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Shairport Sync

Shairport Sync is an AirPlay audio player -- it plays audio streamed from iTunes, iOS devices and third-party AirPlay sources such as ForkedDaapd and others. Audio played by a Shairport Sync-powered device stays synchronised with the source and hence with similar devices playing the same source. In this way, synchronised multi-room audio is possible without difficulty. (Hence the name Shairport Sync, BTW.)

Shairport Sync does not support AirPlay video or photo streaming.

This branch -- "master" -- is the stable branch of Shairport Sync. To access the development version, please switch to the "development" branch.

More Information

Shairport Sync works by using timing information and timestamps present in data coming from the audio source (e.g. an iPhone) to "play" audio at exactly the right time. It does this by monitoring and controlling the latency — the time between a sound frame is supposed to be played, as specified by its timestamp, and the time when it is actually played by the audio output device, usually a Digital to Audio Converter (DAC). Timestamps are measured relative to the source computer's clocks, the source clock, but timing must be done relative to the clock of the computer running Shairport Sync, the local clock. The source and local clocks are synchronised, usually to within a fraction of a millisecond, using a variant of NTP synchronisation protocols.

To maintain the exact latency required, if an output device is running slow relative to the source, Shairport Sync will delete frames of audio to allow the device to keep up. If the output device is running fast, Shairport Sync will insert frames to keep time. The number of frames inserted or deleted is so small as to be almost inaudible on normal audio material. Frames are inserted or deleted as necessary at pseudorandom intervals. Alternatively, with libsoxr support, Shairport Sync can resample the audio feed to ensure the output device can keep up. This is less obtrusive than insertion and deletion but requires a good deal of processing power — most embedded devices probably can't support it. The process of insertion/deletion or resampling is rather inelegantly called “stuffing”.

The exact latency to be used is specified by the source when it negotiates with Shaiport Sync. Most sources set a latency of 88,200 frames -- exactly two seconds. Recent versions of iTunes and forkedDaapd use a latency of 99,577 frames (pretty close to the 99,400 frames estimated from listening tests!).

Shairport Sync is a pretty substantial rewrite of the fantastic work done in Shairport 1.0 by James Laird and others — please see https://github.com/abrasive/shairport/blob/master/README.md#contributors-to-version-1x for a list of the contributors to Shairport 1.x and Shairport 0.x. From a "heritage" point of view, Shairport Sync is a fork of Shairport 1.0.

Shairport Sync is mainly designed for alsa and thus for Linux, although since alsa has been ported to FreeBSD, Shairport Sync runs in FreeBSD too. It must have direct access to the output device, which must be a real sound card capable of working with 44,100 samples per second interleaved PCM stereo (you'll get a message in the logfile if there's a problem).

For more about the motivation behind Shairport Sync, please see the wiki at https://github.com/mikebrady/shairport-sync/wiki.

What else?

  • Better Volume Control — Shairport Sync offers finer control at very top and very bottom of the volume range. See http://tangentsoft.net/audio/atten.html for a good discussion of audio "attenuators", upon which volume control in Shairport Sync is modelled. See also the diagram of the volume transfer function in the documents folder.
  • Hardware Mute — Shairport Sync will mute properly if the hardware supports it.
  • Fast Response — With hardware volume control, response is instantaneous; otherwise the response time is 0.15 seconds.
  • Non-Interruptible — Shairport Sync sends back a "busy" signal if it's already playing audio from another source, so other sources can't disrupt an existing Shairport Sync session. (If a source disappears without warning, the session automatically terminates after two minutes and the device becomes available again.)
  • Metadata — Shairport Sync can be configured to deliver metadata supplied by the source, such as Album Name, Artist Name, Cover Art, etc. through a pipe to a recipient application program — see https://github.com/mikebrady/shairport-sync-metadata-reader for a sample recipient. Sources that supply metadata include iTunes among others but the Music app in iOS 9 only supplies volume control metadata.
  • Raw Audio — Shairport Sync can deliver raw PCM audio to standard output or to a pipe. This output is delivered synchronously with the source after the appropriate latency and is not interpolated or "stuffed" on its way through Shairport Sync.
  • Autotools and Libtool Support — One important difference between Shairport Sync and other versions of Shairport is that the Shairport Sync build process uses GNU autotools and libtool to examine and configure the build environment — very important for cross compilation. Previous versions of Shairport looked at the current system to determine which packages were available, instead of looking at the target system for what packages were available.

Status

Shairport Sync works on a wide variety of Linux devices. It works on standard Ubuntu laptops, on the Raspberry Pi with Raspbian Wheezy and Jessie, Arch Linux and OpenWrt, and it runs on a Linksys NSLU2 and a TP-Link 710N using OpenWrt. It works with built-in audio and with a variety of USB-connected audio amplifiers and DACs, including a cheapo USB "3D Sound" dongle, a first generation iMic and a Topping TP30 amplifier with a USB DAC input. It will not work properly – if at all – with a PulseAudio (pseudo-)output device. Using a port of the alsa system, Shairport Sync runs rather well on FreeBSD.

Shairport Sync runs well on the Raspberry Pi. It can drive the built-in sound card, though the audio out of the card is of poor quality (see the note below on configuring the Raspberry Pi to make best use of it). USB-connected sound cards work well on recent versions of Raspbian; however older versions of Raspbian appear to suffer from a problem — see http://www.raspberrypi.org/forums/viewtopic.php?t=23544, so it is wise to update. Shairport Sync works well with the IQAudIO Pi-DAC — see http://www.iqaudio.com.

At the time of writing, OpenWrt trunk does not support USB audio well on the Raspberry Pi.

Shairport Sync runs on Ubuntu, OpenWrt, Debian, Arch Linux and Fedora inside VMWare Fusion on a Mac, but synchronisation in inaccurate — possibly because the soundcard is being emulated.

Shairport Sync will output to alsa cards, to standard output and to pipes using appropriate backends. You can try compiling additional backends in as you wish, but it definitely will not work properly with them. Maybe someday...

For information about changes and updates, please refer to the RELEASENOTES.md file in the distribution.

Note: Historically, Shairport Sync has taken its settings from command line arguments. While this is still the case, it does not always work well across distributions. Accordingly, from version 2.4 onwards, Shairport Sync reads settings from the file /etc/shairport-sync.conf. Access to new features will only be provided via the settings file.

Building And Installing

If you wish to install Shairport Sync on OpenWrt, Arch or Fedora platforms, please follow the appropriate instructions below. Otherwise follow the General Build Instructions. Then, when the program has been installed, refer to the section on Configuring Shairport Sync that follows.

Note The following procedures will install shairport-sync at /usr/local/bin/shairport-sync. Before continuing, you should check to see if shairport-sync is already installed on your system -- use which shairport-sync to find where it is located, if installed. If it is installed anywhere other than at /usr/local/bin/shairport-sync, you should delete it -- you may need to have superuser privileges.

OpenWrt: There is a Shairport Sync package in OpenWrt trunk. Also, there's an OpenWrt package at https://github.com/mikebrady/shairport-sync-for-openwrt, including one that builds back to Attitude Adjustment.

Arch Linux: An Arch Linux installation package is available at EliaCereda/shairport-sync-PKGBUILD.

Fedora: Install the toolchain and pre-requisites, if necessary:

% sudo yum install make automake gcc gcc-c++ kernel-devel
% sudo yum install alsa-lib-devel autoconf automake avahi-devel libconfig-devel libdaemon-devel openssl-devel popt-devel soxr-devel

Download the tarball from the "releases" tab on github or use wget and then use rpmbuild. This example is for version 2.6:

% wget -O shairport-sync-2.6.tar.gz https://github.com/mikebrady/shairport-sync/archive/2.6.tar.gz
% rpmbuild -ta shairport-sync-2.6.tar.gz

The -ta means "build all from this tarball".

The RPM will be built in a directory and will have a pathname like, for example, ~/rpmbuild/RPMS/i686/shairport-sync-2.6-1.fc22.i686.rpm You should then install it with (for this example):

%sudo rpm -i ~/rpmbuild/RPMS/i686/shairport-sync-2.6-1.fc22.i686.rpm

You may have to manually create the directory /var/shairport-sync for the installation to succeed. Having edited the configuration file /etc/shairport-sync.conf as appropriate (see "Configuring Shairport Sync" below), enable and start the service with:

%sudo systemctl enable shairport-sync.service
%sudo systemctl start shairport-sync.service

Sincere thanks to all package contributors!

General Build Instructions

To build Shairport Sync from sources on Debian, Ubuntu, Raspbian, etc. follow these instructions.

The following libraries are required:

  • OpenSSL or PolarSSL
  • Avahi
  • ALSA
  • libdaemon
  • autoconf
  • libtool
  • libpopt
  • libconfig

Optional:

  • libsoxr

Many Linux distributions have Avahi and OpenSSL already in place, so normally it probably makes sense to choose those options rather than tinysvcmdns or PolarSSL. Libsoxr is available in recent Linux distributions, but it requires lots of processor power — chances are an embedded processor won't be able to keep up.

Assuming the usual build essentials and git, Debian, Ubuntu and Raspbian users can get the basics with:

  • apt-get install autoconf libtool libdaemon-dev libasound2-dev libpopt-dev libconfig-dev
  • apt-get install avahi-daemon libavahi-client-dev if you want to use Avahi (recommended).
  • apt-get install libssl-dev if you want to use OpenSSL and libcrypto, or use PolarSSL otherwise.
  • apt-get install libpolarssl-dev if you want to use PolarSSL, or use OpenSSL/libcrypto otherwise.
  • apt-get install libsoxr-dev if you want support for libsoxr-based resampling. This library is not yet part of Raspbian; instructions for how to build it from source are available at LIBSOXR.md.

Download Shairport Sync:

git clone https://github.com/mikebrady/shairport-sync.git

Next, cd into the shairport-sync directory and execute the following command:

$ autoreconf -i -f

Choose the appropriate --with-* options:

  • --with-alsa for the ALSA audio back end. This is required.
  • --with-stdout include an optional backend module to enable raw audio to be output through standard output (stdout).
  • --with-pipe include an optional backend module to enable raw audio to be output through a unix pipe.
  • --with-avahi or --with-tinysvcmdns for mdns support. Avahi is a widely-used system-wide zero-configuration networking (zeroconf) service — it may already be in your system. If you don't have Avahi, or similar, then consider including tinysvcmdns, which is a tiny zeroconf service embedded inside the shairport-sync application itself. To enable multicast for tinysvcmdns, you may have to add a default route with the following command: route add -net 224.0.0.0 netmask 224.0.0.0 eth0 (substitute the correct network port for eth0). You should not have more than one zeroconf service on the same system — bad things may happen, according to RFC 6762, §15.
  • --with-ssl=openssl or --with-ssl=polarssl for encryption and related utilities using either OpenSSL or PolarSSL.
  • --with-soxr for libsoxr-based resampling.
  • --with-piddir for specifying where the PID file should be stored. This directory is normally chosen automatically. The directory must be writable. If you use this option, you may have to edit the init script to search for the PID file in your new location.
  • --with-metadata to add support for Shairport Sync to pipe metadata to a compatible application of your choice. See https://github.com/mikebrady/shairport-sync-metadata-reader for a sample metadata reader.
  • --with-systemv to install a System V init script at the make install stage. Default is not to to install.
  • --with-systemd to install a systemd service description at the make install stage. Default is not to to install.
  • --with-configfile to install a configuration file and a separate sample file at the make install stage. Default is to install. An existing /etc/shairport-sync.conf will not be overwritten.
  • --with-pkg-config to use pkg-config to find libraries. Default is to use pkg-config — this option is for special purpose use.

System V and systemd

At the time of writing, there are two general systems for automatically starting programs automatically at startup: "System V" or systemd. To see if the systemd process is running on your system, enter the following command:

ps aux | grep systemd | grep -v grep

On a system using systemd (this is a Raspberry Pi running Raspbian Jessie) you'll get many lines containing systemd, for example:

pi@raspberrypi ~ $ ps aux | grep systemd | grep -v grep
root        90  0.1  0.6   8088  2764 ?        Ss   08:00   0:01 /lib/systemd/systemd-journald
root        93  0.0  0.6  11816  3004 ?        Ss   08:00   0:00 /lib/systemd/systemd-udevd
root       502  0.0  0.5   3824  2436 ?        Ss   08:00   0:00 /lib/systemd/systemd-logind
message+   528  0.0  0.7   5568  3172 ?        Ss   08:00   0:01 /usr/bin/dbus-daemon --system --address=systemd: --nofork --nopidfile --systemd-activation
pi         983  0.0  0.7   4912  3256 ?        Ss   08:00   0:00 /lib/systemd/systemd --user
pi@raspberrypi ~ $ 

whereas on a system without systemd -- presumably using System V -- (this is a Raspberry Pi running Raspbian Wheezy) , you'll get nothing:

pi@raspberrypi ~ $ ps aux | grep systemd | grep -v grep
pi@raspberrypi ~ $ 

Choose --with-systemd or --with-systemv on the basis of the outcome.

Here is an example, suitable for installations such as Ubuntu and Raspbian:

$ ./configure --with-alsa --with-avahi --with-ssl=openssl --with-metadata --with-soxr --with-systemv

  • Omit the --with-soxr if the libsoxr library is not available.
  • For installation into a systemd system, replace the --with-systemv with --with-systemd.

Enter:

$ make

to build the application.

Installation to a System V system If you are installing onto a System V system:

$sudo make install

to install shairport-sync along with a man page, a default configuration file and a System V startup script to launch it automatically at system startup.

To complete the installation, enter:

$sudo update-rc.d shairport-sync defaults 90 10

Installation to a systemd system To complete the installation, you need to define a shairport-sync group and user. This is a security measure -- the user and group are relatively unprivileged, and the user does not have login priviliges. The user must be a member of the audio group to be able to access the audio hardware. The following commands define the group and user correctly if they do not already exist (note the use of sudo -- omit this if you already have superuser privileges:

$getent group shairport-sync &>/dev/null || sudo groupadd -r shairport-sync >/dev/null
$getent passwd shairport-sync &> /dev/null || sudo useradd -r -M -g shairport-sync -s /usr/bin/nologin -G audio shairport-sync >/dev/null

Next, enter:

$sudo make install

to install shairport-sync along with a man page, a default configuration file and a systemd configuration file called shairport-sync.service to launch it automatically at system startup.

To enable Shairport Sync to start automatically at system startup, enter:

$sudo systemctl enable shairport-sync

Man Page

You can view the man page here: http://htmlpreview.github.io/?https://github.com/mikebrady/shairport-sync/blob/master/man/shairport-sync.html

Configuring Shairport Sync

There are two logically distinct parts to getting Shairport Sync to run properly on your machine — (1) starting and stopping it and (2) ensuring it has the right settings.

Starting and stopping automatically is taken care of differently in different versions of Linux -- see the previous section for an example of installing into a System V or a systemd based system.

To get the best from Shairport Sync, you’ll need to (1) give Shairport Sync a service name by which it will be seen in iTunes etc., (2) specify the output device to use and (3) specify the name of the mixer volume control to use to control the output level. To get values for (2) and (3) you might need to explore the ALSA output devices with a program like alsamixer or similar.

Shairport Sync reads settings from a configuration file at /etc/shairport-sync.conf. While it can also take configuration settings from command line options, it is recommended that you use the configuration file method. When you run $sudo make install, a default configuration is installed at /etc/shairport-sync.conf (it won't replace an existing one) which should work in almost any system with a sound card.

A sample configuration file is installed (or updated) at /etc/shairport-sync.conf.sample. This contains all the setting groups and all the settings available, but they all are commented out (comments begin with //) so that default values are used. The file contains explanations of the settings, useful hints and suggestions.

Settings in the configuration file are grouped. For instance, there is a general group within which you can use the name tag to set the service name. Suppose you wanted to set the name of the service to Front Room, give the service the password secret and used libsoxr interpolation, then you should do the following:

general =
{
	name = "Front Room";
	password = "secret";
	interpolation = "soxr";
	// ... other general settings
};

The alsa group is used to specify properties of the output device. The most obvious setting is the name of the output device which you can set using the output_device tag.

The following alsa group settings are very important for maximum performance. If your audio device has a mixer that can be use to control the volume, then Shairport Sync can use it to give instant response to volume and mute commands and it can offload some work from the processor.

  • The mixer_control_name tag allows you to specify the name of the mixer volume control.
  • The mixer_device tag allows you specify where the mixer is. By default, the mixer is on the output_device, so you only need to use the mixer_device tag if the mixer is elsewhere. This can happen if you specify a device rather than a card with the output_device tag, because normally a mixer is associated with a card rather than a device. Suppose you wish to use the output device 5 of card hw:0 and the mixer volume-control named PCM:
alsa =
{
  output_device = "hw:0,5";
  mixer_device = "hw:0";
  mixer_control_name = "PCM";
  // ... other alsa settings
};

Shairport Sync can run programs just before it starts to play an audio stream and just after it finishes. You specify them using the sessioncontrol group settings run_this_before_play_begins and run_this_after_play_ends. This is to facilitate situations where something has to be done before and after playing, e.g. switching on an amplifier beforehand and switching it off afterwards. Set the wait_for_completion value to "yes" for Shairport Sync to wait until the respective commands have been completed before continuing.

Please note that the full path to the programs must be specified, and script files will not be executed unless they are marked as executable and have the standard #!/bin/... first line. (This behaviour may be different from other Shairports.)

Raspberry Pi The Raspberry Pi has a built-in audio DAC that is connected to the device's headphone jack. This provides a low-quality output that is nevertheless useful for testing purposes and may be adequate for [very] casual listening. It is not HiFi -- it is quite noisy and can't play anything above about 15kHz. A further problem is that it declares itself to have a very large mixer volume control range -- all the way from -102.38dB up to +4dB, a range of 106.38 dB. In reality, only the top 35dB of it is in any way usable. To help get the most from the DAC, consider using the volume_range_db setting in the general stanza to instruct Shairport Sync to use the top of the DAC mixer's declared range. For example, if you set the volume_range_db figure to 35, the top 35 dB of the range will the used. With this setting on the Raspberry Pi, maximum volume will be +4dB and minimum volume will be -31dB, below which muting will occur.

From a user's point of view, the effect of using this setting is to move the minimum usable volume all the way down to the bottom of the user's volume control, rather than have the minimum usable volume concentrated very close to the maximum volume.

Command Line Arguments

You can use command line arguments to provide settings to Shairport Sync as before. For full information, please read the Shairport Sync man page, also available at http://htmlpreview.github.io/?https://github.com/mikebrady/shairport-sync/blob/master/man/shairport-sync.html.

Apart from the following options, all command line options can be replaced by settings in the configuration file. Here is a brief description of command line options that are not replicated by settings in the settings file.

  • The -c option allows you to specify the location of the configuration file — default is /etc/shairport-sync.conf.
  • The -V option gives you version information about Shairport Sync and then quits.
  • The -d option causes Shairport Sync to properly daemonise itself, that is, to run in the background. You may need sudo privileges for this.
  • The -k option causes Shairport Sync to kill an existing Shairport Sync daemon. You may need to have sudo privileges for this.

The System V init script at /etc/init.d/shairport-sync has a bare minimum : -d. Basically all it does is put the program in daemon mode. The program will read its settings from the configuration file, normally /etc/shairport-sync.conf.

Examples

Here are some examples of complete configuration files.

general = {
  name = "Joe's Stereo";
};

alsa = {
  output_device = "hw:0";
};

This gives the service a particular name — "Joe's Stereo" and specifies that audio device hw:0 be used.

For best results — including getting true mute and instant response to volume control and pause commands — you should access the hardware volume controls. Use amixer or alsamixer or similar to discover the name of the mixer control to be used as the mixer_control_name.

Here is an example for for a Raspberry Pi using its internal soundcard — device hw:0 — that drives the headphone jack:

general = {
  name = "Mike's Boombox";
};

alsa = {
  output_device = "hw:0";
  mixer_control_name = "PCM";
};

Here is an example of using soxr-based resampling and driving a Topping TP30 Digital Amplifier, which has an integrated USB DAC and which is connected as audio device hw:1:

general = {
  name = "Kitchen";
  interpolation = "soxr";
};

alsa = {
  output_device = "hw:1";
  mixer_control_name = "PCM";
};

For a cheapo "3D Sound" USB card (Stereo output and input only) on a Raspberry Pi:

general = {
  name = "Front Room";
};

alsa = {
  output_device = "hw:1";
  mixer_control_name = "Speaker";
};

For a first generation Griffin iMic on a Raspberry Pi:

general = {
  name = "Attic";
};

alsa = {
  output_device = "hw:1";
  mixer_control_name = "PCM";
};

For an NSLU2, which has no internal soundcard, there appears to be a bug in ALSA — you can not specify a device other than "default". Thus:

On an NSLU2, to drive a first generation Griffin iMic:

general = {
  name = "Den";
};

alsa = {
  mixer_control_name = "PCM";
};

On an NSLU2, to drive the "3D Sound" USB card:

general = {
  name = "TV Room";
};

alsa = {
  mixer_control_name = "Speaker";
};

Latency

Latency is the exact time from a sound signal's original timestamp until that signal actually "appears" on the output of the audio output device, usually a Digital to Audio Converter (DAC), irrespective of any internal delays, processing times, etc. in the computer.

Shairport Sync uses latencies supplied by the source, typically either 88,200 or 99,577 frames. You shouldn't need to change them. (The latencies stanza in the configuration file and the various latency command-line options are deprecated.)

Problems can arise when you are trying to synchronise with speaker systems — typically surround-sound home theatre systems — that have their own inherent delays. You can compensate for an inherent delay using the appropriate backend (typically alsa) audio_backend_latency_offset. Set this offset (in frames) to compensate for a fixed delay in the audio back end, for example, if the output device delays by 100 ms, set this to -4410.

Resynchronisation

Shairport Sync actively maintains synchronisation with the source. If synchronisation is lost — say due to a busy source or a congested network — Shairport Sync will mute its output and resynchronise. The loss-of-sync threshold is a very conservative 50 ms — i.e. the actual time and the expected time must differ by more than 50 ms to trigger a resynchronisation. Smaller disparities are corrected by insertions or deletions, as described above.

  • You can vary the resync threshold, or turn resync off completely, with the general resync_threshold setting.

Tolerance

Playback synchronisation is allowed to wander, or to "drift") a small amount before attempting to correct it. The default is 88 frames, i.e. 2 ms. The smaller the tolerance, the more likely it is that overcorrection will occur. Overcorrection is when more corrections (insertions and deletions) are made than are strictly necessary to keep the stream in sync. Use the statistics setting to monitor correction levels. Corrections should not greatly exceed net corrections.

  • You can vary the tolerance with the general drift setting.

Some Statistics

If you turn on the general statistics setting, statistics like this will be printed at intervals on the console (or in the logfile if running in daemon mode):

Sync error: -35.4 (frames); net correction: 24.2 (ppm); corrections: 24.2 (ppm); missing packets 0; late packets 5; too late packets 0; resend requests 6; min DAC queue size 4430.

"Sync error" is the average deviation from exact synchronisation. The example above indicates that the output is on average 35.4 frames ahead of exact synchronisation. Sync is allowed to drift by the general drift setting — 88 frames (± 2 milliseconds) by default — before a correction will be made.

"Net correction" is actually the net sum of corrections — the number of frame insertions less the number of frame deletions — given as a moving average in parts per million. After an initial settling period, it represents the drift — the divergence between the rate at which frames are generated at the source and the rate at which the output device consumes them. The example above indicates that the output device is consuming frames 24.2 ppm faster than the source is generating them.

"Corrections" is the number of frame insertions plus the number of frame deletions (i.e. the total number of corrections), given as a moving average in parts per million. The closer this is to the net corrections, the fewer "unnecessary" corrections that are being made. Third party programs tend to have much larger levels of corrections.

For reference, a drift of one second per day is approximately 11.57 ppm. Left uncorrected, even a drift this small between two audio outputs will be audible after a short time. The above sample is from a second-generation iPod driving the Raspberry Pi which is connected over Ethernet.

It's not unusual to have resend requests, late packets and even missing packets if some part of the connection to the Shairport Sync device is over WiFi. Late packets can sometimes be asked for and received multiple times. Sometimes late packets are sent and arrive too late, but have already been sent and received in time, so weren't needed anyway...

"Min DAC queue size" is the minimum size the queue of samples in the output device's hardware buffer was measured at. It is meant to stand at 0.15 seconds = 6,615 samples, and will go low if the processor is very busy. If it goes below about 2,000 then it's a sign that the processor can't really keep up.

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