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- == Opus audio codec ==
- Opus is a codec for interactive speech and audio transmission over the Internet.
- Opus can handle a wide range of interactive audio applications, including
- Voice over IP, videoconferencing, in-game chat, and even remote live music
- performances. It can scale from low bit-rate narrowband speech to very high
- quality stereo music.
- Opus, when coupled with an appropriate container format, is also suitable
- for non-realtime stored-file applications such as music distribution, game
- soundtracks, portable music players, jukeboxes, and other applications that
- have historically used high latency formats such as MP3, AAC, or Vorbis.
- Opus is specified by IETF RFC 6716:
- https://tools.ietf.org/html/rfc6716
- The Opus format and this implementation of it are subject to the royalty-
- free patent and copyright licenses specified in the file COPYING.
- This package implements a shared library for encoding and decoding raw Opus
- bitstreams. Raw Opus bitstreams should be used over RTP according to
- https://tools.ietf.org/html/rfc7587
- The package also includes a number of test tools used for testing the
- correct operation of the library. The bitstreams read/written by these
- tools should not be used for Opus file distribution: They include
- additional debugging data and cannot support seeking.
- Opus stored in files should use the Ogg encapsulation for Opus which is
- described at:
- https://tools.ietf.org/html/rfc7845
- An opus-tools package is available which provides encoding and decoding of
- Ogg encapsulated Opus files and includes a number of useful features.
- Opus-tools can be found at:
- https://git.xiph.org/?p=opus-tools.git
- or on the main Opus website:
- https://opus-codec.org/
- == Compiling libopus ==
- To build from a distribution tarball, you only need to do the following:
- % ./configure
- % make
- To build from the git repository, the following steps are necessary:
- 0) Set up a development environment:
- On an Ubuntu or Debian family Linux distribution:
- % sudo apt-get install git autoconf automake libtool gcc make
- On a Fedora/Redhat based Linux:
- % sudo dnf install git autoconf automake libtool gcc make
- Or for older Redhat/Centos Linux releases:
- % sudo yum install git autoconf automake libtool gcc make
- On Apple macOS, install Xcode and brew.sh, then in the Terminal enter:
- % brew install autoconf automake libtool
- 1) Clone the repository:
- % git clone https://git.xiph.org/opus.git
- % cd opus
- 2) Compiling the source
- % ./autogen.sh
- % ./configure
- % make
- 3) Install the codec libraries (optional)
- % sudo make install
- Once you have compiled the codec, there will be a opus_demo executable
- in the top directory.
- Usage: opus_demo [-e] <application> <sampling rate (Hz)> <channels (1/2)>
- <bits per second> [options] <input> <output>
- opus_demo -d <sampling rate (Hz)> <channels (1/2)> [options]
- <input> <output>
- mode: voip | audio | restricted-lowdelay
- options:
- -e : only runs the encoder (output the bit-stream)
- -d : only runs the decoder (reads the bit-stream as input)
- -cbr : enable constant bitrate; default: variable bitrate
- -cvbr : enable constrained variable bitrate; default:
- unconstrained
- -bandwidth <NB|MB|WB|SWB|FB>
- : audio bandwidth (from narrowband to fullband);
- default: sampling rate
- -framesize <2.5|5|10|20|40|60>
- : frame size in ms; default: 20
- -max_payload <bytes>
- : maximum payload size in bytes, default: 1024
- -complexity <comp>
- : complexity, 0 (lowest) ... 10 (highest); default: 10
- -inbandfec : enable SILK inband FEC
- -forcemono : force mono encoding, even for stereo input
- -dtx : enable SILK DTX
- -loss <perc> : simulate packet loss, in percent (0-100); default: 0
- input and output are little-endian signed 16-bit PCM files or opus
- bitstreams with simple opus_demo proprietary framing.
- == Testing ==
- This package includes a collection of automated unit and system tests
- which SHOULD be run after compiling the package especially the first
- time it is run on a new platform.
- To run the integrated tests:
- % make check
- There is also collection of standard test vectors which are not
- included in this package for size reasons but can be obtained from:
- https://opus-codec.org/docs/opus_testvectors-rfc8251.tar.gz
- To run compare the code to these test vectors:
- % curl -OL https://opus-codec.org/docs/opus_testvectors-rfc8251.tar.gz
- % tar -zxf opus_testvectors-rfc8251.tar.gz
- % ./tests/run_vectors.sh ./ opus_newvectors 48000
- == Portability notes ==
- This implementation uses floating-point by default but can be compiled to
- use only fixed-point arithmetic by setting --enable-fixed-point (if using
- autoconf) or by defining the FIXED_POINT macro (if building manually).
- The fixed point implementation has somewhat lower audio quality and is
- slower on platforms with fast FPUs, it is normally only used in embedded
- environments.
- The implementation can be compiled with either a C89 or a C99 compiler.
- While it does not rely on any _undefined behavior_ as defined by C89 or
- C99, it relies on common _implementation-defined behavior_ for two's
- complement architectures:
- o Right shifts of negative values are consistent with two's
- complement arithmetic, so that a>>b is equivalent to
- floor(a/(2^b)),
- o For conversion to a signed integer of N bits, the value is reduced
- modulo 2^N to be within range of the type,
- o The result of integer division of a negative value is truncated
- towards zero, and
- o The compiler provides a 64-bit integer type (a C99 requirement
- which is supported by most C89 compilers).
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