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Introduction to libSRTP

This package provides an implementation of the Secure Real-time
Transport Protocol (SRTP), the Universal Security Transform (UST), and
a supporting cryptographic kernel. The SRTP API is documented in include/srtp.h,
and the library is in libsrtp2.a (after compilation).

This document describes libSRTP, the Open Source Secure RTP library
from Cisco Systems, Inc. RTP is the Real-time Transport Protocol, an
IETF standard for the transport of real-time data such as telephony,
audio, and video, defined by RFC 3550.
Secure RTP (SRTP) is an RTP profile for providing confidentiality to RTP data
and authentication to the RTP header and payload. SRTP is an IETF Standard,
defined in RFC 3711, and was developed
in the IETF Audio/Video Transport (AVT) Working Group. This library supports
all of the mandatory features of SRTP, but not all of the optional features. See
the Supported Features section for more detailed information.

This document is also used to generate the documentation files in the /doc/
folder where a more detailed reference to the libSRTP API and related functions
can be created (requires installing doxygen.). The reference material is created
automatically from comments embedded in some of the C header files. The
documentation is organized into modules in order to improve its clarity. These
modules do not directly correspond to files. An underlying cryptographic kernel
provides much of the basic functionality of libSRTP but is mostly undocumented
because it does its work behind the scenes.


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Contents


License and Disclaimer

libSRTP is distributed under the following license, which is included
in the source code distribution. It is reproduced in the manual in
case you got the library from another source.

Copyright (c) 2001-2017 Cisco Systems, Inc. All rights reserved.

Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:

  • Redistributions of source code must retain the above copyright
    notice, this list of conditions and the following disclaimer.
  • Redistributions in binary form must reproduce the above copyright
    notice, this list of conditions and the following disclaimer in
    the documentation and/or other materials provided with the distribution.
  • Neither the name of the Cisco Systems, Inc. nor the names of its
    contributors may be used to endorse or promote products derived
    from this software without specific prior written permission.

THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED
OF THE POSSIBILITY OF SUCH DAMAGE.


libSRTP Overview

libSRTP provides functions for protecting RTP and RTCP. RTP packets
can be encrypted and authenticated (using the srtp_protect()
function), turning them into SRTP packets. Similarly, SRTP packets
can be decrypted and have their authentication verified (using the
srtp_unprotect() function), turning them into RTP packets. Similar
functions apply security to RTCP packets.

The typedef srtp_stream_t points to a structure holding all of the
state associated with an SRTP stream, including the keys and
parameters for cipher and message authentication functions and the
anti-replay data. A particular srtp_stream_t holds the information
needed to protect a particular RTP and RTCP stream. This datatype
is intentionally opaque in order to better seperate the libSRTP
API from its implementation.

Within an SRTP session, there can be multiple streams, each
originating from a particular sender. Each source uses a distinct
stream context to protect the RTP and RTCP stream that it is
originating. The typedef srtp_t points to a structure holding all of
the state associated with an SRTP session. There can be multiple
stream contexts associated with a single srtp_t. A stream context
cannot exist indepent from an srtp_t, though of course an srtp_t can
be created that contains only a single stream context. A device
participating in an SRTP session must have a stream context for each
source in that session, so that it can process the data that it
receives from each sender.

In libSRTP, a session is created using the function srtp_create().
The policy to be implemented in the session is passed into this
function as an srtp_policy_t structure. A single one of these
structures describes the policy of a single stream. These structures
can also be linked together to form an entire session policy. A linked
list of srtp_policy_t structures is equivalent to a session policy.
In such a policy, we refer to a single srtp_policy_t as an element.

An srtp_policy_t structure contains two srtp_crypto_policy_t structures
that describe the cryptograhic policies for RTP and RTCP, as well as
the SRTP master key and the SSRC value. The SSRC describes what to
protect (e.g. which stream), and the srtp_crypto_policy_t structures
describe how to protect it. The key is contained in a policy element
because it simplifies the interface to the library. In many cases, it
is desirable to use the same cryptographic policies across all of the
streams in a session, but to use a distinct key for each stream. A
srtp_crypto_policy_t structure can be initialized by using either the
srtp_crypto_policy_set_rtp_default() or srtp_crypto_policy_set_rtcp_default()
functions, which set a crypto policy structure to the default policies
for RTP and RTCP protection, respectively.


Secure RTP Background

In this section we review SRTP and introduce some terms that are used
in libSRTP. An RTP session is defined by a pair of destination
transport addresses, that is, a network address plus a pair of UDP
ports for RTP and RTCP. RTCP, the RTP control protocol, is used to
coordinate between the participants in an RTP session, e.g. to provide
feedback from receivers to senders. An SRTP session is
similarly defined; it is just an RTP session for which the SRTP
profile is being used. An SRTP session consists of the traffic sent
to the SRTP or SRTCP destination transport addresses. Each
participant in a session is identified by a synchronization source
(SSRC) identifier. Some participants may not send any SRTP traffic;
they are called receivers, even though they send out SRTCP traffic,
such as receiver reports.

RTP allows multiple sources to send RTP and RTCP traffic during the
same session. The synchronization source identifier (SSRC) is used to
distinguish these sources. In libSRTP, we call the SRTP and SRTCP
traffic from a particular source a stream. Each stream has its own
SSRC, sequence number, rollover counter, and other data. A particular
choice of options, cryptographic mechanisms, and keys is called a
policy. Each stream within a session can have a distinct policy
applied to it. A session policy is a collection of stream policies.

A single policy can be used for all of the streams in a given session,
though the case in which a single key is shared across multiple
streams requires care. When key sharing is used, the SSRC values that
identify the streams must be distinct. This requirement can be
enforced by using the convention that each SRTP and SRTCP key is used
for encryption by only a single sender. In other words, the key is
shared only across streams that originate from a particular device (of
course, other SRTP participants will need to use the key for
decryption). libSRTP supports this enforcement by detecting the case
in which a key is used for both inbound and outbound data.


Supported Features

This library supports all of the mandatory-to-implement features of
SRTP (as defined in RFC 3711). Some of these
features can be selected (or de-selected) at run time by setting an
appropriate policy; this is done using the structure srtp_policy_t.
Some other behaviors of the protocol can be adapted by defining an
approriate event handler for the exceptional events; see the SRTPevents
section in the generated documentation.

Some options that are described in the SRTP specification are not
supported. This includes

  • key derivation rates other than zero,
  • the cipher F8,
  • the use of the packet index to select between master keys.

The user should be aware that it is possible to misuse this library,
and that the result may be that the security level it provides is
inadequate. If you are implementing a feature using this library, you
will want to read the Security Considerations section of RFC 3711.
In addition, it is important that you read and understand the
terms outlined in the License and Disclaimer section.

This library also supports the AES-GCM Authenticated Encryption methods
described in RFC 7714


Implementation Notes

  • It is possible to configure which 3rd party (ie openssl/nss/etc) crypto backend
    libSRTP will be built with. If no 3rd party backend is set then libSRTP provides
    an internal implementation of AES and Sha1. The internal implementation only
    supports AES-128 & AES-256, so to use AES-192 or the AES-GCM group of ciphers a
    3rd party crypto backend must be configured. For this and performance reasons it
    is highly recommended to use a 3rd party crypto backend.

  • The srtp_protect() function assumes that the buffer holding the
    rtp packet has enough storage allocated that the authentication
    tag can be written to the end of that packet. If this assumption
    is not valid, memory corruption will ensue.

  • Automated tests for the crypto functions are provided through
    the cipher_type_self_test() and auth_type_self_test() functions.
    These functions should be used to test each port of this code
    to a new platform.

  • Replay protection is contained in the crypto engine, and
    tests for it are provided.

  • This implementation provides calls to initialize, protect, and
    unprotect RTP packets, and makes as few as possible assumptions
    about how these functions will be called. For example, the
    caller is not expected to provide packets in order (though if
    they're called more than 65k out of sequence, synchronization
    will be lost).

  • The sequence number in the rtp packet is used as the low 16 bits
    of the sender's local packet index. Note that RTP will start its
    sequence number in a random place, and the SRTP layer just jumps
    forward to that number at its first invocation. An earlier
    version of this library used initial sequence numbers that are
    less than 32,768; this trick is no longer required as the
    rdbx_estimate_index(...) function has been made smarter.

  • The replay window for (S)RTCP is hardcoded to 128 bits in length.


Installing and Building libSRTP

To install libSRTP, download the latest release of the distribution
from https://github.com/cisco/libsrtp/releases.
You probably want to get the most recent release. Unpack the distribution and
extract the source files; the directory into which the source files
will go is named libsrtp-A-B-C where A is the version number, B is the
major release number and C is the minor release number.

libSRTP uses the GNU autoconf and make utilities (BSD make will not work; if
both versions of make are on your platform, you can invoke GNU make as
gmake.). In the libsrtp directory, run the configure script and then
make:

./configure [ options ]
make

The configure script accepts the following options:

Option Description
--help -h Display help
--enable-debug-logging Enable debug logging in all modules
--enable-openssl Enable OpenSSL crypto engine
--enable-nss Enable NSS crypto engine
--enable-openssl-kdf Enable OpenSSL KDF algorithm
--enable-log-stdout Enable logging to stdout
--with-openssl-dir Location of OpenSSL installation
--with-nss-dir Location of NSS installation
--with-log-file Use file for logging

By default there is no log output, logging can be enabled to be output to stdout
or a given file using the configure options.

This package has been tested on the following platforms: Mac OS X
(powerpc-apple-darwin1.4), Cygwin (i686-pc-cygwin), Solaris
(sparc-sun-solaris2.6), RedHat Linux 7.1 and 9 (i686-pc-linux), and
OpenBSD (sparc-unknown-openbsd2.7).


Changing Build Configuration

To build the ./configure script mentioned above, libSRTP relies on the
automake toolchain. Since
./configure is built from configure.in by automake, if you make changes in
how ./configure works (e.g., to add a new library dependency), you will need
to rebuild ./configure and commit the updated version. In addition to
automake itself, you will need to have the pkgconfig tools installed as well.

For example, on macOS:

brew install automake pkgconfig
# Edit configure.in
autoremake -ivf

Using Visual Studio

On Windows one can use Visual Studio via CMake. CMake can be downloaded here:
https://cmake.org/ . To create Visual Studio build files, for example run the
following commands:

# Create build subdirectory
mkdir build
cd build

# Make project files
cmake .. -G "Visual Studio 15 2017"

# Or for 64 bit project files
cmake .. -G "Visual Studio 15 2017 Win64"

Using Meson

On all platforms including Windows, one can build using Meson.
Steps to download Meson are here: https://mesonbuild.com/Getting-meson.html

To build with Meson, you can do something like:

# Setup the build subdirectory
meson setup --prefix=/path/to/prefix builddir

# Build the project
meson compile -C builddir

# Run tests
meson test -C builddir

# Optionally, install
meson install -C builddir

To build with Visual Studio, run the above commands from inside a Visual Studio
command prompt, or run vcvarsall.bat with the appropriate arguments inside
a Command Prompt.

Note that you can also replace the above commands with the appropriate ninja
targets: ninja -C build, ninja -C build test, ninja -C build install.


Applications

Several test drivers and a simple and portable srtp application are
included in the test/ subdirectory.

Test driver Function tested
kernel_driver crypto kernel (ciphers, auth funcs, rng)
srtp_driver srtp in-memory tests (does not use the network)
rdbx_driver rdbx (extended replay database)
roc_driver extended sequence number functions
replay_driver replay database
cipher_driver ciphers
auth_driver hash functions

The app rtpw is a simple rtp application which reads words from
/usr/dict/words and then sends them out one at a time using [s]rtp.
Manual srtp keying uses the -k option; automated key management
using gdoi will be added later.

usage:

rtpw [[-d <debug>]* [-k|b <key> [-a][-e <key size>][-g]] [-s | -r] dest_ip dest_port] | [-l]

Either the -s (sender) or -r (receiver) option must be chosen. The
values dest_ip, dest_port are the IP address and UDP port to which
the dictionary will be sent, respectively.

The options are:

Option Description
-s (S)RTP sender - causes app to send words
-r (S)RTP receive - causes app to receive words
-k use SRTP master key , where the key is a hexadecimal (without the leading "0x")
-b same as -k but with base64 encoded key
-e encrypt/decrypt (for data confidentiality) (requires use of -k option as well) (use 128, 192, or 256 for keysize)
-g use AES-GCM mode (must be used with -e)
-a message authentication (requires use of -k option as well)
-l list the available debug modules
-d turn on debugging for module

In order to get random 30-byte values for use as key/salt pairs , you
can use the following bash function to format the output of
/dev/random (where that device is available).

function randhex() {
   cat /dev/random | od --read-bytes=32 --width=32 -x | awk '{ print $2 $3 $4 $5 $6 $7 $8 $9 $10 $11 $12 $13 $14 $15 $16 }'
}

An example of an SRTP session using two rtpw programs follows:

set k=c1eec3717da76195bb878578790af71c4ee9f859e197a414a78d5abc7451

[sh1]$ test/rtpw -s -k $k -e 128 -a 0.0.0.0 9999
Security services: confidentiality message authentication
set master key/salt to C1EEC3717DA76195BB878578790AF71C/4EE9F859E197A414A78D5ABC7451
setting SSRC to 2078917053
sending word: A
sending word: a
sending word: aa
sending word: aal
...

[sh2]$ test/rtpw -r -k $k -e 128 -a 0.0.0.0 9999
security services: confidentiality message authentication
set master key/salt to C1EEC3717DA76195BB878578790AF71C/4EE9F859E197A414A78D5ABC7451
19 octets received from SSRC 2078917053 word: A
19 octets received from SSRC 2078917053 word: a
20 octets received from SSRC 2078917053 word: aa
21 octets received from SSRC 2078917053 word: aal
...

Example Code

This section provides a simple example of how to use libSRTP. The
example code lacks error checking, but is functional. Here we assume
that the value ssrc is already set to describe the SSRC of the stream
that we are sending, and that the functions get_rtp_packet() and
send_srtp_packet() are available to us. The former puts an RTP packet
into the buffer and returns the number of octets written to that
buffer. The latter sends the RTP packet in the buffer, given the
length as its second argument.

srtp_t session;
srtp_policy_t policy;

// Set key to predetermined value
uint8_t key[30] = {0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
                   0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F,
                   0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
                   0x18, 0x19, 0x1A, 0x1B, 0x1C, 0x1D};

// initialize libSRTP
srtp_init();

// default policy values
memset(&policy, 0x0, sizeof(srtp_policy_t));

// set policy to describe a policy for an SRTP stream
srtp_crypto_policy_set_rtp_default(&policy.rtp);
srtp_crypto_policy_set_rtcp_default(&policy.rtcp);
policy.ssrc = ssrc;
policy.key  = key;
policy.next = NULL;

// allocate and initialize the SRTP session
srtp_create(&session, &policy);

// main loop: get rtp packets, send srtp packets
while (1) {
  char rtp_buffer[2048];
  size_t len;

  len = get_rtp_packet(rtp_buffer);
  srtp_protect(session, rtp_buffer, &len);
  send_srtp_packet(rtp_buffer, len);
}

Credits

The original implementation and documentation of libSRTP was written
by David McGrew of Cisco Systems, Inc. in order to promote the use,
understanding, and interoperability of Secure RTP. Michael Jerris
contributed support for building under MSVC. Andris Pavenis
contributed many important fixes. Brian West contributed changes to
enable dynamic linking. Yves Shumann reported documentation bugs.
Randell Jesup contributed a working SRTCP implementation and other
fixes. Steve Underwood contributed x86_64 portability changes. We also give
thanks to Fredrik Thulin, Brian Weis, Mark Baugher, Jeff Chan, Bill
Simon, Douglas Smith, Bill May, Richard Preistley, Joe Tardo and
others for contributions, comments, and corrections.

This reference material, when applicable, in this documenation was generated
using the doxygen utility for automatic documentation of source code.

Copyright 2001-2005 by David A. McGrew, Cisco Systems, Inc.


References

SRTP and ICM References
September, 2005

Secure RTP is defined in RFC 3711.
The counter mode definition is in Section 4.1.1.

SHA-1 is defined in FIPS PUB 180-4.

HMAC is defined in RFC 2104
and HMAC-SHA1 test vectors are available
in RFC 2202.

AES-GCM usage in SRTP is defined in RFC 7714

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