libdatachannel is a standalone implementation of WebRTC Data Channels, WebRTC Media Transport, and WebSockets in C++17 with C bindings for POSIX platforms (including GNU/Linux, Android, and Apple macOS) and Microsoft Windows. It enables direct connectivity between native applications and web browsers without the pain of importing the entire WebRTC stack. The interface consists of simplified versions of the JavaScript WebRTC and WebSocket APIs present in browsers, in order to ease the design of cross-environment applications. It can be compiled with multiple backends:
- The security layer can be provided through OpenSSL or GnuTLS.
- The connectivity for WebRTC can be provided through my ad-hoc ICE library libjuice as submodule or through libnice.
This projet is originally inspired by librtcdcpp, however it is a complete rewrite from scratch, because the messy architecture of librtcdcpp made solving its implementation issues difficult.
Licensed under LGPLv2, see LICENSE.
The library aims at implementing the following communication protocols:
The WebRTC stack has been tested to be compatible with Firefox and Chromium.
Protocol stack:
- SCTP-based Data Channels (draft-ietf-rtcweb-data-channel-13)
- SRTP-based Media Transport (draft-ietf-rtcweb-rtp-usage-26) with libSRTP
- DTLS/UDP (RFC7350 and RFC8261)
- ICE (RFC8445) with STUN (RFC5389)
Features:
- Full IPv6 support
- Trickle ICE (draft-ietf-ice-trickle-21)
- JSEP compatible (draft-ietf-rtcweb-jsep-26)
- SRTP and SRTCP key derivation from DTLS (RFC5764)
- Multicast DNS candidates (draft-ietf-rtcweb-mdns-ice-candidates-04)
- TURN relaying (RFC5766) with libnice as ICE backend
Note only SDP BUNDLE mode is supported for media multiplexing (draft-ietf-mmusic-sdp-bundle-negotiation-54). The behavior is equivalent to the JSEP bundle-only policy: the library always negociates one unique network component, where SRTP media streams are multiplexed with SRTCP control packets (RFC5761) and SCTP/DTLS data traffic (RFC5764).
WebSocket is the protocol of choice for WebRTC signaling. The support is optional and can be disabled at compile time.
Protocol stack:
Features:
- IPv6 and IPv4/IPv6 dual-stack support
- Keepalive with ping/pong
Dependencies:
- GnuTLS: https://www.gnutls.org/ or OpenSSL: https://www.openssl.org/
Submodules:
- libjuice: https://github.com/paullouisageneau/libjuice
- usrsctp: https://github.com/sctplab/usrsctp
Optional dependencies:
- libnice: https://nice.freedesktop.org/ (only if selected as ICE backend instead of libjuice)
- libSRTP: https://github.com/cisco/libsrtp (only necessary for supporting media transport)
$ git clone https://github.com/paullouisageneau/libdatachannel.git
$ cd libdatachannel
$ git submodule update --init --recursiveThe CMake library targets libdatachannel and libdatachannel-static respectively correspond to the shared and static libraries. The default target will build tests and examples. The option USE_GNUTLS allows to switch between OpenSSL (default) and GnuTLS, and the option USE_NICE allows to switch between libjuice as submodule (default) and libnice.
On Windows, the DLL resulting from the shared library build only exposes the C API, use the static library for the C++ API.
$ cmake -B build -DUSE_GNUTLS=1 -DUSE_NICE=0
$ cd build
$ make -j2$ cmake -B build -DCMAKE_TOOLCHAIN_FILE=/usr/share/mingw/toolchain-x86_64-w64-mingw32.cmake # replace with your toolchain file
$ cd build
$ make -j2$ cmake -B build -G "NMake Makefiles"
$ cd build
$ nmakeThe option USE_GNUTLS allows to switch between OpenSSL (default) and GnuTLS, and the option USE_NICE allows to switch between libjuice as submodule (default) and libnice.
$ make USE_GNUTLS=1 USE_NICE=0See examples for a complete usage example with signaling server (under GPLv2).
Additionnaly, you might want to have a look at the C API.
#include "rtc/rtc.hpp"rtc::Configuration config;
config.iceServers.emplace_back("mystunserver.org:3478");
auto pc = make_shared<rtc::PeerConnection>(config);
pc->onLocalDescription([](rtc::Description sdp) {
// Send the SDP to the remote peer
MY_SEND_DESCRIPTION_TO_REMOTE(string(sdp));
});
pc->onLocalCandidate([](rtc::Candidate candidate) {
// Send the candidate to the remote peer
MY_SEND_CANDIDATE_TO_REMOTE(candidate.candidate(), candidate.mid());
});
MY_ON_RECV_DESCRIPTION_FROM_REMOTE([pc](string sdp) {
pc->setRemoteDescription(rtc::Description(sdp));
});
MY_ON_RECV_CANDIDATE_FROM_REMOTE([pc](string candidate, string mid) {
pc->addRemoteCandidate(rtc::Candidate(candidate, mid));
});pc->onStateChange([](PeerConnection::State state) {
cout << "State: " << state << endl;
});
pc->onGatheringStateChange([](PeerConnection::GatheringState state) {
cout << "Gathering state: " << state << endl;
});
auto dc = pc->createDataChannel("test");
dc->onOpen([]() {
cout << "Open" << endl;
});
dc->onMessage([](variant<binary, string> message) {
if (holds_alternative<string>(message)) {
cout << "Received: " << get<string>(message) << endl;
}
});shared_ptr<rtc::DataChannel> dc;
pc->onDataChannel([&dc](shared_ptr<rtc::DataChannel> incoming) {
dc = incoming;
dc->send("Hello world!");
});
auto ws = make_shared<rtc::WebSocket>();
ws->onOpen([]() {
cout << "WebSocket open" << endl;
});
ws->onMessage([](variant<binary, string> message) {
if (holds_alternative<string>(message)) {
cout << "WebSocket received: " << get<string>(message) << endl;
}
});
ws->open("wss://my.websocket/service");
- Rust wrapper for libdatachannel: datachannel-rs
- Node.js wrapper for libdatachannel: node-datachannel
- WebAssembly wrapper compatible with libdatachannel: datachannel-wasm
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