rsc3/doc-schelp/HelpSource/Classes/Pproto.scrbl

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2022-08-24 13:53:18 +00:00
#lang scribble/manual
@(require (for-label racket))
@title{Pproto}
provide a proto event for an event stream@section{related}
Classes/Pattern
@section{categories}
Streams-Patterns-Events>Patterns>Server Control
@section{description}
Pproto uses the strong::makeFunction:: to allocate resources (buffers, buses, groups) and create a protoEvent that makes those resources available to a pattern. It is fully compatible with non-realtime synthesis using strong::render::.
The strong::makeFunction:: "makes" the protoEvent (i.e. protoEvent is
@racketblock[currentEnvironment::). Typically, it defines and yields a sequence of events that create the needed resources using the following link::Overviews/Event_types:::
]
@section{definitionList}
## \allocRead || load a file from ~path, starting at ~firstFileFrame, reading ~numFrames sample frames
## \cue || cue a file for DiskIn, with ~bufferSize frames
## \table || load ~amps directly into a buffer
## \sine1 || generate a buffer from ~amps
## \sine2 || generate a buffer from ~freqs, ~amps
## \sine3 || generate a buffer from ~freqs, ~amps, ~phases
## \cheby || generate a waveshape buffer from ~amps
## \audioBus || allocate ~channels consecutive audio buses
## \controlBus || allocate ~channels consecutive control buses
## \on || create a synth
::
@section{note}
These eventTypes will allocate their own buffers and buses unless they are specified. To support this, the key
@racketblock[\bufNum:: is used rather than ]
@racketblock[\bufnum:: which has a default value assigned.
::
When Pproto ends, these eventTypes will respond to the strong::cleanup:: call by strong::deallocating any resources they have allocated::. Do not assume your buffers, buses etc. will exist after Pproto stops!
The function yields each event. That event is then performed with possible modifications by enclosing patterns and the player (either an link::Classes/EventStreamPlayer:: or a link::Classes/ScoreStreamPlayer::). The resultant event is returned to the function where it can be assigned to a key within the protoEvent.
The patternarray is played using Pfpar, a variant of Ppar that ends when any of its subpatterns end. In this way,
you can use Pproto to create effects that can be controlled by a pattern that runs in parallel with the note generating pattern and ends together with that note generating pattern (see example 0 below).
A strong::cleanupFunction:: that deallocates resources when the pattern ends or is stopped is automatically created. It can be replaced with a user defined cleanup if needed. This function receives two arguments: strong::proto::, the prototype event, and strong::flag::, which is set false if all nodes have been freed already by link::Classes/CmdPeriod::.
]
@section{Examples}
@section{note}
The syntax used for patterns like Pbind and Pmono is a little bit different for making the code more readable. The difference has nothing to do with Pproto. This is the same:
@racketblock[Pbind(\freq, 700, \amp, 0.1):: and ]
@racketblock[Pbind(*[freq: 700, amp: 0.1])::
::
]
@section{subsection}
Example 1, loading and granulating a sound file.
@racketblock[
(
SynthDef(\help_playbuf, { | out=0, bufnum = 0, rate = 1, startPos = 0, amp = 0.1, sustain = 1, pan = 0, loop = 1|
var audio;
rate = rate * BufRateScale.kr(bufnum);
startPos = startPos * BufFrames.kr(bufnum);
audio = BufRd.ar(1, bufnum, Phasor.ar(0, rate, startPos, BufFrames.ir(bufnum)), 1, 1);
audio = EnvGen.ar(Env.sine, 1, timeScale: sustain, doneAction: Done.freeSelf) * audio;
audio = Pan2.ar(audio, pan, amp);
OffsetOut.ar(out, audio);
}).add;
a = Pproto({
~newgroup = (type: \group).yield;
~sf1 = (type: \allocRead, path: Platform.resourceDir +/+ "sounds/a11wlk01-44_1.aiff").yield;
},
Pbind(*[
instrument: \help_playbuf,
dur: Pseg([0,0,0.25,0.5, 0.75, 1],10).linexp(0,1,0.01,2),
legato: 4,
startPos: Pn(Pseg([0,1], 20), inf),
rate: Pwhite(1, 1).midiratio,
loop: 0,
group: Pkey(\newgroup),
bufnum: Pkey(\sf1)
])
);
a.play;
)
//a.render("sounds/test.aif", 40)
//SoundFile.openRead("sounds/test.aif").play
::
]
@section{subsection}
Example 2, loading a waveform buffer and modifying it in performance.
@racketblock[
(
SynthDef(\osc,{ arg out=0, bufnum=0, numbufs = 8, sustain = 1, freq = 500, amp = 0.1, pan = 0;
var audio;
audio = Osc.ar(bufnum, freq);
audio = EnvGen.ar(Env.linen(0.01, 0.90,0.9), 1, timeScale: sustain, doneAction: Done.freeSelf) * audio;
audio = Pan2.ar(audio, pan, amp);
OffsetOut.ar(out, audio);
}).add;
b = Pproto({
~bufnum = (type: \sine1, amps: 1.0/[1,2,3,4,5,6] ).yield;
},
Ppar([
Pbind(*[
instrument: \osc,
freq: Pwhite(1, 16) * 100,
detune: Pfunc { Array.fill(3.rand + 1, {3.0.rand}) },
dur: Prand([2,2,2.5,1],10),
db: Pn(Pstep([-10, -20, -20, -15, -20, -20, -20], 0.5) ),
legato: Pwhite(0.0,1).linexp(0,1,0.1, 3)
]),
Pbind(*[
type: \sine1,
amps: Pseg(Pfunc{ | ev | Array.fill(10, {1.0.rand}) }, 1),
numOvertones: Pseg(Pwhite(0, 9), 10).asInteger,
amps: Pfunc{ | ev | ev[\amps].copyRange(0, ev[\numOvertones]) },
dur: 0.05,
bufNum: Pkey(\bufnum)
])
])
);
b.play
)
//b.render("sounds/test.aif", 40)
//SoundFile.openRead("sounds/test.aif").play
::
]
@section{subsection}
Example 3, loading a waveshaper buffer and modifying it in performance.
@racketblock[
(
SynthDef(\shaper,{ arg out=0, bufnum=0, numbufs = 8, sustain = 1, freq = 500, amp = 0.1, pan = 0;
var audio;
audio = SinOsc.ar(freq);
audio = EnvGen.ar(Env.linen(0.4, 0.50,0.9), 1, timeScale: sustain, doneAction: Done.freeSelf) * audio;
audio = Shaper.ar(bufnum, audio);
audio = Pan2.ar(audio, pan, amp);
OffsetOut.ar(out, LeakDC.ar(audio));
}).add;
c = Pproto({
~bufnum = (type: \cheby, amps: 1.0/[1,2,3,4,5,6] ).yield;
},
Ppar([
Pbind(*[
instrument: \shaper,
freq: Pwhite(1, 16) * 100,
detune: Pfunc { Array.fill(3.rand + 1, {3.0.rand}) },
dur: Prand([2,2,2.5,1],inf),
db: Pn(Pstep([-10, -20, -20, -15, -20, -20, -20], 0.5) ),
legato: Pwhite(0.0,1).linexp(0,1,1.1, 5)
]),
Pbind(*[
type: \cheby,
amps: Pseg(Pfunc{ | ev | Array.fill(10, {1.0.rand}) }, 4),
dur: 0.05
])
])
);
c.play
)
//c.render("sounds/test.aif", 40)
//SoundFile("sounds/test.aif").play
//
::
]
@section{subsection}
Example 4, using an effect with parallel control.
@racketblock[
(
SynthDef(\echo, { arg out=0, maxdtime=0.2, dtime=0.2, decay=2, gate=1;
var env, in;
env = Linen.kr(gate, 0.05, 1, 5, 2);
in = In.ar(out, 2);
XOut.ar(out, env, CombL.ar(in * env, maxdtime, Lag.kr(dtime, 4), decay, 1, in));
}, [\ir, \ir, 0.1, 0.1, 0]).add;
SynthDef(\fm, { arg out=0, freq, index, decay=2, gate=1;
var env, in;
env = Linen.kr(gate, 0.05, 1, 5, 2);
in = In.ar(out, 2);
XOut.ar(out, env, SinOsc.ar(freq, in * index));
}).add;
Pproto({
// start two effect synths (just switching them on) and store the parameters in the environment
~fsynth = (type: \on, instrument: \fm, freq: 4, index: 1, addAction: 1, db: -30).yield;
~fControl = [\set, ~fsynth[\id], ~fsynth[\msgFunc] ];
~synth = (type: \on, instrument: \echo, addAction: 1).yield;
~sControl = [\set, ~synth[\id], ~synth[\msgFunc] ];
}, [
Pbind(*[
#[type, id, msgFunc], Pkey(\fControl), // fetch the parameters from the environment
freq: Pseg([0,1], 10).linexp(0,1, 0.1, 1000),
index: Pseg([0,1], 10).linexp(0,1, 0.1, 100),
dur: 0.1
]),
Pbind(*[
#[type, id, msgFunc], Pkey(\sControl), // fetch the parameters from the environment
dtime: Pwhite(0,0.2),
decay: Pwhite(0.1,2),
dur: 1
]),
Pbind(*[
instrument: \default,
freq: Pwhite(1,16) * 100,
dur: 0.2,
db: 0
])
]
).play
)
::
]