2016-06-04 06:03:13 +00:00
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---
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title: Different scheduling modes
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...
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# Different scheduling modes
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The scheduling mode of a pad defines how data is retrieved from (source)
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or given to (sink) pads. GStreamer can operate in two scheduling mode,
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called push- and pull-mode. GStreamer supports elements with pads in any
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of the scheduling modes where not all pads need to be operating in the
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same mode.
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So far, we have only discussed `_chain ()`-operating elements, i.e.
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elements that have a chain-function set on their sink pad and push
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buffers on their source pad(s). We call this the push-mode because a
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peer element will use `gst_pad_push ()` on a srcpad, which will cause
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our `_chain ()`-function to be called, which in turn causes our element
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to push out a buffer on the source pad. The initiative to start the
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dataflow happens somewhere upstream when it pushes out a buffer and all
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downstream elements get scheduled when their `_chain ()`-functions are
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called in turn.
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Before we explain pull-mode scheduling, let's first understand how the
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different scheduling modes are selected and activated on a pad.
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2016-06-17 22:41:07 +00:00
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## The pad activation stage
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2016-06-04 06:03:13 +00:00
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During the element state change of READY-\>PAUSED, the pads of an
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element will be activated. This happens first on the source pads and
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then on the sink pads of the element. GStreamer calls the `_activate ()`
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of a pad. By default this function will activate the pad in push-mode by
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calling `gst_pad_activate_mode ()` with the GST\_PAD\_MODE\_PUSH
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scheduling mode. It is possible to override the `_activate ()` of a pad
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and decide on a different scheduling mode. You can know in what
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scheduling mode a pad is activated by overriding the `_activate_mode
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()`-function.
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GStreamer allows the different pads of an element to operate in
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different scheduling modes. This allows for many different possible
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use-cases. What follows is an overview of some typical use-cases.
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- If all pads of an element are activated in push-mode scheduling, the
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element as a whole is operating in push-mode. For source elements
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this means that they will have to start a task that pushes out
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buffers on the source pad to the downstream elements. Downstream
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elements will have data pushed to them by upstream elements using
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the sinkpads `_chain ()`-function which will push out buffers on the
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source pads. Prerequisites for this scheduling mode are that a
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chain-function was set for each sinkpad using
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`gst_pad_set_chain_function ()` and that all downstream elements
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operate in the same mode.
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- Alternatively, sinkpads can be the driving force behind a pipeline
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by operating in pull-mode, while the sourcepads of the element still
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operate in push-mode. In order to be the driving force, those pads
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start a `GstTask` when they are activated. This task is a thread,
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which will call a function specified by the element. When called,
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this function will have random data access (through
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`gst_pad_pull_range ()`) over all sinkpads, and can push data over
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the sourcepads, which effectively means that this element controls
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data flow in the pipeline. Prerequisites for this mode are that all
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downstream elements can act in push mode, and that all upstream
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elements operate in pull-mode (see below).
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Source pads can be activated in PULL mode by a downstream element
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when they return GST\_PAD\_MODE\_PULL from the
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GST\_QUERY\_SCHEDULING query. Prerequisites for this scheduling mode
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are that a getrange-function was set for the source pad using
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`gst_pad_set_getrange_function ()`.
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- Lastly, all pads in an element can be activated in PULL-mode.
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However, contrary to the above, this does not mean that they start a
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task on their own. Rather, it means that they are pull slave for the
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downstream element, and have to provide random data access to it
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from their `_get_range ()`-function. Requirements are that the a
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`_get_range
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()`-function was set on this pad using the function
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`gst_pad_set_getrange_function ()`. Also, if the element has any
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sinkpads, all those pads (and thereby their peers) need to operate
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in PULL access mode, too.
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When a sink element is activated in PULL mode, it should start a
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task that calls `gst_pad_pull_range ()` on its sinkpad. It can only
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do this when the upstream SCHEDULING query returns support for the
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GST\_PAD\_MODE\_PULL scheduling mode.
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In the next two sections, we will go closer into pull-mode scheduling
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(elements/pads driving the pipeline, and elements/pads providing random
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access), and some specific use cases will be given.
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2016-06-17 22:41:07 +00:00
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## Pads driving the pipeline
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2016-06-04 06:03:13 +00:00
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Sinkpads operating in pull-mode, with the sourcepads operating in
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push-mode (or it has no sourcepads when it is a sink), can start a task
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that will drive the pipeline data flow. Within this task function, you
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have random access over all of the sinkpads, and push data over the
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sourcepads. This can come in useful for several different kinds of
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elements:
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- Demuxers, parsers and certain kinds of decoders where data comes in
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unparsed (such as MPEG-audio or video streams), since those will
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prefer byte-exact (random) access from their input. If possible,
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however, such elements should be prepared to operate in push-mode
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mode, too.
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- Certain kind of audio outputs, which require control over their
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input data flow, such as the Jack sound server.
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First you need to perform a SCHEDULING query to check if the upstream
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element(s) support pull-mode scheduling. If that is possible, you can
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activate the sinkpad in pull-mode. Inside the activate\_mode function
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you can then start the task.
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2016-06-06 01:50:32 +00:00
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``` c
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2016-06-04 06:03:13 +00:00
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#include "filter.h"
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#include <string.h>
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static gboolean gst_my_filter_activate (GstPad * pad,
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GstObject * parent);
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static gboolean gst_my_filter_activate_mode (GstPad * pad,
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GstObject * parent,
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GstPadMode mode,
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gboolean active);
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static void gst_my_filter_loop (GstMyFilter * filter);
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G_DEFINE_TYPE (GstMyFilter, gst_my_filter, GST_TYPE_ELEMENT);
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static void
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gst_my_filter_init (GstMyFilter * filter)
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{
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[..]
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gst_pad_set_activate_function (filter->sinkpad, gst_my_filter_activate);
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gst_pad_set_activatemode_function (filter->sinkpad,
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gst_my_filter_activate_mode);
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[..]
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}
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[..]
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static gboolean
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gst_my_filter_activate (GstPad * pad, GstObject * parent)
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{
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GstQuery *query;
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gboolean pull_mode;
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/* first check what upstream scheduling is supported */
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query = gst_query_new_scheduling ();
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if (!gst_pad_peer_query (pad, query)) {
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gst_query_unref (query);
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goto activate_push;
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}
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/* see if pull-mode is supported */
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pull_mode = gst_query_has_scheduling_mode_with_flags (query,
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GST_PAD_MODE_PULL, GST_SCHEDULING_FLAG_SEEKABLE);
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gst_query_unref (query);
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if (!pull_mode)
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goto activate_push;
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/* now we can activate in pull-mode. GStreamer will also
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* activate the upstream peer in pull-mode */
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return gst_pad_activate_mode (pad, GST_PAD_MODE_PULL, TRUE);
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activate_push:
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{
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/* something not right, we fallback to push-mode */
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return gst_pad_activate_mode (pad, GST_PAD_MODE_PUSH, TRUE);
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}
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}
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static gboolean
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gst_my_filter_activate_pull (GstPad * pad,
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GstObject * parent,
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GstPadMode mode,
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gboolean active)
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{
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gboolean res;
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GstMyFilter *filter = GST_MY_FILTER (parent);
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switch (mode) {
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case GST_PAD_MODE_PUSH:
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res = TRUE;
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break;
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case GST_PAD_MODE_PULL:
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if (active) {
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filter->offset = 0;
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res = gst_pad_start_task (pad,
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(GstTaskFunction) gst_my_filter_loop, filter, NULL);
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} else {
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res = gst_pad_stop_task (pad);
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}
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break;
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default:
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/* unknown scheduling mode */
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res = FALSE;
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break;
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}
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return res;
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}
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```
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Once started, your task has full control over input and output. The most
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simple case of a task function is one that reads input and pushes that
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over its source pad. It's not all that useful, but provides some more
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flexibility than the old push-mode case that we've been looking at so
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far.
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2016-06-06 01:50:32 +00:00
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``` c
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2016-06-04 06:03:13 +00:00
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#define BLOCKSIZE 2048
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static void
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gst_my_filter_loop (GstMyFilter * filter)
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{
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GstFlowReturn ret;
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guint64 len;
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GstFormat fmt = GST_FORMAT_BYTES;
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GstBuffer *buf = NULL;
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if (!gst_pad_query_duration (filter->sinkpad, fmt, &len)) {
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GST_DEBUG_OBJECT (filter, "failed to query duration, pausing");
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goto stop;
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}
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if (filter->offset >= len) {
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GST_DEBUG_OBJECT (filter, "at end of input, sending EOS, pausing");
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gst_pad_push_event (filter->srcpad, gst_event_new_eos ());
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goto stop;
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}
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/* now, read BLOCKSIZE bytes from byte offset filter->offset */
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ret = gst_pad_pull_range (filter->sinkpad, filter->offset,
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BLOCKSIZE, &buf);
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if (ret != GST_FLOW_OK) {
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GST_DEBUG_OBJECT (filter, "pull_range failed: %s", gst_flow_get_name (ret));
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goto stop;
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}
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/* now push buffer downstream */
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ret = gst_pad_push (filter->srcpad, buf);
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buf = NULL; /* gst_pad_push() took ownership of buffer */
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if (ret != GST_FLOW_OK) {
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GST_DEBUG_OBJECT (filter, "pad_push failed: %s", gst_flow_get_name (ret));
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goto stop;
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}
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/* everything is fine, increase offset and wait for us to be called again */
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filter->offset += BLOCKSIZE;
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return;
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stop:
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GST_DEBUG_OBJECT (filter, "pausing task");
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gst_pad_pause_task (filter->sinkpad);
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}
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2016-06-06 01:50:32 +00:00
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```
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2016-06-04 06:03:13 +00:00
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2016-06-17 22:41:07 +00:00
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## Providing random access
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2016-06-04 06:03:13 +00:00
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In the previous section, we have talked about how elements (or pads)
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that are activated to drive the pipeline using their own task, must use
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pull-mode scheduling on their sinkpads. This means that all pads linked
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to those pads need to be activated in pull-mode. Source pads activated
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in pull-mode must implement a `_get_range ()`-function set using
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`gst_pad_set_getrange_function ()`, and that function will be called
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when the peer pad requests some data with `gst_pad_pull_range ()`. The
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element is then responsible for seeking to the right offset and
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providing the requested data. Several elements can implement random
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access:
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- Data sources, such as a file source, that can provide data from any
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offset with reasonable low latency.
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- Filters that would like to provide a pull-mode scheduling over the
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whole pipeline.
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- Parsers who can easily provide this by skipping a small part of
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their input and are thus essentially "forwarding" getrange requests
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literally without any own processing involved. Examples include tag
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readers (e.g. ID3) or single output parsers, such as a WAVE parser.
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The following example will show how a `_get_range
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()`-function can be implemented in a source element:
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#include "filter.h"
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static GstFlowReturn
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gst_my_filter_get_range (GstPad * pad,
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GstObject * parent,
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guint64 offset,
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guint length,
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GstBuffer ** buf);
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G_DEFINE_TYPE (GstMyFilter, gst_my_filter, GST_TYPE_ELEMENT);
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static void
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gst_my_filter_init (GstMyFilter * filter)
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{
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[..]
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gst_pad_set_getrange_function (filter->srcpad,
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gst_my_filter_get_range);
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[..]
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}
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static GstFlowReturn
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gst_my_filter_get_range (GstPad * pad,
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GstObject * parent,
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guint64 offset,
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guint length,
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GstBuffer ** buf)
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{
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GstMyFilter *filter = GST_MY_FILTER (parent);
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[.. here, you would fill *buf ..]
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return GST_FLOW_OK;
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}
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In practice, many elements that could theoretically do random access,
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may in practice often be activated in push-mode scheduling anyway, since
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there is no downstream element able to start its own task. Therefore, in
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practice, those elements should implement both a `_get_range
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()`-function and a `_chain
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()`-function (for filters and parsers) or a `_get_range
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()`-function and be prepared to start their own task by providing
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`_activate_* ()`-functions (for source elements).
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