/* GStreamer * Copyright (C) <2007> Wim Taymans * * 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. */ #include #include #include #include #include "rtpjitterbuffer.h" GST_DEBUG_CATEGORY_STATIC (rtp_jitter_buffer_debug); #define GST_CAT_DEFAULT rtp_jitter_buffer_debug #define MAX_WINDOW RTP_JITTER_BUFFER_MAX_WINDOW #define MAX_TIME (2 * GST_SECOND) /* signals and args */ enum { LAST_SIGNAL }; enum { PROP_0 }; /* GObject vmethods */ static void rtp_jitter_buffer_finalize (GObject * object); GType rtp_jitter_buffer_mode_get_type (void) { static GType jitter_buffer_mode_type = 0; static const GEnumValue jitter_buffer_modes[] = { {RTP_JITTER_BUFFER_MODE_NONE, "Only use RTP timestamps", "none"}, {RTP_JITTER_BUFFER_MODE_SLAVE, "Slave receiver to sender clock", "slave"}, {RTP_JITTER_BUFFER_MODE_BUFFER, "Do low/high watermark buffering", "buffer"}, {0, NULL, NULL}, }; if (!jitter_buffer_mode_type) { jitter_buffer_mode_type = g_enum_register_static ("RTPJitterBufferMode", jitter_buffer_modes); } return jitter_buffer_mode_type; } /* static guint rtp_jitter_buffer_signals[LAST_SIGNAL] = { 0 }; */ G_DEFINE_TYPE (RTPJitterBuffer, rtp_jitter_buffer, G_TYPE_OBJECT); static void rtp_jitter_buffer_class_init (RTPJitterBufferClass * klass) { GObjectClass *gobject_class; gobject_class = (GObjectClass *) klass; gobject_class->finalize = rtp_jitter_buffer_finalize; GST_DEBUG_CATEGORY_INIT (rtp_jitter_buffer_debug, "rtpjitterbuffer", 0, "RTP Jitter Buffer"); } static void rtp_jitter_buffer_init (RTPJitterBuffer * jbuf) { jbuf->packets = g_queue_new (); jbuf->mode = RTP_JITTER_BUFFER_MODE_SLAVE; rtp_jitter_buffer_reset_skew (jbuf); } static void rtp_jitter_buffer_finalize (GObject * object) { RTPJitterBuffer *jbuf; jbuf = RTP_JITTER_BUFFER_CAST (object); rtp_jitter_buffer_flush (jbuf); g_queue_free (jbuf->packets); G_OBJECT_CLASS (rtp_jitter_buffer_parent_class)->finalize (object); } /** * rtp_jitter_buffer_new: * * Create an #RTPJitterBuffer. * * Returns: a new #RTPJitterBuffer. Use g_object_unref() after usage. */ RTPJitterBuffer * rtp_jitter_buffer_new (void) { RTPJitterBuffer *jbuf; jbuf = g_object_new (RTP_TYPE_JITTER_BUFFER, NULL); return jbuf; } /** * rtp_jitter_buffer_get_mode: * @jbuf: an #RTPJitterBuffer * * Get the current jitterbuffer mode. * * Returns: the current jitterbuffer mode. */ RTPJitterBufferMode rtp_jitter_buffer_get_mode (RTPJitterBuffer * jbuf) { return jbuf->mode; } /** * rtp_jitter_buffer_set_mode: * @jbuf: an #RTPJitterBuffer * @mode: a #RTPJitterBufferMode * * Set the buffering and clock slaving algorithm used in the @jbuf. */ void rtp_jitter_buffer_set_mode (RTPJitterBuffer * jbuf, RTPJitterBufferMode mode) { jbuf->mode = mode; } GstClockTime rtp_jitter_buffer_get_delay (RTPJitterBuffer * jbuf) { return jbuf->delay; } void rtp_jitter_buffer_set_delay (RTPJitterBuffer * jbuf, GstClockTime delay) { jbuf->delay = delay; jbuf->low_level = (delay * 15) / 100; /* the high level is at 90% in order to release packets before we fill up the * buffer up to the latency */ jbuf->high_level = (delay * 90) / 100; GST_DEBUG ("delay %" GST_TIME_FORMAT ", min %" GST_TIME_FORMAT ", max %" GST_TIME_FORMAT, GST_TIME_ARGS (jbuf->delay), GST_TIME_ARGS (jbuf->low_level), GST_TIME_ARGS (jbuf->high_level)); } /** * rtp_jitter_buffer_reset_skew: * @jbuf: an #RTPJitterBuffer * * Reset the skew calculations in @jbuf. */ void rtp_jitter_buffer_reset_skew (RTPJitterBuffer * jbuf) { jbuf->base_time = -1; jbuf->base_rtptime = -1; jbuf->base_extrtp = -1; jbuf->clock_rate = -1; jbuf->ext_rtptime = -1; jbuf->last_rtptime = -1; jbuf->window_pos = 0; jbuf->window_filling = TRUE; jbuf->window_min = 0; jbuf->skew = 0; jbuf->prev_send_diff = -1; jbuf->prev_out_time = -1; GST_DEBUG ("reset skew correction"); } static void rtp_jitter_buffer_resync (RTPJitterBuffer * jbuf, GstClockTime time, GstClockTime gstrtptime, guint64 ext_rtptime, gboolean reset_skew) { jbuf->base_time = time; jbuf->base_rtptime = gstrtptime; jbuf->base_extrtp = ext_rtptime; jbuf->prev_out_time = -1; jbuf->prev_send_diff = -1; if (reset_skew) { jbuf->window_filling = TRUE; jbuf->window_pos = 0; jbuf->window_min = 0; jbuf->window_size = 0; jbuf->skew = 0; } } static guint64 get_buffer_level (RTPJitterBuffer * jbuf) { GstBuffer *high_buf = NULL, *low_buf = NULL; guint64 level; GList *find; /* first first buffer with timestamp */ find = g_queue_peek_head_link (jbuf->packets); while (find) { high_buf = find->data; if (GST_BUFFER_TIMESTAMP (high_buf) != -1) break; high_buf = NULL; find = g_list_next (find); } find = g_queue_peek_tail_link (jbuf->packets); while (find) { low_buf = find->data; if (GST_BUFFER_TIMESTAMP (low_buf) != -1) break; low_buf = NULL; find = g_list_previous (find); } if (!high_buf || !low_buf || high_buf == low_buf) { level = 0; } else { guint64 high_ts, low_ts; high_ts = GST_BUFFER_TIMESTAMP (high_buf); low_ts = GST_BUFFER_TIMESTAMP (low_buf); if (high_ts > low_ts) level = high_ts - low_ts; else level = 0; GST_LOG_OBJECT (jbuf, "low %" GST_TIME_FORMAT " high %" GST_TIME_FORMAT " level %" G_GUINT64_FORMAT, GST_TIME_ARGS (low_ts), GST_TIME_ARGS (high_ts), level); } return level; } static void update_buffer_level (RTPJitterBuffer * jbuf, gint * percent) { gboolean post = FALSE; guint64 level; level = get_buffer_level (jbuf); GST_DEBUG ("buffer level %" GST_TIME_FORMAT, GST_TIME_ARGS (level)); if (jbuf->buffering) { post = TRUE; if (level > jbuf->high_level) { GST_DEBUG ("buffering finished"); jbuf->buffering = FALSE; } } else { if (level < jbuf->low_level) { GST_DEBUG ("buffering started"); jbuf->buffering = TRUE; post = TRUE; } } if (post) { gint perc; if (jbuf->buffering && (jbuf->high_level != 0)) { perc = (level * 100 / jbuf->high_level); perc = MIN (perc, 100); } else { perc = 100; } if (percent) *percent = perc; GST_DEBUG ("buffering %d", perc); } } /* For the clock skew we use a windowed low point averaging algorithm as can be * found in Fober, Orlarey and Letz, 2005, "Real Time Clock Skew Estimation * over Network Delays": * http://www.grame.fr/Ressources/pub/TR-050601.pdf * http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.102.1546 * * The idea is that the jitter is composed of: * * J = N + n * * N : a constant network delay. * n : random added noise. The noise is concentrated around 0 * * In the receiver we can track the elapsed time at the sender with: * * send_diff(i) = (Tsi - Ts0); * * Tsi : The time at the sender at packet i * Ts0 : The time at the sender at the first packet * * This is the difference between the RTP timestamp in the first received packet * and the current packet. * * At the receiver we have to deal with the jitter introduced by the network. * * recv_diff(i) = (Tri - Tr0) * * Tri : The time at the receiver at packet i * Tr0 : The time at the receiver at the first packet * * Both of these values contain a jitter Ji, a jitter for packet i, so we can * write: * * recv_diff(i) = (Cri + D + ni) - (Cr0 + D + n0)) * * Cri : The time of the clock at the receiver for packet i * D + ni : The jitter when receiving packet i * * We see that the network delay is irrelevant here as we can elliminate D: * * recv_diff(i) = (Cri + ni) - (Cr0 + n0)) * * The drift is now expressed as: * * Drift(i) = recv_diff(i) - send_diff(i); * * We now keep the W latest values of Drift and find the minimum (this is the * one with the lowest network jitter and thus the one which is least affected * by it). We average this lowest value to smooth out the resulting network skew. * * Both the window and the weighting used for averaging influence the accuracy * of the drift estimation. Finding the correct parameters turns out to be a * compromise between accuracy and inertia. * * We use a 2 second window or up to 512 data points, which is statistically big * enough to catch spikes (FIXME, detect spikes). * We also use a rather large weighting factor (125) to smoothly adapt. During * startup, when filling the window, we use a parabolic weighting factor, the * more the window is filled, the faster we move to the detected possible skew. * * Returns: @time adjusted with the clock skew. */ static GstClockTime calculate_skew (RTPJitterBuffer * jbuf, guint32 rtptime, GstClockTime time, guint32 clock_rate) { guint64 ext_rtptime; guint64 send_diff, recv_diff; gint64 delta; gint64 old; gint pos, i; GstClockTime gstrtptime, out_time; guint64 slope; ext_rtptime = gst_rtp_buffer_ext_timestamp (&jbuf->ext_rtptime, rtptime); gstrtptime = gst_util_uint64_scale_int (ext_rtptime, GST_SECOND, clock_rate); /* keep track of the last extended rtptime */ jbuf->last_rtptime = ext_rtptime; if (jbuf->clock_rate != clock_rate) { if (jbuf->clock_rate == -1) { GST_DEBUG ("Clock rate changed from %" G_GUINT32_FORMAT " to %" G_GUINT32_FORMAT, jbuf->clock_rate, clock_rate); } else { GST_WARNING ("Clock rate changed from %" G_GUINT32_FORMAT " to %" G_GUINT32_FORMAT, jbuf->clock_rate, clock_rate); } jbuf->base_time = -1; jbuf->base_rtptime = -1; jbuf->clock_rate = clock_rate; jbuf->prev_out_time = -1; jbuf->prev_send_diff = -1; } /* first time, lock on to time and gstrtptime */ if (G_UNLIKELY (jbuf->base_time == -1)) { jbuf->base_time = time; jbuf->prev_out_time = -1; GST_DEBUG ("Taking new base time %" GST_TIME_FORMAT, GST_TIME_ARGS (time)); } if (G_UNLIKELY (jbuf->base_rtptime == -1)) { jbuf->base_rtptime = gstrtptime; jbuf->base_extrtp = ext_rtptime; jbuf->prev_send_diff = -1; GST_DEBUG ("Taking new base rtptime %" GST_TIME_FORMAT, GST_TIME_ARGS (gstrtptime)); } if (G_LIKELY (gstrtptime >= jbuf->base_rtptime)) send_diff = gstrtptime - jbuf->base_rtptime; else if (time != -1) { /* elapsed time at sender, timestamps can go backwards and thus be smaller * than our base time, take a new base time in that case. */ GST_WARNING ("backward timestamps at server, taking new base time"); rtp_jitter_buffer_resync (jbuf, time, gstrtptime, ext_rtptime, FALSE); send_diff = 0; } else { GST_WARNING ("backward timestamps at server but no timestamps"); send_diff = 0; /* at least try to get a new timestamp.. */ jbuf->base_time = -1; } GST_DEBUG ("extrtp %" G_GUINT64_FORMAT ", gstrtp %" GST_TIME_FORMAT ", base %" GST_TIME_FORMAT ", send_diff %" GST_TIME_FORMAT, ext_rtptime, GST_TIME_ARGS (gstrtptime), GST_TIME_ARGS (jbuf->base_rtptime), GST_TIME_ARGS (send_diff)); /* we don't have an arrival timestamp so we can't do skew detection. we * should still apply a timestamp based on RTP timestamp and base_time */ if (time == -1 || jbuf->base_time == -1) goto no_skew; /* elapsed time at receiver, includes the jitter */ recv_diff = time - jbuf->base_time; /* measure the diff */ delta = ((gint64) recv_diff) - ((gint64) send_diff); /* measure the slope, this gives a rought estimate between the sender speed * and the receiver speed. This should be approximately 8, higher values * indicate a burst (especially when the connection starts) */ if (recv_diff > 0) slope = (send_diff * 8) / recv_diff; else slope = 8; GST_DEBUG ("time %" GST_TIME_FORMAT ", base %" GST_TIME_FORMAT ", recv_diff %" GST_TIME_FORMAT ", slope %" G_GUINT64_FORMAT, GST_TIME_ARGS (time), GST_TIME_ARGS (jbuf->base_time), GST_TIME_ARGS (recv_diff), slope); /* if the difference between the sender timeline and the receiver timeline * changed too quickly we have to resync because the server likely restarted * its timestamps. */ if (ABS (delta - jbuf->skew) > GST_SECOND) { GST_WARNING ("delta - skew: %" GST_TIME_FORMAT " too big, reset skew", GST_TIME_ARGS (delta - jbuf->skew)); rtp_jitter_buffer_resync (jbuf, time, gstrtptime, ext_rtptime, TRUE); send_diff = 0; delta = 0; } pos = jbuf->window_pos; if (G_UNLIKELY (jbuf->window_filling)) { /* we are filling the window */ GST_DEBUG ("filling %d, delta %" G_GINT64_FORMAT, pos, delta); jbuf->window[pos++] = delta; /* calc the min delta we observed */ if (G_UNLIKELY (pos == 1 || delta < jbuf->window_min)) jbuf->window_min = delta; if (G_UNLIKELY (send_diff >= MAX_TIME || pos >= MAX_WINDOW)) { jbuf->window_size = pos; /* window filled */ GST_DEBUG ("min %" G_GINT64_FORMAT, jbuf->window_min); /* the skew is now the min */ jbuf->skew = jbuf->window_min; jbuf->window_filling = FALSE; } else { gint perc_time, perc_window, perc; /* figure out how much we filled the window, this depends on the amount of * time we have or the max number of points we keep. */ perc_time = send_diff * 100 / MAX_TIME; perc_window = pos * 100 / MAX_WINDOW; perc = MAX (perc_time, perc_window); /* make a parabolic function, the closer we get to the MAX, the more value * we give to the scaling factor of the new value */ perc = perc * perc; /* quickly go to the min value when we are filling up, slowly when we are * just starting because we're not sure it's a good value yet. */ jbuf->skew = (perc * jbuf->window_min + ((10000 - perc) * jbuf->skew)) / 10000; jbuf->window_size = pos + 1; } } else { /* pick old value and store new value. We keep the previous value in order * to quickly check if the min of the window changed */ old = jbuf->window[pos]; jbuf->window[pos++] = delta; if (G_UNLIKELY (delta <= jbuf->window_min)) { /* if the new value we inserted is smaller or equal to the current min, * it becomes the new min */ jbuf->window_min = delta; } else if (G_UNLIKELY (old == jbuf->window_min)) { gint64 min = G_MAXINT64; /* if we removed the old min, we have to find a new min */ for (i = 0; i < jbuf->window_size; i++) { /* we found another value equal to the old min, we can stop searching now */ if (jbuf->window[i] == old) { min = old; break; } if (jbuf->window[i] < min) min = jbuf->window[i]; } jbuf->window_min = min; } /* average the min values */ jbuf->skew = (jbuf->window_min + (124 * jbuf->skew)) / 125; GST_DEBUG ("delta %" G_GINT64_FORMAT ", new min: %" G_GINT64_FORMAT, delta, jbuf->window_min); } /* wrap around in the window */ if (G_UNLIKELY (pos >= jbuf->window_size)) pos = 0; jbuf->window_pos = pos; no_skew: /* the output time is defined as the base timestamp plus the RTP time * adjusted for the clock skew .*/ if (jbuf->base_time != -1) { out_time = jbuf->base_time + send_diff; /* skew can be negative and we don't want to make invalid timestamps */ if (jbuf->skew < 0 && out_time < -jbuf->skew) { out_time = 0; } else { out_time += jbuf->skew; } /* check if timestamps are not going backwards, we can only check this if we * have a previous out time and a previous send_diff */ if (G_LIKELY (jbuf->prev_out_time != -1 && jbuf->prev_send_diff != -1)) { /* now check for backwards timestamps */ if (G_UNLIKELY ( /* if the server timestamps went up and the out_time backwards */ (send_diff > jbuf->prev_send_diff && out_time < jbuf->prev_out_time) || /* if the server timestamps went backwards and the out_time forwards */ (send_diff < jbuf->prev_send_diff && out_time > jbuf->prev_out_time) || /* if the server timestamps did not change */ send_diff == jbuf->prev_send_diff)) { GST_DEBUG ("backwards timestamps, using previous time"); out_time = jbuf->prev_out_time; } } if (time != -1 && out_time + jbuf->delay < time) { /* if we are going to produce a timestamp that is later than the input * timestamp, we need to reset the jitterbuffer. Likely the server paused * temporarily */ GST_DEBUG ("out %" GST_TIME_FORMAT " + %" G_GUINT64_FORMAT " < time %" GST_TIME_FORMAT ", reset jitterbuffer", GST_TIME_ARGS (out_time), jbuf->delay, GST_TIME_ARGS (time)); rtp_jitter_buffer_resync (jbuf, time, gstrtptime, ext_rtptime, TRUE); out_time = time; send_diff = 0; } } else out_time = -1; jbuf->prev_out_time = out_time; jbuf->prev_send_diff = send_diff; GST_DEBUG ("skew %" G_GINT64_FORMAT ", out %" GST_TIME_FORMAT, jbuf->skew, GST_TIME_ARGS (out_time)); return out_time; } /** * rtp_jitter_buffer_insert: * @jbuf: an #RTPJitterBuffer * @buf: a buffer * @time: a running_time when this buffer was received in nanoseconds * @clock_rate: the clock-rate of the payload of @buf * @max_delay: the maximum lateness of @buf * @tail: TRUE when the tail element changed. * * Inserts @buf into the packet queue of @jbuf. The sequence number of the * packet will be used to sort the packets. This function takes ownerhip of * @buf when the function returns %TRUE. * @buf should have writable metadata when calling this function. * * Returns: %FALSE if a packet with the same number already existed. */ gboolean rtp_jitter_buffer_insert (RTPJitterBuffer * jbuf, GstBuffer * buf, GstClockTime time, guint32 clock_rate, gboolean * tail, gint * percent) { GList *list; guint32 rtptime; guint16 seqnum; GstRTPBuffer rtp; g_return_val_if_fail (jbuf != NULL, FALSE); g_return_val_if_fail (buf != NULL, FALSE); gst_rtp_buffer_map (buf, GST_MAP_READ, &rtp); seqnum = gst_rtp_buffer_get_seq (&rtp); /* loop the list to skip strictly smaller seqnum buffers */ for (list = jbuf->packets->head; list; list = g_list_next (list)) { guint16 qseq; gint gap; GstRTPBuffer rtpb; gst_rtp_buffer_map (GST_BUFFER_CAST (list->data), GST_MAP_READ, &rtpb); qseq = gst_rtp_buffer_get_seq (&rtpb); gst_rtp_buffer_unmap (&rtpb); /* compare the new seqnum to the one in the buffer */ gap = gst_rtp_buffer_compare_seqnum (seqnum, qseq); /* we hit a packet with the same seqnum, notify a duplicate */ if (G_UNLIKELY (gap == 0)) goto duplicate; /* seqnum > qseq, we can stop looking */ if (G_LIKELY (gap < 0)) break; } rtptime = gst_rtp_buffer_get_timestamp (&rtp); switch (jbuf->mode) { case RTP_JITTER_BUFFER_MODE_NONE: case RTP_JITTER_BUFFER_MODE_BUFFER: /* send 0 as the first timestamp and -1 for the other ones. This will * interpollate them from the RTP timestamps with a 0 origin. In buffering * mode we will adjust the outgoing timestamps according to the amount of * time we spent buffering. */ if (jbuf->base_time == -1) time = 0; else time = -1; break; case RTP_JITTER_BUFFER_MODE_SLAVE: default: break; } /* do skew calculation by measuring the difference between rtptime and the * receive time, this function will retimestamp @buf with the skew corrected * running time. */ time = calculate_skew (jbuf, rtptime, time, clock_rate); GST_BUFFER_TIMESTAMP (buf) = time; /* It's more likely that the packet was inserted in the front of the buffer */ if (G_LIKELY (list)) g_queue_insert_before (jbuf->packets, list, buf); else g_queue_push_tail (jbuf->packets, buf); /* buffering mode, update buffer stats */ if (jbuf->mode == RTP_JITTER_BUFFER_MODE_BUFFER) update_buffer_level (jbuf, percent); else *percent = -1; /* tail was changed when we did not find a previous packet, we set the return * flag when requested. */ if (G_LIKELY (tail)) *tail = (list == NULL); gst_rtp_buffer_unmap (&rtp); return TRUE; /* ERRORS */ duplicate: { gst_rtp_buffer_unmap (&rtp); GST_WARNING ("duplicate packet %d found", (gint) seqnum); return FALSE; } } /** * rtp_jitter_buffer_pop: * @jbuf: an #RTPJitterBuffer * @percent: the buffering percent * * Pops the oldest buffer from the packet queue of @jbuf. The popped buffer will * have its timestamp adjusted with the incomming running_time and the detected * clock skew. * * Returns: a #GstBuffer or %NULL when there was no packet in the queue. */ GstBuffer * rtp_jitter_buffer_pop (RTPJitterBuffer * jbuf, gint * percent) { GstBuffer *buf; g_return_val_if_fail (jbuf != NULL, NULL); buf = g_queue_pop_tail (jbuf->packets); /* buffering mode, update buffer stats */ if (jbuf->mode == RTP_JITTER_BUFFER_MODE_BUFFER) update_buffer_level (jbuf, percent); else *percent = -1; return buf; } /** * rtp_jitter_buffer_peek: * @jbuf: an #RTPJitterBuffer * * Peek the oldest buffer from the packet queue of @jbuf. Register a callback * with rtp_jitter_buffer_set_tail_changed() to be notified when an older packet * was inserted in the queue. * * Returns: a #GstBuffer or %NULL when there was no packet in the queue. */ GstBuffer * rtp_jitter_buffer_peek (RTPJitterBuffer * jbuf) { GstBuffer *buf; g_return_val_if_fail (jbuf != NULL, NULL); buf = g_queue_peek_tail (jbuf->packets); return buf; } /** * rtp_jitter_buffer_flush: * @jbuf: an #RTPJitterBuffer * * Flush all packets from the jitterbuffer. */ void rtp_jitter_buffer_flush (RTPJitterBuffer * jbuf) { GstBuffer *buffer; g_return_if_fail (jbuf != NULL); while ((buffer = g_queue_pop_head (jbuf->packets))) gst_buffer_unref (buffer); } /** * rtp_jitter_buffer_is_buffering: * @jbuf: an #RTPJitterBuffer * * Check if @jbuf is buffering currently. Users of the jitterbuffer should not * pop packets while in buffering mode. * * Returns: the buffering state of @jbuf */ gboolean rtp_jitter_buffer_is_buffering (RTPJitterBuffer * jbuf) { return jbuf->buffering; } /** * rtp_jitter_buffer_set_buffering: * @jbuf: an #RTPJitterBuffer * @buffering: the new buffering state * * Forces @jbuf to go into the buffering state. */ void rtp_jitter_buffer_set_buffering (RTPJitterBuffer * jbuf, gboolean buffering) { jbuf->buffering = buffering; } /** * rtp_jitter_buffer_get_percent: * @jbuf: an #RTPJitterBuffer * * Get the buffering percent of the jitterbuffer. * * Returns: the buffering percent */ gint rtp_jitter_buffer_get_percent (RTPJitterBuffer * jbuf) { gint percent; guint64 level; if (G_UNLIKELY (jbuf->high_level == 0)) return 100; level = get_buffer_level (jbuf); percent = (level * 100 / jbuf->high_level); percent = MIN (percent, 100); return percent; } /** * rtp_jitter_buffer_num_packets: * @jbuf: an #RTPJitterBuffer * * Get the number of packets currently in "jbuf. * * Returns: The number of packets in @jbuf. */ guint rtp_jitter_buffer_num_packets (RTPJitterBuffer * jbuf) { g_return_val_if_fail (jbuf != NULL, 0); return jbuf->packets->length; } /** * rtp_jitter_buffer_get_ts_diff: * @jbuf: an #RTPJitterBuffer * * Get the difference between the timestamps of first and last packet in the * jitterbuffer. * * Returns: The difference expressed in the timestamp units of the packets. */ guint32 rtp_jitter_buffer_get_ts_diff (RTPJitterBuffer * jbuf) { guint64 high_ts, low_ts; GstBuffer *high_buf, *low_buf; guint32 result; GstRTPBuffer rtp; g_return_val_if_fail (jbuf != NULL, 0); high_buf = g_queue_peek_head (jbuf->packets); low_buf = g_queue_peek_tail (jbuf->packets); if (!high_buf || !low_buf || high_buf == low_buf) return 0; gst_rtp_buffer_map (high_buf, GST_MAP_READ, &rtp); high_ts = gst_rtp_buffer_get_timestamp (&rtp); gst_rtp_buffer_unmap (&rtp); gst_rtp_buffer_map (low_buf, GST_MAP_READ, &rtp); low_ts = gst_rtp_buffer_get_timestamp (&rtp); gst_rtp_buffer_unmap (&rtp); /* it needs to work if ts wraps */ if (high_ts >= low_ts) { result = (guint32) (high_ts - low_ts); } else { result = (guint32) (high_ts + G_MAXUINT32 + 1 - low_ts); } return result; } /** * rtp_jitter_buffer_get_sync: * @jbuf: an #RTPJitterBuffer * @rtptime: result RTP time * @timestamp: result GStreamer timestamp * @clock_rate: clock-rate of @rtptime * @last_rtptime: last seen rtptime. * * Calculates the relation between the RTP timestamp and the GStreamer timestamp * used for constructing timestamps. * * For extended RTP timestamp @rtptime with a clock-rate of @clock_rate, * the GStreamer timestamp is currently @timestamp. * * The last seen extended RTP timestamp with clock-rate @clock-rate is returned in * @last_rtptime. */ void rtp_jitter_buffer_get_sync (RTPJitterBuffer * jbuf, guint64 * rtptime, guint64 * timestamp, guint32 * clock_rate, guint64 * last_rtptime) { if (rtptime) *rtptime = jbuf->base_extrtp; if (timestamp) *timestamp = jbuf->base_time + jbuf->skew; if (clock_rate) *clock_rate = jbuf->clock_rate; if (last_rtptime) *last_rtptime = jbuf->last_rtptime; }