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/*
* Copyright (c) 2007,2008 Wayne Meissner
* Copyright (C) 1999,2000 Erik Walthinsen
* 2004,2005 Wim Taymans
*
* This file is part of gstreamer-java.
*
* This code is free software: you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License version 3 only, as
* published by the Free Software Foundation.
*
* This code 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 Lesser General Public License
* version 3 for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* version 3 along with this work. If not, see
* Elements are added and removed from the pipeline using the {@code Bin}
* methods like {@link Bin#add add} and {@link Bin#remove remove}.
*
*
* Before changing the state of the Pipeline (see {@link Element}) a
* {@link Bus} can be retrieved with {@link #getBus getBus}. This bus can then
* be used to receive {@link Message}s from the elements in the pipeline.
*
*
* By default, a Pipeline will automatically flush the pending Bus
* messages when going to the NULL state to ensure that no circular
* references exist when no messages are read from the Bus. This
* behaviour can be changed with {@link #setAutoFlushBus setAutoFlushBus}
*
*
* When the Pipeline performs the PAUSED to PLAYING state change it will
* select a clock for the elements. The clock selection algorithm will by
* default select a clock provided by an element that is most upstream
* (closest to the source). For live pipelines (ones that return
* {@link StateChangeReturn#NO_PREROLL} from the
* {@link Element#setState setState} call) this will select the clock provided
* by the live source. For normal pipelines this will select a clock provided
* by the sinks (most likely the audio sink). If no element provides a clock,
* a default SystemClock is used.
*
*
* The clock selection can be controlled with the gst_pipeline_use_clock()
* method, which will enforce a given clock on the pipeline. With
* gst_pipeline_auto_clock() the default clock selection algorithm can be
* restored.
*
*
* A Pipeline maintains a stream time for the elements. The stream
* time is defined as the difference between the current clock time and
* the base time. When the pipeline goes to READY or a flushing seek is
* performed on it, the stream time is reset to 0. When the pipeline is
* set from PLAYING to PAUSED, the current clock time is sampled and used to
* configure the base time for the elements when the pipeline is set
* to PLAYING again. This default behaviour can be changed with the
* gst_pipeline_set_new_stream_time() method.
*
* When sending a flushing seek event to a GstPipeline (see
* {@link #seek seek}), it will make sure that the pipeline is properly
* PAUSED and resumed as well as set the new stream time to 0 when the
* seek succeeded.
*/
public class Pipeline extends Bin {
private static interface API extends GstElementAPI, GstPipelineAPI, GstParseAPI {
@CallerOwnsReturn Pointer ptr_gst_pipeline_new(String name);
}
private static final API gst = GstNative.load(API.class);
public static final String GST_NAME = "pipeline";
public Pipeline(Initializer init) {
super(init);
}
/**
* Creates a new instance of Pipeline with a unique name.
*/
public Pipeline() {
this(initializer(gst.ptr_gst_pipeline_new(null)));
initBus();
}
/**
* Creates a new instance of Pipeline with the given name.
*
* @param name The name used to identify this pipeline.
*/
public Pipeline(String name) {
this(initializer(gst.ptr_gst_pipeline_new(name)));
initBus();
}
/**
* Creates a pipeline from a text pipeline description.
*
* This function allows creation of a pipeline based on the syntax used in the
* gst-launch utillity.
*
* @param pipelineDecription the command line describing the pipeline
* @return The new Pipeline.
*/
public static Pipeline launch(String pipelineDecription) {
Pointer[] err = { null };
Pipeline pipeline = gst.gst_parse_launch(pipelineDecription, err);
if (pipeline == null) {
throw new GstException(new GError(new GErrorStruct(err[0])));
}
pipeline.initBus();
return pipeline;
}
/**
* Creates a pipeline from a text pipeline description.
*
* This function allows creation of a pipeline based on the syntax used in the
* gst-launch utillity.
*
* @param pipelineDecription An array of strings containing the command line describing the pipeline.
* @return The new Pipeline.
*/
public static Pipeline launch(String... pipelineDecription) {
Pointer[] err = { null };
Pipeline pipeline = gst.gst_parse_launchv(pipelineDecription, err);
if (pipeline == null) {
throw new GstException(new GError(new GErrorStruct(err[0])));
}
pipeline.initBus();
return pipeline;
}
private void initBus() {
Bus bus = getBus();
//
// This is mostly a hack to get the Bus to install a sync message handler
//
bus.setFlushing(true);
bus.setFlushing(false);
}
/**
* Sets this pipeline to automatically flush {@link Bus} messages or not.
*
* @param flush true if automatic flushing is desired, else false.
*/
public void setAutoFlushBus(boolean flush) {
gst.gst_pipeline_set_auto_flush_bus(this, flush);
}
/**
* Checks if the pipeline will automatically flush messages when going to the NULL state.
*
* @return true if the pipeline automatically flushes messages.
*/
public boolean getAutoFlushBus() {
return gst.gst_pipeline_get_auto_flush_bus(this);
}
/**
* Set the clock for pipeline.
* The clock will be distributed to all the elements managed by the pipeline.
*
MT safe
*
* @param clock The {@link Clock} to use
* @return true if the clock could be set on the pipeline, false if some
* element did not accept the clock.
*
*/
public boolean setClock(Clock clock) {
return gst.gst_pipeline_set_clock(this, clock);
}
/**
* Return the current {@link Clock} used by the pipeline.
*
* @return The {@link Clock} currently in use.
*/
public Clock getClock() {
return gst.gst_pipeline_get_clock(this);
}
/**
* Force the Pipeline to use the a specific clock.
* The pipeline will always use the given clock even if new clock
* providers are added to this pipeline.
*
MT safe
*
* @param clock The {@link Clock} to use. If clock is null, all clocking is
* disabled, and the pipeline will run as fast as possible.
*
*/
public void useClock(Clock clock) {
gst.gst_pipeline_use_clock(this, clock);
}
/**
* Gets the {@link Bus} this pipeline uses for messages.
*
* @return The {@link Bus} that this pipeline uses.
*/
@Override
public Bus getBus() {
return gst.gst_pipeline_get_bus(this);
}
/**
* Sets the position in the media stream to time.
*
* @param time The time to change the position to.
* @return true if seek is successful
*/
public boolean seek(ClockTime time) {
return seek(time.convertTo(TimeUnit.NANOSECONDS), TimeUnit.NANOSECONDS);
}
/**
* Sets the current position in the media stream.
*
* @param time the time to change the position to.
* @param unit the {@code TimeUnit} the time is expressed in.
* @return true if seek is successful
*/
public boolean seek(long time, TimeUnit unit) {
return seek(1.0, Format.TIME, SeekFlags.FLUSH | SeekFlags.KEY_UNIT,
SeekType.SET, TimeUnit.NANOSECONDS.convert(time, unit),
SeekType.NONE, -1);
}
/**
* Seeks to a new position in the media stream.
*
*
* The start and stop values are expressed in format.
*
* A rate of 1.0 means normal playback rate, 2.0 means double speed.
* Negative values means backwards playback. A value of 0.0 for the
* rate is not allowed and should be accomplished instead by PAUSING the
* pipeline.
*
* A pipeline has a default playback segment configured with a start
* position of 0, a stop position of -1 and a rate of 1.0. The currently
* configured playback segment can be queried with #GST_QUERY_SEGMENT.
*
* and stopType specify how to adjust the currently configured
* start and stop fields in segment. Adjustments can be made relative or
* absolute to the last configured values. A type of {@link SeekType#NONE} means
* that the position should not be updated.
*
* When the rate is positive and start has been updated, playback will start
* from the newly configured start position.
*
* For negative rates, playback will start from the newly configured stop
* position (if any). If the stop position if updated, it must be different from
* -1 for negative rates.
*
* It is not possible to seek relative to the current playback position, to do
* this, PAUSE the pipeline, query the current playback position with
* {@link org.gstreamer.Pipeline#queryPosition queryPosition} and update the playback segment
* current position with a {@link SeekType#SET} to the desired position.
*
* @param rate the new playback rate
* @param format the format of the seek values
* @param flags the optional seek flags
* @param startType the type and flags for the new start position
* @param start the value of the new start position
* @param stopType the type and flags for the new stop position
* @param stop the value of the new stop position
* @return true if seek is successful
*/
public boolean seek(double rate, Format format, int flags,
SeekType startType, long start, SeekType stopType, long stop) {
return gst.gst_element_seek(this, rate, format, flags,
startType, start, stopType, stop);
}
/**
* Gets the current position in the media stream in units of time.
*
* @return the ClockTime representing the current position.
*/
public ClockTime queryPosition() {
return ClockTime.valueOf(queryPosition(Format.TIME), TimeUnit.NANOSECONDS);
}
/**
* Gets the current position in the media stream.
*
* @param unit the {@code TimeUnit} to return the position in terms of.
* @return a time value representing the current position in units of unit.
*/
public long queryPosition(TimeUnit unit) {
return unit.convert(queryPosition(Format.TIME), TimeUnit.NANOSECONDS);
}
/**
* Gets the current position in terms of the specified {@link Format}.
*
* @param format The {@link Format} to return the position in.
* @return The current position or -1 if the query failed.
*/
public long queryPosition(Format format) {
Format[] fmt = { format };
long[] pos = { 0 };
return gst.gst_element_query_position(this, fmt, pos) ? pos[0] : -1L;
}
/**
* Gets the time duration of the current media stream.
*
* @return The total duration of the current media stream.
*/
public ClockTime queryDuration() {
return ClockTime.valueOf(queryDuration(TimeUnit.NANOSECONDS), TimeUnit.NANOSECONDS);
}
/**
* Gets the time duration of the current media stream.
*
* @param unit the {@code TimeUnit} to return the position in.
* @return The total duration of the current media stream.
*/
public long queryDuration(TimeUnit unit) {
Format[] fmt = { Format.TIME };
long[] duration = { 0 };
gst.gst_element_query_duration(this, fmt, duration);
return unit.convert(duration[0], TimeUnit.NANOSECONDS);
}
/**
* Gets the duration of the current media stream in terms of the specified {@link Format}.
*
* @param format the {@code Format} to return the duration in.
* @return The total duration of the current media stream.
*/
public long queryDuration(Format format) {
Format[] fmt = { format };
long[] duration = { 0 };
gst.gst_element_query_duration(this, fmt, duration);
return duration[0];
}
/**
* Gets the {@link Segment} for the current media stream in terms of the specified {@link Format}.
*
* @return The information regarding the current {@code Segment}.
*/
public Segment querySegment() {
return querySegment(Format.TIME);
}
/**
* Gets the {@link Segment} for the current media stream in terms of the specified {@link Format}.
*
* @param format the {@code Format} to return the segment in.
* @return The information regarding the current {@code Segment}.
*/
public Segment querySegment(Format format) {
Query qry = GstQueryAPI.GSTQUERY_API.gst_query_new_segment(format);
gst.gst_element_query(this, qry);
double[] rate = { 0.0D };
Format[] fmt = { Format.UNDEFINED };
long[] start_value = { 0 };
long[] stop_value = { 0 };
GstQueryAPI.GSTQUERY_API.gst_query_parse_segment(qry, rate, fmt, start_value, stop_value);
return new Segment(rate[0], fmt[0], start_value[0], stop_value[0]);
}
}