/* GstHarness - A test-harness for GStreamer testing * * Copyright (C) 2012-2015 Pexip * * 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., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ /** * SECTION:gstharness * @short_description: A test-harness for writing GStreamer unit tests * @see_also: #GstTestClock,\ * * #GstHarness is meant to make writing unit test for GStreamer much easier. * It can be thought of as a way of treating a #GstElement as a black box, * deterministically feeding it data, and controlling what data it outputs. * * The basic structure of #GstHarness is two "floating" #GstPads that connect * to the harnessed #GstElement src and sink #GstPads like so: * * * __________________________ * _____ | _____ _____ | _____ * | | | | | | | | | | * | src |--+-| sink| Element | src |-+--| sink| * |_____| | |_____| |_____| | |_____| * |__________________________| * * * * With this, you can now simulate any environment the #GstElement might find * itself in. By specifying the #GstCaps of the harness #GstPads, using * functions like gst_harness_set_src_caps() or gst_harness_set_sink_caps_str(), * you can test how the #GstElement interacts with different caps sets. * * Your harnessed #GstElement can of course also be a bin, and using * gst_harness_new_parse() supporting standard gst-launch syntax, you can * easily test a whole pipeline instead of just one element. * * You can then go on to push #GstBuffers and #GstEvents on to the srcpad, * using functions like gst_harness_push() and gst_harness_push_event(), and * then pull them out to examine them with gst_harness_pull() and * gst_harness_pull_event(). * * * A simple buffer-in buffer-out example * * #include <gst/gst.h> * #include <gst/check/gstharness.h> * GstHarness *h; * GstBuffer *in_buf; * GstBuffer *out_buf; * * // attach the harness to the src and sink pad of GstQueue * h = gst_harness_new ("queue"); * * // we must specify a caps before pushing buffers * gst_harness_set_src_caps_str (h, "mycaps"); * * // create a buffer of size 42 * in_buf = gst_harness_create_buffer (h, 42); * * // push the buffer into the queue * gst_harness_push (h, in_buf); * * // pull the buffer from the queue * out_buf = gst_harness_pull (h); * * // validate the buffer in is the same as buffer out * fail_unless (in_buf == out_buf); * * // cleanup * gst_buffer_unref (out_buf); * gst_harness_teardown (h); * * * * * Another main feature of the #GstHarness is its integration with the * #GstTestClock. Operating the #GstTestClock can be very challenging, but * #GstHarness simplifies some of the most desired actions a lot, like wanting * to manually advance the clock while at the same time releasing a #GstClockID * that is waiting, with functions like gst_harness_crank_single_clock_wait(). * * #GstHarness also supports sub-harnesses, as a way of generating and * validating data. A sub-harness is another #GstHarness that is managed by * the "parent" harness, and can either be created by using the standard * gst_harness_new type functions directly on the (GstHarness *)->src_harness, * or using the much more convenient gst_harness_add_src() or * gst_harness_add_sink_parse(). If you have a decoder-element you want to test, * (like vp8dec) it can be very useful to add a src-harness with both a * src-element (videotestsrc) and an encoder (vp8enc) to feed the decoder data * with different configurations, by simply doing: * * * * GstHarness * h = gst_harness_new (h, "vp8dec"); * gst_harness_add_src_parse (h, "videotestsrc is-live=1 ! vp8enc", TRUE); * * * * and then feeding it data with: * * * * gst_harness_push_from_src (h); * * * */ #ifdef HAVE_CONFIG_H #include "config.h" #endif /* we have code with side effects in asserts, so make sure they are active */ #ifdef G_DISABLE_ASSERT #error "GstHarness must be compiled with G_DISABLE_ASSERT undefined" #endif #include "gstharness.h" #include #include #include static void gst_harness_stress_free (GstHarnessThread * t); #define HARNESS_KEY "harness" #define HARNESS_REF "harness-ref" #define HARNESS_LOCK(h) g_mutex_lock (&(h)->priv->priv_mutex) #define HARNESS_UNLOCK(h) g_mutex_unlock (&(h)->priv->priv_mutex) static GstStaticPadTemplate hsrctemplate = GST_STATIC_PAD_TEMPLATE ("src", GST_PAD_SRC, GST_PAD_ALWAYS, GST_STATIC_CAPS_ANY); static GstStaticPadTemplate hsinktemplate = GST_STATIC_PAD_TEMPLATE ("sink", GST_PAD_SINK, GST_PAD_ALWAYS, GST_STATIC_CAPS_ANY); struct _GstHarnessPrivate { gchar *element_sinkpad_name; gchar *element_srcpad_name; GstCaps *src_caps; GstCaps *sink_caps; gboolean forwarding; GstPad *sink_forward_pad; GstTestClock *testclock; volatile gint recv_buffers; volatile gint recv_events; volatile gint recv_upstream_events; GAsyncQueue *buffer_queue; GAsyncQueue *src_event_queue; GAsyncQueue *sink_event_queue; GstClockTime latency_min; GstClockTime latency_max; gboolean has_clock_wait; gboolean drop_buffers; GstClockTime last_push_ts; GstBufferPool *pool; GstAllocator *allocator; GstAllocationParams allocation_params; GstAllocator *propose_allocator; GstAllocationParams propose_allocation_params; gboolean blocking_push_mode; GCond blocking_push_cond; GMutex blocking_push_mutex; GMutex priv_mutex; GPtrArray *stress; }; static GstFlowReturn gst_harness_chain (GstPad * pad, GstObject * parent, GstBuffer * buffer) { GstHarness *h = g_object_get_data (G_OBJECT (pad), HARNESS_KEY); GstHarnessPrivate *priv = h->priv; (void) parent; g_assert (h != NULL); g_mutex_lock (&priv->blocking_push_mutex); g_atomic_int_inc (&priv->recv_buffers); if (priv->drop_buffers) gst_buffer_unref (buffer); else g_async_queue_push (priv->buffer_queue, buffer); if (priv->blocking_push_mode) { g_cond_wait (&priv->blocking_push_cond, &priv->blocking_push_mutex); } g_mutex_unlock (&priv->blocking_push_mutex); return GST_FLOW_OK; } static gboolean gst_harness_src_event (GstPad * pad, GstObject * parent, GstEvent * event) { GstHarness *h = g_object_get_data (G_OBJECT (pad), HARNESS_KEY); GstHarnessPrivate *priv = h->priv; (void) parent; g_assert (h != NULL); g_atomic_int_inc (&priv->recv_upstream_events); g_async_queue_push (priv->src_event_queue, event); return TRUE; } static gboolean gst_harness_sink_event (GstPad * pad, GstObject * parent, GstEvent * event) { GstHarness *h = g_object_get_data (G_OBJECT (pad), HARNESS_KEY); GstHarnessPrivate *priv = h->priv; gboolean ret = TRUE; gboolean forward; g_assert (h != NULL); (void) parent; g_atomic_int_inc (&priv->recv_events); switch (GST_EVENT_TYPE (event)) { case GST_EVENT_STREAM_START: case GST_EVENT_CAPS: case GST_EVENT_SEGMENT: forward = TRUE; break; default: forward = FALSE; break; } HARNESS_LOCK (h); if (priv->forwarding && forward && priv->sink_forward_pad) { GstPad *fwdpad = gst_object_ref (priv->sink_forward_pad); HARNESS_UNLOCK (h); ret = gst_pad_push_event (fwdpad, event); gst_object_unref (fwdpad); HARNESS_LOCK (h); } else { g_async_queue_push (priv->sink_event_queue, event); } HARNESS_UNLOCK (h); return ret; } static void gst_harness_decide_allocation (GstHarness * h, GstCaps * caps) { GstHarnessPrivate *priv = h->priv; GstQuery *query; GstAllocator *allocator; GstAllocationParams params; GstBufferPool *pool = NULL; guint size, min, max; query = gst_query_new_allocation (caps, FALSE); gst_pad_peer_query (h->srcpad, query); if (gst_query_get_n_allocation_params (query) > 0) { gst_query_parse_nth_allocation_param (query, 0, &allocator, ¶ms); } else { allocator = NULL; gst_allocation_params_init (¶ms); } if (gst_query_get_n_allocation_pools (query) > 0) { gst_query_parse_nth_allocation_pool (query, 0, &pool, &size, &min, &max); #if 0 /* Most elements create their own pools if pool == NULL. Not sure if we * want to do that in the harness since we may want to test the pool * implementation of the elements. Not creating a pool will however ignore * the returned size. */ if (pool == NULL) pool = gst_buffer_pool_new (); #endif } else { pool = NULL; size = min = max = 0; } gst_query_unref (query); if (pool) { GstStructure *config = gst_buffer_pool_get_config (pool); gst_buffer_pool_config_set_params (config, caps, size, min, max); gst_buffer_pool_config_set_allocator (config, allocator, ¶ms); gst_buffer_pool_set_config (pool, config); } if (pool != priv->pool) { if (priv->pool != NULL) gst_buffer_pool_set_active (priv->pool, FALSE); if (pool) gst_buffer_pool_set_active (pool, TRUE); } priv->allocation_params = params; if (priv->allocator) gst_object_unref (priv->allocator); priv->allocator = allocator; if (priv->pool) gst_object_unref (priv->pool); priv->pool = pool; } static void gst_harness_negotiate (GstHarness * h) { GstCaps *caps; caps = gst_pad_get_current_caps (h->srcpad); if (caps != NULL) { gst_harness_decide_allocation (h, caps); gst_caps_unref (caps); } else { GST_FIXME_OBJECT (h, "Cannot negotiate allocation because caps is not set"); } } static gboolean gst_harness_sink_query (GstPad * pad, GstObject * parent, GstQuery * query) { GstHarness *h = g_object_get_data (G_OBJECT (pad), HARNESS_KEY); GstHarnessPrivate *priv = h->priv; gboolean res = TRUE; g_assert (h != NULL); // FIXME: forward all queries? switch (GST_QUERY_TYPE (query)) { case GST_QUERY_LATENCY: gst_query_set_latency (query, TRUE, priv->latency_min, priv->latency_max); break; case GST_QUERY_CAPS: { GstCaps *caps, *filter = NULL; if (priv->sink_caps) { caps = gst_caps_ref (priv->sink_caps); } else { caps = gst_pad_get_pad_template_caps (pad); } gst_query_parse_caps (query, &filter); if (filter != NULL) { gst_caps_take (&caps, gst_caps_intersect_full (filter, caps, GST_CAPS_INTERSECT_FIRST)); } gst_query_set_caps_result (query, caps); gst_caps_unref (caps); } break; case GST_QUERY_ALLOCATION: { HARNESS_LOCK (h); if (priv->forwarding && priv->sink_forward_pad != NULL) { GstPad *peer = gst_pad_get_peer (priv->sink_forward_pad); g_assert (peer != NULL); HARNESS_UNLOCK (h); res = gst_pad_query (peer, query); gst_object_unref (peer); HARNESS_LOCK (h); } else { GstCaps *caps; gboolean need_pool; guint size; gst_query_parse_allocation (query, &caps, &need_pool); /* FIXME: Can this be removed? */ size = gst_query_get_n_allocation_params (query); g_assert_cmpuint (0, ==, size); gst_query_add_allocation_param (query, priv->propose_allocator, &priv->propose_allocation_params); GST_DEBUG_OBJECT (pad, "proposing allocation %" GST_PTR_FORMAT, priv->propose_allocator); } HARNESS_UNLOCK (h); break; } default: res = gst_pad_query_default (pad, parent, query); } return res; } static gboolean gst_harness_src_query (GstPad * pad, GstObject * parent, GstQuery * query) { GstHarness *h = g_object_get_data (G_OBJECT (pad), HARNESS_KEY); GstHarnessPrivate *priv = h->priv; gboolean res = TRUE; g_assert (h != NULL); switch (GST_QUERY_TYPE (query)) { case GST_QUERY_LATENCY: gst_query_set_latency (query, TRUE, priv->latency_min, priv->latency_max); break; case GST_QUERY_CAPS: { GstCaps *caps, *filter = NULL; if (priv->src_caps) { caps = gst_caps_ref (priv->src_caps); } else { caps = gst_pad_get_pad_template_caps (pad); } gst_query_parse_caps (query, &filter); if (filter != NULL) { gst_caps_take (&caps, gst_caps_intersect_full (filter, caps, GST_CAPS_INTERSECT_FIRST)); } gst_query_set_caps_result (query, caps); gst_caps_unref (caps); } break; default: res = gst_pad_query_default (pad, parent, query); } return res; } static void gst_harness_element_ref (GstHarness * h) { guint *data; GST_OBJECT_LOCK (h->element); data = g_object_get_data (G_OBJECT (h->element), HARNESS_REF); if (data == NULL) { data = g_new0 (guint, 1); *data = 1; g_object_set_data_full (G_OBJECT (h->element), HARNESS_REF, data, g_free); } else { (*data)++; } GST_OBJECT_UNLOCK (h->element); } static guint gst_harness_element_unref (GstHarness * h) { guint *data; guint ret; GST_OBJECT_LOCK (h->element); data = g_object_get_data (G_OBJECT (h->element), HARNESS_REF); g_assert (data != NULL); (*data)--; ret = *data; GST_OBJECT_UNLOCK (h->element); return ret; } static void gst_harness_link_element_srcpad (GstHarness * h, const gchar * element_srcpad_name) { GstHarnessPrivate *priv = h->priv; GstPad *srcpad = gst_element_get_static_pad (h->element, element_srcpad_name); GstPadLinkReturn link; if (srcpad == NULL) srcpad = gst_element_get_request_pad (h->element, element_srcpad_name); g_assert (srcpad); link = gst_pad_link (srcpad, h->sinkpad); g_assert_cmpint (link, ==, GST_PAD_LINK_OK); g_free (priv->element_srcpad_name); priv->element_srcpad_name = gst_pad_get_name (srcpad); gst_object_unref (srcpad); } static void gst_harness_link_element_sinkpad (GstHarness * h, const gchar * element_sinkpad_name) { GstHarnessPrivate *priv = h->priv; GstPad *sinkpad = gst_element_get_static_pad (h->element, element_sinkpad_name); GstPadLinkReturn link; if (sinkpad == NULL) sinkpad = gst_element_get_request_pad (h->element, element_sinkpad_name); g_assert (sinkpad); link = gst_pad_link (h->srcpad, sinkpad); g_assert_cmpint (link, ==, GST_PAD_LINK_OK); g_free (priv->element_sinkpad_name); priv->element_sinkpad_name = gst_pad_get_name (sinkpad); gst_object_unref (sinkpad); } static void gst_harness_setup_src_pad (GstHarness * h, GstStaticPadTemplate * src_tmpl, const gchar * element_sinkpad_name) { GstHarnessPrivate *priv = h->priv; g_assert (src_tmpl); g_assert (h->srcpad == NULL); priv->src_event_queue = g_async_queue_new_full ((GDestroyNotify) gst_event_unref); /* sending pad */ h->srcpad = gst_pad_new_from_static_template (src_tmpl, "src"); g_assert (h->srcpad); g_object_set_data (G_OBJECT (h->srcpad), HARNESS_KEY, h); gst_pad_set_query_function (h->srcpad, gst_harness_src_query); gst_pad_set_event_function (h->srcpad, gst_harness_src_event); gst_pad_set_active (h->srcpad, TRUE); if (element_sinkpad_name) gst_harness_link_element_sinkpad (h, element_sinkpad_name); } static void gst_harness_setup_sink_pad (GstHarness * h, GstStaticPadTemplate * sink_tmpl, const gchar * element_srcpad_name) { GstHarnessPrivate *priv = h->priv; g_assert (sink_tmpl); g_assert (h->sinkpad == NULL); priv->buffer_queue = g_async_queue_new_full ( (GDestroyNotify) gst_buffer_unref); priv->sink_event_queue = g_async_queue_new_full ( (GDestroyNotify) gst_event_unref); /* receiving pad */ h->sinkpad = gst_pad_new_from_static_template (sink_tmpl, "sink"); g_assert (h->sinkpad); g_object_set_data (G_OBJECT (h->sinkpad), HARNESS_KEY, h); gst_pad_set_chain_function (h->sinkpad, gst_harness_chain); gst_pad_set_query_function (h->sinkpad, gst_harness_sink_query); gst_pad_set_event_function (h->sinkpad, gst_harness_sink_event); gst_pad_set_active (h->sinkpad, TRUE); if (element_srcpad_name) gst_harness_link_element_srcpad (h, element_srcpad_name); } static void check_element_type (GstElement * element, gboolean * has_sinkpad, gboolean * has_srcpad) { GstElementClass *element_class = GST_ELEMENT_GET_CLASS (element); const GList *tmpl_list; *has_srcpad = element->numsrcpads > 0; *has_sinkpad = element->numsinkpads > 0; tmpl_list = gst_element_class_get_pad_template_list (element_class); while (tmpl_list) { GstPadTemplate *pad_tmpl = (GstPadTemplate *) tmpl_list->data; tmpl_list = g_list_next (tmpl_list); if (GST_PAD_TEMPLATE_DIRECTION (pad_tmpl) == GST_PAD_SRC) *has_srcpad |= TRUE; if (GST_PAD_TEMPLATE_DIRECTION (pad_tmpl) == GST_PAD_SINK) *has_sinkpad |= TRUE; } } static void turn_async_and_sync_off (GstElement * element) { GObjectClass *class = G_OBJECT_GET_CLASS (element); if (g_object_class_find_property (class, "async")) g_object_set (element, "async", FALSE, NULL); if (g_object_class_find_property (class, "sync")) g_object_set (element, "sync", FALSE, NULL); } static gboolean gst_pad_is_request_pad (GstPad * pad) { GstPadTemplate *temp; gboolean is_request; if (pad == NULL) return FALSE; temp = gst_pad_get_pad_template (pad); if (temp == NULL) return FALSE; is_request = GST_PAD_TEMPLATE_PRESENCE (temp) == GST_PAD_REQUEST; gst_object_unref (temp); return is_request; } /** * gst_harness_new_empty: (skip) * * Creates a new empty harness. Use gst_harness_add_element_full() to add * an #GstElement to it. * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.8 */ GstHarness * gst_harness_new_empty (void) { GstHarness *h; GstHarnessPrivate *priv; h = g_new0 (GstHarness, 1); g_assert (h != NULL); h->priv = g_new0 (GstHarnessPrivate, 1); priv = h->priv; GST_DEBUG_OBJECT (h, "about to create new harness %p", h); priv->last_push_ts = GST_CLOCK_TIME_NONE; priv->latency_min = 0; priv->latency_max = GST_CLOCK_TIME_NONE; priv->drop_buffers = FALSE; priv->testclock = GST_TEST_CLOCK_CAST (gst_test_clock_new ()); priv->propose_allocator = NULL; gst_allocation_params_init (&priv->propose_allocation_params); g_mutex_init (&priv->blocking_push_mutex); g_cond_init (&priv->blocking_push_cond); g_mutex_init (&priv->priv_mutex); priv->stress = g_ptr_array_new_with_free_func ( (GDestroyNotify) gst_harness_stress_free); /* we have forwarding on as a default */ gst_harness_set_forwarding (h, TRUE); return h; } /** * gst_harness_add_element_full: (skip) * @h: a #GstHarness * @element: a #GstElement to add to the harness (transfer none) * @hsrc: (allow-none): a #GstStaticPadTemplate describing the harness srcpad. * %NULL will not create a harness srcpad. * @element_sinkpad_name: (allow-none): a #gchar with the name of the element * sinkpad that is then linked to the harness srcpad. Can be a static or request * or a sometimes pad that has been added. %NULL will not get/request a sinkpad * from the element. (Like if the element is a src.) * @hsink: (allow-none): a #GstStaticPadTemplate describing the harness sinkpad. * %NULL will not create a harness sinkpad. * @element_srcpad_name: (allow-none): a #gchar with the name of the element * srcpad that is then linked to the harness sinkpad, similar to the * @element_sinkpad_name. * * Adds a #GstElement to an empty #GstHarness * * MT safe. * * Since: 1.6 */ void gst_harness_add_element_full (GstHarness * h, GstElement * element, GstStaticPadTemplate * hsrc, const gchar * element_sinkpad_name, GstStaticPadTemplate * hsink, const gchar * element_srcpad_name) { GstClock * element_clock; gboolean has_sinkpad, has_srcpad; g_return_if_fail (element != NULL); g_return_if_fail (h->element == NULL); element_clock = GST_ELEMENT_CLOCK (element); h->element = gst_object_ref (element); check_element_type (element, &has_sinkpad, &has_srcpad); /* setup the loose srcpad linked to the element sinkpad */ if (has_sinkpad) gst_harness_setup_src_pad (h, hsrc, element_sinkpad_name); /* setup the loose sinkpad linked to the element srcpad */ if (has_srcpad) gst_harness_setup_sink_pad (h, hsink, element_srcpad_name); /* as a harness sink, we should not need sync and async */ if (has_sinkpad && !has_srcpad) turn_async_and_sync_off (h->element); if (h->srcpad != NULL) { gboolean handled; gchar *stream_id = g_strdup_printf ("%s-%p", GST_OBJECT_NAME (h->element), h); handled = gst_pad_push_event (h->srcpad, gst_event_new_stream_start (stream_id)); g_assert (handled); g_free (stream_id); } /* if the element already has a testclock attached, we replace our own with it, if no clock we attach the testclock */ if (element_clock) { if (GST_IS_TEST_CLOCK (element_clock)) { gst_object_replace ((GstObject **) & h->priv->testclock, (GstObject *) GST_ELEMENT_CLOCK (element)); } } else { gst_harness_use_testclock (h); } /* don't start sources, they start producing data! */ if (has_sinkpad) gst_harness_play (h); gst_harness_element_ref (h); GST_DEBUG_OBJECT (h, "added element to harness %p " "with element_srcpad_name (%p, %s, %s) and element_sinkpad_name (%p, %s, %s)", h, h->srcpad, GST_DEBUG_PAD_NAME (h->srcpad), h->sinkpad, GST_DEBUG_PAD_NAME (h->sinkpad)); } /** * gst_harness_new_full: (skip) * @element: a #GstElement to attach the harness to (transfer none) * @hsrc: (allow-none): a #GstStaticPadTemplate describing the harness srcpad. * %NULL will not create a harness srcpad. * @element_sinkpad_name: (allow-none): a #gchar with the name of the element * sinkpad that is then linked to the harness srcpad. Can be a static or request * or a sometimes pad that has been added. %NULL will not get/request a sinkpad * from the element. (Like if the element is a src.) * @hsink: (allow-none): a #GstStaticPadTemplate describing the harness sinkpad. * %NULL will not create a harness sinkpad. * @element_srcpad_name: (allow-none): a #gchar with the name of the element * srcpad that is then linked to the harness sinkpad, similar to the * @element_sinkpad_name. * * Creates a new harness. * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.6 */ GstHarness * gst_harness_new_full (GstElement * element, GstStaticPadTemplate * hsrc, const gchar * element_sinkpad_name, GstStaticPadTemplate * hsink, const gchar * element_srcpad_name) { GstHarness *h; h = gst_harness_new_empty (); gst_harness_add_element_full (h, element, hsrc, element_sinkpad_name, hsink, element_srcpad_name); return h; } /** * gst_harness_new_with_element: (skip) * @element: a #GstElement to attach the harness to (transfer none) * @element_sinkpad_name: (allow-none): a #gchar with the name of the element * sinkpad that is then linked to the harness srcpad. %NULL does not attach a * sinkpad * @element_srcpad_name: (allow-none): a #gchar with the name of the element * srcpad that is then linked to the harness sinkpad. %NULL does not attach a * srcpad * * Creates a new harness. Works in the same way as gst_harness_new_full(), only * that generic padtemplates are used for the harness src and sinkpads, which * will be sufficient in most usecases. * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.6 */ GstHarness * gst_harness_new_with_element (GstElement * element, const gchar * element_sinkpad_name, const gchar * element_srcpad_name) { return gst_harness_new_full (element, &hsrctemplate, element_sinkpad_name, &hsinktemplate, element_srcpad_name); } /** * gst_harness_new_with_padnames: (skip) * @element_name: a #gchar describing the #GstElement name * @element_sinkpad_name: (allow-none): a #gchar with the name of the element * sinkpad that is then linked to the harness srcpad. %NULL does not attach a * sinkpad * @element_srcpad_name: (allow-none): a #gchar with the name of the element * srcpad that is then linked to the harness sinkpad. %NULL does not attach a * srcpad * * Creates a new harness. Works like gst_harness_new_with_element(), * except you specify the factoryname of the #GstElement * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.6 */ GstHarness * gst_harness_new_with_padnames (const gchar * element_name, const gchar * element_sinkpad_name, const gchar * element_srcpad_name) { GstHarness *h; GstElement *element = gst_element_factory_make (element_name, NULL); g_assert (element != NULL); h = gst_harness_new_with_element (element, element_sinkpad_name, element_srcpad_name); gst_object_unref (element); return h; } /** * gst_harness_new_with_templates: (skip) * @element_name: a #gchar describing the #GstElement name * @hsrc: (allow-none): a #GstStaticPadTemplate describing the harness srcpad. * %NULL will not create a harness srcpad. * @hsink: (allow-none): a #GstStaticPadTemplate describing the harness sinkpad. * %NULL will not create a harness sinkpad. * * Creates a new harness, like gst_harness_new_full(), except it * assumes the #GstElement sinkpad is named "sink" and srcpad is named "src" * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.6 */ GstHarness * gst_harness_new_with_templates (const gchar * element_name, GstStaticPadTemplate * hsrc, GstStaticPadTemplate * hsink) { GstHarness *h; GstElement *element = gst_element_factory_make (element_name, NULL); g_assert (element != NULL); h = gst_harness_new_full (element, hsrc, "sink", hsink, "src"); gst_object_unref (element); return h; } /** * gst_harness_new: (skip) * @element_name: a #gchar describing the #GstElement name * * Creates a new harness. Works like gst_harness_new_with_padnames(), except it * assumes the #GstElement sinkpad is named "sink" and srcpad is named "src" * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.6 */ GstHarness * gst_harness_new (const gchar * element_name) { return gst_harness_new_with_padnames (element_name, "sink", "src"); } /** * gst_harness_add_parse: (skip) * @h: a #GstHarness * @launchline: a #gchar describing a gst-launch type line * * Parses the @launchline and puts that in a #GstBin, * and then attches the supplied #GstHarness to the bin. * * MT safe. * * Since: 1.6 */ void gst_harness_add_parse (GstHarness * h, const gchar * launchline) { GstBin *bin; gchar *desc; GstPad *pad; GstIterator *iter; gboolean done = FALSE; g_return_if_fail (launchline != NULL); desc = g_strdup_printf ("bin.( %s )", launchline); bin = (GstBin *) gst_parse_launch_full (desc, NULL, GST_PARSE_FLAG_NONE, NULL); g_free (desc); if (G_UNLIKELY (bin == NULL)) return; /* find pads and ghost them if necessary */ if ((pad = gst_bin_find_unlinked_pad (bin, GST_PAD_SRC)) != NULL) { gst_element_add_pad (GST_ELEMENT (bin), gst_ghost_pad_new ("src", pad)); gst_object_unref (pad); } if ((pad = gst_bin_find_unlinked_pad (bin, GST_PAD_SINK)) != NULL) { gst_element_add_pad (GST_ELEMENT (bin), gst_ghost_pad_new ("sink", pad)); gst_object_unref (pad); } iter = gst_bin_iterate_sinks (bin); while (!done) { GValue item = { 0, }; switch (gst_iterator_next (iter, &item)) { case GST_ITERATOR_OK: turn_async_and_sync_off (GST_ELEMENT (g_value_get_object (&item))); g_value_reset (&item); break; case GST_ITERATOR_DONE: done = TRUE; break; case GST_ITERATOR_RESYNC: gst_iterator_resync (iter); break; case GST_ITERATOR_ERROR: gst_object_unref (bin); gst_iterator_free (iter); g_return_if_reached (); break; } } gst_iterator_free (iter); gst_harness_add_element_full (h, GST_ELEMENT_CAST (bin), &hsrctemplate, "sink", &hsinktemplate, "src"); gst_object_unref (bin); } /** * gst_harness_new_parse: (skip) * @launchline: a #gchar describing a gst-launch type line * * Creates a new harness, parsing the @launchline and putting that in a #GstBin, * and then attches the harness to the bin. * * MT safe. * * Returns: (transfer full): a #GstHarness, or %NULL if the harness could * not be created * * Since: 1.6 */ GstHarness * gst_harness_new_parse (const gchar * launchline) { GstHarness *h; h = gst_harness_new_empty (); gst_harness_add_parse (h, launchline); return h; } /** * gst_harness_teardown: * @h: a #GstHarness * * Tears down a @GstHarness, freeing all resources allocated using it. * * MT safe. * * Since: 1.6 */ void gst_harness_teardown (GstHarness * h) { GstHarnessPrivate *priv = h->priv; if (priv->blocking_push_mode) { g_mutex_lock (&priv->blocking_push_mutex); priv->blocking_push_mode = FALSE; g_cond_signal (&priv->blocking_push_cond); g_mutex_unlock (&priv->blocking_push_mutex); } if (h->src_harness) { gst_harness_teardown (h->src_harness); } gst_object_replace ((GstObject **) & priv->sink_forward_pad, NULL); if (h->sink_harness) { gst_harness_teardown (h->sink_harness); } if (priv->src_caps) gst_caps_unref (priv->src_caps); if (priv->sink_caps) gst_caps_unref (priv->sink_caps); if (h->srcpad) { if (gst_pad_is_request_pad (GST_PAD_PEER (h->srcpad))) gst_element_release_request_pad (h->element, GST_PAD_PEER (h->srcpad)); g_free (priv->element_sinkpad_name); gst_pad_set_active (h->srcpad, FALSE); gst_object_unref (h->srcpad); g_async_queue_unref (priv->src_event_queue); } if (h->sinkpad) { if (gst_pad_is_request_pad (GST_PAD_PEER (h->sinkpad))) gst_element_release_request_pad (h->element, GST_PAD_PEER (h->sinkpad)); g_free (priv->element_srcpad_name); gst_pad_set_active (h->sinkpad, FALSE); gst_object_unref (h->sinkpad); g_async_queue_unref (priv->buffer_queue); g_async_queue_unref (priv->sink_event_queue); } gst_object_replace ((GstObject **) & priv->propose_allocator, NULL); gst_object_replace ((GstObject **) & priv->allocator, NULL); gst_object_replace ((GstObject **) & priv->pool, NULL); /* if we hold the last ref, set to NULL */ if (gst_harness_element_unref (h) == 0) { gboolean state_change; GstState state, pending; state_change = gst_element_set_state (h->element, GST_STATE_NULL); g_assert (state_change == GST_STATE_CHANGE_SUCCESS); state_change = gst_element_get_state (h->element, &state, &pending, 0); g_assert (state_change == GST_STATE_CHANGE_SUCCESS); g_assert (state == GST_STATE_NULL); } g_cond_clear (&priv->blocking_push_cond); g_mutex_clear (&priv->blocking_push_mutex); g_mutex_clear (&priv->priv_mutex); g_ptr_array_unref (priv->stress); gst_object_unref (h->element); gst_object_replace ((GstObject **) & priv->testclock, NULL); g_free (h->priv); g_free (h); } /** * gst_harness_add_element_src_pad: * @h: a #GstHarness * @srcpad: a #GstPad to link to the harness sinkpad * * Links the specifed #GstPad the @GstHarness sinkpad. This can be useful if * perhaps the srcpad did not exist at the time of creating the harness, * like a demuxer that provides a sometimes-pad after receiving data. * * MT safe. * * Since: 1.6 */ void gst_harness_add_element_src_pad (GstHarness * h, GstPad * srcpad) { GstHarnessPrivate *priv = h->priv; GstPadLinkReturn link; if (h->sinkpad == NULL) gst_harness_setup_sink_pad (h, &hsinktemplate, NULL); link = gst_pad_link (srcpad, h->sinkpad); g_assert_cmpint (link, ==, GST_PAD_LINK_OK); g_free (priv->element_srcpad_name); priv->element_srcpad_name = gst_pad_get_name (srcpad); } /** * gst_harness_add_element_sink_pad: * @h: a #GstHarness * @sinkpad: a #GstPad to link to the harness srcpad * * Links the specifed #GstPad the @GstHarness srcpad. * * MT safe. * * Since: 1.6 */ void gst_harness_add_element_sink_pad (GstHarness * h, GstPad * sinkpad) { GstHarnessPrivate *priv = h->priv; GstPadLinkReturn link; if (h->srcpad == NULL) gst_harness_setup_src_pad (h, &hsrctemplate, NULL); link = gst_pad_link (h->srcpad, sinkpad); g_assert_cmpint (link, ==, GST_PAD_LINK_OK); g_free (priv->element_sinkpad_name); priv->element_sinkpad_name = gst_pad_get_name (sinkpad); } /** * gst_harness_set_src_caps: * @h: a #GstHarness * @caps: (transfer full): a #GstCaps to set on the harness srcpad * * Sets the @GstHarness srcpad caps. This must be done before any buffers * can legally be pushed from the harness to the element. * * MT safe. * * Since: 1.6 */ void gst_harness_set_src_caps (GstHarness * h, GstCaps * caps) { GstHarnessPrivate *priv = h->priv; GstSegment segment; gboolean handled; handled = gst_pad_push_event (h->srcpad, gst_event_new_caps (caps)); g_assert (handled); gst_caps_take (&priv->src_caps, caps); gst_segment_init (&segment, GST_FORMAT_TIME); handled = gst_pad_push_event (h->srcpad, gst_event_new_segment (&segment)); } /** * gst_harness_set_sink_caps: * @h: a #GstHarness * @caps: (transfer full): a #GstCaps to set on the harness sinkpad * * Sets the @GstHarness sinkpad caps. * * MT safe. * * Since: 1.6 */ void gst_harness_set_sink_caps (GstHarness * h, GstCaps * caps) { GstHarnessPrivate *priv = h->priv; gst_caps_take (&priv->sink_caps, caps); gst_pad_push_event (h->sinkpad, gst_event_new_reconfigure ()); } /** * gst_harness_set_caps: * @h: a #GstHarness * @in: (transfer full): a #GstCaps to set on the harness srcpad * @out: (transfer full): a #GstCaps to set on the harness sinkpad * * Sets the @GstHarness srcpad and sinkpad caps. * * MT safe. * * Since: 1.6 */ void gst_harness_set_caps (GstHarness * h, GstCaps * in, GstCaps * out) { gst_harness_set_sink_caps (h, out); gst_harness_set_src_caps (h, in); } /** * gst_harness_set_src_caps_str: * @h: a #GstHarness * @str: a @gchar describing a #GstCaps to set on the harness srcpad * * Sets the @GstHarness srcpad caps using a string. This must be done before * any buffers can legally be pushed from the harness to the element. * * MT safe. * * Since: 1.6 */ void gst_harness_set_src_caps_str (GstHarness * h, const gchar * str) { gst_harness_set_src_caps (h, gst_caps_from_string (str)); } /** * gst_harness_set_sink_caps_str: * @h: a #GstHarness * @str: a @gchar describing a #GstCaps to set on the harness sinkpad * * Sets the @GstHarness sinkpad caps using a string. * * MT safe. * * Since: 1.6 */ void gst_harness_set_sink_caps_str (GstHarness * h, const gchar * str) { gst_harness_set_sink_caps (h, gst_caps_from_string (str)); } /** * gst_harness_set_caps_str: * @h: a #GstHarness * @in: a @gchar describing a #GstCaps to set on the harness srcpad * @out: a @gchar describing a #GstCaps to set on the harness sinkpad * * Sets the @GstHarness srcpad and sinkpad caps using strings. * * MT safe. * * Since: 1.6 */ void gst_harness_set_caps_str (GstHarness * h, const gchar * in, const gchar * out) { gst_harness_set_sink_caps_str (h, out); gst_harness_set_src_caps_str (h, in); } /** * gst_harness_use_systemclock: * @h: a #GstHarness * * Sets the system #GstClock on the @GstHarness #GstElement * * MT safe. * * Since: 1.6 */ void gst_harness_use_systemclock (GstHarness * h) { GstClock *clock = gst_system_clock_obtain (); g_assert (clock != NULL); gst_element_set_clock (h->element, clock); gst_object_unref (clock); } /** * gst_harness_use_testclock: * @h: a #GstHarness * * Sets the #GstTestClock on the #GstHarness #GstElement * * MT safe. * * Since: 1.6 */ void gst_harness_use_testclock (GstHarness * h) { gst_element_set_clock (h->element, GST_CLOCK_CAST (h->priv->testclock)); } /** * gst_harness_get_testclock: * @h: a #GstHarness * * Get the #GstTestClock. Useful if specific operations on the testclock is * needed. * * MT safe. * * Returns: (transfer full): a #GstTestClock, or %NULL if the testclock is not * present. * * Since: 1.6 */ GstTestClock * gst_harness_get_testclock (GstHarness * h) { return gst_object_ref (h->priv->testclock); } /** * gst_harness_set_time: * @h: a #GstHarness * @time: a #GstClockTime to advance the clock to * * Advance the #GstTestClock to a specific time. * * MT safe. * * Returns: a @gboolean %TRUE if the time could be set. %FALSE if not. * * Since: 1.6 */ gboolean gst_harness_set_time (GstHarness * h, GstClockTime time) { gst_test_clock_set_time (h->priv->testclock, time); return TRUE; } /** * gst_harness_wait_for_clock_id_waits: * @h: a #GstHarness * @waits: a #guint describing the numbers of #GstClockID registered with * the #GstTestClock * @timeout: a #guint describing how many seconds to wait for @waits to be true * * Waits for @timeout seconds until @waits number of #GstClockID waits is * registered with the #GstTestClock. Useful for writing deterministic tests, * where you want to make sure that an expected number of waits have been * reached. * * MT safe. * * Returns: a @gboolean %TRUE if the waits have been registered, %FALSE if not. * (Could be that it timed out waiting or that more waits then waits was found) * * Since: 1.6 */ gboolean gst_harness_wait_for_clock_id_waits (GstHarness * h, guint waits, guint timeout) { GstTestClock *testclock = h->priv->testclock; gint64 start_time; gboolean ret; start_time = g_get_monotonic_time (); while (gst_test_clock_peek_id_count (testclock) < waits) { gint64 time_spent; g_usleep (G_USEC_PER_SEC / 1000); time_spent = g_get_monotonic_time () - start_time; if ((time_spent / G_USEC_PER_SEC) > timeout) break; } ret = (waits == gst_test_clock_peek_id_count (testclock)); return ret; } /** * gst_harness_crank_single_clock_wait: * @h: a #GstHarness * * A "crank" consists of three steps: * 1: Wait for a #GstClockID to be registered with the #GstTestClock. * 2: Advance the #GstTestClock to the time the #GstClockID is waiting for. * 3: Release the #GstClockID wait. * Together, this provides an easy way to not have to think about the details * around clocks and time, but still being able to write deterministic tests * that are dependant on this. A "crank" can be though of as the notion of * manually driving the clock forward to its next logical step. * * MT safe. * * Returns: a @gboolean %TRUE if the "crank" was successful, %FALSE if not. * * Since: 1.6 */ gboolean gst_harness_crank_single_clock_wait (GstHarness * h) { return gst_test_clock_crank (h->priv->testclock); } /** * gst_harness_crank_multiple_clock_waits: * @h: a #GstHarness * @waits: a #guint describing the number of #GstClockIDs to crank * * Similar to gst_harness_crank_single_clock_wait(), this is the function to use * if your harnessed element(s) are using more then one gst_clock_id_wait. * Failing to do so can (and will) make it racy which #GstClockID you actually * are releasing, where as this function will process all the waits at the * same time, ensuring that one thread can't register another wait before * both are released. * * MT safe. * * Returns: a @gboolean %TRUE if the "crank" was successful, %FALSE if not. * * Since: 1.6 */ gboolean gst_harness_crank_multiple_clock_waits (GstHarness * h, guint waits) { GstTestClock *testclock = h->priv->testclock; GList *pending; guint processed; gst_test_clock_wait_for_multiple_pending_ids (testclock, waits, &pending); gst_harness_set_time (h, gst_test_clock_id_list_get_latest_time (pending)); processed = gst_test_clock_process_id_list (testclock, pending); g_list_free_full (pending, gst_clock_id_unref); return processed == waits; } /** * gst_harness_play: * @h: a #GstHarness * * This will set the harnessed #GstElement to %GST_STATE_PLAYING. * #GstElements without a sink-#GstPad and with the %GST_ELEMENT_FLAG_SOURCE * flag set is concidered a src #GstElement * Non-src #GstElements (like sinks and filters) are automatically set to * playing by the #GstHarness, but src #GstElements are not to avoid them * starting to produce buffers. * Hence, for src #GstElement you must call gst_harness_play() explicitly. * * MT safe. * * Since: 1.6 */ void gst_harness_play (GstHarness * h) { GstState state, pending; gboolean state_change; state_change = gst_element_set_state (h->element, GST_STATE_PLAYING); g_assert_cmpint (GST_STATE_CHANGE_SUCCESS, ==, state_change); state_change = gst_element_get_state (h->element, &state, &pending, 0); g_assert_cmpint (GST_STATE_CHANGE_SUCCESS, ==, state_change); g_assert_cmpint (GST_STATE_PLAYING, ==, state); } /** * gst_harness_set_blocking_push_mode: * @h: a #GstHarness * * Setting this will make the harness block in the chain-function, and * then release when gst_harness_pull() or gst_harness_try_pull() is called. * Can be useful when wanting to control a src-element that is not implementing * gst_clock_id_wait() so it can't be controlled by the #GstTestClock, since * it otherwise would produce buffers as fast as possible. * * MT safe. * * Since: 1.6 */ void gst_harness_set_blocking_push_mode (GstHarness * h) { GstHarnessPrivate *priv = h->priv; priv->blocking_push_mode = TRUE; } /** * gst_harness_set_forwarding: * @h: a #GstHarness * @forwarding: a #gboolean to enable/disable forwarding * * As a convenience, a src-harness will forward %GST_EVENT_STREAM_START, * %GST_EVENT_CAPS and %GST_EVENT_SEGMENT to the main-harness if forwarding * is enabled, and forward any sticky-events from the main-harness to * the sink-harness. It will also forward the %GST_QUERY_ALLOCATION. * * If forwarding is disabled, the user will have to either manually push * these events from the src-harness using gst_harness_src_push_event(), or * create and push them manually. While this will allow full control and * inspection of these events, for the most cases having forwarding enabled * will be sufficient when writing a test where the src-harness' main function * is providing data for the main-harness. * * Forwarding is enabled by default. * * MT safe. * * Since: 1.6 */ void gst_harness_set_forwarding (GstHarness * h, gboolean forwarding) { GstHarnessPrivate *priv = h->priv; priv->forwarding = forwarding; if (h->src_harness) gst_harness_set_forwarding (h->src_harness, forwarding); if (h->sink_harness) gst_harness_set_forwarding (h->sink_harness, forwarding); } static void gst_harness_set_forward_pad (GstHarness * h, GstPad * fwdpad) { HARNESS_LOCK (h); gst_object_replace ((GstObject **) & h->priv->sink_forward_pad, (GstObject *) fwdpad); HARNESS_UNLOCK (h); } /** * gst_harness_create_buffer: * @h: a #GstHarness * @size: a #gsize specifying the size of the buffer * * Allocates a buffer using a #GstBufferPool if present, or else using the * configured #GstAllocator and #GstAllocationParams * * MT safe. * * Returns: a #GstBuffer of size @size * * Since: 1.6 */ GstBuffer * gst_harness_create_buffer (GstHarness * h, gsize size) { GstHarnessPrivate *priv = h->priv; GstBuffer *ret = NULL; GstFlowReturn flow; if (gst_pad_check_reconfigure (h->srcpad)) gst_harness_negotiate (h); if (priv->pool) { flow = gst_buffer_pool_acquire_buffer (priv->pool, &ret, NULL); g_assert_cmpint (flow, ==, GST_FLOW_OK); if (gst_buffer_get_size (ret) != size) { GST_DEBUG_OBJECT (h, "use fallback, pool is configured with a different size (%zu != %zu)", size, gst_buffer_get_size (ret)); gst_buffer_unref (ret); ret = NULL; } } if (!ret) ret = gst_buffer_new_allocate (priv->allocator, size, &priv->allocation_params); g_assert (ret != NULL); return ret; } /** * gst_harness_push: * @h: a #GstHarness * @buffer: a #GstBuffer to push * * Pushes a #GstBuffer on the #GstHarness srcpad. The standard way of * interacting with an harnessed element. * * MT safe. * * Returns: a #GstFlowReturn with the result from the push * * Since: 1.6 */ GstFlowReturn gst_harness_push (GstHarness * h, GstBuffer * buffer) { GstHarnessPrivate *priv = h->priv; g_assert (buffer != NULL); priv->last_push_ts = GST_BUFFER_TIMESTAMP (buffer); return gst_pad_push (h->srcpad, buffer); } /** * gst_harness_pull: * @h: a #GstHarness * * Pulls a #GstBuffer from the #GAsyncQueue on the #GstHarness sinkpad. The pull * will timeout in 60 seconds. This is the standard way of getting a buffer * from a harnessed #GstElement. * * MT safe. * * Returns: a #GstBuffer or %NULL if timed out. * * Since: 1.6 */ GstBuffer * gst_harness_pull (GstHarness * h) { GstHarnessPrivate *priv = h->priv; GstBuffer *buf = (GstBuffer *) g_async_queue_timeout_pop (priv->buffer_queue, G_USEC_PER_SEC * 60); if (priv->blocking_push_mode) { g_mutex_lock (&priv->blocking_push_mutex); g_cond_signal (&priv->blocking_push_cond); g_mutex_unlock (&priv->blocking_push_mutex); } return buf; } /** * gst_harness_try_pull: * @h: a #GstHarness * * Pulls a #GstBuffer from the #GAsyncQueue on the #GstHarness sinkpad. Unlike * gst_harness_pull this will not wait for any buffers if not any are present, * and return %NULL straight away. * * MT safe. * * Returns: a #GstBuffer or %NULL if no buffers are present in the #GAsyncQueue * * Since: 1.6 */ GstBuffer * gst_harness_try_pull (GstHarness * h) { GstHarnessPrivate *priv = h->priv; GstBuffer *buf = (GstBuffer *) g_async_queue_try_pop (priv->buffer_queue); if (priv->blocking_push_mode) { g_mutex_lock (&priv->blocking_push_mutex); g_cond_signal (&priv->blocking_push_cond); g_mutex_unlock (&priv->blocking_push_mutex); } return buf; } /** * gst_harness_push_and_pull: * @h: a #GstHarness * @buffer: a #GstBuffer to push * * Basically a gst_harness_push and a gst_harness_pull in one line. Reflects * the fact that you often want to do exactly this in your test: Push one buffer * in, and inspect the outcome. * * MT safe. * * Returns: a #GstBuffer or %NULL if timed out. * * Since: 1.6 */ GstBuffer * gst_harness_push_and_pull (GstHarness * h, GstBuffer * buffer) { gst_harness_push (h, buffer); return gst_harness_pull (h); } /** * gst_harness_buffers_received: * @h: a #GstHarness * * The total number of #GstBuffers that has arrived on the #GstHarness sinkpad. * This number includes buffers that have been dropped as well as buffers * that have already been pulled out. * * MT safe. * * Returns: a #guint number of buffers received * * Since: 1.6 */ guint gst_harness_buffers_received (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return g_atomic_int_get (&priv->recv_buffers); } /** * gst_harness_buffers_in_queue: * @h: a #GstHarness * * The number of #GstBuffers currently in the #GstHarness sinkpad #GAsyncQueue * * MT safe. * * Returns: a #guint number of buffers in the queue * * Since: 1.6 */ guint gst_harness_buffers_in_queue (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return g_async_queue_length (priv->buffer_queue); } /** * gst_harness_set_drop_buffers: * @h: a #GstHarness * @drop_buffers: a #gboolean specifying to drop outgoing buffers or not * * When set to %TRUE, instead of placing the buffers arriving from the harnessed * #GstElement inside the sinkpads #GAsyncQueue, they are instead unreffed. * * MT safe. * * Since: 1.6 */ void gst_harness_set_drop_buffers (GstHarness * h, gboolean drop_buffers) { GstHarnessPrivate *priv = h->priv; priv->drop_buffers = drop_buffers; } /** * gst_harness_dump_to_file: * @h: a #GstHarness * @filename: a #gchar with a the name of a file * * Allows you to dump the #GstBuffers the #GstHarness sinkpad #GAsyncQueue * to a file. * * MT safe. * * Since: 1.6 */ void gst_harness_dump_to_file (GstHarness * h, const gchar * filename) { GstHarnessPrivate *priv = h->priv; FILE *fd; GstBuffer *buf; fd = fopen (filename, "wb"); g_assert (fd); while ((buf = g_async_queue_try_pop (priv->buffer_queue))) { GstMapInfo info; gst_buffer_map (buf, &info, GST_MAP_READ); fwrite (info.data, 1, info.size, fd); gst_buffer_unmap (buf, &info); gst_buffer_unref (buf); } fflush (fd); fclose (fd); } /** * gst_harness_get_last_pushed_timestamp: * @h: a #GstHarness * * Get the timestamp of the last #GstBuffer pushed on the #GstHarness srcpad, * typically with gst_harness_push or gst_harness_push_from_src. * * MT safe. * * Returns: a #GstClockTime with the timestamp or %GST_CLOCK_TIME_NONE if no * #GstBuffer has been pushed on the #GstHarness srcpad * * Since: 1.6 */ GstClockTime gst_harness_get_last_pushed_timestamp (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return priv->last_push_ts; } /** * gst_harness_push_event: * @h: a #GstHarness * @event: a #GstEvent to push * * Pushes an #GstEvent on the #GstHarness srcpad. * * MT safe. * * Returns: a #gboolean with the result from the push * * Since: 1.6 */ gboolean gst_harness_push_event (GstHarness * h, GstEvent * event) { return gst_pad_push_event (h->srcpad, event); } /** * gst_harness_pull_event: * @h: a #GstHarness * * Pulls an #GstEvent from the #GAsyncQueue on the #GstHarness sinkpad. * Timeouts after 60 seconds similar to gst_harness_pull. * * MT safe. * * Returns: a #GstEvent or %NULL if timed out. * * Since: 1.6 */ GstEvent * gst_harness_pull_event (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return (GstEvent *) g_async_queue_timeout_pop (priv->sink_event_queue, G_USEC_PER_SEC * 60); } /** * gst_harness_try_pull_event: * @h: a #GstHarness * * Pulls an #GstEvent from the #GAsyncQueue on the #GstHarness sinkpad. * See gst_harness_try_pull for details. * * MT safe. * * Returns: a #GstEvent or %NULL if no buffers are present in the #GAsyncQueue * * Since: 1.6 */ GstEvent * gst_harness_try_pull_event (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return (GstEvent *) g_async_queue_try_pop (priv->sink_event_queue); } /** * gst_harness_events_received: * @h: a #GstHarness * * The total number of #GstEvents that has arrived on the #GstHarness sinkpad * This number includes events handled by the harness as well as events * that have already been pulled out. * * MT safe. * * Returns: a #guint number of events received * * Since: 1.6 */ guint gst_harness_events_received (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return g_atomic_int_get (&priv->recv_events); } /** * gst_harness_events_in_queue: * @h: a #GstHarness * * The number of #GstEvents currently in the #GstHarness sinkpad #GAsyncQueue * * MT safe. * * Returns: a #guint number of events in the queue * * Since: 1.6 */ guint gst_harness_events_in_queue (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return g_async_queue_length (priv->sink_event_queue); } /** * gst_harness_push_upstream_event: * @h: a #GstHarness * @event: a #GstEvent to push * * Pushes an #GstEvent on the #GstHarness sinkpad. * * MT safe. * * Returns: a #gboolean with the result from the push * * Since: 1.6 */ gboolean gst_harness_push_upstream_event (GstHarness * h, GstEvent * event) { g_return_val_if_fail (event != NULL, FALSE); g_return_val_if_fail (GST_EVENT_IS_UPSTREAM (event), FALSE); return gst_pad_push_event (h->sinkpad, event); } /** * gst_harness_pull_upstream_event: * @h: a #GstHarness * * Pulls an #GstEvent from the #GAsyncQueue on the #GstHarness srcpad. * Timeouts after 60 seconds similar to gst_harness_pull. * * MT safe. * * Returns: a #GstEvent or %NULL if timed out. * * Since: 1.6 */ GstEvent * gst_harness_pull_upstream_event (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return (GstEvent *) g_async_queue_timeout_pop (priv->src_event_queue, G_USEC_PER_SEC * 60); } /** * gst_harness_try_pull_upstream_event: * @h: a #GstHarness * * Pulls an #GstEvent from the #GAsyncQueue on the #GstHarness srcpad. * See gst_harness_try_pull for details. * * MT safe. * * Returns: a #GstEvent or %NULL if no buffers are present in the #GAsyncQueue * * Since: 1.6 */ GstEvent * gst_harness_try_pull_upstream_event (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return (GstEvent *) g_async_queue_try_pop (priv->src_event_queue); } /** * gst_harness_upstream_events_received: * @h: a #GstHarness * * The total number of #GstEvents that has arrived on the #GstHarness srcpad * This number includes events handled by the harness as well as events * that have already been pulled out. * * MT safe. * * Returns: a #guint number of events received * * Since: 1.6 */ guint gst_harness_upstream_events_received (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return g_atomic_int_get (&priv->recv_upstream_events); } /** * gst_harness_upstream_events_in_queue: * @h: a #GstHarness * * The number of #GstEvents currently in the #GstHarness srcpad #GAsyncQueue * * MT safe. * * Returns: a #guint number of events in the queue * * Since: 1.6 */ guint gst_harness_upstream_events_in_queue (GstHarness * h) { GstHarnessPrivate *priv = h->priv; return g_async_queue_length (priv->src_event_queue); } /** * gst_harness_query_latency: * @h: a #GstHarness * * Get the min latency reported by any harnessed #GstElement. * * MT safe. * * Returns: a #GstClockTime with min latency * * Since: 1.6 */ GstClockTime gst_harness_query_latency (GstHarness * h) { GstQuery *query; gboolean is_live; GstClockTime min = GST_CLOCK_TIME_NONE; GstClockTime max; query = gst_query_new_latency (); if (gst_pad_peer_query (h->sinkpad, query)) { gst_query_parse_latency (query, &is_live, &min, &max); } gst_query_unref (query); return min; } /** * gst_harness_set_upstream_latency: * @h: a #GstHarness * @latency: a #GstClockTime specifying the latency * * Sets the min latency reported by #GstHarness when receiving a latency-query * * MT safe. * * Returns: a #GstClockTime with min latency * * Since: 1.6 */ void gst_harness_set_upstream_latency (GstHarness * h, GstClockTime latency) { GstHarnessPrivate *priv = h->priv; priv->latency_min = latency; } /** * gst_harness_get_allocator: * @h: a #GstHarness * @allocator: (out) (allow-none) (transfer none): the #GstAllocator used * @params: (out) (allow-none) (transfer full): the #GstAllocationParams of * @allocator * * Gets the @allocator and its @params that has been decided to use after an * allocation query. * * MT safe. * * Since: 1.6 */ void gst_harness_get_allocator (GstHarness * h, GstAllocator ** allocator, GstAllocationParams * params) { GstHarnessPrivate *priv = h->priv; if (allocator) *allocator = priv->allocator; if (params) *params = priv->allocation_params; } /** * gst_harness_set_propose_allocator: * @h: a #GstHarness * @allocator: (allow-none) (transfer full): a #GstAllocator * @params: (allow-none) (transfer none): a #GstAllocationParams * * Sets the @allocator and @params to propose when receiving an allocation * query. * * MT safe. * * Since: 1.6 */ void gst_harness_set_propose_allocator (GstHarness * h, GstAllocator * allocator, const GstAllocationParams * params) { GstHarnessPrivate *priv = h->priv; if (allocator) priv->propose_allocator = allocator; if (params) priv->propose_allocation_params = *params; } /** * gst_harness_add_src_harness: * @h: a #GstHarness * @src_harness: (transfer full): a #GstHarness to be added as a src-harness. * @has_clock_wait: a #gboolean specifying if the #GstElement uses * gst_clock_wait_id internally. * * A src-harness is a great way of providing the #GstHarness with data. * By adding a src-type #GstElement, it is then easy to use functions like * gst_harness_push_from_src or gst_harness_src_crank_and_push_many * to provide your harnessed element with input. The @has_clock_wait variable * is a greate way to control you src-element with, in that you can have it * produce a buffer for you by simply cranking the clock, and not have it * spin out of control producing buffers as fast as possible. * * If a src-harness already exists it will be replaced. * * MT safe. * * Since: 1.6 */ void gst_harness_add_src_harness (GstHarness * h, GstHarness * src_harness, gboolean has_clock_wait) { if (h->src_harness) gst_harness_teardown (h->src_harness); h->src_harness = src_harness; gst_harness_set_forward_pad (h->src_harness, h->srcpad); h->src_harness->priv->has_clock_wait = has_clock_wait; gst_harness_set_forwarding (h->src_harness, h->priv->forwarding); } /** * gst_harness_add_src: * @h: a #GstHarness * @src_element_name: a #gchar with the name of a #GstElement * @has_clock_wait: a #gboolean specifying if the #GstElement uses * gst_clock_wait_id internally. * * Similar to gst_harness_add_src_harness, this is a convenience to * directly create a src-harness using the @src_element_name name specified. * * MT safe. * * Since: 1.6 */ void gst_harness_add_src (GstHarness * h, const gchar * src_element_name, gboolean has_clock_wait) { GstHarness *src_harness = gst_harness_new (src_element_name); gst_harness_add_src_harness (h, src_harness, has_clock_wait); } /** * gst_harness_add_src_parse: * @h: a #GstHarness * @launchline: a #gchar describing a gst-launch type line * @has_clock_wait: a #gboolean specifying if the #GstElement uses * gst_clock_wait_id internally. * * Similar to gst_harness_add_src, this allows you to specify a launch-line, * which can be useful for both having more then one #GstElement acting as your * src (Like a src producing raw buffers, and then an encoder, providing encoded * data), but also by allowing you to set properties like "is-live" directly on * the elements. * * MT safe. * * Since: 1.6 */ void gst_harness_add_src_parse (GstHarness * h, const gchar * launchline, gboolean has_clock_wait) { GstHarness *src_harness = gst_harness_new_parse (launchline); gst_harness_add_src_harness (h, src_harness, has_clock_wait); } /** * gst_harness_push_from_src: * @h: a #GstHarness * * Transfer data from the src-#GstHarness to the main-#GstHarness. It consists * of 4 steps: * 1: Make sure the src is started. (see: gst_harness_play) * 2: Crank the clock (see: gst_harness_crank_single_clock_wait) * 3: Pull a #GstBuffer from the src-#GstHarness (see: gst_harness_pull) * 4: Push the same #GstBuffer into the main-#GstHarness (see: gst_harness_push) * * MT safe. * * Returns: a #GstFlowReturn with the result of the push * * Since: 1.6 */ GstFlowReturn gst_harness_push_from_src (GstHarness * h) { GstBuffer *buf; gboolean crank; g_assert (h->src_harness); /* FIXME: this *is* the right time to start the src, but maybe a flag so we don't keep telling it to play? */ gst_harness_play (h->src_harness); if (h->src_harness->priv->has_clock_wait) { crank = gst_harness_crank_single_clock_wait (h->src_harness); g_assert (crank); } buf = gst_harness_pull (h->src_harness); g_assert (buf != NULL); return gst_harness_push (h, buf); } /** * gst_harness_src_crank_and_push_many: * @h: a #GstHarness * @cranks: a #gint with the number of calls to gst_harness_crank_single_clock_wait * @pushes: a #gint with the number of calls to gst_harness_push * * Transfer data from the src-#GstHarness to the main-#GstHarness. Similar to * gst_harness_push_from_src, this variant allows you to specify how many cranks * and how many pushes to perform. This can be useful for both moving a lot * of data at the same time, as well as cases when one crank does not equal one * buffer to push and v.v. * * MT safe. * * Returns: a #GstFlowReturn with the result of the push * * Since: 1.6 */ GstFlowReturn gst_harness_src_crank_and_push_many (GstHarness * h, gint cranks, gint pushes) { GstFlowReturn ret = GST_FLOW_OK; gboolean crank; g_assert (h->src_harness); gst_harness_play (h->src_harness); for (int i = 0; i < cranks; i++) { crank = gst_harness_crank_single_clock_wait (h->src_harness); g_assert (crank); } for (int i = 0; i < pushes; i++) { GstBuffer *buf; buf = gst_harness_pull (h->src_harness); g_assert (buf != NULL); ret = gst_harness_push (h, buf); if (ret != GST_FLOW_OK) break; } return ret; } /** * gst_harness_src_push_event: * @h: a #GstHarness * * Similar to what gst_harness_src_push does with #GstBuffers, this transfers * a #GstEvent from the src-#GstHarness to the main-#GstHarness. Note that * some #GstEvents are being transferred automagically. Look at sink_forward_pad * for details. * * MT safe. * * Returns: a #gboolean with the result of the push * * Since: 1.6 */ gboolean gst_harness_src_push_event (GstHarness * h) { return gst_harness_push_event (h, gst_harness_pull_event (h->src_harness)); } static gboolean forward_sticky_events (GstPad * pad, GstEvent ** ev, gpointer user_data) { GstHarness *h = user_data; return gst_pad_push_event (h->priv->sink_forward_pad, gst_event_ref (*ev)); } /** * gst_harness_add_sink_harness: * @h: a #GstHarness * @sink_harness: (transfer full): a #GstHarness to be added as a sink-harness. * * Similar to gst_harness_add_src, this allows you to send the data coming out * of your harnessed #GstElement to a sink-element, allowing to test different * responses the element output might create in sink elements. An example might * be an existing sink providing some analytical data on the input it receives that * can be useful to your testing. If the goal is to test a sink-element itself, * this is better acheived using gst_harness_new directly on the sink. * * If a sink-harness already exists it will be replaced. * * MT safe. * * Since: 1.6 */ void gst_harness_add_sink_harness (GstHarness * h, GstHarness * sink_harness) { GstHarnessPrivate *priv = h->priv; if (h->sink_harness) { gst_harness_set_forward_pad (h, NULL); gst_harness_teardown (h->sink_harness); } h->sink_harness = sink_harness; gst_harness_set_forward_pad (h, h->sink_harness->srcpad); if (priv->forwarding && h->sinkpad) gst_pad_sticky_events_foreach (h->sinkpad, forward_sticky_events, h); gst_harness_set_forwarding (h->sink_harness, priv->forwarding); } /** * gst_harness_add_sink: * @h: a #GstHarness * @sink_element_name: a #gchar with the name of a #GstElement * * Similar to gst_harness_add_sink_harness, this is a convenience to * directly create a sink-harness using the @sink_element_name name specified. * * MT safe. * * Since: 1.6 */ void gst_harness_add_sink (GstHarness * h, const gchar * sink_element_name) { GstHarness *sink_harness = gst_harness_new (sink_element_name); gst_harness_add_sink_harness (h, sink_harness); } /** * gst_harness_add_sink_parse: * @h: a #GstHarness * @launchline: a #gchar with the name of a #GstElement * * Similar to gst_harness_add_sink, this allows you to specify a launch-line * instead of just an element name. See gst_harness_add_src_parse for details. * * MT safe. * * Since: 1.6 */ void gst_harness_add_sink_parse (GstHarness * h, const gchar * launchline) { GstHarness *sink_harness = gst_harness_new_parse (launchline); gst_harness_add_sink_harness (h, sink_harness); } /** * gst_harness_push_to_sink: * @h: a #GstHarness * * Transfer one #GstBuffer from the main-#GstHarness to the sink-#GstHarness. * See gst_harness_push_from_src for details. * * MT safe. * * Returns: a #GstFlowReturn with the result of the push * * Since: 1.6 */ GstFlowReturn gst_harness_push_to_sink (GstHarness * h) { GstBuffer *buf; g_assert (h->sink_harness); buf = gst_harness_pull (h); g_assert (buf != NULL); return gst_harness_push (h->sink_harness, buf); } /** * gst_harness_sink_push_many: * @h: a #GstHarness * @pushes: a #gint with the number of calls to gst_harness_push_to_sink * * Convenience that calls gst_harness_push_to_sink @pushes number of times. * Will abort the pushing if any one push fails. * * MT safe. * * Returns: a #GstFlowReturn with the result of the push * * Since: 1.6 */ GstFlowReturn gst_harness_sink_push_many (GstHarness * h, gint pushes) { GstFlowReturn ret = GST_FLOW_OK; g_assert (h->sink_harness); for (int i = 0; i < pushes; i++) { ret = gst_harness_push_to_sink (h); if (ret != GST_FLOW_OK) break; } return ret; } /** * gst_harness_find_element: * @h: a #GstHarness * @element_name: a #gchar with a #GstElementFactory name * * Most useful in conjunction with gst_harness_new_parse, this will scan the * #GstElements inside the #GstHarness, and check if any of them matches * @element_name. Typical usecase being that you need to access one of the * harnessed elements for properties and/or signals. * * MT safe. * * Returns: (transfer full) (allow-none): a #GstElement or %NULL if not found * * Since: 1.6 */ GstElement * gst_harness_find_element (GstHarness * h, const gchar * element_name) { gboolean done = FALSE; GstIterator *iter; GValue data = G_VALUE_INIT; iter = gst_bin_iterate_elements (GST_BIN (h->element)); done = FALSE; while (!done) { switch (gst_iterator_next (iter, &data)) { case GST_ITERATOR_OK: { GstElement *element = g_value_get_object (&data); GstPluginFeature *feature = GST_PLUGIN_FEATURE (gst_element_get_factory (element)); if (!strcmp (element_name, gst_plugin_feature_get_name (feature))) { gst_iterator_free (iter); return element; } g_value_reset (&data); break; } case GST_ITERATOR_RESYNC: gst_iterator_resync (iter); break; case GST_ITERATOR_ERROR: case GST_ITERATOR_DONE: done = TRUE; break; } } gst_iterator_free (iter); return NULL; } /** * gst_harness_set: * @h: a #GstHarness * @element_name: a #gchar with a #GstElementFactory name * @first_property_name: a #gchar with the first property name * @...: value for the first property, followed optionally by more * name/value pairs, followed by %NULL * * A convenience function to allows you to call g_object_set on a #GstElement * that are residing inside the #GstHarness, by using normal g_object_set * syntax. * * MT safe. * * Since: 1.6 */ void gst_harness_set (GstHarness * h, const gchar * element_name, const gchar * first_property_name, ...) { va_list var_args; GstElement *element = gst_harness_find_element (h, element_name); va_start (var_args, first_property_name); g_object_set_valist (G_OBJECT (element), first_property_name, var_args); va_end (var_args); gst_object_unref (element); } /** * gst_harness_get: * @h: a #GstHarness * @element_name: a #gchar with a #GstElementFactory name * @first_property_name: a #gchar with the first property name * @...: return location for the first property, followed optionally by more * name/return location pairs, followed by %NULL * * A convenience function to allows you to call g_object_get on a #GstElement * that are residing inside the #GstHarness, by using normal g_object_get * syntax. * * MT safe. * * Since: 1.6 */ void gst_harness_get (GstHarness * h, const gchar * element_name, const gchar * first_property_name, ...) { va_list var_args; GstElement *element = gst_harness_find_element (h, element_name); va_start (var_args, first_property_name); g_object_get_valist (G_OBJECT (element), first_property_name, var_args); va_end (var_args); gst_object_unref (element); } /** * gst_harness_add_probe: * @h: a #GstHarness * @element_name: a #gchar with a #GstElementFactory name * @pad_name: a #gchar with the name of the pad to attach the probe to * @mask: a #GstPadProbeType (see gst_pad_add_probe) * @callback: a #GstPadProbeCallback (see gst_pad_add_probe) * @user_data: a #gpointer (see gst_pad_add_probe) * @destroy_data: a #GDestroyNotify (see gst_pad_add_probe) * * A convenience function to allows you to call gst_pad_add_probe on a * #GstPad of a #GstElement that are residing inside the #GstHarness, * by using normal gst_pad_add_probe syntax * * MT safe. * * Since: 1.6 */ void gst_harness_add_probe (GstHarness * h, const gchar * element_name, const gchar * pad_name, GstPadProbeType mask, GstPadProbeCallback callback, gpointer user_data, GDestroyNotify destroy_data) { GstElement *element = gst_harness_find_element (h, element_name); GstPad *pad = gst_element_get_static_pad (element, pad_name); gst_pad_add_probe (pad, mask, callback, user_data, destroy_data); gst_object_unref (pad); gst_object_unref (element); } /******************************************************************************/ /* STRESS */ /******************************************************************************/ struct _GstHarnessThread { GstHarness *h; GThread *thread; gboolean running; gulong sleep; GDestroyNotify freefunc; }; typedef struct { GstHarnessThread t; GFunc init; GFunc callback; gpointer data; } GstHarnessCustomThread; typedef struct { GstHarnessThread t; GstCaps *caps; GstSegment segment; GstHarnessPrepareBufferFunc func; gpointer data; GDestroyNotify notify; } GstHarnessPushBufferThread; typedef struct { GstHarnessThread t; GstHarnessPrepareEventFunc func; gpointer data; GDestroyNotify notify; } GstHarnessPushEventThread; typedef struct { GstHarnessThread t; gchar *name; GValue value; } GstHarnessPropThread; typedef struct { GstHarnessThread t; GstPadTemplate *templ; gchar *name; GstCaps *caps; gboolean release; GSList *pads; } GstHarnessReqPadThread; static void gst_harness_thread_init (GstHarnessThread * t, GDestroyNotify freefunc, GstHarness * h, gulong sleep) { t->freefunc = freefunc; t->h = h; t->sleep = sleep; g_ptr_array_add (h->priv->stress, t); } static void gst_harness_thread_free (GstHarnessThread * t) { g_slice_free (GstHarnessThread, t); } static void gst_harness_custom_thread_free (GstHarnessCustomThread * t) { g_slice_free (GstHarnessCustomThread, t); } static void gst_harness_push_buffer_thread_free (GstHarnessPushBufferThread * t) { if (t != NULL) { gst_caps_replace (&t->caps, NULL); if (t->notify != NULL) t->notify (t->data); g_slice_free (GstHarnessPushBufferThread, t); } } static void gst_harness_push_event_thread_free (GstHarnessPushEventThread * t) { if (t != NULL) { if (t->notify != NULL) t->notify (t->data); g_slice_free (GstHarnessPushEventThread, t); } } static void gst_harness_property_thread_free (GstHarnessPropThread * t) { if (t != NULL) { g_free (t->name); g_value_unset (&t->value); g_slice_free (GstHarnessPropThread, t); } } static void gst_harness_requestpad_release (GstPad * pad, GstElement * element) { gst_element_release_request_pad (element, pad); gst_object_unref (pad); } static void gst_harness_requestpad_release_pads (GstHarnessReqPadThread * rpt) { g_slist_foreach (rpt->pads, (GFunc) gst_harness_requestpad_release, rpt->t.h->element); g_slist_free (rpt->pads); rpt->pads = NULL; } static void gst_harness_requestpad_thread_free (GstHarnessReqPadThread * t) { if (t != NULL) { gst_object_replace ((GstObject **) & t->templ, NULL); g_free (t->name); gst_caps_replace (&t->caps, NULL); gst_harness_requestpad_release_pads (t); g_slice_free (GstHarnessReqPadThread, t); } } #define GST_HARNESS_THREAD_START(ID, t) \ (((GstHarnessThread *)t)->running = TRUE, \ ((GstHarnessThread *)t)->thread = g_thread_new ( \ "gst-harness-stress-"G_STRINGIFY(ID), \ (GThreadFunc)gst_harness_stress_##ID##_func, t)) #define GST_HARNESS_THREAD_END(t) \ (t->running = FALSE, \ GPOINTER_TO_UINT (g_thread_join (t->thread))) static void gst_harness_stress_free (GstHarnessThread * t) { if (t != NULL && t->freefunc != NULL) t->freefunc (t); } static gpointer gst_harness_stress_custom_func (GstHarnessThread * t) { GstHarnessCustomThread *ct = (GstHarnessCustomThread *) t; guint count = 0; if (ct->init != NULL) ct->init (ct, ct->data); while (t->running) { ct->callback (ct, ct->data); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } static gpointer gst_harness_stress_statechange_func (GstHarnessThread * t) { guint count = 0; while (t->running) { GstClock *clock = gst_element_get_clock (t->h->element); GstIterator *it; gboolean done = FALSE; gboolean change; change = gst_element_set_state (t->h->element, GST_STATE_NULL); g_assert (change == GST_STATE_CHANGE_SUCCESS); g_thread_yield (); it = gst_element_iterate_sink_pads (t->h->element); while (!done) { GValue item = G_VALUE_INIT; switch (gst_iterator_next (it, &item)) { case GST_ITERATOR_OK: { GstPad *sinkpad = g_value_get_object (&item); GstPad *srcpad = gst_pad_get_peer (sinkpad); if (srcpad != NULL) { gst_pad_unlink (srcpad, sinkpad); gst_pad_link (srcpad, sinkpad); gst_object_unref (srcpad); } g_value_reset (&item); break; } case GST_ITERATOR_RESYNC: gst_iterator_resync (it); break; case GST_ITERATOR_ERROR: g_assert_not_reached (); case GST_ITERATOR_DONE: done = TRUE; break; } g_value_unset (&item); } gst_iterator_free (it); if (clock != NULL) { gst_element_set_clock (t->h->element, clock); gst_object_unref (clock); } change = gst_element_set_state (t->h->element, GST_STATE_PLAYING); g_assert (change == GST_STATE_CHANGE_SUCCESS); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } static gpointer gst_harness_stress_buffer_func (GstHarnessThread * t) { GstHarnessPushBufferThread *pt = (GstHarnessPushBufferThread *) t; guint count = 0; gchar *sid; gboolean handled; /* Push stream start, caps and segment events */ sid = g_strdup_printf ("%s-%p", GST_OBJECT_NAME (t->h->element), t->h); handled = gst_pad_push_event (t->h->srcpad, gst_event_new_stream_start (sid)); g_assert (handled); g_free (sid); handled = gst_pad_push_event (t->h->srcpad, gst_event_new_caps (pt->caps)); g_assert (handled); handled = gst_pad_push_event (t->h->srcpad, gst_event_new_segment (&pt->segment)); g_assert (handled); while (t->running) { gst_harness_push (t->h, pt->func (t->h, pt->data)); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } static gpointer gst_harness_stress_event_func (GstHarnessThread * t) { GstHarnessPushEventThread *pet = (GstHarnessPushEventThread *) t; guint count = 0; while (t->running) { gst_harness_push_event (t->h, pet->func (t->h, pet->data)); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } static gpointer gst_harness_stress_upstream_event_func (GstHarnessThread * t) { GstHarnessPushEventThread *pet = (GstHarnessPushEventThread *) t; guint count = 0; while (t->running) { gst_harness_push_upstream_event (t->h, pet->func (t->h, pet->data)); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } static gpointer gst_harness_stress_property_func (GstHarnessThread * t) { GstHarnessPropThread *pt = (GstHarnessPropThread *) t; guint count = 0; while (t->running) { GValue value = G_VALUE_INIT; g_object_set_property (G_OBJECT (t->h->element), pt->name, &pt->value); g_value_init (&value, G_VALUE_TYPE (&pt->value)); g_object_get_property (G_OBJECT (t->h->element), pt->name, &value); g_value_reset (&value); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } static gpointer gst_harness_stress_requestpad_func (GstHarnessThread * t) { GstHarnessReqPadThread *rpt = (GstHarnessReqPadThread *) t; guint count = 0; while (t->running) { GstPad *reqpad; if (rpt->release) gst_harness_requestpad_release_pads (rpt); g_thread_yield (); reqpad = gst_element_request_pad (t->h->element, rpt->templ, rpt->name, rpt->caps); g_assert (reqpad != NULL); rpt->pads = g_slist_prepend (rpt->pads, reqpad); count++; g_usleep (t->sleep); } return GUINT_TO_POINTER (count); } /** * gst_harness_stress_thread_stop: * @t: a #GstHarnessThread * * Stop the running #GstHarnessThread * * MT safe. * * Since: 1.6 */ guint gst_harness_stress_thread_stop (GstHarnessThread * t) { guint ret; g_return_val_if_fail (t != NULL, 0); ret = GST_HARNESS_THREAD_END (t); g_ptr_array_remove (t->h->priv->stress, t); return ret; } /** * gst_harness_stress_custom_start: (skip) * @h: a #GstHarness * @init: (allow-none): a #GFunc that is called initially and only once * @callback: a #GFunc that is called as often as possible * @data: a #gpointer with custom data to pass to the @callback function * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each call to the @callback * * Start a custom stress-thread that will call your @callback for every * iteration allowing you to do something nasty. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_custom_start (GstHarness * h, GFunc init, GFunc callback, gpointer data, gulong sleep) { GstHarnessCustomThread *t = g_slice_new0 (GstHarnessCustomThread); gst_harness_thread_init (&t->t, (GDestroyNotify) gst_harness_custom_thread_free, h, sleep); t->init = init; t->callback = callback; t->data = data; GST_HARNESS_THREAD_START (custom, t); return &t->t; } /** * gst_harness_stress_statechange_start_full: (skip) * @h: a #GstHarness * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each state-change * * Change the state of your harnessed #GstElement from NULL to PLAYING and * back again, only pausing for @sleep microseconds every time. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_statechange_start_full (GstHarness * h, gulong sleep) { GstHarnessThread *t = g_slice_new0 (GstHarnessThread); gst_harness_thread_init (t, (GDestroyNotify) gst_harness_thread_free, h, sleep); GST_HARNESS_THREAD_START (statechange, t); return t; } static GstBuffer * gst_harness_ref_buffer (GstHarness * h, gpointer data) { (void) h; return gst_buffer_ref (GST_BUFFER_CAST (data)); } static GstEvent * gst_harness_ref_event (GstHarness * h, gpointer data) { (void) h; return gst_event_ref (GST_EVENT_CAST (data)); } /** * gst_harness_stress_push_buffer_start_full: (skip) * @h: a #GstHarness * @caps: a #GstCaps for the #GstBuffer * @segment: a #GstSegment * @buf: a #GstBuffer to push * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each call to gst_pad_push * * Push a #GstBuffer in intervals of @sleep microseconds. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_push_buffer_start_full (GstHarness * h, GstCaps * caps, const GstSegment * segment, GstBuffer * buf, gulong sleep) { return gst_harness_stress_push_buffer_with_cb_start_full (h, caps, segment, gst_harness_ref_buffer, gst_buffer_ref (buf), (GDestroyNotify) gst_buffer_unref, sleep); } /** * gst_harness_stress_push_buffer_with_cb_start_full: (skip) * @h: a #GstHarness * @caps: a #GstCaps for the #GstBuffer * @segment: a #GstSegment * @func: a #GstHarnessPrepareBufferFunc function called before every iteration * to prepare / create a #GstBuffer for pushing * @data: a #gpointer with data to the #GstHarnessPrepareBufferFunc function * @notify: a #GDestroyNotify that is called when thread is stopped * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each call to gst_pad_push * * Push a #GstBuffer returned by @func in intervals of @sleep microseconds. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_push_buffer_with_cb_start_full (GstHarness * h, GstCaps * caps, const GstSegment * segment, GstHarnessPrepareBufferFunc func, gpointer data, GDestroyNotify notify, gulong sleep) { GstHarnessPushBufferThread *t = g_slice_new0 (GstHarnessPushBufferThread); gst_harness_thread_init (&t->t, (GDestroyNotify) gst_harness_push_buffer_thread_free, h, sleep); gst_caps_replace (&t->caps, caps); t->segment = *segment; t->func = func; t->data = data; t->notify = notify; GST_HARNESS_THREAD_START (buffer, t); return &t->t; } /** * gst_harness_stress_push_event_start_full: (skip) * @h: a #GstHarness * @event: a #GstEvent to push * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each gst_event_push with @event * * Push the @event onto the harnessed #GstElement sinkpad in intervals of * @sleep microseconds * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_push_event_start_full (GstHarness * h, GstEvent * event, gulong sleep) { return gst_harness_stress_push_event_with_cb_start_full (h, gst_harness_ref_event, gst_event_ref (event), (GDestroyNotify) gst_event_unref, sleep); } /** * gst_harness_stress_push_event_with_cb_start_full: (skip) * @h: a #GstHarness * @func: a #GstHarnessPrepareEventFunc function called before every iteration * to prepare / create a #GstEvent for pushing * @data: a #gpointer with data to the #GstHarnessPrepareEventFunc function * @notify: a #GDestroyNotify that is called when thread is stopped * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each call to gst_pad_push * * Push a #GstEvent returned by @func onto the harnessed #GstElement sinkpad * in intervals of @sleep microseconds. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.8 */ GstHarnessThread * gst_harness_stress_push_event_with_cb_start_full (GstHarness * h, GstHarnessPrepareEventFunc func, gpointer data, GDestroyNotify notify, gulong sleep) { GstHarnessPushEventThread *t = g_slice_new0 (GstHarnessPushEventThread); gst_harness_thread_init (&t->t, (GDestroyNotify) gst_harness_push_event_thread_free, h, sleep); t->func = func; t->data = data; t->notify = notify; GST_HARNESS_THREAD_START (event, t); return &t->t; } /** * gst_harness_stress_push_upstream_event_start_full: (skip) * @h: a #GstHarness * @event: a #GstEvent to push * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each gst_event_push with @event * * Push the @event onto the harnessed #GstElement srcpad in intervals of * @sleep microseconds. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_push_upstream_event_start_full (GstHarness * h, GstEvent * event, gulong sleep) { return gst_harness_stress_push_upstream_event_with_cb_start_full (h, gst_harness_ref_event, gst_event_ref (event), (GDestroyNotify) gst_event_unref, sleep); } /** * gst_harness_stress_push_upstream_event_with_cb_start_full: (skip) * @h: a #GstHarness * @func: a #GstHarnessPrepareEventFunc function called before every iteration * to prepare / create a #GstEvent for pushing * @data: a #gpointer with data to the #GstHarnessPrepareEventFunc function * @notify: a #GDestroyNotify that is called when thread is stopped * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each call to gst_pad_push * * Push a #GstEvent returned by @func onto the harnessed #GstElement srcpad * in intervals of @sleep microseconds. * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.8 */ GstHarnessThread * gst_harness_stress_push_upstream_event_with_cb_start_full (GstHarness * h, GstHarnessPrepareEventFunc func, gpointer data, GDestroyNotify notify, gulong sleep) { GstHarnessPushEventThread *t = g_slice_new0 (GstHarnessPushEventThread); gst_harness_thread_init (&t->t, (GDestroyNotify) gst_harness_push_event_thread_free, h, sleep); t->func = func; t->data = data; t->notify = notify; GST_HARNESS_THREAD_START (upstream_event, t); return &t->t; } /** * gst_harness_stress_property_start_full: (skip) * @h: a #GstHarness * @name: a #gchar specifying a property name * @value: a #GValue to set the property to * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each g_object_set with @name and @value * * Call g_object_set with @name and @value in intervals of @sleep microseconds * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_property_start_full (GstHarness * h, const gchar * name, const GValue * value, gulong sleep) { GstHarnessPropThread *t = g_slice_new0 (GstHarnessPropThread); gst_harness_thread_init (&t->t, (GDestroyNotify) gst_harness_property_thread_free, h, sleep); t->name = g_strdup (name); g_value_init (&t->value, G_VALUE_TYPE (value)); g_value_copy (value, &t->value); GST_HARNESS_THREAD_START (property, t); return &t->t; } /** * gst_harness_stress_requestpad_start_full: (skip) * @h: a #GstHarness * @templ: a #GstPadTemplate * @name: a #gchar * @caps: a #GstCaps * @release: a #gboolean * @sleep: a #gulong specifying how long to sleep in (microseconds) for * each gst_element_request_pad * * Call gst_element_request_pad in intervals of @sleep microseconds * * MT safe. * * Returns: a #GstHarnessThread * * Since: 1.6 */ GstHarnessThread * gst_harness_stress_requestpad_start_full (GstHarness * h, GstPadTemplate * templ, const gchar * name, GstCaps * caps, gboolean release, gulong sleep) { GstHarnessReqPadThread *t = g_slice_new0 (GstHarnessReqPadThread); gst_harness_thread_init (&t->t, (GDestroyNotify) gst_harness_requestpad_thread_free, h, sleep); t->templ = gst_object_ref (templ); t->name = g_strdup (name); gst_caps_replace (&t->caps, caps); t->release = release; GST_HARNESS_THREAD_START (requestpad, t); return &t->t; }