/* GStreamer * Copyright (C) 1999,2000 Erik Walthinsen * 2000 Wim Taymans * * gstscheduler.c: Default scheduling code for most cases * * 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. */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include #include "cothreads_compat.h" GST_DEBUG_CATEGORY_STATIC(debug_dataflow); GST_DEBUG_CATEGORY_STATIC(debug_scheduler); #define GST_CAT_DEFAULT debug_scheduler typedef struct _GstSchedulerChain GstSchedulerChain; #define GST_ELEMENT_THREADSTATE(elem) (cothread*) (GST_ELEMENT_CAST (elem)->sched_private) #define GST_RPAD_BUFPEN(pad) (GstData*) (GST_REAL_PAD_CAST(pad)->sched_private) #define GST_ELEMENT_COTHREAD_STOPPING GST_ELEMENT_SCHEDULER_PRIVATE1 #define GST_ELEMENT_IS_COTHREAD_STOPPING(element) GST_FLAG_IS_SET((element), GST_ELEMENT_COTHREAD_STOPPING) typedef struct _GstBasicScheduler GstBasicScheduler; typedef struct _GstBasicSchedulerClass GstBasicSchedulerClass; #ifdef _COTHREADS_STANDARD # define _SCHEDULER_NAME "standard" #else # define _SCHEDULER_NAME "basic" #endif struct _GstSchedulerChain { GstBasicScheduler *sched; GList *disabled; GList *elements; gint num_elements; GstElement *entry; gint cothreaded_elements; gboolean schedule; }; #define GST_TYPE_BASIC_SCHEDULER \ (gst_basic_scheduler_get_type()) #define GST_BASIC_SCHEDULER(obj) \ (G_TYPE_CHECK_INSTANCE_CAST((obj),GST_TYPE_BASIC_SCHEDULER,GstBasicScheduler)) #define GST_BASIC_SCHEDULER_CLASS(klass) \ (G_TYPE_CHECK_CLASS_CAST((klass),GST_TYPE_BASIC_SCHEDULER,GstBasicSchedulerClass)) #define GST_IS_BASIC_SCHEDULER(obj) \ (G_TYPE_CHECK_INSTANCE_TYPE((obj),GST_TYPE_BASIC_SCHEDULER)) #define GST_IS_BASIC_SCHEDULER_CLASS(obj) \ (G_TYPE_CHECK_CLASS_TYPE((klass),GST_TYPE_BASIC_SCHEDULER)) #define GST_BASIC_SCHEDULER_CAST(sched) ((GstBasicScheduler *)(sched)) #define SCHED(element) GST_BASIC_SCHEDULER_CAST (GST_ELEMENT_SCHED (element)) typedef enum { GST_BASIC_SCHEDULER_STATE_NONE, GST_BASIC_SCHEDULER_STATE_STOPPED, GST_BASIC_SCHEDULER_STATE_ERROR, GST_BASIC_SCHEDULER_STATE_RUNNING, } GstBasicSchedulerState; typedef enum { /* something important has changed inside the scheduler */ GST_BASIC_SCHEDULER_CHANGE = GST_SCHEDULER_FLAG_LAST, } GstBasicSchedulerFlags; struct _GstBasicScheduler { GstScheduler parent; GList *elements; gint num_elements; GList *chains; gint num_chains; GstBasicSchedulerState state; cothread_context *context; GstElement *current; }; struct _GstBasicSchedulerClass { GstSchedulerClass parent_class; }; static GType _gst_basic_scheduler_type = 0; static void gst_basic_scheduler_class_init (GstBasicSchedulerClass * klass); static void gst_basic_scheduler_init (GstBasicScheduler * scheduler); static void gst_basic_scheduler_dispose (GObject *object); static void gst_basic_scheduler_setup (GstScheduler *sched); static void gst_basic_scheduler_reset (GstScheduler *sched); static void gst_basic_scheduler_add_element (GstScheduler *sched, GstElement *element); static void gst_basic_scheduler_remove_element (GstScheduler *sched, GstElement *element); static GstElementStateReturn gst_basic_scheduler_state_transition (GstScheduler *sched, GstElement *element, gint transition); static void gst_basic_scheduler_lock_element (GstScheduler *sched, GstElement *element); static void gst_basic_scheduler_unlock_element (GstScheduler *sched, GstElement *element); static gboolean gst_basic_scheduler_yield (GstScheduler *sched, GstElement *element); static gboolean gst_basic_scheduler_interrupt (GstScheduler *sched, GstElement *element); static void gst_basic_scheduler_error (GstScheduler *sched, GstElement *element); static void gst_basic_scheduler_pad_link (GstScheduler *sched, GstPad *srcpad, GstPad *sinkpad); static void gst_basic_scheduler_pad_unlink (GstScheduler *sched, GstPad *srcpad, GstPad *sinkpad); static void gst_basic_scheduler_pad_select (GstScheduler *sched, GList *padlist); static GstClockReturn gst_basic_scheduler_clock_wait (GstScheduler *sched, GstElement *element, GstClockID id, GstClockTimeDiff *jitter); static GstSchedulerState gst_basic_scheduler_iterate (GstScheduler *sched); static void gst_basic_scheduler_show (GstScheduler *sched); static GstSchedulerClass *parent_class = NULL; /* for threaded bins, these pre- and post-run functions lock and unlock the * elements. we have to avoid deadlocks, so we make these convenience macros * that will avoid using do_cothread_switch from within the scheduler. */ #define do_element_switch(element) G_STMT_START{ \ GstElement *from = SCHED (element)->current; \ if (from && from->post_run_func) \ from->post_run_func (from); \ SCHED (element)->current = element; \ if (element->pre_run_func) \ element->pre_run_func (element); \ do_cothread_switch (GST_ELEMENT_THREADSTATE (element)); \ }G_STMT_END #define do_switch_to_main(sched) G_STMT_START{ \ GstElement *current = ((GstBasicScheduler*)sched)->current; \ if (current && current->post_run_func) \ current->post_run_func (current); \ SCHED (current)->current = NULL; \ do_cothread_switch \ (do_cothread_get_main \ (((GstBasicScheduler*)sched)->context)); \ }G_STMT_END #define do_switch_from_main(entry) G_STMT_START{ \ if (entry->pre_run_func) \ entry->pre_run_func (entry); \ SCHED (entry)->current = entry; \ do_cothread_switch (GST_ELEMENT_THREADSTATE (entry)); \ }G_STMT_END static GType gst_basic_scheduler_get_type (void) { if (!_gst_basic_scheduler_type) { static const GTypeInfo scheduler_info = { sizeof (GstBasicSchedulerClass), NULL, NULL, (GClassInitFunc) gst_basic_scheduler_class_init, NULL, NULL, sizeof (GstBasicScheduler), 0, (GInstanceInitFunc) gst_basic_scheduler_init, NULL }; _gst_basic_scheduler_type = g_type_register_static (GST_TYPE_SCHEDULER, "Gst"COTHREADS_NAME_CAPITAL"Scheduler", &scheduler_info, 0); } return _gst_basic_scheduler_type; } static void gst_basic_scheduler_class_init (GstBasicSchedulerClass * klass) { GObjectClass *gobject_class; GstObjectClass *gstobject_class; GstSchedulerClass *gstscheduler_class; gobject_class = (GObjectClass*)klass; gstobject_class = (GstObjectClass*)klass; gstscheduler_class = (GstSchedulerClass*)klass; parent_class = g_type_class_ref (GST_TYPE_SCHEDULER); gobject_class->dispose = GST_DEBUG_FUNCPTR (gst_basic_scheduler_dispose); gstscheduler_class->setup = GST_DEBUG_FUNCPTR (gst_basic_scheduler_setup); gstscheduler_class->reset = GST_DEBUG_FUNCPTR (gst_basic_scheduler_reset); gstscheduler_class->add_element = GST_DEBUG_FUNCPTR (gst_basic_scheduler_add_element); gstscheduler_class->remove_element = GST_DEBUG_FUNCPTR (gst_basic_scheduler_remove_element); gstscheduler_class->state_transition = GST_DEBUG_FUNCPTR (gst_basic_scheduler_state_transition); gstscheduler_class->lock_element = GST_DEBUG_FUNCPTR (gst_basic_scheduler_lock_element); gstscheduler_class->unlock_element = GST_DEBUG_FUNCPTR (gst_basic_scheduler_unlock_element); gstscheduler_class->yield = GST_DEBUG_FUNCPTR (gst_basic_scheduler_yield); gstscheduler_class->interrupt = GST_DEBUG_FUNCPTR (gst_basic_scheduler_interrupt); gstscheduler_class->error = GST_DEBUG_FUNCPTR (gst_basic_scheduler_error); gstscheduler_class->pad_link = GST_DEBUG_FUNCPTR (gst_basic_scheduler_pad_link); gstscheduler_class->pad_unlink = GST_DEBUG_FUNCPTR (gst_basic_scheduler_pad_unlink); gstscheduler_class->pad_select = GST_DEBUG_FUNCPTR (gst_basic_scheduler_pad_select); gstscheduler_class->clock_wait = GST_DEBUG_FUNCPTR (gst_basic_scheduler_clock_wait); gstscheduler_class->iterate = GST_DEBUG_FUNCPTR (gst_basic_scheduler_iterate); gstscheduler_class->show = GST_DEBUG_FUNCPTR (gst_basic_scheduler_show); do_cothreads_init(NULL); } static void gst_basic_scheduler_init (GstBasicScheduler *scheduler) { scheduler->elements = NULL; scheduler->num_elements = 0; scheduler->chains = NULL; scheduler->num_chains = 0; } static void gst_basic_scheduler_dispose (GObject *object) { G_OBJECT_CLASS (parent_class)->dispose (object); } static gboolean plugin_init (GstPlugin *plugin) { GstSchedulerFactory *factory; GST_DEBUG_CATEGORY_INIT (debug_dataflow, "dataflow", 0, "basic scheduler dataflow"); GST_DEBUG_CATEGORY_INIT (debug_scheduler, "scheduler", 0, "basic scheduler general information"); factory = gst_scheduler_factory_new ("basic"COTHREADS_NAME, "A basic scheduler using "COTHREADS_NAME" cothreads", gst_basic_scheduler_get_type()); if (factory != NULL) { gst_plugin_add_feature (plugin, GST_PLUGIN_FEATURE (factory)); } else { g_warning ("could not register scheduler: "COTHREADS_NAME); } return TRUE; } GST_PLUGIN_DEFINE ( GST_VERSION_MAJOR, GST_VERSION_MINOR, "gstbasic"COTHREADS_NAME"scheduler", "a basic scheduler using "COTHREADS_NAME" cothreads", plugin_init, VERSION, GST_LICENSE, GST_COPYRIGHT, GST_PACKAGE, GST_ORIGIN ) static int gst_basic_scheduler_loopfunc_wrapper (int argc, char **argv) { GstElement *element = GST_ELEMENT_CAST (argv); G_GNUC_UNUSED const gchar *name = GST_ELEMENT_NAME (element); GST_DEBUG("entering loopfunc wrapper of %s", name); gst_object_ref (GST_OBJECT (element)); do { GST_CAT_DEBUG (debug_dataflow, "calling loopfunc %s for element %s", GST_DEBUG_FUNCPTR_NAME (element->loopfunc), name); (element->loopfunc) (element); GST_CAT_DEBUG (debug_dataflow, "element %s ended loop function", name); } while (!GST_ELEMENT_IS_COTHREAD_STOPPING (element)); GST_FLAG_UNSET (element, GST_ELEMENT_COTHREAD_STOPPING); /* due to oddities in the cothreads code, when this function returns it will * switch to the main cothread. thus, we need to unlock the current element. */ if (SCHED (element)) { if (SCHED (element)->current && SCHED (element)->current->post_run_func) { SCHED (element)->current->post_run_func (SCHED (element)->current); } SCHED (element)->current = NULL; } GST_DEBUG("leaving loopfunc wrapper of %s", name); gst_object_unref (GST_OBJECT (element)); return 0; } static int gst_basic_scheduler_chain_wrapper (int argc, char **argv) { GSList *already_iterated = NULL; GstElement *element = GST_ELEMENT_CAST (argv); G_GNUC_UNUSED const gchar *name = GST_ELEMENT_NAME (element); GST_DEBUG ("entered chain wrapper of element %s", name); GST_CAT_DEBUG (debug_dataflow, "stepping through pads"); gst_object_ref (GST_OBJECT (element)); do { GList *pads; do { pads = element->pads; while (pads) { GstPad *pad = GST_PAD (pads->data); GstRealPad *realpad; if (!GST_IS_REAL_PAD (pad)) continue; realpad = GST_REAL_PAD (pad); if (GST_RPAD_DIRECTION (realpad) == GST_PAD_SINK && GST_PAD_IS_LINKED (realpad) && g_slist_find (already_iterated, pad) == NULL) { GstData *data; GST_CAT_DEBUG (debug_dataflow, "pulling data from %s:%s", name, GST_PAD_NAME (pad)); data = gst_pad_pull (pad); if (data) { if (GST_IS_EVENT (data) && !GST_ELEMENT_IS_EVENT_AWARE (element)) { gst_pad_send_event (pad, GST_EVENT (data)); } else { GST_CAT_DEBUG (debug_dataflow, "calling chain function of %s:%s %p", name, GST_PAD_NAME (pad), data); GST_RPAD_CHAINFUNC (realpad) (pad, data); GST_CAT_DEBUG (debug_dataflow, "calling chain function of element %s done", name); } } already_iterated = g_slist_prepend (already_iterated, pad); break; } pads = g_list_next (pads); } } while (pads != NULL); g_slist_free (already_iterated); already_iterated = NULL; } while (!GST_ELEMENT_IS_COTHREAD_STOPPING (element)); GST_FLAG_UNSET (element, GST_ELEMENT_COTHREAD_STOPPING); /* due to oddities in the cothreads code, when this function returns it will * switch to the main cothread. thus, we need to unlock the current element. */ if (SCHED (element)) { if (SCHED (element)->current && SCHED (element)->current->post_run_func) { SCHED (element)->current->post_run_func (SCHED (element)->current); } SCHED (element)->current = NULL; } GST_DEBUG ("leaving chain wrapper of element %s", name); gst_object_unref (GST_OBJECT (element)); return 0; } static int gst_basic_scheduler_src_wrapper (int argc, char **argv) { GstElement *element = GST_ELEMENT_CAST (argv); GList *pads; GstRealPad *realpad; GstData *data = NULL; G_GNUC_UNUSED const gchar *name = GST_ELEMENT_NAME (element); GST_DEBUG ("entering src wrapper of element %s", name); do { pads = element->pads; while (pads) { if (!GST_IS_REAL_PAD (pads->data)) continue; realpad = GST_REAL_PAD_CAST (pads->data); pads = g_list_next (pads); if (GST_RPAD_DIRECTION (realpad) == GST_PAD_SRC && GST_PAD_IS_USABLE (realpad)) { GST_CAT_DEBUG (debug_dataflow, "calling _getfunc for %s:%s", GST_DEBUG_PAD_NAME (realpad)); g_return_val_if_fail (GST_RPAD_GETFUNC (realpad) != NULL, 0); data = GST_RPAD_GETFUNC (realpad) (GST_PAD_CAST (realpad)); if (data) { GST_CAT_DEBUG (debug_dataflow, "calling gst_pad_push on pad %s:%s %p", GST_DEBUG_PAD_NAME (realpad), data); gst_pad_push (GST_PAD_CAST (realpad), data); } } } } while (!GST_ELEMENT_IS_COTHREAD_STOPPING (element)); GST_FLAG_UNSET (element, GST_ELEMENT_COTHREAD_STOPPING); /* due to oddities in the cothreads code, when this function returns it will * switch to the main cothread. thus, we need to unlock the current element. */ if (SCHED (element)->current->post_run_func) SCHED (element)->current->post_run_func (SCHED (element)->current); SCHED (element)->current = NULL; GST_DEBUG ("leaving src wrapper of element %s", name); return 0; } static void gst_basic_scheduler_chainhandler_proxy (GstPad * pad, GstData * data) { gint loop_count = 100; GstElement *parent; GstRealPad *peer; parent = GST_PAD_PARENT (pad); peer = GST_RPAD_PEER (pad); GST_DEBUG ("entered chainhandler proxy of %s:%s", GST_DEBUG_PAD_NAME (pad)); GST_CAT_DEBUG (debug_dataflow, "putting buffer %p in peer \"%s:%s\"'s pen", data, GST_DEBUG_PAD_NAME (peer)); /* * loop until the bufferpen is empty so we can fill it up again */ while (GST_RPAD_BUFPEN (GST_RPAD_PEER (pad)) != NULL && --loop_count) { GST_CAT_DEBUG (debug_dataflow, "switching to %p to empty bufpen %d", GST_ELEMENT_THREADSTATE (parent), loop_count); do_element_switch (parent); /* we may no longer be the same pad, check. */ if (GST_RPAD_PEER (peer) != (GstRealPad *) pad) { GST_CAT_DEBUG (debug_dataflow, "new pad in mid-switch!"); pad = (GstPad *) GST_RPAD_PEER (peer); } parent = GST_PAD_PARENT (pad); peer = GST_RPAD_PEER (pad); } if (loop_count == 0) { gst_element_error (parent, "(internal error) basic: maximum number of switches exceeded"); return; } g_assert (GST_RPAD_BUFPEN (GST_RPAD_PEER (pad)) == NULL); /* now fill the bufferpen and switch so it can be consumed */ GST_RPAD_BUFPEN (GST_RPAD_PEER (pad)) = data; GST_CAT_DEBUG (debug_dataflow, "switching to %p to consume buffer %p", GST_ELEMENT_THREADSTATE (GST_PAD_PARENT (pad)), data); do_element_switch (parent); GST_DEBUG ("leaving chainhandler proxy of %s:%s", GST_DEBUG_PAD_NAME (pad)); } static void gst_basic_scheduler_select_proxy (GstPad * pad, GstData * data) { GstElement *parent; parent = GST_PAD_PARENT (pad); GST_CAT_DEBUG (debug_dataflow, "putting buffer %p in peer's pen of pad %s:%s", data, GST_DEBUG_PAD_NAME (pad)); g_assert (GST_RPAD_BUFPEN (GST_RPAD_PEER (pad)) == NULL); /* now fill the bufferpen and switch so it can be consumed */ GST_RPAD_BUFPEN (GST_RPAD_PEER (pad)) = data; GST_CAT_DEBUG (debug_dataflow, "switching to %p", GST_ELEMENT_THREADSTATE (parent)); /* FIXME temporarily diabled */ /* parent->select_pad = pad; */ do_element_switch (parent); GST_CAT_DEBUG (debug_dataflow, "done switching"); } static GstData * gst_basic_scheduler_gethandler_proxy (GstPad * pad) { GstData *data; GstElement *parent; GstRealPad *peer; GST_DEBUG ("entering gethandler proxy of %s:%s", GST_DEBUG_PAD_NAME (pad)); parent = GST_PAD_PARENT (pad); peer = GST_RPAD_PEER (pad); /* FIXME this should be bounded */ /* we will loop switching to the peer until it's filled up the bufferpen */ while (GST_RPAD_BUFPEN (pad) == NULL) { GST_CAT_DEBUG (debug_dataflow, "switching to \"%s\": %p to fill bufpen", GST_ELEMENT_NAME (parent), GST_ELEMENT_THREADSTATE (parent)); do_element_switch (parent); /* we may no longer be the same pad, check. */ if (GST_RPAD_PEER (peer) != (GstRealPad *) pad) { GST_CAT_DEBUG (debug_dataflow, "new pad in mid-switch!"); pad = (GstPad *) GST_RPAD_PEER (peer); if (!pad) { gst_element_error (parent, "pad unlinked"); } parent = GST_PAD_PARENT (pad); peer = GST_RPAD_PEER (pad); } } GST_CAT_DEBUG (debug_dataflow, "done switching"); /* now grab the buffer from the pen, clear the pen, and return the buffer */ data = GST_RPAD_BUFPEN (pad); GST_RPAD_BUFPEN (pad) = NULL; GST_DEBUG ("leaving gethandler proxy of %s:%s", GST_DEBUG_PAD_NAME (pad)); return data; } static gboolean gst_basic_scheduler_eventhandler_proxy (GstPad *srcpad, GstEvent *event) { gboolean flush; GST_INFO ("intercepting event %d on pad %s:%s", GST_EVENT_TYPE (event), GST_DEBUG_PAD_NAME (srcpad)); /* figure out if we need to flush */ switch (GST_EVENT_TYPE (event)) { case GST_EVENT_FLUSH: flush = TRUE; break; case GST_EVENT_SEEK: case GST_EVENT_SEEK_SEGMENT: flush = GST_EVENT_SEEK_FLAGS (event) & GST_SEEK_FLAG_FLUSH; break; default: flush = FALSE; break; } if (flush) { GstData *data = GST_RPAD_BUFPEN (srcpad); GST_INFO ("event is flush"); if (data) { GST_INFO ("need to clear some buffers"); gst_data_unref (data); GST_RPAD_BUFPEN (srcpad) = NULL; } } return GST_RPAD_EVENTFUNC (srcpad) (srcpad, event); } static gboolean gst_basic_scheduler_cothreaded_chain (GstBin * bin, GstSchedulerChain * chain) { GList *elements; GstElement *element; cothread_func wrapper_function; const GList *pads; GstPad *pad; GST_DEBUG ("chain is using COTHREADS"); g_assert (chain->sched->context != NULL); /* walk through all the chain's elements */ elements = chain->elements; while (elements) { gboolean decoupled; element = GST_ELEMENT_CAST (elements->data); elements = g_list_next (elements); decoupled = GST_FLAG_IS_SET (element, GST_ELEMENT_DECOUPLED); /* start out without a wrapper function, we select it later */ wrapper_function = NULL; /* if the element has a loopfunc... */ if (element->loopfunc != NULL) { wrapper_function = GST_DEBUG_FUNCPTR (gst_basic_scheduler_loopfunc_wrapper); GST_DEBUG ("element '%s' is a loop-based", GST_ELEMENT_NAME (element)); } else { /* otherwise we need to decide what kind of cothread * if it's not DECOUPLED, we decide based on * whether it's a source or not */ if (!decoupled) { /* if it doesn't have any sinks, it must be a source (duh) */ if (element->numsinkpads == 0) { wrapper_function = GST_DEBUG_FUNCPTR (gst_basic_scheduler_src_wrapper); GST_DEBUG ("element '%s' is a source, using _src_wrapper", GST_ELEMENT_NAME (element)); } else { wrapper_function = GST_DEBUG_FUNCPTR (gst_basic_scheduler_chain_wrapper); GST_DEBUG ("element '%s' is a filter, using _chain_wrapper", GST_ELEMENT_NAME (element)); } } } /* now we have to walk through the pads to set up their state */ pads = gst_element_get_pad_list (element); while (pads) { GstPad *peerpad; pad = GST_PAD (pads->data); pads = g_list_next (pads); if (!GST_IS_REAL_PAD (pad)) continue; peerpad = GST_PAD_PEER (pad); if (peerpad) { GstElement *peerelement = GST_ELEMENT_CAST (GST_PAD_PARENT (peerpad)); gboolean different_sched = (peerelement->sched != GST_SCHEDULER (chain->sched)); gboolean peer_decoupled = GST_FLAG_IS_SET (peerelement, GST_ELEMENT_DECOUPLED); GST_DEBUG ("inspecting pad %s:%s", GST_DEBUG_PAD_NAME (peerpad)); /* we don't need to check this for decoupled elements */ if (!decoupled) { /* if the peer element is in another schedule, * it's not decoupled and we are not decoupled * either, we have an error */ if (different_sched && !peer_decoupled) { gst_element_error (element, "element \"%s\" is not decoupled but has pads " "in different schedulers", GST_ELEMENT_NAME (element), NULL); return FALSE; } /* ok, the peer is in a different scheduler and is decoupled, * we need to set the * handlers so we can talk with it */ else if (different_sched) { if (GST_RPAD_DIRECTION (peerpad) == GST_PAD_SINK) { GST_DEBUG ("copying chain func into push proxy for peer %s:%s", GST_DEBUG_PAD_NAME (peerpad)); GST_RPAD_CHAINHANDLER (peerpad) = GST_RPAD_CHAINFUNC (peerpad); } else { GST_DEBUG ("copying get func into pull proxy for peer %s:%s", GST_DEBUG_PAD_NAME (peerpad)); GST_RPAD_GETHANDLER (peerpad) = GST_RPAD_GETFUNC (peerpad); } } } /* in any case we need to copy the eventfunc into the handler */ GST_RPAD_EVENTHANDLER (peerpad) = GST_RPAD_EVENTFUNC (peerpad); } /* if the element is DECOUPLED or outside the manager, we have to chain */ if (decoupled) { /* set the chain proxies */ if (GST_RPAD_DIRECTION (pad) == GST_PAD_SINK) { GST_DEBUG ("copying chain function into push proxy for %s:%s", GST_DEBUG_PAD_NAME (pad)); GST_RPAD_CHAINHANDLER (pad) = GST_RPAD_CHAINFUNC (pad); } else { GST_DEBUG ("copying get function into pull proxy for %s:%s", GST_DEBUG_PAD_NAME (pad)); GST_RPAD_GETHANDLER (pad) = GST_RPAD_GETFUNC (pad); } } /* otherwise we really are a cothread */ else { if (GST_RPAD_DIRECTION (pad) == GST_PAD_SINK) { GST_DEBUG ("setting cothreaded push proxy for sinkpad %s:%s", GST_DEBUG_PAD_NAME (pad)); GST_RPAD_CHAINHANDLER (pad) = GST_DEBUG_FUNCPTR (gst_basic_scheduler_chainhandler_proxy); GST_RPAD_EVENTHANDLER (pad) = GST_RPAD_EVENTFUNC (pad); } else { GST_DEBUG ("setting cothreaded pull proxy for srcpad %s:%s", GST_DEBUG_PAD_NAME (pad)); GST_RPAD_GETHANDLER (pad) = GST_DEBUG_FUNCPTR (gst_basic_scheduler_gethandler_proxy); /* the gethandler proxy function can queue a buffer in the bufpen, we need * to remove this buffer when a flush event is sent on the pad */ GST_RPAD_EVENTHANDLER (pad) = GST_DEBUG_FUNCPTR (gst_basic_scheduler_eventhandler_proxy); } } } /* need to set up the cothread now */ if (wrapper_function != NULL) { if (GST_ELEMENT_THREADSTATE (element) == NULL) { GST_DEBUG ("about to create a cothread, wrapper for '%s' is &%s", GST_ELEMENT_NAME (element), GST_DEBUG_FUNCPTR_NAME (wrapper_function)); do_cothread_create (GST_ELEMENT_THREADSTATE (element), chain->sched->context, wrapper_function, 0, (char **) element); if (GST_ELEMENT_THREADSTATE (element) == NULL) { gst_element_error (element, "could not create cothread for \"%s\"", GST_ELEMENT_NAME (element), NULL); return FALSE; } GST_DEBUG ("created cothread %p for '%s'", GST_ELEMENT_THREADSTATE (element), GST_ELEMENT_NAME (element)); } else { /* set the cothread wrapper function */ GST_DEBUG ("about to set the wrapper function for '%s' to &%s", GST_ELEMENT_NAME (element), GST_DEBUG_FUNCPTR_NAME (wrapper_function)); do_cothread_setfunc (GST_ELEMENT_THREADSTATE (element), chain->sched->context, wrapper_function, 0, (char **) element); GST_DEBUG ("set wrapper function for '%s' to &%s", GST_ELEMENT_NAME (element), GST_DEBUG_FUNCPTR_NAME (wrapper_function)); } } } return TRUE; } static GstSchedulerChain * gst_basic_scheduler_chain_new (GstBasicScheduler * sched) { GstSchedulerChain *chain = g_new (GstSchedulerChain, 1); /* initialize the chain with sane values */ chain->sched = sched; chain->disabled = NULL; chain->elements = NULL; chain->num_elements = 0; chain->entry = NULL; chain->cothreaded_elements = 0; chain->schedule = FALSE; /* add the chain to the schedulers' list of chains */ sched->chains = g_list_prepend (sched->chains, chain); sched->num_chains++; /* notify the scheduler that something changed */ GST_FLAG_SET(sched, GST_BASIC_SCHEDULER_CHANGE); GST_INFO ("created new chain %p, now are %d chains in sched %p", chain, sched->num_chains, sched); return chain; } static void gst_basic_scheduler_chain_destroy (GstSchedulerChain * chain) { GstBasicScheduler *sched = chain->sched; /* remove the chain from the schedulers' list of chains */ sched->chains = g_list_remove (sched->chains, chain); sched->num_chains--; /* destroy the chain */ g_list_free (chain->disabled); /* should be empty... */ g_list_free (chain->elements); /* ditto */ GST_INFO ("destroyed chain %p, now are %d chains in sched %p", chain, sched->num_chains, sched); g_free (chain); /* notify the scheduler that something changed */ GST_FLAG_SET(sched, GST_BASIC_SCHEDULER_CHANGE); } static void gst_basic_scheduler_chain_add_element (GstSchedulerChain * chain, GstElement * element) { /* set the sched pointer for the element */ element->sched = GST_SCHEDULER (chain->sched); /* add the element to either the main list or the disabled list */ if (GST_STATE(element) == GST_STATE_PLAYING) { GST_INFO ("adding element \"%s\" to chain %p enabled", GST_ELEMENT_NAME (element),chain); chain->elements = g_list_prepend (chain->elements, element); } else { GST_INFO ("adding element \"%s\" to chain %p disabled", GST_ELEMENT_NAME (element),chain); chain->disabled = g_list_prepend (chain->disabled, element); } chain->num_elements++; /* notify the scheduler that something changed */ GST_FLAG_SET(chain->sched, GST_BASIC_SCHEDULER_CHANGE); } static gboolean gst_basic_scheduler_chain_enable_element (GstSchedulerChain * chain, GstElement * element) { GST_INFO ("enabling element \"%s\" in chain %p", GST_ELEMENT_NAME (element), chain); /* remove from disabled list */ chain->disabled = g_list_remove (chain->disabled, element); /* add to elements list */ chain->elements = g_list_prepend (chain->elements, element); /* notify the scheduler that something changed */ GST_FLAG_SET(chain->sched, GST_BASIC_SCHEDULER_CHANGE); /* GST_FLAG_UNSET(element, GST_ELEMENT_COTHREAD_STOPPING); */ /* reschedule the chain */ return gst_basic_scheduler_cothreaded_chain (GST_BIN (GST_SCHEDULER (chain->sched)->parent), chain); } static void gst_basic_scheduler_chain_disable_element (GstSchedulerChain * chain, GstElement * element) { GST_INFO ("disabling element \"%s\" in chain %p", GST_ELEMENT_NAME (element), chain); /* remove from elements list */ chain->elements = g_list_remove (chain->elements, element); /* add to disabled list */ chain->disabled = g_list_prepend (chain->disabled, element); /* notify the scheduler that something changed */ GST_FLAG_SET(chain->sched, GST_BASIC_SCHEDULER_CHANGE); GST_FLAG_SET(element, GST_ELEMENT_COTHREAD_STOPPING); /* reschedule the chain */ /* FIXME this should be done only if manager state != NULL */ /* gst_basic_scheduler_cothreaded_chain(GST_BIN(chain->sched->parent),chain); */ } static void gst_basic_scheduler_chain_remove_element (GstSchedulerChain * chain, GstElement * element) { GST_INFO ("removing element \"%s\" from chain %p", GST_ELEMENT_NAME (element), chain); /* if it's active, deactivate it */ if (g_list_find (chain->elements, element)) { gst_basic_scheduler_chain_disable_element (chain, element); } /* we have to check for a threadstate here because a queue doesn't have one */ if (GST_ELEMENT_THREADSTATE (element)) { do_cothread_destroy (GST_ELEMENT_THREADSTATE (element)); GST_ELEMENT_THREADSTATE (element) = NULL; } /* remove the element from the list of elements */ chain->disabled = g_list_remove (chain->disabled, element); chain->num_elements--; /* notify the scheduler that something changed */ GST_FLAG_SET(chain->sched, GST_BASIC_SCHEDULER_CHANGE); /* if there are no more elements in the chain, destroy the chain */ if (chain->num_elements == 0) gst_basic_scheduler_chain_destroy (chain); } static void gst_basic_scheduler_chain_elements (GstBasicScheduler * sched, GstElement * element1, GstElement * element2) { GList *chains; GstSchedulerChain *chain; GstSchedulerChain *chain1 = NULL, *chain2 = NULL; GstElement *element; /* first find the chains that hold the two */ chains = sched->chains; while (chains) { chain = (GstSchedulerChain *) (chains->data); chains = g_list_next (chains); if (g_list_find (chain->disabled, element1)) chain1 = chain; else if (g_list_find (chain->elements, element1)) chain1 = chain; if (g_list_find (chain->disabled, element2)) chain2 = chain; else if (g_list_find (chain->elements, element2)) chain2 = chain; } /* first check to see if they're in the same chain, we're done if that's the case */ if ((chain1 != NULL) && (chain1 == chain2)) { GST_INFO ("elements are already in the same chain"); return; } /* now, if neither element has a chain, create one */ if ((chain1 == NULL) && (chain2 == NULL)) { GST_INFO ("creating new chain to hold two new elements"); chain = gst_basic_scheduler_chain_new (sched); gst_basic_scheduler_chain_add_element (chain, element1); gst_basic_scheduler_chain_add_element (chain, element2); /* FIXME chain changed here */ /* gst_basic_scheduler_cothreaded_chain(chain->sched->parent,chain); */ /* otherwise if both have chains already, join them */ } else if ((chain1 != NULL) && (chain2 != NULL)) { GST_INFO ("merging chain %p into chain %p", chain2, chain1); /* take the contents of chain2 and merge them into chain1 */ chain1->disabled = g_list_concat (chain1->disabled, g_list_copy (chain2->disabled)); chain1->elements = g_list_concat (chain1->elements, g_list_copy (chain2->elements)); chain1->num_elements += chain2->num_elements; /* FIXME chain changed here */ /* gst_basic_scheduler_cothreaded_chain(chain->sched->parent,chain); */ gst_basic_scheduler_chain_destroy (chain2); /* otherwise one has a chain already, the other doesn't */ } else { /* pick out which one has the chain, and which doesn't */ if (chain1 != NULL) chain = chain1, element = element2; else chain = chain2, element = element1; GST_INFO ("adding element to existing chain"); gst_basic_scheduler_chain_add_element (chain, element); /* FIXME chain changed here */ /* gst_basic_scheduler_cothreaded_chain(chain->sched->parent,chain); */ } } /* find the chain within the scheduler that holds the element, if any */ static GstSchedulerChain * gst_basic_scheduler_find_chain (GstBasicScheduler * sched, GstElement * element) { GList *chains; GstSchedulerChain *chain; GST_INFO ("searching for element \"%s\" in chains", GST_ELEMENT_NAME (element)); chains = sched->chains; while (chains) { chain = (GstSchedulerChain *) (chains->data); chains = g_list_next (chains); if (g_list_find (chain->elements, element)) return chain; if (g_list_find (chain->disabled, element)) return chain; } return NULL; } static void gst_basic_scheduler_chain_recursive_add (GstSchedulerChain * chain, GstElement * element, gboolean remove) { GList *pads; GstPad *pad; GstElement *peerelement; GstSchedulerChain *prevchain; /* check to see if it's in a chain already */ prevchain = gst_basic_scheduler_find_chain (chain->sched, element); /* if it's already in another chain, either remove or punt */ if (prevchain != NULL) { if (remove == TRUE) gst_basic_scheduler_chain_remove_element (prevchain, element); else return; } /* add it to this one */ gst_basic_scheduler_chain_add_element (chain, element); GST_DEBUG ("recursing on element \"%s\"", GST_ELEMENT_NAME (element)); /* now go through all the pads and see which peers can be added */ pads = element->pads; while (pads) { pad = GST_PAD (pads->data); pads = g_list_next (pads); GST_DEBUG ("have pad %s:%s, checking for valid peer", GST_DEBUG_PAD_NAME (pad)); /* if the peer exists and could be in the same chain */ if (GST_PAD_PEER (pad)) { GST_DEBUG ("has peer %s:%s", GST_DEBUG_PAD_NAME (GST_PAD_PEER (pad))); peerelement = GST_PAD_PARENT (GST_PAD_PEER (pad)); if (GST_ELEMENT_SCHED (GST_PAD_PARENT (pad)) == GST_ELEMENT_SCHED (peerelement)) { GST_DEBUG ("peer \"%s\" is valid for same chain", GST_ELEMENT_NAME (peerelement)); gst_basic_scheduler_chain_recursive_add (chain, peerelement, remove); } } } } /* * Entry points for this scheduler. */ static void gst_basic_scheduler_setup (GstScheduler *sched) { /* first create thread context */ if (GST_BASIC_SCHEDULER_CAST (sched)->context == NULL) { GST_DEBUG ("initializing cothread context"); GST_BASIC_SCHEDULER_CAST (sched)->context = do_cothread_context_init (); } } static void gst_basic_scheduler_reset (GstScheduler *sched) { cothread_context *ctx; GList *elements = GST_BASIC_SCHEDULER_CAST (sched)->elements; while (elements) { GstElement *element = GST_ELEMENT (elements->data); if (GST_ELEMENT_THREADSTATE (element)) { do_cothread_destroy (GST_ELEMENT_THREADSTATE (element)); GST_ELEMENT_THREADSTATE (element) = NULL; } elements = g_list_next (elements); } ctx = GST_BASIC_SCHEDULER_CAST (sched)->context; do_cothread_context_destroy (ctx); GST_BASIC_SCHEDULER_CAST (sched)->context = NULL; } static void gst_basic_scheduler_add_element (GstScheduler * sched, GstElement * element) { GstSchedulerChain *chain; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); GST_INFO ("adding element \"%s\" to scheduler", GST_ELEMENT_NAME (element)); /* only deal with elements after this point, not bins */ /* exception is made for Bin's that are schedulable, like the autoplugger */ if (GST_IS_BIN (element) && !GST_FLAG_IS_SET (element, GST_BIN_SELF_SCHEDULABLE)) return; /* first add it to the list of elements that are to be scheduled */ bsched->elements = g_list_prepend (bsched->elements, element); bsched->num_elements++; /* create a chain to hold it, and add */ chain = gst_basic_scheduler_chain_new (bsched); gst_basic_scheduler_chain_add_element (chain, element); } static void gst_basic_scheduler_remove_element (GstScheduler * sched, GstElement * element) { GstSchedulerChain *chain; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); if (g_list_find (bsched->elements, element)) { GST_INFO ("removing element \"%s\" from scheduler", GST_ELEMENT_NAME (element)); /* if we are removing the currently scheduled element */ if (bsched->current == element) { GST_FLAG_SET(element, GST_ELEMENT_COTHREAD_STOPPING); if (element->post_run_func) element->post_run_func (element); bsched->current = NULL; } /* find what chain the element is in */ chain = gst_basic_scheduler_find_chain (bsched, element); /* remove it from its chain */ if (chain != NULL) { gst_basic_scheduler_chain_remove_element (chain, element); } /* remove it from the list of elements */ bsched->elements = g_list_remove (bsched->elements, element); bsched->num_elements--; /* unset the scheduler pointer in the element */ } } static GstElementStateReturn gst_basic_scheduler_state_transition (GstScheduler *sched, GstElement *element, gint transition) { GstSchedulerChain *chain; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); /* check if our parent changed state */ if (GST_SCHEDULER_PARENT (sched) == element) { GST_INFO ("parent \"%s\" changed state", GST_ELEMENT_NAME (element)); if (transition == GST_STATE_PLAYING_TO_PAUSED) { GST_INFO ("setting scheduler state to stopped"); GST_SCHEDULER_STATE (sched) = GST_SCHEDULER_STATE_STOPPED; } else if (transition == GST_STATE_PAUSED_TO_PLAYING) { GST_INFO ("setting scheduler state to running"); GST_SCHEDULER_STATE (sched) = GST_SCHEDULER_STATE_RUNNING; } else { GST_INFO ("no interesting state change, doing nothing"); } } else if (transition == GST_STATE_PLAYING_TO_PAUSED || transition == GST_STATE_PAUSED_TO_PLAYING) { /* find the chain the element is in */ chain = gst_basic_scheduler_find_chain (bsched, element); /* remove it from the chain */ if (chain) { if (transition == GST_STATE_PLAYING_TO_PAUSED) { gst_basic_scheduler_chain_disable_element (chain, element); } else if (transition == GST_STATE_PAUSED_TO_PLAYING) { if (!gst_basic_scheduler_chain_enable_element (chain, element)) { GST_INFO ("could not enable element \"%s\"", GST_ELEMENT_NAME (element)); return GST_STATE_FAILURE; } } } else { GST_INFO ("element \"%s\" not found in any chain, no state change", GST_ELEMENT_NAME (element)); } } return GST_STATE_SUCCESS; } static void gst_basic_scheduler_lock_element (GstScheduler * sched, GstElement * element) { if (GST_ELEMENT_THREADSTATE (element)) do_cothread_lock (GST_ELEMENT_THREADSTATE (element)); } static void gst_basic_scheduler_unlock_element (GstScheduler * sched, GstElement * element) { if (GST_ELEMENT_THREADSTATE (element)) do_cothread_unlock (GST_ELEMENT_THREADSTATE (element)); } static gboolean gst_basic_scheduler_yield (GstScheduler *sched, GstElement *element) { if (GST_ELEMENT_IS_COTHREAD_STOPPING (element)) { do_switch_to_main (sched); /* no need to do a pre_run, the cothread is stopping */ } return FALSE; } static gboolean gst_basic_scheduler_interrupt (GstScheduler *sched, GstElement *element) { GST_FLAG_SET (element, GST_ELEMENT_COTHREAD_STOPPING); do_switch_to_main (sched); return FALSE; } static void gst_basic_scheduler_error (GstScheduler *sched, GstElement *element) { GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); if (GST_ELEMENT_THREADSTATE (element)) { GstSchedulerChain *chain; chain = gst_basic_scheduler_find_chain (bsched, element); if (chain) gst_basic_scheduler_chain_disable_element (chain, element); GST_SCHEDULER_STATE (sched) = GST_SCHEDULER_STATE_ERROR; do_switch_to_main (sched); } } static void gst_basic_scheduler_pad_link (GstScheduler * sched, GstPad *srcpad, GstPad *sinkpad) { GstElement *srcelement, *sinkelement; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); srcelement = GST_PAD_PARENT (srcpad); g_return_if_fail (srcelement != NULL); sinkelement = GST_PAD_PARENT (sinkpad); g_return_if_fail (sinkelement != NULL); GST_INFO ("have pad linked callback on %s:%s to %s:%s", GST_DEBUG_PAD_NAME (srcpad), GST_DEBUG_PAD_NAME (sinkpad)); GST_DEBUG ("srcpad sched is %p, sinkpad sched is %p", GST_ELEMENT_SCHED (srcelement), GST_ELEMENT_SCHED (sinkelement)); if (GST_ELEMENT_SCHED (srcelement) == GST_ELEMENT_SCHED (sinkelement)) { GST_INFO ("peer %s:%s is in same scheduler, chaining together", GST_DEBUG_PAD_NAME (sinkpad)); gst_basic_scheduler_chain_elements (bsched, srcelement, sinkelement); } } static void gst_basic_scheduler_pad_unlink (GstScheduler * sched, GstPad * srcpad, GstPad * sinkpad) { GstElement *element1, *element2; GstSchedulerChain *chain1, *chain2; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); GST_INFO ("unlinking pads %s:%s and %s:%s", GST_DEBUG_PAD_NAME (srcpad), GST_DEBUG_PAD_NAME (sinkpad)); /* we need to have the parent elements of each pad */ element1 = GST_ELEMENT_CAST (GST_PAD_PARENT (srcpad)); element2 = GST_ELEMENT_CAST (GST_PAD_PARENT (sinkpad)); /* first task is to remove the old chain they belonged to. * this can be accomplished by taking either of the elements, * since they are guaranteed to be in the same chain * FIXME is it potentially better to make an attempt at splitting cleaner?? */ chain1 = gst_basic_scheduler_find_chain (bsched, element1); chain2 = gst_basic_scheduler_find_chain (bsched, element2); /* FIXME: The old code still works in most cases, but does not deal with * the problem of screwed up sched chains in some autoplugging cases. * The new code has an infinite recursion bug during pipeline shutdown, * which must be fixed before it can be enabled again. */ #if 1 if (chain1 != chain2) { /* elements not in the same chain don't need to be separated */ GST_INFO ("elements not in the same chain"); return; } if (chain1) { GST_INFO ("destroying chain"); gst_basic_scheduler_chain_destroy (chain1); /* now create a new chain to hold element1 and build it from scratch */ chain1 = gst_basic_scheduler_chain_new (bsched); gst_basic_scheduler_chain_recursive_add (chain1, element1, FALSE); } /* check the other element to see if it landed in the newly created chain */ if (gst_basic_scheduler_find_chain (bsched, element2) == NULL) { /* if not in chain, create chain and build from scratch */ chain2 = gst_basic_scheduler_chain_new (bsched); gst_basic_scheduler_chain_recursive_add (chain2, element2, FALSE); } #else /* if they're both in the same chain, move second set of elements to a new chain */ if (chain1 && (chain1 == chain2)) { GST_INFO ("creating new chain for second element and peers"); chain2 = gst_basic_scheduler_chain_new (bsched); gst_basic_scheduler_chain_recursive_add (chain2, element2, TRUE); } #endif } static void gst_basic_scheduler_pad_select (GstScheduler * sched, GList * padlist) { GstPad *pad = NULL; GList *padlist2 = padlist; GST_INFO ("performing select"); while (padlist2) { pad = GST_PAD (padlist2->data); padlist2 = g_list_next (padlist2); } /* else there is nothing ready to consume, set up the select functions */ while (padlist) { pad = GST_PAD (padlist->data); GST_RPAD_CHAINHANDLER (pad) = GST_DEBUG_FUNCPTR (gst_basic_scheduler_select_proxy); padlist = g_list_next (padlist); } if (pad != NULL) { GstRealPad *peer = GST_RPAD_PEER (pad); do_element_switch (GST_PAD_PARENT (peer)); /* FIXME disabled for now */ /* pad = GST_ELEMENT (GST_PAD_PARENT (pad))->select_pad;*/ g_assert (pad != NULL); } } static GstClockReturn gst_basic_scheduler_clock_wait (GstScheduler *sched, GstElement *element, GstClockID id, GstClockTimeDiff *jitter) { return gst_clock_id_wait (id, jitter); } static GstSchedulerState gst_basic_scheduler_iterate (GstScheduler * sched) { GList *chains; GstSchedulerChain *chain; GstElement *entry; GList *elements; gint scheduled = 0; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); GST_CAT_LOG_OBJECT (debug_dataflow, sched, "starting iteration in bin %s", GST_ELEMENT_NAME (sched->parent)); /* clear the changes flag */ GST_FLAG_UNSET(bsched, GST_BASIC_SCHEDULER_CHANGE); /* step through all the chains */ chains = bsched->chains; if (chains == NULL) return GST_SCHEDULER_STATE_STOPPED; while (chains) { chain = (GstSchedulerChain *) (chains->data); chains = g_list_next (chains); /* all we really have to do is switch to the first child */ /* FIXME this should be lots more intelligent about where to start */ GST_CAT_DEBUG (debug_dataflow, "starting iteration via cothreads using %s scheduler", _SCHEDULER_NAME); if (chain->elements) { entry = NULL; /*MattH ADDED?*/ GST_DEBUG ("there are %d elements in this chain", chain->num_elements); elements = chain->elements; while (elements) { entry = GST_ELEMENT_CAST (elements->data); elements = g_list_next (elements); if (GST_FLAG_IS_SET (entry, GST_ELEMENT_DECOUPLED)) { GST_DEBUG ("entry \"%s\" is DECOUPLED, skipping", GST_ELEMENT_NAME (entry)); entry = NULL; } else if (GST_FLAG_IS_SET (entry, GST_ELEMENT_INFINITE_LOOP)) { GST_DEBUG ("entry \"%s\" is not valid, skipping", GST_ELEMENT_NAME (entry)); entry = NULL; } else break; } if (entry) { GstSchedulerState state; GST_FLAG_SET (entry, GST_ELEMENT_COTHREAD_STOPPING); GST_CAT_DEBUG (debug_dataflow, "set COTHREAD_STOPPING flag on \"%s\"(@%p)", GST_ELEMENT_NAME (entry), entry); if (GST_ELEMENT_THREADSTATE (entry)) { do_switch_from_main (entry); state = GST_SCHEDULER_STATE (sched); /* if something changed, return - go on else */ if (GST_FLAG_IS_SET(bsched, GST_BASIC_SCHEDULER_CHANGE) && state != GST_SCHEDULER_STATE_ERROR) return GST_SCHEDULER_STATE_RUNNING; } else { GST_CAT_DEBUG (debug_dataflow, "cothread switch not possible, element has no threadstate"); return GST_SCHEDULER_STATE_ERROR; } /* following is a check to see if the chain was interrupted due to a * top-half state_change(). (i.e., if there's a pending state.) * * if it was, return to gstthread.c::gst_thread_main_loop() to * execute the state change. */ GST_CAT_DEBUG (debug_dataflow, "cothread switch ended or interrupted"); if (state != GST_SCHEDULER_STATE_RUNNING) { GST_CAT_INFO (debug_dataflow, "scheduler is not running, in state %d", state); return state; } scheduled++; } else { GST_CAT_INFO (debug_dataflow, "no entry in this chain, trying the next one"); } } else { GST_CAT_INFO (debug_dataflow, "no enabled elements in this chain, trying the next one"); } } GST_CAT_LOG_OBJECT (debug_dataflow, sched, "leaving (%s)", GST_ELEMENT_NAME (sched->parent)); if (scheduled == 0) { GST_CAT_INFO (debug_dataflow, "nothing was scheduled, return STOPPED"); return GST_SCHEDULER_STATE_STOPPED; } else { GST_CAT_INFO (debug_dataflow, "scheduler still running, return RUNNING"); return GST_SCHEDULER_STATE_RUNNING; } } static void gst_basic_scheduler_show (GstScheduler * sched) { GList *chains, *elements; GstElement *element; GstSchedulerChain *chain; GstBasicScheduler *bsched = GST_BASIC_SCHEDULER (sched); if (sched == NULL) { g_print ("scheduler doesn't exist for this element\n"); return; } g_return_if_fail (GST_IS_SCHEDULER (sched)); g_print ("SCHEDULER DUMP FOR MANAGING BIN \"%s\"\n", GST_ELEMENT_NAME (sched->parent)); g_print ("scheduler has %d elements in it: ", bsched->num_elements); elements = bsched->elements; while (elements) { element = GST_ELEMENT (elements->data); elements = g_list_next (elements); g_print ("%s, ", GST_ELEMENT_NAME (element)); } g_print ("\n"); g_print ("scheduler has %d chains in it\n", bsched->num_chains); chains = bsched->chains; while (chains) { chain = (GstSchedulerChain *) (chains->data); chains = g_list_next (chains); g_print ("%p: ", chain); elements = chain->disabled; while (elements) { element = GST_ELEMENT (elements->data); elements = g_list_next (elements); g_print ("!%s, ", GST_ELEMENT_NAME (element)); } elements = chain->elements; while (elements) { element = GST_ELEMENT (elements->data); elements = g_list_next (elements); g_print ("%s, ", GST_ELEMENT_NAME (element)); } g_print ("\n"); } }