/* GStreamer * Copyright (C) 2008 Wim Taymans * Copyright (C) 2015 Centricular Ltd * Author: Sebastian Dröge * * 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., 51 Franklin St, Fifth Floor, * Boston, MA 02110-1301, USA. */ /** * SECTION:rtsp-stream * @short_description: A media stream * @see_also: #GstRTSPMedia * * The #GstRTSPStream object manages the data transport for one stream. It * is created from a payloader element and a source pad that produce the RTP * packets for the stream. * * With gst_rtsp_stream_join_bin() the streaming elements are added to the bin * and rtpbin. gst_rtsp_stream_leave_bin() removes the elements again. * * The #GstRTSPStream will use the configured addresspool, as set with * gst_rtsp_stream_set_address_pool(), to allocate multicast addresses for the * stream. With gst_rtsp_stream_get_multicast_address() you can get the * configured address. * * With gst_rtsp_stream_get_server_port () you can get the port that the server * will use to receive RTCP. This is the part that the clients will use to send * RTCP to. * * With gst_rtsp_stream_add_transport() destinations can be added where the * stream should be sent to. Use gst_rtsp_stream_remove_transport() to remove * the destination again. * * Each #GstRTSPStreamTransport spawns one queue that will serve as a backlog of a * controllable maximum size when the reflux from the TCP connection's backpressure * starts spilling all over. * * Unlike the backlog in rtspconnection, which we have decided should only contain * at most one RTP and one RTCP data message in order to allow control messages to * go through unobstructed, this backlog only consists of data messages, allowing * us to fill it up without concern. * * When multiple TCP transports exist, for example in the context of a shared media, * we only pop samples from our appsinks when at least one of the transports doesn't * experience back pressure: this allows us to pace our sample popping to the speed * of the fastest client. * * When a sample is popped, it is either sent directly on transports that don't * experience backpressure, or queued on the transport's backlog otherwise. Samples * are then popped from that backlog when the transport reports it has sent the message. * * Once the backlog reaches an overly large duration, the transport is dropped as * the client was deemed too slow. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include "rtsp-stream.h" #include "rtsp-server-internal.h" struct _GstRTSPStreamPrivate { GMutex lock; guint idx; /* Only one pad is ever set */ GstPad *srcpad, *sinkpad; GstElement *payloader; guint buffer_size; GstBin *joined_bin; /* TRUE if this stream is running on * the client side of an RTSP link (for RECORD) */ gboolean client_side; gchar *control; /* TRUE if stream is complete. This means that the receiver and the sender * parts are present in the stream. */ gboolean is_complete; GstRTSPProfile profiles; GstRTSPLowerTrans allowed_protocols; GstRTSPLowerTrans configured_protocols; /* pads on the rtpbin */ GstPad *send_rtp_sink; GstPad *recv_rtp_src; GstPad *recv_sink[2]; GstPad *send_src[2]; /* the RTPSession object */ GObject *session; /* SRTP encoder/decoder */ GstElement *srtpenc; GstElement *srtpdec; GHashTable *keys; /* for UDP unicast */ GstElement *udpsrc_v4[2]; GstElement *udpsrc_v6[2]; GstElement *udpqueue[2]; GstElement *udpsink[2]; GSocket *socket_v4[2]; GSocket *socket_v6[2]; /* for UDP multicast */ GstElement *mcast_udpsrc_v4[2]; GstElement *mcast_udpsrc_v6[2]; GstElement *mcast_udpqueue[2]; GstElement *mcast_udpsink[2]; GSocket *mcast_socket_v4[2]; GSocket *mcast_socket_v6[2]; GList *mcast_clients; /* for TCP transport */ GstElement *appsrc[2]; GstClockTime appsrc_base_time[2]; GstElement *appqueue[2]; GstElement *appsink[2]; GstElement *tee[2]; GstElement *funnel[2]; /* retransmission */ GstElement *rtxsend; GstElement *rtxreceive; guint rtx_pt; GstClockTime rtx_time; /* rate control */ gboolean do_rate_control; /* Forward Error Correction with RFC 5109 */ GstElement *ulpfec_decoder; GstElement *ulpfec_encoder; guint ulpfec_pt; gboolean ulpfec_enabled; guint ulpfec_percentage; /* pool used to manage unicast and multicast addresses */ GstRTSPAddressPool *pool; /* unicast server addr/port */ GstRTSPAddress *server_addr_v4; GstRTSPAddress *server_addr_v6; /* multicast addresses */ GstRTSPAddress *mcast_addr_v4; GstRTSPAddress *mcast_addr_v6; gchar *multicast_iface; guint max_mcast_ttl; gboolean bind_mcast_address; /* the caps of the stream */ gulong caps_sig; GstCaps *caps; /* transports we stream to */ guint n_active; GList *transports; guint transports_cookie; GPtrArray *tr_cache; guint tr_cache_cookie; guint n_tcp_transports; gboolean have_buffer[2]; gint dscp_qos; /* Sending logic for TCP */ GThread *send_thread; GCond send_cond; GMutex send_lock; /* @send_lock is released when pushing data out, we use * a cookie to decide whether we should wait on @send_cond * before checking the transports' backlogs again */ guint send_cookie; /* Used to control shutdown of @send_thread */ gboolean continue_sending; /* stream blocking */ gulong blocked_id[2]; gboolean blocking; /* current stream postion */ GstClockTime position; /* pt->caps map for RECORD streams */ GHashTable *ptmap; GstRTSPPublishClockMode publish_clock_mode; GThreadPool *send_pool; /* Used to provide accurate rtpinfo when the stream is blocking */ gboolean blocked_buffer; guint32 blocked_seqnum; guint32 blocked_rtptime; GstClockTime blocked_running_time; gint blocked_clock_rate; /* Whether we should send and receive RTCP */ gboolean enable_rtcp; /* blocking early rtcp packets */ GstPad *block_early_rtcp_pad; gulong block_early_rtcp_probe; GstPad *block_early_rtcp_pad_ipv6; gulong block_early_rtcp_probe_ipv6; /* set to drop delta units in blocking pad */ gboolean drop_delta_units; /* used to indicate that the drop probe has dropped a buffer and should be * removed */ gboolean remove_drop_probe; }; #define DEFAULT_CONTROL NULL #define DEFAULT_PROFILES GST_RTSP_PROFILE_AVP #define DEFAULT_PROTOCOLS GST_RTSP_LOWER_TRANS_UDP | GST_RTSP_LOWER_TRANS_UDP_MCAST | \ GST_RTSP_LOWER_TRANS_TCP #define DEFAULT_MAX_MCAST_TTL 255 #define DEFAULT_BIND_MCAST_ADDRESS FALSE #define DEFAULT_DO_RATE_CONTROL TRUE #define DEFAULT_ENABLE_RTCP TRUE enum { PROP_0, PROP_CONTROL, PROP_PROFILES, PROP_PROTOCOLS, PROP_LAST }; enum { SIGNAL_NEW_RTP_ENCODER, SIGNAL_NEW_RTCP_ENCODER, SIGNAL_NEW_RTP_RTCP_DECODER, SIGNAL_LAST }; GST_DEBUG_CATEGORY_STATIC (rtsp_stream_debug); #define GST_CAT_DEFAULT rtsp_stream_debug static GQuark ssrc_stream_map_key; static void gst_rtsp_stream_get_property (GObject * object, guint propid, GValue * value, GParamSpec * pspec); static void gst_rtsp_stream_set_property (GObject * object, guint propid, const GValue * value, GParamSpec * pspec); static void gst_rtsp_stream_finalize (GObject * obj); static gboolean update_transport (GstRTSPStream * stream, GstRTSPStreamTransport * trans, gboolean add); static guint gst_rtsp_stream_signals[SIGNAL_LAST] = { 0 }; G_DEFINE_TYPE_WITH_PRIVATE (GstRTSPStream, gst_rtsp_stream, G_TYPE_OBJECT); static void gst_rtsp_stream_class_init (GstRTSPStreamClass * klass) { GObjectClass *gobject_class; gobject_class = G_OBJECT_CLASS (klass); gobject_class->get_property = gst_rtsp_stream_get_property; gobject_class->set_property = gst_rtsp_stream_set_property; gobject_class->finalize = gst_rtsp_stream_finalize; g_object_class_install_property (gobject_class, PROP_CONTROL, g_param_spec_string ("control", "Control", "The control string for this stream", DEFAULT_CONTROL, G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_PROFILES, g_param_spec_flags ("profiles", "Profiles", "Allowed transfer profiles", GST_TYPE_RTSP_PROFILE, DEFAULT_PROFILES, G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS)); g_object_class_install_property (gobject_class, PROP_PROTOCOLS, g_param_spec_flags ("protocols", "Protocols", "Allowed lower transport protocols", GST_TYPE_RTSP_LOWER_TRANS, DEFAULT_PROTOCOLS, G_PARAM_READWRITE | G_PARAM_STATIC_STRINGS)); gst_rtsp_stream_signals[SIGNAL_NEW_RTP_ENCODER] = g_signal_new ("new-rtp-encoder", G_TYPE_FROM_CLASS (klass), G_SIGNAL_RUN_LAST, 0, NULL, NULL, NULL, G_TYPE_NONE, 1, GST_TYPE_ELEMENT); gst_rtsp_stream_signals[SIGNAL_NEW_RTCP_ENCODER] = g_signal_new ("new-rtcp-encoder", G_TYPE_FROM_CLASS (klass), G_SIGNAL_RUN_LAST, 0, NULL, NULL, NULL, G_TYPE_NONE, 1, GST_TYPE_ELEMENT); gst_rtsp_stream_signals[SIGNAL_NEW_RTP_RTCP_DECODER] = g_signal_new ("new-rtp-rtcp-decoder", G_TYPE_FROM_CLASS (klass), G_SIGNAL_RUN_LAST, 0, NULL, NULL, NULL, G_TYPE_NONE, 1, GST_TYPE_ELEMENT); GST_DEBUG_CATEGORY_INIT (rtsp_stream_debug, "rtspstream", 0, "GstRTSPStream"); ssrc_stream_map_key = g_quark_from_static_string ("GstRTSPServer.stream"); } static void gst_rtsp_stream_init (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = gst_rtsp_stream_get_instance_private (stream); GST_DEBUG ("new stream %p", stream); stream->priv = priv; priv->dscp_qos = -1; priv->control = g_strdup (DEFAULT_CONTROL); priv->profiles = DEFAULT_PROFILES; priv->allowed_protocols = DEFAULT_PROTOCOLS; priv->configured_protocols = 0; priv->publish_clock_mode = GST_RTSP_PUBLISH_CLOCK_MODE_CLOCK; priv->max_mcast_ttl = DEFAULT_MAX_MCAST_TTL; priv->bind_mcast_address = DEFAULT_BIND_MCAST_ADDRESS; priv->do_rate_control = DEFAULT_DO_RATE_CONTROL; priv->enable_rtcp = DEFAULT_ENABLE_RTCP; g_mutex_init (&priv->lock); priv->continue_sending = TRUE; priv->send_cookie = 0; g_cond_init (&priv->send_cond); g_mutex_init (&priv->send_lock); priv->keys = g_hash_table_new_full (g_direct_hash, g_direct_equal, NULL, (GDestroyNotify) gst_caps_unref); priv->ptmap = g_hash_table_new_full (NULL, NULL, NULL, (GDestroyNotify) gst_caps_unref); priv->send_pool = NULL; priv->block_early_rtcp_pad = NULL; priv->block_early_rtcp_probe = 0; priv->block_early_rtcp_pad_ipv6 = NULL; priv->block_early_rtcp_probe_ipv6 = 0; priv->drop_delta_units = FALSE; priv->remove_drop_probe = FALSE; } typedef struct _UdpClientAddrInfo UdpClientAddrInfo; struct _UdpClientAddrInfo { gchar *address; guint rtp_port; guint add_count; /* how often this address has been added */ }; static void free_mcast_client (gpointer data) { UdpClientAddrInfo *client = data; g_free (client->address); g_free (client); } static void gst_rtsp_stream_finalize (GObject * obj) { GstRTSPStream *stream; GstRTSPStreamPrivate *priv; guint i; stream = GST_RTSP_STREAM (obj); priv = stream->priv; GST_DEBUG ("finalize stream %p", stream); /* we really need to be unjoined now */ g_return_if_fail (priv->joined_bin == NULL); if (priv->send_pool) g_thread_pool_free (priv->send_pool, TRUE, TRUE); if (priv->mcast_addr_v4) gst_rtsp_address_free (priv->mcast_addr_v4); if (priv->mcast_addr_v6) gst_rtsp_address_free (priv->mcast_addr_v6); if (priv->server_addr_v4) gst_rtsp_address_free (priv->server_addr_v4); if (priv->server_addr_v6) gst_rtsp_address_free (priv->server_addr_v6); if (priv->pool) g_object_unref (priv->pool); if (priv->rtxsend) g_object_unref (priv->rtxsend); if (priv->rtxreceive) g_object_unref (priv->rtxreceive); if (priv->ulpfec_encoder) gst_object_unref (priv->ulpfec_encoder); if (priv->ulpfec_decoder) gst_object_unref (priv->ulpfec_decoder); for (i = 0; i < 2; i++) { if (priv->socket_v4[i]) g_object_unref (priv->socket_v4[i]); if (priv->socket_v6[i]) g_object_unref (priv->socket_v6[i]); if (priv->mcast_socket_v4[i]) g_object_unref (priv->mcast_socket_v4[i]); if (priv->mcast_socket_v6[i]) g_object_unref (priv->mcast_socket_v6[i]); } g_free (priv->multicast_iface); g_list_free_full (priv->mcast_clients, (GDestroyNotify) free_mcast_client); gst_object_unref (priv->payloader); if (priv->srcpad) gst_object_unref (priv->srcpad); if (priv->sinkpad) gst_object_unref (priv->sinkpad); g_free (priv->control); g_mutex_clear (&priv->lock); g_hash_table_unref (priv->keys); g_hash_table_destroy (priv->ptmap); g_mutex_clear (&priv->send_lock); g_cond_clear (&priv->send_cond); if (priv->block_early_rtcp_probe != 0) { gst_pad_remove_probe (priv->block_early_rtcp_pad, priv->block_early_rtcp_probe); gst_object_unref (priv->block_early_rtcp_pad); } if (priv->block_early_rtcp_probe_ipv6 != 0) { gst_pad_remove_probe (priv->block_early_rtcp_pad_ipv6, priv->block_early_rtcp_probe_ipv6); gst_object_unref (priv->block_early_rtcp_pad_ipv6); } G_OBJECT_CLASS (gst_rtsp_stream_parent_class)->finalize (obj); } static void gst_rtsp_stream_get_property (GObject * object, guint propid, GValue * value, GParamSpec * pspec) { GstRTSPStream *stream = GST_RTSP_STREAM (object); switch (propid) { case PROP_CONTROL: g_value_take_string (value, gst_rtsp_stream_get_control (stream)); break; case PROP_PROFILES: g_value_set_flags (value, gst_rtsp_stream_get_profiles (stream)); break; case PROP_PROTOCOLS: g_value_set_flags (value, gst_rtsp_stream_get_protocols (stream)); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, propid, pspec); } } static void gst_rtsp_stream_set_property (GObject * object, guint propid, const GValue * value, GParamSpec * pspec) { GstRTSPStream *stream = GST_RTSP_STREAM (object); switch (propid) { case PROP_CONTROL: gst_rtsp_stream_set_control (stream, g_value_get_string (value)); break; case PROP_PROFILES: gst_rtsp_stream_set_profiles (stream, g_value_get_flags (value)); break; case PROP_PROTOCOLS: gst_rtsp_stream_set_protocols (stream, g_value_get_flags (value)); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, propid, pspec); } } /** * gst_rtsp_stream_new: * @idx: an index * @pad: a #GstPad * @payloader: a #GstElement * * Create a new media stream with index @idx that handles RTP data on * @pad and has a payloader element @payloader if @pad is a source pad * or a depayloader element @payloader if @pad is a sink pad. * * Returns: (transfer full): a new #GstRTSPStream */ GstRTSPStream * gst_rtsp_stream_new (guint idx, GstElement * payloader, GstPad * pad) { GstRTSPStreamPrivate *priv; GstRTSPStream *stream; g_return_val_if_fail (GST_IS_ELEMENT (payloader), NULL); g_return_val_if_fail (GST_IS_PAD (pad), NULL); stream = g_object_new (GST_TYPE_RTSP_STREAM, NULL); priv = stream->priv; priv->idx = idx; priv->payloader = gst_object_ref (payloader); if (GST_PAD_IS_SRC (pad)) priv->srcpad = gst_object_ref (pad); else priv->sinkpad = gst_object_ref (pad); return stream; } /** * gst_rtsp_stream_get_index: * @stream: a #GstRTSPStream * * Get the stream index. * * Return: the stream index. */ guint gst_rtsp_stream_get_index (GstRTSPStream * stream) { g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), -1); return stream->priv->idx; } /** * gst_rtsp_stream_get_pt: * @stream: a #GstRTSPStream * * Get the stream payload type. * * Return: the stream payload type. */ guint gst_rtsp_stream_get_pt (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; guint pt; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), -1); priv = stream->priv; g_object_get (G_OBJECT (priv->payloader), "pt", &pt, NULL); return pt; } /** * gst_rtsp_stream_get_srcpad: * @stream: a #GstRTSPStream * * Get the srcpad associated with @stream. * * Returns: (transfer full) (nullable): the srcpad. Unref after usage. */ GstPad * gst_rtsp_stream_get_srcpad (GstRTSPStream * stream) { g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); if (!stream->priv->srcpad) return NULL; return gst_object_ref (stream->priv->srcpad); } /** * gst_rtsp_stream_get_sinkpad: * @stream: a #GstRTSPStream * * Get the sinkpad associated with @stream. * * Returns: (transfer full) (nullable): the sinkpad. Unref after usage. */ GstPad * gst_rtsp_stream_get_sinkpad (GstRTSPStream * stream) { g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); if (!stream->priv->sinkpad) return NULL; return gst_object_ref (stream->priv->sinkpad); } /** * gst_rtsp_stream_get_control: * @stream: a #GstRTSPStream * * Get the control string to identify this stream. * * Returns: (transfer full) (nullable): the control string. g_free() after usage. */ gchar * gst_rtsp_stream_get_control (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gchar *result; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&priv->lock); if ((result = g_strdup (priv->control)) == NULL) result = g_strdup_printf ("stream=%u", priv->idx); g_mutex_unlock (&priv->lock); return result; } /** * gst_rtsp_stream_set_control: * @stream: a #GstRTSPStream * @control: (nullable): a control string * * Set the control string in @stream. */ void gst_rtsp_stream_set_control (GstRTSPStream * stream, const gchar * control) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_mutex_lock (&priv->lock); g_free (priv->control); priv->control = g_strdup (control); g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_has_control: * @stream: a #GstRTSPStream * @control: (nullable): a control string * * Check if @stream has the control string @control. * * Returns: %TRUE is @stream has @control as the control string */ gboolean gst_rtsp_stream_has_control (GstRTSPStream * stream, const gchar * control) { GstRTSPStreamPrivate *priv; gboolean res; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); if (priv->control) res = (g_strcmp0 (priv->control, control) == 0); else { guint streamid; if (sscanf (control, "stream=%u", &streamid) > 0) res = (streamid == priv->idx); else res = FALSE; } g_mutex_unlock (&priv->lock); return res; } /** * gst_rtsp_stream_set_mtu: * @stream: a #GstRTSPStream * @mtu: a new MTU * * Configure the mtu in the payloader of @stream to @mtu. */ void gst_rtsp_stream_set_mtu (GstRTSPStream * stream, guint mtu) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; GST_LOG_OBJECT (stream, "set MTU %u", mtu); g_object_set (G_OBJECT (priv->payloader), "mtu", mtu, NULL); } /** * gst_rtsp_stream_get_mtu: * @stream: a #GstRTSPStream * * Get the configured MTU in the payloader of @stream. * * Returns: the MTU of the payloader. */ guint gst_rtsp_stream_get_mtu (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; guint mtu; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), 0); priv = stream->priv; g_object_get (G_OBJECT (priv->payloader), "mtu", &mtu, NULL); return mtu; } /* Update the dscp qos property on the udp sinks */ static void update_dscp_qos (GstRTSPStream * stream, GstElement ** udpsink) { GstRTSPStreamPrivate *priv; priv = stream->priv; if (*udpsink) { g_object_set (G_OBJECT (*udpsink), "qos-dscp", priv->dscp_qos, NULL); } } /** * gst_rtsp_stream_set_dscp_qos: * @stream: a #GstRTSPStream * @dscp_qos: a new dscp qos value (0-63, or -1 to disable) * * Configure the dscp qos of the outgoing sockets to @dscp_qos. */ void gst_rtsp_stream_set_dscp_qos (GstRTSPStream * stream, gint dscp_qos) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; GST_LOG_OBJECT (stream, "set DSCP QoS %d", dscp_qos); if (dscp_qos < -1 || dscp_qos > 63) { GST_WARNING_OBJECT (stream, "trying to set illegal dscp qos %d", dscp_qos); return; } priv->dscp_qos = dscp_qos; update_dscp_qos (stream, priv->udpsink); } /** * gst_rtsp_stream_get_dscp_qos: * @stream: a #GstRTSPStream * * Get the configured DSCP QoS in of the outgoing sockets. * * Returns: the DSCP QoS value of the outgoing sockets, or -1 if disbled. */ gint gst_rtsp_stream_get_dscp_qos (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), -1); priv = stream->priv; return priv->dscp_qos; } /** * gst_rtsp_stream_is_transport_supported: * @stream: a #GstRTSPStream * @transport: (transfer none): a #GstRTSPTransport * * Check if @transport can be handled by stream * * Returns: %TRUE if @transport can be handled by @stream. */ gboolean gst_rtsp_stream_is_transport_supported (GstRTSPStream * stream, GstRTSPTransport * transport) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_return_val_if_fail (transport != NULL, FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); if (transport->trans != GST_RTSP_TRANS_RTP) goto unsupported_transmode; if (!(transport->profile & priv->profiles)) goto unsupported_profile; if (!(transport->lower_transport & priv->allowed_protocols)) goto unsupported_ltrans; g_mutex_unlock (&priv->lock); return TRUE; /* ERRORS */ unsupported_transmode: { GST_DEBUG ("unsupported transport mode %d", transport->trans); g_mutex_unlock (&priv->lock); return FALSE; } unsupported_profile: { GST_DEBUG ("unsupported profile %d", transport->profile); g_mutex_unlock (&priv->lock); return FALSE; } unsupported_ltrans: { GST_DEBUG ("unsupported lower transport %d", transport->lower_transport); g_mutex_unlock (&priv->lock); return FALSE; } } /** * gst_rtsp_stream_set_profiles: * @stream: a #GstRTSPStream * @profiles: the new profiles * * Configure the allowed profiles for @stream. */ void gst_rtsp_stream_set_profiles (GstRTSPStream * stream, GstRTSPProfile profiles) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_mutex_lock (&priv->lock); priv->profiles = profiles; g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_get_profiles: * @stream: a #GstRTSPStream * * Get the allowed profiles of @stream. * * Returns: a #GstRTSPProfile */ GstRTSPProfile gst_rtsp_stream_get_profiles (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstRTSPProfile res; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), GST_RTSP_PROFILE_UNKNOWN); priv = stream->priv; g_mutex_lock (&priv->lock); res = priv->profiles; g_mutex_unlock (&priv->lock); return res; } /** * gst_rtsp_stream_set_protocols: * @stream: a #GstRTSPStream * @protocols: the new flags * * Configure the allowed lower transport for @stream. */ void gst_rtsp_stream_set_protocols (GstRTSPStream * stream, GstRTSPLowerTrans protocols) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_mutex_lock (&priv->lock); priv->allowed_protocols = protocols; g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_get_protocols: * @stream: a #GstRTSPStream * * Get the allowed protocols of @stream. * * Returns: a #GstRTSPLowerTrans */ GstRTSPLowerTrans gst_rtsp_stream_get_protocols (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstRTSPLowerTrans res; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), GST_RTSP_LOWER_TRANS_UNKNOWN); priv = stream->priv; g_mutex_lock (&priv->lock); res = priv->allowed_protocols; g_mutex_unlock (&priv->lock); return res; } /** * gst_rtsp_stream_set_address_pool: * @stream: a #GstRTSPStream * @pool: (transfer none) (nullable): a #GstRTSPAddressPool * * configure @pool to be used as the address pool of @stream. */ void gst_rtsp_stream_set_address_pool (GstRTSPStream * stream, GstRTSPAddressPool * pool) { GstRTSPStreamPrivate *priv; GstRTSPAddressPool *old; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; GST_LOG_OBJECT (stream, "set address pool %p", pool); g_mutex_lock (&priv->lock); if ((old = priv->pool) != pool) priv->pool = pool ? g_object_ref (pool) : NULL; else old = NULL; g_mutex_unlock (&priv->lock); if (old) g_object_unref (old); } /** * gst_rtsp_stream_get_address_pool: * @stream: a #GstRTSPStream * * Get the #GstRTSPAddressPool used as the address pool of @stream. * * Returns: (transfer full) (nullable): the #GstRTSPAddressPool of @stream. * g_object_unref() after usage. */ GstRTSPAddressPool * gst_rtsp_stream_get_address_pool (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstRTSPAddressPool *result; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&priv->lock); if ((result = priv->pool)) g_object_ref (result); g_mutex_unlock (&priv->lock); return result; } /** * gst_rtsp_stream_set_multicast_iface: * @stream: a #GstRTSPStream * @multicast_iface: (transfer none) (nullable): a multicast interface name * * configure @multicast_iface to be used for @stream. */ void gst_rtsp_stream_set_multicast_iface (GstRTSPStream * stream, const gchar * multicast_iface) { GstRTSPStreamPrivate *priv; gchar *old; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; GST_LOG_OBJECT (stream, "set multicast iface %s", GST_STR_NULL (multicast_iface)); g_mutex_lock (&priv->lock); if ((old = priv->multicast_iface) != multicast_iface) priv->multicast_iface = multicast_iface ? g_strdup (multicast_iface) : NULL; else old = NULL; g_mutex_unlock (&priv->lock); if (old) g_free (old); } /** * gst_rtsp_stream_get_multicast_iface: * @stream: a #GstRTSPStream * * Get the multicast interface used for @stream. * * Returns: (transfer full) (nullable): the multicast interface for @stream. * g_free() after usage. */ gchar * gst_rtsp_stream_get_multicast_iface (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gchar *result; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&priv->lock); if ((result = priv->multicast_iface)) result = g_strdup (result); g_mutex_unlock (&priv->lock); return result; } /** * gst_rtsp_stream_get_multicast_address: * @stream: a #GstRTSPStream * @family: the #GSocketFamily * * Get the multicast address of @stream for @family. The original * #GstRTSPAddress is cached and copy is returned, so freeing the return value * won't release the address from the pool. * * Returns: (transfer full) (nullable): the #GstRTSPAddress of @stream * or %NULL when no address could be allocated. gst_rtsp_address_free() * after usage. */ GstRTSPAddress * gst_rtsp_stream_get_multicast_address (GstRTSPStream * stream, GSocketFamily family) { GstRTSPStreamPrivate *priv; GstRTSPAddress *result; GstRTSPAddress **addrp; GstRTSPAddressFlags flags; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&stream->priv->lock); if (family == G_SOCKET_FAMILY_IPV6) { flags = GST_RTSP_ADDRESS_FLAG_IPV6; addrp = &priv->mcast_addr_v6; } else { flags = GST_RTSP_ADDRESS_FLAG_IPV4; addrp = &priv->mcast_addr_v4; } if (*addrp == NULL) { if (priv->pool == NULL) goto no_pool; flags |= GST_RTSP_ADDRESS_FLAG_EVEN_PORT | GST_RTSP_ADDRESS_FLAG_MULTICAST; *addrp = gst_rtsp_address_pool_acquire_address (priv->pool, flags, 2); if (*addrp == NULL) goto no_address; /* FIXME: Also reserve the same port with unicast ANY address, since that's * where we are going to bind our socket. Probably loop until we find a port * available in both mcast and unicast pools. Maybe GstRTSPAddressPool * should do it for us when both GST_RTSP_ADDRESS_FLAG_MULTICAST and * GST_RTSP_ADDRESS_FLAG_UNICAST are givent. */ } result = gst_rtsp_address_copy (*addrp); g_mutex_unlock (&stream->priv->lock); return result; /* ERRORS */ no_pool: { GST_ERROR_OBJECT (stream, "no address pool specified"); g_mutex_unlock (&stream->priv->lock); return NULL; } no_address: { GST_ERROR_OBJECT (stream, "failed to acquire address from pool"); g_mutex_unlock (&stream->priv->lock); return NULL; } } /** * gst_rtsp_stream_reserve_address: * @stream: a #GstRTSPStream * @address: an address * @port: a port * @n_ports: n_ports * @ttl: a TTL * * Reserve @address and @port as the address and port of @stream. The original * #GstRTSPAddress is cached and copy is returned, so freeing the return value * won't release the address from the pool. * * Returns: (nullable): the #GstRTSPAddress of @stream or %NULL when * the address could not be reserved. gst_rtsp_address_free() after * usage. */ GstRTSPAddress * gst_rtsp_stream_reserve_address (GstRTSPStream * stream, const gchar * address, guint port, guint n_ports, guint ttl) { GstRTSPStreamPrivate *priv; GstRTSPAddress *result; GInetAddress *addr; GSocketFamily family; GstRTSPAddress **addrp; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); g_return_val_if_fail (address != NULL, NULL); g_return_val_if_fail (port > 0, NULL); g_return_val_if_fail (n_ports > 0, NULL); g_return_val_if_fail (ttl > 0, NULL); priv = stream->priv; addr = g_inet_address_new_from_string (address); if (!addr) { GST_ERROR ("failed to get inet addr from %s", address); family = G_SOCKET_FAMILY_IPV4; } else { family = g_inet_address_get_family (addr); g_object_unref (addr); } if (family == G_SOCKET_FAMILY_IPV6) addrp = &priv->mcast_addr_v6; else addrp = &priv->mcast_addr_v4; g_mutex_lock (&priv->lock); if (*addrp == NULL) { GstRTSPAddressPoolResult res; if (priv->pool == NULL) goto no_pool; res = gst_rtsp_address_pool_reserve_address (priv->pool, address, port, n_ports, ttl, addrp); if (res != GST_RTSP_ADDRESS_POOL_OK) goto no_address; /* FIXME: Also reserve the same port with unicast ANY address, since that's * where we are going to bind our socket. */ } else { if (g_ascii_strcasecmp ((*addrp)->address, address) || (*addrp)->port != port || (*addrp)->n_ports != n_ports || (*addrp)->ttl != ttl) goto different_address; } result = gst_rtsp_address_copy (*addrp); g_mutex_unlock (&priv->lock); return result; /* ERRORS */ no_pool: { GST_ERROR_OBJECT (stream, "no address pool specified"); g_mutex_unlock (&priv->lock); return NULL; } no_address: { GST_ERROR_OBJECT (stream, "failed to acquire address %s from pool", address); g_mutex_unlock (&priv->lock); return NULL; } different_address: { GST_ERROR_OBJECT (stream, "address %s is not the same as %s that was already reserved", address, (*addrp)->address); g_mutex_unlock (&priv->lock); return NULL; } } /* must be called with lock */ static void set_socket_for_udpsink (GstElement * udpsink, GSocket * socket, GSocketFamily family) { const gchar *multisink_socket; if (family == G_SOCKET_FAMILY_IPV6) multisink_socket = "socket-v6"; else multisink_socket = "socket"; g_object_set (G_OBJECT (udpsink), multisink_socket, socket, NULL); } /* must be called with lock */ static void set_multicast_socket_for_udpsink (GstElement * udpsink, GSocket * socket, GSocketFamily family, const gchar * multicast_iface, const gchar * addr_str, gint port, gint mcast_ttl) { set_socket_for_udpsink (udpsink, socket, family); if (multicast_iface) { GST_INFO ("setting multicast-iface %s", multicast_iface); g_object_set (G_OBJECT (udpsink), "multicast-iface", multicast_iface, NULL); } if (mcast_ttl > 0) { GST_INFO ("setting ttl-mc %d", mcast_ttl); g_object_set (G_OBJECT (udpsink), "ttl-mc", mcast_ttl, NULL); } } /* must be called with lock */ static void set_unicast_socket_for_udpsink (GstElement * udpsink, GSocket * socket, GSocketFamily family) { set_socket_for_udpsink (udpsink, socket, family); } static guint16 get_port_from_socket (GSocket * socket) { guint16 port; GSocketAddress *sockaddr; GError *err; GST_DEBUG ("socket: %p", socket); sockaddr = g_socket_get_local_address (socket, &err); if (sockaddr == NULL || !G_IS_INET_SOCKET_ADDRESS (sockaddr)) { g_clear_object (&sockaddr); GST_ERROR ("failed to get sockaddr: %s", err->message); g_error_free (err); return 0; } port = g_inet_socket_address_get_port (G_INET_SOCKET_ADDRESS (sockaddr)); g_object_unref (sockaddr); return port; } static gboolean create_and_configure_udpsink (GstRTSPStream * stream, GstElement ** udpsink, GSocket * socket_v4, GSocket * socket_v6, gboolean multicast, gboolean is_rtp, gint mcast_ttl) { GstRTSPStreamPrivate *priv = stream->priv; *udpsink = gst_element_factory_make ("multiudpsink", NULL); if (!*udpsink) goto no_udp_protocol; /* configure sinks */ g_object_set (G_OBJECT (*udpsink), "close-socket", FALSE, NULL); g_object_set (G_OBJECT (*udpsink), "send-duplicates", FALSE, NULL); if (is_rtp) g_object_set (G_OBJECT (*udpsink), "buffer-size", priv->buffer_size, NULL); else g_object_set (G_OBJECT (*udpsink), "sync", FALSE, NULL); /* Needs to be async for RECORD streams, otherwise we will never go to * PLAYING because the sinks will wait for data while the udpsrc can't * provide data with timestamps in PAUSED. */ if (!is_rtp || priv->sinkpad) g_object_set (G_OBJECT (*udpsink), "async", FALSE, NULL); if (multicast) { /* join multicast group when adding clients, so we'll start receiving from it. * We cannot rely on the udpsrc to join the group since its socket is always a * local unicast one. */ g_object_set (G_OBJECT (*udpsink), "auto-multicast", TRUE, NULL); g_object_set (G_OBJECT (*udpsink), "loop", FALSE, NULL); } /* update the dscp qos field in the sinks */ update_dscp_qos (stream, udpsink); if (priv->server_addr_v4) { GST_DEBUG_OBJECT (stream, "udp IPv4, configure udpsinks"); set_unicast_socket_for_udpsink (*udpsink, socket_v4, G_SOCKET_FAMILY_IPV4); } if (priv->server_addr_v6) { GST_DEBUG_OBJECT (stream, "udp IPv6, configure udpsinks"); set_unicast_socket_for_udpsink (*udpsink, socket_v6, G_SOCKET_FAMILY_IPV6); } if (multicast) { gint port; if (priv->mcast_addr_v4) { GST_DEBUG_OBJECT (stream, "mcast IPv4, configure udpsinks"); port = get_port_from_socket (socket_v4); if (!port) goto get_port_failed; set_multicast_socket_for_udpsink (*udpsink, socket_v4, G_SOCKET_FAMILY_IPV4, priv->multicast_iface, priv->mcast_addr_v4->address, port, mcast_ttl); } if (priv->mcast_addr_v6) { GST_DEBUG_OBJECT (stream, "mcast IPv6, configure udpsinks"); port = get_port_from_socket (socket_v6); if (!port) goto get_port_failed; set_multicast_socket_for_udpsink (*udpsink, socket_v6, G_SOCKET_FAMILY_IPV6, priv->multicast_iface, priv->mcast_addr_v6->address, port, mcast_ttl); } } return TRUE; /* ERRORS */ no_udp_protocol: { GST_ERROR_OBJECT (stream, "failed to create udpsink element"); return FALSE; } get_port_failed: { GST_ERROR_OBJECT (stream, "failed to get udp port"); return FALSE; } } /* must be called with lock */ static gboolean create_and_configure_udpsource (GstElement ** udpsrc, GSocket * socket) { GstStateChangeReturn ret; g_assert (socket != NULL); *udpsrc = gst_element_factory_make ("udpsrc", NULL); if (*udpsrc == NULL) goto error; g_object_set (G_OBJECT (*udpsrc), "socket", socket, NULL); /* The udpsrc cannot do the join because its socket is always a local unicast * one. The udpsink sharing the same socket will do it for us. */ g_object_set (G_OBJECT (*udpsrc), "auto-multicast", FALSE, NULL); g_object_set (G_OBJECT (*udpsrc), "loop", FALSE, NULL); g_object_set (G_OBJECT (*udpsrc), "close-socket", FALSE, NULL); ret = gst_element_set_state (*udpsrc, GST_STATE_READY); if (ret == GST_STATE_CHANGE_FAILURE) goto error; return TRUE; /* ERRORS */ error: { if (*udpsrc) { gst_element_set_state (*udpsrc, GST_STATE_NULL); g_clear_object (udpsrc); } return FALSE; } } static gboolean alloc_ports_one_family (GstRTSPStream * stream, GSocketFamily family, GSocket * socket_out[2], GstRTSPAddress ** server_addr_out, gboolean multicast, GstRTSPTransport * ct, gboolean use_transport_settings) { GstRTSPStreamPrivate *priv = stream->priv; GSocket *rtp_socket = NULL; GSocket *rtcp_socket = NULL; gint tmp_rtp, tmp_rtcp; guint count; GList *rejected_addresses = NULL; GstRTSPAddress *addr = NULL; GInetAddress *inetaddr = NULL; GSocketAddress *rtp_sockaddr = NULL; GSocketAddress *rtcp_sockaddr = NULL; GstRTSPAddressPool *pool; gboolean transport_settings_defined = FALSE; pool = priv->pool; count = 0; /* Start with random port */ tmp_rtp = 0; tmp_rtcp = 0; if (use_transport_settings) { if (!multicast) goto no_mcast; if (ct == NULL) goto no_transport; /* multicast and transport specific case */ if (ct->destination != NULL) { tmp_rtp = ct->port.min; tmp_rtcp = ct->port.max; /* check if the provided address is a multicast address */ inetaddr = g_inet_address_new_from_string (ct->destination); if (inetaddr == NULL) goto destination_error; if (!g_inet_address_get_is_multicast (inetaddr)) goto destination_no_mcast; if (!priv->bind_mcast_address) { g_clear_object (&inetaddr); inetaddr = g_inet_address_new_any (family); } GST_DEBUG_OBJECT (stream, "use transport settings"); transport_settings_defined = TRUE; } } if (priv->enable_rtcp) { rtcp_socket = g_socket_new (family, G_SOCKET_TYPE_DATAGRAM, G_SOCKET_PROTOCOL_UDP, NULL); if (!rtcp_socket) goto no_udp_protocol; g_socket_set_multicast_loopback (rtcp_socket, FALSE); } /* try to allocate UDP ports, the RTP port should be an even * number and the RTCP port (if enabled) should be the next (uneven) port */ again: if (rtp_socket == NULL) { rtp_socket = g_socket_new (family, G_SOCKET_TYPE_DATAGRAM, G_SOCKET_PROTOCOL_UDP, NULL); if (!rtp_socket) goto no_udp_protocol; g_socket_set_multicast_loopback (rtp_socket, FALSE); } if (!transport_settings_defined) { if ((pool && gst_rtsp_address_pool_has_unicast_addresses (pool)) || multicast) { GstRTSPAddressFlags flags; if (addr) { g_assert (*server_addr_out == NULL); rejected_addresses = g_list_prepend (rejected_addresses, addr); } if (!pool) goto no_pool; flags = GST_RTSP_ADDRESS_FLAG_EVEN_PORT; if (multicast) flags |= GST_RTSP_ADDRESS_FLAG_MULTICAST; else flags |= GST_RTSP_ADDRESS_FLAG_UNICAST; if (family == G_SOCKET_FAMILY_IPV6) flags |= GST_RTSP_ADDRESS_FLAG_IPV6; else flags |= GST_RTSP_ADDRESS_FLAG_IPV4; if (*server_addr_out) addr = *server_addr_out; else addr = gst_rtsp_address_pool_acquire_address (pool, flags, priv->enable_rtcp ? 2 : 1); if (addr == NULL) goto no_address; tmp_rtp = addr->port; g_clear_object (&inetaddr); /* FIXME: Does it really work with the IP_MULTICAST_ALL socket option and * socket control message set in udpsrc? */ if (priv->bind_mcast_address || !multicast) inetaddr = g_inet_address_new_from_string (addr->address); else inetaddr = g_inet_address_new_any (family); } else { if (tmp_rtp != 0) { tmp_rtp += 2; if (++count > 20) goto no_ports; } if (inetaddr == NULL) inetaddr = g_inet_address_new_any (family); } } rtp_sockaddr = g_inet_socket_address_new (inetaddr, tmp_rtp); if (!g_socket_bind (rtp_socket, rtp_sockaddr, FALSE, NULL)) { GST_DEBUG_OBJECT (stream, "rtp bind() failed, will try again"); g_object_unref (rtp_sockaddr); if (transport_settings_defined) { goto transport_settings_error; } else if (*server_addr_out && ((pool && gst_rtsp_address_pool_has_unicast_addresses (pool)) || multicast)) { goto no_address; } else { goto again; } } g_object_unref (rtp_sockaddr); rtp_sockaddr = g_socket_get_local_address (rtp_socket, NULL); if (rtp_sockaddr == NULL || !G_IS_INET_SOCKET_ADDRESS (rtp_sockaddr)) { g_clear_object (&rtp_sockaddr); goto socket_error; } if (!transport_settings_defined) { tmp_rtp = g_inet_socket_address_get_port (G_INET_SOCKET_ADDRESS (rtp_sockaddr)); /* check if port is even. RFC 3550 encorages the use of an even/odd port * pair, however it's not a strict requirement so this check is not done * for the client selected ports. */ if ((tmp_rtp & 1) != 0) { /* port not even, close and allocate another */ tmp_rtp++; g_object_unref (rtp_sockaddr); g_clear_object (&rtp_socket); goto again; } } g_object_unref (rtp_sockaddr); /* set port */ if (priv->enable_rtcp) { tmp_rtcp = tmp_rtp + 1; rtcp_sockaddr = g_inet_socket_address_new (inetaddr, tmp_rtcp); if (!g_socket_bind (rtcp_socket, rtcp_sockaddr, FALSE, NULL)) { GST_DEBUG_OBJECT (stream, "rctp bind() failed, will try again"); g_object_unref (rtcp_sockaddr); g_clear_object (&rtp_socket); if (transport_settings_defined) goto transport_settings_error; goto again; } g_object_unref (rtcp_sockaddr); } if (!addr) { addr = g_new0 (GstRTSPAddress, 1); addr->port = tmp_rtp; addr->n_ports = 2; if (transport_settings_defined) addr->address = g_strdup (ct->destination); else addr->address = g_inet_address_to_string (inetaddr); addr->ttl = ct->ttl; } g_clear_object (&inetaddr); if (multicast && (ct->ttl > 0) && (ct->ttl <= priv->max_mcast_ttl)) { GST_DEBUG ("setting mcast ttl to %d", ct->ttl); g_socket_set_multicast_ttl (rtp_socket, ct->ttl); if (rtcp_socket) g_socket_set_multicast_ttl (rtcp_socket, ct->ttl); } socket_out[0] = rtp_socket; socket_out[1] = rtcp_socket; *server_addr_out = addr; if (priv->enable_rtcp) { GST_DEBUG_OBJECT (stream, "allocated address: %s and ports: %d, %d", addr->address, tmp_rtp, tmp_rtcp); } else { GST_DEBUG_OBJECT (stream, "allocated address: %s and port: %d", addr->address, tmp_rtp); } g_list_free_full (rejected_addresses, (GDestroyNotify) gst_rtsp_address_free); return TRUE; /* ERRORS */ no_mcast: { GST_ERROR_OBJECT (stream, "failed to allocate UDP ports: wrong transport"); goto cleanup; } no_transport: { GST_ERROR_OBJECT (stream, "failed to allocate UDP ports: no transport"); goto cleanup; } destination_error: { GST_ERROR_OBJECT (stream, "failed to allocate UDP ports: destination error"); goto cleanup; } destination_no_mcast: { GST_ERROR_OBJECT (stream, "failed to allocate UDP ports: destination not multicast address"); goto cleanup; } no_udp_protocol: { GST_WARNING_OBJECT (stream, "failed to allocate UDP ports: protocol error"); goto cleanup; } no_pool: { GST_WARNING_OBJECT (stream, "failed to allocate UDP ports: no address pool specified"); goto cleanup; } no_address: { GST_WARNING_OBJECT (stream, "failed to acquire address from pool"); goto cleanup; } no_ports: { GST_WARNING_OBJECT (stream, "failed to allocate UDP ports: no ports"); goto cleanup; } transport_settings_error: { GST_ERROR_OBJECT (stream, "failed to allocate UDP ports with requested transport settings"); goto cleanup; } socket_error: { GST_WARNING_OBJECT (stream, "failed to allocate UDP ports: socket error"); goto cleanup; } cleanup: { if (inetaddr) g_object_unref (inetaddr); g_list_free_full (rejected_addresses, (GDestroyNotify) gst_rtsp_address_free); if (addr) gst_rtsp_address_free (addr); if (rtp_socket) g_object_unref (rtp_socket); if (rtcp_socket) g_object_unref (rtcp_socket); return FALSE; } } /* must be called with lock */ static gboolean add_mcast_client_addr (GstRTSPStream * stream, const gchar * destination, guint rtp_port, guint rtcp_port) { GstRTSPStreamPrivate *priv; GList *walk; UdpClientAddrInfo *client; GInetAddress *inet; priv = stream->priv; if (destination == NULL) return FALSE; inet = g_inet_address_new_from_string (destination); if (inet == NULL) goto invalid_address; if (!g_inet_address_get_is_multicast (inet)) { g_object_unref (inet); goto invalid_address; } g_object_unref (inet); for (walk = priv->mcast_clients; walk; walk = g_list_next (walk)) { UdpClientAddrInfo *cli = walk->data; if ((g_strcmp0 (cli->address, destination) == 0) && (cli->rtp_port == rtp_port)) { GST_DEBUG ("requested destination already exists: %s:%u-%u", destination, rtp_port, rtcp_port); cli->add_count++; return TRUE; } } client = g_new0 (UdpClientAddrInfo, 1); client->address = g_strdup (destination); client->rtp_port = rtp_port; client->add_count = 1; priv->mcast_clients = g_list_prepend (priv->mcast_clients, client); GST_DEBUG ("added mcast client %s:%u-%u", destination, rtp_port, rtcp_port); return TRUE; invalid_address: { GST_WARNING_OBJECT (stream, "Multicast address is invalid: %s", destination); return FALSE; } } /* must be called with lock */ static gboolean remove_mcast_client_addr (GstRTSPStream * stream, const gchar * destination, guint rtp_port, guint rtcp_port) { GstRTSPStreamPrivate *priv; GList *walk; priv = stream->priv; if (destination == NULL) goto no_destination; for (walk = priv->mcast_clients; walk; walk = g_list_next (walk)) { UdpClientAddrInfo *cli = walk->data; if ((g_strcmp0 (cli->address, destination) == 0) && (cli->rtp_port == rtp_port)) { cli->add_count--; if (!cli->add_count) { priv->mcast_clients = g_list_remove (priv->mcast_clients, cli); free_mcast_client (cli); } return TRUE; } } GST_WARNING_OBJECT (stream, "Address not found"); return FALSE; no_destination: { GST_WARNING_OBJECT (stream, "No destination has been provided"); return FALSE; } } /** * gst_rtsp_stream_allocate_udp_sockets: * @stream: a #GstRTSPStream * @family: protocol family * @transport: transport method * @use_client_settings: Whether to use client settings or not * * Allocates RTP and RTCP ports. * * Returns: %TRUE if the RTP and RTCP sockets have been succeccully allocated. */ gboolean gst_rtsp_stream_allocate_udp_sockets (GstRTSPStream * stream, GSocketFamily family, GstRTSPTransport * ct, gboolean use_transport_settings) { GstRTSPStreamPrivate *priv; gboolean ret = FALSE; GstRTSPLowerTrans transport; gboolean allocated = FALSE; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_return_val_if_fail (ct != NULL, FALSE); priv = stream->priv; transport = ct->lower_transport; g_mutex_lock (&priv->lock); if (transport == GST_RTSP_LOWER_TRANS_UDP_MCAST) { if (family == G_SOCKET_FAMILY_IPV4 && priv->mcast_socket_v4[0]) allocated = TRUE; else if (family == G_SOCKET_FAMILY_IPV6 && priv->mcast_socket_v6[0]) allocated = TRUE; } else if (transport == GST_RTSP_LOWER_TRANS_UDP) { if (family == G_SOCKET_FAMILY_IPV4 && priv->socket_v4[0]) allocated = TRUE; else if (family == G_SOCKET_FAMILY_IPV6 && priv->socket_v6[0]) allocated = TRUE; } if (allocated) { GST_DEBUG_OBJECT (stream, "Allocated already"); g_mutex_unlock (&priv->lock); return TRUE; } if (family == G_SOCKET_FAMILY_IPV4) { /* IPv4 */ if (transport == GST_RTSP_LOWER_TRANS_UDP) { /* UDP unicast */ GST_DEBUG_OBJECT (stream, "GST_RTSP_LOWER_TRANS_UDP, ipv4"); ret = alloc_ports_one_family (stream, G_SOCKET_FAMILY_IPV4, priv->socket_v4, &priv->server_addr_v4, FALSE, ct, FALSE); } else { /* multicast */ GST_DEBUG_OBJECT (stream, "GST_RTSP_LOWER_TRANS_MCAST_UDP, ipv4"); ret = alloc_ports_one_family (stream, G_SOCKET_FAMILY_IPV4, priv->mcast_socket_v4, &priv->mcast_addr_v4, TRUE, ct, use_transport_settings); } } else { /* IPv6 */ if (transport == GST_RTSP_LOWER_TRANS_UDP) { /* unicast */ GST_DEBUG_OBJECT (stream, "GST_RTSP_LOWER_TRANS_UDP, ipv6"); ret = alloc_ports_one_family (stream, G_SOCKET_FAMILY_IPV6, priv->socket_v6, &priv->server_addr_v6, FALSE, ct, FALSE); } else { /* multicast */ GST_DEBUG_OBJECT (stream, "GST_RTSP_LOWER_TRANS_MCAST_UDP, ipv6"); ret = alloc_ports_one_family (stream, G_SOCKET_FAMILY_IPV6, priv->mcast_socket_v6, &priv->mcast_addr_v6, TRUE, ct, use_transport_settings); } } g_mutex_unlock (&priv->lock); return ret; } /** * gst_rtsp_stream_set_client_side: * @stream: a #GstRTSPStream * @client_side: TRUE if this #GstRTSPStream is running on the 'client' side of * an RTSP connection. * * Sets the #GstRTSPStream as a 'client side' stream - used for sending * streams to an RTSP server via RECORD. This has the practical effect * of changing which UDP port numbers are used when setting up the local * side of the stream sending to be either the 'server' or 'client' pair * of a configured UDP transport. */ void gst_rtsp_stream_set_client_side (GstRTSPStream * stream, gboolean client_side) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_mutex_lock (&priv->lock); priv->client_side = client_side; g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_is_client_side: * @stream: a #GstRTSPStream * * See gst_rtsp_stream_set_client_side() * * Returns: TRUE if this #GstRTSPStream is client-side. */ gboolean gst_rtsp_stream_is_client_side (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gboolean ret; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); ret = priv->client_side; g_mutex_unlock (&priv->lock); return ret; } /** * gst_rtsp_stream_get_server_port: * @stream: a #GstRTSPStream * @server_port: (out): result server port * @family: the port family to get * * Fill @server_port with the port pair used by the server. This function can * only be called when @stream has been joined. */ void gst_rtsp_stream_get_server_port (GstRTSPStream * stream, GstRTSPRange * server_port, GSocketFamily family) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_return_if_fail (priv->joined_bin != NULL); if (server_port) { server_port->min = 0; server_port->max = 0; } g_mutex_lock (&priv->lock); if (family == G_SOCKET_FAMILY_IPV4) { if (server_port && priv->server_addr_v4) { server_port->min = priv->server_addr_v4->port; if (priv->enable_rtcp) { server_port->max = priv->server_addr_v4->port + priv->server_addr_v4->n_ports - 1; } } } else { if (server_port && priv->server_addr_v6) { server_port->min = priv->server_addr_v6->port; if (priv->enable_rtcp) { server_port->max = priv->server_addr_v6->port + priv->server_addr_v6->n_ports - 1; } } } g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_get_rtpsession: * @stream: a #GstRTSPStream * * Get the RTP session of this stream. * * Returns: (transfer full) (nullable): The RTP session of this stream. Unref after usage. */ GObject * gst_rtsp_stream_get_rtpsession (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GObject *session; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&priv->lock); if ((session = priv->session)) g_object_ref (session); g_mutex_unlock (&priv->lock); return session; } /** * gst_rtsp_stream_get_srtp_encoder: * @stream: a #GstRTSPStream * * Get the SRTP encoder for this stream. * * Returns: (transfer full) (nullable): The SRTP encoder for this stream. Unref after usage. */ GstElement * gst_rtsp_stream_get_srtp_encoder (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstElement *encoder; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&priv->lock); if ((encoder = priv->srtpenc)) g_object_ref (encoder); g_mutex_unlock (&priv->lock); return encoder; } /** * gst_rtsp_stream_get_ssrc: * @stream: a #GstRTSPStream * @ssrc: (out): result ssrc * * Get the SSRC used by the RTP session of this stream. This function can only * be called when @stream has been joined. */ void gst_rtsp_stream_get_ssrc (GstRTSPStream * stream, guint * ssrc) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_return_if_fail (priv->joined_bin != NULL); g_mutex_lock (&priv->lock); if (ssrc && priv->session) g_object_get (priv->session, "internal-ssrc", ssrc, NULL); g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_set_retransmission_time: * @stream: a #GstRTSPStream * @time: a #GstClockTime * * Set the amount of time to store retransmission packets. */ void gst_rtsp_stream_set_retransmission_time (GstRTSPStream * stream, GstClockTime time) { GST_DEBUG_OBJECT (stream, "set retransmission time %" G_GUINT64_FORMAT, time); g_mutex_lock (&stream->priv->lock); stream->priv->rtx_time = time; if (stream->priv->rtxsend) g_object_set (stream->priv->rtxsend, "max-size-time", GST_TIME_AS_MSECONDS (time), NULL); g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_get_retransmission_time: * @stream: a #GstRTSPStream * * Get the amount of time to store retransmission data. * * Returns: the amount of time to store retransmission data. */ GstClockTime gst_rtsp_stream_get_retransmission_time (GstRTSPStream * stream) { GstClockTime ret; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), 0); g_mutex_lock (&stream->priv->lock); ret = stream->priv->rtx_time; g_mutex_unlock (&stream->priv->lock); return ret; } /** * gst_rtsp_stream_set_retransmission_pt: * @stream: a #GstRTSPStream * @rtx_pt: a #guint * * Set the payload type (pt) for retransmission of this stream. */ void gst_rtsp_stream_set_retransmission_pt (GstRTSPStream * stream, guint rtx_pt) { g_return_if_fail (GST_IS_RTSP_STREAM (stream)); GST_DEBUG_OBJECT (stream, "set retransmission pt %u", rtx_pt); g_mutex_lock (&stream->priv->lock); stream->priv->rtx_pt = rtx_pt; if (stream->priv->rtxsend) { guint pt = gst_rtsp_stream_get_pt (stream); gchar *pt_s = g_strdup_printf ("%d", pt); GstStructure *rtx_pt_map = gst_structure_new ("application/x-rtp-pt-map", pt_s, G_TYPE_UINT, rtx_pt, NULL); g_object_set (stream->priv->rtxsend, "payload-type-map", rtx_pt_map, NULL); g_free (pt_s); gst_structure_free (rtx_pt_map); } g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_get_retransmission_pt: * @stream: a #GstRTSPStream * * Get the payload-type used for retransmission of this stream * * Returns: The retransmission PT. */ guint gst_rtsp_stream_get_retransmission_pt (GstRTSPStream * stream) { guint rtx_pt; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), 0); g_mutex_lock (&stream->priv->lock); rtx_pt = stream->priv->rtx_pt; g_mutex_unlock (&stream->priv->lock); return rtx_pt; } /** * gst_rtsp_stream_set_buffer_size: * @stream: a #GstRTSPStream * @size: the buffer size * * Set the size of the UDP transmission buffer (in bytes) * Needs to be set before the stream is joined to a bin. * * Since: 1.6 */ void gst_rtsp_stream_set_buffer_size (GstRTSPStream * stream, guint size) { g_mutex_lock (&stream->priv->lock); stream->priv->buffer_size = size; g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_get_buffer_size: * @stream: a #GstRTSPStream * * Get the size of the UDP transmission buffer (in bytes) * * Returns: the size of the UDP TX buffer * * Since: 1.6 */ guint gst_rtsp_stream_get_buffer_size (GstRTSPStream * stream) { guint buffer_size; g_mutex_lock (&stream->priv->lock); buffer_size = stream->priv->buffer_size; g_mutex_unlock (&stream->priv->lock); return buffer_size; } /** * gst_rtsp_stream_set_max_mcast_ttl: * @stream: a #GstRTSPStream * @ttl: the new multicast ttl value * * Set the maximum time-to-live value of outgoing multicast packets. * * Returns: %TRUE if the requested ttl has been set successfully. * * Since: 1.16 */ gboolean gst_rtsp_stream_set_max_mcast_ttl (GstRTSPStream * stream, guint ttl) { g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_mutex_lock (&stream->priv->lock); if (ttl == 0 || ttl > DEFAULT_MAX_MCAST_TTL) { GST_WARNING_OBJECT (stream, "The reqested mcast TTL value is not valid."); g_mutex_unlock (&stream->priv->lock); return FALSE; } stream->priv->max_mcast_ttl = ttl; g_mutex_unlock (&stream->priv->lock); return TRUE; } /** * gst_rtsp_stream_get_max_mcast_ttl: * @stream: a #GstRTSPStream * * Get the the maximum time-to-live value of outgoing multicast packets. * * Returns: the maximum time-to-live value of outgoing multicast packets. * * Since: 1.16 */ guint gst_rtsp_stream_get_max_mcast_ttl (GstRTSPStream * stream) { guint ttl; g_mutex_lock (&stream->priv->lock); ttl = stream->priv->max_mcast_ttl; g_mutex_unlock (&stream->priv->lock); return ttl; } /** * gst_rtsp_stream_verify_mcast_ttl: * @stream: a #GstRTSPStream * @ttl: a requested multicast ttl * * Check if the requested multicast ttl value is allowed. * * Returns: TRUE if the requested ttl value is allowed. * * Since: 1.16 */ gboolean gst_rtsp_stream_verify_mcast_ttl (GstRTSPStream * stream, guint ttl) { gboolean res = FALSE; g_mutex_lock (&stream->priv->lock); if ((ttl > 0) && (ttl <= stream->priv->max_mcast_ttl)) res = TRUE; g_mutex_unlock (&stream->priv->lock); return res; } /** * gst_rtsp_stream_set_bind_mcast_address: * @stream: a #GstRTSPStream, * @bind_mcast_addr: the new value * * Decide whether the multicast socket should be bound to a multicast address or * INADDR_ANY. * * Since: 1.16 */ void gst_rtsp_stream_set_bind_mcast_address (GstRTSPStream * stream, gboolean bind_mcast_addr) { g_return_if_fail (GST_IS_RTSP_STREAM (stream)); g_mutex_lock (&stream->priv->lock); stream->priv->bind_mcast_address = bind_mcast_addr; g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_is_bind_mcast_address: * @stream: a #GstRTSPStream * * Check if multicast sockets are configured to be bound to multicast addresses. * * Returns: %TRUE if multicast sockets are configured to be bound to multicast addresses. * * Since: 1.16 */ gboolean gst_rtsp_stream_is_bind_mcast_address (GstRTSPStream * stream) { gboolean result; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_mutex_lock (&stream->priv->lock); result = stream->priv->bind_mcast_address; g_mutex_unlock (&stream->priv->lock); return result; } void gst_rtsp_stream_set_enable_rtcp (GstRTSPStream * stream, gboolean enable) { g_return_if_fail (GST_IS_RTSP_STREAM (stream)); g_mutex_lock (&stream->priv->lock); stream->priv->enable_rtcp = enable; g_mutex_unlock (&stream->priv->lock); } /* executed from streaming thread */ static void caps_notify (GstPad * pad, GParamSpec * unused, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; GstCaps *newcaps, *oldcaps; newcaps = gst_pad_get_current_caps (pad); GST_INFO ("stream %p received caps %p, %" GST_PTR_FORMAT, stream, newcaps, newcaps); g_mutex_lock (&priv->lock); oldcaps = priv->caps; priv->caps = newcaps; g_mutex_unlock (&priv->lock); if (oldcaps) gst_caps_unref (oldcaps); } static void dump_structure (const GstStructure * s) { gchar *sstr; sstr = gst_structure_to_string (s); GST_INFO ("structure: %s", sstr); g_free (sstr); } static GstRTSPStreamTransport * find_transport (GstRTSPStream * stream, const gchar * rtcp_from) { GstRTSPStreamPrivate *priv = stream->priv; GList *walk; GstRTSPStreamTransport *result = NULL; const gchar *tmp; gchar *dest; guint port; if (rtcp_from == NULL) return NULL; tmp = g_strrstr (rtcp_from, ":"); if (tmp == NULL) return NULL; port = atoi (tmp + 1); dest = g_strndup (rtcp_from, tmp - rtcp_from); g_mutex_lock (&priv->lock); GST_INFO ("finding %s:%d in %d transports", dest, port, g_list_length (priv->transports)); for (walk = priv->transports; walk; walk = g_list_next (walk)) { GstRTSPStreamTransport *trans = walk->data; const GstRTSPTransport *tr; gint min, max; tr = gst_rtsp_stream_transport_get_transport (trans); if (priv->client_side) { /* In client side mode the 'destination' is the RTSP server, so send * to those ports */ min = tr->server_port.min; max = tr->server_port.max; } else { min = tr->client_port.min; max = tr->client_port.max; } if ((g_ascii_strcasecmp (tr->destination, dest) == 0) && (min == port || max == port)) { result = trans; break; } } if (result) g_object_ref (result); g_mutex_unlock (&priv->lock); g_free (dest); return result; } static GstRTSPStreamTransport * check_transport (GObject * source, GstRTSPStream * stream) { GstStructure *stats; GstRTSPStreamTransport *trans; /* see if we have a stream to match with the origin of the RTCP packet */ trans = g_object_get_qdata (source, ssrc_stream_map_key); if (trans == NULL) { g_object_get (source, "stats", &stats, NULL); if (stats) { const gchar *rtcp_from; dump_structure (stats); rtcp_from = gst_structure_get_string (stats, "rtcp-from"); if ((trans = find_transport (stream, rtcp_from))) { GST_INFO ("%p: found transport %p for source %p", stream, trans, source); g_object_set_qdata_full (source, ssrc_stream_map_key, trans, g_object_unref); } gst_structure_free (stats); } } return trans; } static void on_new_ssrc (GObject * session, GObject * source, GstRTSPStream * stream) { GstRTSPStreamTransport *trans; GST_INFO ("%p: new source %p", stream, source); trans = check_transport (source, stream); if (trans) GST_INFO ("%p: source %p for transport %p", stream, source, trans); } static void on_ssrc_sdes (GObject * session, GObject * source, GstRTSPStream * stream) { GST_INFO ("%p: new SDES %p", stream, source); } static void on_ssrc_active (GObject * session, GObject * source, GstRTSPStream * stream) { GstRTSPStreamTransport *trans; trans = check_transport (source, stream); if (trans) { GST_INFO ("%p: source %p in transport %p is active", stream, source, trans); gst_rtsp_stream_transport_keep_alive (trans); } #ifdef DUMP_STATS { GstStructure *stats; g_object_get (source, "stats", &stats, NULL); if (stats) { dump_structure (stats); gst_structure_free (stats); } } #endif } static void on_bye_ssrc (GObject * session, GObject * source, GstRTSPStream * stream) { GST_INFO ("%p: source %p bye", stream, source); } static void on_bye_timeout (GObject * session, GObject * source, GstRTSPStream * stream) { GstRTSPStreamTransport *trans; GST_INFO ("%p: source %p bye timeout", stream, source); if ((trans = g_object_get_qdata (source, ssrc_stream_map_key))) { gst_rtsp_stream_transport_set_timed_out (trans, TRUE); g_object_set_qdata (source, ssrc_stream_map_key, NULL); } } static void on_timeout (GObject * session, GObject * source, GstRTSPStream * stream) { GstRTSPStreamTransport *trans; GST_INFO ("%p: source %p timeout", stream, source); if ((trans = g_object_get_qdata (source, ssrc_stream_map_key))) { gst_rtsp_stream_transport_set_timed_out (trans, TRUE); g_object_set_qdata (source, ssrc_stream_map_key, NULL); } } static void on_new_sender_ssrc (GObject * session, GObject * source, GstRTSPStream * stream) { GST_INFO ("%p: new sender source %p", stream, source); #ifndef DUMP_STATS { GstStructure *stats; g_object_get (source, "stats", &stats, NULL); if (stats) { dump_structure (stats); gst_structure_free (stats); } } #endif } static void on_sender_ssrc_active (GObject * session, GObject * source, GstRTSPStream * stream) { #ifndef DUMP_STATS { GstStructure *stats; g_object_get (source, "stats", &stats, NULL); if (stats) { dump_structure (stats); gst_structure_free (stats); } } #endif } static void clear_tr_cache (GstRTSPStreamPrivate * priv) { if (priv->tr_cache) g_ptr_array_unref (priv->tr_cache); priv->tr_cache = NULL; } /* With lock taken */ static gboolean any_transport_ready (GstRTSPStream * stream, gboolean is_rtp) { gboolean ret = TRUE; GstRTSPStreamPrivate *priv = stream->priv; GPtrArray *transports; gint index; transports = priv->tr_cache; if (!transports) goto done; for (index = 0; index < transports->len; index++) { GstRTSPStreamTransport *tr = g_ptr_array_index (transports, index); if (!gst_rtsp_stream_transport_check_back_pressure (tr, is_rtp)) { ret = TRUE; break; } else { ret = FALSE; } } done: return ret; } /* Must be called *without* priv->lock */ static gboolean push_data (GstRTSPStream * stream, GstRTSPStreamTransport * trans, GstBuffer * buffer, GstBufferList * buffer_list, gboolean is_rtp) { gboolean send_ret = TRUE; if (is_rtp) { if (buffer) send_ret = gst_rtsp_stream_transport_send_rtp (trans, buffer); if (buffer_list) send_ret = gst_rtsp_stream_transport_send_rtp_list (trans, buffer_list); } else { if (buffer) send_ret = gst_rtsp_stream_transport_send_rtcp (trans, buffer); if (buffer_list) send_ret = gst_rtsp_stream_transport_send_rtcp_list (trans, buffer_list); } return send_ret; } /* With priv->lock */ static void ensure_cached_transports (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; GList *walk; if (priv->tr_cache_cookie != priv->transports_cookie) { clear_tr_cache (priv); priv->tr_cache = g_ptr_array_new_full (priv->n_tcp_transports, g_object_unref); for (walk = priv->transports; walk; walk = g_list_next (walk)) { GstRTSPStreamTransport *tr = (GstRTSPStreamTransport *) walk->data; const GstRTSPTransport *t = gst_rtsp_stream_transport_get_transport (tr); if (t->lower_transport != GST_RTSP_LOWER_TRANS_TCP) continue; g_ptr_array_add (priv->tr_cache, g_object_ref (tr)); } priv->tr_cache_cookie = priv->transports_cookie; } } /* Must be called *without* priv->lock */ static void check_transport_backlog (GstRTSPStream * stream, GstRTSPStreamTransport * trans) { GstRTSPStreamPrivate *priv = stream->priv; gboolean send_ret = TRUE; gst_rtsp_stream_transport_lock_backlog (trans); if (!gst_rtsp_stream_transport_backlog_is_empty (trans)) { GstBuffer *buffer; GstBufferList *buffer_list; gboolean is_rtp; gboolean popped; is_rtp = gst_rtsp_stream_transport_backlog_peek_is_rtp (trans); if (!gst_rtsp_stream_transport_check_back_pressure (trans, is_rtp)) { popped = gst_rtsp_stream_transport_backlog_pop (trans, &buffer, &buffer_list, &is_rtp); g_assert (popped == TRUE); send_ret = push_data (stream, trans, buffer, buffer_list, is_rtp); gst_clear_buffer (&buffer); gst_clear_buffer_list (&buffer_list); } } gst_rtsp_stream_transport_unlock_backlog (trans); if (!send_ret) { /* remove transport on send error */ g_mutex_lock (&priv->lock); update_transport (stream, trans, FALSE); g_mutex_unlock (&priv->lock); } } /* Must be called with priv->lock */ static void send_tcp_message (GstRTSPStream * stream, gint idx) { GstRTSPStreamPrivate *priv = stream->priv; GstAppSink *sink; GstSample *sample; GstBuffer *buffer; GstBufferList *buffer_list; gboolean is_rtp; GPtrArray *transports; if (!priv->have_buffer[idx]) return; ensure_cached_transports (stream); is_rtp = (idx == 0); if (!any_transport_ready (stream, is_rtp)) return; priv->have_buffer[idx] = FALSE; if (priv->appsink[idx] == NULL) { /* session expired */ return; } sink = GST_APP_SINK (priv->appsink[idx]); sample = gst_app_sink_pull_sample (sink); if (!sample) { return; } buffer = gst_sample_get_buffer (sample); buffer_list = gst_sample_get_buffer_list (sample); /* We will get one message-sent notification per buffer or * complete buffer-list. We handle each buffer-list as a unit */ transports = priv->tr_cache; if (transports) g_ptr_array_ref (transports); if (transports) { gint index; for (index = 0; index < transports->len; index++) { GstRTSPStreamTransport *tr = g_ptr_array_index (transports, index); GstBuffer *buf_ref = NULL; GstBufferList *buflist_ref = NULL; gst_rtsp_stream_transport_lock_backlog (tr); if (buffer) buf_ref = gst_buffer_ref (buffer); if (buffer_list) buflist_ref = gst_buffer_list_ref (buffer_list); if (!gst_rtsp_stream_transport_backlog_push (tr, buf_ref, buflist_ref, is_rtp)) { GST_ERROR_OBJECT (stream, "Dropping slow transport %" GST_PTR_FORMAT, tr); update_transport (stream, tr, FALSE); } gst_rtsp_stream_transport_unlock_backlog (tr); } } gst_sample_unref (sample); g_mutex_unlock (&priv->lock); if (transports) { gint index; for (index = 0; index < transports->len; index++) { GstRTSPStreamTransport *tr = g_ptr_array_index (transports, index); check_transport_backlog (stream, tr); } g_ptr_array_unref (transports); } g_mutex_lock (&priv->lock); } static gpointer send_func (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; g_mutex_lock (&priv->send_lock); while (priv->continue_sending) { int i; int idx = -1; guint cookie; cookie = priv->send_cookie; g_mutex_unlock (&priv->send_lock); g_mutex_lock (&priv->lock); /* iterate from 1 and down, so we prioritize RTCP over RTP */ for (i = 1; i >= 0; i--) { if (priv->have_buffer[i]) { /* send message */ idx = i; break; } } if (idx != -1) { send_tcp_message (stream, idx); } g_mutex_unlock (&priv->lock); g_mutex_lock (&priv->send_lock); while (cookie == priv->send_cookie && priv->continue_sending) { g_cond_wait (&priv->send_cond, &priv->send_lock); } } g_mutex_unlock (&priv->send_lock); return NULL; } static GstFlowReturn handle_new_sample (GstAppSink * sink, gpointer user_data) { GstRTSPStream *stream = user_data; GstRTSPStreamPrivate *priv = stream->priv; int i; g_mutex_lock (&priv->lock); for (i = 0; i < 2; i++) { if (GST_ELEMENT_CAST (sink) == priv->appsink[i]) { priv->have_buffer[i] = TRUE; break; } } if (priv->send_thread == NULL) { priv->send_thread = g_thread_new (NULL, (GThreadFunc) send_func, user_data); } g_mutex_unlock (&priv->lock); g_mutex_lock (&priv->send_lock); priv->send_cookie++; g_cond_signal (&priv->send_cond); g_mutex_unlock (&priv->send_lock); return GST_FLOW_OK; } static GstAppSinkCallbacks sink_cb = { NULL, /* not interested in EOS */ NULL, /* not interested in preroll samples */ handle_new_sample, }; static GstElement * get_rtp_encoder (GstRTSPStream * stream, guint session) { GstRTSPStreamPrivate *priv = stream->priv; if (priv->srtpenc == NULL) { gchar *name; name = g_strdup_printf ("srtpenc_%u", session); priv->srtpenc = gst_element_factory_make ("srtpenc", name); g_free (name); g_object_set (priv->srtpenc, "random-key", TRUE, NULL); } return gst_object_ref (priv->srtpenc); } static GstElement * request_rtp_encoder (GstElement * rtpbin, guint session, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; GstElement *oldenc, *enc; GstPad *pad; gchar *name; if (priv->idx != session) return NULL; GST_DEBUG_OBJECT (stream, "make RTP encoder for session %u", session); oldenc = priv->srtpenc; enc = get_rtp_encoder (stream, session); name = g_strdup_printf ("rtp_sink_%d", session); pad = gst_element_request_pad_simple (enc, name); g_free (name); gst_object_unref (pad); if (oldenc == NULL) g_signal_emit (stream, gst_rtsp_stream_signals[SIGNAL_NEW_RTP_ENCODER], 0, enc); return enc; } static GstElement * request_rtcp_encoder (GstElement * rtpbin, guint session, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; GstElement *oldenc, *enc; GstPad *pad; gchar *name; if (priv->idx != session) return NULL; GST_DEBUG_OBJECT (stream, "make RTCP encoder for session %u", session); oldenc = priv->srtpenc; enc = get_rtp_encoder (stream, session); name = g_strdup_printf ("rtcp_sink_%d", session); pad = gst_element_request_pad_simple (enc, name); g_free (name); gst_object_unref (pad); if (oldenc == NULL) g_signal_emit (stream, gst_rtsp_stream_signals[SIGNAL_NEW_RTCP_ENCODER], 0, enc); return enc; } static GstCaps * request_key (GstElement * srtpdec, guint ssrc, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; GstCaps *caps; GST_DEBUG ("request key %08x", ssrc); g_mutex_lock (&priv->lock); if ((caps = g_hash_table_lookup (priv->keys, GINT_TO_POINTER (ssrc)))) gst_caps_ref (caps); g_mutex_unlock (&priv->lock); return caps; } static GstElement * request_rtp_rtcp_decoder (GstElement * rtpbin, guint session, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; if (priv->idx != session) return NULL; if (priv->srtpdec == NULL) { gchar *name; name = g_strdup_printf ("srtpdec_%u", session); priv->srtpdec = gst_element_factory_make ("srtpdec", name); g_free (name); g_signal_connect (priv->srtpdec, "request-key", (GCallback) request_key, stream); g_signal_emit (stream, gst_rtsp_stream_signals[SIGNAL_NEW_RTP_RTCP_DECODER], 0, priv->srtpdec); } return gst_object_ref (priv->srtpdec); } /** * gst_rtsp_stream_request_aux_sender: * @stream: a #GstRTSPStream * @sessid: the session id * * Creating a rtxsend bin * * Returns: (transfer full) (nullable): a #GstElement. * * Since: 1.6 */ GstElement * gst_rtsp_stream_request_aux_sender (GstRTSPStream * stream, guint sessid) { GstElement *bin; GstPad *pad; GstStructure *pt_map; gchar *name; guint pt, rtx_pt; gchar *pt_s; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); pt = gst_rtsp_stream_get_pt (stream); pt_s = g_strdup_printf ("%u", pt); rtx_pt = stream->priv->rtx_pt; GST_INFO ("creating rtxsend with pt %u to %u", pt, rtx_pt); bin = gst_bin_new (NULL); stream->priv->rtxsend = gst_element_factory_make ("rtprtxsend", NULL); pt_map = gst_structure_new ("application/x-rtp-pt-map", pt_s, G_TYPE_UINT, rtx_pt, NULL); g_object_set (stream->priv->rtxsend, "payload-type-map", pt_map, "max-size-time", GST_TIME_AS_MSECONDS (stream->priv->rtx_time), NULL); g_free (pt_s); gst_structure_free (pt_map); gst_bin_add (GST_BIN (bin), gst_object_ref (stream->priv->rtxsend)); pad = gst_element_get_static_pad (stream->priv->rtxsend, "src"); name = g_strdup_printf ("src_%u", sessid); gst_element_add_pad (bin, gst_ghost_pad_new (name, pad)); g_free (name); gst_object_unref (pad); pad = gst_element_get_static_pad (stream->priv->rtxsend, "sink"); name = g_strdup_printf ("sink_%u", sessid); gst_element_add_pad (bin, gst_ghost_pad_new (name, pad)); g_free (name); gst_object_unref (pad); return bin; } static void add_rtx_pt (gpointer key, GstCaps * caps, GstStructure * pt_map) { guint pt = GPOINTER_TO_INT (key); const GstStructure *s = gst_caps_get_structure (caps, 0); const gchar *apt; if (!g_strcmp0 (gst_structure_get_string (s, "encoding-name"), "RTX") && (apt = gst_structure_get_string (s, "apt"))) { gst_structure_set (pt_map, apt, G_TYPE_UINT, pt, NULL); } } /* Call with priv->lock taken */ static void update_rtx_receive_pt_map (GstRTSPStream * stream) { GstStructure *pt_map; if (!stream->priv->rtxreceive) goto done; pt_map = gst_structure_new_empty ("application/x-rtp-pt-map"); g_hash_table_foreach (stream->priv->ptmap, (GHFunc) add_rtx_pt, pt_map); g_object_set (stream->priv->rtxreceive, "payload-type-map", pt_map, NULL); gst_structure_free (pt_map); done: return; } static void retrieve_ulpfec_pt (gpointer key, GstCaps * caps, GstElement * ulpfec_decoder) { guint pt = GPOINTER_TO_INT (key); const GstStructure *s = gst_caps_get_structure (caps, 0); if (!g_strcmp0 (gst_structure_get_string (s, "encoding-name"), "ULPFEC")) g_object_set (ulpfec_decoder, "pt", pt, NULL); } static void update_ulpfec_decoder_pt (GstRTSPStream * stream) { if (!stream->priv->ulpfec_decoder) goto done; g_hash_table_foreach (stream->priv->ptmap, (GHFunc) retrieve_ulpfec_pt, stream->priv->ulpfec_decoder); done: return; } /** * gst_rtsp_stream_request_aux_receiver: * @stream: a #GstRTSPStream * @sessid: the session id * * Creating a rtxreceive bin * * Returns: (transfer full) (nullable): a #GstElement. * * Since: 1.16 */ GstElement * gst_rtsp_stream_request_aux_receiver (GstRTSPStream * stream, guint sessid) { GstElement *bin; GstPad *pad; gchar *name; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); bin = gst_bin_new (NULL); stream->priv->rtxreceive = gst_element_factory_make ("rtprtxreceive", NULL); update_rtx_receive_pt_map (stream); update_ulpfec_decoder_pt (stream); gst_bin_add (GST_BIN (bin), gst_object_ref (stream->priv->rtxreceive)); pad = gst_element_get_static_pad (stream->priv->rtxreceive, "src"); name = g_strdup_printf ("src_%u", sessid); gst_element_add_pad (bin, gst_ghost_pad_new (name, pad)); g_free (name); gst_object_unref (pad); pad = gst_element_get_static_pad (stream->priv->rtxreceive, "sink"); name = g_strdup_printf ("sink_%u", sessid); gst_element_add_pad (bin, gst_ghost_pad_new (name, pad)); g_free (name); gst_object_unref (pad); return bin; } /** * gst_rtsp_stream_set_pt_map: * @stream: a #GstRTSPStream * @pt: the pt * @caps: a #GstCaps * * Configure a pt map between @pt and @caps. */ void gst_rtsp_stream_set_pt_map (GstRTSPStream * stream, guint pt, GstCaps * caps) { GstRTSPStreamPrivate *priv = stream->priv; if (!GST_IS_CAPS (caps)) return; g_mutex_lock (&priv->lock); g_hash_table_insert (priv->ptmap, GINT_TO_POINTER (pt), gst_caps_ref (caps)); update_rtx_receive_pt_map (stream); g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_set_publish_clock_mode: * @stream: a #GstRTSPStream * @mode: the clock publish mode * * Sets if and how the stream clock should be published according to RFC7273. * * Since: 1.8 */ void gst_rtsp_stream_set_publish_clock_mode (GstRTSPStream * stream, GstRTSPPublishClockMode mode) { GstRTSPStreamPrivate *priv; priv = stream->priv; g_mutex_lock (&priv->lock); priv->publish_clock_mode = mode; g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_get_publish_clock_mode: * @stream: a #GstRTSPStream * * Gets if and how the stream clock should be published according to RFC7273. * * Returns: The GstRTSPPublishClockMode * * Since: 1.8 */ GstRTSPPublishClockMode gst_rtsp_stream_get_publish_clock_mode (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstRTSPPublishClockMode ret; priv = stream->priv; g_mutex_lock (&priv->lock); ret = priv->publish_clock_mode; g_mutex_unlock (&priv->lock); return ret; } static GstCaps * request_pt_map (GstElement * rtpbin, guint session, guint pt, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; GstCaps *caps = NULL; g_mutex_lock (&priv->lock); if (priv->idx == session) { caps = g_hash_table_lookup (priv->ptmap, GINT_TO_POINTER (pt)); if (caps) { GST_DEBUG ("Stream %p, pt %u: caps %" GST_PTR_FORMAT, stream, pt, caps); gst_caps_ref (caps); } else { GST_DEBUG ("Stream %p, pt %u: no caps", stream, pt); } } g_mutex_unlock (&priv->lock); return caps; } static void pad_added (GstElement * rtpbin, GstPad * pad, GstRTSPStream * stream) { GstRTSPStreamPrivate *priv = stream->priv; gchar *name; GstPadLinkReturn ret; guint sessid; GST_DEBUG ("Stream %p added pad %s:%s for pad %s:%s", stream, GST_DEBUG_PAD_NAME (pad), GST_DEBUG_PAD_NAME (priv->sinkpad)); name = gst_pad_get_name (pad); if (sscanf (name, "recv_rtp_src_%u", &sessid) != 1) { g_free (name); return; } g_free (name); if (priv->idx != sessid) return; if (gst_pad_is_linked (priv->sinkpad)) { GST_WARNING ("Stream %p: Pad %s:%s is linked already", stream, GST_DEBUG_PAD_NAME (priv->sinkpad)); return; } /* link the RTP pad to the session manager, it should not really fail unless * this is not really an RTP pad */ ret = gst_pad_link (pad, priv->sinkpad); if (ret != GST_PAD_LINK_OK) goto link_failed; priv->recv_rtp_src = gst_object_ref (pad); return; /* ERRORS */ link_failed: { GST_ERROR ("Stream %p: Failed to link pads %s:%s and %s:%s", stream, GST_DEBUG_PAD_NAME (pad), GST_DEBUG_PAD_NAME (priv->sinkpad)); } } static void on_npt_stop (GstElement * rtpbin, guint session, guint ssrc, GstRTSPStream * stream) { /* TODO: What to do here other than this? */ GST_DEBUG ("Stream %p: Got EOS", stream); gst_pad_send_event (stream->priv->sinkpad, gst_event_new_eos ()); } typedef struct _ProbeData ProbeData; struct _ProbeData { GstRTSPStream *stream; /* existing sink, already linked to tee */ GstElement *sink1; /* new sink, about to be linked */ GstElement *sink2; /* new queue element, that will be linked to tee and sink1 */ GstElement **queue1; /* new queue element, that will be linked to tee and sink2 */ GstElement **queue2; GstPad *sink_pad; GstPad *tee_pad; guint index; }; static void free_cb_data (gpointer user_data) { ProbeData *data = user_data; gst_object_unref (data->stream); gst_object_unref (data->sink1); gst_object_unref (data->sink2); gst_object_unref (data->sink_pad); gst_object_unref (data->tee_pad); g_free (data); } static void create_and_plug_queue_to_unlinked_stream (GstRTSPStream * stream, GstElement * tee, GstElement * sink, GstElement ** queue) { GstRTSPStreamPrivate *priv = stream->priv; GstPad *tee_pad; GstPad *queue_pad; GstPad *sink_pad; /* create queue for the new stream */ *queue = gst_element_factory_make ("queue", NULL); g_object_set (*queue, "max-size-buffers", 1, "max-size-bytes", 0, "max-size-time", G_GINT64_CONSTANT (0), NULL); gst_bin_add (priv->joined_bin, *queue); /* link tee to queue */ tee_pad = gst_element_request_pad_simple (tee, "src_%u"); queue_pad = gst_element_get_static_pad (*queue, "sink"); gst_pad_link (tee_pad, queue_pad); gst_object_unref (queue_pad); gst_object_unref (tee_pad); /* link queue to sink */ queue_pad = gst_element_get_static_pad (*queue, "src"); sink_pad = gst_element_get_static_pad (sink, "sink"); gst_pad_link (queue_pad, sink_pad); gst_object_unref (queue_pad); gst_object_unref (sink_pad); gst_element_sync_state_with_parent (sink); gst_element_sync_state_with_parent (*queue); } static GstPadProbeReturn create_and_plug_queue_to_linked_stream_probe_cb (GstPad * inpad, GstPadProbeInfo * info, gpointer user_data) { GstRTSPStreamPrivate *priv; ProbeData *data = user_data; GstRTSPStream *stream; GstElement **queue1; GstElement **queue2; GstPad *sink_pad; GstPad *tee_pad; GstPad *queue_pad; guint index; stream = data->stream; priv = stream->priv; queue1 = data->queue1; queue2 = data->queue2; sink_pad = data->sink_pad; tee_pad = data->tee_pad; index = data->index; /* unlink tee and the existing sink: * .-----. .---------. * | tee | | sink1 | * sink src->sink | * '-----' '---------' */ g_assert (gst_pad_unlink (tee_pad, sink_pad)); /* add queue to the already existing stream */ *queue1 = gst_element_factory_make ("queue", NULL); g_object_set (*queue1, "max-size-buffers", 1, "max-size-bytes", 0, "max-size-time", G_GINT64_CONSTANT (0), NULL); gst_bin_add (priv->joined_bin, *queue1); /* link tee, queue and sink: * .-----. .---------. .---------. * | tee | | queue1 | | sink1 | * sink src->sink src->sink | * '-----' '---------' '---------' */ queue_pad = gst_element_get_static_pad (*queue1, "sink"); gst_pad_link (tee_pad, queue_pad); gst_object_unref (queue_pad); queue_pad = gst_element_get_static_pad (*queue1, "src"); gst_pad_link (queue_pad, sink_pad); gst_object_unref (queue_pad); gst_element_sync_state_with_parent (*queue1); /* create queue and link it to tee and the new sink */ create_and_plug_queue_to_unlinked_stream (stream, priv->tee[index], data->sink2, queue2); /* the final stream: * * .-----. .---------. .---------. * | tee | | queue1 | | sink1 | * sink src->sink src->sink | * | | '---------' '---------' * | | .---------. .---------. * | | | queue2 | | sink2 | * | src->sink src->sink | * '-----' '---------' '---------' */ return GST_PAD_PROBE_REMOVE; } static void create_and_plug_queue_to_linked_stream (GstRTSPStream * stream, GstElement * sink1, GstElement * sink2, guint index, GstElement ** queue1, GstElement ** queue2) { ProbeData *data; data = g_new0 (ProbeData, 1); data->stream = gst_object_ref (stream); data->sink1 = gst_object_ref (sink1); data->sink2 = gst_object_ref (sink2); data->queue1 = queue1; data->queue2 = queue2; data->index = index; data->sink_pad = gst_element_get_static_pad (sink1, "sink"); g_assert (data->sink_pad); data->tee_pad = gst_pad_get_peer (data->sink_pad); g_assert (data->tee_pad); gst_pad_add_probe (data->tee_pad, GST_PAD_PROBE_TYPE_IDLE, create_and_plug_queue_to_linked_stream_probe_cb, data, free_cb_data); } static void plug_udp_sink (GstRTSPStream * stream, GstElement * sink_to_plug, GstElement ** queue_to_plug, guint index, gboolean is_mcast) { GstRTSPStreamPrivate *priv = stream->priv; GstElement *existing_sink; if (is_mcast) existing_sink = priv->udpsink[index]; else existing_sink = priv->mcast_udpsink[index]; GST_DEBUG_OBJECT (stream, "plug %s sink", is_mcast ? "mcast" : "udp"); /* add sink to the bin */ gst_bin_add (priv->joined_bin, sink_to_plug); if (priv->appsink[index] && existing_sink) { /* queues are already added for the existing stream, add one for the newly added udp stream */ create_and_plug_queue_to_unlinked_stream (stream, priv->tee[index], sink_to_plug, queue_to_plug); } else if (priv->appsink[index] || existing_sink) { GstElement **queue; GstElement *element; /* add queue to the already existing stream plus the newly created udp stream */ if (priv->appsink[index]) { element = priv->appsink[index]; queue = &priv->appqueue[index]; } else { element = existing_sink; if (is_mcast) queue = &priv->udpqueue[index]; else queue = &priv->mcast_udpqueue[index]; } create_and_plug_queue_to_linked_stream (stream, element, sink_to_plug, index, queue, queue_to_plug); } else { GstPad *tee_pad; GstPad *sink_pad; GST_DEBUG_OBJECT (stream, "creating first stream"); /* no need to add queues */ tee_pad = gst_element_request_pad_simple (priv->tee[index], "src_%u"); sink_pad = gst_element_get_static_pad (sink_to_plug, "sink"); gst_pad_link (tee_pad, sink_pad); gst_object_unref (tee_pad); gst_object_unref (sink_pad); } gst_element_sync_state_with_parent (sink_to_plug); } static void plug_tcp_sink (GstRTSPStream * stream, guint index) { GstRTSPStreamPrivate *priv = stream->priv; GST_DEBUG_OBJECT (stream, "plug tcp sink"); /* add sink to the bin */ gst_bin_add (priv->joined_bin, priv->appsink[index]); if (priv->mcast_udpsink[index] && priv->udpsink[index]) { /* queues are already added for the existing stream, add one for the newly added tcp stream */ create_and_plug_queue_to_unlinked_stream (stream, priv->tee[index], priv->appsink[index], &priv->appqueue[index]); } else if (priv->mcast_udpsink[index] || priv->udpsink[index]) { GstElement **queue; GstElement *element; /* add queue to the already existing stream plus the newly created tcp stream */ if (priv->mcast_udpsink[index]) { element = priv->mcast_udpsink[index]; queue = &priv->mcast_udpqueue[index]; } else { element = priv->udpsink[index]; queue = &priv->udpqueue[index]; } create_and_plug_queue_to_linked_stream (stream, element, priv->appsink[index], index, queue, &priv->appqueue[index]); } else { GstPad *tee_pad; GstPad *sink_pad; /* no need to add queues */ tee_pad = gst_element_request_pad_simple (priv->tee[index], "src_%u"); sink_pad = gst_element_get_static_pad (priv->appsink[index], "sink"); gst_pad_link (tee_pad, sink_pad); gst_object_unref (tee_pad); gst_object_unref (sink_pad); } gst_element_sync_state_with_parent (priv->appsink[index]); } static void plug_sink (GstRTSPStream * stream, const GstRTSPTransport * transport, guint index) { GstRTSPStreamPrivate *priv; gboolean is_tcp, is_udp, is_mcast; priv = stream->priv; is_tcp = transport->lower_transport == GST_RTSP_LOWER_TRANS_TCP; is_udp = transport->lower_transport == GST_RTSP_LOWER_TRANS_UDP; is_mcast = transport->lower_transport == GST_RTSP_LOWER_TRANS_UDP_MCAST; if (is_udp) plug_udp_sink (stream, priv->udpsink[index], &priv->udpqueue[index], index, FALSE); else if (is_mcast) plug_udp_sink (stream, priv->mcast_udpsink[index], &priv->mcast_udpqueue[index], index, TRUE); else if (is_tcp) plug_tcp_sink (stream, index); } /* must be called with lock */ static gboolean create_sender_part (GstRTSPStream * stream, const GstRTSPTransport * transport) { GstRTSPStreamPrivate *priv; GstPad *pad; GstBin *bin; gboolean is_tcp, is_udp, is_mcast; gint mcast_ttl = 0; gint i; GST_DEBUG_OBJECT (stream, "create sender part"); priv = stream->priv; bin = priv->joined_bin; is_tcp = transport->lower_transport == GST_RTSP_LOWER_TRANS_TCP; is_udp = transport->lower_transport == GST_RTSP_LOWER_TRANS_UDP; is_mcast = transport->lower_transport == GST_RTSP_LOWER_TRANS_UDP_MCAST; if (is_mcast) mcast_ttl = transport->ttl; GST_DEBUG_OBJECT (stream, "tcp: %d, udp: %d, mcast: %d (ttl: %d)", is_tcp, is_udp, is_mcast, mcast_ttl); if (is_udp && !priv->server_addr_v4 && !priv->server_addr_v6) { GST_WARNING_OBJECT (stream, "no sockets assigned for UDP"); return FALSE; } if (is_mcast && !priv->mcast_addr_v4 && !priv->mcast_addr_v6) { GST_WARNING_OBJECT (stream, "no sockets assigned for UDP multicast"); return FALSE; } if (g_object_class_find_property (G_OBJECT_GET_CLASS (priv->payloader), "onvif-no-rate-control")) g_object_set (priv->payloader, "onvif-no-rate-control", !priv->do_rate_control, NULL); for (i = 0; i < (priv->enable_rtcp ? 2 : 1); i++) { gboolean link_tee = FALSE; /* For the sender we create this bit of pipeline for both * RTP and RTCP (when enabled). * Initially there will be only one active transport for * the stream, so the pipeline will look like this: * * .--------. .-----. .---------. * | rtpbin | | tee | | sink | * | send->sink src->sink | * '--------' '-----' '---------' * * For each new transport, the already existing branch will * be reconfigured by adding a queue element: * * .--------. .-----. .---------. .---------. * | rtpbin | | tee | | queue | | udpsink | * | send->sink src->sink src->sink | * '--------' | | '---------' '---------' * | | .---------. .---------. * | | | queue | | udpsink | * | src->sink src->sink | * | | '---------' '---------' * | | .---------. .---------. * | | | queue | | appsink | * | src->sink src->sink | * '-----' '---------' '---------' */ /* Only link the RTP send src if we're going to send RTP, link * the RTCP send src always */ if (!priv->srcpad && i == 0) continue; if (!priv->tee[i]) { /* make tee for RTP/RTCP */ priv->tee[i] = gst_element_factory_make ("tee", NULL); gst_bin_add (bin, priv->tee[i]); link_tee = TRUE; } if (is_udp && !priv->udpsink[i]) { /* we create only one pair of udpsinks for IPv4 and IPv6 */ create_and_configure_udpsink (stream, &priv->udpsink[i], priv->socket_v4[i], priv->socket_v6[i], FALSE, (i == 0), mcast_ttl); plug_sink (stream, transport, i); } else if (is_mcast && !priv->mcast_udpsink[i]) { /* we create only one pair of mcast-udpsinks for IPv4 and IPv6 */ create_and_configure_udpsink (stream, &priv->mcast_udpsink[i], priv->mcast_socket_v4[i], priv->mcast_socket_v6[i], TRUE, (i == 0), mcast_ttl); plug_sink (stream, transport, i); } else if (is_tcp && !priv->appsink[i]) { /* make appsink */ priv->appsink[i] = gst_element_factory_make ("appsink", NULL); g_object_set (priv->appsink[i], "emit-signals", FALSE, "buffer-list", TRUE, "max-buffers", 1, NULL); if (i == 0) g_object_set (priv->appsink[i], "sync", priv->do_rate_control, NULL); /* we need to set sync and preroll to FALSE for the sink to avoid * deadlock. This is only needed for sink sending RTCP data. */ if (i == 1) g_object_set (priv->appsink[i], "async", FALSE, "sync", FALSE, NULL); gst_app_sink_set_callbacks (GST_APP_SINK_CAST (priv->appsink[i]), &sink_cb, stream, NULL); plug_sink (stream, transport, i); } if (link_tee) { /* and link to rtpbin send pad */ gst_element_sync_state_with_parent (priv->tee[i]); pad = gst_element_get_static_pad (priv->tee[i], "sink"); gst_pad_link (priv->send_src[i], pad); gst_object_unref (pad); } } return TRUE; } /* must be called with lock */ static void plug_src (GstRTSPStream * stream, GstBin * bin, GstElement * src, GstElement * funnel) { GstRTSPStreamPrivate *priv; GstPad *pad, *selpad; gulong id = 0; priv = stream->priv; /* add src */ gst_bin_add (bin, src); pad = gst_element_get_static_pad (src, "src"); if (priv->srcpad) { /* block pad so src can't push data while it's not yet linked */ id = gst_pad_add_probe (pad, GST_PAD_PROBE_TYPE_BLOCK | GST_PAD_PROBE_TYPE_BUFFER, NULL, NULL, NULL); /* we set and keep these to playing so that they don't cause NO_PREROLL return * values. This is only relevant for PLAY pipelines */ gst_element_set_state (src, GST_STATE_PLAYING); gst_element_set_locked_state (src, TRUE); } /* and link to the funnel */ selpad = gst_element_request_pad_simple (funnel, "sink_%u"); gst_pad_link (pad, selpad); if (id != 0) gst_pad_remove_probe (pad, id); gst_object_unref (pad); gst_object_unref (selpad); } /* must be called with lock */ static gboolean create_receiver_part (GstRTSPStream * stream, const GstRTSPTransport * transport) { gboolean ret = FALSE; GstRTSPStreamPrivate *priv; GstPad *pad; GstBin *bin; gboolean tcp; gboolean udp; gboolean mcast; gboolean secure; gint i; GstCaps *rtp_caps; GstCaps *rtcp_caps; GST_DEBUG_OBJECT (stream, "create receiver part"); priv = stream->priv; bin = priv->joined_bin; tcp = transport->lower_transport == GST_RTSP_LOWER_TRANS_TCP; udp = transport->lower_transport == GST_RTSP_LOWER_TRANS_UDP; mcast = transport->lower_transport == GST_RTSP_LOWER_TRANS_UDP_MCAST; secure = (priv->profiles & GST_RTSP_PROFILE_SAVP) || (priv->profiles & GST_RTSP_PROFILE_SAVPF); if (secure) { rtp_caps = gst_caps_new_empty_simple ("application/x-srtp"); rtcp_caps = gst_caps_new_empty_simple ("application/x-srtcp"); } else { rtp_caps = gst_caps_new_empty_simple ("application/x-rtp"); rtcp_caps = gst_caps_new_empty_simple ("application/x-rtcp"); } GST_DEBUG_OBJECT (stream, "RTP caps: %" GST_PTR_FORMAT " RTCP caps: %" GST_PTR_FORMAT, rtp_caps, rtcp_caps); for (i = 0; i < (priv->enable_rtcp ? 2 : 1); i++) { /* For the receiver we create this bit of pipeline for both * RTP and RTCP (when enabled). We receive RTP/RTCP on appsrc and udpsrc * and it is all funneled into the rtpbin receive pad. * * * .--------. .--------. .--------. * | udpsrc | | funnel | | rtpbin | * | RTP src->sink src->sink | * '--------' | | | | * .--------. | | | | * | appsrc | | | | | * | RTP src->sink | | | * '--------' '--------' | | * | | * .--------. .--------. | | * | udpsrc | | funnel | | | * | RTCP src->sink src->sink | * '--------' | | '--------' * .--------. | | * | appsrc | | | * | RTCP src->sink | * '--------' '--------' */ if (!priv->sinkpad && i == 0) { /* Only connect recv RTP sink if we expect to receive RTP. Connect recv * RTCP sink always */ continue; } /* make funnel for the RTP/RTCP receivers */ if (!priv->funnel[i]) { priv->funnel[i] = gst_element_factory_make ("funnel", NULL); gst_bin_add (bin, priv->funnel[i]); pad = gst_element_get_static_pad (priv->funnel[i], "src"); gst_pad_link (pad, priv->recv_sink[i]); gst_object_unref (pad); } if (udp && !priv->udpsrc_v4[i] && priv->server_addr_v4) { GST_DEBUG_OBJECT (stream, "udp IPv4, create and configure udpsources"); if (!create_and_configure_udpsource (&priv->udpsrc_v4[i], priv->socket_v4[i])) goto done; if (i == 0) { g_object_set (priv->udpsrc_v4[i], "caps", rtp_caps, NULL); } else { g_object_set (priv->udpsrc_v4[i], "caps", rtcp_caps, NULL); /* block early rtcp packets, pipeline not ready */ g_assert (priv->block_early_rtcp_pad == NULL); priv->block_early_rtcp_pad = gst_element_get_static_pad (priv->udpsrc_v4[i], "src"); priv->block_early_rtcp_probe = gst_pad_add_probe (priv->block_early_rtcp_pad, GST_PAD_PROBE_TYPE_BLOCK | GST_PAD_PROBE_TYPE_BUFFER, NULL, NULL, NULL); } plug_src (stream, bin, priv->udpsrc_v4[i], priv->funnel[i]); } if (udp && !priv->udpsrc_v6[i] && priv->server_addr_v6) { GST_DEBUG_OBJECT (stream, "udp IPv6, create and configure udpsources"); if (!create_and_configure_udpsource (&priv->udpsrc_v6[i], priv->socket_v6[i])) goto done; if (i == 0) { g_object_set (priv->udpsrc_v6[i], "caps", rtp_caps, NULL); } else { g_object_set (priv->udpsrc_v6[i], "caps", rtcp_caps, NULL); /* block early rtcp packets, pipeline not ready */ g_assert (priv->block_early_rtcp_pad_ipv6 == NULL); priv->block_early_rtcp_pad_ipv6 = gst_element_get_static_pad (priv->udpsrc_v6[i], "src"); priv->block_early_rtcp_probe_ipv6 = gst_pad_add_probe (priv->block_early_rtcp_pad_ipv6, GST_PAD_PROBE_TYPE_BLOCK | GST_PAD_PROBE_TYPE_BUFFER, NULL, NULL, NULL); } plug_src (stream, bin, priv->udpsrc_v6[i], priv->funnel[i]); } if (mcast && !priv->mcast_udpsrc_v4[i] && priv->mcast_addr_v4) { GST_DEBUG_OBJECT (stream, "mcast IPv4, create and configure udpsources"); if (!create_and_configure_udpsource (&priv->mcast_udpsrc_v4[i], priv->mcast_socket_v4[i])) goto done; if (i == 0) { g_object_set (priv->mcast_udpsrc_v4[i], "caps", rtp_caps, NULL); } else { g_object_set (priv->mcast_udpsrc_v4[i], "caps", rtcp_caps, NULL); } plug_src (stream, bin, priv->mcast_udpsrc_v4[i], priv->funnel[i]); } if (mcast && !priv->mcast_udpsrc_v6[i] && priv->mcast_addr_v6) { GST_DEBUG_OBJECT (stream, "mcast IPv6, create and configure udpsources"); if (!create_and_configure_udpsource (&priv->mcast_udpsrc_v6[i], priv->mcast_socket_v6[i])) goto done; if (i == 0) { g_object_set (priv->mcast_udpsrc_v6[i], "caps", rtp_caps, NULL); } else { g_object_set (priv->mcast_udpsrc_v6[i], "caps", rtcp_caps, NULL); } plug_src (stream, bin, priv->mcast_udpsrc_v6[i], priv->funnel[i]); } if (tcp && !priv->appsrc[i]) { /* make and add appsrc */ priv->appsrc[i] = gst_element_factory_make ("appsrc", NULL); priv->appsrc_base_time[i] = -1; g_object_set (priv->appsrc[i], "format", GST_FORMAT_TIME, "is-live", TRUE, NULL); plug_src (stream, bin, priv->appsrc[i], priv->funnel[i]); } gst_element_sync_state_with_parent (priv->funnel[i]); } ret = TRUE; done: gst_caps_unref (rtp_caps); gst_caps_unref (rtcp_caps); return ret; } gboolean gst_rtsp_stream_is_tcp_receiver (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gboolean ret = FALSE; priv = stream->priv; g_mutex_lock (&priv->lock); ret = (priv->sinkpad != NULL && priv->appsrc[0] != NULL); g_mutex_unlock (&priv->lock); return ret; } static gboolean check_mcast_client_addr (GstRTSPStream * stream, const GstRTSPTransport * tr) { GstRTSPStreamPrivate *priv = stream->priv; GList *walk; if (priv->mcast_clients == NULL) goto no_addr; if (tr == NULL) goto no_transport; if (tr->destination == NULL) goto no_destination; for (walk = priv->mcast_clients; walk; walk = g_list_next (walk)) { UdpClientAddrInfo *cli = walk->data; if ((g_strcmp0 (cli->address, tr->destination) == 0) && (cli->rtp_port == tr->port.min)) return TRUE; } return FALSE; no_addr: { GST_WARNING_OBJECT (stream, "Adding mcast transport, but no mcast address " "has been reserved"); return FALSE; } no_transport: { GST_WARNING_OBJECT (stream, "Adding mcast transport, but no transport " "has been provided"); return FALSE; } no_destination: { GST_WARNING_OBJECT (stream, "Adding mcast transport, but it doesn't match " "the reserved address"); return FALSE; } } /** * gst_rtsp_stream_join_bin: * @stream: a #GstRTSPStream * @bin: (transfer none): a #GstBin to join * @rtpbin: (transfer none): a rtpbin element in @bin * @state: the target state of the new elements * * Join the #GstBin @bin that contains the element @rtpbin. * * @stream will link to @rtpbin, which must be inside @bin. The elements * added to @bin will be set to the state given in @state. * * Returns: %TRUE on success. */ gboolean gst_rtsp_stream_join_bin (GstRTSPStream * stream, GstBin * bin, GstElement * rtpbin, GstState state) { GstRTSPStreamPrivate *priv; guint idx; gchar *name; GstPadLinkReturn ret; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_return_val_if_fail (GST_IS_BIN (bin), FALSE); g_return_val_if_fail (GST_IS_ELEMENT (rtpbin), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); if (priv->joined_bin != NULL) goto was_joined; /* create a session with the same index as the stream */ idx = priv->idx; GST_INFO ("stream %p joining bin as session %u", stream, idx); if (priv->profiles & GST_RTSP_PROFILE_SAVP || priv->profiles & GST_RTSP_PROFILE_SAVPF) { /* For SRTP */ g_signal_connect (rtpbin, "request-rtp-encoder", (GCallback) request_rtp_encoder, stream); g_signal_connect (rtpbin, "request-rtcp-encoder", (GCallback) request_rtcp_encoder, stream); g_signal_connect (rtpbin, "request-rtp-decoder", (GCallback) request_rtp_rtcp_decoder, stream); g_signal_connect (rtpbin, "request-rtcp-decoder", (GCallback) request_rtp_rtcp_decoder, stream); } if (priv->sinkpad) { g_signal_connect (rtpbin, "request-pt-map", (GCallback) request_pt_map, stream); } /* get pads from the RTP session element for sending and receiving * RTP/RTCP*/ if (priv->srcpad) { /* get a pad for sending RTP */ name = g_strdup_printf ("send_rtp_sink_%u", idx); priv->send_rtp_sink = gst_element_request_pad_simple (rtpbin, name); g_free (name); /* link the RTP pad to the session manager, it should not really fail unless * this is not really an RTP pad */ ret = gst_pad_link (priv->srcpad, priv->send_rtp_sink); if (ret != GST_PAD_LINK_OK) goto link_failed; name = g_strdup_printf ("send_rtp_src_%u", idx); priv->send_src[0] = gst_element_get_static_pad (rtpbin, name); g_free (name); } else { /* RECORD case: need to connect our sinkpad from here */ g_signal_connect (rtpbin, "pad-added", (GCallback) pad_added, stream); /* EOS */ g_signal_connect (rtpbin, "on-npt-stop", (GCallback) on_npt_stop, stream); name = g_strdup_printf ("recv_rtp_sink_%u", idx); priv->recv_sink[0] = gst_element_request_pad_simple (rtpbin, name); g_free (name); } if (priv->enable_rtcp) { name = g_strdup_printf ("send_rtcp_src_%u", idx); priv->send_src[1] = gst_element_request_pad_simple (rtpbin, name); g_free (name); name = g_strdup_printf ("recv_rtcp_sink_%u", idx); priv->recv_sink[1] = gst_element_request_pad_simple (rtpbin, name); g_free (name); } /* get the session */ g_signal_emit_by_name (rtpbin, "get-internal-session", idx, &priv->session); g_signal_connect (priv->session, "on-new-ssrc", (GCallback) on_new_ssrc, stream); g_signal_connect (priv->session, "on-ssrc-sdes", (GCallback) on_ssrc_sdes, stream); g_signal_connect (priv->session, "on-ssrc-active", (GCallback) on_ssrc_active, stream); g_signal_connect (priv->session, "on-bye-ssrc", (GCallback) on_bye_ssrc, stream); g_signal_connect (priv->session, "on-bye-timeout", (GCallback) on_bye_timeout, stream); g_signal_connect (priv->session, "on-timeout", (GCallback) on_timeout, stream); /* signal for sender ssrc */ g_signal_connect (priv->session, "on-new-sender-ssrc", (GCallback) on_new_sender_ssrc, stream); g_signal_connect (priv->session, "on-sender-ssrc-active", (GCallback) on_sender_ssrc_active, stream); g_object_set (priv->session, "disable-sr-timestamp", !priv->do_rate_control, NULL); if (priv->srcpad) { /* be notified of caps changes */ priv->caps_sig = g_signal_connect (priv->send_src[0], "notify::caps", (GCallback) caps_notify, stream); priv->caps = gst_pad_get_current_caps (priv->send_src[0]); } priv->joined_bin = bin; GST_DEBUG_OBJECT (stream, "successfully joined bin"); g_mutex_unlock (&priv->lock); return TRUE; /* ERRORS */ was_joined: { g_mutex_unlock (&priv->lock); return TRUE; } link_failed: { GST_WARNING ("failed to link stream %u", idx); gst_object_unref (priv->send_rtp_sink); priv->send_rtp_sink = NULL; g_mutex_unlock (&priv->lock); return FALSE; } } static void clear_element (GstBin * bin, GstElement ** elementptr) { if (*elementptr) { gst_element_set_locked_state (*elementptr, FALSE); gst_element_set_state (*elementptr, GST_STATE_NULL); if (GST_ELEMENT_PARENT (*elementptr)) gst_bin_remove (bin, *elementptr); else gst_object_unref (*elementptr); *elementptr = NULL; } } /** * gst_rtsp_stream_leave_bin: * @stream: a #GstRTSPStream * @bin: (transfer none): a #GstBin * @rtpbin: (transfer none): a rtpbin #GstElement * * Remove the elements of @stream from @bin. * * Return: %TRUE on success. */ gboolean gst_rtsp_stream_leave_bin (GstRTSPStream * stream, GstBin * bin, GstElement * rtpbin) { GstRTSPStreamPrivate *priv; gint i; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_return_val_if_fail (GST_IS_BIN (bin), FALSE); g_return_val_if_fail (GST_IS_ELEMENT (rtpbin), FALSE); priv = stream->priv; g_mutex_lock (&priv->send_lock); priv->continue_sending = FALSE; priv->send_cookie++; g_cond_signal (&priv->send_cond); g_mutex_unlock (&priv->send_lock); if (priv->send_thread) { g_thread_join (priv->send_thread); } g_mutex_lock (&priv->lock); if (priv->joined_bin == NULL) goto was_not_joined; if (priv->joined_bin != bin) goto wrong_bin; priv->joined_bin = NULL; /* all transports must be removed by now */ if (priv->transports != NULL) goto transports_not_removed; if (priv->send_pool) { GThreadPool *slask; slask = priv->send_pool; priv->send_pool = NULL; g_mutex_unlock (&priv->lock); g_thread_pool_free (slask, TRUE, TRUE); g_mutex_lock (&priv->lock); } clear_tr_cache (priv); GST_INFO ("stream %p leaving bin", stream); if (priv->srcpad) { gst_pad_unlink (priv->srcpad, priv->send_rtp_sink); g_signal_handler_disconnect (priv->send_src[0], priv->caps_sig); gst_element_release_request_pad (rtpbin, priv->send_rtp_sink); gst_object_unref (priv->send_rtp_sink); priv->send_rtp_sink = NULL; } else if (priv->recv_rtp_src) { gst_pad_unlink (priv->recv_rtp_src, priv->sinkpad); gst_object_unref (priv->recv_rtp_src); priv->recv_rtp_src = NULL; } for (i = 0; i < (priv->enable_rtcp ? 2 : 1); i++) { clear_element (bin, &priv->udpsrc_v4[i]); clear_element (bin, &priv->udpsrc_v6[i]); clear_element (bin, &priv->udpqueue[i]); clear_element (bin, &priv->udpsink[i]); clear_element (bin, &priv->mcast_udpsrc_v4[i]); clear_element (bin, &priv->mcast_udpsrc_v6[i]); clear_element (bin, &priv->mcast_udpqueue[i]); clear_element (bin, &priv->mcast_udpsink[i]); clear_element (bin, &priv->appsrc[i]); clear_element (bin, &priv->appqueue[i]); clear_element (bin, &priv->appsink[i]); clear_element (bin, &priv->tee[i]); clear_element (bin, &priv->funnel[i]); if (priv->sinkpad || i == 1) { gst_element_release_request_pad (rtpbin, priv->recv_sink[i]); gst_object_unref (priv->recv_sink[i]); priv->recv_sink[i] = NULL; } } if (priv->srcpad) { gst_object_unref (priv->send_src[0]); priv->send_src[0] = NULL; } if (priv->enable_rtcp) { gst_element_release_request_pad (rtpbin, priv->send_src[1]); gst_object_unref (priv->send_src[1]); priv->send_src[1] = NULL; } g_object_unref (priv->session); priv->session = NULL; if (priv->caps) gst_caps_unref (priv->caps); priv->caps = NULL; if (priv->srtpenc) gst_object_unref (priv->srtpenc); if (priv->srtpdec) gst_object_unref (priv->srtpdec); if (priv->mcast_addr_v4) gst_rtsp_address_free (priv->mcast_addr_v4); priv->mcast_addr_v4 = NULL; if (priv->mcast_addr_v6) gst_rtsp_address_free (priv->mcast_addr_v6); priv->mcast_addr_v6 = NULL; if (priv->server_addr_v4) gst_rtsp_address_free (priv->server_addr_v4); priv->server_addr_v4 = NULL; if (priv->server_addr_v6) gst_rtsp_address_free (priv->server_addr_v6); priv->server_addr_v6 = NULL; for (i = 0; i < 2; i++) { g_clear_object (&priv->socket_v4[i]); g_clear_object (&priv->socket_v6[i]); g_clear_object (&priv->mcast_socket_v4[i]); g_clear_object (&priv->mcast_socket_v6[i]); } g_mutex_unlock (&priv->lock); return TRUE; was_not_joined: { g_mutex_unlock (&priv->lock); return TRUE; } transports_not_removed: { GST_ERROR_OBJECT (stream, "can't leave bin (transports not removed)"); g_mutex_unlock (&priv->lock); return FALSE; } wrong_bin: { GST_ERROR_OBJECT (stream, "leaving the wrong bin"); g_mutex_unlock (&priv->lock); return FALSE; } } /** * gst_rtsp_stream_get_joined_bin: * @stream: a #GstRTSPStream * * Get the previous joined bin with gst_rtsp_stream_join_bin() or NULL. * * Return: (transfer full) (nullable): the joined bin or NULL. */ GstBin * gst_rtsp_stream_get_joined_bin (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstBin *bin = NULL; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); bin = priv->joined_bin ? gst_object_ref (priv->joined_bin) : NULL; g_mutex_unlock (&priv->lock); return bin; } /** * gst_rtsp_stream_get_rtpinfo: * @stream: a #GstRTSPStream * @rtptime: (allow-none) (out caller-allocates): result RTP timestamp * @seq: (allow-none) (out caller-allocates): result RTP seqnum * @clock_rate: (allow-none) (out caller-allocates): the clock rate * @running_time: (out caller-allocates): result running-time * * Retrieve the current rtptime, seq and running-time. This is used to * construct a RTPInfo reply header. * * Returns: %TRUE when rtptime, seq and running-time could be determined. */ gboolean gst_rtsp_stream_get_rtpinfo (GstRTSPStream * stream, guint * rtptime, guint * seq, guint * clock_rate, GstClockTime * running_time) { GstRTSPStreamPrivate *priv; GstStructure *stats; GObjectClass *payobjclass; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; payobjclass = G_OBJECT_GET_CLASS (priv->payloader); g_mutex_lock (&priv->lock); /* First try to extract the information from the last buffer on the sinks. * This will have a more accurate sequence number and timestamp, as between * the payloader and the sink there can be some queues */ if (priv->udpsink[0] || priv->mcast_udpsink[0] || priv->appsink[0]) { GstSample *last_sample; if (priv->udpsink[0]) g_object_get (priv->udpsink[0], "last-sample", &last_sample, NULL); else if (priv->mcast_udpsink[0]) g_object_get (priv->mcast_udpsink[0], "last-sample", &last_sample, NULL); else g_object_get (priv->appsink[0], "last-sample", &last_sample, NULL); if (last_sample && !priv->blocking) { GstCaps *caps; GstBuffer *buffer; GstSegment *segment; GstStructure *s; GstRTPBuffer rtp_buffer = GST_RTP_BUFFER_INIT; caps = gst_sample_get_caps (last_sample); buffer = gst_sample_get_buffer (last_sample); segment = gst_sample_get_segment (last_sample); s = gst_caps_get_structure (caps, 0); if (gst_rtp_buffer_map (buffer, GST_MAP_READ, &rtp_buffer)) { guint ssrc_buf = gst_rtp_buffer_get_ssrc (&rtp_buffer); guint ssrc_stream = 0; if (gst_structure_has_field_typed (s, "ssrc", G_TYPE_UINT) && gst_structure_get_uint (s, "ssrc", &ssrc_stream) && ssrc_buf != ssrc_stream) { /* Skip buffers from auxiliary streams. */ GST_DEBUG_OBJECT (stream, "not a buffer from the payloader, SSRC: %08x", ssrc_buf); gst_rtp_buffer_unmap (&rtp_buffer); gst_sample_unref (last_sample); goto stats; } if (seq) { *seq = gst_rtp_buffer_get_seq (&rtp_buffer); } if (rtptime) { *rtptime = gst_rtp_buffer_get_timestamp (&rtp_buffer); } gst_rtp_buffer_unmap (&rtp_buffer); if (running_time) { *running_time = gst_segment_to_running_time (segment, GST_FORMAT_TIME, GST_BUFFER_TIMESTAMP (buffer)); } if (clock_rate) { gst_structure_get_int (s, "clock-rate", (gint *) clock_rate); if (*clock_rate == 0 && running_time) *running_time = GST_CLOCK_TIME_NONE; } gst_sample_unref (last_sample); goto done; } else { gst_sample_unref (last_sample); } } else if (priv->blocking) { if (last_sample != NULL) gst_sample_unref (last_sample); if (seq) { if (!priv->blocked_buffer) goto stats; *seq = priv->blocked_seqnum; } if (rtptime) { if (!priv->blocked_buffer) goto stats; *rtptime = priv->blocked_rtptime; } if (running_time) { if (!GST_CLOCK_TIME_IS_VALID (priv->blocked_running_time)) goto stats; *running_time = priv->blocked_running_time; } if (clock_rate) { *clock_rate = priv->blocked_clock_rate; if (*clock_rate == 0 && running_time) *running_time = GST_CLOCK_TIME_NONE; } goto done; } } stats: if (g_object_class_find_property (payobjclass, "stats")) { g_object_get (priv->payloader, "stats", &stats, NULL); if (stats == NULL) goto no_stats; if (seq) gst_structure_get_uint (stats, "seqnum-offset", seq); if (rtptime) gst_structure_get_uint (stats, "timestamp", rtptime); if (running_time) gst_structure_get_clock_time (stats, "running-time", running_time); if (clock_rate) { gst_structure_get_uint (stats, "clock-rate", clock_rate); if (*clock_rate == 0 && running_time) *running_time = GST_CLOCK_TIME_NONE; } gst_structure_free (stats); } else { if (!g_object_class_find_property (payobjclass, "seqnum") || !g_object_class_find_property (payobjclass, "timestamp")) goto no_stats; if (seq) g_object_get (priv->payloader, "seqnum", seq, NULL); if (rtptime) g_object_get (priv->payloader, "timestamp", rtptime, NULL); if (running_time) *running_time = GST_CLOCK_TIME_NONE; } done: g_mutex_unlock (&priv->lock); return TRUE; /* ERRORS */ no_stats: { GST_WARNING ("Could not get payloader stats"); g_mutex_unlock (&priv->lock); return FALSE; } } /** * gst_rtsp_stream_get_rates: * @stream: a #GstRTSPStream * @rate: (optional) (out caller-allocates): the configured rate * @applied_rate: (optional) (out caller-allocates): the configured applied_rate * * Retrieve the current rate and/or applied_rate. * * Returns: %TRUE if rate and/or applied_rate could be determined. * Since: 1.18 */ gboolean gst_rtsp_stream_get_rates (GstRTSPStream * stream, gdouble * rate, gdouble * applied_rate) { GstRTSPStreamPrivate *priv; GstEvent *event; const GstSegment *segment; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); if (!rate && !applied_rate) { GST_WARNING_OBJECT (stream, "rate and applied_rate are both NULL"); return FALSE; } priv = stream->priv; g_mutex_lock (&priv->lock); if (!priv->send_rtp_sink) goto no_rtp_sink_pad; event = gst_pad_get_sticky_event (priv->send_rtp_sink, GST_EVENT_SEGMENT, 0); if (!event) goto no_sticky_event; gst_event_parse_segment (event, &segment); if (rate) *rate = segment->rate; if (applied_rate) *applied_rate = segment->applied_rate; gst_event_unref (event); g_mutex_unlock (&priv->lock); return TRUE; /* ERRORS */ no_rtp_sink_pad: { GST_WARNING_OBJECT (stream, "no send_rtp_sink pad yet"); g_mutex_unlock (&priv->lock); return FALSE; } no_sticky_event: { GST_WARNING_OBJECT (stream, "no segment event on send_rtp_sink pad"); g_mutex_unlock (&priv->lock); return FALSE; } } /** * gst_rtsp_stream_get_caps: * @stream: a #GstRTSPStream * * Retrieve the current caps of @stream. * * Returns: (transfer full) (nullable): the #GstCaps of @stream. * use gst_caps_unref() after usage. */ GstCaps * gst_rtsp_stream_get_caps (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstCaps *result; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; g_mutex_lock (&priv->lock); if ((result = priv->caps)) gst_caps_ref (result); g_mutex_unlock (&priv->lock); return result; } /** * gst_rtsp_stream_recv_rtp: * @stream: a #GstRTSPStream * @buffer: (transfer full): a #GstBuffer * * Handle an RTP buffer for the stream. This method is usually called when a * message has been received from a client using the TCP transport. * * This function takes ownership of @buffer. * * Returns: a GstFlowReturn. */ GstFlowReturn gst_rtsp_stream_recv_rtp (GstRTSPStream * stream, GstBuffer * buffer) { GstRTSPStreamPrivate *priv; GstFlowReturn ret; GstElement *element; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), GST_FLOW_ERROR); priv = stream->priv; g_return_val_if_fail (GST_IS_BUFFER (buffer), GST_FLOW_ERROR); g_return_val_if_fail (priv->joined_bin != NULL, FALSE); g_mutex_lock (&priv->lock); if (priv->appsrc[0]) element = gst_object_ref (priv->appsrc[0]); else element = NULL; g_mutex_unlock (&priv->lock); if (element) { if (priv->appsrc_base_time[0] == -1) { /* Take current running_time. This timestamp will be put on * the first buffer of each stream because we are a live source and so we * timestamp with the running_time. When we are dealing with TCP, we also * only timestamp the first buffer (using the DISCONT flag) because a server * typically bursts data, for which we don't want to compensate by speeding * up the media. The other timestamps will be interpollated from this one * using the RTP timestamps. */ GST_OBJECT_LOCK (element); if (GST_ELEMENT_CLOCK (element)) { GstClockTime now; GstClockTime base_time; now = gst_clock_get_time (GST_ELEMENT_CLOCK (element)); base_time = GST_ELEMENT_CAST (element)->base_time; priv->appsrc_base_time[0] = now - base_time; GST_BUFFER_TIMESTAMP (buffer) = priv->appsrc_base_time[0]; GST_DEBUG ("stream %p: first buffer at time %" GST_TIME_FORMAT ", base %" GST_TIME_FORMAT, stream, GST_TIME_ARGS (now), GST_TIME_ARGS (base_time)); } GST_OBJECT_UNLOCK (element); } ret = gst_app_src_push_buffer (GST_APP_SRC_CAST (element), buffer); gst_object_unref (element); } else { ret = GST_FLOW_OK; } return ret; } /** * gst_rtsp_stream_recv_rtcp: * @stream: a #GstRTSPStream * @buffer: (transfer full): a #GstBuffer * * Handle an RTCP buffer for the stream. This method is usually called when a * message has been received from a client using the TCP transport. * * This function takes ownership of @buffer. * * Returns: a GstFlowReturn. */ GstFlowReturn gst_rtsp_stream_recv_rtcp (GstRTSPStream * stream, GstBuffer * buffer) { GstRTSPStreamPrivate *priv; GstFlowReturn ret; GstElement *element; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), GST_FLOW_ERROR); priv = stream->priv; g_return_val_if_fail (GST_IS_BUFFER (buffer), GST_FLOW_ERROR); if (priv->joined_bin == NULL) { gst_buffer_unref (buffer); return GST_FLOW_NOT_LINKED; } g_mutex_lock (&priv->lock); if (priv->appsrc[1]) element = gst_object_ref (priv->appsrc[1]); else element = NULL; g_mutex_unlock (&priv->lock); if (element) { if (priv->appsrc_base_time[1] == -1) { /* Take current running_time. This timestamp will be put on * the first buffer of each stream because we are a live source and so we * timestamp with the running_time. When we are dealing with TCP, we also * only timestamp the first buffer (using the DISCONT flag) because a server * typically bursts data, for which we don't want to compensate by speeding * up the media. The other timestamps will be interpollated from this one * using the RTP timestamps. */ GST_OBJECT_LOCK (element); if (GST_ELEMENT_CLOCK (element)) { GstClockTime now; GstClockTime base_time; now = gst_clock_get_time (GST_ELEMENT_CLOCK (element)); base_time = GST_ELEMENT_CAST (element)->base_time; priv->appsrc_base_time[1] = now - base_time; GST_BUFFER_TIMESTAMP (buffer) = priv->appsrc_base_time[1]; GST_DEBUG ("stream %p: first buffer at time %" GST_TIME_FORMAT ", base %" GST_TIME_FORMAT, stream, GST_TIME_ARGS (now), GST_TIME_ARGS (base_time)); } GST_OBJECT_UNLOCK (element); } ret = gst_app_src_push_buffer (GST_APP_SRC_CAST (element), buffer); gst_object_unref (element); } else { ret = GST_FLOW_OK; gst_buffer_unref (buffer); } return ret; } /* must be called with lock */ static inline void add_client (GstElement * rtp_sink, GstElement * rtcp_sink, const gchar * host, gint rtp_port, gint rtcp_port) { if (rtp_sink != NULL) g_signal_emit_by_name (rtp_sink, "add", host, rtp_port, NULL); if (rtcp_sink != NULL) g_signal_emit_by_name (rtcp_sink, "add", host, rtcp_port, NULL); } /* must be called with lock */ static void remove_client (GstElement * rtp_sink, GstElement * rtcp_sink, const gchar * host, gint rtp_port, gint rtcp_port) { if (rtp_sink != NULL) g_signal_emit_by_name (rtp_sink, "remove", host, rtp_port, NULL); if (rtcp_sink != NULL) g_signal_emit_by_name (rtcp_sink, "remove", host, rtcp_port, NULL); } /* must be called with lock */ static gboolean update_transport (GstRTSPStream * stream, GstRTSPStreamTransport * trans, gboolean add) { GstRTSPStreamPrivate *priv = stream->priv; const GstRTSPTransport *tr; gchar *dest; gint min, max; GList *tr_element; tr = gst_rtsp_stream_transport_get_transport (trans); dest = tr->destination; tr_element = g_list_find (priv->transports, trans); if (add && tr_element) return TRUE; else if (!add && !tr_element) return FALSE; switch (tr->lower_transport) { case GST_RTSP_LOWER_TRANS_UDP_MCAST: { min = tr->port.min; max = tr->port.max; if (add) { GST_INFO ("adding %s:%d-%d", dest, min, max); if (!check_mcast_client_addr (stream, tr)) goto mcast_error; add_client (priv->mcast_udpsink[0], priv->mcast_udpsink[1], dest, min, max); if (tr->ttl > 0) { GST_INFO ("setting ttl-mc %d", tr->ttl); if (priv->mcast_udpsink[0]) g_object_set (G_OBJECT (priv->mcast_udpsink[0]), "ttl-mc", tr->ttl, NULL); if (priv->mcast_udpsink[1]) g_object_set (G_OBJECT (priv->mcast_udpsink[1]), "ttl-mc", tr->ttl, NULL); } priv->transports = g_list_prepend (priv->transports, trans); } else { GST_INFO ("removing %s:%d-%d", dest, min, max); if (!remove_mcast_client_addr (stream, dest, min, max)) GST_WARNING_OBJECT (stream, "Failed to remove multicast address: %s:%d-%d", dest, min, max); priv->transports = g_list_delete_link (priv->transports, tr_element); remove_client (priv->mcast_udpsink[0], priv->mcast_udpsink[1], dest, min, max); } break; } case GST_RTSP_LOWER_TRANS_UDP: { if (priv->client_side) { /* In client side mode the 'destination' is the RTSP server, so send * to those ports */ min = tr->server_port.min; max = tr->server_port.max; } else { min = tr->client_port.min; max = tr->client_port.max; } if (add) { GST_INFO ("adding %s:%d-%d", dest, min, max); add_client (priv->udpsink[0], priv->udpsink[1], dest, min, max); priv->transports = g_list_prepend (priv->transports, trans); } else { GST_INFO ("removing %s:%d-%d", dest, min, max); priv->transports = g_list_delete_link (priv->transports, tr_element); remove_client (priv->udpsink[0], priv->udpsink[1], dest, min, max); } priv->transports_cookie++; break; } case GST_RTSP_LOWER_TRANS_TCP: if (add) { GST_INFO ("adding TCP %s", tr->destination); priv->transports = g_list_prepend (priv->transports, trans); priv->n_tcp_transports++; } else { GST_INFO ("removing TCP %s", tr->destination); priv->transports = g_list_delete_link (priv->transports, tr_element); gst_rtsp_stream_transport_lock_backlog (trans); gst_rtsp_stream_transport_clear_backlog (trans); gst_rtsp_stream_transport_unlock_backlog (trans); priv->n_tcp_transports--; } priv->transports_cookie++; break; default: goto unknown_transport; } return TRUE; /* ERRORS */ unknown_transport: { GST_INFO ("Unknown transport %d", tr->lower_transport); return FALSE; } mcast_error: { return FALSE; } } static void on_message_sent (GstRTSPStreamTransport * trans, gpointer user_data) { GstRTSPStream *stream = GST_RTSP_STREAM (user_data); GstRTSPStreamPrivate *priv = stream->priv; GST_DEBUG_OBJECT (stream, "message send complete"); check_transport_backlog (stream, trans); g_mutex_lock (&priv->send_lock); priv->send_cookie++; g_cond_signal (&priv->send_cond); g_mutex_unlock (&priv->send_lock); } /** * gst_rtsp_stream_add_transport: * @stream: a #GstRTSPStream * @trans: (transfer none): a #GstRTSPStreamTransport * * Add the transport in @trans to @stream. The media of @stream will * then also be send to the values configured in @trans. Adding the * same transport twice will not add it a second time. * * @stream must be joined to a bin. * * @trans must contain a valid #GstRTSPTransport. * * Returns: %TRUE if @trans was added */ gboolean gst_rtsp_stream_add_transport (GstRTSPStream * stream, GstRTSPStreamTransport * trans) { GstRTSPStreamPrivate *priv; gboolean res; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_return_val_if_fail (GST_IS_RTSP_STREAM_TRANSPORT (trans), FALSE); g_return_val_if_fail (priv->joined_bin != NULL, FALSE); g_mutex_lock (&priv->lock); res = update_transport (stream, trans, TRUE); if (res) gst_rtsp_stream_transport_set_message_sent_full (trans, on_message_sent, stream, NULL); g_mutex_unlock (&priv->lock); return res; } /** * gst_rtsp_stream_remove_transport: * @stream: a #GstRTSPStream * @trans: (transfer none): a #GstRTSPStreamTransport * * Remove the transport in @trans from @stream. The media of @stream will * not be sent to the values configured in @trans. * * @stream must be joined to a bin. * * @trans must contain a valid #GstRTSPTransport. * * Returns: %TRUE if @trans was removed */ gboolean gst_rtsp_stream_remove_transport (GstRTSPStream * stream, GstRTSPStreamTransport * trans) { GstRTSPStreamPrivate *priv; gboolean res; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_return_val_if_fail (GST_IS_RTSP_STREAM_TRANSPORT (trans), FALSE); g_return_val_if_fail (priv->joined_bin != NULL, FALSE); g_mutex_lock (&priv->lock); res = update_transport (stream, trans, FALSE); g_mutex_unlock (&priv->lock); return res; } /** * gst_rtsp_stream_update_crypto: * @stream: a #GstRTSPStream * @ssrc: the SSRC * @crypto: (transfer none) (allow-none): a #GstCaps with crypto info * * Update the new crypto information for @ssrc in @stream. If information * for @ssrc did not exist, it will be added. If information * for @ssrc existed, it will be replaced. If @crypto is %NULL, it will * be removed from @stream. * * Returns: %TRUE if @crypto could be updated */ gboolean gst_rtsp_stream_update_crypto (GstRTSPStream * stream, guint ssrc, GstCaps * crypto) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_return_val_if_fail (crypto == NULL || GST_IS_CAPS (crypto), FALSE); priv = stream->priv; GST_DEBUG_OBJECT (stream, "update key for %08x", ssrc); g_mutex_lock (&priv->lock); if (crypto) g_hash_table_insert (priv->keys, GINT_TO_POINTER (ssrc), gst_caps_ref (crypto)); else g_hash_table_remove (priv->keys, GINT_TO_POINTER (ssrc)); g_mutex_unlock (&priv->lock); return TRUE; } /** * gst_rtsp_stream_get_rtp_socket: * @stream: a #GstRTSPStream * @family: the socket family * * Get the RTP socket from @stream for a @family. * * @stream must be joined to a bin. * * Returns: (transfer full) (nullable): the RTP socket or %NULL if no * socket could be allocated for @family. Unref after usage */ GSocket * gst_rtsp_stream_get_rtp_socket (GstRTSPStream * stream, GSocketFamily family) { GstRTSPStreamPrivate *priv = stream->priv; GSocket *socket; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); g_return_val_if_fail (family == G_SOCKET_FAMILY_IPV4 || family == G_SOCKET_FAMILY_IPV6, NULL); g_mutex_lock (&priv->lock); if (family == G_SOCKET_FAMILY_IPV6) socket = priv->socket_v6[0]; else socket = priv->socket_v4[0]; if (socket != NULL) socket = g_object_ref (socket); g_mutex_unlock (&priv->lock); return socket; } /** * gst_rtsp_stream_get_rtcp_socket: * @stream: a #GstRTSPStream * @family: the socket family * * Get the RTCP socket from @stream for a @family. * * @stream must be joined to a bin. * * Returns: (transfer full) (nullable): the RTCP socket or %NULL if no * socket could be allocated for @family. Unref after usage */ GSocket * gst_rtsp_stream_get_rtcp_socket (GstRTSPStream * stream, GSocketFamily family) { GstRTSPStreamPrivate *priv = stream->priv; GSocket *socket; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); g_return_val_if_fail (family == G_SOCKET_FAMILY_IPV4 || family == G_SOCKET_FAMILY_IPV6, NULL); g_mutex_lock (&priv->lock); if (family == G_SOCKET_FAMILY_IPV6) socket = priv->socket_v6[1]; else socket = priv->socket_v4[1]; if (socket != NULL) socket = g_object_ref (socket); g_mutex_unlock (&priv->lock); return socket; } /** * gst_rtsp_stream_get_rtp_multicast_socket: * @stream: a #GstRTSPStream * @family: the socket family * * Get the multicast RTP socket from @stream for a @family. * * Returns: (transfer full) (nullable): the multicast RTP socket or %NULL if no * * socket could be allocated for @family. Unref after usage */ GSocket * gst_rtsp_stream_get_rtp_multicast_socket (GstRTSPStream * stream, GSocketFamily family) { GstRTSPStreamPrivate *priv = stream->priv; GSocket *socket; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); g_return_val_if_fail (family == G_SOCKET_FAMILY_IPV4 || family == G_SOCKET_FAMILY_IPV6, NULL); g_mutex_lock (&priv->lock); if (family == G_SOCKET_FAMILY_IPV6) socket = priv->mcast_socket_v6[0]; else socket = priv->mcast_socket_v4[0]; if (socket != NULL) socket = g_object_ref (socket); g_mutex_unlock (&priv->lock); return socket; } /** * gst_rtsp_stream_get_rtcp_multicast_socket: * @stream: a #GstRTSPStream * @family: the socket family * * Get the multicast RTCP socket from @stream for a @family. * * Returns: (transfer full) (nullable): the multicast RTCP socket or %NULL if no * socket could be allocated for @family. Unref after usage * * Since: 1.14 */ GSocket * gst_rtsp_stream_get_rtcp_multicast_socket (GstRTSPStream * stream, GSocketFamily family) { GstRTSPStreamPrivate *priv = stream->priv; GSocket *socket; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); g_return_val_if_fail (family == G_SOCKET_FAMILY_IPV4 || family == G_SOCKET_FAMILY_IPV6, NULL); g_mutex_lock (&priv->lock); if (family == G_SOCKET_FAMILY_IPV6) socket = priv->mcast_socket_v6[1]; else socket = priv->mcast_socket_v4[1]; if (socket != NULL) socket = g_object_ref (socket); g_mutex_unlock (&priv->lock); return socket; } /** * gst_rtsp_stream_add_multicast_client_address: * @stream: a #GstRTSPStream * @destination: (transfer none): a multicast address to add * @rtp_port: RTP port * @rtcp_port: RTCP port * @family: socket family * * Add multicast client address to stream. At this point, the sockets that * will stream RTP and RTCP data to @destination are supposed to be * allocated. * * Returns: %TRUE if @destination can be addedd and handled by @stream. * * Since: 1.16 */ gboolean gst_rtsp_stream_add_multicast_client_address (GstRTSPStream * stream, const gchar * destination, guint rtp_port, guint rtcp_port, GSocketFamily family) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); g_return_val_if_fail (destination != NULL, FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); if ((family == G_SOCKET_FAMILY_IPV4) && (priv->mcast_socket_v4[0] == NULL)) goto socket_error; else if ((family == G_SOCKET_FAMILY_IPV6) && (priv->mcast_socket_v6[0] == NULL)) goto socket_error; if (!add_mcast_client_addr (stream, destination, rtp_port, rtcp_port)) goto add_addr_error; g_mutex_unlock (&priv->lock); return TRUE; socket_error: { GST_WARNING_OBJECT (stream, "Failed to add multicast address: no udp socket"); g_mutex_unlock (&priv->lock); return FALSE; } add_addr_error: { GST_WARNING_OBJECT (stream, "Failed to add multicast address: invalid address"); g_mutex_unlock (&priv->lock); return FALSE; } } /** * gst_rtsp_stream_get_multicast_client_addresses * @stream: a #GstRTSPStream * * Get all multicast client addresses that RTP data will be sent to * * Returns: A comma separated list of host:port pairs with destinations * * Since: 1.16 */ gchar * gst_rtsp_stream_get_multicast_client_addresses (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GString *str; GList *clients; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; str = g_string_new (""); g_mutex_lock (&priv->lock); clients = priv->mcast_clients; while (clients != NULL) { UdpClientAddrInfo *client; client = (UdpClientAddrInfo *) clients->data; clients = g_list_next (clients); g_string_append_printf (str, "%s:%d%s", client->address, client->rtp_port, (clients != NULL ? "," : "")); } g_mutex_unlock (&priv->lock); return g_string_free (str, FALSE); } /** * gst_rtsp_stream_set_seqnum: * @stream: a #GstRTSPStream * @seqnum: a new sequence number * * Configure the sequence number in the payloader of @stream to @seqnum. */ void gst_rtsp_stream_set_seqnum_offset (GstRTSPStream * stream, guint16 seqnum) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_object_set (G_OBJECT (priv->payloader), "seqnum-offset", seqnum, NULL); } /** * gst_rtsp_stream_get_seqnum: * @stream: a #GstRTSPStream * * Get the configured sequence number in the payloader of @stream. * * Returns: the sequence number of the payloader. */ guint16 gst_rtsp_stream_get_current_seqnum (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; guint seqnum; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), 0); priv = stream->priv; g_object_get (G_OBJECT (priv->payloader), "seqnum", &seqnum, NULL); return seqnum; } /** * gst_rtsp_stream_transport_filter: * @stream: a #GstRTSPStream * @func: (scope call) (allow-none) (closure user_data): a callback * @user_data: user data passed to @func * * Call @func for each transport managed by @stream. The result value of @func * determines what happens to the transport. @func will be called with @stream * locked so no further actions on @stream can be performed from @func. * * If @func returns #GST_RTSP_FILTER_REMOVE, the transport will be removed from * @stream. * * If @func returns #GST_RTSP_FILTER_KEEP, the transport will remain in @stream. * * If @func returns #GST_RTSP_FILTER_REF, the transport will remain in @stream but * will also be added with an additional ref to the result #GList of this * function.. * * When @func is %NULL, #GST_RTSP_FILTER_REF will be assumed for each transport. * * Returns: (element-type GstRTSPStreamTransport) (transfer full): a #GList with all * transports for which @func returned #GST_RTSP_FILTER_REF. After usage, each * element in the #GList should be unreffed before the list is freed. */ GList * gst_rtsp_stream_transport_filter (GstRTSPStream * stream, GstRTSPStreamTransportFilterFunc func, gpointer user_data) { GstRTSPStreamPrivate *priv; GList *result, *walk, *next; GHashTable *visited = NULL; guint cookie; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); priv = stream->priv; result = NULL; if (func) visited = g_hash_table_new_full (NULL, NULL, g_object_unref, NULL); g_mutex_lock (&priv->lock); restart: cookie = priv->transports_cookie; for (walk = priv->transports; walk; walk = next) { GstRTSPStreamTransport *trans = walk->data; GstRTSPFilterResult res; gboolean changed; next = g_list_next (walk); if (func) { /* only visit each transport once */ if (g_hash_table_contains (visited, trans)) continue; g_hash_table_add (visited, g_object_ref (trans)); g_mutex_unlock (&priv->lock); res = func (stream, trans, user_data); g_mutex_lock (&priv->lock); } else res = GST_RTSP_FILTER_REF; changed = (cookie != priv->transports_cookie); switch (res) { case GST_RTSP_FILTER_REMOVE: update_transport (stream, trans, FALSE); break; case GST_RTSP_FILTER_REF: result = g_list_prepend (result, g_object_ref (trans)); break; case GST_RTSP_FILTER_KEEP: default: break; } if (changed) goto restart; } g_mutex_unlock (&priv->lock); if (func) g_hash_table_unref (visited); return result; } static GstPadProbeReturn rtp_pad_blocking (GstPad * pad, GstPadProbeInfo * info, gpointer user_data) { GstRTSPStreamPrivate *priv; GstRTSPStream *stream; GstBuffer *buffer = NULL; GstPadProbeReturn ret = GST_PAD_PROBE_OK; GstEvent *event; stream = user_data; priv = stream->priv; g_mutex_lock (&priv->lock); if ((info->type & GST_PAD_PROBE_TYPE_BUFFER)) { GstRTPBuffer rtp = GST_RTP_BUFFER_INIT; buffer = gst_pad_probe_info_get_buffer (info); if (gst_rtp_buffer_map (buffer, GST_MAP_READ, &rtp)) { priv->blocked_buffer = TRUE; priv->blocked_seqnum = gst_rtp_buffer_get_seq (&rtp); priv->blocked_rtptime = gst_rtp_buffer_get_timestamp (&rtp); gst_rtp_buffer_unmap (&rtp); } priv->position = GST_BUFFER_TIMESTAMP (buffer); if (priv->drop_delta_units) { if (GST_BUFFER_FLAG_IS_SET (buffer, GST_BUFFER_FLAG_DELTA_UNIT)) { g_assert (!priv->blocking); GST_DEBUG_OBJECT (pad, "dropping delta-unit buffer"); ret = GST_PAD_PROBE_DROP; goto done; } } } else if ((info->type & GST_PAD_PROBE_TYPE_BUFFER_LIST)) { GstRTPBuffer rtp = GST_RTP_BUFFER_INIT; GstBufferList *list = gst_pad_probe_info_get_buffer_list (info); buffer = gst_buffer_list_get (list, 0); if (gst_rtp_buffer_map (buffer, GST_MAP_READ, &rtp)) { priv->blocked_buffer = TRUE; priv->blocked_seqnum = gst_rtp_buffer_get_seq (&rtp); priv->blocked_rtptime = gst_rtp_buffer_get_timestamp (&rtp); gst_rtp_buffer_unmap (&rtp); } priv->position = GST_BUFFER_TIMESTAMP (buffer); if (priv->drop_delta_units) { if (GST_BUFFER_FLAG_IS_SET (buffer, GST_BUFFER_FLAG_DELTA_UNIT)) { g_assert (!priv->blocking); GST_DEBUG_OBJECT (pad, "dropping delta-unit buffer"); ret = GST_PAD_PROBE_DROP; goto done; } } } else if ((info->type & GST_PAD_PROBE_TYPE_EVENT_DOWNSTREAM)) { if (GST_EVENT_TYPE (info->data) == GST_EVENT_GAP) { gst_event_parse_gap (info->data, &priv->position, NULL); } else { ret = GST_PAD_PROBE_PASS; GST_WARNING ("Passing event."); goto done; } } else { g_assert_not_reached (); } event = gst_pad_get_sticky_event (pad, GST_EVENT_SEGMENT, 0); if (event) { const GstSegment *segment; gst_event_parse_segment (event, &segment); priv->blocked_running_time = gst_segment_to_stream_time (segment, GST_FORMAT_TIME, priv->position); gst_event_unref (event); } event = gst_pad_get_sticky_event (pad, GST_EVENT_CAPS, 0); if (event) { GstCaps *caps; GstStructure *s; gst_event_parse_caps (event, &caps); s = gst_caps_get_structure (caps, 0); gst_structure_get_int (s, "clock-rate", &priv->blocked_clock_rate); gst_event_unref (event); } /* make sure to block on the correct frame type */ if (priv->drop_delta_units) { g_assert (!GST_BUFFER_FLAG_IS_SET (buffer, GST_BUFFER_FLAG_DELTA_UNIT)); } priv->blocking = TRUE; GST_DEBUG_OBJECT (pad, "Now blocking"); GST_DEBUG_OBJECT (stream, "position: %" GST_TIME_FORMAT, GST_TIME_ARGS (priv->position)); gst_element_post_message (priv->payloader, gst_message_new_element (GST_OBJECT_CAST (priv->payloader), gst_structure_new ("GstRTSPStreamBlocking", "is_complete", G_TYPE_BOOLEAN, priv->is_complete, NULL))); done: g_mutex_unlock (&priv->lock); return ret; } /* this probe will drop a single buffer. It is used when an old buffer is * blocking the pipeline, such as between a DESCRIBE and a PLAY request. */ static GstPadProbeReturn drop_probe (GstPad * pad, GstPadProbeInfo * info, gpointer user_data) { GstRTSPStreamPrivate *priv; GstRTSPStream *stream; /* drop an old buffer stuck in a blocked pipeline */ GstPadProbeReturn ret = GST_PAD_PROBE_DROP; stream = user_data; priv = stream->priv; g_mutex_lock (&priv->lock); if ((info->type & GST_PAD_PROBE_TYPE_BUFFER || info->type & GST_PAD_PROBE_TYPE_BUFFER_LIST)) { /* if a buffer has been dropped then remove this probe */ if (priv->remove_drop_probe) { priv->remove_drop_probe = FALSE; ret = GST_PAD_PROBE_REMOVE; } else { priv->blocking = FALSE; priv->remove_drop_probe = TRUE; } } else { ret = GST_PAD_PROBE_PASS; } g_mutex_unlock (&priv->lock); return ret; } static GstPadProbeReturn rtcp_pad_blocking (GstPad * pad, GstPadProbeInfo * info, gpointer user_data) { GstRTSPStreamPrivate *priv; GstRTSPStream *stream; GstPadProbeReturn ret = GST_PAD_PROBE_OK; stream = user_data; priv = stream->priv; g_mutex_lock (&priv->lock); if ((info->type & GST_PAD_PROBE_TYPE_BUFFER) || (info->type & GST_PAD_PROBE_TYPE_BUFFER_LIST)) { GST_DEBUG_OBJECT (pad, "Now blocking on buffer"); } else if ((info->type & GST_PAD_PROBE_TYPE_EVENT_DOWNSTREAM)) { if (GST_EVENT_TYPE (info->data) == GST_EVENT_GAP) { GST_DEBUG_OBJECT (pad, "Now blocking on gap event"); ret = GST_PAD_PROBE_OK; } else { ret = GST_PAD_PROBE_PASS; g_mutex_unlock (&priv->lock); goto done; } } else { g_assert_not_reached (); } g_mutex_unlock (&priv->lock); done: return ret; } static void install_drop_probe (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; priv = stream->priv; /* if receiver */ if (priv->sinkpad) return; /* install for data channel only */ if (priv->send_src[0]) { gst_pad_add_probe (priv->send_src[0], GST_PAD_PROBE_TYPE_BLOCK | GST_PAD_PROBE_TYPE_BUFFER | GST_PAD_PROBE_TYPE_BUFFER_LIST | GST_PAD_PROBE_TYPE_EVENT_DOWNSTREAM, drop_probe, g_object_ref (stream), g_object_unref); } } static void set_blocked (GstRTSPStream * stream, gboolean blocked) { GstRTSPStreamPrivate *priv; int i; GST_DEBUG_OBJECT (stream, "blocked: %d", blocked); priv = stream->priv; if (blocked) { /* if receiver */ if (priv->sinkpad) { priv->blocking = TRUE; return; } for (i = 0; i < 2; i++) { if (priv->blocked_id[i] != 0) continue; if (priv->send_src[i]) { priv->blocking = FALSE; priv->blocked_buffer = FALSE; priv->blocked_running_time = GST_CLOCK_TIME_NONE; priv->blocked_clock_rate = 0; if (i == 0) { priv->blocked_id[i] = gst_pad_add_probe (priv->send_src[i], GST_PAD_PROBE_TYPE_BLOCK | GST_PAD_PROBE_TYPE_BUFFER | GST_PAD_PROBE_TYPE_BUFFER_LIST | GST_PAD_PROBE_TYPE_EVENT_DOWNSTREAM, rtp_pad_blocking, g_object_ref (stream), g_object_unref); } else { priv->blocked_id[i] = gst_pad_add_probe (priv->send_src[i], GST_PAD_PROBE_TYPE_BLOCK | GST_PAD_PROBE_TYPE_BUFFER | GST_PAD_PROBE_TYPE_BUFFER_LIST | GST_PAD_PROBE_TYPE_EVENT_DOWNSTREAM, rtcp_pad_blocking, g_object_ref (stream), g_object_unref); } } } } else { for (i = 0; i < 2; i++) { if (priv->blocked_id[i] != 0) { gst_pad_remove_probe (priv->send_src[i], priv->blocked_id[i]); priv->blocked_id[i] = 0; } } priv->blocking = FALSE; } } /** * gst_rtsp_stream_set_blocked: * @stream: a #GstRTSPStream * @blocked: boolean indicating we should block or unblock * * Blocks or unblocks the dataflow on @stream. * * Returns: %TRUE on success */ gboolean gst_rtsp_stream_set_blocked (GstRTSPStream * stream, gboolean blocked) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); set_blocked (stream, blocked); g_mutex_unlock (&priv->lock); return TRUE; } /** * gst_rtsp_stream_install_drop_probe: * @stream: a #GstRTSPStream * * This probe can be installed when the currently blocking buffer should be * dropped. When it has successfully dropped the buffer, it will remove itself. * The goal is to avoid sending old data, typically when there has been a delay * between a DESCRIBE and a PLAY request. * * Returns: %TRUE on success * * Since: 1.24 */ gboolean gst_rtsp_stream_install_drop_probe (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); install_drop_probe (stream); g_mutex_unlock (&priv->lock); return TRUE; } /** * gst_rtsp_stream_ublock_linked: * @stream: a #GstRTSPStream * * Unblocks the dataflow on @stream if it is linked. * * Returns: %TRUE on success * * Since: 1.14 */ gboolean gst_rtsp_stream_unblock_linked (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); if (priv->send_src[0] && gst_pad_is_linked (priv->send_src[0])) set_blocked (stream, FALSE); g_mutex_unlock (&priv->lock); return TRUE; } /** * gst_rtsp_stream_is_blocking: * @stream: a #GstRTSPStream * * Check if @stream is blocking on a #GstBuffer. * * Returns: %TRUE if @stream is blocking */ gboolean gst_rtsp_stream_is_blocking (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gboolean result; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); result = priv->blocking; g_mutex_unlock (&priv->lock); return result; } /** * gst_rtsp_stream_query_position: * @stream: a #GstRTSPStream * @position: (out): current position of a #GstRTSPStream * * Query the position of the stream in %GST_FORMAT_TIME. This only considers * the RTP parts of the pipeline and not the RTCP parts. * * Returns: %TRUE if the position could be queried */ gboolean gst_rtsp_stream_query_position (GstRTSPStream * stream, gint64 * position) { GstRTSPStreamPrivate *priv; GstElement *sink; GstPad *pad = NULL; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); /* query position: if no sinks have been added yet, * we obtain the position from the pad otherwise we query the sinks */ priv = stream->priv; g_mutex_lock (&priv->lock); if (priv->blocking && GST_CLOCK_TIME_IS_VALID (priv->blocked_running_time)) { *position = priv->blocked_running_time; g_mutex_unlock (&priv->lock); return TRUE; } /* depending on the transport type, it should query corresponding sink */ if (priv->configured_protocols & GST_RTSP_LOWER_TRANS_UDP) sink = priv->udpsink[0]; else if (priv->configured_protocols & GST_RTSP_LOWER_TRANS_UDP_MCAST) sink = priv->mcast_udpsink[0]; else sink = priv->appsink[0]; if (sink) { gst_object_ref (sink); } else if (priv->send_src[0]) { pad = gst_object_ref (priv->send_src[0]); } else { g_mutex_unlock (&priv->lock); GST_WARNING_OBJECT (stream, "Couldn't obtain position: erroneous pipeline"); return FALSE; } g_mutex_unlock (&priv->lock); if (sink) { if (!gst_element_query_position (sink, GST_FORMAT_TIME, position)) { GST_WARNING_OBJECT (stream, "Couldn't obtain position: position query failed"); gst_object_unref (sink); return FALSE; } gst_object_unref (sink); } else if (pad) { GstEvent *event; const GstSegment *segment; event = gst_pad_get_sticky_event (pad, GST_EVENT_SEGMENT, 0); if (!event) { GST_WARNING_OBJECT (stream, "Couldn't obtain position: no segment event"); gst_object_unref (pad); return FALSE; } gst_event_parse_segment (event, &segment); if (segment->format != GST_FORMAT_TIME) { *position = -1; } else { g_mutex_lock (&priv->lock); *position = priv->position; g_mutex_unlock (&priv->lock); *position = gst_segment_to_stream_time (segment, GST_FORMAT_TIME, *position); } gst_event_unref (event); gst_object_unref (pad); } return TRUE; } /** * gst_rtsp_stream_query_stop: * @stream: a #GstRTSPStream * @stop: (out): current stop of a #GstRTSPStream * * Query the stop of the stream in %GST_FORMAT_TIME. This only considers * the RTP parts of the pipeline and not the RTCP parts. * * Returns: %TRUE if the stop could be queried */ gboolean gst_rtsp_stream_query_stop (GstRTSPStream * stream, gint64 * stop) { GstRTSPStreamPrivate *priv; GstElement *sink; GstPad *pad = NULL; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); /* query stop position: if no sinks have been added yet, * we obtain the stop position from the pad otherwise we query the sinks */ priv = stream->priv; g_mutex_lock (&priv->lock); /* depending on the transport type, it should query corresponding sink */ if (priv->configured_protocols & GST_RTSP_LOWER_TRANS_UDP) sink = priv->udpsink[0]; else if (priv->configured_protocols & GST_RTSP_LOWER_TRANS_UDP_MCAST) sink = priv->mcast_udpsink[0]; else sink = priv->appsink[0]; if (sink) { gst_object_ref (sink); } else if (priv->send_src[0]) { pad = gst_object_ref (priv->send_src[0]); } else { g_mutex_unlock (&priv->lock); GST_WARNING_OBJECT (stream, "Couldn't obtain stop: erroneous pipeline"); return FALSE; } g_mutex_unlock (&priv->lock); if (sink) { GstQuery *query; GstFormat format; gdouble rate; gint64 start_value; gint64 stop_value; query = gst_query_new_segment (GST_FORMAT_TIME); if (!gst_element_query (sink, query)) { GST_WARNING_OBJECT (stream, "Couldn't obtain stop: element query failed"); gst_query_unref (query); gst_object_unref (sink); return FALSE; } gst_query_parse_segment (query, &rate, &format, &start_value, &stop_value); if (format != GST_FORMAT_TIME) *stop = -1; else *stop = rate > 0.0 ? stop_value : start_value; gst_query_unref (query); gst_object_unref (sink); } else if (pad) { GstEvent *event; const GstSegment *segment; event = gst_pad_get_sticky_event (pad, GST_EVENT_SEGMENT, 0); if (!event) { GST_WARNING_OBJECT (stream, "Couldn't obtain stop: no segment event"); gst_object_unref (pad); return FALSE; } gst_event_parse_segment (event, &segment); if (segment->format != GST_FORMAT_TIME) { *stop = -1; } else { *stop = segment->stop; if (*stop == -1) *stop = segment->duration; else *stop = gst_segment_to_stream_time (segment, GST_FORMAT_TIME, *stop); } gst_event_unref (event); gst_object_unref (pad); } return TRUE; } /** * gst_rtsp_stream_seekable: * @stream: a #GstRTSPStream * * Checks whether the individual @stream is seekable. * * Returns: %TRUE if @stream is seekable, else %FALSE. * * Since: 1.14 */ gboolean gst_rtsp_stream_seekable (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; GstPad *pad = NULL; GstQuery *query = NULL; gboolean seekable = FALSE; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); /* query stop position: if no sinks have been added yet, * we obtain the stop position from the pad otherwise we query the sinks */ priv = stream->priv; g_mutex_lock (&priv->lock); /* depending on the transport type, it should query corresponding sink */ if (priv->srcpad) { pad = gst_object_ref (priv->srcpad); } else { g_mutex_unlock (&priv->lock); GST_WARNING_OBJECT (stream, "Pad not available, can't query seekability"); goto beach; } g_mutex_unlock (&priv->lock); query = gst_query_new_seeking (GST_FORMAT_TIME); if (!gst_pad_query (pad, query)) { GST_WARNING_OBJECT (stream, "seeking query failed"); goto beach; } gst_query_parse_seeking (query, NULL, &seekable, NULL, NULL); beach: if (pad) gst_object_unref (pad); if (query) gst_query_unref (query); GST_DEBUG_OBJECT (stream, "Returning %d", seekable); return seekable; } /** * gst_rtsp_stream_complete_stream: * @stream: a #GstRTSPStream * @transport: a #GstRTSPTransport * * Add a receiver and sender part to the pipeline based on the transport from * SETUP. * * Returns: %TRUE if the stream has been successfully updated. * * Since: 1.14 */ gboolean gst_rtsp_stream_complete_stream (GstRTSPStream * stream, const GstRTSPTransport * transport) { GstRTSPStreamPrivate *priv; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; GST_DEBUG_OBJECT (stream, "complete stream"); g_mutex_lock (&priv->lock); if (!(priv->allowed_protocols & transport->lower_transport)) goto unallowed_transport; if (!create_receiver_part (stream, transport)) goto create_receiver_error; /* in the RECORD case, we only add RTCP sender part */ if (!create_sender_part (stream, transport)) goto create_sender_error; priv->configured_protocols |= transport->lower_transport; priv->is_complete = TRUE; g_mutex_unlock (&priv->lock); GST_DEBUG_OBJECT (stream, "pipeline successfully updated"); return TRUE; create_receiver_error: create_sender_error: unallowed_transport: { g_mutex_unlock (&priv->lock); return FALSE; } } /** * gst_rtsp_stream_is_complete: * @stream: a #GstRTSPStream * * Checks whether the stream is complete, contains the receiver and the sender * parts. As the stream contains sink(s) element(s), it's possible to perform * seek operations on it. * * Returns: %TRUE if the stream contains at least one sink element. * * Since: 1.14 */ gboolean gst_rtsp_stream_is_complete (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gboolean ret = FALSE; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); ret = priv->is_complete; g_mutex_unlock (&priv->lock); return ret; } /** * gst_rtsp_stream_is_sender: * @stream: a #GstRTSPStream * * Checks whether the stream is a sender. * * Returns: %TRUE if the stream is a sender and %FALSE otherwise. * * Since: 1.14 */ gboolean gst_rtsp_stream_is_sender (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gboolean ret = FALSE; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); ret = (priv->srcpad != NULL); g_mutex_unlock (&priv->lock); return ret; } /** * gst_rtsp_stream_is_receiver: * @stream: a #GstRTSPStream * * Checks whether the stream is a receiver. * * Returns: %TRUE if the stream is a receiver and %FALSE otherwise. * * Since: 1.14 */ gboolean gst_rtsp_stream_is_receiver (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; gboolean ret = FALSE; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), FALSE); priv = stream->priv; g_mutex_lock (&priv->lock); ret = (priv->sinkpad != NULL); g_mutex_unlock (&priv->lock); return ret; } #define AES_128_KEY_LEN 16 #define AES_256_KEY_LEN 32 #define HMAC_32_KEY_LEN 4 #define HMAC_80_KEY_LEN 10 static gboolean mikey_apply_policy (GstCaps * caps, GstMIKEYMessage * msg, guint8 policy) { const gchar *srtp_cipher; const gchar *srtp_auth; const GstMIKEYPayload *sp; guint i; /* loop over Security policy until we find one containing policy */ for (i = 0;; i++) { if ((sp = gst_mikey_message_find_payload (msg, GST_MIKEY_PT_SP, i)) == NULL) break; if (((GstMIKEYPayloadSP *) sp)->policy == policy) break; } /* the default ciphers */ srtp_cipher = "aes-128-icm"; srtp_auth = "hmac-sha1-80"; /* now override the defaults with what is in the Security Policy */ if (sp != NULL) { guint len; guint enc_alg = GST_MIKEY_ENC_AES_CM_128; /* collect all the params and go over them */ len = gst_mikey_payload_sp_get_n_params (sp); for (i = 0; i < len; i++) { const GstMIKEYPayloadSPParam *param = gst_mikey_payload_sp_get_param (sp, i); switch (param->type) { case GST_MIKEY_SP_SRTP_ENC_ALG: enc_alg = param->val[0]; switch (param->val[0]) { case GST_MIKEY_ENC_NULL: srtp_cipher = "null"; break; case GST_MIKEY_ENC_AES_CM_128: case GST_MIKEY_ENC_AES_KW_128: srtp_cipher = "aes-128-icm"; break; case GST_MIKEY_ENC_AES_GCM_128: srtp_cipher = "aes-128-gcm"; break; default: break; } break; case GST_MIKEY_SP_SRTP_ENC_KEY_LEN: switch (param->val[0]) { case AES_128_KEY_LEN: if (enc_alg == GST_MIKEY_ENC_AES_CM_128 || enc_alg == GST_MIKEY_ENC_AES_KW_128) { srtp_cipher = "aes-128-icm"; } else if (enc_alg == GST_MIKEY_ENC_AES_GCM_128) { srtp_cipher = "aes-128-gcm"; } break; case AES_256_KEY_LEN: if (enc_alg == GST_MIKEY_ENC_AES_CM_128 || enc_alg == GST_MIKEY_ENC_AES_KW_128) { srtp_cipher = "aes-256-icm"; } else if (enc_alg == GST_MIKEY_ENC_AES_GCM_128) { srtp_cipher = "aes-256-gcm"; } break; default: break; } break; case GST_MIKEY_SP_SRTP_AUTH_ALG: switch (param->val[0]) { case GST_MIKEY_MAC_NULL: srtp_auth = "null"; break; case GST_MIKEY_MAC_HMAC_SHA_1_160: srtp_auth = "hmac-sha1-80"; break; default: break; } break; case GST_MIKEY_SP_SRTP_AUTH_KEY_LEN: switch (param->val[0]) { case HMAC_32_KEY_LEN: srtp_auth = "hmac-sha1-32"; break; case HMAC_80_KEY_LEN: srtp_auth = "hmac-sha1-80"; break; default: break; } break; case GST_MIKEY_SP_SRTP_SRTP_ENC: break; case GST_MIKEY_SP_SRTP_SRTCP_ENC: break; default: break; } } } /* now configure the SRTP parameters */ gst_caps_set_simple (caps, "srtp-cipher", G_TYPE_STRING, srtp_cipher, "srtp-auth", G_TYPE_STRING, srtp_auth, "srtcp-cipher", G_TYPE_STRING, srtp_cipher, "srtcp-auth", G_TYPE_STRING, srtp_auth, NULL); return TRUE; } static gboolean handle_mikey_data (GstRTSPStream * stream, guint8 * data, gsize size) { GstMIKEYMessage *msg; guint i, n_cs; GstCaps *caps = NULL; GstMIKEYPayloadKEMAC *kemac; const GstMIKEYPayloadKeyData *pkd; GstBuffer *key; /* the MIKEY message contains a CSB or crypto session bundle. It is a * set of Crypto Sessions protected with the same master key. * In the context of SRTP, an RTP and its RTCP stream is part of a * crypto session */ if ((msg = gst_mikey_message_new_from_data (data, size, NULL, NULL)) == NULL) goto parse_failed; /* we can only handle SRTP crypto sessions for now */ if (msg->map_type != GST_MIKEY_MAP_TYPE_SRTP) goto invalid_map_type; /* get the number of crypto sessions. This maps SSRC to its * security parameters */ n_cs = gst_mikey_message_get_n_cs (msg); if (n_cs == 0) goto no_crypto_sessions; /* we also need keys */ if (!(kemac = (GstMIKEYPayloadKEMAC *) gst_mikey_message_find_payload (msg, GST_MIKEY_PT_KEMAC, 0))) goto no_keys; /* we don't support encrypted keys */ if (kemac->enc_alg != GST_MIKEY_ENC_NULL || kemac->mac_alg != GST_MIKEY_MAC_NULL) goto unsupported_encryption; /* get Key data sub-payload */ pkd = (const GstMIKEYPayloadKeyData *) gst_mikey_payload_kemac_get_sub (&kemac->pt, 0); key = gst_buffer_new_memdup (pkd->key_data, pkd->key_len); /* go over all crypto sessions and create the security policy for each * SSRC */ for (i = 0; i < n_cs; i++) { const GstMIKEYMapSRTP *map = gst_mikey_message_get_cs_srtp (msg, i); caps = gst_caps_new_simple ("application/x-srtp", "ssrc", G_TYPE_UINT, map->ssrc, "roc", G_TYPE_UINT, map->roc, "srtp-key", GST_TYPE_BUFFER, key, NULL); mikey_apply_policy (caps, msg, map->policy); gst_rtsp_stream_update_crypto (stream, map->ssrc, caps); gst_caps_unref (caps); } gst_mikey_message_unref (msg); gst_buffer_unref (key); return TRUE; /* ERRORS */ parse_failed: { GST_DEBUG_OBJECT (stream, "failed to parse MIKEY message"); return FALSE; } invalid_map_type: { GST_DEBUG_OBJECT (stream, "invalid map type %d", msg->map_type); goto cleanup_message; } no_crypto_sessions: { GST_DEBUG_OBJECT (stream, "no crypto sessions"); goto cleanup_message; } no_keys: { GST_DEBUG_OBJECT (stream, "no keys found"); goto cleanup_message; } unsupported_encryption: { GST_DEBUG_OBJECT (stream, "unsupported key encryption"); goto cleanup_message; } cleanup_message: { gst_mikey_message_unref (msg); return FALSE; } } #define IS_STRIP_CHAR(c) (g_ascii_isspace ((guchar)(c)) || ((c) == '\"')) static void strip_chars (gchar * str) { gchar *s; gsize len; len = strlen (str); while (len--) { if (!IS_STRIP_CHAR (str[len])) break; str[len] = '\0'; } for (s = str; *s && IS_STRIP_CHAR (*s); s++); memmove (str, s, len + 1); } /** * gst_rtsp_stream_handle_keymgmt: * @stream: a #GstRTSPStream * @keymgmt: a keymgmt header * * Parse and handle a KeyMgmt header. * * Since: 1.16 */ /* KeyMgmt = "KeyMgmt" ":" key-mgmt-spec 0*("," key-mgmt-spec) * key-mgmt-spec = "prot" "=" KMPID ";" ["uri" "=" %x22 URI %x22 ";"] */ gboolean gst_rtsp_stream_handle_keymgmt (GstRTSPStream * stream, const gchar * keymgmt) { gchar **specs; gint i, j; specs = g_strsplit (keymgmt, ",", 0); for (i = 0; specs[i]; i++) { gchar **split; split = g_strsplit (specs[i], ";", 0); for (j = 0; split[j]; j++) { g_strstrip (split[j]); if (g_str_has_prefix (split[j], "prot=")) { g_strstrip (split[j] + 5); if (!g_str_equal (split[j] + 5, "mikey")) break; GST_DEBUG ("found mikey"); } else if (g_str_has_prefix (split[j], "uri=")) { strip_chars (split[j] + 4); GST_DEBUG ("found uri '%s'", split[j] + 4); } else if (g_str_has_prefix (split[j], "data=")) { guchar *data; gsize size; strip_chars (split[j] + 5); GST_DEBUG ("found data '%s'", split[j] + 5); data = g_base64_decode_inplace (split[j] + 5, &size); handle_mikey_data (stream, data, size); } } g_strfreev (split); } g_strfreev (specs); return TRUE; } /** * gst_rtsp_stream_get_ulpfec_pt: * * Returns: the payload type used for ULPFEC protection packets * * Since: 1.16 */ guint gst_rtsp_stream_get_ulpfec_pt (GstRTSPStream * stream) { guint res; g_mutex_lock (&stream->priv->lock); res = stream->priv->ulpfec_pt; g_mutex_unlock (&stream->priv->lock); return res; } /** * gst_rtsp_stream_set_ulpfec_pt: * * Set the payload type to be used for ULPFEC protection packets * * Since: 1.16 */ void gst_rtsp_stream_set_ulpfec_pt (GstRTSPStream * stream, guint pt) { g_return_if_fail (GST_IS_RTSP_STREAM (stream)); g_mutex_lock (&stream->priv->lock); stream->priv->ulpfec_pt = pt; if (stream->priv->ulpfec_encoder) { g_object_set (stream->priv->ulpfec_encoder, "pt", pt, NULL); } g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_request_ulpfec_decoder: * * Creating a rtpulpfecdec element * * Returns: (transfer full) (nullable): a #GstElement. * * Since: 1.16 */ GstElement * gst_rtsp_stream_request_ulpfec_decoder (GstRTSPStream * stream, GstElement * rtpbin, guint sessid) { GObject *internal_storage = NULL; g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); stream->priv->ulpfec_decoder = gst_object_ref (gst_element_factory_make ("rtpulpfecdec", NULL)); g_signal_emit_by_name (G_OBJECT (rtpbin), "get-internal-storage", sessid, &internal_storage); g_object_set (stream->priv->ulpfec_decoder, "storage", internal_storage, NULL); g_object_unref (internal_storage); update_ulpfec_decoder_pt (stream); return stream->priv->ulpfec_decoder; } /** * gst_rtsp_stream_request_ulpfec_encoder: * * Creating a rtpulpfecenc element * * Returns: (transfer full) (nullable): a #GstElement. * * Since: 1.16 */ GstElement * gst_rtsp_stream_request_ulpfec_encoder (GstRTSPStream * stream, guint sessid) { g_return_val_if_fail (GST_IS_RTSP_STREAM (stream), NULL); if (!stream->priv->ulpfec_percentage) return NULL; stream->priv->ulpfec_encoder = gst_object_ref (gst_element_factory_make ("rtpulpfecenc", NULL)); g_object_set (stream->priv->ulpfec_encoder, "pt", stream->priv->ulpfec_pt, "percentage", stream->priv->ulpfec_percentage, NULL); return stream->priv->ulpfec_encoder; } /** * gst_rtsp_stream_set_ulpfec_percentage: * * Sets the amount of redundancy to apply when creating ULPFEC * protection packets. * * Since: 1.16 */ void gst_rtsp_stream_set_ulpfec_percentage (GstRTSPStream * stream, guint percentage) { g_return_if_fail (GST_IS_RTSP_STREAM (stream)); g_mutex_lock (&stream->priv->lock); stream->priv->ulpfec_percentage = percentage; if (stream->priv->ulpfec_encoder) { g_object_set (stream->priv->ulpfec_encoder, "percentage", percentage, NULL); } g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_get_ulpfec_percentage: * * Returns: the amount of redundancy applied when creating ULPFEC * protection packets. * * Since: 1.16 */ guint gst_rtsp_stream_get_ulpfec_percentage (GstRTSPStream * stream) { guint res; g_mutex_lock (&stream->priv->lock); res = stream->priv->ulpfec_percentage; g_mutex_unlock (&stream->priv->lock); return res; } /** * gst_rtsp_stream_set_rate_control: * * Define whether @stream will follow the Rate-Control=no behaviour as specified * in the ONVIF replay spec. * * Since: 1.18 */ void gst_rtsp_stream_set_rate_control (GstRTSPStream * stream, gboolean enabled) { GST_DEBUG_OBJECT (stream, "%s rate control", enabled ? "Enabling" : "Disabling"); g_mutex_lock (&stream->priv->lock); stream->priv->do_rate_control = enabled; if (stream->priv->appsink[0]) g_object_set (stream->priv->appsink[0], "sync", enabled, NULL); if (stream->priv->payloader && g_object_class_find_property (G_OBJECT_GET_CLASS (stream-> priv->payloader), "onvif-no-rate-control")) g_object_set (stream->priv->payloader, "onvif-no-rate-control", !enabled, NULL); if (stream->priv->session) { g_object_set (stream->priv->session, "disable-sr-timestamp", !enabled, NULL); } g_mutex_unlock (&stream->priv->lock); } /** * gst_rtsp_stream_get_rate_control: * * Returns: whether @stream will follow the Rate-Control=no behaviour as specified * in the ONVIF replay spec. * * Since: 1.18 */ gboolean gst_rtsp_stream_get_rate_control (GstRTSPStream * stream) { gboolean ret; g_mutex_lock (&stream->priv->lock); ret = stream->priv->do_rate_control; g_mutex_unlock (&stream->priv->lock); return ret; } /** * gst_rtsp_stream_unblock_rtcp: * * Remove blocking probe from the RTCP source. When creating an UDP source for * RTCP it is initially blocked until this function is called. * This functions should be called once the pipeline is ready for handling RTCP * packets. * * Since: 1.20 */ void gst_rtsp_stream_unblock_rtcp (GstRTSPStream * stream) { GstRTSPStreamPrivate *priv; priv = stream->priv; g_mutex_lock (&priv->lock); if (priv->block_early_rtcp_probe != 0) { gst_pad_remove_probe (priv->block_early_rtcp_pad, priv->block_early_rtcp_probe); priv->block_early_rtcp_probe = 0; gst_object_unref (priv->block_early_rtcp_pad); priv->block_early_rtcp_pad = NULL; } if (priv->block_early_rtcp_probe_ipv6 != 0) { gst_pad_remove_probe (priv->block_early_rtcp_pad_ipv6, priv->block_early_rtcp_probe_ipv6); priv->block_early_rtcp_probe_ipv6 = 0; gst_object_unref (priv->block_early_rtcp_pad_ipv6); priv->block_early_rtcp_pad_ipv6 = NULL; } g_mutex_unlock (&priv->lock); } /** * gst_rtsp_stream_set_drop_delta_units: * @stream: a #GstRTSPStream * @drop: TRUE if delta unit frames are supposed to be dropped. * * Decide whether the blocking probe is supposed to drop delta units at the * beginning of a stream. * * Since: 1.24 */ void gst_rtsp_stream_set_drop_delta_units (GstRTSPStream * stream, gboolean drop) { GstRTSPStreamPrivate *priv; g_return_if_fail (GST_IS_RTSP_STREAM (stream)); priv = stream->priv; g_mutex_lock (&priv->lock); priv->drop_delta_units = drop; g_mutex_unlock (&priv->lock); }