WebSocket is a protocol that provides full-duplex communication between web clients and servers over TCP connections. Using the WebSocket protocol, browsers can connect to web servers and exchange data, regardless the type or nature of the application protocol. RFC 7118 leveraged this protocol in order to allow browsers to make VoIP calls using the SIP protocol. WebSocketSecure (WSS) overlays TLS onto the Websocket protocol making the connection secure, a requirement for many browsers if you want to do WebRTC.
This document describes how to use OpenSIPS as the core component of a SIP platform that connects both SIP clients (over UDP, TCP or TLS) as well as browser based clients using SIP over WebSockets and WebSocketsSecure. While OpenSIPS handles the SIP signalling part, media is handled by RTPengine, a high performance media proxy that is able to handle both RTP and SRTP media streams, as well as bridging between them.
The RTPengine consists of two main components: a kernel module used to efficiently route the RTP packets directly in kernel, and a daemon used to communicate with OpenSIPS. You can find more details here. Both components can be installed from debs (on Debian based systems) or directly from sources. Simply follow the official documentation to install RTPengine.
You must generate certificates to use with TLS and WSS. For this example we are generating certificates using LetsEncrypt
Also important to note that as of 2.2, certificate management has been split out into a new module, TLS_MGM. Setting appropriate modparams for the tls_mgm module is how we will manage our certificates for both WSS and TLS.
After installing the kernel module and the additional libraries, the rtpengine daemon has to be configured. This can be done from /etc/default/ngcp-rtpengine-daemon
if installed from debs, or from the command line if the daemon is started manually. On systemd based OSes, Eric Tamme created some startup scripts.
The interesting parameters we are using are as follows:
-i
: the listening interface for RTP/SRTP-n
: the listening IP and port that is used by OpenSIPS to communicate with the RTPengine (NOTE: the rtpengine module only works with the rtpengine NG protocol, so you must use -n
/--listen-ng
; Using -u
/--listen-udp
or -l
/--listen-tcp
will not work!)-c
: the IP and port of the CLI - this is used to gather statistics for the RTP/SRTP sessions-m, -M
: both take an integer as argument and together define the local port range from which rtpengine will allocate UDP ports for media traffic relay. Default to 30000 and 40000 respectively.-L
: indicates the debugging levelYou can find all the parameters available here.
Here is an example that runs rtpengine
from cli that talks with OpenSIPS over localhost and RTP using the 1.1.1.1 IP:
./rtpengine -p /var/run/rtpengine.pid -i eth0/1.1.1.1 -n 127.0.0.1:60000 -c 127.0.0.0.1:60001 -m 50000 -M 55000 -E -L 7
First make sure the rtpengine
daemon is started:
ps -ef | grep rtpengine
If the rtpengine
daemon does not start, make sure the xt_RTPENGINE
kernel module is loaded:
lsmod | grep xt_RTPENGINE
If the module is not loaded, make sure the ip_tables
and x_tables
kernel modules are loaded. Also, check the logs for the last errors of the system
dmesg
In order to use WebSocket and WebSocketSecure in OpenSIPS, one has to load the proto_ws and proto_wss into its configuration file and define a listener for the WebSocket and WebSocketSecure protocol. We also must load the tls_mgm module in order to manage our certificates.
# set listeners for all protocols listen=ws:127.0.0.1:8080 listen=wss:127.0.0.1:443 listen=tls:127.0.0.1:5061 listen=udp:127.0.0.1:5060 # load our certificate management module loadmodule "tls_mgm.so" #load all protocol modules loadmodule "proto_udp.so" loadmodule "proto_tls.so" loadmodule "proto_wss.so" loadmodule "proto_ws.so" # modparam our certificate information modparam("tls_mgm", "certificate","/etc/letsencrypt/live/acme.com/cert.pem") modparam("tls_mgm", "private_key","/etc/letsencrypt/live/acme.com/privkey.pem")
Next, the rtpengine module has to be loaded and configured to communicate with the rtpengine
daemon.
loadmodule "rtpengine.so" modparam("rtpengine", "rtpengine_sock", "udp:127.0.0.1:60000")
Note that the rtpengine_sock parameter should be the same as the -n
parameter sent to the rtpengine
daemon, and OpenSIPS should have IP connectivity to that socket.
Next, the routing logic has to be changed in order to treat different the clients that use DTLS-SRTP, from the ones that use plain RTP and enable bridging if necessary. To do that, one can check if the request message was received over the WebSocket protocol. This can be achieved using the following code:
if (proto == WS || proto == WSS) setflag(SRC_WS);
In case the request is a REGISTER, we want to store this information in the location table, so that we know then the user is called. To do that, we can set a branch flag before calling the save()function. This way, when the lookup() method returns, we will be able to determine whether the client uses WebSocket or not.
if (is_method("REGISTER")) { if (isflagset(SRC_WS)) setbflag(DST_WS); fix_nated_register(); if (!save("location")) sl_reply_error(); exit; }
When a call is placed, based on the two flags (STR_WS
and DST_WS
) we can determine what our caller and callee can "speak" (either RTP or DTLS-SRTP) and instruct the rtpengine
daemon how to handle the call. We can do that by tuning the parameters passed to the rtpengine_offer() function.
if (isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "ICE=force-relay DTLS=passive"; else if (isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; else if (!isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "UDP/TLS/RTP/SAVPF ICE=force"; else if (!isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; rtpengine_offer("$var(rtpengine_flags)");
The rtpengine_answer() function logic should look like this:
if (isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "ICE=force-relay DTLS=passive"; else if (isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "UDP/TLS/RTP/SAVPF ICE=force"; else if (!isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; else if (!isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; rtpengine_answer("$var(rtpengine_flags)");
Now, all we have to do is to close the RTP/SRTP session when the call is ended. To do that, we use the rtpengine_delete() function:
if (is_method("BYE|CANCEL")) { rtpengine_delete();
Having done all these settings should provide a full setup for interconnecting SIP clients over both UDP, TCP, etc. protocols, as well as browser based SIP clients over WebSocket.
The following configuration file is a minimal working example of a Residential script that can handle clients connections over both UDP and Websocket transports. This example assumes that the SDP offer is present in the INVITE from the UAC and the SDP answer is in the 200 OK from the UAS.
NOTE: the default port for WSS (443) is privileged, so if you are running this script, you should start OpenSIPS with super-user rights (as user root).
# # OpenSIPS residential configuration script # by OpenSIPS Solutions <team@opensips-solutions.com> # # Please refer to the Core CookBook at: # http://www.opensips.org/Resources/DocsCookbooks # for a explanation of possible statements, functions and parameters. # ####### Global Parameters ######### debug=3 log_stderror=no log_facility=LOG_LOCAL0 fork=yes children=4 auto_aliases=no # Set up listeners listen=ws:127.0.0.1:8080 listen=wss:127.0.0.1:443 listen=tls:127.0.0.1:5061 listen=udp:127.0.0.1:5060 ####### Modules Section ######## # set module path mpath="/usr/local/lib/opensips/modules/" #### SIGNALING module loadmodule "signaling.so" #### StateLess module loadmodule "sl.so" #### Transaction Module loadmodule "tm.so" modparam("tm", "fr_timeout", 5) modparam("tm", "fr_inv_timeout", 30) modparam("tm", "restart_fr_on_each_reply", 0) modparam("tm", "onreply_avp_mode", 1) #### Record Route Module loadmodule "rr.so" modparam("rr", "append_fromtag", 0) #### MAX ForWarD module loadmodule "maxfwd.so" #### SIP MSG OPerationS module loadmodule "sipmsgops.so" #### FIFO Management Interface loadmodule "mi_fifo.so" modparam("mi_fifo", "fifo_name", "/tmp/opensips_fifo") modparam("mi_fifo", "fifo_mode", 0666) #### URI module loadmodule "uri.so" modparam("uri", "use_uri_table", 0) #### USeR LOCation module loadmodule "usrloc.so" modparam("usrloc", "nat_bflag", "NAT") modparam("usrloc", "db_mode", 0) #### REGISTRAR module loadmodule "registrar.so" #### RTPengine protocol loadmodule "rtpengine.so" modparam("rtpengine", "rtpengine_sock", "udp:127.0.0.0:60000") #### Nathelper protocol loadmodule "nathelper.so" modparam("registrar|nathelper", "received_avp", "$avp(rcv)") #### UDP protocol loadmodule "proto_udp.so" #### TLS protocol loadmodule "proto_tls.so" #### WebSocket and WebSocketSecure protocol loadmodule "proto_wss.so" loadmodule "proto_ws.so" # Certificate management loadmodule "tls_mgm.so" modparam("tls_mgm", "certificate","/etc/letsencrypt/live/acme.com/cert.pem") modparam("tls_mgm", "private_key","/etc/letsencrypt/live/acme.com/privkey.pem") ####### Routing Logic ######## # main request routing logic route{ if (!mf_process_maxfwd_header("10")) { sl_send_reply("483","Too Many Hops"); exit; } if (has_totag()) { # sequential requests within a dialog should # take the path determined by record-routing if (loose_route()) { if (is_method("INVITE")) { # even if in most of the cases is useless, do RR for # re-INVITEs alos, as some buggy clients do change route set # during the dialog. record_route(); } # route it out to whatever destination was set by loose_route() # in $du (destination URI). route(relay); } else { if ( is_method("ACK") ) { if ( t_check_trans() ) { # non loose-route, but stateful ACK; must be an ACK after # a 487 or e.g. 404 from upstream server t_relay(); exit; } else { # ACK without matching transaction -> # ignore and discard exit; } } sl_send_reply("404","Not here"); } exit; } # CANCEL processing if (is_method("CANCEL")) { if (t_check_trans()) t_relay(); exit; } t_check_trans(); if (!is_method("REGISTER")) { if (from_uri!=myself) { # if caller is not local, then called number must be local if (!uri==myself) { send_reply("403","Rely forbidden"); exit; } } } # preloaded route checking if (loose_route()) { xlog("L_ERR", "Attempt to route with preloaded Route's [$fu/$tu/$ru/$ci]"); if (!is_method("ACK")) sl_send_reply("403","Preload Route denied"); exit; } # record routing if (!is_method("REGISTER|MESSAGE")) record_route(); if (!uri==myself) { append_hf("P-hint: outbound\r\n"); route(relay); } # requests for my domain if (is_method("PUBLISH|SUBSCRIBE")) { sl_send_reply("503", "Service Unavailable"); exit; } # check if the clients are using WebSockets or WebSocketSecure if (proto == WS || proto == WSS) setflag(SRC_WS); # consider the client is behind NAT - always fix the contact fix_nated_contact(); if (is_method("REGISTER")) { # indicate that the client supports DTLS # so we know when he is called if (isflagset(SRC_WS)) setbflag(DST_WS); fix_nated_register(); if (!save("location")) sl_reply_error(); exit; } if ($rU==NULL) { # request with no Username in RURI sl_send_reply("484","Address Incomplete"); exit; } # do lookup with method filtering if (!lookup("location","m")) { t_newtran(); t_reply("404", "Not Found"); exit; } route(relay); } route[relay] { # for INVITEs enable some additional helper routes if (is_method("INVITE")) { t_on_branch("handle_nat"); t_on_reply("handle_nat"); } else if (is_method("BYE|CANCEL")) { rtpengine_delete(); } if (!t_relay()) { send_reply("500","Internal Error"); }; exit; } branch_route[handle_nat] { if (!is_method("INVITE") || !has_body("application/sdp")) return; if (isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "ICE=force-relay DTLS=passive"; else if (isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; else if (!isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "UDP/TLS/RTP/SAVPF ICE=force"; else if (!isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; rtpengine_offer("$var(rtpengine_flags)"); } onreply_route[handle_nat] { fix_nated_contact(); if (!has_body("application/sdp")) return; if (isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "ICE=force-relay DTLS=passive"; else if (isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "UDP/TLS/RTP/SAVPF ICE=force"; else if (!isflagset(SRC_WS) && isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; else if (!isflagset(SRC_WS) && !isbflagset(DST_WS)) $var(rtpengine_flags) = "RTP/AVP replace-session-connection replace-origin ICE=remove"; rtpengine_answer("$var(rtpengine_flags)"); }
Here you can find a more complex configuration file, that also includes support for late SDP negociation (SDP is exchanged between 200 OK and ACK).