timer); buffers_received = gst_harness_buffers_received (h); GST_INFO ("Pushed %d, received %d (%.1f%%)", buffers_pushed, buffers_received, 100.0 * buffers_received / buffers_pushed); gst_harness_teardown (h); } GST_END_TEST; static Suite * rtpjitterbuffer_suite (void) { Suite *s = suite_create ("rtpjitterbuffer"); TCase *tc_chain = tcase_create ("general"); suite_add_tcase (s, tc_chain); tcase_add_test (tc_chain, test_push_forward_seq); tcase_add_test (tc_chain, test_push_backward_seq); tcase_add_test (tc_chain, test_push_unordered); tcase_add_test (tc_chain, test_basetime); tcase_add_test (tc_chain, test_clear_pt_map); tcase_add_test (tc_chain, test_lost_event); tcase_add_test (tc_chain, test_only_one_lost_event_on_large_gaps); tcase_add_test (tc_chain, test_two_lost_one_arrives_in_time); tcase_add_test (tc_chain, test_late_packets_still_makes_lost_events); tcase_add_test (tc_chain, test_lost_event_uses_pts); tcase_add_test (tc_chain, test_lost_event_with_backwards_rtptime); tcase_add_test (tc_chain, test_all_packets_are_timestamped_zero); tcase_add_loop_test (tc_chain, test_num_late_when_considered_lost_arrives, 0, 2); tcase_add_test (tc_chain, test_reorder_of_non_equidistant_packets); tcase_add_test (tc_chain, test_loss_equidistant_spacing_with_parameter_packets); tcase_add_test (tc_chain, test_rtx_expected_next); tcase_add_test (tc_chain, test_rtx_two_missing); tcase_add_test (tc_chain, test_rtx_buffer_arrives_just_in_time); tcase_add_test (tc_chain, test_rtx_buffer_arrives_too_late); tcase_add_test (tc_chain, test_rtx_original_buffer_does_not_update_rtx_stats); tcase_add_test (tc_chain, test_rtx_duplicate_packet_updates_rtx_stats); tcase_add_test (tc_chain, test_rtx_buffer_arrives_after_lost_updates_rtx_stats); tcase_add_test (tc_chain, test_rtx_rtt_larger_than_retry_timeout); tcase_add_test (tc_chain, test_rtx_no_request_if_time_past_retry_period); tcase_add_test (tc_chain, test_rtx_same_delay_and_retry_timeout); tcase_add_test (tc_chain, test_rtx_with_backwards_rtptime); tcase_add_test (tc_chain, test_rtx_timer_reuse); tcase_add_test (tc_chain, test_deadline_ts_offset); tcase_add_test (tc_chain, test_push_big_gap); tcase_add_loop_test (tc_chain, test_considered_lost_packet_in_large_gap_arrives, 0, G_N_ELEMENTS (test_considered_lost_packet_in_large_gap_arrives_input)); tcase_add_test (tc_chain, test_performance); return s; } GST_CHECK_MAIN (rtpjitterbuffer);