/* GStreamer unit tests for multiqueue * * Copyright (C) 2007 Tim-Philipp Müller * * 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 static GMutex _check_lock; static GstElement * setup_multiqueue (GstElement * pipe, GstElement * inputs[], GstElement * outputs[], guint num) { GstElement *mq; guint i; mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL, "failed to create 'multiqueue' element"); gst_bin_add (GST_BIN (pipe), mq); for (i = 0; i < num; ++i) { GstPad *sinkpad = NULL; GstPad *srcpad = NULL; /* create multiqueue sink (and source) pad */ sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (sinkpad != NULL, "failed to create multiqueue request pad #%u", i); /* link input element N to the N-th multiqueue sink pad we just created */ if (inputs != NULL && inputs[i] != NULL) { gst_bin_add (GST_BIN (pipe), inputs[i]); srcpad = gst_element_get_static_pad (inputs[i], "src"); fail_unless (srcpad != NULL, "failed to find src pad for input #%u", i); fail_unless_equals_int (GST_PAD_LINK_OK, gst_pad_link (srcpad, sinkpad)); gst_object_unref (srcpad); srcpad = NULL; } gst_object_unref (sinkpad); sinkpad = NULL; /* link output element N to the N-th multiqueue src pad */ if (outputs != NULL && outputs[i] != NULL) { gchar padname[10]; /* only the sink pads are by request, the source pads are sometimes pads, * so this should return NULL */ srcpad = gst_element_get_request_pad (mq, "src_%u"); fail_unless (srcpad == NULL); g_snprintf (padname, sizeof (padname), "src_%u", i); srcpad = gst_element_get_static_pad (mq, padname); fail_unless (srcpad != NULL, "failed to get multiqueue src pad #%u", i); fail_unless (GST_PAD_IS_SRC (srcpad), "%s:%s is not a source pad?!", GST_DEBUG_PAD_NAME (srcpad)); gst_bin_add (GST_BIN (pipe), outputs[i]); sinkpad = gst_element_get_static_pad (outputs[i], "sink"); fail_unless (sinkpad != NULL, "failed to find sink pad of output #%u", i); fail_unless (GST_PAD_IS_SINK (sinkpad)); fail_unless_equals_int (GST_PAD_LINK_OK, gst_pad_link (srcpad, sinkpad)); gst_object_unref (srcpad); gst_object_unref (sinkpad); } } return mq; } GST_START_TEST (test_simple_pipeline) { GstElement *pipe; GstElement *inputs[1]; GstElement *outputs[1]; GstMessage *msg; pipe = gst_pipeline_new ("pipeline"); inputs[0] = gst_element_factory_make ("fakesrc", NULL); fail_unless (inputs[0] != NULL, "failed to create 'fakesrc' element"); g_object_set (inputs[0], "num-buffers", 256, NULL); outputs[0] = gst_element_factory_make ("fakesink", NULL); fail_unless (outputs[0] != NULL, "failed to create 'fakesink' element"); setup_multiqueue (pipe, inputs, outputs, 1); gst_element_set_state (pipe, GST_STATE_PLAYING); msg = gst_bus_poll (GST_ELEMENT_BUS (pipe), GST_MESSAGE_EOS | GST_MESSAGE_ERROR, -1); fail_if (GST_MESSAGE_TYPE (msg) == GST_MESSAGE_ERROR, "Expected EOS message, got ERROR message"); gst_message_unref (msg); GST_LOG ("Got EOS, cleaning up"); gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (pipe); } GST_END_TEST; GST_START_TEST (test_simple_shutdown_while_running) { GstElement *pipe; GstElement *inputs[1]; GstElement *outputs[1]; GstMessage *msg; pipe = gst_pipeline_new ("pipeline"); inputs[0] = gst_element_factory_make ("fakesrc", NULL); fail_unless (inputs[0] != NULL, "failed to create 'fakesrc' element"); outputs[0] = gst_element_factory_make ("fakesink", NULL); fail_unless (outputs[0] != NULL, "failed to create 'fakesink' element"); setup_multiqueue (pipe, inputs, outputs, 1); gst_element_set_state (pipe, GST_STATE_PAUSED); /* wait until pipeline is up and running */ msg = gst_bus_poll (GST_ELEMENT_BUS (pipe), GST_MESSAGE_ERROR | GST_MESSAGE_ASYNC_DONE, -1); fail_if (GST_MESSAGE_TYPE (msg) == GST_MESSAGE_ERROR, "Got ERROR message"); gst_message_unref (msg); GST_LOG ("pipeline is running now"); gst_element_set_state (pipe, GST_STATE_PAUSED); /* wait a bit to accumulate some buffers in the queue (while it's blocking * in the sink) */ msg = gst_bus_poll (GST_ELEMENT_BUS (pipe), GST_MESSAGE_ERROR, GST_SECOND / 4); if (msg) g_error ("Got ERROR message"); /* now shut down only the sink, so the queue gets a wrong-state flow return */ gst_element_set_state (outputs[0], GST_STATE_NULL); msg = gst_bus_poll (GST_ELEMENT_BUS (pipe), GST_MESSAGE_ERROR, GST_SECOND / 2); if (msg) g_error ("Got ERROR message"); GST_LOG ("Cleaning up"); gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (pipe); } GST_END_TEST; GST_START_TEST (test_simple_create_destroy) { GstElement *mq; mq = gst_element_factory_make ("multiqueue", NULL); gst_object_unref (mq); } GST_END_TEST; GST_START_TEST (test_request_pads) { GstElement *mq; GstPad *sink1, *sink2; mq = gst_element_factory_make ("multiqueue", NULL); sink1 = gst_element_get_request_pad (mq, "foo_%u"); fail_unless (sink1 == NULL, "Expected NULL pad, as there is no request pad template for 'foo_%%u'"); sink1 = gst_element_get_request_pad (mq, "src_%u"); fail_unless (sink1 == NULL, "Expected NULL pad, as there is no request pad template for 'src_%%u'"); sink1 = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (sink1 != NULL); fail_unless (GST_IS_PAD (sink1)); fail_unless (GST_PAD_IS_SINK (sink1)); GST_LOG ("Got pad %s:%s", GST_DEBUG_PAD_NAME (sink1)); sink2 = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (sink2 != NULL); fail_unless (GST_IS_PAD (sink2)); fail_unless (GST_PAD_IS_SINK (sink2)); GST_LOG ("Got pad %s:%s", GST_DEBUG_PAD_NAME (sink2)); fail_unless (sink1 != sink2); GST_LOG ("Cleaning up"); gst_object_unref (sink1); gst_object_unref (sink2); gst_object_unref (mq); } GST_END_TEST; static GstPad * mq_sinkpad_to_srcpad (GstElement * mq, GstPad * sink) { GstPad *srcpad = NULL; gchar *mq_sinkpad_name; gchar *mq_srcpad_name; mq_sinkpad_name = gst_pad_get_name (sink); fail_unless (g_str_has_prefix (mq_sinkpad_name, "sink")); mq_srcpad_name = g_strdup_printf ("src_%s", mq_sinkpad_name + 5); srcpad = gst_element_get_static_pad (mq, mq_srcpad_name); fail_unless (srcpad != NULL); g_free (mq_sinkpad_name); g_free (mq_srcpad_name); return srcpad; } GST_START_TEST (test_request_pads_named) { GstElement *mq; GstPad *sink1, *sink2, *sink3, *sink4; mq = gst_element_factory_make ("multiqueue", NULL); sink1 = gst_element_get_request_pad (mq, "sink_1"); fail_unless (sink1 != NULL); fail_unless (GST_IS_PAD (sink1)); fail_unless (GST_PAD_IS_SINK (sink1)); fail_unless_equals_string (GST_PAD_NAME (sink1), "sink_1"); GST_LOG ("Got pad %s:%s", GST_DEBUG_PAD_NAME (sink1)); sink3 = gst_element_get_request_pad (mq, "sink_3"); fail_unless (sink3 != NULL); fail_unless (GST_IS_PAD (sink3)); fail_unless (GST_PAD_IS_SINK (sink3)); fail_unless_equals_string (GST_PAD_NAME (sink3), "sink_3"); GST_LOG ("Got pad %s:%s", GST_DEBUG_PAD_NAME (sink3)); sink2 = gst_element_get_request_pad (mq, "sink_2"); fail_unless (sink2 != NULL); fail_unless (GST_IS_PAD (sink2)); fail_unless (GST_PAD_IS_SINK (sink2)); fail_unless_equals_string (GST_PAD_NAME (sink2), "sink_2"); GST_LOG ("Got pad %s:%s", GST_DEBUG_PAD_NAME (sink2)); /* This gets us the first unused id, sink0 */ sink4 = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (sink4 != NULL); fail_unless (GST_IS_PAD (sink4)); fail_unless (GST_PAD_IS_SINK (sink4)); fail_unless_equals_string (GST_PAD_NAME (sink4), "sink_0"); GST_LOG ("Got pad %s:%s", GST_DEBUG_PAD_NAME (sink4)); GST_LOG ("Cleaning up"); gst_object_unref (sink1); gst_object_unref (sink2); gst_object_unref (sink3); gst_object_unref (sink4); gst_object_unref (mq); } GST_END_TEST; static gboolean mq_dummypad_query (GstPad * sinkpad, GstObject * parent, GstQuery * query) { gboolean res = TRUE; switch (GST_QUERY_TYPE (query)) { case GST_QUERY_CAPS: { GstCaps *filter, *caps; gst_query_parse_caps (query, &filter); caps = (filter ? gst_caps_ref (filter) : gst_caps_new_any ()); gst_query_set_caps_result (query, caps); gst_caps_unref (caps); break; } default: res = gst_pad_query_default (sinkpad, parent, query); break; } return res; } struct PadData { GstPad *input_pad; GstPad *out_pad; guint8 pad_num; guint32 *max_linked_id_ptr; guint32 *eos_count_ptr; gboolean is_linked; gboolean first_buf; gint n_linked; GMutex *mutex; GCond *cond; /* used by initial_events_nodelay */ gint event_count; }; static GstFlowReturn mq_dummypad_chain (GstPad * sinkpad, GstObject * parent, GstBuffer * buf) { guint32 cur_id; struct PadData *pad_data; GstMapInfo info; pad_data = gst_pad_get_element_private (sinkpad); g_mutex_lock (&_check_lock); fail_if (pad_data == NULL); /* Read an ID from the first 4 bytes of the buffer data and check it's * what we expect */ fail_unless (gst_buffer_map (buf, &info, GST_MAP_READ)); fail_unless (info.size >= 4); g_mutex_unlock (&_check_lock); cur_id = GST_READ_UINT32_BE (info.data); gst_buffer_unmap (buf, &info); g_mutex_lock (pad_data->mutex); /* For not-linked pads, ensure that we're not running ahead of the 'linked' * pads. The first buffer is allowed to get ahead, because otherwise things can't * always pre-roll correctly */ if (pad_data->max_linked_id_ptr) { if (!pad_data->is_linked) { /* If there are no linked pads, we can't track a max_id for them :) */ if (pad_data->n_linked > 0 && !pad_data->first_buf) { g_mutex_lock (&_check_lock); fail_unless (cur_id <= *(pad_data->max_linked_id_ptr) + 1, "Got buffer %u on pad %u before buffer %u was seen on a " "linked pad (max: %u)", cur_id, pad_data->pad_num, cur_id - 1, *(pad_data->max_linked_id_ptr)); g_mutex_unlock (&_check_lock); } } else { /* Update the max_id value */ if (cur_id > *(pad_data->max_linked_id_ptr)) *(pad_data->max_linked_id_ptr) = cur_id; } } pad_data->first_buf = FALSE; g_mutex_unlock (pad_data->mutex); /* Unref the buffer */ gst_buffer_unref (buf); /* Return OK or not-linked as indicated */ return pad_data->is_linked ? GST_FLOW_OK : GST_FLOW_NOT_LINKED; } static gboolean mq_dummypad_event (GstPad * sinkpad, GstObject * parent, GstEvent * event) { struct PadData *pad_data; pad_data = gst_pad_get_element_private (sinkpad); g_mutex_lock (&_check_lock); fail_if (pad_data == NULL); g_mutex_unlock (&_check_lock); if (GST_EVENT_TYPE (event) == GST_EVENT_EOS) { g_mutex_lock (pad_data->mutex); /* Accumulate that we've seen the EOS and signal the main thread */ if (pad_data->eos_count_ptr) *(pad_data->eos_count_ptr) += 1; GST_DEBUG ("EOS on pad %u", pad_data->pad_num); g_cond_broadcast (pad_data->cond); g_mutex_unlock (pad_data->mutex); } gst_event_unref (event); return TRUE; } static void construct_n_pads (GstElement * mq, struct PadData *pad_data, gint n_pads, gint n_linked) { gint i; GstSegment segment; gst_segment_init (&segment, GST_FORMAT_BYTES); /* Construct NPADS dummy output pads. The first 'n_linked' return FLOW_OK, the rest * return NOT_LINKED. The not-linked ones check the expected ordering of * output buffers */ for (i = 0; i < n_pads; i++) { GstPad *mq_srcpad, *mq_sinkpad, *inpad, *outpad; gchar *name; name = g_strdup_printf ("dummysrc%d", i); inpad = gst_pad_new (name, GST_PAD_SRC); g_free (name); gst_pad_set_query_function (inpad, mq_dummypad_query); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inpad, mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inpad, TRUE); gst_pad_push_event (inpad, gst_event_new_stream_start ("test")); gst_pad_push_event (inpad, gst_event_new_segment (&segment)); mq_srcpad = mq_sinkpad_to_srcpad (mq, mq_sinkpad); name = g_strdup_printf ("dummysink%d", i); outpad = gst_pad_new (name, GST_PAD_SINK); g_free (name); gst_pad_set_chain_function (outpad, mq_dummypad_chain); gst_pad_set_event_function (outpad, mq_dummypad_event); gst_pad_set_query_function (outpad, mq_dummypad_query); pad_data[i].pad_num = i; pad_data[i].input_pad = inpad; pad_data[i].out_pad = outpad; pad_data[i].max_linked_id_ptr = NULL; pad_data[i].eos_count_ptr = NULL; pad_data[i].is_linked = (i < n_linked ? TRUE : FALSE); pad_data[i].n_linked = n_linked; pad_data[i].cond = NULL; pad_data[i].mutex = NULL; pad_data[i].first_buf = TRUE; gst_pad_set_element_private (outpad, pad_data + i); fail_unless (gst_pad_link (mq_srcpad, outpad) == GST_PAD_LINK_OK); gst_pad_set_active (outpad, TRUE); gst_object_unref (mq_sinkpad); gst_object_unref (mq_srcpad); } } static void push_n_buffers (struct PadData *pad_data, gint num_buffers, const guint8 * pad_pattern, guint pattern_size) { gint i; for (i = 0; i < num_buffers; i++) { guint8 cur_pad; GstBuffer *buf; GstFlowReturn ret; GstMapInfo info; cur_pad = pad_pattern[i % pattern_size]; buf = gst_buffer_new_and_alloc (4); g_mutex_lock (&_check_lock); fail_if (buf == NULL); g_mutex_unlock (&_check_lock); fail_unless (gst_buffer_map (buf, &info, GST_MAP_WRITE)); GST_WRITE_UINT32_BE (info.data, i + 1); gst_buffer_unmap (buf, &info); GST_BUFFER_TIMESTAMP (buf) = (i + 1) * GST_SECOND; ret = gst_pad_push (pad_data[cur_pad].input_pad, buf); g_mutex_lock (&_check_lock); if (pad_data[cur_pad].is_linked) { fail_unless (ret == GST_FLOW_OK, "Push on pad %d returned %d when FLOW_OK was expected", cur_pad, ret); } else { /* Expect OK initially, then NOT_LINKED when the srcpad starts pushing */ fail_unless (ret == GST_FLOW_OK || ret == GST_FLOW_NOT_LINKED, "Push on pad %d returned %d when FLOW_OK or NOT_LINKED was expected", cur_pad, ret); } g_mutex_unlock (&_check_lock); } } static void run_output_order_test (gint n_linked) { /* This test creates a multiqueue with 2 linked output, and 3 outputs that * return 'not-linked' when data is pushed, then verifies that all buffers * are received on not-linked pads only after earlier buffers on the * 'linked' pads are made */ GstElement *pipe; GstElement *mq; struct PadData pad_data[5]; guint32 max_linked_id; guint32 eos_seen; GMutex mutex; GCond cond; gint i; const gint NPADS = 5; const gint NBUFFERS = 1000; g_mutex_init (&mutex); g_cond_init (&cond); pipe = gst_bin_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); /* No limits */ g_object_set (mq, "max-size-bytes", (guint) 0, "max-size-buffers", (guint) 0, "max-size-time", (guint64) 0, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, NULL); construct_n_pads (mq, pad_data, NPADS, n_linked); for (i = 0; i < NPADS; i++) { pad_data[i].max_linked_id_ptr = &max_linked_id; /* Only look for EOS on the linked pads */ pad_data[i].eos_count_ptr = (i < n_linked) ? &eos_seen : NULL; pad_data[i].cond = &cond; pad_data[i].mutex = &mutex; } /* Run the test. Push 1000 buffers through the multiqueue in a pattern */ max_linked_id = 0; eos_seen = 0; gst_element_set_state (pipe, GST_STATE_PLAYING); { const guint8 pad_pattern[] = { 0, 0, 0, 0, 1, 1, 2, 1, 0, 2, 3, 2, 3, 1, 4 }; const guint n = sizeof (pad_pattern) / sizeof (guint8); push_n_buffers (pad_data, NBUFFERS, pad_pattern, n); } for (i = 0; i < NPADS; i++) { gst_pad_push_event (pad_data[i].input_pad, gst_event_new_eos ()); } /* Wait while the buffers are processed */ g_mutex_lock (&mutex); /* We wait until EOS has been pushed on all linked pads */ while (eos_seen < n_linked) { g_cond_wait (&cond, &mutex); } g_mutex_unlock (&mutex); /* Clean up */ for (i = 0; i < NPADS; i++) { GstPad *mq_input = gst_pad_get_peer (pad_data[i].input_pad); gst_pad_unlink (pad_data[i].input_pad, mq_input); gst_element_release_request_pad (mq, mq_input); gst_object_unref (mq_input); gst_object_unref (pad_data[i].input_pad); gst_object_unref (pad_data[i].out_pad); } gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (pipe); g_cond_clear (&cond); g_mutex_clear (&mutex); } GST_START_TEST (test_output_order) { run_output_order_test (2); run_output_order_test (0); } GST_END_TEST; GST_START_TEST (test_not_linked_eos) { /* This test creates a multiqueue with 1 linked output and 1 not-linked * pad. It pushes a few buffers through each, then EOS on the linked * pad and waits until that arrives. After that, it pushes some more * buffers on the not-linked pad and then EOS and checks that those * are all output */ GstElement *pipe; GstElement *mq; struct PadData pad_data[2]; guint32 eos_seen; GMutex mutex; GCond cond; gint i; const gint NPADS = 2; const gint NBUFFERS = 20; GstSegment segment; gst_segment_init (&segment, GST_FORMAT_BYTES); g_mutex_init (&mutex); g_cond_init (&cond); pipe = gst_bin_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); /* No limits */ g_object_set (mq, "max-size-bytes", (guint) 0, "max-size-buffers", (guint) 0, "max-size-time", (guint64) 0, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, NULL); /* Construct NPADS dummy output pads. The first 1 returns FLOW_OK, the rest * return NOT_LINKED. */ construct_n_pads (mq, pad_data, NPADS, 1); for (i = 0; i < NPADS; i++) { /* Only look for EOS on the linked pads */ pad_data[i].eos_count_ptr = &eos_seen; pad_data[i].cond = &cond; pad_data[i].mutex = &mutex; } /* Run the test. Push 20 buffers through the multiqueue in a pattern */ eos_seen = 0; gst_element_set_state (pipe, GST_STATE_PLAYING); { const guint8 pad_pattern[] = { 0, 1 }; const guint n = sizeof (pad_pattern) / sizeof (guint8); push_n_buffers (pad_data, NBUFFERS, pad_pattern, n); } /* Make the linked pad go EOS */ gst_pad_push_event (pad_data[0].input_pad, gst_event_new_eos ()); g_mutex_lock (&mutex); /* Wait until EOS has been seen on the linked pad */ while (eos_seen == 0) g_cond_wait (&cond, &mutex); g_mutex_unlock (&mutex); /* Now push some more buffers to the not-linked pad */ { const guint8 pad_pattern[] = { 1, 1 }; const guint n = sizeof (pad_pattern) / sizeof (guint8); push_n_buffers (pad_data, NBUFFERS, pad_pattern, n); } /* And EOS on the not-linked pad */ gst_pad_push_event (pad_data[1].input_pad, gst_event_new_eos ()); g_mutex_lock (&mutex); while (eos_seen < NPADS) g_cond_wait (&cond, &mutex); g_mutex_unlock (&mutex); /* Clean up */ for (i = 0; i < NPADS; i++) { GstPad *mq_input = gst_pad_get_peer (pad_data[i].input_pad); gst_pad_unlink (pad_data[i].input_pad, mq_input); gst_element_release_request_pad (mq, mq_input); gst_object_unref (mq_input); gst_object_unref (pad_data[i].input_pad); gst_object_unref (pad_data[i].out_pad); } gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (pipe); g_cond_clear (&cond); g_mutex_clear (&mutex); } GST_END_TEST; GST_START_TEST (test_sparse_stream) { /* This test creates a multiqueue with 2 streams. One receives * a constant flow of buffers, the other only gets one buffer, and then * new-segment events, and returns not-linked. The multiqueue should not fill. */ GstElement *pipe; GstElement *mq; GstPad *inputpads[2]; GstPad *sinkpads[2]; GstEvent *event; struct PadData pad_data[2]; guint32 eos_seen, max_linked_id; GMutex mutex; GCond cond; gint i; const gint NBUFFERS = 100; GstSegment segment; g_mutex_init (&mutex); g_cond_init (&cond); pipe = gst_pipeline_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); /* 1 second limit */ g_object_set (mq, "max-size-bytes", (guint) 0, "max-size-buffers", (guint) 0, "max-size-time", (guint64) GST_SECOND, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, NULL); gst_segment_init (&segment, GST_FORMAT_TIME); /* Construct 2 dummy output pads. */ for (i = 0; i < 2; i++) { GstPad *mq_srcpad, *mq_sinkpad; gchar *name; name = g_strdup_printf ("dummysrc%d", i); inputpads[i] = gst_pad_new (name, GST_PAD_SRC); g_free (name); gst_pad_set_query_function (inputpads[i], mq_dummypad_query); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpads[i], mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpads[i], TRUE); gst_pad_push_event (inputpads[i], gst_event_new_stream_start ("test")); gst_pad_push_event (inputpads[i], gst_event_new_segment (&segment)); mq_srcpad = mq_sinkpad_to_srcpad (mq, mq_sinkpad); name = g_strdup_printf ("dummysink%d", i); sinkpads[i] = gst_pad_new (name, GST_PAD_SINK); g_free (name); gst_pad_set_chain_function (sinkpads[i], mq_dummypad_chain); gst_pad_set_event_function (sinkpads[i], mq_dummypad_event); gst_pad_set_query_function (sinkpads[i], mq_dummypad_query); pad_data[i].pad_num = i; pad_data[i].max_linked_id_ptr = &max_linked_id; if (i == 0) pad_data[i].eos_count_ptr = &eos_seen; else pad_data[i].eos_count_ptr = NULL; pad_data[i].is_linked = (i == 0) ? TRUE : FALSE; pad_data[i].n_linked = 1; pad_data[i].cond = &cond; pad_data[i].mutex = &mutex; pad_data[i].first_buf = TRUE; gst_pad_set_element_private (sinkpads[i], pad_data + i); fail_unless (gst_pad_link (mq_srcpad, sinkpads[i]) == GST_PAD_LINK_OK); gst_pad_set_active (sinkpads[i], TRUE); gst_object_unref (mq_sinkpad); gst_object_unref (mq_srcpad); } /* Run the test. Push 100 buffers through the multiqueue */ max_linked_id = 0; eos_seen = 0; gst_element_set_state (pipe, GST_STATE_PLAYING); for (i = 0; i < NBUFFERS; i++) { GstBuffer *buf; GstFlowReturn ret; GstClockTime ts; GstMapInfo info; ts = gst_util_uint64_scale_int (GST_SECOND, i, 10); buf = gst_buffer_new_and_alloc (4); g_mutex_lock (&_check_lock); fail_if (buf == NULL); g_mutex_unlock (&_check_lock); fail_unless (gst_buffer_map (buf, &info, GST_MAP_WRITE)); GST_WRITE_UINT32_BE (info.data, i + 1); gst_buffer_unmap (buf, &info); GST_BUFFER_TIMESTAMP (buf) = gst_util_uint64_scale_int (GST_SECOND, i, 10); /* If i == 0, also push the buffer to the 2nd pad */ if (i == 0) ret = gst_pad_push (inputpads[1], gst_buffer_ref (buf)); ret = gst_pad_push (inputpads[0], buf); g_mutex_lock (&_check_lock); fail_unless (ret == GST_FLOW_OK, "Push on pad %d returned %d when FLOW_OK was expected", 0, ret); g_mutex_unlock (&_check_lock); /* Push a new segment update on the 2nd pad */ gst_segment_init (&segment, GST_FORMAT_TIME); segment.start = ts; segment.time = ts; event = gst_event_new_segment (&segment); gst_pad_push_event (inputpads[1], event); } event = gst_event_new_eos (); gst_pad_push_event (inputpads[0], gst_event_ref (event)); gst_pad_push_event (inputpads[1], event); /* Wait while the buffers are processed */ g_mutex_lock (&mutex); /* We wait until EOS has been pushed on pad 1 */ while (eos_seen < 1) { g_cond_wait (&cond, &mutex); } g_mutex_unlock (&mutex); /* Clean up */ for (i = 0; i < 2; i++) { GstPad *mq_input = gst_pad_get_peer (inputpads[i]); gst_pad_unlink (inputpads[i], mq_input); gst_element_release_request_pad (mq, mq_input); gst_object_unref (mq_input); gst_object_unref (inputpads[i]); gst_object_unref (sinkpads[i]); } gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (pipe); g_cond_clear (&cond); g_mutex_clear (&mutex); } GST_END_TEST; static gpointer pad_push_datablock_thread (gpointer data) { GstPad *pad = data; GstBuffer *buf; buf = gst_buffer_new_allocate (NULL, 80 * 1000, NULL); gst_pad_push (pad, buf); return NULL; } static GstPadProbeReturn block_probe (GstPad * pad, GstPadProbeInfo * info, gpointer user_data) { return GST_PAD_PROBE_OK; } #define CHECK_FOR_BUFFERING_MSG(PIPELINE, EXPECTED_PERC) \ G_STMT_START { \ gint buf_perc; \ GstMessage *msg; \ GST_LOG ("waiting for %d%% buffering message", (EXPECTED_PERC)); \ msg = gst_bus_poll (GST_ELEMENT_BUS (PIPELINE), \ GST_MESSAGE_BUFFERING | GST_MESSAGE_ERROR, -1); \ fail_if (GST_MESSAGE_TYPE (msg) == GST_MESSAGE_ERROR, \ "Expected BUFFERING message, got ERROR message"); \ gst_message_parse_buffering (msg, &buf_perc); \ gst_message_unref (msg); \ fail_unless (buf_perc == (EXPECTED_PERC), \ "Got incorrect percentage: %d%% expected: %d%%", buf_perc, \ (EXPECTED_PERC)); \ } G_STMT_END GST_START_TEST (test_initial_fill_above_high_threshold) { /* This test checks what happens if the first buffer that enters * the queue immediately fills it above the high-threshold. */ GstElement *pipe; GstElement *mq, *fakesink; GstPad *inputpad; GstPad *mq_sinkpad; GstPad *sinkpad; GstSegment segment; GThread *thread; /* Setup test pipeline with one multiqueue and one fakesink */ pipe = gst_pipeline_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); fakesink = gst_element_factory_make ("fakesink", NULL); fail_unless (fakesink != NULL); gst_bin_add (GST_BIN (pipe), fakesink); /* Block fakesink sinkpad flow to ensure the queue isn't emptied * by the prerolling sink */ sinkpad = gst_element_get_static_pad (fakesink, "sink"); gst_pad_add_probe (sinkpad, GST_PAD_PROBE_TYPE_BLOCK, block_probe, NULL, NULL); gst_object_unref (sinkpad); /* Set size limit to 1000000 byte, low threshold to 1%, high * threshold to 5%, to make sure that even just one data push * will exceed both thresholds.*/ g_object_set (mq, "use-buffering", (gboolean) TRUE, "max-size-bytes", (guint) 1000 * 1000, "max-size-buffers", (guint) 0, "max-size-time", (guint64) 0, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, "low-percent", (gint) 1, "high-percent", (gint) 5, NULL); gst_segment_init (&segment, GST_FORMAT_TIME); inputpad = gst_pad_new ("dummysrc", GST_PAD_SRC); gst_pad_set_query_function (inputpad, mq_dummypad_query); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpad, mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpad, TRUE); gst_pad_push_event (inputpad, gst_event_new_stream_start ("test")); gst_pad_push_event (inputpad, gst_event_new_segment (&segment)); gst_object_unref (mq_sinkpad); fail_unless (gst_element_link (mq, fakesink)); /* Start pipeline in paused state to ensure the sink remains * in preroll mode and blocks */ gst_element_set_state (pipe, GST_STATE_PAUSED); /* Feed data. queue will be filled to 8% (because it pushes 80000 bytes), * which is above both the low- and the high-threshold. This should * produce a 100% buffering message. */ thread = g_thread_new ("push1", pad_push_datablock_thread, inputpad); g_thread_join (thread); CHECK_FOR_BUFFERING_MSG (pipe, 100); gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (inputpad); gst_object_unref (pipe); } GST_END_TEST; GST_START_TEST (test_high_threshold_change) { /* This test checks what happens if the high threshold is changed to a * value below the current buffer fill level. Expected behavior is for * multiqueue to emit a 100% buffering message in that case. */ GstElement *pipe; GstElement *mq, *fakesink; GstPad *inputpad; GstPad *mq_sinkpad; GstPad *sinkpad; GstSegment segment; GThread *thread; /* Setup test pipeline with one multiqueue and one fakesink */ pipe = gst_pipeline_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); fakesink = gst_element_factory_make ("fakesink", NULL); fail_unless (fakesink != NULL); gst_bin_add (GST_BIN (pipe), fakesink); /* Block fakesink sinkpad flow to ensure the queue isn't emptied * by the prerolling sink */ sinkpad = gst_element_get_static_pad (fakesink, "sink"); gst_pad_add_probe (sinkpad, GST_PAD_PROBE_TYPE_BLOCK, block_probe, NULL, NULL); gst_object_unref (sinkpad); g_object_set (mq, "use-buffering", (gboolean) TRUE, "max-size-bytes", (guint) 1000 * 1000, "max-size-buffers", (guint) 0, "max-size-time", (guint64) 0, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, "low-percent", (gint) 1, "high-percent", (gint) 99, NULL); gst_segment_init (&segment, GST_FORMAT_TIME); inputpad = gst_pad_new ("dummysrc", GST_PAD_SRC); gst_pad_set_query_function (inputpad, mq_dummypad_query); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpad, mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpad, TRUE); gst_pad_push_event (inputpad, gst_event_new_stream_start ("test")); gst_pad_push_event (inputpad, gst_event_new_segment (&segment)); gst_object_unref (mq_sinkpad); fail_unless (gst_element_link (mq, fakesink)); /* Start pipeline in paused state to ensure the sink remains * in preroll mode and blocks */ gst_element_set_state (pipe, GST_STATE_PAUSED); /* Feed data. queue will be filled to 8% (because it pushes 80000 bytes), * which is below the high-threshold, provoking a buffering message. */ thread = g_thread_new ("push1", pad_push_datablock_thread, inputpad); g_thread_join (thread); /* Check for the buffering message; it should indicate 8% fill level * (Note that the percentage from the message is normalized, but since * the high threshold is at 99%, it should still apply) */ CHECK_FOR_BUFFERING_MSG (pipe, 8); /* Set high threshold to half of what it was before. This means that the * relative fill level doubles. As a result, this should trigger a buffering * message with a percentage of 16%. */ g_object_set (mq, "high-percent", (gint) 50, NULL); CHECK_FOR_BUFFERING_MSG (pipe, 16); /* Set high threshold to a value that lies below the current fill level. * This should trigger a 100% buffering message immediately, even without * pushing in extra data. */ g_object_set (mq, "high-percent", (gint) 5, NULL); CHECK_FOR_BUFFERING_MSG (pipe, 100); gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (inputpad); gst_object_unref (pipe); } GST_END_TEST; GST_START_TEST (test_low_threshold_change) { /* This tests what happens if the queue isn't currently buffering and the * low-threshold is raised above the current fill level. */ GstElement *pipe; GstElement *mq, *fakesink; GstPad *inputpad; GstPad *mq_sinkpad; GstPad *sinkpad; GstSegment segment; GThread *thread; /* Setup test pipeline with one multiqueue and one fakesink */ pipe = gst_pipeline_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); fakesink = gst_element_factory_make ("fakesink", NULL); fail_unless (fakesink != NULL); gst_bin_add (GST_BIN (pipe), fakesink); /* Block fakesink sinkpad flow to ensure the queue isn't emptied * by the prerolling sink */ sinkpad = gst_element_get_static_pad (fakesink, "sink"); gst_pad_add_probe (sinkpad, GST_PAD_PROBE_TYPE_BLOCK, block_probe, NULL, NULL); gst_object_unref (sinkpad); /* Enable buffering and set the low/high thresholds to 1%/5%. This ensures * that after pushing one data block, the high threshold is reached, and * buffering ceases. */ g_object_set (mq, "use-buffering", (gboolean) TRUE, "max-size-bytes", (guint) 1000 * 1000, "max-size-buffers", (guint) 0, "max-size-time", (guint64) 0, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, "low-percent", (gint) 1, "high-percent", (gint) 5, NULL); gst_segment_init (&segment, GST_FORMAT_TIME); inputpad = gst_pad_new ("dummysrc", GST_PAD_SRC); gst_pad_set_query_function (inputpad, mq_dummypad_query); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpad, mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpad, TRUE); gst_pad_push_event (inputpad, gst_event_new_stream_start ("test")); gst_pad_push_event (inputpad, gst_event_new_segment (&segment)); gst_object_unref (mq_sinkpad); fail_unless (gst_element_link (mq, fakesink)); /* Start pipeline in paused state to ensure the sink remains * in preroll mode and blocks */ gst_element_set_state (pipe, GST_STATE_PAUSED); /* Feed data. queue will be filled to 8% (because it pushes 80000 bytes), * which is above the high-threshold, ensuring that the queue disables * its buffering mode internally. */ thread = g_thread_new ("push1", pad_push_datablock_thread, inputpad); g_thread_join (thread); /* Check for the buffering message; it should indicate 100% relative fill * level (Note that the percentage from the message is normalized) */ CHECK_FOR_BUFFERING_MSG (pipe, 100); /* Set low threshold to a 10%, which is above the current fill level of 8%. * As a result, the queue must re-enable its buffering mode, and post the * current relative fill level of 40% (since high-percent is also set to 20% * and 8%/20% = 40%). */ g_object_set (mq, "high-percent", (gint) 20, "low-percent", (gint) 10, NULL); CHECK_FOR_BUFFERING_MSG (pipe, 40); gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (inputpad); gst_object_unref (pipe); } GST_END_TEST; static gpointer pad_push_thread (gpointer data) { GstPad *pad = data; GstBuffer *buf; buf = gst_buffer_new (); gst_pad_push (pad, buf); return NULL; } GST_START_TEST (test_limit_changes) { /* This test creates a multiqueue with 1 stream. The limit of the queue * is two buffers, we check if we block once this is reached. Then we * change the limit to three buffers and check if this is waking up * the queue and we get the third buffer. */ GstElement *pipe; GstElement *mq, *fakesink; GstPad *inputpad; GstPad *mq_sinkpad; GstSegment segment; GThread *thread; pipe = gst_pipeline_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); fakesink = gst_element_factory_make ("fakesink", NULL); fail_unless (fakesink != NULL); gst_bin_add (GST_BIN (pipe), fakesink); g_object_set (mq, "max-size-bytes", (guint) 0, "max-size-buffers", (guint) 2, "max-size-time", (guint64) 0, "extra-size-bytes", (guint) 0, "extra-size-buffers", (guint) 0, "extra-size-time", (guint64) 0, NULL); gst_segment_init (&segment, GST_FORMAT_TIME); inputpad = gst_pad_new ("dummysrc", GST_PAD_SRC); gst_pad_set_query_function (inputpad, mq_dummypad_query); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpad, mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpad, TRUE); gst_pad_push_event (inputpad, gst_event_new_stream_start ("test")); gst_pad_push_event (inputpad, gst_event_new_segment (&segment)); gst_object_unref (mq_sinkpad); fail_unless (gst_element_link (mq, fakesink)); gst_element_set_state (pipe, GST_STATE_PAUSED); thread = g_thread_new ("push1", pad_push_thread, inputpad); g_thread_join (thread); thread = g_thread_new ("push2", pad_push_thread, inputpad); g_thread_join (thread); thread = g_thread_new ("push3", pad_push_thread, inputpad); g_thread_join (thread); thread = g_thread_new ("push4", pad_push_thread, inputpad); /* Wait until we are actually blocking... we unfortunately can't * know that without sleeping */ sleep (1); g_object_set (mq, "max-size-buffers", (guint) 3, NULL); g_thread_join (thread); g_object_set (mq, "max-size-buffers", (guint) 4, NULL); thread = g_thread_new ("push5", pad_push_thread, inputpad); g_thread_join (thread); gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (inputpad); gst_object_unref (pipe); } GST_END_TEST; static GMutex block_mutex; static GCond block_cond; static gint unblock_count; static gboolean expect_overrun; static GstFlowReturn pad_chain_block (GstPad * pad, GstObject * parent, GstBuffer * buffer) { g_mutex_lock (&block_mutex); while (unblock_count == 0) { g_cond_wait (&block_cond, &block_mutex); } if (unblock_count > 0) { unblock_count--; } g_mutex_unlock (&block_mutex); gst_buffer_unref (buffer); return GST_FLOW_OK; } static gboolean pad_event_always_ok (GstPad * pad, GstObject * parent, GstEvent * event) { gst_event_unref (event); return TRUE; } static void mq_overrun (GstElement * mq, gpointer udata) { fail_unless (expect_overrun); /* unblock always so we don't get stuck */ g_mutex_lock (&block_mutex); unblock_count = 2; /* let the PTS=0 and PTS=none go */ g_cond_signal (&block_cond); g_mutex_unlock (&block_mutex); } GST_START_TEST (test_buffering_with_none_pts) { /* * This test creates a multiqueue where source pushing blocks so we can check * how its buffering level is reacting to GST_CLOCK_TIME_NONE buffers * mixed with properly timestamped buffers. * * Sequence of pushing: * pts=0 * pts=none * pts=1 (it gets full now) * pts=none (overrun expected) */ GstElement *mq; GstPad *inputpad; GstPad *outputpad; GstPad *mq_sinkpad; GstPad *mq_srcpad; GstSegment segment; GstBuffer *buffer; g_mutex_init (&block_mutex); g_cond_init (&block_cond); unblock_count = 0; expect_overrun = FALSE; mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); g_object_set (mq, "max-size-bytes", (guint) 0, "max-size-buffers", (guint) 0, "max-size-time", (guint64) GST_SECOND, NULL); g_signal_connect (mq, "overrun", (GCallback) mq_overrun, NULL); gst_segment_init (&segment, GST_FORMAT_TIME); inputpad = gst_pad_new ("dummysrc", GST_PAD_SRC); outputpad = gst_pad_new ("dummysink", GST_PAD_SINK); gst_pad_set_chain_function (outputpad, pad_chain_block); gst_pad_set_event_function (outputpad, pad_event_always_ok); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); mq_srcpad = gst_element_get_static_pad (mq, "src_0"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpad, mq_sinkpad) == GST_PAD_LINK_OK); fail_unless (gst_pad_link (mq_srcpad, outputpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpad, TRUE); gst_pad_set_active (outputpad, TRUE); gst_pad_push_event (inputpad, gst_event_new_stream_start ("test")); gst_pad_push_event (inputpad, gst_event_new_segment (&segment)); gst_element_set_state (mq, GST_STATE_PAUSED); /* push a buffer with PTS = 0 */ buffer = gst_buffer_new (); GST_BUFFER_PTS (buffer) = 0; fail_unless (gst_pad_push (inputpad, buffer) == GST_FLOW_OK); /* push a buffer with PTS = NONE */ buffer = gst_buffer_new (); GST_BUFFER_PTS (buffer) = GST_CLOCK_TIME_NONE; fail_unless (gst_pad_push (inputpad, buffer) == GST_FLOW_OK); /* push a buffer with PTS = 1s, so we have 1s of data in multiqueue, we are * full */ buffer = gst_buffer_new (); GST_BUFFER_PTS (buffer) = GST_SECOND; fail_unless (gst_pad_push (inputpad, buffer) == GST_FLOW_OK); /* push a buffer with PTS = NONE, the queue is full so it should overrun */ expect_overrun = TRUE; buffer = gst_buffer_new (); GST_BUFFER_PTS (buffer) = GST_CLOCK_TIME_NONE; fail_unless (gst_pad_push (inputpad, buffer) == GST_FLOW_OK); g_mutex_lock (&block_mutex); unblock_count = -1; g_cond_signal (&block_cond); g_mutex_unlock (&block_mutex); gst_element_set_state (mq, GST_STATE_NULL); gst_object_unref (inputpad); gst_object_unref (outputpad); gst_object_unref (mq_sinkpad); gst_object_unref (mq_srcpad); gst_object_unref (mq); g_mutex_clear (&block_mutex); g_cond_clear (&block_cond); } GST_END_TEST; static gboolean event_func_signal (GstPad * sinkpad, GstObject * parent, GstEvent * event) { struct PadData *pad_data; GST_LOG_OBJECT (sinkpad, "%s event", GST_EVENT_TYPE_NAME (event)); pad_data = gst_pad_get_element_private (sinkpad); g_mutex_lock (pad_data->mutex); ++pad_data->event_count; g_cond_broadcast (pad_data->cond); g_mutex_unlock (pad_data->mutex); gst_event_unref (event); return TRUE; } GST_START_TEST (test_initial_events_nodelay) { struct PadData pad_data = { 0, }; GstElement *pipe; GstElement *mq; GstPad *inputpad; GstPad *sinkpad; GstSegment segment; GstCaps *caps; GMutex mutex; GCond cond; g_mutex_init (&mutex); g_cond_init (&cond); pipe = gst_pipeline_new ("testbin"); mq = gst_element_factory_make ("multiqueue", NULL); fail_unless (mq != NULL); gst_bin_add (GST_BIN (pipe), mq); { GstPad *mq_srcpad, *mq_sinkpad; inputpad = gst_pad_new ("dummysrc", GST_PAD_SRC); mq_sinkpad = gst_element_get_request_pad (mq, "sink_%u"); fail_unless (mq_sinkpad != NULL); fail_unless (gst_pad_link (inputpad, mq_sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (inputpad, TRUE); mq_srcpad = mq_sinkpad_to_srcpad (mq, mq_sinkpad); sinkpad = gst_pad_new ("dummysink", GST_PAD_SINK); gst_pad_set_event_function (sinkpad, event_func_signal); pad_data.event_count = 0; pad_data.cond = &cond; pad_data.mutex = &mutex; gst_pad_set_element_private (sinkpad, &pad_data); fail_unless (gst_pad_link (mq_srcpad, sinkpad) == GST_PAD_LINK_OK); gst_pad_set_active (sinkpad, TRUE); gst_object_unref (mq_sinkpad); gst_object_unref (mq_srcpad); } /* Run the test: push events through multiqueue */ gst_element_set_state (pipe, GST_STATE_PLAYING); gst_pad_push_event (inputpad, gst_event_new_stream_start ("test")); caps = gst_caps_new_empty_simple ("foo/x-bar"); gst_pad_push_event (inputpad, gst_event_new_caps (caps)); gst_caps_unref (caps); gst_segment_init (&segment, GST_FORMAT_TIME); gst_pad_push_event (inputpad, gst_event_new_segment (&segment)); g_mutex_lock (&mutex); while (pad_data.event_count < 3) { GST_LOG ("%d events so far, waiting for more", pad_data.event_count); g_cond_wait (&cond, &mutex); } g_mutex_unlock (&mutex); /* Clean up */ { GstPad *mq_input = gst_pad_get_peer (inputpad); gst_pad_unlink (inputpad, mq_input); gst_element_release_request_pad (mq, mq_input); gst_object_unref (mq_input); gst_object_unref (inputpad); gst_object_unref (sinkpad); } gst_element_set_state (pipe, GST_STATE_NULL); gst_object_unref (pipe); g_cond_clear (&cond); g_mutex_clear (&mutex); } GST_END_TEST; static Suite * multiqueue_suite (void) { Suite *s = suite_create ("multiqueue"); TCase *tc_chain = tcase_create ("general"); suite_add_tcase (s, tc_chain); tcase_add_test (tc_chain, test_simple_create_destroy); tcase_add_test (tc_chain, test_simple_pipeline); tcase_add_test (tc_chain, test_simple_shutdown_while_running); tcase_add_test (tc_chain, test_request_pads); tcase_add_test (tc_chain, test_request_pads_named); /* Disabled, The test (and not multiqueue itself) is racy. * See https://bugzilla.gnome.org/show_bug.cgi?id=708661 */ tcase_skip_broken_test (tc_chain, test_output_order); tcase_add_test (tc_chain, test_not_linked_eos); tcase_add_test (tc_chain, test_sparse_stream); tcase_add_test (tc_chain, test_initial_fill_above_high_threshold); tcase_add_test (tc_chain, test_high_threshold_change); tcase_add_test (tc_chain, test_low_threshold_change); tcase_add_test (tc_chain, test_limit_changes); tcase_add_test (tc_chain, test_buffering_with_none_pts); tcase_add_test (tc_chain, test_initial_events_nodelay); return s; } GST_CHECK_MAIN (multiqueue)