gstreamer/gst/schedulers/gstoptimalscheduler.c
Johan Dahlin 5c403b9abe gst/schedulers/gstoptimalscheduler.c
Original commit message from CVS:
* gst/schedulers/gstoptimalscheduler.c
(gst_opt_scheduler_pad_unlink): Remove double ;, spotted by Scott Wheeler
2004-03-16 09:53:16 +00:00

2408 lines
72 KiB
C

/* GStreamer
* Copyright (C) 1999,2000 Erik Walthinsen <omega@cse.ogi.edu>
* 2000 Wim Taymans <wtay@chello.be>
*
* 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 <gst/gst.h>
GST_DEBUG_CATEGORY_STATIC (debug_scheduler);
#define GST_CAT_DEFAULT debug_scheduler
#ifdef USE_COTHREADS
# include "cothreads_compat.h"
#else
# define COTHREADS_NAME_CAPITAL ""
# define COTHREADS_NAME ""
#endif
#define GST_ELEMENT_SCHED_CONTEXT(elem) ((GstOptSchedulerCtx*) (GST_ELEMENT (elem)->sched_private))
#define GST_ELEMENT_SCHED_GROUP(elem) (GST_ELEMENT_SCHED_CONTEXT (elem)->group)
#define GST_PAD_BUFLIST(pad) ((GList*) (GST_REAL_PAD(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)
#define GST_ELEMENT_INTERRUPTED GST_ELEMENT_SCHEDULER_PRIVATE2
#define GST_ELEMENT_IS_INTERRUPTED(element) GST_FLAG_IS_SET((element), GST_ELEMENT_INTERRUPTED)
typedef struct _GstOptScheduler GstOptScheduler;
typedef struct _GstOptSchedulerClass GstOptSchedulerClass;
#define GST_TYPE_OPT_SCHEDULER \
(gst_opt_scheduler_get_type())
#define GST_OPT_SCHEDULER(obj) \
(G_TYPE_CHECK_INSTANCE_CAST((obj),GST_TYPE_OPT_SCHEDULER,GstOptScheduler))
#define GST_OPT_SCHEDULER_CLASS(klass) \
(G_TYPE_CHECK_CLASS_CAST((klass),GST_TYPE_OPT_SCHEDULER,GstOptSchedulerClass))
#define GST_IS_OPT_SCHEDULER(obj) \
(G_TYPE_CHECK_INSTANCE_TYPE((obj),GST_TYPE_OPT_SCHEDULER))
#define GST_IS_OPT_SCHEDULER_CLASS(obj) \
(G_TYPE_CHECK_CLASS_TYPE((klass),GST_TYPE_OPT_SCHEDULER))
typedef enum
{
GST_OPT_SCHEDULER_STATE_NONE,
GST_OPT_SCHEDULER_STATE_STOPPED,
GST_OPT_SCHEDULER_STATE_ERROR,
GST_OPT_SCHEDULER_STATE_RUNNING,
GST_OPT_SCHEDULER_STATE_INTERRUPTED
}
GstOptSchedulerState;
struct _GstOptScheduler
{
GstScheduler parent;
GstOptSchedulerState state;
#ifdef USE_COTHREADS
cothread_context *context;
#endif
gint iterations;
GSList *elements;
GSList *chains;
GList *runqueue;
gint recursion;
gint max_recursion;
};
struct _GstOptSchedulerClass
{
GstSchedulerClass parent_class;
};
static GType _gst_opt_scheduler_type = 0;
typedef enum
{
GST_OPT_SCHEDULER_CHAIN_DIRTY = (1 << 1),
GST_OPT_SCHEDULER_CHAIN_DISABLED = (1 << 2),
GST_OPT_SCHEDULER_CHAIN_RUNNING = (1 << 3),
}
GstOptSchedulerChainFlags;
#define GST_OPT_SCHEDULER_CHAIN_DISABLE(chain) ((chain)->flags |= GST_OPT_SCHEDULER_CHAIN_DISABLED)
#define GST_OPT_SCHEDULER_CHAIN_ENABLE(chain) ((chain)->flags &= ~GST_OPT_SCHEDULER_CHAIN_DISABLED)
#define GST_OPT_SCHEDULER_CHAIN_IS_DISABLED(chain) ((chain)->flags & GST_OPT_SCHEDULER_CHAIN_DISABLED)
typedef struct _GstOptSchedulerChain GstOptSchedulerChain;
struct _GstOptSchedulerChain
{
gint refcount;
GstOptScheduler *sched;
GstOptSchedulerChainFlags flags;
GSList *groups; /* the groups in this chain */
gint num_groups;
gint num_enabled;
};
/*
* elements that are scheduled in one cothread
*/
typedef enum
{
GST_OPT_SCHEDULER_GROUP_DIRTY = (1 << 1), /* this group has been modified */
GST_OPT_SCHEDULER_GROUP_COTHREAD_STOPPING = (1 << 2), /* the group's cothread stops after one iteration */
GST_OPT_SCHEDULER_GROUP_DISABLED = (1 << 3), /* this group is disabled */
GST_OPT_SCHEDULER_GROUP_RUNNING = (1 << 4), /* this group is running */
GST_OPT_SCHEDULER_GROUP_SCHEDULABLE = (1 << 5), /* this group is schedulable */
GST_OPT_SCHEDULER_GROUP_VISITED = (1 << 6), /* this group is visited when finding links */
}
GstOptSchedulerGroupFlags;
typedef enum
{
GST_OPT_SCHEDULER_GROUP_GET = 1,
GST_OPT_SCHEDULER_GROUP_LOOP = 2,
}
GstOptSchedulerGroupType;
#define GST_OPT_SCHEDULER_GROUP_SET_FLAG(group,flag) ((group)->flags |= (flag))
#define GST_OPT_SCHEDULER_GROUP_UNSET_FLAG(group,flag) ((group)->flags &= ~(flag))
#define GST_OPT_SCHEDULER_GROUP_IS_FLAG_SET(group,flag) ((group)->flags & (flag))
#define GST_OPT_SCHEDULER_GROUP_DISABLE(group) ((group)->flags |= GST_OPT_SCHEDULER_GROUP_DISABLED)
#define GST_OPT_SCHEDULER_GROUP_ENABLE(group) ((group)->flags &= ~GST_OPT_SCHEDULER_GROUP_DISABLED)
#define GST_OPT_SCHEDULER_GROUP_IS_ENABLED(group) (!((group)->flags & GST_OPT_SCHEDULER_GROUP_DISABLED))
#define GST_OPT_SCHEDULER_GROUP_IS_DISABLED(group) ((group)->flags & GST_OPT_SCHEDULER_GROUP_DISABLED)
typedef struct _GstOptSchedulerGroup GstOptSchedulerGroup;
typedef struct _GstOptSchedulerGroupLink GstOptSchedulerGroupLink;
/* used to keep track of links with other groups */
struct _GstOptSchedulerGroupLink
{
GstOptSchedulerGroup *group1; /* the group we are linked with */
GstOptSchedulerGroup *group2; /* the group we are linked with */
gint count; /* the number of links with the group */
};
#define IS_GROUP_LINK(link, group1, group2) ((link->group1 == group1 && link->group2 == group2) || \
(link->group2 == group1 && link->group1 == group2))
#define OTHER_GROUP_LINK(link, group) (link->group1 == group ? link->group2 : link->group1)
typedef int (*GroupScheduleFunction) (int argc, char *argv[]);
struct _GstOptSchedulerGroup
{
GstOptSchedulerChain *chain; /* the chain this group belongs to */
GstOptSchedulerGroupFlags flags; /* flags for this group */
GstOptSchedulerGroupType type; /* flags for this group */
gint refcount;
GSList *elements; /* elements of this group */
gint num_elements;
gint num_enabled;
GstElement *entry; /* the group's entry point */
GSList *group_links; /* other groups that are linked with this group */
#ifdef USE_COTHREADS
cothread *cothread; /* the cothread of this group */
#else
GroupScheduleFunction schedulefunc;
#endif
int argc;
char **argv;
};
/*
* A group is a set of elements through which data can flow without switching
* cothreads or without invoking the scheduler's run queue.
*/
static GstOptSchedulerGroup *ref_group (GstOptSchedulerGroup * group);
static GstOptSchedulerGroup *unref_group (GstOptSchedulerGroup * group);
static GstOptSchedulerGroup *create_group (GstOptSchedulerChain * chain,
GstElement * element, GstOptSchedulerGroupType type);
static void destroy_group (GstOptSchedulerGroup * group);
static GstOptSchedulerGroup *add_to_group (GstOptSchedulerGroup * group,
GstElement * element);
static GstOptSchedulerGroup *remove_from_group (GstOptSchedulerGroup * group,
GstElement * element);
static GstOptSchedulerGroup *merge_groups (GstOptSchedulerGroup * group1,
GstOptSchedulerGroup * group2);
static void setup_group_scheduler (GstOptScheduler * osched,
GstOptSchedulerGroup * group);
static void destroy_group_scheduler (GstOptSchedulerGroup * group);
static void group_error_handler (GstOptSchedulerGroup * group);
static void group_element_set_enabled (GstOptSchedulerGroup * group,
GstElement * element, gboolean enabled);
static gboolean schedule_group (GstOptSchedulerGroup * group);
/*
* A chain is a set of groups that are linked to each other.
*/
static void destroy_chain (GstOptSchedulerChain * chain);
static GstOptSchedulerChain *create_chain (GstOptScheduler * osched);
static GstOptSchedulerChain *ref_chain (GstOptSchedulerChain * chain);
static GstOptSchedulerChain *unref_chain (GstOptSchedulerChain * chain);
static GstOptSchedulerChain *add_to_chain (GstOptSchedulerChain * chain,
GstOptSchedulerGroup * group);
static GstOptSchedulerChain *remove_from_chain (GstOptSchedulerChain * chain,
GstOptSchedulerGroup * group);
static GstOptSchedulerChain *merge_chains (GstOptSchedulerChain * chain1,
GstOptSchedulerChain * chain2);
static void chain_recursively_migrate_group (GstOptSchedulerChain * chain,
GstOptSchedulerGroup * group);
static void chain_group_set_enabled (GstOptSchedulerChain * chain,
GstOptSchedulerGroup * group, gboolean enabled);
static void schedule_chain (GstOptSchedulerChain * chain);
/*
* The schedule functions are the entry points for cothreads, or called directly
* by gst_opt_scheduler_schedule_run_queue
*/
static int get_group_schedule_function (int argc, char *argv[]);
static int loop_group_schedule_function (int argc, char *argv[]);
static int unknown_group_schedule_function (int argc, char *argv[]);
/*
* These wrappers are set on the pads as the chain handler (what happens when
* gst_pad_push is called) or get handler (for gst_pad_pull).
*/
static void gst_opt_scheduler_loop_wrapper (GstPad * sinkpad, GstData * data);
static GstData *gst_opt_scheduler_get_wrapper (GstPad * srcpad);
static void gst_opt_scheduler_chain_wrapper (GstPad * sinkpad, GstData * data);
/*
* Without cothreads, gst_pad_push or gst_pad_pull on a loop-based group will
* just queue the peer element on a list. We need to actually run the queue
* instead of relying on cothreads to do the switch for us.
*/
#ifndef USE_COTHREADS
static void gst_opt_scheduler_schedule_run_queue (GstOptScheduler * osched);
#endif
/*
* Scheduler private data for an element
*/
typedef struct _GstOptSchedulerCtx GstOptSchedulerCtx;
typedef enum
{
GST_OPT_SCHEDULER_CTX_DISABLED = (1 << 1), /* the element is disabled */
}
GstOptSchedulerCtxFlags;
struct _GstOptSchedulerCtx
{
GstOptSchedulerGroup *group; /* the group this element belongs to */
GstOptSchedulerCtxFlags flags; /* flags for this element */
};
/*
* Implementation of GstScheduler
*/
enum
{
ARG_0,
ARG_ITERATIONS,
ARG_MAX_RECURSION,
};
static void gst_opt_scheduler_class_init (GstOptSchedulerClass * klass);
static void gst_opt_scheduler_init (GstOptScheduler * scheduler);
static void gst_opt_scheduler_set_property (GObject * object, guint prop_id,
const GValue * value, GParamSpec * pspec);
static void gst_opt_scheduler_get_property (GObject * object, guint prop_id,
GValue * value, GParamSpec * pspec);
static void gst_opt_scheduler_dispose (GObject * object);
static void gst_opt_scheduler_setup (GstScheduler * sched);
static void gst_opt_scheduler_reset (GstScheduler * sched);
static void gst_opt_scheduler_add_element (GstScheduler * sched,
GstElement * element);
static void gst_opt_scheduler_remove_element (GstScheduler * sched,
GstElement * element);
static GstElementStateReturn gst_opt_scheduler_state_transition (GstScheduler *
sched, GstElement * element, gint transition);
static void gst_opt_scheduler_scheduling_change (GstScheduler * sched,
GstElement * element);
static void gst_opt_scheduler_lock_element (GstScheduler * sched,
GstElement * element);
static void gst_opt_scheduler_unlock_element (GstScheduler * sched,
GstElement * element);
static gboolean gst_opt_scheduler_yield (GstScheduler * sched,
GstElement * element);
static gboolean gst_opt_scheduler_interrupt (GstScheduler * sched,
GstElement * element);
static void gst_opt_scheduler_error (GstScheduler * sched,
GstElement * element);
static void gst_opt_scheduler_pad_link (GstScheduler * sched, GstPad * srcpad,
GstPad * sinkpad);
static void gst_opt_scheduler_pad_unlink (GstScheduler * sched, GstPad * srcpad,
GstPad * sinkpad);
static void gst_opt_scheduler_pad_select (GstScheduler * sched,
GList * padlist);
static GstSchedulerState gst_opt_scheduler_iterate (GstScheduler * sched);
static void gst_opt_scheduler_show (GstScheduler * sched);
static GstSchedulerClass *parent_class = NULL;
static GType
gst_opt_scheduler_get_type (void)
{
if (!_gst_opt_scheduler_type) {
static const GTypeInfo scheduler_info = {
sizeof (GstOptSchedulerClass),
NULL,
NULL,
(GClassInitFunc) gst_opt_scheduler_class_init,
NULL,
NULL,
sizeof (GstOptScheduler),
0,
(GInstanceInitFunc) gst_opt_scheduler_init,
NULL
};
_gst_opt_scheduler_type = g_type_register_static (GST_TYPE_SCHEDULER,
"GstOpt" COTHREADS_NAME_CAPITAL "Scheduler", &scheduler_info, 0);
}
return _gst_opt_scheduler_type;
}
static void
gst_opt_scheduler_class_init (GstOptSchedulerClass * 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->set_property =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_set_property);
gobject_class->get_property =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_get_property);
gobject_class->dispose = GST_DEBUG_FUNCPTR (gst_opt_scheduler_dispose);
g_object_class_install_property (G_OBJECT_CLASS (klass), ARG_ITERATIONS,
g_param_spec_int ("iterations", "Iterations",
"Number of groups to schedule in one iteration (-1 == until EOS/error)",
-1, G_MAXINT, 1, G_PARAM_READWRITE));
#ifndef USE_COTHREADS
g_object_class_install_property (G_OBJECT_CLASS (klass), ARG_MAX_RECURSION,
g_param_spec_int ("max_recursion", "Max recursion",
"Maximum number of recursions", 1, G_MAXINT, 100, G_PARAM_READWRITE));
#endif
gstscheduler_class->setup = GST_DEBUG_FUNCPTR (gst_opt_scheduler_setup);
gstscheduler_class->reset = GST_DEBUG_FUNCPTR (gst_opt_scheduler_reset);
gstscheduler_class->add_element =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_add_element);
gstscheduler_class->remove_element =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_remove_element);
gstscheduler_class->state_transition =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_state_transition);
gstscheduler_class->scheduling_change =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_scheduling_change);
gstscheduler_class->lock_element =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_lock_element);
gstscheduler_class->unlock_element =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_unlock_element);
gstscheduler_class->yield = GST_DEBUG_FUNCPTR (gst_opt_scheduler_yield);
gstscheduler_class->interrupt =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_interrupt);
gstscheduler_class->error = GST_DEBUG_FUNCPTR (gst_opt_scheduler_error);
gstscheduler_class->pad_link = GST_DEBUG_FUNCPTR (gst_opt_scheduler_pad_link);
gstscheduler_class->pad_unlink =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_pad_unlink);
gstscheduler_class->pad_select =
GST_DEBUG_FUNCPTR (gst_opt_scheduler_pad_select);
gstscheduler_class->clock_wait = NULL;
gstscheduler_class->iterate = GST_DEBUG_FUNCPTR (gst_opt_scheduler_iterate);
gstscheduler_class->show = GST_DEBUG_FUNCPTR (gst_opt_scheduler_show);
#ifdef USE_COTHREADS
do_cothreads_init (NULL);
#endif
}
static void
gst_opt_scheduler_init (GstOptScheduler * scheduler)
{
scheduler->elements = NULL;
scheduler->iterations = 1;
scheduler->max_recursion = 100;
}
static void
gst_opt_scheduler_dispose (GObject * object)
{
G_OBJECT_CLASS (parent_class)->dispose (object);
}
static gboolean
plugin_init (GstPlugin * plugin)
{
GstSchedulerFactory *factory;
GST_DEBUG_CATEGORY_INIT (debug_scheduler, "scheduler", 0,
"optimal scheduler");
#ifdef USE_COTHREADS
factory = gst_scheduler_factory_new ("opt" COTHREADS_NAME,
"An optimal scheduler using " COTHREADS_NAME " cothreads",
gst_opt_scheduler_get_type ());
#else
factory = gst_scheduler_factory_new ("opt",
"An optimal scheduler using no cothreads", gst_opt_scheduler_get_type ());
#endif
if (factory != NULL) {
gst_plugin_add_feature (plugin, GST_PLUGIN_FEATURE (factory));
} else {
g_warning ("could not register scheduler: optimal");
}
return TRUE;
}
GST_PLUGIN_DEFINE (GST_VERSION_MAJOR,
GST_VERSION_MINOR,
"gstopt" COTHREADS_NAME "scheduler",
"An optimal scheduler using " COTHREADS_NAME " cothreads",
plugin_init, VERSION, GST_LICENSE, GST_PACKAGE, GST_ORIGIN);
static GstOptSchedulerChain *
ref_chain (GstOptSchedulerChain * chain)
{
GST_LOG ("ref chain %p %d->%d", chain, chain->refcount, chain->refcount + 1);
chain->refcount++;
return chain;
}
static GstOptSchedulerChain *
unref_chain (GstOptSchedulerChain * chain)
{
GST_LOG ("unref chain %p %d->%d", chain,
chain->refcount, chain->refcount - 1);
if (--chain->refcount == 0) {
destroy_chain (chain);
chain = NULL;
}
return chain;
}
static GstOptSchedulerChain *
create_chain (GstOptScheduler * osched)
{
GstOptSchedulerChain *chain;
chain = g_new0 (GstOptSchedulerChain, 1);
chain->sched = osched;
chain->refcount = 1;
chain->flags = GST_OPT_SCHEDULER_CHAIN_DISABLED;
gst_object_ref (GST_OBJECT (osched));
osched->chains = g_slist_prepend (osched->chains, chain);
GST_LOG ("new chain %p", chain);
return chain;
}
static void
destroy_chain (GstOptSchedulerChain * chain)
{
GstOptScheduler *osched;
GST_LOG ("destroy chain %p", chain);
g_assert (chain->num_groups == 0);
g_assert (chain->groups == NULL);
osched = chain->sched;
osched->chains = g_slist_remove (osched->chains, chain);
gst_object_unref (GST_OBJECT (osched));
g_free (chain);
}
static GstOptSchedulerChain *
add_to_chain (GstOptSchedulerChain * chain, GstOptSchedulerGroup * group)
{
GST_LOG ("adding group %p to chain %p", group, chain);
g_assert (group->chain == NULL);
group = ref_group (group);
group->chain = ref_chain (chain);
/* The first non-disabled group in the chain's group list will be the entry
point for the chain. Because buffers can accumulate in loop elements' peer
bufpens, we preferentially schedule loop groups before get groups to avoid
unnecessary execution of get-based groups when the bufpens are already
full. */
if (group->type == GST_OPT_SCHEDULER_GROUP_LOOP)
chain->groups = g_slist_prepend (chain->groups, group);
else
chain->groups = g_slist_append (chain->groups, group);
chain->num_groups++;
if (GST_OPT_SCHEDULER_GROUP_IS_ENABLED (group)) {
chain_group_set_enabled (chain, group, TRUE);
}
return chain;
}
static GstOptSchedulerChain *
remove_from_chain (GstOptSchedulerChain * chain, GstOptSchedulerGroup * group)
{
GST_LOG ("removing group %p from chain %p", group, chain);
if (!chain)
return NULL;
g_assert (group);
g_assert (group->chain == chain);
group->chain = NULL;
chain->groups = g_slist_remove (chain->groups, group);
chain->num_groups--;
unref_group (group);
if (chain->num_groups == 0)
chain = unref_chain (chain);
chain = unref_chain (chain);
return chain;
}
static GstOptSchedulerChain *
merge_chains (GstOptSchedulerChain * chain1, GstOptSchedulerChain * chain2)
{
GSList *walk;
g_assert (chain1 != NULL);
GST_LOG ("merging chain %p and %p", chain1, chain2);
/* FIXME: document how chain2 can be NULL */
if (chain1 == chain2 || chain2 == NULL)
return chain1;
/* switch if it's more efficient */
if (chain1->num_groups < chain2->num_groups) {
GstOptSchedulerChain *tmp = chain2;
chain2 = chain1;
chain1 = tmp;
}
walk = chain2->groups;
while (walk) {
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) walk->data;
walk = g_slist_next (walk);
GST_LOG ("reparenting group %p from chain %p to %p", group, chain2, chain1);
ref_group (group);
remove_from_chain (chain2, group);
add_to_chain (chain1, group);
unref_group (group);
}
/* chain2 is now freed, if nothing else was referencing it before */
return chain1;
}
static void
chain_group_set_enabled (GstOptSchedulerChain * chain,
GstOptSchedulerGroup * group, gboolean enabled)
{
g_assert (group != NULL);
g_assert (chain != NULL);
GST_LOG
("request to %d group %p in chain %p, have %d groups enabled out of %d",
enabled, group, chain, chain->num_enabled, chain->num_groups);
if (enabled)
GST_OPT_SCHEDULER_GROUP_ENABLE (group);
else
GST_OPT_SCHEDULER_GROUP_DISABLE (group);
if (enabled) {
if (chain->num_enabled < chain->num_groups)
chain->num_enabled++;
GST_DEBUG ("enable group %p in chain %p, now %d groups enabled out of %d",
group, chain, chain->num_enabled, chain->num_groups);
/* OK to call even if the scheduler (cothread context / schedulerfunc) was
setup already -- will get destroyed when the group is destroyed */
setup_group_scheduler (chain->sched, group);
if (chain->num_enabled == chain->num_groups) {
GST_DEBUG ("enable chain %p", chain);
GST_OPT_SCHEDULER_CHAIN_ENABLE (chain);
}
} else {
if (chain->num_enabled > 0)
chain->num_enabled--;
GST_DEBUG ("disable group %p in chain %p, now %d groups enabled out of %d",
group, chain, chain->num_enabled, chain->num_groups);
if (chain->num_enabled == 0) {
GST_DEBUG ("disable chain %p", chain);
GST_OPT_SCHEDULER_CHAIN_DISABLE (chain);
}
}
}
/* recursively migrate the group and all connected groups into the new chain */
static void
chain_recursively_migrate_group (GstOptSchedulerChain * chain,
GstOptSchedulerGroup * group)
{
GSList *links;
/* group already in chain */
if (group->chain == chain)
return;
/* first remove the group from its old chain */
remove_from_chain (group->chain, group);
/* add to new chain */
add_to_chain (chain, group);
/* then follow all links */
links = group->group_links;
while (links) {
GstOptSchedulerGroupLink *link = (GstOptSchedulerGroupLink *) links->data;
links = g_slist_next (links);
chain_recursively_migrate_group (chain,
(link->group1 == group ? link->group2 : link->group1));
}
}
static GstOptSchedulerGroup *
ref_group (GstOptSchedulerGroup * group)
{
GST_LOG ("ref group %p %d->%d", group, group->refcount, group->refcount + 1);
group->refcount++;
return group;
}
static GstOptSchedulerGroup *
unref_group (GstOptSchedulerGroup * group)
{
GST_LOG ("unref group %p %d->%d", group,
group->refcount, group->refcount - 1);
if (--group->refcount == 0) {
destroy_group (group);
group = NULL;
}
return group;
}
static GstOptSchedulerGroup *
create_group (GstOptSchedulerChain * chain, GstElement * element,
GstOptSchedulerGroupType type)
{
GstOptSchedulerGroup *group;
group = g_new0 (GstOptSchedulerGroup, 1);
GST_LOG ("new group %p", group);
group->refcount = 1; /* float... */
group->flags = GST_OPT_SCHEDULER_GROUP_DISABLED;
group->type = type;
add_to_group (group, element);
add_to_chain (chain, group);
group = unref_group (group); /* ...and sink. */
/* group's refcount is now 2 (one for the element, one for the chain) */
return group;
}
static void
destroy_group (GstOptSchedulerGroup * group)
{
GST_LOG ("destroy group %p", group);
g_assert (group != NULL);
g_assert (group->elements == NULL);
g_assert (group->chain == NULL);
g_assert (group->group_links == NULL);
if (group->flags & GST_OPT_SCHEDULER_GROUP_SCHEDULABLE)
destroy_group_scheduler (group);
g_free (group);
}
static GstOptSchedulerGroup *
add_to_group (GstOptSchedulerGroup * group, GstElement * element)
{
g_assert (group != NULL);
g_assert (element != NULL);
GST_DEBUG ("adding element \"%s\" to group %p", GST_ELEMENT_NAME (element),
group);
if (GST_ELEMENT_IS_DECOUPLED (element)) {
GST_DEBUG ("element \"%s\" is decoupled, not adding to group %p",
GST_ELEMENT_NAME (element), group);
return group;
}
g_assert (GST_ELEMENT_SCHED_GROUP (element) == NULL);
/* Ref the group... */
GST_ELEMENT_SCHED_GROUP (element) = ref_group (group);
gst_object_ref (GST_OBJECT (element));
group->elements = g_slist_prepend (group->elements, element);
group->num_elements++;
if (gst_element_get_state (element) == GST_STATE_PLAYING) {
group_element_set_enabled (group, element, TRUE);
}
return group;
}
/* if the element is linked to elements from other groups, you must decrement
the link count prior to calling this function */
static GstOptSchedulerGroup *
remove_from_group (GstOptSchedulerGroup * group, GstElement * element)
{
GST_DEBUG ("removing element \"%s\" from group %p",
GST_ELEMENT_NAME (element), group);
g_assert (group != NULL);
g_assert (element != NULL);
g_assert (GST_ELEMENT_SCHED_GROUP (element) == group);
group->elements = g_slist_remove (group->elements, element);
group->num_elements--;
/* if the element was an entry point in the group, clear the group's
* entry point */
if (group->entry == element) {
group->entry = NULL;
}
GST_ELEMENT_SCHED_GROUP (element) = NULL;
gst_object_unref (GST_OBJECT (element));
if (group->num_elements == 0) {
GST_LOG ("group %p is now empty", group);
/* don't know in what case group->chain would be NULL, but putting this here
in deference to 0.8 -- remove me in 0.9 */
if (group->chain) {
GST_LOG ("removing group %p from its chain", group);
chain_group_set_enabled (group->chain, group, FALSE);
remove_from_chain (group->chain, group);
}
}
group = unref_group (group);
return group;
}
/* FIXME need to check if the groups are of the same type -- otherwise need to
setup the scheduler again, if it is setup */
static GstOptSchedulerGroup *
merge_groups (GstOptSchedulerGroup * group1, GstOptSchedulerGroup * group2)
{
g_assert (group1 != NULL);
GST_DEBUG ("merging groups %p and %p", group1, group2);
if (group1 == group2 || group2 == NULL)
return group1;
while (group2 && group2->elements) {
GstElement *element = (GstElement *) group2->elements->data;
group2 = remove_from_group (group2, element);
add_to_group (group1, element);
}
return group1;
}
/* setup the scheduler context for a group. The right schedule function
* is selected based on the group type and cothreads are created if
* needed */
static void
setup_group_scheduler (GstOptScheduler * osched, GstOptSchedulerGroup * group)
{
GroupScheduleFunction wrapper;
wrapper = unknown_group_schedule_function;
/* figure out the wrapper function for this group */
if (group->type == GST_OPT_SCHEDULER_GROUP_GET)
wrapper = get_group_schedule_function;
else if (group->type == GST_OPT_SCHEDULER_GROUP_LOOP)
wrapper = loop_group_schedule_function;
#ifdef USE_COTHREADS
if (!(group->flags & GST_OPT_SCHEDULER_GROUP_SCHEDULABLE)) {
do_cothread_create (group->cothread, osched->context,
(cothread_func) wrapper, 0, (char **) group);
} else {
do_cothread_setfunc (group->cothread, osched->context,
(cothread_func) wrapper, 0, (char **) group);
}
#else
group->schedulefunc = wrapper;
group->argc = 0;
group->argv = (char **) group;
#endif
group->flags |= GST_OPT_SCHEDULER_GROUP_SCHEDULABLE;
}
static void
destroy_group_scheduler (GstOptSchedulerGroup * group)
{
g_assert (group);
if (group->flags & GST_OPT_SCHEDULER_GROUP_RUNNING)
g_warning ("destroying running group scheduler");
#ifdef USE_COTHREADS
if (group->cothread) {
do_cothread_destroy (group->cothread);
group->cothread = NULL;
}
#else
group->schedulefunc = NULL;
group->argc = 0;
group->argv = NULL;
#endif
group->flags &= ~GST_OPT_SCHEDULER_GROUP_SCHEDULABLE;
}
static void
group_error_handler (GstOptSchedulerGroup * group)
{
GST_DEBUG ("group %p has errored", group);
chain_group_set_enabled (group->chain, group, FALSE);
group->chain->sched->state = GST_OPT_SCHEDULER_STATE_ERROR;
}
/* this function enables/disables an element, it will set/clear a flag on the element
* and tells the chain that the group is enabled if all elements inside the group are
* enabled */
static void
group_element_set_enabled (GstOptSchedulerGroup * group, GstElement * element,
gboolean enabled)
{
g_assert (group != NULL);
g_assert (element != NULL);
GST_LOG
("request to %d element %s in group %p, have %d elements enabled out of %d",
enabled, GST_ELEMENT_NAME (element), group, group->num_enabled,
group->num_elements);
/* Note that if an unlinked PLAYING element is added to a bin, we have to
create a new group to hold the element, and this function will be called
before the group is added to the chain. Thus we have a valid case for
group->chain==NULL. */
if (enabled) {
if (group->num_enabled < group->num_elements)
group->num_enabled++;
GST_DEBUG
("enable element %s in group %p, now %d elements enabled out of %d",
GST_ELEMENT_NAME (element), group, group->num_enabled,
group->num_elements);
if (group->num_enabled == group->num_elements) {
if (!group->chain) {
GST_DEBUG ("enable chainless group %p", group);
GST_OPT_SCHEDULER_GROUP_ENABLE (group);
} else {
GST_LOG ("enable group %p", group);
chain_group_set_enabled (group->chain, group, TRUE);
}
}
} else {
if (group->num_enabled > 0)
group->num_enabled--;
GST_DEBUG
("disable element %s in group %p, now %d elements enabled out of %d",
GST_ELEMENT_NAME (element), group, group->num_enabled,
group->num_elements);
if (group->num_enabled == 0) {
if (!group->chain) {
GST_DEBUG ("disable chainless group %p", group);
GST_OPT_SCHEDULER_GROUP_DISABLE (group);
} else {
GST_LOG ("disable group %p", group);
chain_group_set_enabled (group->chain, group, FALSE);
}
}
}
}
/* a group is scheduled by doing a cothread switch to it or
* by calling the schedule function. In the non-cothread case
* we cannot run already running groups so we return FALSE here
* to indicate this to the caller */
static gboolean
schedule_group (GstOptSchedulerGroup * group)
{
if (!group->entry) {
GST_INFO ("not scheduling group %p without entry", group);
return FALSE;
}
#ifdef USE_COTHREADS
if (group->cothread)
do_cothread_switch (group->cothread);
else
g_warning ("(internal error): trying to schedule group without cothread");
return TRUE;
#else
/* cothreads automatically call the pre- and post-run functions for us;
* without cothreads we need to call them manually */
if (group->schedulefunc == NULL) {
GST_INFO ("not scheduling group %p without schedulefunc", group);
return FALSE;
} else {
GSList *l;
for (l = group->elements; l; l = l->next) {
GstElement *e = (GstElement *) l->data;
if (e->pre_run_func)
e->pre_run_func (e);
}
group->schedulefunc (group->argc, group->argv);
for (l = group->elements; l; l = l->next) {
GstElement *e = (GstElement *) l->data;
if (e->post_run_func)
e->post_run_func (e);
}
}
return TRUE;
#endif
}
#ifndef USE_COTHREADS
static void
gst_opt_scheduler_schedule_run_queue (GstOptScheduler * osched)
{
GST_LOG_OBJECT (osched, "running queue: %d groups, recursed %d times",
g_list_length (osched->runqueue),
osched->recursion, g_list_length (osched->runqueue));
/* note that we have a ref on each group on the queue (unref after running) */
/* make sure we don't exceed max_recursion */
if (osched->recursion > osched->max_recursion) {
osched->state = GST_OPT_SCHEDULER_STATE_ERROR;
return;
}
osched->recursion++;
while (osched->runqueue) {
GstOptSchedulerGroup *group;
gboolean res;
group = (GstOptSchedulerGroup *) osched->runqueue->data;
/* runqueue holds refcount to group */
osched->runqueue = g_list_remove (osched->runqueue, group);
GST_LOG_OBJECT (osched, "scheduling group %p", group);
res = schedule_group (group);
if (!res) {
g_warning ("error scheduling group %p", group);
group_error_handler (group);
} else {
GST_LOG_OBJECT (osched, "done scheduling group %p", group);
}
unref_group (group);
}
GST_LOG_OBJECT (osched, "run queue length after scheduling %d",
g_list_length (osched->runqueue));
osched->recursion--;
}
#endif
/* a chain is scheduled by picking the first active group and scheduling it */
static void
schedule_chain (GstOptSchedulerChain * chain)
{
GSList *groups;
GstOptScheduler *osched;
osched = chain->sched;
groups = chain->groups;
while (groups) {
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) groups->data;
if (!GST_OPT_SCHEDULER_GROUP_IS_DISABLED (group)) {
ref_group (group);
GST_LOG ("scheduling group %p in chain %p", group, chain);
#ifdef USE_COTHREADS
schedule_group (group);
#else
osched->recursion = 0;
if (!g_list_find (osched->runqueue, group)) {
ref_group (group);
osched->runqueue = g_list_append (osched->runqueue, group);
}
gst_opt_scheduler_schedule_run_queue (osched);
#endif
GST_LOG ("done scheduling group %p in chain %p", group, chain);
unref_group (group);
break;
}
groups = g_slist_next (groups);
}
}
/* a get-based group is scheduled by getting a buffer from the get based
* entry point and by pushing the buffer to the peer.
* We also set the running flag on this group for as long as this
* function is running. */
static int
get_group_schedule_function (int argc, char *argv[])
{
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) argv;
GstElement *entry = group->entry;
const GList *pads = gst_element_get_pad_list (entry);
GST_LOG ("executing get-based group %p", group);
group->flags |= GST_OPT_SCHEDULER_GROUP_RUNNING;
while (pads) {
GstData *data;
GstPad *pad = GST_PAD (pads->data);
pads = g_list_next (pads);
/* skip sinks and ghostpads */
if (!GST_PAD_IS_SRC (pad) || !GST_IS_REAL_PAD (pad))
continue;
GST_DEBUG ("doing get and push on pad \"%s:%s\" in group %p",
GST_DEBUG_PAD_NAME (pad), group);
data = GST_RPAD_GETFUNC (pad) (pad);
if (data) {
if (GST_EVENT_IS_INTERRUPT (data)) {
gst_event_unref (GST_EVENT (data));
break;
}
gst_pad_push (pad, data);
}
}
group->flags &= ~GST_OPT_SCHEDULER_GROUP_RUNNING;
return 0;
}
/* a loop-based group is scheduled by calling the loop function
* on the entry point.
* We also set the running flag on this group for as long as this
* function is running. */
static int
loop_group_schedule_function (int argc, char *argv[])
{
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) argv;
GstElement *entry = group->entry;
GST_LOG ("executing loop-based group %p", group);
group->flags |= GST_OPT_SCHEDULER_GROUP_RUNNING;
GST_DEBUG ("calling loopfunc of element %s in group %p",
GST_ELEMENT_NAME (entry), group);
entry->loopfunc (entry);
GST_LOG ("loopfunc ended of element %s in group %p",
GST_ELEMENT_NAME (entry), group);
group->flags &= ~GST_OPT_SCHEDULER_GROUP_RUNNING;
return 0;
}
/* the function to schedule an unknown group, which just gives an error */
static int
unknown_group_schedule_function (int argc, char *argv[])
{
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) argv;
g_warning ("(internal error) unknown group type %d, disabling\n",
group->type);
group_error_handler (group);
return 0;
}
/* this function is called when the first element of a chain-loop or a loop-loop
* link performs a push to the loop element. We then schedule the
* group with the loop-based element until the bufpen is empty */
static void
gst_opt_scheduler_loop_wrapper (GstPad * sinkpad, GstData * data)
{
GstOptSchedulerGroup *group;
GstOptScheduler *osched;
GstRealPad *peer;
group = GST_ELEMENT_SCHED_GROUP (GST_PAD_PARENT (sinkpad));
osched = group->chain->sched;
peer = GST_RPAD_PEER (sinkpad);
GST_LOG ("chain handler for loop-based pad %" GST_PTR_FORMAT, sinkpad);
#ifdef USE_COTHREADS
if (GST_PAD_BUFLIST (peer)) {
g_warning ("deadlock detected, disabling group %p", group);
group_error_handler (group);
} else {
GST_LOG ("queueing data %p on %s:%s's bufpen", data,
GST_DEBUG_PAD_NAME (peer));
GST_PAD_BUFLIST (peer) = g_list_append (GST_PAD_BUFLIST (peer), data);
schedule_group (group);
}
#else
GST_LOG ("queueing data %p on %s:%s's bufpen", data,
GST_DEBUG_PAD_NAME (peer));
GST_PAD_BUFLIST (peer) = g_list_append (GST_PAD_BUFLIST (peer), data);
if (!(group->flags & GST_OPT_SCHEDULER_GROUP_RUNNING)) {
GST_LOG ("adding group %p to runqueue", group);
if (!g_list_find (osched->runqueue, group)) {
ref_group (group);
osched->runqueue = g_list_append (osched->runqueue, group);
}
}
#endif
GST_LOG ("%d buffers left on %s:%s's bufpen after chain handler",
g_list_length (GST_PAD_BUFLIST (peer)));
}
/* this function is called by a loop based element that performs a
* pull on a sinkpad. We schedule the peer group until the bufpen
* is filled with the buffer so that this function can return */
static GstData *
gst_opt_scheduler_get_wrapper (GstPad * srcpad)
{
GstData *data;
GstOptSchedulerGroup *group;
GstOptScheduler *osched;
gboolean disabled;
GST_LOG ("get handler for %" GST_PTR_FORMAT, srcpad);
/* first try to grab a queued buffer */
if (GST_PAD_BUFLIST (srcpad)) {
data = GST_PAD_BUFLIST (srcpad)->data;
GST_PAD_BUFLIST (srcpad) = g_list_remove (GST_PAD_BUFLIST (srcpad), data);
GST_LOG ("returning popped queued data %p", data);
return data;
}
/* else we need to schedule the peer element */
group = GST_ELEMENT_SCHED_GROUP (GST_PAD_PARENT (srcpad));
osched = group->chain->sched;
data = NULL;
disabled = FALSE;
do {
GST_LOG ("scheduling upstream group %p to fill bufpen", group);
#ifdef USE_COTHREADS
schedule_group (group);
#else
if (!(group->flags & GST_OPT_SCHEDULER_GROUP_RUNNING)) {
ref_group (group);
if (!g_list_find (osched->runqueue, group)) {
ref_group (group);
osched->runqueue = g_list_append (osched->runqueue, group);
}
GST_LOG ("recursing into scheduler group %p", group);
gst_opt_scheduler_schedule_run_queue (osched);
GST_LOG ("return from recurse group %p", group);
/* if the other group was disabled we might have to break out of the loop */
disabled = GST_OPT_SCHEDULER_GROUP_IS_DISABLED (group);
group = unref_group (group);
/* group is gone */
if (group == NULL) {
/* if the group was gone we also might have to break out of the loop */
disabled = TRUE;
}
} else {
/* in this case, the group was running and we wanted to swtich to it,
* this is not allowed in the optimal scheduler (yet) */
g_warning ("deadlock detected, disabling group %p", group);
group_error_handler (group);
return GST_DATA (gst_event_new (GST_EVENT_INTERRUPT));
}
#endif
/* if the scheduler interrupted, make sure we send an INTERRUPTED event to the
* loop based element */
if (osched->state == GST_OPT_SCHEDULER_STATE_INTERRUPTED) {
GST_INFO ("scheduler interrupted, return interrupt event");
data = GST_DATA (gst_event_new (GST_EVENT_INTERRUPT));
} else {
if (GST_PAD_BUFLIST (srcpad)) {
data = GST_PAD_BUFLIST (srcpad)->data;
GST_PAD_BUFLIST (srcpad) =
g_list_remove (GST_PAD_BUFLIST (srcpad), data);
} else if (disabled) {
/* no buffer in queue and peer group was disabled */
data = GST_DATA (gst_event_new (GST_EVENT_INTERRUPT));
}
}
}
while (data == NULL);
GST_LOG ("get handler, returning data %p, queue length %d",
data, g_list_length (GST_PAD_BUFLIST (srcpad)));
return data;
}
/* this function is a chain wrapper for non-event-aware plugins,
* it'll simply dispatch the events to the (default) event handler */
static void
gst_opt_scheduler_chain_wrapper (GstPad * sinkpad, GstData * data)
{
if (GST_IS_EVENT (data)) {
gst_pad_send_event (sinkpad, GST_EVENT (data));
} else {
GST_RPAD_CHAINFUNC (sinkpad) (sinkpad, data);
}
}
static void
clear_queued (GstData * data, gpointer user_data)
{
gst_data_unref (data);
}
static void
pad_clear_queued (GstPad * srcpad, gpointer user_data)
{
GList *buflist = GST_PAD_BUFLIST (srcpad);
if (buflist) {
GST_LOG ("need to clear some buffers");
g_list_foreach (buflist, (GFunc) clear_queued, NULL);
g_list_free (buflist);
GST_PAD_BUFLIST (srcpad) = NULL;
}
}
static gboolean
gst_opt_scheduler_event_wrapper (GstPad * srcpad, GstEvent * event)
{
gboolean flush;
GST_DEBUG ("intercepting event %d on pad %s:%s",
GST_EVENT_TYPE (event), GST_DEBUG_PAD_NAME (srcpad));
/* figure out if this is a flush event */
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) {
GST_LOG ("event is flush");
pad_clear_queued (srcpad, NULL);
}
return GST_RPAD_EVENTFUNC (srcpad) (srcpad, event);
}
static GstElementStateReturn
gst_opt_scheduler_state_transition (GstScheduler * sched, GstElement * element,
gint transition)
{
GstOptSchedulerGroup *group;
GstElementStateReturn res = GST_STATE_SUCCESS;
GST_DEBUG ("element \"%s\" state change %d", GST_ELEMENT_NAME (element),
transition);
/* we check the state of the managing pipeline here */
if (GST_IS_BIN (element)) {
if (GST_SCHEDULER_PARENT (sched) == element) {
GST_LOG ("parent \"%s\" changed state", GST_ELEMENT_NAME (element));
switch (transition) {
case GST_STATE_PLAYING_TO_PAUSED:
GST_INFO ("setting scheduler state to stopped");
GST_SCHEDULER_STATE (sched) = GST_SCHEDULER_STATE_STOPPED;
break;
case GST_STATE_PAUSED_TO_PLAYING:
GST_INFO ("setting scheduler state to running");
GST_SCHEDULER_STATE (sched) = GST_SCHEDULER_STATE_RUNNING;
break;
default:
GST_LOG ("no interesting state change, doing nothing");
}
}
return res;
}
/* we don't care about decoupled elements after this */
if (GST_ELEMENT_IS_DECOUPLED (element))
return GST_STATE_SUCCESS;
/* get the group of the element */
group = GST_ELEMENT_SCHED_GROUP (element);
switch (transition) {
case GST_STATE_PAUSED_TO_PLAYING:
/* an element withut a group has to be an unlinked src, sink
* filter element */
if (!group) {
GST_INFO ("element \"%s\" has no group", GST_ELEMENT_NAME (element));
res = GST_STATE_FAILURE;
}
/* else construct the scheduling context of this group and enable it */
else {
group_element_set_enabled (group, element, TRUE);
}
break;
case GST_STATE_PLAYING_TO_PAUSED:
/* if the element still has a group, we disable it */
if (group)
group_element_set_enabled (group, element, FALSE);
break;
case GST_STATE_PAUSED_TO_READY:
{
GList *pads = (GList *) gst_element_get_pad_list (element);
g_list_foreach (pads, (GFunc) pad_clear_queued, NULL);
break;
}
default:
break;
}
return res;
}
static void
gst_opt_scheduler_scheduling_change (GstScheduler * sched, GstElement * element)
{
g_warning ("scheduling change, implement me");
}
static void
get_group (GstElement * element, GstOptSchedulerGroup ** group)
{
GstOptSchedulerCtx *ctx;
/*GList *pads; */
ctx = GST_ELEMENT_SCHED_CONTEXT (element);
if (ctx)
*group = ctx->group;
else
*group = NULL;
}
/*
* the idea is to put the two elements into the same group.
* - When no element is inside a group, we create a new group and add
* the elements to it.
* - When one of the elements has a group, add the other element to
* that group
* - if both of the elements have a group, we merge the groups, which
* will also merge the chains.
*/
static GstOptSchedulerGroup *
group_elements (GstOptScheduler * osched, GstElement * element1,
GstElement * element2, GstOptSchedulerGroupType type)
{
GstOptSchedulerGroup *group1, *group2, *group = NULL;
get_group (element1, &group1);
get_group (element2, &group2);
/* none of the elements is added to a group, create a new group
* and chain to add the elements to */
if (!group1 && !group2) {
GstOptSchedulerChain *chain;
GST_DEBUG ("creating new group to hold \"%s\" and \"%s\"",
GST_ELEMENT_NAME (element1), GST_ELEMENT_NAME (element2));
chain = create_chain (osched);
group = create_group (chain, element1, type);
add_to_group (group, element2);
}
/* the first element has a group */
else if (group1) {
GST_DEBUG ("adding \"%s\" to \"%s\"'s group",
GST_ELEMENT_NAME (element2), GST_ELEMENT_NAME (element1));
/* the second element also has a group, merge */
if (group2)
merge_groups (group1, group2);
/* the second element has no group, add it to the group
* of the first element */
else
add_to_group (group1, element2);
group = group1;
}
/* element1 has no group, element2 does. Add element1 to the
* group of element2 */
else {
GST_DEBUG ("adding \"%s\" to \"%s\"'s group",
GST_ELEMENT_NAME (element1), GST_ELEMENT_NAME (element2));
add_to_group (group2, element1);
group = group2;
}
return group;
}
/*
* increment link counts between groups
*/
static void
group_inc_link (GstOptSchedulerGroup * group1, GstOptSchedulerGroup * group2)
{
GSList *links = group1->group_links;
gboolean done = FALSE;
GstOptSchedulerGroupLink *link;
/* first try to find a previous link */
while (links && !done) {
link = (GstOptSchedulerGroupLink *) links->data;
links = g_slist_next (links);
if (IS_GROUP_LINK (link, group1, group2)) {
/* we found a link to this group, increment the link count */
link->count++;
GST_LOG ("incremented group link count between %p and %p to %d",
group1, group2, link->count);
done = TRUE;
}
}
if (!done) {
/* no link was found, create a new one */
link = g_new0 (GstOptSchedulerGroupLink, 1);
link->group1 = group1;
link->group2 = group2;
link->count = 1;
group1->group_links = g_slist_prepend (group1->group_links, link);
group2->group_links = g_slist_prepend (group2->group_links, link);
GST_DEBUG ("added group link between %p and %p", group1, group2);
}
}
/*
* decrement link counts between groups, returns TRUE if the link count reaches 0
*/
static gboolean
group_dec_link (GstOptSchedulerGroup * group1, GstOptSchedulerGroup * group2)
{
GSList *links = group1->group_links;
gboolean res = FALSE;
GstOptSchedulerGroupLink *link;
while (links) {
link = (GstOptSchedulerGroupLink *) links->data;
links = g_slist_next (links);
if (IS_GROUP_LINK (link, group1, group2)) {
link->count--;
GST_LOG ("link count between %p and %p is now %d",
group1, group2, link->count);
if (link->count == 0) {
group1->group_links = g_slist_remove (group1->group_links, link);
group2->group_links = g_slist_remove (group2->group_links, link);
g_free (link);
GST_DEBUG ("removed group link between %p and %p", group1, group2);
res = TRUE;
}
break;
}
}
return res;
}
typedef enum
{
GST_OPT_INVALID,
GST_OPT_GET_TO_CHAIN,
GST_OPT_LOOP_TO_CHAIN,
GST_OPT_GET_TO_LOOP,
GST_OPT_CHAIN_TO_CHAIN,
GST_OPT_CHAIN_TO_LOOP,
GST_OPT_LOOP_TO_LOOP,
}
LinkType;
/*
* Entry points for this scheduler.
*/
static void
gst_opt_scheduler_setup (GstScheduler * sched)
{
#ifdef USE_COTHREADS
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
/* first create thread context */
if (osched->context == NULL) {
GST_DEBUG ("initializing cothread context");
osched->context = do_cothread_context_init ();
}
#endif
}
static void
gst_opt_scheduler_reset (GstScheduler * sched)
{
#ifdef USE_COTHREADS
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
GSList *chains = osched->chains;
while (chains) {
GstOptSchedulerChain *chain = (GstOptSchedulerChain *) chains->data;
GSList *groups = chain->groups;
while (groups) {
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) groups->data;
destroy_group_scheduler (group);
groups = groups->next;
}
chains = chains->next;
}
if (osched->context) {
do_cothread_context_destroy (osched->context);
osched->context = NULL;
}
#endif
}
static void
gst_opt_scheduler_add_element (GstScheduler * sched, GstElement * element)
{
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
GstOptSchedulerCtx *ctx;
const GList *pads;
GST_DEBUG_OBJECT (sched, "adding element \"%s\"", GST_OBJECT_NAME (element));
/* decoupled elements are not added to the scheduler lists */
if (GST_ELEMENT_IS_DECOUPLED (element))
return;
ctx = g_new0 (GstOptSchedulerCtx, 1);
GST_ELEMENT_SCHED_CONTEXT (element) = ctx;
ctx->flags = GST_OPT_SCHEDULER_CTX_DISABLED;
/* set event handler on all pads here so events work unconnected too;
* in _link, it can be overruled if need be */
/* FIXME: we should also do this when new pads on the element are created;
but there are no hooks, so we do it again in _link */
pads = gst_element_get_pad_list (element);
while (pads) {
GstPad *pad = GST_PAD (pads->data);
pads = g_list_next (pads);
if (!GST_IS_REAL_PAD (pad))
continue;
GST_RPAD_EVENTHANDLER (pad) = GST_RPAD_EVENTFUNC (pad);
}
/* loop based elements *always* end up in their own group. It can eventually
* be merged with another group when a link is made */
if (element->loopfunc) {
GstOptSchedulerGroup *group;
GstOptSchedulerChain *chain;
chain = create_chain (osched);
group = create_group (chain, element, GST_OPT_SCHEDULER_GROUP_LOOP);
group->entry = element;
GST_LOG ("added element \"%s\" as loop based entry",
GST_ELEMENT_NAME (element));
}
}
static void
gst_opt_scheduler_remove_element (GstScheduler * sched, GstElement * element)
{
GstOptSchedulerGroup *group;
GST_DEBUG_OBJECT (sched, "removing element \"%s\"",
GST_OBJECT_NAME (element));
/* decoupled elements are not added to the scheduler lists and should therefore
* no be removed */
if (GST_ELEMENT_IS_DECOUPLED (element))
return;
/* the element is guaranteed to live in it's own group/chain now */
get_group (element, &group);
if (group) {
remove_from_group (group, element);
}
g_free (GST_ELEMENT_SCHED_CONTEXT (element));
GST_ELEMENT_SCHED_CONTEXT (element) = NULL;
}
static void
gst_opt_scheduler_lock_element (GstScheduler * sched, GstElement * element)
{
//GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
g_warning ("lock element, implement me");
}
static void
gst_opt_scheduler_unlock_element (GstScheduler * sched, GstElement * element)
{
//GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
g_warning ("unlock element, implement me");
}
static gboolean
gst_opt_scheduler_yield (GstScheduler * sched, GstElement * element)
{
#ifdef USE_COTHREADS
/* yield hands control to the main cothread context if the requesting
* element is the entry point of the group */
GstOptSchedulerGroup *group;
get_group (element, &group);
if (group && group->entry == element)
do_cothread_switch (do_cothread_get_main (((GstOptScheduler *) sched)->
context));
return FALSE;
#else
g_warning ("element %s performs a yield, please fix the element",
GST_ELEMENT_NAME (element));
return TRUE;
#endif
}
static gboolean
gst_opt_scheduler_interrupt (GstScheduler * sched, GstElement * element)
{
GST_INFO ("interrupt from \"%s\"", GST_OBJECT_NAME (element));
#ifdef USE_COTHREADS
do_cothread_switch (do_cothread_get_main (((GstOptScheduler *) sched)->
context));
return FALSE;
#else
{
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
GST_INFO ("scheduler set interrupted state");
osched->state = GST_OPT_SCHEDULER_STATE_INTERRUPTED;
}
return TRUE;
#endif
}
static void
gst_opt_scheduler_error (GstScheduler * sched, GstElement * element)
{
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
GstOptSchedulerGroup *group;
get_group (element, &group);
if (group)
group_error_handler (group);
osched->state = GST_OPT_SCHEDULER_STATE_ERROR;
}
/* link pads, merge groups and chains */
static void
gst_opt_scheduler_pad_link (GstScheduler * sched, GstPad * srcpad,
GstPad * sinkpad)
{
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
LinkType type = GST_OPT_INVALID;
GstElement *element1, *element2;
GST_INFO ("scheduling link between %s:%s and %s:%s",
GST_DEBUG_PAD_NAME (srcpad), GST_DEBUG_PAD_NAME (sinkpad));
element1 = GST_PAD_PARENT (srcpad);
element2 = GST_PAD_PARENT (sinkpad);
/* first we need to figure out what type of link we're dealing
* with */
if (element1->loopfunc && element2->loopfunc)
type = GST_OPT_LOOP_TO_LOOP;
else {
if (element1->loopfunc) {
if (GST_RPAD_CHAINFUNC (sinkpad))
type = GST_OPT_LOOP_TO_CHAIN;
} else if (element2->loopfunc) {
if (GST_RPAD_GETFUNC (srcpad)) {
type = GST_OPT_GET_TO_LOOP;
/* this could be tricky, the get based source could
* already be part of a loop based group in another pad,
* we assert on that for now */
if (GST_ELEMENT_SCHED_CONTEXT (element1) != NULL &&
GST_ELEMENT_SCHED_GROUP (element1) != NULL) {
GstOptSchedulerGroup *group = GST_ELEMENT_SCHED_GROUP (element1);
/* if the loop based element is the entry point we're ok, if it
* isn't then we have multiple loop based elements in this group */
if (group->entry != element2) {
g_error
("internal error: cannot schedule get to loop in multi-loop based group");
return;
}
}
} else
type = GST_OPT_CHAIN_TO_LOOP;
} else {
if (GST_RPAD_GETFUNC (srcpad) && GST_RPAD_CHAINFUNC (sinkpad)) {
type = GST_OPT_GET_TO_CHAIN;
/* the get based source could already be part of a loop
* based group in another pad, we assert on that for now */
if (GST_ELEMENT_SCHED_CONTEXT (element1) != NULL &&
GST_ELEMENT_SCHED_GROUP (element1) != NULL) {
GstOptSchedulerGroup *group = GST_ELEMENT_SCHED_GROUP (element1);
/* if the get based element is the entry point we're ok, if it
* isn't then we have a mixed loop/chain based group */
if (group->entry != element1) {
g_error
("internal error: cannot schedule get to chain with mixed loop/chain based group");
return;
}
}
} else
type = GST_OPT_CHAIN_TO_CHAIN;
}
}
/* since we can't set event handlers on pad creation after addition, it is
* best we set all of them again to the default before linking */
GST_RPAD_EVENTHANDLER (srcpad) = GST_RPAD_EVENTFUNC (srcpad);
GST_RPAD_EVENTHANDLER (sinkpad) = GST_RPAD_EVENTFUNC (sinkpad);
/* for each link type, perform specific actions */
switch (type) {
case GST_OPT_GET_TO_CHAIN:
{
GstOptSchedulerGroup *group = NULL;
GST_LOG ("get to chain based link");
/* setup get/chain handlers */
GST_RPAD_GETHANDLER (srcpad) = GST_RPAD_GETFUNC (srcpad);
if (GST_ELEMENT_IS_EVENT_AWARE (element2))
GST_RPAD_CHAINHANDLER (sinkpad) = GST_RPAD_CHAINFUNC (sinkpad);
else
GST_RPAD_CHAINHANDLER (sinkpad) = gst_opt_scheduler_chain_wrapper;
/* the two elements should be put into the same group,
* this also means that they are in the same chain automatically */
group = group_elements (osched, element1, element2,
GST_OPT_SCHEDULER_GROUP_GET);
/* if there is not yet an entry in the group, select the source
* element as the entry point */
if (!group->entry) {
group->entry = element1;
GST_DEBUG ("setting \"%s\" as entry point of _get-based group %p",
GST_ELEMENT_NAME (element1), group);
}
break;
}
case GST_OPT_LOOP_TO_CHAIN:
case GST_OPT_CHAIN_TO_CHAIN:
GST_LOG ("loop/chain to chain based link");
if (GST_ELEMENT_IS_EVENT_AWARE (element2))
GST_RPAD_CHAINHANDLER (sinkpad) = GST_RPAD_CHAINFUNC (sinkpad);
else
GST_RPAD_CHAINHANDLER (sinkpad) = gst_opt_scheduler_chain_wrapper;
/* the two elements should be put into the same group,
* this also means that they are in the same chain automatically,
* in case of a loop-based element1, there will be a group for element1 and
* element2 will be added to it. */
group_elements (osched, element1, element2, GST_OPT_SCHEDULER_GROUP_LOOP);
break;
case GST_OPT_GET_TO_LOOP:
GST_LOG ("get to loop based link");
GST_RPAD_GETHANDLER (srcpad) = GST_RPAD_GETFUNC (srcpad);
/* the two elements should be put into the same group,
* this also means that they are in the same chain automatically,
* element2 is loop-based so it already has a group where element1
* will be added to */
group_elements (osched, element1, element2, GST_OPT_SCHEDULER_GROUP_LOOP);
break;
case GST_OPT_CHAIN_TO_LOOP:
case GST_OPT_LOOP_TO_LOOP:
{
GstOptSchedulerGroup *group1, *group2;
GST_LOG ("chain/loop to loop based link");
GST_RPAD_CHAINHANDLER (sinkpad) = gst_opt_scheduler_loop_wrapper;
GST_RPAD_GETHANDLER (srcpad) = gst_opt_scheduler_get_wrapper;
/* events on the srcpad have to be intercepted as we might need to
* flush the buffer lists, so override the given eventfunc */
GST_RPAD_EVENTHANDLER (srcpad) = gst_opt_scheduler_event_wrapper;
group1 = GST_ELEMENT_SCHED_GROUP (element1);
group2 = GST_ELEMENT_SCHED_GROUP (element2);
g_assert (group2 != NULL);
/* group2 is guaranteed to exist as it contains a loop-based element.
* group1 only exists if element1 is linked to some other element */
if (!group1) {
/* create a new group for element1 as it cannot be merged into another group
* here. we create the group in the same chain as the loop-based element. */
GST_DEBUG ("creating new group for element %s",
GST_ELEMENT_NAME (element1));
group1 =
create_group (group2->chain, element1,
GST_OPT_SCHEDULER_GROUP_LOOP);
} else {
/* both elements are already in a group, make sure they are added to
* the same chain */
merge_chains (group1->chain, group2->chain);
}
group_inc_link (group1, group2);
break;
}
case GST_OPT_INVALID:
g_error ("(internal error) invalid element link, what are you doing?");
break;
}
}
/*
* checks if an element is still linked to some other element in the group.
* no checking is done on the brokenpad arg
*/
static gboolean
element_has_link_with_group (GstElement * element, GstOptSchedulerGroup * group,
GstPad * brokenpad)
{
gboolean linked = FALSE;
const GList *pads;
/* see if the element has no more links to the peer group */
pads = gst_element_get_pad_list (element);
while (pads && !linked) {
GstPad *pad = GST_PAD (pads->data);
pads = g_list_next (pads);
/* we only operate on real pads and on the pad that is not broken */
if (!GST_IS_REAL_PAD (pad) || pad == brokenpad)
continue;
if (GST_PAD_PEER (pad)) {
GstElement *parent;
GstOptSchedulerGroup *parentgroup;
/* see in what group this element is */
parent = GST_PAD_PARENT (GST_PAD_PEER (pad));
/* links with decoupled elements are valid */
if (GST_ELEMENT_IS_DECOUPLED (parent)) {
linked = TRUE;
} else {
/* for non-decoupled elements we need to check the group */
get_group (parent, &parentgroup);
/* if it's in the same group, we're still linked */
if (parentgroup == group)
linked = TRUE;
}
}
}
return linked;
}
/*
* checks if a target group is still reachable from the group without taking the broken
* group link into account.
*/
static gboolean
group_can_reach_group (GstOptSchedulerGroup * group,
GstOptSchedulerGroup * target)
{
gboolean reachable = FALSE;
const GSList *links = group->group_links;
GST_LOG ("checking if group %p can reach %p", group, target);
/* seems like we found the target element */
if (group == target) {
GST_LOG ("found way to reach %p", target);
return TRUE;
}
/* if the group is marked as visited, we don't need to check here */
if (GST_OPT_SCHEDULER_GROUP_IS_FLAG_SET (group,
GST_OPT_SCHEDULER_GROUP_VISITED)) {
GST_LOG ("already visited %p", group);
return FALSE;
}
/* mark group as visited */
GST_OPT_SCHEDULER_GROUP_SET_FLAG (group, GST_OPT_SCHEDULER_GROUP_VISITED);
while (links && !reachable) {
GstOptSchedulerGroupLink *link = (GstOptSchedulerGroupLink *) links->data;
GstOptSchedulerGroup *other;
links = g_slist_next (links);
/* find other group in this link */
other = OTHER_GROUP_LINK (link, group);
GST_LOG ("found link from %p to %p, count %d", group, other, link->count);
/* check if we can reach the target recursiveley */
reachable = group_can_reach_group (other, target);
}
/* unset the visited flag, note that this is not optimal as we might be checking
* groups several times when they are reachable with a loop. An alternative would be
* to not clear the group flag at this stage but clear all flags in the chain when
* all groups are checked. */
GST_OPT_SCHEDULER_GROUP_UNSET_FLAG (group, GST_OPT_SCHEDULER_GROUP_VISITED);
GST_LOG ("leaving group %p with %s", group, (reachable ? "TRUE" : "FALSE"));
return reachable;
}
static void
group_dec_links_for_element (GstOptSchedulerGroup * group, GstElement * element)
{
GList *l;
GstPad *pad;
GstOptSchedulerGroup *peer_group;
for (l = GST_ELEMENT_PADS (element); l; l = l->next) {
pad = (GstPad *) l->data;
if (GST_IS_REAL_PAD (pad) && GST_PAD_PEER (pad)) {
get_group (GST_PAD_PARENT (GST_PAD_PEER (pad)), &peer_group);
if (peer_group && peer_group != group)
group_dec_link (group, peer_group);
}
}
}
static void
gst_opt_scheduler_pad_unlink (GstScheduler * sched,
GstPad * srcpad, GstPad * sinkpad)
{
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
GstElement *element1, *element2;
GstOptSchedulerGroup *group1, *group2;
GST_INFO ("unscheduling link between %s:%s and %s:%s",
GST_DEBUG_PAD_NAME (srcpad), GST_DEBUG_PAD_NAME (sinkpad));
element1 = GST_PAD_PARENT (srcpad);
element2 = GST_PAD_PARENT (sinkpad);
get_group (element1, &group1);
get_group (element2, &group2);
/* for decoupled elements (that are never put into a group) we use the
* group of the peer element for the remainder of the algorithm */
if (GST_ELEMENT_IS_DECOUPLED (element1)) {
group1 = group2;
}
if (GST_ELEMENT_IS_DECOUPLED (element2)) {
group2 = group1;
}
/* if one the elements has no group (anymore) we don't really care
* about the link */
if (!group1 || !group2) {
GST_LOG
("one (or both) of the elements is not in a group, not interesting");
return;
}
/* easy part, groups are different */
if (group1 != group2) {
gboolean zero;
GST_LOG ("elements are in different groups");
/* we can remove the links between the groups now */
zero = group_dec_link (group1, group2);
/* if the groups are not directly connected anymore, we have to perform a recursive check
* to see if they are really unlinked */
if (zero) {
gboolean still_link;
GstOptSchedulerChain *chain;
/* see if group1 and group2 are still connected in any indirect way */
still_link = group_can_reach_group (group1, group2);
GST_DEBUG ("group %p %s reach group %p", group1,
(still_link ? "can" : "can't"), group2);
if (!still_link) {
/* groups are really disconnected, migrate one group to a new chain */
chain = create_chain (osched);
chain_recursively_migrate_group (chain, group1);
GST_DEBUG ("migrated group %p to new chain %p", group1, chain);
}
} else {
GST_DEBUG ("group %p still has direct link with group %p", group1,
group2);
}
}
/* hard part, groups are equal */
else {
gboolean still_link1, still_link2;
GstOptSchedulerGroup *group;
/* since group1 == group2, it doesn't matter which group we take */
group = group1;
GST_LOG ("elements are in the same group %p", group);
/* check if the element is still linked to some other element in the group,
* we pass the pad that is broken up as an arg because a link on that pad
* is not valid anymore.
* Note that this check is only to make sure that a single element can be removed
* completely from the group, we also have to check for migrating several
* elements to a new group. */
still_link1 = element_has_link_with_group (element1, group, srcpad);
still_link2 = element_has_link_with_group (element2, group, sinkpad);
/* if there is still a link, we don't need to break this group */
if (still_link1 && still_link2) {
GSList *l;
GList *m;
int linkcount;
GST_LOG ("elements still have links with other elements in the group");
while (group->elements)
for (l = group->elements; l && l->data; l = l->next) {
GstElement *element = (GstElement *) l->data;
if (GST_ELEMENT_IS_DECOUPLED (element))
continue;
linkcount = 0;
GST_LOG ("Examining %s\n", GST_ELEMENT_NAME (element));
for (m = GST_ELEMENT_PADS (element); m; m = m->next) {
GstPad *peer, *pad;
GstElement *parent;
GstOptSchedulerGroup *peer_group;
pad = (GstPad *) m->data;
if (!pad || !GST_IS_REAL_PAD (pad))
continue;
peer = GST_PAD_PEER (pad);
if (!peer || !GST_IS_REAL_PAD (peer))
continue;
parent = GST_PAD_PARENT (GST_PAD_PEER (pad));
get_group (parent, &peer_group);
if (peer_group && peer_group != group) {
GST_LOG ("pad %s is linked with %s\n",
GST_PAD_NAME (pad), GST_ELEMENT_NAME (parent));
linkcount++;
}
}
if (linkcount < 2) {
group_dec_links_for_element (group, element);
remove_from_group (group, element);
}
/* if linkcount == 2, it will be unlinked later on */
else if (linkcount > 2) {
g_warning
("opt: Can't handle element %s with 3 or more links, aborting",
GST_ELEMENT_NAME (element));
return;
}
}
/* Peer element will be catched during next iteration */
return;
}
/* now check which one of the elements we can remove from the group */
if (!still_link1) {
/* we only remove elements that are not the entry point of a loop based
* group and are not decoupled */
if (!(group->entry == element1 &&
group->type == GST_OPT_SCHEDULER_GROUP_LOOP) &&
!GST_ELEMENT_IS_DECOUPLED (element1)) {
GST_LOG ("el ement1 is separated from the group");
/* have to decrement links to other groups from other pads */
group_dec_links_for_element (group, element1);
remove_from_group (group, element1);
} else {
GST_LOG ("element1 is decoupled or entry in loop based group");
}
}
if (!still_link2) {
/* we only remove elements that are not the entry point of a loop based
* group and are not decoupled */
if (!(group->entry == element2 &&
group->type == GST_OPT_SCHEDULER_GROUP_LOOP) &&
!GST_ELEMENT_IS_DECOUPLED (element2)) {
GST_LOG ("element2 is separated from the group");
/* have to decrement links to other groups from other pads */
group_dec_links_for_element (group, element2);
remove_from_group (group, element2);
} else {
GST_LOG ("element2 is decoupled or entry in loop based group");
}
}
}
}
static void
gst_opt_scheduler_pad_select (GstScheduler * sched, GList * padlist)
{
//GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
g_warning ("pad select, implement me");
}
/* a scheduler iteration is done by looping and scheduling the active chains */
static GstSchedulerState
gst_opt_scheduler_iterate (GstScheduler * sched)
{
GstSchedulerState state = GST_SCHEDULER_STATE_STOPPED;
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
gint iterations = osched->iterations;
osched->state = GST_OPT_SCHEDULER_STATE_RUNNING;
GST_DEBUG_OBJECT (sched, "iterating");
while (iterations) {
gboolean scheduled = FALSE;
GSList *chains;
/* we have to schedule each of the scheduler chains now */
chains = osched->chains;
while (chains) {
GstOptSchedulerChain *chain = (GstOptSchedulerChain *) chains->data;
ref_chain (chain);
/* if the chain is not disabled, schedule it */
if (!GST_OPT_SCHEDULER_CHAIN_IS_DISABLED (chain)) {
GST_LOG ("scheduling chain %p", chain);
schedule_chain (chain);
scheduled = TRUE;
}
/* don't schedule any more chains when in error */
if (osched->state == GST_OPT_SCHEDULER_STATE_ERROR) {
GST_ERROR_OBJECT (sched, "in error state");
break;
} else if (osched->state == GST_OPT_SCHEDULER_STATE_INTERRUPTED) {
GST_DEBUG_OBJECT (osched, "got interrupted, continue with next chain");
osched->state = GST_OPT_SCHEDULER_STATE_RUNNING;
}
chains = g_slist_next (chains);
unref_chain (chain);
}
/* at this point it's possible that the scheduler state is
* in error, we then return an error */
if (osched->state == GST_OPT_SCHEDULER_STATE_ERROR) {
state = GST_SCHEDULER_STATE_ERROR;
break;
} else {
/* if chains were scheduled, return our current state */
if (scheduled)
state = GST_SCHEDULER_STATE (sched);
/* if no chains were scheduled, we say we are stopped */
else {
state = GST_SCHEDULER_STATE_STOPPED;
break;
}
}
if (iterations > 0)
iterations--;
}
return state;
}
static void
gst_opt_scheduler_show (GstScheduler * sched)
{
GstOptScheduler *osched = GST_OPT_SCHEDULER (sched);
GSList *chains;
g_print ("iterations: %d\n", osched->iterations);
g_print ("max recursion: %d\n", osched->max_recursion);
chains = osched->chains;
while (chains) {
GstOptSchedulerChain *chain = (GstOptSchedulerChain *) chains->data;
GSList *groups = chain->groups;
chains = g_slist_next (chains);
g_print ("+- chain %p: refcount %d, %d groups, %d enabled, flags %d\n",
chain, chain->refcount, chain->num_groups, chain->num_enabled,
chain->flags);
while (groups) {
GstOptSchedulerGroup *group = (GstOptSchedulerGroup *) groups->data;
GSList *elements = group->elements;
groups = g_slist_next (groups);
g_print
(" +- group %p: refcount %d, %d elements, %d enabled, flags %d, entry %s, %s\n",
group, group->refcount, group->num_elements, group->num_enabled,
group->flags,
(group->entry ? GST_ELEMENT_NAME (group->entry) : "(none)"),
(group->type ==
GST_OPT_SCHEDULER_GROUP_GET ? "get-based" : "loop-based"));
while (elements) {
GstElement *element = (GstElement *) elements->data;
elements = g_slist_next (elements);
g_print (" +- element %s\n", GST_ELEMENT_NAME (element));
}
}
}
}
static void
gst_opt_scheduler_get_property (GObject * object, guint prop_id,
GValue * value, GParamSpec * pspec)
{
GstOptScheduler *osched;
g_return_if_fail (GST_IS_OPT_SCHEDULER (object));
osched = GST_OPT_SCHEDULER (object);
switch (prop_id) {
case ARG_ITERATIONS:
g_value_set_int (value, osched->iterations);
break;
case ARG_MAX_RECURSION:
g_value_set_int (value, osched->max_recursion);
break;
default:
G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec);
break;
}
}
static void
gst_opt_scheduler_set_property (GObject * object, guint prop_id,
const GValue * value, GParamSpec * pspec)
{
GstOptScheduler *osched;
g_return_if_fail (GST_IS_OPT_SCHEDULER (object));
osched = GST_OPT_SCHEDULER (object);
switch (prop_id) {
case ARG_ITERATIONS:
osched->iterations = g_value_get_int (value);
break;
case ARG_MAX_RECURSION:
osched->max_recursion = g_value_get_int (value);
break;
default:
G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec);
break;
}
}