This file is indexed.

/usr/lib/pd/extra/cyclone/svf~-help.pd is in pd-cyclone 0.2~beta3-2.

This file is owned by root:root, with mode 0o644.

The actual contents of the file can be viewed below.

  1
  2
  3
  4
  5
  6
  7
  8
  9
 10
 11
 12
 13
 14
 15
 16
 17
 18
 19
 20
 21
 22
 23
 24
 25
 26
 27
 28
 29
 30
 31
 32
 33
 34
 35
 36
 37
 38
 39
 40
 41
 42
 43
 44
 45
 46
 47
 48
 49
 50
 51
 52
 53
 54
 55
 56
 57
 58
 59
 60
 61
 62
 63
 64
 65
 66
 67
 68
 69
 70
 71
 72
 73
 74
 75
 76
 77
 78
 79
 80
 81
 82
 83
 84
 85
 86
 87
 88
 89
 90
 91
 92
 93
 94
 95
 96
 97
 98
 99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
#N canvas 621 82 567 530 10;
#X obj 0 857 cnv 15 552 21 empty empty empty 20 12 0 14 -233017 -33289
0;
#X obj 0 453 cnv 3 550 3 empty empty inlets 8 12 0 13 -228856 -1 0
;
#N canvas 617 315 365 289 META 0;
#X text 0 18 LICENSE SIBSD;
#X text 0 180 LIBRARY cyclone;
#X text 0 0 KEYWORDS signal filter state variable state-variable cutoff
;
#X text 0 36 DESCRIPTION state-variable filter;
#X text 0 54 INLET_0 signal;
#X text 0 72 INLET_1 signal float;
#X text 0 90 INLET_2 signal float;
#X text 0 108 OUTLET_0 signal;
#X text 0 126 OUTLET_1 signal;
#X text 0 144 OUTLET_2 signal;
#X text 0 162 OUTLET_3 signal;
#X text 0 199 VERSION 0.2-beta1;
#X text 0 217 AUTHOR Krzysztof Czaja;
#X text 1 235 RELEASE_DATE 2002;
#X text 2 254 WEBSITE http://suita.chopin.edu.pl/~czaja/miXed/externs/cyclone.html
;
#X text 2 286 HELP_PATCH_AUTHORS Christoph Kummerer. Revised by Jonathan
Wilkes for Pd-extended 0.42 to conform to the PDDP template. Alex Cleveland
updated this patch for Pd-l2ork version 2013.05.28. Fred Jan Kraan
adapted the patch to pd-extended 2015-02-02;
#X restore 500 859 pd META;
#X obj 0 569 cnv 3 550 3 empty empty outlets 8 12 0 13 -228856 -1 0
;
#X obj 0 678 cnv 3 550 3 empty empty arguments 8 12 0 13 -228856 -1
0;
#X obj 0 735 cnv 3 550 3 empty empty more_info 8 12 0 13 -228856 -1
0;
#N canvas 317 494 428 109 Related_objects 0;
#X obj 0 0 cnv 15 425 20 empty empty empty 3 12 0 14 -204280 -1 0;
#X text 6 1 Related Objects;
#X restore 196 859 pd Related_objects;
#X obj 79 462 cnv 17 3 17 empty empty 0 5 9 0 16 -228856 -162280 0
;
#X obj 79 578 cnv 17 3 17 empty empty 0 5 9 0 16 -228856 -162280 0
;
#X obj 0 0 cnv 15 552 40 empty empty svf~ 3 12 0 18 -204280 -1 0;
#X obj 492 9 svf~;
#X text 13 24 state-variable filter;
#X obj 79 529 cnv 17 3 33 empty empty 2 5 9 0 16 -228856 -162280 0
;
#X text 107 462 signal;
#X text 179 462 - signal to filter;
#X text 107 528 signal;
#X text 107 546 float;
#X text 107 486 signal;
#X text 107 503 float;
#X text 179 494 - set cutoff frequency;
#X text 179 536 - set resonance (0-1);
#X obj 79 487 cnv 17 3 33 empty empty 1 5 9 0 16 -228856 -162280 0
;
#X obj 79 603 cnv 17 3 17 empty empty 1 5 9 0 16 -228856 -162280 0
;
#X obj 79 626 cnv 17 3 17 empty empty 2 5 9 0 16 -228856 -162280 0
;
#X text 90 689 1) float;
#X text 90 711 2) float;
#X text 107 816 Floats or signals can modify these in real-time. The
value of these parameters is only sampled once per signal vector.;
#X text 107 770 One of its advantages is that the it produces low-pass
\, high-pass \, band-pass \, and band-reject (notch) output simultaneously
- so all four are available in parallel.;
#X text 107 742 svf~ implements Chamberlin's state-variable filter
algorithm.;
#N canvas 541 341 446 460 svf_part2 0;
#X text 68 324 onepole~.help contains yet another example.;
#X text 68 400 svf~ accepts arguments or max messages to change the
frequency input mode. it is generally recommended to set the mode with
an argument and leave it constant \, to avoid confusion.;
#X text 68 262 try sweeping the cutoff frequency in linear mode \,
then in radians mode \, to appreciate the difference. a similar principle
operates in the amplitude domain \, where exponential audio faders
are used to match our logarithmic perception of loudness.;
#X text 18 152 linear;
#X text 42 99 Hz;
#X text 68 195 in this mode \, input values from (0 -> 1) are interpreted
as radians \, producing a quarter-cycle sinusoidal mapping to cutoff
frequencies. this conforms the frequency mapping to a response that
is closer to our logarithmic perception of pitch.;
#X text 68 143 this mode is essentially the same \, but with a normalized
input range. linear input values from (0 -> 1) are mapped to cutoff
frequencies in the effective range \, (0 -> fs/4).;
#X text 68 90 this is the default mode. input values set the cutoff
frequency directly. therefore \, the input range is the same as the
cutoff frequency (0 -> fs/4) \, and response is linear.;
#X text 68 27 svf~ has three different modes for mapping input values
onto cutoff frequency. these are mainly for convenience \, but they
may also improve efficiency slightly.;
#X text 68 347 since svf~ only samples its control inputs once per
vector \, it is more efficient to use the radians mode than to do logarithmic
scaling outside the object at audio rate.;
#X text 10 209 radians;
#X obj 3 3 cnv 15 425 20 empty empty empty 3 12 0 14 -204280 -1 0;
#X text 8 4 svf~ modes;
#X restore 433 382 pd svf_part2;
#X msg 226 170 0.5;
#X text 191 83 frequency range is 0 - f(s)/4;
#X obj 109 56 noise~;
#X msg 143 110 37;
#X text 262 352 outputs: lowpass \, highpass \, bandpass \, notch;
#X obj 131 83 loadbang;
#X obj 143 173 * 11025;
#X obj 143 152 / 512;
#X floatatom 143 194 0 0 0 0 - - -;
#N canvas 542 410 438 271 svf_algorithm 0;
#X text 150 216 bandstop = lowpass + hipass \;;
#X text 3 105 this is the dsp loop. note how the calculations work
together to produce all four outputs simultaneously.;
#X text 6 49 first \, convert hz to radians (this step is not necessary
in radians input mode);
#X text 159 71 cf_radians = sin(2. * PI * cf_hz * x->ifs) \;;
#X text 150 184 bandpass = bandpass + cf_radians * hipass \;;
#X text 150 168 hipass = in_samp - lowpass - q * bandpass \;;
#X text 150 152 lowpass = lowpass + (cf_radians * bandpass) \;;
#X text 150 200 bandpass = bandpass - (bandpass ^ 3.) * 0.0001 \;;
#X obj 3 4 cnv 15 425 20 empty empty empty 3 12 0 14 -204280 -1 0;
#X text 6 32;
#X text 6 5 the basic algorithm inside svf~;
#X restore 315 382 pd svf_algorithm;
#X obj 246 330 tgl 15 0 empty empty empty 17 7 0 10 -262144 -1 -1 0
1;
#X obj 207 330 tgl 15 0 empty empty empty 17 7 0 10 -262144 -1 -1 0
1;
#X obj 168 330 tgl 15 0 empty empty empty 17 7 0 10 -262144 -1 -1 0
1;
#X obj 131 330 tgl 15 0 empty empty empty 17 7 0 10 -262144 -1 -1 1
1;
#X obj 225 352 *~ 0;
#X obj 186 352 *~ 0;
#X obj 147 352 *~ 0;
#X obj 110 352 *~ 0;
#X floatatom 226 193 0 0 0 0 - - -;
#X obj 146 132 hsl 128 15 0 127 0 0 empty empty empty -2 -8 0 10 -262144
-1 -1 3700 1;
#X text 107 578 signal;
#X text 179 578 - lowpass signal;
#X text 107 603 signal;
#X text 179 603 - highpass signal;
#X text 107 626 signal;
#X text 179 626 - bandpass signal;
#X obj 79 651 cnv 17 3 17 empty empty 3 5 9 0 16 -228856 -162280 0
;
#X text 107 651 signal;
#X text 179 651 - notch signal;
#X text 179 686 - initial cutoff frequency (Hz);
#X text 179 710 - initial resonance (0-1);
#X obj 109 381 *~ 0.7;
#X obj 109 410 output~;
#X obj 109 261 cyclone/svf~ 797 0.5;
#X connect 30 0 48 0;
#X connect 32 0 63 0;
#X connect 33 0 49 0;
#X connect 35 0 30 0;
#X connect 35 0 33 0;
#X connect 35 0 43 0;
#X connect 36 0 38 0;
#X connect 37 0 36 0;
#X connect 38 0 63 1;
#X connect 40 0 44 1;
#X connect 41 0 45 1;
#X connect 42 0 46 1;
#X connect 43 0 47 1;
#X connect 44 0 61 0;
#X connect 45 0 61 0;
#X connect 46 0 61 0;
#X connect 47 0 61 0;
#X connect 48 0 63 2;
#X connect 49 0 37 0;
#X connect 61 0 62 0;
#X connect 61 0 62 1;
#X connect 63 0 47 0;
#X connect 63 1 46 0;
#X connect 63 2 45 0;
#X connect 63 3 44 0;