Csound: Difference between revisions
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Csound is the music and audio signal processing language developed by [http://web.media.mit.edu/~bv/ MIT's Barry Vercoe] |
Csound is the music and audio signal processing language originally developed by [http://web.media.mit.edu/~bv/ MIT's Barry Vercoe] and now expanded and maintained by |
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a world-wide community, as Free Software [http://en.wikipedia.org/wiki/Free_Software]. Csound will provide audio services for the XO computer. |
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Csound is both a [[Programming languages|programming language]] and a sound synthesis engine. Csound, as included in the OLPC project, can be used by Activities or directly by children and teachers. It can be accessed in a variety of ways. In the XO platform, two basic ways are provided: |
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*Through the [[Python]] programming environment: eg. programmed in Activities. |
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*Through its 'classic' command-line frontend, directly invoking it from the Terminal activity. |
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Further information about Csound can be found on its official website: http://csounds.com/. The canonical Csound sources and multi-platform binaries are hosted by Sourceforge[http://csound.sf.net]. |
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== Activities == |
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Csound is both a [[Programming languages|programming language]] and a sound synthesis engine. It will be included on the OLPC to be used by applications or directly by the children. |
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* [[Csound:Csound Editor|Csound Editor]] - view, edit and perform Csound files |
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Further information about Csound is on their website: http://csounds.com/ |
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* [[Csound:Audio Loop Remixer|Audio Loop Remixer]] - perform audio loops and apply a variety of effects |
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* [[Csound:MIDI File Player|MIDI File Player]] - performs MIDI files using the donated General MIDI soundfont |
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* [[Csound:Instrument Player|Instrument Player]] - a keyboard interface to play a variety of instruments |
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* [[TamTam]] - Tam Tam uses Csound, but you would never know it as its interface is designed to wrap the Csound engine with a child-friendly look and feel. This excellent group of Activities allows kids to make sounds, make music, jam, record and transform their voices in an intuitive way. TamTam Edit allows students to patch together Csound's opcodes (modules) and teaches them all about signals, synthesis, and synthesizers. TamTam Activities demonstrate well how the power of Csound can be harnessed in the XO platform. |
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* [http://csounds.com/GregCsoundActivities.zip GregCsoundActivities.zip] - A number of Csound Server-based activities developed by Greg for Build 542 including a pretty cool Pitch-Tracker Bouncing Ball Activity and a Pitch Reverse Game – both lot's of fun for kids, but not currently supported by the latest builds and security models. |
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* [[Pippy]] - Pippy uses Csound to help teach children the Python programming language and to build XO Activities. |
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* [http://www.thumbuki.com/xo/step.activity.zip Step] - A simple 8-note step sequencer that children will use to play music and record their own loops for use in other sample-based activities. Step uses [[csndsugui]]. |
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* [http://wiki.laptop.org/go/Csound:Funny_Talk Funny Talk] - An activity that children can use to record their voices with the built-in microphone, and process them with effects such as reverb, echo, chorus, etc. Funny Talk allows a child to save their manipulated voices as soundfiles so that they can be used in other musical activities. Funny Talk uses [[csndsugui]]. |
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== OLPCsound Manual == |
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View the online OLPCsound manual here: |
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http://www.csounds.com/manualOLPC/ |
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Download the OLPCsound manual here: |
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http://www.csounds.com/manualOLPC/olpcsound5.08_manual.tar.gz |
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There's a content bundle for the XO which is installed the same as an activity and appears automatically in the Web Activity Library (the Web Activity default page). You can find it here: |
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http://www.csounds.com/manualOLPC/olpcsound5.08_manual.xol |
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Also in french: |
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http://www.csounds.com/manualOLPC/olpcsound5.08_manual-fr.xol |
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== Csound code and CSD files == |
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Csound code is most commonly written in the Unified Csound File format ([[CSD Files|CSD]]). This uses XML-like tags to contain the different code elements in sections. Two of these are required: orchestra (<CsInstruments>) and score (<CsScore>) contained within the <CsoundSynthesizer> tags. Here is a trivial instrument and score: |
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<CsoundSynthesizer> |
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<CsInstruments> |
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instr 1 |
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a1 oscili p4, p5, 1 |
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out a1 |
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endin |
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</CsInstruments> |
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<CsScore> |
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f1 0 16384 10 1 |
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i1 0 1 10000 440 |
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e |
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</CsScore> |
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</CsoundSynthesizer> |
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This will give you a nice 1-second sinewave beep. |
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== Orchestra and Score == |
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Csound is loosely based on the concept of an Orchestra, made up of Instruments, and a Score, made up of events, function table definitions etc.. Instruments contain the synthesis/processing code and the score the parameters to run these. In practice, you might not need a score, because |
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realtime events (from MIDI, from Python or from other Csound instruments), so in that case an empty or minimal one will do. |
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Instruments are written using a variety of opcodes (there are over 1000 of these), which are interconnected using audio signal (a-), control signal (k-), spectral signal(f-), initialisation (i-) and string (S-) variables. A slightly more interesting example shows some of these in operation: |
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<CsoundSynthesizer> |
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<CsInstruments> |
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instr 1 |
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idur = p3 |
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iamp = p4 |
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ifrq = cpspch(p5) |
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kenv expon 1, idur, 0.01 |
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asig oscili kenv*iamp, ifrq, 1 |
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out asig |
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endin |
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</CsInstruments> |
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<CsScore> |
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f1 0 16384 10 1 |
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i1 0 1 8000 8.00 |
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i1 + 1 12000 8.04 |
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i1 + 1 16000 8.07 |
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i1 + 2 24000 9.00 |
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e |
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</CsScore> |
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</CsoundSynthesizer> |
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What you should hear is an arpeggio of 'ping' sounds, a bit like a chime or |
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tuning fork, which is much more interesting than our previous attempt. You will note that the envelope signal generated by the opcode 'expon' is a control (k-) signal and the sound produced by the 'oscili' opcode (an oscillator) is an audio signal. The parameters for the instrument are held in initialisation (i-) variables. The instrument is run 4 times (there are 4 i-statements in the score) in a sequential manner (the '+' makes the start times of events aligned with the end times of previous events). The frequency is notated in octave.pitch-class format in the score (last parameter field, 5, in each event) and translated to Hz in the instrument code. |
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== MIDI playback == |
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Csound can play back MIDI files, as well as realtime MIDI events (say from a keyboard or a sequencer). All you need is Csound code that understands MIDI. For MIDI file playback, the compilation option -F <your-midi-file> is used. |
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Here is a version of the ping instrument used above, adapted for simple MIDI input (listening on MIDI channel 1). |
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<CsoundSynthesizer> |
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<CsInstruments> |
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instr 1 |
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idec = 1 |
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iamp ampmidi 32767 |
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kfrq cpsmidib 2 |
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kenv expsegr 1, idec, 0.1, 0.1, 0.01 |
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asig oscili kenv*iamp, kfrq, 1 |
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out asig |
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endin |
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</CsInstruments> |
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<CsScore> |
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f0 36000 |
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f1 0 16384 10 1 |
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</CsScore> |
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</CsoundSynthesizer> |
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In this case, we just need to do the following simple alterations: add opcodes for using MIDI NOTE data (frequency, amplitude) and a release-sensing envelope generator; remove the not required score events; and include a 'f0 36000' line to keep Csound listening for realtime events for 36000 seconds. |
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A more generic (and complex) example is shown below: a General MIDI (GM) soundfont synthesizer for playing GM files. This is give a good example of how flexible Csound can be, doing almost anything you would like in terms of sound synthesis. The code is based on two Csound instruments: one that parses raw MIDI data and another one that actually plays it. |
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{{ Box File | GM_example.csd | 2=<pre> |
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<CsoundSynthesizer> |
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<CsInstruments> |
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nchnls=2 |
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ichn = 1 |
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lp1: massign ichn, 0 |
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loop_le ichn, 1, 16, lp1 |
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pgmassign 0, 0 |
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gisf sfload "gmgsBank1.sf2" |
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sfpassign 0, gisf |
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/* this instrument parses MIDI input |
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to trigger the GM soundfont synthesis |
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instrument (instr 10 |
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*/ |
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instr 1 |
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idkit = 317 /* drum-kit preset */ |
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tableiw idkit, 9, 1 |
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irel = 0.5 /* release envelope */ |
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ipg = 1 |
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ivol = 2 |
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ipan = 3 |
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nxt: |
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kst, kch, kd1, kd2 midiin |
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if (kst != 0) then |
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kch = kch - 1 |
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if (kst == 144 && kd2 != 0) then ; note on |
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kpg table kch, ipg |
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/* instrument identifier is 10.[chn][note] */ |
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kinst = 10 + kd1/100000 + kch/100 |
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if kch == 9 then |
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/* exclusive identifiers */ |
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if kpg == idkit+7 then |
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krel = 2 /* add extra release time for orch perc*/ |
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else |
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krel = 0.5 |
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endif |
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if (kd1 == 29 || kd1 == 30) then ; EXC7 |
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kinst = 10.97 |
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elseif (kd1 == 42 || kd1 == 44 || kd1 == 46 || kd1 == 49) then ; EXC1 |
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kinst = 10.91 |
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elseif (kd1 == 71 || kd1 == 72) then ; EXC2 |
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kinst = 10.92 |
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elseif (kd1 == 73 || kd1 == 74) then ; EXC3 |
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kinst = 10.93 |
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elseif (kd1 == 78 || kd1 == 79) then ; EXC4 |
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kinst = 10.94 |
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elseif (kd1 == 80 || kd1 == 81) then ; EXC5 |
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kinst = 10.95 |
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elseif (kd1 == 86 || kd1 == 87) then ; EXC6 |
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kinst = 10.96 |
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endif |
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else |
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krel = 0.5 |
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endif |
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event "i", kinst, 0, -1, kd1, kd2, kpg, kch,krel |
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elseif (kst == 128 || (kst == 144 && kd2 == 0)) then ; note off |
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kpg table kch, ipg |
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kinst = 10 + kd1/100000 + kch/100 |
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if kch == 9 then |
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if (kd1 == 29 || kd1 == 30) then ; EXC7 |
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kinst = 10.97 |
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elseif (kd1 == 42 || kd1 == 44 || kd1 == 46 || kd1 == 49) then ; EXC1 |
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kinst = 10.91 |
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elseif (kd1 == 71 || kd1 == 72) then ; EXC2 |
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kinst = 10.92 |
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elseif (kd1 == 73 || kd1 == 74) then ; EXC3 |
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kinst = 10.93 |
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elseif (kd1 == 78 || kd1 == 79) then ; EXC4 |
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kinst = 10.94 |
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elseif (kd1 == 80 || kd1 == 81) then ; EXC5 |
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kinst = 10.95 |
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elseif (kd1 == 86 || kd1 == 87) then ; EXC6 |
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kinst = 10.96 |
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endif |
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else |
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kpg = 0 |
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endif |
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event "i", -kinst, 0, 1 |
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elseif (kst == 192) then /* program change msgs */ |
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if kch == 9 then |
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kpg = idkit |
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if kd1 == 8 then |
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kpg = idkit+1 |
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elseif kd1 == 16 then |
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kpg = idkit+2 |
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elseif kd1 == 24 then |
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kpg = idkit+3 |
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elseif kd1 == 25 then |
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kpg = idkit+4 |
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elseif kd1 == 32 then |
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kpg = idkit+5 |
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elseif kd1 == 40 then |
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kpg = idkit+6 |
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elseif kd1 == 48 then |
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kpg = idkit+7 |
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endif |
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else |
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kpg = kd1 |
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endif |
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tablew kpg, kch, ipg |
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elseif (kst == 176 && kd1 == 11) then /* volume msgs */ |
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tablew kd2, kch, ivol |
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elseif (kst == 176 && kd1 == 7) then /* pan msgs */ |
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tablew kd2, kch, ipan |
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endif |
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kgoto nxt |
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endif |
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endin |
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/* this is the GM soundfont synthesizer instrument */ |
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instr 10 |
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kenv linenr 1,0.001,p8,0.001 |
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iamp table p5, 5 |
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a1, a2 sfplay p5, p4, iamp,1, p6, 0, 0, 2 |
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kv table p7, 2 |
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kvol tablei kv, 5 |
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kpan table p7, 3 |
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kpan = (kpan - 64)/128 |
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outs a1*kvol*(0.5-kpan/2)*kenv, a2*kvol*(0.5+kpan/2)*kenv |
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endin |
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</CsInstruments> |
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<CsScore> |
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/* program preset (memory) table */ |
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f1 0 16 -2 0 0 0 0 0 0 0 0 226 0 0 0 0 0 0 0 |
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/* velocity (memory) table */ |
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f2 0 16 -2 127 127 127 127 127 127 127 127 127 127 127 127 127 127 127 127 |
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/* pan (memory) table */ |
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f3 0 16 -2 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 |
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f5 0 128 5 0.1 128 1 /* velocity mapping: less nuanced */ |
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f6 0 128 5 0.01 128 1 /* velocity mapping: more nuanced */ |
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i 1 0 360000 |
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e |
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</CsScore> |
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</CsoundSynthesizer> |
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</pre> |
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}} |
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The above example is not very typical of MIDI usage in Csound, as it handles MIDI data at its lowest level. Much simpler examples of how MIDI can be used by Csound exist. However the example is a good demonstration of how a universally-existing standard such as GM can be handled by Csound. |
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== MIDI connections == |
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To connect an alsa MIDI port to Csound, we use the -M <midi-device> option. |
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$ csound -M hw:1,0 ... |
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MIDI devices can be listed with the amidi command (see [[Sound]]). If virtual MIDI devices are present, |
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Csound can be used as a soft synth with other programs connecting to it. It is just a matter |
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of connecting the source software MIDI output to the virmidi device and starting Csound with the |
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correct device selected. For instance, if csound is started at the terminal with the the GM csd |
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shown above, it's possible then to use it as a MIDI synthesiser for a sequencer. |
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A simple example using aplaymidi as a 'sequencer' demonstrates the principle. First we list the virtual MIDI ports using amidi: |
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$ amidi -l |
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Dir Device Name |
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IO hw:1,0 Virtual Raw MIDI (16 subdevices) |
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... |
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Then we start Csound listening in for MIDI in one of the virtual MIDI device: |
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$ csound -M hw:1,0 -o dac gm.csd |
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Now in a second terminal, we list the MIDI port numbers available for aplaymidi: |
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$ aplaymidi -l |
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Port Client name Port name |
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14:0 Midi Through Midi Through Port-0 |
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24:0 Virtual Raw MIDI 2-0 VirMIDI 2-0 |
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... |
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Then we use aplaymidi to play a MIDI file using Csound as the soft synth |
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$ aplaymidi -p 24 mymidifile.mid |
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Of course this is only an example to show the functionality, as Csound can play MIDI files |
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directly (see above). Any other software can be used instead of aplaymidi. |
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== csndsugui == |
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As you can see from some of the examples above, it is possible to use [[csndsugui]] for fast Activity development. It is basically Python toolkit for the development of Csound-based audio and music applications under sugar and GTK. The code, plus examples and documentation, can be found in: |
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http://dev.laptop.org/git/activities/csndsugui |
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== Tutorials and... TOOTS== |
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See [[Csound tutorials]] for a wiki introduction to using Csound for music development. A [[Csound TOOTS]] page in this Wiki is also available. |
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For controlling Csound through Python, see the [[Csound-Python]] page. |
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== Sample Code == |
== Sample Code == |
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* A [http://blog.vrplumber.com/1876 simple Python project] using Csound to create an audible system load monitor using the standard Python Csound binding |
* A [http://blog.vrplumber.com/1876 simple Python project] using Csound to create an audible system load monitor using the standard Python Csound binding |
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* [http://dev.laptop.org/git?p=projects/tamtam;a=tree TamTam] uses a custom C++ wrapper around Csound and has a very large sound library available |
* [http://dev.laptop.org/git?p=projects/tamtam;a=tree TamTam] uses a custom C++ wrapper around Csound and has a very large sound library available |
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* [http://wiki.laptop.org/go/Csndsugui#A_complete_example Activity example] shows a complete Python and Csound code for a simple Activity. |
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* [http://csounds.com/4csEditor.zip 4csEditor.zip] is a collection of approximately 500 Csound csd files, covering everything from compositions to DSP processor instruments. LINK BROKEN. |
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== Updating Csound with yum == |
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Csound is available for the XO as a specialised subset of Csound5, olpcsound. The latest versions of this package are available with the latest builds. However, it is possible to install or update an earlier version using. For installing (please make sure that the older 'csound' packages have been removed to avoid conflicts, using rpm -e csound & rpm -e csound-python) |
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$ yum install olpcsound |
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and updating |
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$ yum update olpcsound |
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[[Category:Developers]] |
[[Category:Developers]] |
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[[Category:Programming language]] |
[[Category:Programming language]] |
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[[Category:Software]] |
[[Category:Software]] |
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[[Category:Audio]] |
Latest revision as of 16:54, 17 March 2012
Csound is the music and audio signal processing language originally developed by MIT's Barry Vercoe and now expanded and maintained by
a world-wide community, as Free Software [1]. Csound will provide audio services for the XO computer.
Csound is both a programming language and a sound synthesis engine. Csound, as included in the OLPC project, can be used by Activities or directly by children and teachers. It can be accessed in a variety of ways. In the XO platform, two basic ways are provided:
- Through the Python programming environment: eg. programmed in Activities.
- Through its 'classic' command-line frontend, directly invoking it from the Terminal activity.
Further information about Csound can be found on its official website: http://csounds.com/. The canonical Csound sources and multi-platform binaries are hosted by Sourceforge[2].
Activities
- Csound Editor - view, edit and perform Csound files
- Audio Loop Remixer - perform audio loops and apply a variety of effects
- MIDI File Player - performs MIDI files using the donated General MIDI soundfont
- Instrument Player - a keyboard interface to play a variety of instruments
- TamTam - Tam Tam uses Csound, but you would never know it as its interface is designed to wrap the Csound engine with a child-friendly look and feel. This excellent group of Activities allows kids to make sounds, make music, jam, record and transform their voices in an intuitive way. TamTam Edit allows students to patch together Csound's opcodes (modules) and teaches them all about signals, synthesis, and synthesizers. TamTam Activities demonstrate well how the power of Csound can be harnessed in the XO platform.
- GregCsoundActivities.zip - A number of Csound Server-based activities developed by Greg for Build 542 including a pretty cool Pitch-Tracker Bouncing Ball Activity and a Pitch Reverse Game – both lot's of fun for kids, but not currently supported by the latest builds and security models.
- Pippy - Pippy uses Csound to help teach children the Python programming language and to build XO Activities.
- Step - A simple 8-note step sequencer that children will use to play music and record their own loops for use in other sample-based activities. Step uses csndsugui.
- Funny Talk - An activity that children can use to record their voices with the built-in microphone, and process them with effects such as reverb, echo, chorus, etc. Funny Talk allows a child to save their manipulated voices as soundfiles so that they can be used in other musical activities. Funny Talk uses csndsugui.
OLPCsound Manual
View the online OLPCsound manual here:
http://www.csounds.com/manualOLPC/
Download the OLPCsound manual here:
http://www.csounds.com/manualOLPC/olpcsound5.08_manual.tar.gz
There's a content bundle for the XO which is installed the same as an activity and appears automatically in the Web Activity Library (the Web Activity default page). You can find it here:
http://www.csounds.com/manualOLPC/olpcsound5.08_manual.xol
Also in french:
http://www.csounds.com/manualOLPC/olpcsound5.08_manual-fr.xol
Csound code and CSD files
Csound code is most commonly written in the Unified Csound File format (CSD). This uses XML-like tags to contain the different code elements in sections. Two of these are required: orchestra (<CsInstruments>) and score (<CsScore>) contained within the <CsoundSynthesizer> tags. Here is a trivial instrument and score:
<CsoundSynthesizer> <CsInstruments> instr 1 a1 oscili p4, p5, 1 out a1 endin </CsInstruments> <CsScore> f1 0 16384 10 1 i1 0 1 10000 440 e </CsScore> </CsoundSynthesizer>
This will give you a nice 1-second sinewave beep.
Orchestra and Score
Csound is loosely based on the concept of an Orchestra, made up of Instruments, and a Score, made up of events, function table definitions etc.. Instruments contain the synthesis/processing code and the score the parameters to run these. In practice, you might not need a score, because realtime events (from MIDI, from Python or from other Csound instruments), so in that case an empty or minimal one will do. Instruments are written using a variety of opcodes (there are over 1000 of these), which are interconnected using audio signal (a-), control signal (k-), spectral signal(f-), initialisation (i-) and string (S-) variables. A slightly more interesting example shows some of these in operation:
<CsoundSynthesizer> <CsInstruments> instr 1 idur = p3 iamp = p4 ifrq = cpspch(p5) kenv expon 1, idur, 0.01 asig oscili kenv*iamp, ifrq, 1 out asig endin </CsInstruments> <CsScore> f1 0 16384 10 1 i1 0 1 8000 8.00 i1 + 1 12000 8.04 i1 + 1 16000 8.07 i1 + 2 24000 9.00 e </CsScore> </CsoundSynthesizer>
What you should hear is an arpeggio of 'ping' sounds, a bit like a chime or tuning fork, which is much more interesting than our previous attempt. You will note that the envelope signal generated by the opcode 'expon' is a control (k-) signal and the sound produced by the 'oscili' opcode (an oscillator) is an audio signal. The parameters for the instrument are held in initialisation (i-) variables. The instrument is run 4 times (there are 4 i-statements in the score) in a sequential manner (the '+' makes the start times of events aligned with the end times of previous events). The frequency is notated in octave.pitch-class format in the score (last parameter field, 5, in each event) and translated to Hz in the instrument code.
MIDI playback
Csound can play back MIDI files, as well as realtime MIDI events (say from a keyboard or a sequencer). All you need is Csound code that understands MIDI. For MIDI file playback, the compilation option -F <your-midi-file> is used.
Here is a version of the ping instrument used above, adapted for simple MIDI input (listening on MIDI channel 1).
<CsoundSynthesizer> <CsInstruments> instr 1 idec = 1 iamp ampmidi 32767 kfrq cpsmidib 2 kenv expsegr 1, idec, 0.1, 0.1, 0.01 asig oscili kenv*iamp, kfrq, 1 out asig endin </CsInstruments> <CsScore> f0 36000 f1 0 16384 10 1 </CsScore> </CsoundSynthesizer>
In this case, we just need to do the following simple alterations: add opcodes for using MIDI NOTE data (frequency, amplitude) and a release-sensing envelope generator; remove the not required score events; and include a 'f0 36000' line to keep Csound listening for realtime events for 36000 seconds.
A more generic (and complex) example is shown below: a General MIDI (GM) soundfont synthesizer for playing GM files. This is give a good example of how flexible Csound can be, doing almost anything you would like in terms of sound synthesis. The code is based on two Csound instruments: one that parses raw MIDI data and another one that actually plays it.
File: GM_example.csd |
<CsoundSynthesizer> <CsInstruments> nchnls=2 ichn = 1 lp1: massign ichn, 0 loop_le ichn, 1, 16, lp1 pgmassign 0, 0 gisf sfload "gmgsBank1.sf2" sfpassign 0, gisf /* this instrument parses MIDI input to trigger the GM soundfont synthesis instrument (instr 10 */ instr 1 idkit = 317 /* drum-kit preset */ tableiw idkit, 9, 1 irel = 0.5 /* release envelope */ ipg = 1 ivol = 2 ipan = 3 nxt: kst, kch, kd1, kd2 midiin if (kst != 0) then kch = kch - 1 if (kst == 144 && kd2 != 0) then ; note on kpg table kch, ipg /* instrument identifier is 10.[chn][note] */ kinst = 10 + kd1/100000 + kch/100 if kch == 9 then /* exclusive identifiers */ if kpg == idkit+7 then krel = 2 /* add extra release time for orch perc*/ else krel = 0.5 endif if (kd1 == 29 || kd1 == 30) then ; EXC7 kinst = 10.97 elseif (kd1 == 42 || kd1 == 44 || kd1 == 46 || kd1 == 49) then ; EXC1 kinst = 10.91 elseif (kd1 == 71 || kd1 == 72) then ; EXC2 kinst = 10.92 elseif (kd1 == 73 || kd1 == 74) then ; EXC3 kinst = 10.93 elseif (kd1 == 78 || kd1 == 79) then ; EXC4 kinst = 10.94 elseif (kd1 == 80 || kd1 == 81) then ; EXC5 kinst = 10.95 elseif (kd1 == 86 || kd1 == 87) then ; EXC6 kinst = 10.96 endif else krel = 0.5 endif event "i", kinst, 0, -1, kd1, kd2, kpg, kch,krel elseif (kst == 128 || (kst == 144 && kd2 == 0)) then ; note off kpg table kch, ipg kinst = 10 + kd1/100000 + kch/100 if kch == 9 then if (kd1 == 29 || kd1 == 30) then ; EXC7 kinst = 10.97 elseif (kd1 == 42 || kd1 == 44 || kd1 == 46 || kd1 == 49) then ; EXC1 kinst = 10.91 elseif (kd1 == 71 || kd1 == 72) then ; EXC2 kinst = 10.92 elseif (kd1 == 73 || kd1 == 74) then ; EXC3 kinst = 10.93 elseif (kd1 == 78 || kd1 == 79) then ; EXC4 kinst = 10.94 elseif (kd1 == 80 || kd1 == 81) then ; EXC5 kinst = 10.95 elseif (kd1 == 86 || kd1 == 87) then ; EXC6 kinst = 10.96 endif else kpg = 0 endif event "i", -kinst, 0, 1 elseif (kst == 192) then /* program change msgs */ if kch == 9 then kpg = idkit if kd1 == 8 then kpg = idkit+1 elseif kd1 == 16 then kpg = idkit+2 elseif kd1 == 24 then kpg = idkit+3 elseif kd1 == 25 then kpg = idkit+4 elseif kd1 == 32 then kpg = idkit+5 elseif kd1 == 40 then kpg = idkit+6 elseif kd1 == 48 then kpg = idkit+7 endif else kpg = kd1 endif tablew kpg, kch, ipg elseif (kst == 176 && kd1 == 11) then /* volume msgs */ tablew kd2, kch, ivol elseif (kst == 176 && kd1 == 7) then /* pan msgs */ tablew kd2, kch, ipan endif kgoto nxt endif endin /* this is the GM soundfont synthesizer instrument */ instr 10 kenv linenr 1,0.001,p8,0.001 iamp table p5, 5 a1, a2 sfplay p5, p4, iamp,1, p6, 0, 0, 2 kv table p7, 2 kvol tablei kv, 5 kpan table p7, 3 kpan = (kpan - 64)/128 outs a1*kvol*(0.5-kpan/2)*kenv, a2*kvol*(0.5+kpan/2)*kenv endin </CsInstruments> <CsScore> /* program preset (memory) table */ f1 0 16 -2 0 0 0 0 0 0 0 0 226 0 0 0 0 0 0 0 /* velocity (memory) table */ f2 0 16 -2 127 127 127 127 127 127 127 127 127 127 127 127 127 127 127 127 /* pan (memory) table */ f3 0 16 -2 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 64 f5 0 128 5 0.1 128 1 /* velocity mapping: less nuanced */ f6 0 128 5 0.01 128 1 /* velocity mapping: more nuanced */ i 1 0 360000 e </CsScore> </CsoundSynthesizer> |
The above example is not very typical of MIDI usage in Csound, as it handles MIDI data at its lowest level. Much simpler examples of how MIDI can be used by Csound exist. However the example is a good demonstration of how a universally-existing standard such as GM can be handled by Csound.
MIDI connections
To connect an alsa MIDI port to Csound, we use the -M <midi-device> option.
$ csound -M hw:1,0 ...
MIDI devices can be listed with the amidi command (see Sound). If virtual MIDI devices are present, Csound can be used as a soft synth with other programs connecting to it. It is just a matter of connecting the source software MIDI output to the virmidi device and starting Csound with the correct device selected. For instance, if csound is started at the terminal with the the GM csd shown above, it's possible then to use it as a MIDI synthesiser for a sequencer. A simple example using aplaymidi as a 'sequencer' demonstrates the principle. First we list the virtual MIDI ports using amidi:
$ amidi -l Dir Device Name IO hw:1,0 Virtual Raw MIDI (16 subdevices) ...
Then we start Csound listening in for MIDI in one of the virtual MIDI device:
$ csound -M hw:1,0 -o dac gm.csd
Now in a second terminal, we list the MIDI port numbers available for aplaymidi:
$ aplaymidi -l Port Client name Port name 14:0 Midi Through Midi Through Port-0 24:0 Virtual Raw MIDI 2-0 VirMIDI 2-0 ...
Then we use aplaymidi to play a MIDI file using Csound as the soft synth
$ aplaymidi -p 24 mymidifile.mid
Of course this is only an example to show the functionality, as Csound can play MIDI files directly (see above). Any other software can be used instead of aplaymidi.
csndsugui
As you can see from some of the examples above, it is possible to use csndsugui for fast Activity development. It is basically Python toolkit for the development of Csound-based audio and music applications under sugar and GTK. The code, plus examples and documentation, can be found in:
http://dev.laptop.org/git/activities/csndsugui
Tutorials and... TOOTS
See Csound tutorials for a wiki introduction to using Csound for music development. A Csound TOOTS page in this Wiki is also available.
For controlling Csound through Python, see the Csound-Python page.
Sample Code
- A simple Python project using Csound to create an audible system load monitor using the standard Python Csound binding
- TamTam uses a custom C++ wrapper around Csound and has a very large sound library available
- Activity example shows a complete Python and Csound code for a simple Activity.
- 4csEditor.zip is a collection of approximately 500 Csound csd files, covering everything from compositions to DSP processor instruments. LINK BROKEN.
Updating Csound with yum
Csound is available for the XO as a specialised subset of Csound5, olpcsound. The latest versions of this package are available with the latest builds. However, it is possible to install or update an earlier version using. For installing (please make sure that the older 'csound' packages have been removed to avoid conflicts, using rpm -e csound & rpm -e csound-python)
$ yum install olpcsound
and updating
$ yum update olpcsound