--- title: Buffering ... # Buffering The purpose of buffering is to accumulate enough data in a pipeline so that playback can occur smoothly and without interruptions. It is typically done when reading from a (slow) and non-live network source but can also be used for live sources. GStreamer provides support for the following use cases: - Buffering up to a specific amount of data, in memory, before starting playback so that network fluctuations are minimized. See [Stream buffering](#stream-buffering). - Download of the network file to a local disk with fast seeking in the downloaded data. This is similar to the quicktime/youtube players. See [Download buffering](#download-buffering). - Caching of (semi)-live streams to a local, on disk, ringbuffer with seeking in the cached area. This is similar to tivo-like timeshifting. See [Timeshift buffering](#timeshift-buffering). GStreamer can provide the application with progress reports about the current buffering state as well as let the application decide on how to buffer and when the buffering stops. In the most simple case, the application has to listen for BUFFERING messages on the bus. If the percent indicator inside the BUFFERING message is smaller than 100, the pipeline is buffering. When a message is received with 100 percent, buffering is complete. In the buffering state, the application should keep the pipeline in the PAUSED state. When buffering completes, it can put the pipeline (back) in the PLAYING state. What follows is an example of how the message handler could deal with the BUFFERING messages. We will see more advanced methods in [Buffering strategies](#buffering-strategies). ``` c [...] switch (GST_MESSAGE_TYPE (message)) { case GST_MESSAGE_BUFFERING:{ gint percent; /* no state management needed for live pipelines */ if (is_live) break; gst_message_parse_buffering (message, &percent); if (percent == 100) { /* a 100% message means buffering is done */ buffering = FALSE; /* if the desired state is playing, go back */ if (target_state == GST_STATE_PLAYING) { gst_element_set_state (pipeline, GST_STATE_PLAYING); } } else { /* buffering busy */ if (!buffering && target_state == GST_STATE_PLAYING) { /* we were not buffering but PLAYING, PAUSE the pipeline. */ gst_element_set_state (pipeline, GST_STATE_PAUSED); } buffering = TRUE; } break; case ... [...] ``` # Stream buffering ``` +---------+ +---------+ +-------+ | httpsrc | | buffer | | demux | | src - sink src - sink .... +---------+ +---------+ +-------+ ``` In this case we are reading from a slow network source into a buffer element (such as queue2). The buffer element has a low and high watermark expressed in bytes. The buffer uses the watermarks as follows: - The buffer element will post BUFFERING messages until the high watermark is hit. This instructs the application to keep the pipeline PAUSED, which will eventually block the srcpad from pushing while data is prerolled in the sinks. - When the high watermark is hit, a BUFFERING message with 100% will be posted, which instructs the application to continue playback. - When during playback, the low watermark is hit, the queue will start posting BUFFERING messages again, making the application PAUSE the pipeline again until the high watermark is hit again. This is called the rebuffering stage. - During playback, the queue level will fluctuate between the high and the low watermark as a way to compensate for network irregularities. This buffering method is usable when the demuxer operates in push mode. Seeking in the stream requires the seek to happen in the network source. It is mostly desirable when the total duration of the file is not known, such as in live streaming or when efficient seeking is not possible/required. The problem is configuring a good low and high watermark. Here are some ideas: - It is possible to measure the network bandwidth and configure the low/high watermarks in such a way that buffering takes a fixed amount of time. The queue2 element in GStreamer core has the max-size-time property that, together with the use-rate-estimate property, does exactly that. Also the playbin buffer-duration property uses the rate estimate to scale the amount of data that is buffered. - Based on the codec bitrate, it is also possible to set the watermarks in such a way that a fixed amount of data is buffered before playback starts. Normally, the buffering element doesn't know about the bitrate of the stream but it can get this with a query. - Start with a fixed amount of bytes, measure the time between rebuffering and increase the queue size until the time between rebuffering is within the application's chosen limits. The buffering element can be inserted anywhere in the pipeline. You could, for example, insert the buffering element before a decoder. This would make it possible to set the low/high watermarks based on time. The buffering flag on playbin, performs buffering on the parsed data. Another advantage of doing the buffering at a later stage is that you can let the demuxer operate in pull mode. When reading data from a slow network drive (with filesrc) this can be an interesting way to buffer. # Download buffering ``` +---------+ +---------+ +-------+ | httpsrc | | buffer | | demux | | src - sink src - sink .... +---------+ +----|----+ +-------+ V file ``` If we know the server is streaming a fixed length file to the client, the application can choose to download the entire file on disk. The buffer element will provide a push or pull based srcpad to the demuxer to navigate in the downloaded file. This mode is only suitable when the client can determine the length of the file on the server. In this case, buffering messages will be emitted as usual when the requested range is not within the downloaded area + buffersize. The buffering message will also contain an indication that incremental download is being performed. This flag can be used to let the application control the buffering in a more intelligent way, using the BUFFERING query, for example. See [Buffering strategies](#buffering-strategies). # Timeshift buffering ``` +---------+ +---------+ +-------+ | httpsrc | | buffer | | demux | | src - sink src - sink .... +---------+ +----|----+ +-------+ V file-ringbuffer ``` In this mode, a fixed size ringbuffer is kept to download the server content. This allows for seeking in the buffered data. Depending on the size of the ringbuffer one can seek further back in time. This mode is suitable for all live streams. As with the incremental download mode, buffering messages are emitted along with an indication that timeshifting download is in progress. # Live buffering In live pipelines we usually introduce some fixed latency between the capture and the playback elements. This latency can be introduced by a queue (such as a jitterbuffer) or by other means (in the audiosink). Buffering messages can be emitted in those live pipelines as well and serve as an indication to the user of the latency buffering. The application usually does not react to these buffering messages with a state change. # Buffering strategies What follows are some ideas for implementing different buffering strategies based on the buffering messages and buffering query. ## No-rebuffer strategy We would like to buffer enough data in the pipeline so that playback continues without interruptions. What we need to know to implement this is know the total remaining playback time in the file and the total remaining download time. If the buffering time is less than the playback time, we can start playback without interruptions. We have all this information available with the DURATION, POSITION and BUFFERING queries. We need to periodically execute the buffering query to get the current buffering status. We also need to have a large enough buffer to hold the complete file, worst case. It is best to use this buffering strategy with download buffering (see [Download buffering](#download-buffering)). This is what the code would look like: ``` c #include GstState target_state; static gboolean is_live; static gboolean is_buffering; static gboolean buffer_timeout (gpointer data) { GstElement *pipeline = data; GstQuery *query; gboolean busy; gint percent; gint64 estimated_total; gint64 position, duration; guint64 play_left; query = gst_query_new_buffering (GST_FORMAT_TIME); if (!gst_element_query (pipeline, query)) return TRUE; gst_query_parse_buffering_percent (query, &busy, &percent); gst_query_parse_buffering_range (query, NULL, NULL, NULL, &estimated_total); if (estimated_total == -1) estimated_total = 0; /* calculate the remaining playback time */ if (!gst_element_query_position (pipeline, GST_FORMAT_TIME, &position)) position = -1; if (!gst_element_query_duration (pipeline, GST_FORMAT_TIME, &duration)) duration = -1; if (duration != -1 && position != -1) play_left = GST_TIME_AS_MSECONDS (duration - position); else play_left = 0; g_message ("play_left %" G_GUINT64_FORMAT", estimated_total %" G_GUINT64_FORMAT ", percent %d", play_left, estimated_total, percent); /* we are buffering or the estimated download time is bigger than the * remaining playback time. We keep buffering. */ is_buffering = (busy || estimated_total * 1.1 > play_left); if (!is_buffering) gst_element_set_state (pipeline, target_state); return is_buffering; } static void on_message_buffering (GstBus *bus, GstMessage *message, gpointer user_data) { GstElement *pipeline = user_data; gint percent; /* no state management needed for live pipelines */ if (is_live) return; gst_message_parse_buffering (message, &percent); if (percent < 100) { /* buffering busy */ if (!is_buffering) { is_buffering = TRUE; if (target_state == GST_STATE_PLAYING) { /* we were not buffering but PLAYING, PAUSE the pipeline. */ gst_element_set_state (pipeline, GST_STATE_PAUSED); } } } } static void on_message_async_done (GstBus *bus, GstMessage *message, gpointer user_data) { GstElement *pipeline = user_data; if (!is_buffering) gst_element_set_state (pipeline, target_state); else g_timeout_add (500, buffer_timeout, pipeline); } gint main (gint argc, gchar *argv[]) { GstElement *pipeline; GMainLoop *loop; GstBus *bus; GstStateChangeReturn ret; /* init GStreamer */ gst_init (&argc, &argv); loop = g_main_loop_new (NULL, FALSE); /* make sure we have a URI */ if (argc != 2) { g_print ("Usage: %s <URI>\n", argv[0]); return -1; } /* set up */ pipeline = gst_element_factory_make ("playbin", "pipeline"); g_object_set (G_OBJECT (pipeline), "uri", argv[1], NULL); g_object_set (G_OBJECT (pipeline), "flags", 0x697 , NULL); bus = gst_pipeline_get_bus (GST_PIPELINE (pipeline)); gst_bus_add_signal_watch (bus); g_signal_connect (bus, "message::buffering", (GCallback) on_message_buffering, pipeline); g_signal_connect (bus, "message::async-done", (GCallback) on_message_async_done, pipeline); gst_object_unref (bus); is_buffering = FALSE; target_state = GST_STATE_PLAYING; ret = gst_element_set_state (pipeline, GST_STATE_PAUSED); switch (ret) { case GST_STATE_CHANGE_SUCCESS: is_live = FALSE; break; case GST_STATE_CHANGE_FAILURE: g_warning ("failed to PAUSE"); return -1; case GST_STATE_CHANGE_NO_PREROLL: is_live = TRUE; break; default: break; } /* now run */ g_main_loop_run (loop); /* also clean up */ gst_element_set_state (pipeline, GST_STATE_NULL); gst_object_unref (GST_OBJECT (pipeline)); g_main_loop_unref (loop); return 0; } ``` See how we set the pipeline to the PAUSED state first. We will receive buffering messages during the preroll state when buffering is needed. When we are prerolled (on\_message\_async\_done) we see if buffering is going on, if not, we start playback. If buffering was going on, we start a timeout to poll the buffering state. If the estimated time to download is less than the remaining playback time, we start playback.