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Csound

Csound is a domain-specific computer programming language for audio programming. It is called Csound because it is written in C, as opposed to some of its predecessors.

Initial release

1986 (1986)[1]

6.18.1 / November 24, 2022 (2022-11-24)[2]

C

It is free software, available under the LGPL-2.1-or-later.


Csound was originally written at MIT by Barry Vercoe in 1985, based on his earlier system called Music 11, which in its turn followed the MUSIC-N model initiated by Max Mathews at the Bell Labs. Its development continued throughout the 1990s and 2000s, led by John Fitch at the University of Bath. The first documented version 5 release is version 5.01 on March 18, 2006. Many developers have contributed to it, most notably Istvan Varga, Gabriel Maldonado, Robin Whittle, Richard Karpen, Iain McCurdy, Michael Gogins, Matt Ingalls, Steven Yi, Richard Boulanger, Victor Lazzarini and Joachim Heintz.


Developed over many years, it currently has nearly 1700 unit generators. One of its greatest strengths is that it is completely modular and extensible by the user. Csound is closely related to the underlying language for the Structured Audio extensions to MPEG-4, SAOL.

Csound 5[edit]

Version 5.01 was released on March 18, 2006 – 20 years after csound's first release. Csound 5 is available in binary and source code for Linux, Microsoft Windows and Mac OS X from the SourceForge Csound project.[3] It is much improved and expanded compared to the original software, effectively made into a software library with an API. A variety of front ends have been developed for it. In addition to the basic C API, there are also Python, Java, Lisp, Tcl and C++ among other bindings, like one from Haskell which allows control of Csound from a purely functional environment.


The use of plug-ins allows additional capabilities without modifications to the Csound code, as there is the possibility to write user-defined opcodes as extensions to the original language. LADSPA and DSSI are supported, but VST support has been removed.


Real-time performance through MIDI was added in the 1990s. Another addition was the support of FLTK widgets (graphical interface components with sliders, knobs, etc.) for controlling real-time audio, and integration of custom graphical interfaces written in Python.

A /flex based parser for the Csound language is now standard. It generates an abstract syntax tree that is accessible via the Csound API. The tree can then be compiled to a Csound performance runtime using the API. Therefore, after the tree has been compiled, it can be manipulated by user code before compiling it to a Csound performance runtime. Alternatively, the user could create the entire abstract syntax tree from another language, then compile the tree to a Csound performance runtime.

bison

There is a new built-in multi-dimensional array type. Arrays can be passed to instruments and opcodes. Arithmetic may be performed directly on arrays.

There is a new type system that enables user-defined types to be used in the Csound language.

The orchestra can be re-compiled at any time, or individual instruments can be compiled at any time, during a running performance. This enables true "live coding" in Csound performances.

The Csound API has been rationalized and simplified.

Csound can take advantage of any number of CPUs for concurrent processing during performance. This occurs without any changes to Csound code. This produces substantial speedups of most Csound processing. For example, a piece that renders in 100 seconds with 1 core should render in about 50 seconds with 4 cores.

Csound can compile orchestras and scores directly from strings of text, enabling the use of Csound in environments where writing to the file system is not permitted.

Score events such as notes can be scheduled to sample accurate times, even if synthesis is processed in blocks of samples.

All opcodes that return a single value may be used as functions in the orchestra language.

Audio analysis file formats can be byte-order independent.

A single score statement can contain multiple string parameters.

Most oscillator opcodes will use an internal sine function table if the table number is omitted.

Command-line options can be set programmatically using the Csound API.

Numerous duplicate areas of code within Csound have been rationalized.

An Android app was built which provides user-defined graphical user interfaces and JavaScript-based algorithmic composition using HTML5.

Csound 6 has been in development since its features were hashed out at the Csound Conference held in 2011 in Hanover. Csound 6 was released in July 2013 and is now available on GitHub.[4] Csound 6 is also available for Android. The major new features of Csound 6 include:


The development of Csound 6 was led by John Fitch, Steven Yi and Victor Lazzarini.

Csound for live performance[edit]

Currently only Csound score or note events can be generated in real time (as opposed to instruments, which are only definable at compile time, when csound first starts; in Csound 6 this limitation is removed). The set of sound processors is defined and compiled at load time, but the individual processing objects can be spawned or destroyed in real time, input audio processed in real time, and output generated also in real time. Note events can be triggered based on OSC communications within an instrument instance, spawned by MIDI, or entered to stdin (by typing into a terminal or sending textual statements from another program). The use of Csound 5 as a live performance tool can be augmented with a variety of third-party software. Live Event Sheet within CsoundQt can be used to modify the score in real-time. In addition, interfaces to other programming languages can be used to script Csound. A paper detailing the use of Csound with Qt or Pure Data in real-time musical synthesis was presented at the 2012 Linux Audio Conference [5] The Ounk project attempts to integrate Python with Csound while CsoundAC provides a way to do algorithmic composition from Python using Csound as backend. Audivation's Csound for Live packages various opcodes into Max/MSP wrappers suitable for use in Ableton Live.[6][7] Csound is also available for mobile systems (iOS, Android).[8]

One Laptop per Child (OLPC)[edit]

Csound5 was chosen to be the audio/music development system for the OLPC project on the XO-1 Laptop platform.[9]

Audio signal processing

Software synthesizer

Computer music

Comparison of audio synthesis environments

List of music software

Richard Charles Boulanger, ed. (2000). The Csound Book: Perspectives in Software Synthesis, Sound Design, Signal Processing, and Programming. MIT Press.  978-0-262-52261-8.

ISBN

R. Bianchini; A Cipriani. (2000). Virtual Sound. Sound Synthesis and Signal Processing. Theory and Practice with Csound. ConTempo s.a.s.  88-900261-1-1.

ISBN

Richard Charles Boulanger and Victor Lazzarini, ed. (2011). The Audio Programming Book. MIT Press.  978-0-262-01446-5. This is a book mostly about programming sound directly using the C language, but it does have a couple of chapters about programming Csound opcodes.

ISBN

Jim Aikin (2013). Csound Power! The Comprehensive Guide. Cengage Learning.  1-4354-6005-7.

ISBN

Official website