add clipboard support and alto777_LFSR, Autodafe, CastleRocktronics, computerscare, FrankBuss, JE, Nohmad, SynthKit, TheXOR modules

6 years ago · f455deed13
--- a/README.md
+++ b/README.md
@@ -30,7 +30,7 @@ Tested in
 # Downloads
 The current release can be found in the [vst2_bin/](vst2_bin/) folder.

 Here's a snapshot of it: [veeseevstrack_0_6_1_win64_bin-16Aug2018.7z](dist/veeseevstrack_0_6_1_win64_bin-16Aug2018.7z) (64bit)
 Here's a snapshot of it: [veeseevstrack_0_6_1_win64_bin-18Aug2018.7z](dist/veeseevstrack_0_6_1_win64_bin-18Aug2018.7z) (64bit)

 Note: The effect plugin can used be as an instrument, too. You just have to send it MIDI events !

@@ -71,7 +71,7 @@ The binary distribution contains the following (17) dynamically loaded add-on mo
 - Template_shared.MyModule


 The following (517) add-on modules are statically linked with the VST plugin:
 The following (575) add-on modules are statically linked with the VST plugin:
 - 21kHz.D_Inf
 - 21kHz.PalmLoop
 - Alikins.IdleSwitch
@@ -80,6 +80,13 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - Alikins.ColorPanel
 - Alikins.GateLength
 - Alikins.SpecificValue
 - alto777_LFSR.FG8
 - alto777_LFSR.Psychtone
 - alto777_LFSR.Amuse
 - alto777_LFSR.a7Utility
 - alto777_LFSR.cheapFX
 - alto777_LFSR.Divada
 - alto777_LFSR.YASeq3
 - AS.ADSR
 - AS.AtNuVrTr
 - AS.BPMCalc
@@ -129,6 +136,23 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - AudibleInstruments.Blinds
 - AudibleInstruments.Veils
 - AudibleInstruments.Frames
 - Autodafe.Multiple18
 - Autodafe.Multiple28
 - Autodafe.LFOWidget
 - Autodafe.Keyboard
 - Autodafe.BPMClock
 - Autodafe.ClockDivider
 - Autodafe.SEQ8
 - Autodafe.SEQ16
 - Autodafe.TriggerSeq
 - Autodafe.FixedFilter
 - Autodafe.MultiModeFilter
 - Autodafe.FormantFilter
 - Autodafe.FoldBack
 - Autodafe.BitCrusher
 - Autodafe.PhaserFx
 - Autodafe.ChorusFx
 - Autodafe.ReverbFx
 - BaconMusic.Glissinator
 - BaconMusic.PolyGnome
 - BaconMusic.QuantEyes
@@ -218,6 +242,7 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - Bogaudio.TwentyTwoHP
 - Bogaudio.TwentyFiveHP
 - Bogaudio.ThirtyHP
 - CastleRocktronics.Cubefader
 - cf.trSEQ
 - cf.LEDSEQ
 - cf.L3DS3Q
@@ -236,6 +261,8 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - cf.PATCH
 - cf.LEDS
 - cf.DAVE
 - computerscare.ComputerscareDebug
 - computerscare.ComputerscarePatchSequencer
 - DHE-Modules.BoosterStage
 - DHE-Modules.Cubic
 - DHE-Modules.Hostage
@@ -250,6 +277,7 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - ESeries.E340
 - ErraticInstruments.MPEToCV
 - ErraticInstruments.QuadMPEToCV
 - FrankBuss.Formula
 - FrozenWasteland.BPMLFO
 - FrozenWasteland.BPMLFO2
 - FrozenWasteland.DamianLillard
@@ -336,6 +364,8 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - ImpromptuModular.BigButtonSeq
 - ImpromptuModular.SemiModularSynth
 - ImpromptuModular.BlankPanel
 - JE.SimpleWaveFolder
 - JE.RingModulator
 - JW_Modules.Cat
 - JW_Modules.BouncyBalls
 - JW_Modules.FullScope
@@ -424,6 +454,8 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - ML_modules.TrigSwitch2
 - ML_modules.TrigSwitch3
 - ML_modules.TrigSwitch3_2
 - Nohmad.Noise
 - Nohmad.StrangeAttractors
 - Ohmer.KlokSpid
 - Ohmer.RKD
 - Ohmer.RKDBRK
@@ -576,7 +608,33 @@ The following (517) add-on modules are statically linked with the VST plugin:
 - SubmarineFree.BP120
 - SubmarineFree.BP124
 - SubmarineFree.BP132
 - SynthKit.Addition
 - SynthKit.Subtraction
 - SynthKit.And
 - SynthKit.Or
 - SynthKit.M1x8
 - SynthKit.M1x8CV
 - SynthKit.ClockDivider
 - SynthKit.RotatingClockDivider
 - SynthKit.RotatingClockDivider2
 - SynthKit.PrimeClockDivider
 - SynthKit.FibonacciClockDivider
 - SynthKit.Seq4
 - SynthKit.Seq8
 - Template.MyModule
 - TheXOR.Klee
 - TheXOR.M581
 - TheXOR.Z8K
 - TheXOR.Renato
 - TheXOR.Spiralone
 - TheXOR.Burst
 - TheXOR.Uncertain
 - TheXOR.PwmClock
 - TheXOR.Quantizer
 - TheXOR.Attenuator
 - TheXOR.Boole
 - TheXOR.Switch
 - TheXOR.Mplex
 - trowaSoft.TrigSeq
 - trowaSoft.TrigSeq64
 - trowaSoft.VoltSeq
--- a/dep/dep.7z
+++ b/dep/dep.7z
--- a/plugins/community/repos/Autodafe/.gitignore
+++ b/plugins/community/repos/Autodafe/.gitignore
--- a/plugins/community/repos/Autodafe/Autodafe.dll
+++ b/plugins/community/repos/Autodafe/Autodafe.dll
--- a/plugins/community/repos/Autodafe/LICENSE-dist.txt
+++ b/plugins/community/repos/Autodafe/LICENSE-dist.txt
@@ -0,0 +1,13 @@
 # kissfft

 Copyright (c) 2003-2010 Mark Borgerding

 All rights reserved.

 Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:

    * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.
    * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution.
    * Neither the author nor the names of any contributors may be used to endorse or promote products derived from this software without specific prior written permission.

 THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
--- a/plugins/community/repos/Autodafe/LICENSE.txt
+++ b/plugins/community/repos/Autodafe/LICENSE.txt
@@ -0,0 +1,5 @@
 Copyright (c) 2016 Antonio Grazioli (AUtodafe) is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

 The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
--- a/plugins/community/repos/Autodafe/Makefile
+++ b/plugins/community/repos/Autodafe/Makefile
@@ -0,0 +1,18 @@

 SOURCES = $(wildcard src/*.cpp)

 LDFLAGS += -Lsrc/stk/src -lstk

 LDFLAGS += -Lsrc/Gamma/build/lib -lGamma


 include ../../plugin.mk




 dist: all
 	mkdir -p dist/Autodafe
 	cp LICENSE* dist/Autodafe/
 	cp plugin.* dist/Autodafe/
 	cp -R res dist/Autodafe/
--- a/plugins/community/repos/Autodafe/README.md
+++ b/plugins/community/repos/Autodafe/README.md
@@ -0,0 +1,3 @@
 # Autodafe Module Pack for VCV Rack

 At the moment the sources here on github are broken. I plan to remove everything and upload them from scratch, in the meantime you can download all my compiled plugins from https://www.autodafe.net/virtual-instruments/vcv-rack-modules.html
--- a/plugins/community/repos/Autodafe/build/src/Autodafe.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Autodafe.cpp.d
@@ -0,0 +1,17 @@
 build/src/Autodafe.cpp.o: src/Autodafe.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp \
  ../../include/dsp/decimator.hpp ../../include/dsp/ringbuffer.hpp \
  ../../include/dsp/fir.hpp ../../include/dsp/fft.hpp \
  ../../include/dsp/filter.hpp ../../include/dsp/frame.hpp \
  ../../include/dsp/minblep.hpp ../../include/dsp/ode.hpp \
  ../../include/dsp/samplerate.hpp ../../dep/include/samplerate.h
--- a/plugins/community/repos/Autodafe/build/src/BMPClock.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/BMPClock.cpp.d
@@ -0,0 +1,12 @@
 build/src/BMPClock.cpp.o: src/BMPClock.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp
--- a/plugins/community/repos/Autodafe/build/src/BitCrusher.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/BitCrusher.cpp.d
@@ -0,0 +1,12 @@
 build/src/BitCrusher.cpp.o: src/BitCrusher.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/Chorus.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Chorus.cpp.d
@@ -0,0 +1,15 @@
 build/src/Chorus.cpp.o: src/Chorus.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h src/stk/include/Chorus.h src/stk/include/Effect.h \
  src/stk/include/Stk.h src/stk/include/DelayL.h \
  src/stk/include/Filter.h src/stk/include/SineWave.h \
  src/stk/include/Generator.h
--- a/plugins/community/repos/Autodafe/build/src/ClockDivider.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/ClockDivider.cpp.d
@@ -0,0 +1,12 @@
 build/src/ClockDivider.cpp.o: src/ClockDivider.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp
--- a/plugins/community/repos/Autodafe/build/src/DSPUtilities.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/DSPUtilities.cpp.d
@@ -0,0 +1 @@
 build/src/DSPUtilities.cpp.o: src/DSPUtilities.cpp src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/FixedFilterBank.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/FixedFilterBank.cpp.d
@@ -0,0 +1,12 @@
 build/src/FixedFilterBank.cpp.o: src/FixedFilterBank.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/FoldBack.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/FoldBack.cpp.d
@@ -0,0 +1,12 @@
 build/src/FoldBack.cpp.o: src/FoldBack.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/FormantFilter.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/FormantFilter.cpp.d
@@ -0,0 +1,12 @@
 build/src/FormantFilter.cpp.o: src/FormantFilter.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/Keyboard.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Keyboard.cpp.d
@@ -0,0 +1,12 @@
 build/src/Keyboard.cpp.o: src/Keyboard.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp
--- a/plugins/community/repos/Autodafe/build/src/LFO.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/LFO.cpp.d
@@ -0,0 +1,13 @@
 build/src/LFO.cpp.o: src/LFO.cpp src/Autodafe.hpp ../../include/rack.hpp \
  ../../include/util.hpp ../../include/math.hpp ../../include/asset.hpp \
  ../../include/plugin.hpp ../../include/engine.hpp \
  ../../dep/include/jansson.h ../../dep/include/jansson_config.h \
  ../../include/gui.hpp ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/decimator.hpp \
  ../../include/dsp/ringbuffer.hpp ../../include/dsp/fir.hpp \
  ../../include/dsp/filter.hpp
--- a/plugins/community/repos/Autodafe/build/src/MultiModeFilter.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/MultiModeFilter.cpp.d
@@ -0,0 +1,12 @@
 build/src/MultiModeFilter.cpp.o: src/MultiModeFilter.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/Multiple1x8.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Multiple1x8.cpp.d
@@ -0,0 +1,12 @@
 build/src/Multiple1x8.cpp.o: src/Multiple1x8.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/Multiple2x8.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Multiple2x8.cpp.d
@@ -0,0 +1,12 @@
 build/src/Multiple2x8.cpp.o: src/Multiple2x8.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/Phaser.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Phaser.cpp.d
@@ -0,0 +1,12 @@
 build/src/Phaser.cpp.o: src/Phaser.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/build/src/Reverb.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/Reverb.cpp.d
@@ -0,0 +1,13 @@
 build/src/Reverb.cpp.o: src/Reverb.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h src/stk/include/NRev.h src/stk/include/Effect.h \
  src/stk/include/Stk.h src/stk/include/Delay.h src/stk/include/Filter.h
--- a/plugins/community/repos/Autodafe/build/src/SEQ16.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/SEQ16.cpp.d
@@ -0,0 +1,12 @@
 build/src/SEQ16.cpp.o: src/SEQ16.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp
--- a/plugins/community/repos/Autodafe/build/src/SEQ8.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/SEQ8.cpp.d
@@ -0,0 +1,12 @@
 build/src/SEQ8.cpp.o: src/SEQ8.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp
--- a/plugins/community/repos/Autodafe/build/src/TriggerSeq.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/TriggerSeq.cpp.d
@@ -0,0 +1,12 @@
 build/src/TriggerSeq.cpp.o: src/TriggerSeq.cpp src/Autodafe.hpp \
  ../../include/rack.hpp ../../include/util.hpp ../../include/math.hpp \
  ../../include/asset.hpp ../../include/plugin.hpp \
  ../../include/engine.hpp ../../dep/include/jansson.h \
  ../../dep/include/jansson_config.h ../../include/gui.hpp \
  ../../include/app.hpp ../../include/widgets.hpp \
  ../../include/../ext/nanovg/src/nanovg.h \
  ../../include/../ext/oui-blendish/blendish.h \
  ../../include/../ext/nanosvg/src/nanosvg.h ../../include/events.hpp \
  ../../dep/include/GL/glew.h ../../dep/include/GLFW/glfw3.h \
  ../../include/components.hpp src/Biquad.h src/VAStateVariableFilter.h \
  src/DSPUtilities.h ../../include/dsp/digital.hpp
--- a/plugins/community/repos/Autodafe/build/src/VAStateVariableFilter.cpp.d
+++ b/plugins/community/repos/Autodafe/build/src/VAStateVariableFilter.cpp.d
@@ -0,0 +1,2 @@
 build/src/VAStateVariableFilter.cpp.o: src/VAStateVariableFilter.cpp \
  src/VAStateVariableFilter.h src/DSPUtilities.h
--- a/plugins/community/repos/Autodafe/dep/stk/.gitignore
+++ b/plugins/community/repos/Autodafe/dep/stk/.gitignore
@@ -0,0 +1,188 @@
 #####
 # OS X temporary files that should never be committed
 #
 # c.f. http://www.westwind.com/reference/os-x/invisibles.html

 .DS_Store

 # c.f. http://www.westwind.com/reference/os-x/invisibles.html

 .Trashes

 # c.f. http://www.westwind.com/reference/os-x/invisibles.html

 *.swp

 # *.lock - this is used and abused by many editors for many different things.
 #    For the main ones I use (e.g. Eclipse), it should be excluded 
 #    from source-control, but YMMV

 *.lock

 #
 # profile - REMOVED temporarily (on double-checking, this seems incorrect; I can't find it in OS X docs?)
 #profile


 ####
 # Xcode temporary files that should never be committed
 # 
 # NB: NIB/XIB files still exist even on Storyboard projects, so we want this...

 *~.nib


 ####
 # Xcode build files -
 #
 # NB: slash on the end, so we only remove the FOLDER, not any files that were badly named "DerivedData"

 DerivedData/

 # NB: slash on the end, so we only remove the FOLDER, not any files that were badly named "build"

 build/


 #####
 # Xcode private settings (window sizes, bookmarks, breakpoints, custom executables, smart groups)
 #
 # This is complicated:
 #
 # SOMETIMES you need to put this file in version control.
 # Apple designed it poorly - if you use "custom executables", they are
 #  saved in this file.
 # 99% of projects do NOT use those, so they do NOT want to version control this file.
 #  ..but if you're in the 1%, comment out the line "*.pbxuser"

 # .pbxuser: http://lists.apple.com/archives/xcode-users/2004/Jan/msg00193.html

 *.pbxuser

 # .mode1v3: http://lists.apple.com/archives/xcode-users/2007/Oct/msg00465.html

 *.mode1v3

 # .mode2v3: http://lists.apple.com/archives/xcode-users/2007/Oct/msg00465.html

 *.mode2v3

 # .perspectivev3: http://stackoverflow.com/questions/5223297/xcode-projects-what-is-a-perspectivev3-file

 *.perspectivev3

 #    NB: also, whitelist the default ones, some projects need to use these
 !default.pbxuser
 !default.mode1v3
 !default.mode2v3
 !default.perspectivev3


 ####
 # Xcode 4 - semi-personal settings
 #
 #
 # OPTION 1: ---------------------------------
 #     throw away ALL personal settings (including custom schemes!
 #     - unless they are "shared")
 #
 # NB: this is exclusive with OPTION 2 below
 xcuserdata

 # OPTION 2: ---------------------------------
 #     get rid of ALL personal settings, but KEEP SOME OF THEM
 #     - NB: you must manually uncomment the bits you want to keep
 #
 # NB: this *requires* git v1.8.2 or above; you may need to upgrade to latest OS X,
 #    or manually install git over the top of the OS X version
 # NB: this is exclusive with OPTION 1 above
 #
 #xcuserdata/**/*

 #     (requires option 2 above): Personal Schemes
 #
 #!xcuserdata/**/xcschemes/*

 ####
 # XCode 4 workspaces - more detailed
 #
 # Workspaces are important! They are a core feature of Xcode - don't exclude them :)
 #
 # Workspace layout is quite spammy. For reference:
 #
 # /(root)/
 #   /(project-name).xcodeproj/
 #     project.pbxproj
 #     /project.xcworkspace/
 #       contents.xcworkspacedata
 #       /xcuserdata/
 #         /(your name)/xcuserdatad/
 #           UserInterfaceState.xcuserstate
 #     /xcsshareddata/
 #       /xcschemes/
 #         (shared scheme name).xcscheme
 #     /xcuserdata/
 #       /(your name)/xcuserdatad/
 #         (private scheme).xcscheme
 #         xcschememanagement.plist
 #
 #

 ####
 # Xcode 4 - Deprecated classes
 #
 # Allegedly, if you manually "deprecate" your classes, they get moved here.
 #
 # We're using source-control, so this is a "feature" that we do not want!

 *.moved-aside

 ####
 # Files generated by automake

 Makefile
 autom4te.cache
 config.log
 config.status
 configure
 projects/demo/Makefile
 projects/demo/stk-demo
 projects/demo/Release
 projects/demo/Debug
 projects/effects/Makefile
 projects/effects/effects
 projects/effects/Release
 projects/effects/Debug
 projects/eguitar/Makefile
 projects/eguitar/eguitar
 projects/eguitar/Release
 projects/eguitar/Debug
 projects/examples/Makefile
 projects/examples/audioprobe
 projects/examples/bethree
 projects/examples/controlbee
 projects/examples/crtsine
 projects/examples/duplex
 projects/examples/foursine
 projects/examples/grains
 projects/examples/inetIn
 projects/examples/inetOut
 projects/examples/libMakefile
 projects/examples/midiprobe
 projects/examples/play
 projects/examples/playsmf
 projects/examples/record
 projects/examples/rtsine
 projects/examples/sine
 projects/examples/sineosc
 projects/examples/threebees
 projects/examples/Release
 projects/examples/Debug
 projects/ragamatic/Makefile
 projects/ragamatic/ragamat
 projects/ragamatic/Release
 projects/ragamatic/Debug
 src/libstk.a
 src/Release
 src/Debug
 src/Makefile
--- a/plugins/community/repos/Autodafe/dep/stk/INSTALL.md
+++ b/plugins/community/repos/Autodafe/dep/stk/INSTALL.md
@@ -0,0 +1,58 @@
 % The Synthesis ToolKit in C++ (STK)
 % Perry R. Cook and Gary P. Scavone
 % 1995--2017

 # The Synthesis ToolKit in C++ (STK)
 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 The Synthesis ToolKit in C++ can be used in a variety of ways, depending on your particular needs.  Some people simply choose the classes they need for a particular project and copy those to their project directory.  Others like to compile and link to a library of object files.  STK was not designed with one particular style of use in mind.

 ## Unix systems and MinGW

 1. If you downloaded the software from the git repository, first run autoconf,

        autoconf

 otherwise, if you downloaded the software from the STK source distribution, unpack the tar file,

        tar -xzf stk-4.x.x.tar.gz

 2. From within the directory containing this file, run configure:

        ./configure

 3. From within each project directory, type `make`.

 4. To compile a library of objects, type `make` from within the `src` directory.

 Several options can be passed to configure, including:

    --disable-realtime = only compile generic non-realtime classes
    --enable-debug = enable various debug output
    --with-alsa = choose native ALSA API support (default, linux only)
    --with-oss = choose native OSS API support (unixes only)
    --with-jack = choose native JACK server API support (linux and macintosh OS-X)
    --with-core = choose OS-X Core Audio API (macintosh OS-X only)
    --with-asio = choose ASIO API support (windows only)
    --with-ds = choose DirectSound API support (windows only)
    --with-wasapi = choose Windows Audio Session API support (windows only)

 It is now possible to specify more than one audio and MIDI API where supported.  Note, however, that the ALSA library is required in order to compile the RtMidi class in Linux if the `--with-oss` option is provided (only the OSS audio API will be used, not the OSS MIDI API).  Typing `./configure --help` will display all the available options.  In addition, it is possible to specify the RAWWAVES and INCLUDE paths to configure as (ex. to set to /home/me/rawwaves and /home/me/include):

    ./configure RAWWAVE_PATH='$(HOME)/rawwaves/'
    ./configure INCLUDE_PATH='$(HOME)/include/'

 The ending "/" is required for the RAWWAVES path.  The default behavior will set a relative path that works for the project files included with the distribution (assuming they are not moved).  You can also change the RAWWAVE_PATH dynamically via the static Stk::setRawwavePath() function.

 If you wish to use a different compiler than that selected by configure, specify that compiler in the command line (ex. to use CC):

    ./configure CXX=CC


 ## Windows

 MinGW support is provided in the configure script.  In addition, Visual C++ 6.0 project files are included for each of the example STK projects, though these may not work with more recent versions of Visual Studio.

 ##iOS

 You can integrate the STK in iOS projects either by using its iOS static library or Cocoapods. See the [iOS README file](iOS/README-iOS.md) for instructions. 
--- a/plugins/community/repos/Autodafe/dep/stk/LICENSE
+++ b/plugins/community/repos/Autodafe/dep/stk/LICENSE
@@ -0,0 +1,27 @@
 The Synthesis ToolKit in C++ (STK)

 Copyright (c) 1995--2017 Perry R. Cook and Gary P. Scavone

 Permission is hereby granted, free of charge, to any person obtaining
 a copy of this software and associated documentation files (the
 "Software"), to deal in the Software without restriction, including
 without limitation the rights to use, copy, modify, merge, publish,
 distribute, sublicense, and/or sell copies of the Software, and to
 permit persons to whom the Software is furnished to do so, subject to
 the following conditions:

 The above copyright notice and this permission notice shall be
 included in all copies or substantial portions of the Software.

 Any person wishing to distribute modifications to the Software is
 asked to send the modifications to the original developer so that they
 can be incorporated into the canonical version.  This is, however, not
 a binding provision of this license.

 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
 IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR
 ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF
 CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
--- a/plugins/community/repos/Autodafe/dep/stk/Makefile.in
+++ b/plugins/community/repos/Autodafe/dep/stk/Makefile.in
@@ -0,0 +1,41 @@
 ### Do not edit -- Generated by 'configure --with-whatever' from Makefile.in

 RM = /bin/rm

 REALTIME = @realtime@

 all :
 	cd src && $(MAKE)
 	cd projects/demo && $(MAKE) libdemo
 ifeq ($(REALTIME),yes)
 	cd projects/effects && $(MAKE) libeffects
 	cd projects/ragamatic && $(MAKE) libragamat
 	cd projects/eguitar && $(MAKE) libeguitar
 endif
 	cd projects/examples && $(MAKE) -f libMakefile

 clean : 
 	$(RM) -f *~
 	cd src && $(MAKE) clean
 	cd projects/demo && $(MAKE) clean
 ifeq ($(REALTIME),yes)
 	cd projects/effects && $(MAKE) clean
 	cd projects/ragamatic && $(MAKE) clean
 	cd projects/eguitar && $(MAKE) clean
 endif
 	cd projects/examples && $(MAKE) clean

 distclean: clean
 	$(RM) -rf config.log config.status autom4te.cache Makefile
 	cd src && $(MAKE) distclean
 	cd projects/demo && $(MAKE) distclean
 ifeq ($(REALTIME),yes)
 	cd projects/effects && $(MAKE) distclean
 	cd projects/ragamatic && $(MAKE) distclean
 	cd projects/eguitar && $(MAKE) distclean
 endif
 	cd projects/examples && $(MAKE) distclean

 install:
 	$(MAKE) -C src install

--- a/plugins/community/repos/Autodafe/dep/stk/README.md
+++ b/plugins/community/repos/Autodafe/dep/stk/README.md
@@ -0,0 +1,194 @@
 # The Synthesis ToolKit in C++ (STK)
 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 This distribution of the Synthesis ToolKit in C++ (STK) contains the following:

 * [`include`](include/):  STK class header files
 * [`src`](src/): STK class source files
 * [`rawwaves`](rawwaves): STK audio files (1-channel, 16-bit, big-endian)
 * [`doc`](doc): STK documentation
 * [`projects`](projects): example STK projects and programs

 Please read the [Legal and Ethical notes](#legal-and-ethical) near the bottom of this document and the [License](LICENSE).

 For compiling and installing STK, see the [INSTALL.md](INSTALL.md) file in this directory.

 ##Contents

 * [Overview](#overview)
 * [System Requirements](#system-requirements)
 * [What's New (and not so new)](#whats-new-and-not-so-new)
 * [Disclaimer](#disclaimer)
 * [Legal and Ethical](#legal-and-ethical)
 * [Further Reading](#further-reading)
 * [Perry's Notes From the Original Distribution](#perrys-notes-from-the-original-distribution)

 # OVERVIEW

 The Synthesis ToolKit in C++ (STK) is a set of open source audio
 signal processing and algorithmic synthesis classes written in the C++
 programming language.  STK was designed to facilitate rapid
 development of music synthesis and audio processing software, with an
 emphasis on cross-platform functionality, realtime control, ease of
 use, and educational example code.  The Synthesis ToolKit is extremely
 portable (most classes are platform-independent C++ code), and it's
 completely user-extensible (all source included, no unusual libraries,
 and no hidden drivers).  We like to think that this increases the
 chances that our programs will still work in another 5-10 years.  STK
 currently runs with "realtime" support (audio and MIDI) on Linux,
 Macintosh OS X, and Windows computer platforms.  Generic, non-realtime
 support has been tested under NeXTStep, Sun, and other platforms and
 should work with any standard C++ compiler.

 The only classes of the Synthesis ToolKit that are platform-dependent
 concern sockets, threads, mutexes, and real-time audio and MIDI input
 and output.  The interface for MIDI input and the simple Tcl/Tk
 graphical user interfaces (GUIs) provided is the same, so it's easy to
 experiment in real time using either the GUIs or MIDI.  The Synthesis
 ToolKit can generate simultaneous SND (AU), WAV, AIFF, and MAT-file
 output soundfile formats (as well as realtime sound output), so you
 can view your results using one of a large variety of sound/signal
 analysis tools already available (e.g. Snd, Cool Edit, Matlab).

 The Synthesis Toolkit is not one particular program.  Rather, it is a
 set of C++ classes that you can use to create your own programs.  A
 few example applications are provided to demonstrate some of the ways
 to use the classes.  If you have specific needs, you will probably
 have to either modify the example programs or write a new program
 altogether. Further, the example programs don't have a fancy GUI
 wrapper. If you feel the need to have a "drag and drop" graphical
 patching GUI, you probably don't want to use the ToolKit. Spending
 hundreds of hours making platform-dependent graphics code would go
 against one of the fundamental design goals of the ToolKit - platform
 independence.

 For those instances where a simple GUI with sliders and buttons is
 helpful, we use Tcl/Tk (http://dev.scriptics.com) which is freely
 distributed for all the supported ToolKit platforms. A number of
 Tcl/Tk GUI scripts are distributed with the ToolKit release.  For
 control, the Synthesis Toolkit uses raw MIDI (on supported platforms),
 and SKINI (Synthesis ToolKit Instrument Network Interface, a MIDI-like
 text message synthesis control format).


 # SYSTEM REQUIREMENTS

 See the individual README's (eg. README-linux) in the /doc directory
 for platform specific information and system requirements.  In
 general, you will use the configure script to create Makefiles on unix
 platforms (and MinGW) or the VC++ workspace files to compile the
 example programs.  To use the Tcl/Tk GUIs, you will need Tcl/Tk
 version 8.0 or higher.


 # WHAT'S NEW (AND NOT SO NEW)

 Despite being available in one form or another since 1996, we still
 consider STK to be alpha software.  We attempt to maintain backward
 compatability but changes are sometimes made in an effort to improve
 the overall design or performance of the software.  Please read the
 "Release Notes" in the /doc directory to see what has changed since
 the last release.

 A new StkFrames class has been created to facilitate the handling and
 passing of multichannel, vectorized audio data.  All STK classes have
 been updated to include tick() functions that accept StkFrames
 arguments.

 The control message handling scheme has been simplified greatly
 through the use of the Messager class.  It is now possible to have
 access to simultaneous piped, socketed, and/or MIDI input control
 messages.  In most cases, this should eliminate the use of the
 Md2Skini program.

 Realtime audio input capabilities were added to STK with release 3.0,
 though the behavior of such is very hardware dependent.  Under Linux
 and Macintosh OS-X, audio input and output are possible with very low
 latency.  Using the Windoze DirectSound API, minimum dependable output
 sound latency seems to be around 20 milliseconds or so, while input
 sound latency is generally higher.  Performance with the ASIO audio
 API on Windoze provides much better performance.

 As mentioned above, it is possible to record the audio ouput of an STK
 program to .snd, .wav, .raw, .aif, and .mat (Matlab MAT-file) output
 file types.  Though somewhat obsolete, the program Md2Skini can be
 used to write SKINI scorefiles from realtime MIDI input.  Finally, STK
 should compile with non-realtime functionality on any platform with a
 generic C++ compiler.

 For those who wish to make a library from the core STK classes, the
 configure script generates a Makefile in the src directory that will
 accomplish that.


 # DISCLAIMER

 You probably already guessed this, but just to be sure, we don't
 guarantee anything works.  :-) It's free ... what do you expect?  If
 you find a bug, please let us know and we'll try to correct it.  You
 can also make suggestions, but again, no guarantees.  Send email to
 the mail list.


 # LEGAL AND ETHICAL

 This software was designed and created to be made publicly available
 for free, primarily for academic purposes, so if you use it, pass it
 on with this documentation, and for free.

 If you make a million dollars with it, it would be nice if you would
 share. If you make compositions with it, put us in the program notes.

 Some of the concepts are covered by various patents, some known to us
 and likely others which are unknown.  Many of the ones known to us are
 administered by the Stanford Office of Technology and Licensing.

 The good news is that large hunks of the techniques used here are
 public domain.  To avoid subtle legal issues, we'll not state what's
 freely useable here, but we'll try to note within the various classes
 where certain things are likely to be protected by patents.


 # FURTHER READING

 For complete documentation on this ToolKit, the classes, etc., see the
 doc directory of the distribution or surf to
 http://ccrma.stanford.edu/software/stk/.  Also check the platform
 specific README's for specific system requirements.


 # PERRY'S NOTES FROM THE ORIGINAL DISTRIBUTION

 This whole world was created with no particular hardware in mind.
 These examples are intended to be tutorial in nature, as a platform
 for the continuation of my research, and as a possible starting point
 for a software synthesis system.  The basic motivation was to create
 the necessary unit generators to do the synthesis, processing, and
 control that I want to do and teach about.  Little thought for
 optimization was given and therefore improvements, especially speed
 enhancements, should be possible with these classes.  It was written
 with some basic concepts in mind about how to let compilers optimize.

 Your question at this point might be, "But Perry, with CMix, CMusic,
 CSound, CShells, CMonkeys, etc. already cluttering the landscape, why
 a new set of stupid C functions for music synthesis and processing?"
 The answers lie below.

 1) I needed to port many of the things I've done into something which is generic enough to port further to different machines.

 2) I really plan to document this stuff, so that you don't have to be me to figure out what's going on. (I'll probably be sorry I said this in a couple of years, when even I can't figure out what I was thinking.)

 3) The classic difficulties most people have in trying to implement physical models are:

    A) They have trouble understanding the papers, and/or in turning the theory into practice.

    B) The Physical Model instruments are a pain to get to oscillate, and coming up with stable and meaningful parameter values is required to get the models to work at all.

 This set of C++ unit generators and instruments might help to diminish the scores of emails I get asking what to do with those block diagrams I put in my papers.

 4) I wanted to try some new stuff with modal synthesis, and implement some classic FM patches as well.

 5) I wanted to reimplement, and newly implement more of the intelligent and physical performer models I've talked about in some of my papers. But I wanted to do it in a portable way, and in such a way that I can hook up modules quickly.  I also wanted to make these instruments connectable to such player objects, so folks like Brad Garton who really think a lot about the players can connect them to my instruments, a lot about which I think.

 6) More rationalizations to follow . . .

--- a/plugins/community/repos/Autodafe/dep/stk/bin/treesed
+++ b/plugins/community/repos/Autodafe/dep/stk/bin/treesed
@@ -0,0 +1,189 @@
 #!/usr/bin/perl

 # treesed
 # Written January 1996 by Rick Jansen (rick@sara.nl)
 # URL: http://www.sara.nl/rick

 # usage: treesed pattern1 pattern2 -tree 
 #        treesed pattern1 pattern2 -files file1 file2 ... 

 # example: treesed href HREF -files *.html

 # Treesed searches for pattern1 and replaces pattern1 by pattern2
 # if pattern2 supplied. If only pattern1 given treesed just searches.
 # Treesed will search in all files and subdirectories of the current
 # directory



 #--------------------------------------------------------
 # Parameters

 $DoEdit=0;
 $search_pattern = $ARGV[0];
 $search_pattern =~ s/(\W)/\\$1/g;  # escape regexp chars
 shift;

 while ($#ARGV >= 0) {
  
  if ($ARGV[0] eq '-files') {
    @temp_ls = @ARGV[1 ..  $#ARGV];
    # Get list of files, skip dirs
    foreach $file (@ARGV[1 ..  $#ARGV]) {
      if (-f $file) { 
        push(@ls, $file); 
      }
    }
    last;
  }
  elsif ($ARGV[0] eq '-tree') {
    &Get_LS;
    last;
  }

  if (! -f $ARGV[0]) {
    if (defined($replacement_pattern)) {
      print "usage: treesed pattern1 <pattern2> -tree/-files <files>\n";
      exit(1);
    }

    $replacement_pattern = $ARGV[0];
    #$replacement_pattern =~ s/(\W)/\\$1/g;  # escape regexp chars
    $DoEdit=1;
    shift;
  }

 }

 # No files?
 if ($#ls < 0) {
  print "xx No input files\n";
  exit(1);
 }

 print "search_pattern: $search_pattern\n";
 print "replacement_pattern: $replacement_pattern\n";
 if ($DoEdit) {
  print "\n** EDIT MODE!\n\n"; }
 else {
  print "\n** Search mode\n\n";
 }

 #foreach $file (@ls) {
 #  print "$file \n";
 #}
  

 #--------------------------------------------------------
 # Search list of files for pattern

 $linepos=0;

 $| = 1;  # Force flush after every write
 foreach $file (@ls) {
  #print "$file\n";
  print '.';
  $linepos++;
  if ($linepos > 50) {
    $linepos=0;
    print "\n";
  }

  if (!open(FILE, $file)) {
    print "\nCould not open $file\n";
    next;
  }

  $Found = 0;
  $Count = 0;
  $lineno = 0;
  @lines = ();
  while (<FILE>) {
    $lineno++;
    if (/$search_pattern/i) {
      #print;
      $Count++; 
      $Found = 1;
      push(@lines, $lineno);
    }
  }
  close(FILE);
  if ($Found) { 
    print "\n$file: $Count lines on: @lines\n"; 
  }

  if ($Found && $DoEdit) { &Edit($file); }
  
 }
 $| = 0;
 print "\n";


 exit(0);


 #--------------------------------------------------------
 # Edit file

 sub Edit {

 # Replace $ARGV[0] with $ARGV[1] in $file

 local($file) = @_;
 local($bakfile) = $file.'.'.$$;

 # First create backup
 open(FILE, $file) || die "Could not open $file for read\n";
 open(BAKFILE, ">$bakfile")  || die "Could not open $bakfile for backup\n";
 while (<FILE>) {
  print BAKFILE;
 }
 close(BAKFILE);
 close(FILE);

 # Now replace $ARGV[0] by $ARGV[1] in the backupfile, 
 # result into $file
 open(BAKFILE, $bakfile) || die "Could not open $bakfile for read\n";
 open(FILE,">$file") || die "Could not open $file for write\n";
 $Count=0;
 while (<BAKFILE>) {
  if (/$search_pattern/i) { $Count++; }
  s/$search_pattern/$replacement_pattern/gi;
  print FILE;
 }
 close(BAKFILE);
 close(FILE);

 print 
 "\nReplaced $search_pattern by $replacement_pattern on $Count lines in $file\n";

 }  #sub Edit

 #--------------------------------------------------------

 sub Get_LS {

 # Get a list of full path names into array @ls

 local(@localls)=`ls -R1`;
 local($item,$Dir);

 #print "localls: @localls\n";
 $Dir='';
 foreach $item (@localls) {
  #print "$item\n";
  if ($item =~ /:$/) { 
    $Dir=$item; 
    chop($Dir);
    $Dir =~ s/:$/\//;
  }
  else {
    chop($item);
    $item = $Dir.$item;
    if ($item !~ /^\s*$/) { push(@ls, $item); }
  }
 }
@localls=();

 }  # sub Get_LS

--- a/plugins/community/repos/Autodafe/dep/stk/config/config.guess
+++ b/plugins/community/repos/Autodafe/dep/stk/config/config.guess
--- a/plugins/community/repos/Autodafe/dep/stk/config/config.sub
+++ b/plugins/community/repos/Autodafe/dep/stk/config/config.sub
--- a/plugins/community/repos/Autodafe/dep/stk/config/install.sh
+++ b/plugins/community/repos/Autodafe/dep/stk/config/install.sh
--- a/plugins/community/repos/Autodafe/dep/stk/configure.ac
+++ b/plugins/community/repos/Autodafe/dep/stk/configure.ac
@@ -0,0 +1,225 @@
 # Process this file with autoconf to produce a configure script.
 AC_INIT(STK, 4.6.0, gary@music.mcgill.ca, stk)
 AC_CONFIG_AUX_DIR(config)
 AC_CONFIG_SRCDIR(src/Stk.cpp)
 AC_CONFIG_FILES(Makefile src/Makefile projects/demo/Makefile projects/effects/Makefile projects/ragamatic/Makefile projects/examples/Makefile projects/examples/libMakefile projects/eguitar/Makefile)

 # Fill GXX with something before test.
 AC_SUBST( GXX, ["no"] )

 # Checks for programs.
 AC_PROG_CXX(g++ CC c++ cxx)
 AC_PROG_RANLIB
 AC_PATH_PROG(AR, ar, no)
 if [[ $AR = "no" ]] ; then
    AC_MSG_ERROR("Could not find ar - needed to create a library");
 fi

 # Checks for header files.
 AC_HEADER_STDC
 AC_CHECK_HEADERS(fcntl.h sys/ioctl.h sys/time.h termio.h unistd.h)

 # Checks for typedefs, structures, and compiler characteristics.
 AC_C_CONST
 AC_TYPE_SIZE_T
 AC_HEADER_TIME
 AC_C_BIGENDIAN
 AC_EGREP_CPP(yes,
 [#ifndef WORDS_BIGENDIAN
  yes
 #endif
 ], [AC_SUBST( byte_order, [-D__LITTLE_ENDIAN__] )] )

 AC_MSG_CHECKING(for RAWWAVE_PATH argument)
 AC_SUBST( rawwaves, $RAWWAVE_PATH )
 AC_MSG_RESULT($RAWWAVE_PATH)

 AC_MSG_CHECKING(for INCLUDE_PATH argument)
 AC_SUBST( include, $INCLUDE_PATH )
 AC_MSG_RESULT($INCLUDE_PATH)

 # Check for realtime support disable
 AC_MSG_CHECKING(whether to compile realtime support)
 AC_ARG_ENABLE(realtime,
         [  --disable-realtime = only compile generic non-realtime classes],
         realtime=$enableval)
 if test "$realtime" = "no"; then
   AC_SUBST( sound_api, [] )
 else
   AC_SUBST( realtime, [yes] )
 fi
 AC_MSG_RESULT($realtime)

 AC_MSG_CHECKING(whether to build the static library)
 AC_ARG_ENABLE(static,
         [  --disable-static = do not compile static library ],
 	 build_static=$enableval,
 	 build_static=yes)
 AC_SUBST(build_static)
 AC_MSG_RESULT($build_static)

 AC_MSG_CHECKING(whether to build the shared library)
 AC_ARG_ENABLE(shared,
         [  --enable-shared = compile the shared library ],
 	 build_shared=$enableval,
 	 build_shared=no)
 AC_SUBST(build_shared)
 AC_MSG_RESULT($build_shared)

 if test x$build_static = xno -a x$build_shared = xno ; then
        AC_MSG_ERROR([ both static and shared libraries are disabled], 1)
 fi

 # Check for math library
 AC_CHECK_LIB(m, cos, , AC_MSG_ERROR(math library is needed!))

 # Check for debug
 AC_MSG_CHECKING(whether to compile debug version)
 AC_ARG_ENABLE(debug,
        [  --enable-debug = enable various debug output],
        debug=$enableval)
 if test "$debug" = "yes"; then
   AC_SUBST( cppflag, ["-D_STK_DEBUG_ -D__RTAUDIO_DEBUG__ -D__RTMIDI_DEBUG__"] )
   AC_SUBST( cxxflag, ["-g"] )
   AC_SUBST( object_path, [Debug] )
 else
  AC_SUBST( debug, [no] )
  AC_SUBST( cppflag, [] )
  AC_SUBST( cxxflag, [-O3] )
  AC_SUBST( object_path, [Release] )
 fi
 AC_MSG_RESULT($debug)

 # Checks for functions
 if test $realtime = yes; then
  AC_CHECK_FUNCS(select socket)
  AC_CHECK_FUNC(gettimeofday, [cppflag="$cppflag -DHAVE_GETTIMEOFDAY"], )
 fi

 # For -I and -D flags
 CPPFLAGS="$CPPFLAGS $cppflag"

 # For debugging and optimization ... overwrite default because it has both -g and -O2
 CXXFLAGS="$cxxflag"

 # Check compiler and use -Wall if gnu.
 if [test $GXX = "yes" ;] then
  AC_SUBST( cxxflag, [-Wall] )
 fi

 CXXFLAGS="$CXXFLAGS $cxxflag"

 AC_CANONICAL_HOST

 basesharedname="libstk-\$(RELEASE)"

 AC_SUBST( sharedlib, ["libstk.so"] )
 AC_SUBST( sharedname, [${basesharedname}.so] )
 AC_SUBST( libflags, ["-shared -Wl,-soname,${basesharedname}.so -o $sharedname"] )
 case $host in
  *-apple*)
  AC_SUBST( sharedlib, ["libstk.dylib"] )
  AC_SUBST( sharedname, ["${basesharedname}.dylib"] )
  AC_SUBST( libflags, ["-dynamiclib -o ${basesharedname}.dylib"] )
 esac

 if test $realtime = yes; then
  # Checks for package options and external software
  AC_MSG_CHECKING(for audio API)

  AC_ARG_WITH(jack, [  --with-jack = choose JACK server support (mac and linux only)])
  AS_IF([test "x$with_jack" == "xyes"], [
 api="$api -D__UNIX_JACK__"
  AC_MSG_RESULT(using JACK)
  AC_CHECK_LIB(jack, jack_client_open, , AC_MSG_ERROR(JACK support requires the jack library!))])

  case $host in
    *-*-linux*)
    # Look for ALSA flag
    AC_ARG_WITH(alsa, [  --with-alsa = choose native ALSA API support (linux only)])
    AS_IF([test "x$with_alsa" == "xyes"], [
    api="$api -D__LINUX_ALSA__"
    AC_MSG_RESULT(using ALSA)
    AC_CHECK_LIB(asound, snd_pcm_open, , AC_MSG_ERROR(ALSA support requires the asound library!))])

    # Look for OSS flag
    AC_ARG_WITH(oss, [  --with-oss = choose OSS API support (unixes only)])
    AS_IF([test "x$with_oss" == "xyes"], [
    api="$api -D__LINUX_OSS__ -D__LINUX_ALSA__"
    AC_MSG_RESULT(using OSS)
    AC_CHECK_LIB(asound, snd_pcm_open, , AC_MSG_ERROR(OSS support requires ALSA for RtMidi!))])

    # If no audio api flags specified, use ALSA
    AS_IF([test "$api" == ""], [
      AC_MSG_RESULT(using ALSA)
      AC_SUBST( api, [-D__LINUX_ALSA__] )
      AC_CHECK_LIB(asound, snd_pcm_open, , AC_MSG_ERROR(ALSA support requires the asound library!))
    ])

    AC_CHECK_LIB(pthread, pthread_create, , AC_MSG_ERROR(RtAudio requires the pthread library!))
    ;;

    *-apple*)
    # Look for Core flag
    AC_ARG_WITH(core, [  --with-core = choose CoreAudio API support (mac only)])
    AS_IF([test "x$with_core" == "xyes"], [
    api="$api -D__MACOSX_CORE__"
    AC_MSG_RESULT(using CoreAudio)
    AC_CHECK_HEADER(CoreAudio/CoreAudio.h, [], [AC_MSG_ERROR(CoreAudio header files not found!)] )
    LIBS="$LIBS -framework CoreAudio -framework CoreFoundation -framework CoreMIDI" ])

    # If no audio api flags specified, use CoreAudio
    AS_IF([test "$api" == ""], [
      AC_SUBST( api, [-D__MACOSX_CORE__] )
      AC_MSG_RESULT(using CoreAudio)
      AC_CHECK_HEADER(CoreAudio/CoreAudio.h,
      [],
      [AC_MSG_ERROR(CoreAudio header files not found!)] )
      AC_SUBST( LIBS, ["-framework CoreAudio -framework CoreFoundation -framework CoreMIDI"] )
    ])

    AC_CHECK_LIB(pthread, pthread_create, , AC_MSG_ERROR(RtAudio requires the pthread library!))
    ;;

    *-mingw32*)
    AC_ARG_WITH(asio, [  --with-asio = choose ASIO API support (windoze only)])
    AS_IF([test "x$with_asio" == "xyes"], [
    api="$api -D__WINDOWS_ASIO__"
    AC_MSG_RESULT(using ASIO)
    AC_SUBST( objects, ["asio.o asiodrivers.o asiolist.o iasiothiscallresolver.o"] ) ])

    # Look for DirectSound flag
    AC_ARG_WITH(ds, [  --with-ds = choose DirectSound API support (windoze only)])
    AS_IF([test "x$with_ds" == "xyes"], [
    api="$api -D__WINDOWS_DS__"
    AC_MSG_RESULT(using DirectSound)
    LIBS="-ldsound $LIBS" ])

    # Look for WASAPI flag
    AC_ARG_WITH(wasapi, [  --with-wasapi = choose Windows Audio Session API support (windoze only)])
    AS_IF([test "x$with_wasapi" == "xyes"], [
    api="$api -D__WINDOWS_WASAPI__"
    AC_MSG_RESULT(using WASAPI)
    LIBS="-luuid -lksuser $LIBS" ])

    # If no audio api flags specified, use DirectSound
    AS_IF([test "$api" == ""], [
      AC_SUBST( api, [-D__WINDOWS_DS__] )
      AC_MSG_RESULT(using DirectSound)
      LIBS="-ldsound -lwinmm $LIBS"
    ])

    api="$api -D__WINDOWS_MM__"
    LIBS="-lole32 -lwinmm -lwsock32 $LIBS"
    ;;

    *)
    # Default case for unknown realtime systems.
    AC_MSG_ERROR(Unknown system type for realtime support ... try --disable-realtime argument!)
    ;;
  esac

 CPPFLAGS="$CPPFLAGS $api"
 fi

 AC_OUTPUT
--- a/plugins/community/repos/Autodafe/dep/stk/doc/README-Linux.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/README-Linux.txt
@@ -0,0 +1,13 @@
 The Synthesis ToolKit in C++ (STK)

 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 Please read the file README and INSTALL for more general STK information.

 Realtime audio support for Linux currently includes the Advanced Linux Sound Architecture (ALSA), the JACK low-latency audio server, and/or Open Sound System (OSS version 4.0 and higher only) APIs.  That said, the OSS API support has not been tested in several years and is not considered a high priority.  One or more APIs are selected during compilation using the __LINUX_ALSA__, __UNIX_JACK__, and/or __LINUX_OSS__ definitions.  Because the ALSA library is now integrated into the standard Linux kernel, it is the default audio/MIDI API with STK versions 4.2 and higher.

 Realtime MIDI support Linux currently includes the Jack and ALSA sequencer support.  Native OSS MIDI support no longer exists in RtMidi.  If the __LINUX_OSS__ preprocessor definition is specified, only OSS audio support will be compiled and RtMidi will still be compiled using the ALSA API.  For this reason, STK now requires the asound library for realtime support (unless only using the Jack API).  Realtime programs must also link with the pthread library.

 STK should compile without much trouble under Linux.  Since all Linux distributions typically include the GNU makefile utilities, you should be able to use the default Makefiles.  Typing "make" in a project directory will initiate the compilation process (after initially running the configure script in the top-level directory).


--- a/plugins/community/repos/Autodafe/dep/stk/doc/README-MacOSX.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/README-MacOSX.txt
@@ -0,0 +1,16 @@
 The Synthesis ToolKit in C++ (STK)

 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 Please read the file README and INSTALL for more general STK information.

 The default realtime support for Macintosh OS X uses the CoreAudio HAL API and is specified during compilation using the __MACOSX_CORE__ preprocessor definition.  There is also support for the JACK audio server using the __UNIX_JACK__ preprocessor definition.

 It is necessary to install the OS X developer kit (or the command line tools) in order to compile STK.  STK was successfully tested on the latest version of OS X.

 Tcl/Tk on OS X:

 I think that tcl/tk interpreter is now included in the XCode package, since I haven't had to download it for several years now.

 It appears that socket support in Tcl/Tk on OS X uses the Nagle algorithm, which produces poor response between changes made in the tcl/tk script and the resulting audio updates.  Note that this is only a problem when using a socket connection from a Tcl/Tk script.

--- a/plugins/community/repos/Autodafe/dep/stk/doc/README-SGI.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/README-SGI.txt
@@ -0,0 +1,7 @@
 The Synthesis ToolKit in C++ (STK)

 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 Please read the file README and INSTALL for more general STK information.

 Since STK version 4.3, realtime support for IRIX has been discontinued due to an inability to test it.  If you need realtime support on an SGI, go back to version 4.2.1.  Release 4.0 of STK is confirmed to compile (with various warnings) using CC version 7.30.
--- a/plugins/community/repos/Autodafe/dep/stk/doc/README-Win.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/README-Win.txt
@@ -0,0 +1,35 @@
 The Synthesis ToolKit in C++ (STK)

 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 Please read the file README for more general STK information.

 The configure script supports MinGW.  As well, STK is distributed with Visual C++ .NET project and workspace files (though these may no longer work with current versions of Visual Studio).  It no longer compiles with Visual C++ 6.0.

 With Windows XP/7, piping works as under unix.  Simply fire up the script files (ex. StkDemo.bat) by either double-clicking on them or from within a shell.

 IMPORTANT VC++ NOTE: When compiling "release" versions of STK programs, link to the release multithreaded library.  When compiling "debug" versions, link to the debug multithreaded library.  Compiler errors will result otherwise.

 The DirectSound, WASAPI and Steinberg ASIO audio APIs are supported for realtime audio input/output.  The Visual C++ project files included with this distribution are configured to use all supported APIs.  In order to use the ASIO API, it is necessary to use the preprocessor definition __WINDOWS_ASIO__, as well as include most of the files in the /src/include/ directory (i.e. asio.h, asio.cpp, ...).  If you have a good quality soundcard and a native ASIO driver (not emulated), you are likely to get much better input/output response using that.

 When using the DirectSound API for audio input, latency can be high.  If you experience realtime audio "stuttering", you should experiment with different "buffer size" and "number of buffers" values.

 Realtime MIDI input/output is supported by RtMidi using the winmm.lib API and requires the __WINDOWS_MM__ preprocessor definition.

 Visual C++ workspaces have been created for the various STK projects.  Everything has already been configured for you.  The intermediate .obj files will be written to either the "Release" or "Debug" directories, but the executable files will be written to the main project directories (where they need to be for proper execution).  If you should somehow lose or hose the VC++ workspace file for a project, then you will have to do a LOT of configuring to recreate it ... it's probably easier just to download the distribution again from our WWW sites.  Anyway, for your benefit and mine, here is a list of things that need to be added to the various "Project Settings" (this was for VC 6.0 ... things have changed with the newer versions of the VC compiler):

 1. Under General: Set "Output files:" to <blank> (this will put the executable in the main project directory.

 2. Under C/C++ > Code Generation: Set "Use run-time library:" to Multithreaded (use "debug" versions for the debug configuration).

 3. Under Link > General:  Add winmm.lib, dsound.lib, and Wsock32.lib to the end of the Object/library modules list.

 4. Under C/C++ > Preprocessor: Add "../../include" directory to the "extra include" field.

 5. Under C/C++ > Preprocessor: Add "__WINDOWS_DS__", "__WINDOWS_MM__", and "__LITTLE_ENDIAN__ to the definitions field.

 6. Add all the necessary files to the project.

 Remember that items 1-5 above need to be done for each project and for each configuration.  There might be an easy way to make global changes, but I couldn't figure it out.

 To use the Tcl/Tk GUIs, you will have to install Tcl/Tk.
--- a/plugins/community/repos/Autodafe/dep/stk/doc/ReleaseNotes.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/ReleaseNotes.txt
@@ -0,0 +1,289 @@
 The Synthesis ToolKit in C++ (STK)

 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 v.4.6.0 (31 August 2017)
 - see github site for complete details
 - various build system updates
 - fixes in FileWvIn / FileLoop for normalisation and scaling, as well as file opening
 - bug fix for MAT-files in FileWrite
 - bug fix in MidiFileIn.cpp for timing and time-code formats
 - updated versions of RtAudio and RtMidi

 v4.5.1 (22 February 2017)
 - fix for FileWvIn / FileLoop classes to avoid keeping files open if not necessary
 - miscellaneous bug fixes, documented on GitHub site (github.com/thestk/stk)
 - update to play.cpp example to play mono files as stereo
 - bug fix in DelayL::setDelay() function
 - miscellanous build bug fixes

 v4.5.0: (26 April 2014)
 - updated versions of RtAudio and RtMidi, with associated renaming of RtError class to either RtAudioError or RtMidiError and addition of WASAPI support in Windows
 - added support in FileRead for little-endian AIFC file format
 - new iOS project files (thanks to Ariel Elkin)
 - bug fix in FreeVerb that could cause crackling for stereo input
 - various bug fixes and updates to minimize compiler warnings
 - ADSR fix for decay/release time calculations
 - various updates to build system

 v4.4.4: (24 August 2012)
 - new FreeVerb class (thanks to Greg Burlet)
 - new Guitar class
 - new electric guitar project
 - cleaned / revised Shakers class
 - updated versions of RtAudio and RtMidi
 - bug fix in LentPitShift
 - bug fix in Echo constructor
 - bug fix in FileWvIn (file size when chunking)
 - bug fix in StkFrames copy constructor

 v4.4.3: (30 August 2011)
 - changed SINT24 to be lower 3 bytes of 32-bit word
 - bug fixes to vectorized tick functions in Effects classes
 - updated versions of RtAudio and RtMidi
 - fix to ADSR bugs
 - updates to the internal argument checking and reporting scheme
 - updates to Bowed class (thanks to Esteban Maestre!)
 - fixes for 24-bit support in FileRead and FileWrite
 - added WAVE_FORMAT_EXTENSIBLE support in FileWrite
 - added sample rate variable reading and writing for MAT-files in FileRead and FileWrite

 v4.4.2: (4 February 2011)
 - added various header file includes for newer compilers
 - new LentPitShift class (thanks to Francois Germain)
 - added "addTo" function to Delay class
 - updates to RtAudio and RtMidi
 - bug fixes in Voicer class (thanks Richard Dobson!)
 - bug fixes in Granulate class
 - added Makefile.in to compile library and all projects, as well as clean and distclean all

 v4.4.1: (3 June 2010)
 - added multi-channel/frame tick() virtual function to WvIn and WvOut abstract base classes (required update to RtWvOut class)
 - updated configure script to select g++ compiler by default
 - in demo.cpp: removed voicer grouping for messages, fixing polyphony when messages are on the same MIDI/SKINI channel
 - updates to RtAudio and RtMidi

 v4.4: (30 April 2010)
 - all classes embedded in the "stk" namespace (except RtAudio, RtMidi, and RtError)
 - class WaveLoop renamed FileLoop
 - significant efficiency improvements via code restructuring and inlining
 - some class source (.cpp) files deleted as part of inlining (Generator, Filter, Function, WvIn, WvOut, Effect, Instrmnt, BowTable, ReedTable, JetTable, Vector3D)
 - updates to RtAudio and RtMidi
 - previous "tickFrame()" functions renamed "tick" for more consistent API
 - more consistent and scalable approach to multichannel data and computations
 - multichannel support added to Granulate class
 - Filter class made abstract.  New Iir and Fir classes made for non-order-specific filtering.
 - new TapDelay class
 - SubNoise class deleted (same as sub-sampled "ticking" of Noise class)


 v4.3.1: (7 December 2007)
 - further headerless file support in FileRead
 - bug fix in RtWvOut.cpp
 - added configure support for MinGW
 - updates to RtAudio and RtMidi for MinGW
 - changes to channel assignment in demo.cpp


 v4.3.0: (13 August 2007)
 - an official MIT-like license
 - new functionality to automatically update class data when the STK sample rate changes (partly implemented)
 - updates for new RtAudio version 4.0
 - removed RtDuplex class, users should use RtAudio directly with a callback function
 - bug fix in interpolate() function in Stk.h for non-interleaved data
 - fixes / improvements to the Granulate class
 - fix in Whistle when doing animation
 - fixes in BlitSquare for frequency, harmonics, and dc offset
 - updates to Makefiles for non-realtime compile
 - fix in demo.cpp for voice channel assignment
 - updated versions of RtMidi and RtAudio
 - updated ASIO files for MinGW compiler
 - new FAQ in documentation
 - MAT-file bug fix in FileRead class


 v4.2.1: (14 October 2005)
 - greatly expanded StkFrames functionality (including interpolation and indexing by channel/frame)
 - new Granulate granular synthesis class
 - new Blit, BlitSaw, and BlitSquare bandlimited waveform classes (thanks to Robin Davies!)
 - removed Table class ... all functionality (including interpolation) now in StkFrames and FileRead classes
 - revised Socket class (now abstract) and added TcpServer, TcpClient, and UdpSocket subclasses
 - added Stk::showWarnings() and Stk::printErrors() functions to dis/enable warning and error printouts
 - extracted file I/O functionality to new FileRead and FileWrite classes
 - revised WvIn / WvOut class structure (WvIn / WvOut now abstract and file I/O functionality in new FileWvIn / FileWvOut subclasses)
 - new SineWave class which calculates its own static table of variable length (no rawwave dependency)
 - new sinewave.raw file of length 1024 samples (used to be 256)
 - TcpWvIn and TcpWvOut renamed InetWvIn and InetWvOut, with added support for UDP sockets
 - fixed bug in WvOut tickFrame( const  StkFrames &frames ) function
 - fixed bug in demo.cpp when writing output soundfiles without realtime output
 - added "binary" open flag to MidiFileIn class for Windows
 - fixed oversized MAT-file header in WvOut.cpp
 - fixed case statement bug in MidiFileIn.cpp for sysex
 - added missing getDelay() function to DelayA.cpp
 - fixed modDepth omission in Chorus.cpp
 - fixed DC blocker initialization bug in Flute.cpp
 - changed Filter class behavior so no default clearing of state when changing coefficients
 - bug fixes to RtAudio, especially for Windows DirectSound and ASIO (thanks to Robin Davies)
 - bug fixes to RtMidi, especially for Linux (thanks to Pedro Pedro Lopez-Cabanillas)


 v4.2.0: (4 October 2004)
 - simultaneous multiple audio APIs supported at compile time
 - fixed hidden overloaded virtual functions
 - new Asymp exponential envelope class
 - various changes to better conform to standard C++ programming practices
 - MY_FLOAT type converted to StkFloat and changed throughout (use treesed utility to search/replace in old files)
 - most example programs rewritten to use an audio callback paradigm (which works better in OS-X)
 - new StkFrames class for vectorized multichannel data and associated new tick() functions making use of StkFrames
 - new RtMidi class with MIDI output capabilities (API changes)
 - new MidiFileIn class for reading MIDI files
 - revised Filter classes to use std::vectors for coefficients (API changes)
 - revised Messager class (now queues messages for retrieval) (API changes)
 - new abstract parent Effect class for various effects
 - added setT60 function to all reverbs
 - new abstract parent Generator class for various signal sources
 - new abstract parent Function class for tables and various non-linear functions
 - Skini class completely rewritten (simplified) using the C++ STL (API changes)
 - WvOut classes now clip to -1.0 to +1.0 and report out of range
 - new Mutex class
 - turned Nagle algorithm off by default in Socket class
 - error reporting standardized in all classes

 v4.1.3: (22 March 2004)
 - bug fix in RtAudio for Windows DirectSound output only support

 v4.1.2: (15 March 2004)
 - added Linux JACK support to RtAudio
 - added optional doNormalize argument to WvIn to allow specification of data normalization or not
 - added volume control to demo program and various tcl scripts
 - added support for dynamic rawwavePath() setting
 - WaveLoop bug fix
 - fixed bug in ADSR::setReleaseTime() method
 - fixed missing initialization of apInput in non-default constructor of DelayA class
 - added time seeding of random number generator to Noise constructor
 - update to the contentsAt() method of Delay class
 - WAV file fixes (8-bit) in WvIn and WvOut classes
 - configure changes
 - updated <iostream> include statements and appended "std::" as necessary throughout for compatibility with gcc 3

 v4.1.1: (24 October 2002)
 - bug fix in RtAudio for Macintosh OS X and Windows ASIO duplex operation
 - windows ASIO fix in Stk.h
 - documentation updates
 - expanded tutorial
 - fixed RtDuplex omission in src Makefile

 v4.1: (8 October 2002)
 - Macintosh OS X support added
 - new Whistle class
 - added Voicer, SingWave, and VoicForm classes
 - improvements/fixes to the banded waveguide instruments
 - demo program now uses Voicer, allowing polyphony
 - demo tcl/tk scripts changed to use SKINI PitchChange instead of PitchBend
 - demo program response to PitchBend modified to octave up/down
 - several RtAudio fixes and improvements (OS X and Windows ASIO support added)
 - added nextOut() method to Delay classes
 - documentation fixes for Reverb classes
 - RAWWAVE_PATH changed to include the "rawwave" directory
 - "configure" support added for unix systems
 - multivoice flag (-n NUMBER) added as command line option to demo program
 - sample rate flag added as command line option to all example programs
 - socket port number added as command line option to all example programs

 v4.0: (April 2002)
 - new documentation and tutorial
 - several new instruments, including Saxofony, BlowBotl, and StifKarp
 - new Stk base class, replacing Object class
 - new Filter class structure and methods
 - extensive modifications to WvIn and WvOut class structures and methods
 - looping functionality moved to WaveLoop (subclass of WvIn)
 - automatic file type detection in WvIn ... hosed WavWvIn, AifWvIn, RawWavIn, SndWavIn, and MatWvIn subclasses
 - new file type specifier argument in WvOut ... hosed WavWvOut, AifWvOut, RawWavOut, SndWavOut, and MatWvOut subclasses
 - some simplifications of Messager class (was Controller)
 - new independent RtAudio class
 - extensive revisions in code and a significant number of API changes

 v3.2: (13 November 2000)
 - new control handling class (Controller)
 - added AIFF file input/output support
 - stklib.a Makefile in src directory
 - added C++ error handling capabilities
 - added input/output internet streaming support (StrmWvIn/StrmWvOut)
 - added native ALSA support for linux
 - added optional "device" argument to all "Rt" classes (audio and MIDI) and printout of devices when argument is invalid
 - WvIn classes rewritten to support very big files (incremental load from disk)
 - changed WvIn/WvOut classes to work with sample frame buffers
 - fixed looping and negative rate calculations in WvIn classes
 - fixed interpolation bug in RtWvIn
 - windoze RtAudio code rewritten (thanks Dave!)
 - simplified byte-swapping functions (in-place swapping)
 - new FIR filter class (thanks Julius!)
 - "stereo-ized" RagaMatic
 - probably a bunch more fixes that I've long since forgotten about


 v3.1: (13 March 2000)
 - new RagaMatic project!!!
 - added "microphone position" to Mandolin in STKdemo
 - fixed MIDI system message exclusion under Irix
 - added a few bitmaps for the Shaker instruments
 - made destructors virtual for Reverb.h, WvIn.h and Simple.h
 - fixed bug setting delay length in DLineA when value too big
 - fixed bug in WinMM realtime code (RTSoundIO)
 - added tick() method to BowTabl, JetTabl, and ReedTabl (same as lookup)
 - switched to pthread API on SGI platforms
 - added some defines to Object.h for random number generation, FPU overflow checking, etc...
 - a lot of minor changes, some bug fixes ... can't remember all of them


 v3.0: (10 October 1999)
 - new #define flags for OS and realtime dependencies (this will probably cause problems for most everyone, but it was necessary to make future ports easier)
 - fixed Linux MIDI input bug
 - fixed MIDI status masking problem in Windows
 - OS type defines now in Makefile
 - new RAWWAVE_PATH define in Object.h
 - syntmono pulled out to separate directory and cleaned up
 - socketing capabilities under Unix, as well as Windoze
 - multiple simultaneous socket client connections to STK servers now possible
 - MD2SKINI now can merge MIDI and piped messages under Irix and Linux (for TCL->MD2SKINI->syntmono control)
 - defined INT16 and INT32 types and fixed various WvIn and WvOut classes
 - updated MatWvIn and MatWvOut for new MAT-file documentation from Matlab
 - new demo GUI
 - minor fixes to FM behavior
 - added record/duplex capabilities to RTSoundIO (Linux, SGI, and Windoze)
 - fixed bugs in WavWvOut and MatWvOut header specifications
 - added RawWvOut class
 - new WvIn class with RawWvIn, SndWvIn, WavWvIn, MatWvIn, and RTWvIn subclasses
 - removed RawWave, RawShot, RawInterp, and RawLoop classes (supplanted by RawWvIn)
 - multi-channel data support in WvIn and WvOut classes using MY_MULTI data type (pointer to StkFloat) and the methods mtick() and mlastOutput()
 - now writing to primary buffer under Windoze when allowed by hardware
 - cleaned up Object.h a bit
 - pulled various utility and thread functions out of syntmono.cpp (to aid readability of the code)


 v2.02: (16 November 1998)
 - created RawWave abstract class, with subclasses of RawLoop (looping rawwave oscillator), RawShot (non-looping, non-interpolating rawwave player ... used to be RawWvIn), and RawInterp (looping or non-looping, interpolating rawwave player ... used to be RawWave).
 - modified DrumSynt to correctly handle sample rates different than 22050 Hz.
 - modified syntmono parsing vs. tick routine so that some ticking occurs between each message.  When multiple messages are waiting to be processed, the time between message updates is inversely proportional to the number of messages in the buffer.
 - fixed DirectSound playback bug in Win distribution.  Sound was being played at 8-bit, 22 kHz in all cases.  Playback is now 16-bit and dependent on SRATE.
 - fixed bug in MD2SKINI which prevented some NoteOff statements from being output.


 v2.01: (27 July 1998)
 - Corrected extraneous ^M line return characters that were incompatible with SGI.


 v2.0: (20 July 1998)
 - The first true release by Gary, with unified capabilities across SGI, Linux, and Win platforms.  See WWW pages (http://www-ccrma.stanford.edu/CCRMA/Software/STK/) for more info.


 v1.1:
 - More linux support and other changes that happened so long ago that I can't remember anymore.  Never officially released.


 v1.0:
 - Linux support added with the help of Tim Stilson.  Never officially released.


 v0.8:
 - One of (if not THE) original distributions for SGI, NeXTStep, and basic Win support.  I think this came out in 1996.
--- a/plugins/community/repos/Autodafe/dep/stk/doc/SKINI.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/SKINI.txt
@@ -0,0 +1,388 @@
 This describes the latest (version 1.1) implementation of SKINI.

 Synthesis toolKit Instrument Network Interface

 for the Synthesis Toolkit in C++ by Perry R. Cook.

 *********************************
 *     Too good to be true?      *
 * Have control and read it too? *
 *       A SKINI Haiku.          *
 *********************************

 Profound thanks to Dan trueman, Brad Garton, and
 Gary Scavone for input on this revision.  Thanks
 also to MIDI, the NeXT MusicKit, ZIPI and all
 the creators and modifiers of these for good bases
 upon/from which to build and depart.

 1)  MIDI Compatibility

    SKINI was designed to be MIDI compatible wherever possible,
    and extend MIDI in incremental, then maybe profound ways.

    Differences from MIDI, and motivations, include:

        Text-based messages are used, with meaningful names
        wherever possible.  This allows any language or system
        capable of formatted printing to generate SKINI.
        Similarly, any system capable of reading in a string
        and turning delimited fields into strings, floats,
        and ints can consume SKINI for control.  More importantly,
        humans can actually read, and even write if they want,
        SKINI files and streams.  Use an editor and search/
        replace or macros to change a channel or control number.
        Load a SKINI score into a spread sheet to apply
        transformations to time, control parameters, MIDI
        velocities, etc.  Put a monkey on a special typewriter
        and get your next great work.  Life's too short to debug
        bit/nybble packed variable length mumble messages.  Disk
        space gets cheaper, available bandwidth increases, music
        takes up so little space and bandwidth compared to video
        and grapics.  Live a little.

        Floating point numbers are used wherever possible.
        Note Numbers, Velocities, Controller Values, and
        Delta and Absolute Times are all represented and
        scanned as ASCII double-precision floats.  MIDI byte
        values are preserved, so that incoming MIDI bytes
        from an interface can be put directly into SKINI
        messages.  60.0 or 60 is middle C, 127.0 or 127 is
        maximum velocity etc.  But, unlike MIDI, 60.5 can
        cause a 50cent sharp middle C to be played.  As with
        MIDI byte values like velocity, use of the integer and
        SKINI-added fractional parts is up to the implementor
        of the algorithm being controlled by SKINI messages.
        But the extra precision is there to be used or ignored.

 2)  WHY SKINI?

    SKINI was designed to be extensable and hackable for a number
    of applications: imbedded synthesis in a game or VR simulation,
    scoring and mixing tasks, real-time and non-real time applications
    which could benefit from controllable sound synthesis,
    JAVA controlled synthesis, or eventually maybe JAVA synthesis,
    etc.  SKINI is not intended to be "the mother of scorefiles,"
    but since the entire system is based on text representations
    of names, floats, and ints, converters from one scorefile
    language to SKINI, or back, should be easily created.

    I am basically a bottom-up designer with an awareness of top-
    down design ideas, so SKINI above all reflects the needs of my
    particular research and creative projects as they have arisen and
    developed.  SKINI 1.1 represents a profound advance beyond
    versions 0.8 and 0.9 (the first versions), future SKINI's might
    reflect some changes.  Compatibility with prior scorefiles
    will be attempted, but there aren't that many scorefiles out
    there yet.

 3)  SKINI MESSAGES

    A basic SKINI message is a line of text.  There are only three
    required fields, the message type (an ASCII name), the time (either
    delta or absolute), and the channel number.  Don't freak out and
    think that this is MIDI channel 0-15 (which is supported), because
    the channel number is scanned as a long int.  Channels could be socket
    numbers, machine IDs, serial numbers, or even unique tags for each
    event in a synthesis.  Other fields might be used, as specified in the
    SKINItbl.h file.  This is described in more detail later.

    Fields in a SKINI line are delimited by spaces, commas, or
    tabs.  The SKINI parser only operates on a line at a time,
    so a newline means the message is over.  Multiple messages are
    NOT allowed directly on a single line (by use of the ; for
    example in C).  This could be supported, but it isn't in
    version 1.1.

    Message types include standard MIDI types like NoteOn, NoteOff,
    ControlChange, etc.  MIDI extension message types (messages
    which look better than MIDI but actually get turned into
    MIDI-like messages) include LipTension, StringDamping, etc.
    NonMIDI message types include SetPath (sets a path for file
    use later), and OpenReadFile (for streaming, mixing, and applying
    effects to soundfiles along with synthesis, for example).
    Other non-MIDI message types include Trilling, HammerOn, etc. (these
    translate to gestures, behaviors, and contexts for use by
    intellegent players and instruments using SKINI).  Where possible
    I will still use these as MIDI extension messages, so foot
    switches, etc. can be used to control them in real time.

    All fields other than type, time, and channel are optional, and the
    types and useage of the additional fields is defined in the file
    SKINItbl.h.

    The other important file used by SKINI is SKINImsg.h, which is a
    set of #defines to make C code more readable, and to allow reasonably
    quick re-mapping of control numbers, etc..  All of these defined
    symbols are assigned integer values.  For JAVA, the #defines could
    be replaced by declaration and assignment statements, preserving
    the look and behavior of the rest of the code.

 4)  C Files Used To Implement SKINI

    Skini.cpp is an object which can either open a SKINI file, and
    successively read and parse lines of text as SKINI strings, or
    accept strings from another object and parse them.  The latter
    functionality would be used by a socket, pipe, or other connection
    receiving SKINI messages a line at a time, usually in real time,
    but not restricted to real time.

    SKINImsg.h should be included by anything wanting to use the
    Skini.cpp object.  This is not mandatory, but use of the __SK_blah_
    symbols which are defined in the .msg file will help to ensure
    clarity and consistency when messages are added and changed.

    SKINItbl.h is used only by the SKINI parser object (Skini.cpp).
    In the file SKINItbl.h, an array of structures is declared and
    assigned values which instruct the parser as to what the message
    types are, and what the fields mean for those message types.
    This table is compiled and linked into applications using SKINI, but
    could be dynamically loaded and changed in a future version of
    SKINI.

 5)  SKINI Messages and the SKINI Parser:

    The parser isn't all that smart, but neither am I.  Here are the
    basic rules governing a valid SKINI message:

    a)  If the first (non-delimiter (see c)) character in a SKINI
        string is '/' that line is treated as a comment and echoed
        to stdout.

    b)  If there are no characters on a line, that line is treated
        as blank and echoed to stdout.  Tabs and spaces are treated
        as non-characters.

    c)  Spaces, commas, and tabs delimit the fields in a SKINI
        message line.  (We might allow for multiple messages per
        line later using the semicolon, but probably not.  A series
        of lines with deltaTimes of 0.0 denotes simultaneous events.
        For read-ability, multiple messages per line doesn't help much,
        so it's unlikely to be supported later).

    d)  The first field must be a SKINI message name.  (like NoteOn).
        These might become case-insensitive in future versions, so don't
        plan on exciting clever overloading of names (like noTeOn being
        different from NoTeON).  There can be a number of leading
        spaces or tabs, but don't exceed 32 or so.

    e)  The second field must be a time specification in seconds.
        A time field can be either delta-time (most common and the only one
        supported in version 0.8), or absolute time.  Absolute time
        messages have an '=' appended to the beginning of the floating
        point number with no space.  So 0.10000 means delta time of
        100 ms, while =0.10000 means absolute time of 100 ms.  Absolute
        time messages make most sense in score files, but could also be
        used for (loose) synchronization in a real-time context.  Real
        time messages should be time-ordered AND time-correct.  That is,
        if you've sent 100 total delta-time messages of 1.0 seconds, and
        then send an absolute time message of =90.0 seconds, or if you
        send two absolute time messages of =100.0 and =90.0 in that
        order, things will get really fouled up.  The SKINI parser
        doesn't know about time, however.  The WvOut device is the
        master time keeper in the Synthesis Toolkit, so it should be
        queried to see if absolute time messages are making sense.
        There's an example of how to do that later in this document.
        Absolute times are returned by the parser as negative numbers
        (since negative deltaTimes are not allowed).

    f)  The third field must be an integer channel number.  Don't go
        crazy and think that this is just MIDI channel 0-15 (which is
        supported).  The channel number is scanned as a long int.  Channels
        0-15 are in general to be treated as MIDI channels.  After that
        it's wide open.  Channels could be socket numbers, machine IDs,
        serial numbers, or even unique tags for each event in a synthesis.
        A -1 channel can be used as don't care, omni, or other functions
        depending on your needs and taste.

    g)  All remaining fields are specified in the SKINItbl.h file.
        In general, there are maximum two more fields, which are either
        SK_INT (long), SK_DBL (double float), or SK_STR (string).  The
        latter is the mechanism by which more arguments can be specified
        on the line, but the object using SKINI must take that string
        apart (retrived by using getRemainderString()) and scan it.
        Any excess fields are stashed in remainderString.

 6)  A Short SKINI File:

        /*  Howdy!!! Welcome to SKINI, by P. Cook 1999

        NoteOn          0.000082 2 55 82
        NoteOff         1.000000 2 55 0
        NoteOn          0.000082 2 69 82
        StringDetune    0.100000 2    10
        StringDetune    0.100000 2    30
        StringDetune    0.100000 2    50
        NoteOn          0.000000 2 69 82
        StringDetune    0.100000 2    40
        StringDetune    0.100000 2    22
        StringDetune    0.100000 2    12
        //
        StringDamping   0.000100 2     0.0
        NoteOn          0.000082 2 55 82
        NoteOn          0.200000 2 62 82
        NoteOn          0.100000 2 71 82
        NoteOn          0.200000 2 79 82
        NoteOff         1.000000 2 55 82
        NoteOff         0.000000 2 62 82
        NoteOff         0.000000 2 71 82
        NoteOff         0.000000 2 79 82
        StringDamping  =4.000000 2       0.0
        NoteOn          0.000082 2 55 82
        NoteOn          0.200000 2 62 82
        NoteOn          0.100000 2 71 82
        NoteOn          0.200000 2 79 82
        NoteOff         1.000000 2 55 82
        NoteOff         0.000000 2 62 82
        NoteOff         0.000000 2 71 82
        NoteOff         0.000000 2 79 82

 7)  The SKINItbl.h File, How Messages are Parsed:

    The SKINItbl.h file contains an array of structures which
    are accessed by the parser object Skini.cpp.  The struct is:

        struct SKINISpec { char messageString[32];
                   long  type;
                   long data2;
                   long data3;
                 };

    so an assignment of one of these structs looks like:

        MessageStr$      ,type, data2, data3,

            type is the message type sent back from the SKINI line parser.
            data<n> is either
                 NOPE    : field not used, specifically, there aren't going
                           to be any more fields on this line.  So if there
                           is is NOPE in data2, data3 won't even be checked
                 SK_INT  : byte (actually scanned as 32 bit signed long int)
                           If it's a MIDI data field which is required to
                           be an integer, like a controller number, it's
                           0-127.  Otherwise) get creative with SK_INTs
                 SK_DBL  : double precision floating point.  SKINI uses these
                           in the MIDI context for note numbers with micro
                           tuning, velocities, controller values, etc.
                 SK_STR  : only valid in final field.  This allows (nearly)
                           arbitrary message types to be supported by simply
                           scanning the string to EndOfLine and then passing
                           it to a more intellegent handler.  For example,
                           MIDI SYSEX (system exclusive) messages of up to
                           256 bytes can be read as space-delimited integers
                           into the 1K SK_STR buffer.  Longer bulk dumps,
                           soundfiles, etc. should be handled as a new
                           message type pointing to a FileName, Socket, or
                           something else stored in the SK_STR field, or
                           as a new type of multi-line message.

    Here's a couple of lines from the SKINItbl.h file

 {"NoteOff"          ,        __SK_NoteOff_,               SK_DBL,  SK_DBL},
 {"NoteOn"           ,         __SK_NoteOn_,               SK_DBL,  SK_DBL},

 {"ControlChange"    ,  __SK_ControlChange_,               SK_INT,  SK_DBL},
 {"Volume"           ,  __SK_ControlChange_, __SK_Volume_        ,  SK_DBL},

 {"StringDamping"    ,   __SK_ControlChange_, __SK_StringDamping_,  SK_DBL},
 {"StringDetune"     ,    __SK_ControlChange_, __SK_StringDetune_,  SK_DBL},

    The first three are basic MIDI messages.  The first two would cause the
    parser, after recognizing a match of the string "NoteOff" or "NoteOn",
    to set the message type to 128 or 144 (__SK_NoteOff_ and __SK_NoteOn_
    are #defined in the file SKINImsg.h to be the MIDI byte value, without
    channel, of the actual MIDI messages for NoteOn and NoteOff).  The parser
    would then set the time or delta time (this is always done and is
    therefore not described in the SKINI Message Struct).  The next two
    fields would be scanned as double-precision floats and assigned to
    the byteTwo and byteThree variables of the SKINI parser.  The remainder
    of the line is stashed in the remainderString variable.

    The ControlChange spec is basically the same as NoteOn and NoteOff, but
    the second data byte is set to an integer (for checking later as to
    what MIDI control is being changed).

    The Volume spec is a MIDI Extension message, which behaves like a
    ControlChange message with the controller number set explicitly to
    the value for MIDI Volume (7).  Thus the following two lines would
    accomplish the same changing of MIDI volume on channel 2:

    ControlChange  0.000000 2 7 64.1
    Volume         0.000000 2   64.1

    I like the 2nd line better, thus my motivation for SKINI in the first
    place.

    The StringDamping and StringDetune messages behave the same as
    the Volume message, but use Control Numbers which aren't specifically
    nailed-down in MIDI.  Note that these Control Numbers are carried
    around as long ints, so we're not limited to 0-127.  If, however,
    you want to use a MIDI controller to play an instrument, using
    controller numbers in the 0-127 range might make sense.

 8)  Objects using SKINI

    Here's a simple example of code which uses the Skini object
    to read a SKINI file and control a single instrument.

        Skini score;
        Skini::Message message;
        instrument = new Mandolin(50.0);
        score.setFile( argv[1] );
        while ( score.nextMessage( message ) != 0 ) {
          tempDouble = message.time;
          if (tempDouble < 0)     {
            tempDouble = - tempDouble;
            tempDouble = tempDouble - output.getTime();
            if (tempDouble < 0) {
              printf("Bad News Here!!!  Backward Absolute Time Required.\n");
              tempDouble = 0.0;
            }
          }
          tempLong = (long) ( tempDouble * Stk::sampleRate() );
          for ( i=0; i<tempLong; i++ ) {
            output.tick( instrument->tick() );
          }

          tempDouble3 = message.floatValues[1] * NORM_MIDI;
          if ( message.type == __SK_NoteOn_ ) {
            if ( tempDouble3 == 0.0 ) {
              tempDouble3 = 0.5;
              instrument->noteOff( tempDouble3 );
            }
            else {
              tempLong = message.intValues[0];
              tempDouble2 = Midi2Pitch[tempLong];
              instrument->noteOn( tempDouble2, tempDouble3 );
            }
          }
          else if ( message.type == __SK_NoteOff_ ) {
            instrument->noteOff( tempDouble3 );
          }
          else if ( message.type == __SK_ControlChange_ ) {
            tempLong = message.intValues[0];
            instrument->controlChange( tempLong, tempDouble3 );
          }
        }

    When a SKINI score is passed to a Skini object using the
    Skini::setFile() function, valid messages are read from
    the file and returned using the Skini::nextMessage() function.

    A Skini::Message structure contains all the information parsed
    from a single SKINI message.  A returned message type of zero
    indicates either an invalid message or the end of a scorefile.

    The "time" member of a Skini::Message is the deltaTime until the
    current message should occur.  If this is greater than 0,
    synthesis occurs until the deltaTime has elapsed.  If deltaTime is
    less than zero, the time is interpreted as absolute time and the
    output device is queried as to what time it is now.  That is used
    to form a deltaTime, and if it's positive we synthesize.  If it's
    negative, we print an error, pretend this never happened and we
    hang around hoping to eventually catch up.

    The rest of the code sorts out message types NoteOn, NoteOff
    (including NoteOn with velocity 0), and ControlChange.  The
    code implicitly takes into account the integer type of the
    control number, but all other data is treated as double float.
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/Doxyfile
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/Doxyfile
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/classes.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/classes.txt
@@ -0,0 +1,10 @@
 /*! \page classes Class Documentation

 <UL>
 <LI><a class="qindex" href="hierarchy.html">Class Hierarchy</a></LI>
 <LI><a class="qindex" href="annotated.html">Class/Enum List</a></LI>
 <LI><a class="qindex" href="files.html">File List</a></LI>
 <LI><a class="qindex" href="functions.html">Compound Members</a></LI>
 </UL>

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/compile.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/compile.txt
@@ -0,0 +1,127 @@
 /*! \page compile Compiling

 The Synthesis ToolKit can be used in a variety of ways, depending on your particular needs.  Some people choose the classes they need for a particular project and copy those to their working directory.  Others create <TT>Makefiles</TT> that compile project-specific class objects from common <TT>src</TT> and <TT>include</TT> directories.  And still others like to compile and link to a common library of object files.  STK was not designed with one particular style of use in mind.


 \section rtvsnonrt "Realtime" vs. "Non-Realtime"

 Most of the Synthesis ToolKit classes are platform independent.  That
 means that they should compile on any reasonably current C++ compiler.
 The functionality needed for realtime audio and MIDI input/output, as
 well as realtime control message acquistion, is inherently platform
 and operating-system (OS) <I>dependent</I>.  STK classes that require
 specific platform/OS support include RtAudio, RtWvOut, RtWvIn,
 RtDuplex, RtMidi, InetWvIn, InetWvOut, Socket, UdpSocket, TcpServer,
 TcpClient, Thread, and Mutex.  These classes currently can only be
 compiled on Linux, Macintosh OS X, and Windows systems.

 Without the "realtime" classes, it is still possible to read SKINI
 scorefiles for control input and to read and write to/from a variety
 of audio file formats (WAV, SND, AIFF, MAT-file, and RAW).  If
 compiling for a "little-endian" host processor, the
 <TT>__LITTLE_ENDIAN__</TT> preprocessor definition should be provided.


 \section unix Unix Systems:

 STK compiles with realtime support on the following flavors of the Unix operating system: Linux, Irix, and Macintosh OS X.  Aside from differences in compilers, audio/MIDI APIs, and host endianness, the steps necessary to compile STK programs and classes on these platforms are the same.  The following table summarizes these differences.

 <CENTER>
 <TABLE BORDER=2 COLS=5 WIDTH="100%">
 <TR BGCOLOR="beige">
  <TD WIDTH="5%"><B>OS:</B></TD>
  <TD WIDTH="5%"><B>Realtime Audio/MIDI API:</B></TD>
  <TD WIDTH="5%"><B>Preprocessor Definition:</B></TD>
  <TD WIDTH="5%"><B>Library or Framework:</B></TD>
 </TR>
 <TR>
  <TD>Linux</TD>
  <TD>ALSA</TD>
  <TD>__LINUX_ALSA__, __LITTLE_ENDIAN__</TD>
  <TD><TT>asound, pthread</TT></TD>
 </TR>
 <TR>
  <TD>Linux</TD>
  <TD>OSS (version 4.0 only, use ALSA for MIDI support)</TD>
  <TD>__LINUX_OSS__, __LINUX_ALSA__, __LITTLE_ENDIAN__</TD>
  <TD><TT>asound, pthread</TT></TD>
 </TR>
 <TR>
  <TD>Linux and Macintosh OS-X</TD>
  <TD>Jack</TD>
  <TD>__UNIX_JACK__, __LITTLE_ENDIAN__</TD>
  <TD><TT>asound, pthread, jack</TT></TD>
 </TR>
 <TR>
  <TD>Macintosh OS X</TD>
  <TD>CoreAudio</TD>
  <TD>__MACOSX_CORE__</TD>
  <TD><TT>pthread, CoreAudio, CoreMIDI, CoreFoundation</TT></TD>
 </TR>
 </TABLE>
 </CENTER>

 The available C++ compilers on any of these systems can vary.

 One approach in using STK is to simply copy the class files needed for
 a particular program into a project directory.  Taking the
 <TT>sineosc.cpp</TT> example from the previous tutorial chapter, it
 would be necessary to set up a directory that includes the files
 <TT>sineosc.cpp</TT>, the rawwave file <TT>sinewave.raw</TT> in a
 subdirectory called <TT>rawwaves</TT>, and the header and source files
 for the classes Stk, FileRead, FileWrite, FileWvIn, FileLoop, and
 FileWvOut.  The program could then be compiled on a little-endian
 system, such as a PC running Linux, using the GNU g++ compiler as
 follows:
 \code g++ -Wall -D__LITTLE_ENDIAN__ -o sineosc Stk.cpp FileRead.cpp FileWrite.cpp FileWvIn.cpp FileLoop.cpp FileWvOut.cpp sineosc.cpp \endcode

 Note that the <TT>sineosc.cpp</TT> example does not make use of realtime audio or MIDI input/output classes.  For programs using any of the STK realtime classes mentioned above, it is necessary to specify an audio/MIDI API preprocessor definition and link with the appropriate libraries or frameworks.

 When working with a number of different projects that make use of ToolKit classes, the above approach can become cumbersome (especially when trying to synchronize with new STK releases).  Most of the STK projects (e.g., demo, effects, ...) contain <TT>Makefiles</TT> (built by the configure script) that compile project-specific class objects from the distribution <TT>src</TT> and <TT>include</TT> directories.  This approach makes it relatively easy when upgrading to a new STK release (by making path substitutions in the <TT>Makefile</TT> or by moving the projects to a similar relative path within the new STK source tree).  A <TT>Makefile</TT> is provided in the <TT>projects/examples</TT> directory for compiling all the tutorial programs, as well as other example programs.  To compile the <TT>sineosc.cpp</TT> program, for example, one need only type <TT>make sineosc</TT> from within the <TT>projects/examples</TT> directory.


 \subsection library Library Use:

 The STK distribution provides a <TT>Makefile</TT> that can be used on Unix systems to build a static library.  After unpacking the distribution (<TT>tar -xzf stk-4.x.x.tar.gz</TT>), run the configure script by typing <TT>./configure</TT> from the top level distribution directory (see the INSTALL file in the same directory for more information).  Then from within the <TT>src</TT> directory, type <TT>make</TT>.  After a successful build, you may wish to move the library (<TT>libstk.a</TT>) and the contents of the <TT>include</TT> directory to standard library and include search paths on your system.  For example, the linux RPM distribution of STK puts the library in <TT>/usr/lib/</TT> and the STK header files in <TT>/usr/include/stk/</TT>.

 Assuming the library is located in a standard search path and the header files are located in <TT>/usr/include/stk/</TT>, the <TT>sineosc.cpp</TT> example from the previous tutorial chapter can be compiled on a little-endian system using the GNU g++ compiler as follows:

 \code
 g++ -Wall -D__LITTLE_ENDIAN__ -I/usr/include/stk -o sineosc sineosc.cpp -lstk
 \endcode

 With the header files in a standard search path, it is possible to modify the <TT>\#include</TT> statements in the <TT>sineosc.cpp</TT> program as follows:

 \code
 #include "stk/FileLoop.h"
 #include "stk/FileWvOut.h"
 \endcode

 and then compile without an explicit include path argument to the compiler:

 \code
 g++ -Wall -D__LITTLE_ENDIAN__ -o sineosc sineosc.cpp -lstk
 \endcode


 \section compileWin Windows:

 STK has been tested on Windows platforms using the Visual .NET compiler
 only.  It is assumed here that you're familiar with Visual C++ and its
 particular idiosyncrasies.  STK won't compile in Visual C++ 6.0 any more.

 The approach when using Visual C++ is to build a project that
 includes the necessary ToolKit files from the distribution
 <TT>src</TT> and <TT>include</TT> directories.  For the example
 program from the previous tutorial chapter, create a VC++ console
 application project, add the Stk, FileRead, FileWrite, WvIn, FileWvIn,
 FileLoop, WvOut, and FileWvOut class files, as well as
 <TT>sineosc.cpp</TT>, and make sure the <TT>sinewave.raw</TT> file is
 in the subdirectory <TT>rawwaves</TT>.

 For programs using any of the STK realtime classes mentioned above, it is necessary to link with the DirectSound (<TT>dsound.lib</TT>), <TT>winmm.lib</TT>, and <TT>Wsock32.lib</TT> libraries, select the multithreaded library, and provide the <TT>__LITTLE_ENDIAN__</TT>, <TT>__WINDOWS_DS__</TT>, and <TT>__WINDOWS_MM__</TT> preprocessor definitions.

 For Steinberg ASIO support, use the <TT>__WINDOWS_ASIO__</TT> preprocessor definition (and the <TT>__WINDOWS_MM__</TT> definition for RtMidi support), include all the files in the <TT>src/asio/</TT> directory (i.e., <TT>asio.h,cpp</TT>, <TT>asiodrivers.h,cpp</TT>, ...), and link with the <TT>winmm.lib</TT>, and <TT>Wsock32.lib</TT> libraries.

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="filtering.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/control.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/control.txt
@@ -0,0 +1,54 @@
 /*! \page controlin Control Input

 Each Synthesis ToolKit instrument exposes its relevant control parameters via public functions such as setFrequency() and controlChange().  Programmers are free to implement the control scheme of their choice in exposing those parameters to the user.

 A text-based control protocol called <A HREF="skini.html">SKINI</A> is provided with the Synthesis ToolKit.  SKINI extends the MIDI protocol in incremental ways, providing a text-based messaging scheme in human-readable format and making use of floating-point numbers wherever possible.  Each SKINI message consists  of a message type (e.g., NoteOn, PitchBend), a time specification (absolute or delta), a channel number (scanned as a long integer), and a maximum of two subsequent message-specific field values.  Knowing this, it should be relatively clear what the following SKINI "scorefile" specifies:

 \code
 NoteOn          0.000082  2  55.0  82.3
 NoteOff         1.000000  2  55.0  64.0
 NoteOn          0.000082  2  69.0  82.8
 StringDetune    0.100000  2  10.0
 StringDetune    0.100000  2  30.0
 StringDetune    0.100000  2  50.0
 StringDetune    0.100000  2  40.0
 StringDetune    0.100000  2  22.0
 StringDetune    0.100000  2  12.0
 NoteOff         1.000000  2  69.0  64.0
 \endcode

 MIDI messages are easily represented within the SKINI protocol.

 The class stk::Messager can be used to acquire and parse MIDI messages
 from a MIDI device and SKINI messages from STDIN and socket
 connections.  Incoming messages are acquired asynchronously and saved
 to an internal message queue of stk::Skini::Message types (MIDI
 messages are converted to the stk::Skini:Message format).  The user
 then uses the stk::Messager:popMessage() function to retrieve incoming
 control messages.  This function does not block, instead returning a
 message type of zero when no more messages are in the queue.  Many of
 the example programs included with the ToolKit distribution use a
 stk::Messager instance to accept control input from the accompanying tcl/tk
 graphical user interfaces, from external MIDI devices, or from SKINI
 scorefiles.

 In the following example, we'll modify the <TT>bethree.cpp</TT> program from the previous tutorial chapter and incorporate a stk::Messager class to allow control via SKINI messages read from a SKINI file.

 \include controlbee.cpp

 A realtime control message will usually have a delta time of zero, in which case it is processed as soon as possible.  Non-realtime messages, normally from a scorefile, will usually have non-zero delta times.  The scheme used in this example is designed to work for both scorefile and realtime input types.  When no message is available from the queue, the instrument is "ticked" for DELTA_CONTROL_TICKS and then the queue is checked again.  The value of DELTA_CONTROL_TICKS roughly defines the program "control rate" in a realtime context, though multiple available messages in the queue are processed in immediate succession when their delta time values are zero.

 The \c processMessage() function centralizes the handling of control messages.  Other control update schemes can be implemented, perhaps using a separate thread or in the \c main() function, and this function should work in any context.

 Assuming the program is compiled as <TT>controlbee</TT> and the SKINI scorefile <A HREF="tutorial/bookert.ski"><TT>bookert.ski</TT></A> is in the <TT>scores</TT> directory, the program can be run as:

 \code
 controlbee scores/bookert.ski
 \endcode

 Only a few basic SKINI message type case statements are included in this example.  It is easy to extend the program to support a much more elaborate set of instrument control parameters.

 This example could also be easily extended to accept "realtime" control input messages via pipe, socket or MIDI connections.  The stk::Messager class provides stk::Messager::startStdInput(), stk::Messager::startSocketInput(), and stk::Messager::startMidiInput() functions for this purpose.

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="multichannel.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/crealtime.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/crealtime.txt
@@ -0,0 +1,74 @@
 /*! \page crealtime Realtime Audio (callback)

 An alternative scheme for audio input/output is to define a specific
 function in which audio computations are performed and to let the
 audio system call this function when more input/output data can be
 accepted by the hardware (referred to as a callback scheme).  In this
 section, we show how the previous <TT>rtsine.cpp</TT> program can be
 modified to work in a callback scenario.  There is no "single-sample"
 interface for this functionality.  The callback function will be
 invoked automatically by the audio system controller (RtAudio) when
 new data is needed and it is necessary to compute a full audio buffer
 of samples at that time (see \ref callback for further information).

 The previous section described the use of the stk::RtWvOut class for
 realtime audio output. The stk::RtWvOut::tick() function writes data to a
 large ring-buffer, from which data is periodically written to the
 computer's audio hardware via an underlying callback routine.

 \include crtsine.cpp

 The sinusoidal oscillator is created as before.  The instantiation of
 RtAudio requires quite a few more parameters, including output/input
 device and channel specifiers, the data format, and the desired buffer
 length (in frames).  In this example, we request a single output
 channel using the default output device, zero channels of input, the
 RtAudio data format which corresponds to an <tt>StkFloat</tt>, and the
 RT_BUFFER_SIZE defined in Stk.h.  The \c bufferFrames argument is an
 API-dependent buffering parameter (see RtAudio for further
 information).

 We also provide the audio system controller with a pointer to our
 callback function and an optional pointer to data that will be made
 available in the callback.  In this example, we need to pass only the
 pointer to the oscillator.  In more complex programs, it is typically
 necessary to put all shared data in a <tt>struct</tt> (see the next
 tutorial program for an example) or make use of global variables.

 Our callback routine is the \c tick() function.  Function arguments
 include pointers to the audio input and output data buffers, the
 buffer size (in frames), a stream time argument, a status argument to
 test for over/underruns, and the data pointer passed in the
 openStream() function (if it exists).  It is necessary to cast these
 pointers to their corresponding data types before use.  Our tick()
 routine simply "ticks" the oscillator for \c nBufferFrames counts and
 writes the result into the audio data buffer before returning.

 The \c main() function blocks at the std::cin.get() call until the
 user hits the "enter" key, after which the audio controller is shut
 down and program execution ends.

 \section callback Blocking vs. Callbacks

 Prior to version 4.2.0, all STK example projects and programs used
 blocking audio input/output functionality (typically with the RtWvIn,
 RtWvOut, or RtDuplex classes).  In many instances, a blocking scheme
 results in a clearer and more straight-forward program structure.
 Within a graphical user interface (GUI) programming context, however,
 callback routines are often more natural.

 In order to allow all STK programs to function with equal proficiency
 on all supported computer platforms, a decision was made to modify the
 example projects to use audio callback routines.  The result is a more
 complicated code structure, which is unfortunate given that we
 generally strive to make STK code as clear as possible for educational
 purposes.  This was especially an issue with the demo program because
 it is designed to function in both realtime and non-realtime contexts.
 The use of global variables has been avoided by defining data
 structures to hold all variables that must be accessible to the
 callback routine and other functions.  Alternative schemes for making
 control updates could be designed depending on particular program
 needs and constraints.

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="instruments.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/download.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/download.txt
@@ -0,0 +1,274 @@
 /*! \page download Download, Release Notes, and Bug Fixes

 \section down Download Version 4.6.0 (31 August 2017):

 - <A HREF="http://ccrma.stanford.edu/software/stk/release/stk-4.6.0.tar.gz">Source distribution</A>

 \section notes Release Notes:
 \subsection v4dot6dot0 Version 4.6.0
 - see github site for complete details (github.com/thestk/stk)
 - various build system updates
 - fixes in FileWvIn / FileLoop for normalisation and scaling, as well as file opening
 - bug fix for MAT-files in FileWrite
 - bug fix in MidiFileIn.cpp for timing and time-code formats
 - updated versions of RtAudio and RtMidi

 \subsection v4dot5dot1 Version 4.5.1
 - fix for FileWvIn / FileLoop classes to avoid keeping files open if not necessary
 - miscellaneous bug fixes, documented on GitHub site (github.com/thestk/stk)
 - update to play.cpp example to play mono files as stereo
 - bug fix in DelayL::setDelay() function
 - miscellanous build bug fixes

 \subsection v4dot5dot0 Version 4.5.0
 - Updated versions of RtAudio and RtMidi, with associated renaming of RtError class to either RtAudioError or RtMidiError
 - New iOS project files (thanks to Ariel Elkin)
 - Bug fix in FreeVerb that could cause crackling for stereo input
 - Various bug fixes and updates to minimize compiler warnings
 - ADSR fix for decay/release time calculations
 - Various updates to build system

 \subsection v4dot4dot4 Version 4.4.4
 - New FreeVerb class (thanks to Greg Burlet)
 - New Guitar class
 - New electric guitar project
 - Updated versions of RtAudio and RtMidi
 - Cleaned / revised Shakers class
 - Bug fix in LentPitShift
 - Bug fix in Echo constructor
 - Bug fix in FileWvIn (file size when chunking)
 - Bug fix in StkFrames copy constructor

 \subsection v4dot4dot3 Version 4.4.3
 - Changed SINT24 to be lower 3 bytes of 32-bit word.
 - Bug fixes to vectorized tick functions in Effects classes.
 - Updated versions of RtAudio and RtMidi.
 - Bug fixes in ADSR and Envelope classes.
 - Updates to the internal argument checking and reporting scheme.
 - Updates to Bowed class (thanks to Esteban Maestre!).
 - Fixes for 24-bit support in FileRead and FileWrite.
 - Added WAVE_FORMAT_EXTENSIBLE support in FileWrite.
 - Added sample rate variable reading and writing for MAT-files in FileRead and FileWrite.

 \subsection v4dot4dot2 Version 4.4.2
 - Added various header file includes for newer compilers.
 - Updates to RtAudio and RtMidi.
 - New LentPitShift class (thanks to Francois Germain).
 - Bug fixes in Voicer class (thanks Richard Dobson!).
 - Added Makefile.in to compile library and all projects, as well as clean and distclean.

 \subsection v4dot4dot1 Version 4.4.1
 - Added multi-channel/frame tick() virtual function to WvIn and WvOut abstract base classes (required update to RtWvOut class).
 - Updated configure script to select g++ compiler by default.
 - In demo.cpp: removed voicer grouping for messages, fixing polyphony when messages are on the same MIDI/SKINI channel.
 - Updates to RtAudio and RtMidi.

 \subsection v4dot4dot0 Version 4.4.0
 - All classes embedded in the "stk" namespace (except RtAudio, RtMidi, and RtError).
 - Class WaveLoop renamed FileLoop.
 - Significant efficiency improvements via code restructuring and inlining.
 - Some class source (.cpp) files deleted as part of inlining (Generator, Filter, Function, WvIn, WvOut, Effect, Instrmnt, BowTable, ReedTable, JetTable, Vector3D).
 - Updates to RtAudio and RtMidi.
 - Previous "tickFrame()" functions renamed "tick" for more consistent API.
 - More consistent and scalable approach to multichannel data and computations.
 - Multichannel support added to Granulate class.
 - Filter class made abstract.  New Iir and Fir classes made for non-order-specific filtering.
 - New TapDelay class.
 - SubNoise class deleted (same as sub-sampled "ticking" of Noise class).

 \subsection v4dot3dot1 Version 4.3.1
 - Further headerless file support in FileRead.
 - Bug fix in RtWvOut.cpp.
 - Added configure support for MinGW.
 - Updates to RtAudio and RtMidi for MinGW.
 - Changes to channel assignment in demo.cpp.

 \subsection v4dot3dot0 Version 4.3.0
 - An official MIT-like license.
 - New functionality to automatically update class data when the STK sample rate changes (partly implemented).
 - Updates for new RtAudio version 4.0.
 - Removed RtDuplex class, users should use RtAudio directly with a callback function.
 - Bug fix in interpolate() function in Stk.h for non-interleaved data.
 - Fixes / improvements to the Granulate class.
 - Fix in Whistle when doing animation.
 - Fixes in BlitSquare for frequency, harmonics, and dc offset.
 - Updates to Makefiles for non-realtime compile.
 - Fix in demo.cpp for voice channel assignment.
 - Updated versions of RtMidi and RtAudio.
 - Updated ASIO files for MinGW compiler.
 - New FAQ in documentation.
 - MAT-file bug fix in FileRead class.

 \subsection v4dot2dot1 Version 4.2.1
 - Greatly expanded StkFrames functionality (including interpolation and indexing by channel/frame).
 - New Blit, BlitSaw, and BlitSquare bandlimited waveform classes (thanks to Robin Davies!).
 - New Granulate granular synthesis class.
 - Removed Table class ... all functionality (including interpolation) now in StkFrames and FileRead classes.
 - Revised Socket class (now abstract) and added TcpServer, TcpClient, and UdpSocket subclasses.
 - Added Stk::showWarnings() and Stk::printErrors() functions to dis/enable warning and error printouts.
 - Extracted file I/O functionality to FileRead and FileWrite classes.
 - Revised WvIn / WvOut class structure (WvIn / WvOut now abstract and file I/O functionality in new FileWvIn / FileWvOut subclasses).
 - New SineWave class which calculates its own static table of variable length (no rawwave dependency).
 - New sinewave.raw file of length 1024 samples (used to be 256).
 - TcpWvIn and TcpWvOut renamed InetWvIn and InetWvOut, with added support for UDP sockets.
 - Fixed bug in WvOut tickFrame( const  StkFrames &frames ) function.
 - Fixed bug in demo.cpp when writing output soundfiles without realtime output.
 - Added "binary" open flag to MidiFileIn class for Windows.
 - Fixed oversized MAT-file header in WvOut.cpp
 - Fixed case statement bug in MidiFileIn.cpp for sysex.
 - Added missing getDelay() function to DelayA.cpp.
 - Fixed modDepth omission in Chorus.cpp.
 - Fixed DC blocker initialization bug in Flute.cpp.
 - Changed Filter class behavior so no default clearing of state when changing coefficients.
 - Fixes to RtAudio, especially for Windows DirectSound and ASIO (thanks to Robin Davies).

 \subsection v4dot2dot0 Version 4.2.0
 - Simultaneous multiple audio APIs supported at compile time.
 - Various changes to better conform to standard C++ programming practices.
 - Fixed hidden overloaded virtual functions.
 - New Asymp exponential envelope class.
 - <tt>MY_FLOAT</tt> type converted to <tt>StkFloat</tt> and changed throughout (use \c treesed utility to search/replace in old files).
 - Most example programs rewritten to use an audio callback paradigm (which works better in OS-X).
 - New StkFrames class for vectorized multichannel data and associated new tick() functions making use of StkFrames.
 - New RtMidi class with MIDI output capabilities (API changes).
 - New MidiFileIn class for reading MIDI files.
 - Revised Filter classes to use std::vectors for coefficients (API changes).
 - Revised Messager class (API changes).
 - New abstract parent Effect class for various effects.
 - New abstract parent Generator class for various signal sources.
 - New abstract parent Function class for tables and various non-linear functions.
 - Skini class completely rewritten (simplified) using the C++ STL (API changes).
 - WvOut classes now clip to -1.0 to +1.0 and report out of range.
 - New Mutex class.
 - Turned Nagle algorithm off by default in Socket class.
 - Error reporting standardized in all classes.

 \subsection v4dot1dot3 Version 4.1.3
 - Bug fix in RtAudio for Windows DirectSound output only support

 \subsection v4dot1dot2 Version 4.1.2
 - Added Linux JACK support to RtAudio.
 - Added optional doNormalize argument to WvIn to allow specification of data normalization or not.
 - Added volume control to demo program and various tcl scripts.
 - Added support for dynamic rawwavePath() setting.
 - WaveLoop bug fix.
 - Fixed bug in ADSR::setReleaseTime() method.
 - Fixed missing initialization of apInput in non-default constructor of DelayA class.
 - Added time seeding of random number generator to Noise constructor.
 - Update to the contentsAt() method of Delay class.
 - WAV file fixes (8-bit) in WvIn and WvOut classes.
 - Configure script changes.
 - Updated \<iostream\> include statements and appended "std::" as necessary throughout for compatibility with gcc 3.

 \subsection v4dot1dot1 Version 4.1.1
 - Bug fix in RtAudio for Macintosh OS X and Windows ASIO duplex operation.
 - Windows ASIO fix in Stk.h.
 - Documentation updates.
 - Expanded tutorial.
 - Fixed RtDuplex omission in src Makefile.

 \subsection v4dot1 Version 4.1
 - Macintosh OS X support added.
 - New Whistle class.
 - Added Voicer, SingWave, and VoicForm classes.
 - Improvements/fixes to the banded waveguide instruments.
 - Demo program now uses Voicer, allowing polyphony.
 - Demo tcl/tk scripts changed to use SKINI PitchChange instead of PitchBend.
 - Demo program response to PitchBend modified to octave up/down.
 - Several RtAudio fixes and improvements (OS X and Windows ASIO support added).
 - Added nextOut() method to Delay classes.
 - Documentation fixes for Reverb classes.
 - RAWWAVE_PATH changed to include the "rawwave" directory.
 - "configure" support added for unix systems.
 - Multivoice flag (-n NUMBER) added as command line option to demo program.
 - Sample rate flag added as command line option to example programs.
 - Socket port number added as command line option to example programs.

 \subsection v4 Version 4.0
 - New documentation and tutorial.
 - Several new instruments, including Saxofony, BlowBotl, and StifKarp.
 - New Stk base class, replacing Object class.
 - New Filter class structure and methods.
 - Extensive modifications to WvIn and WvOut class structures and methods.
 - Looping functionality moved to WaveLoop (subclass of WvIn).
 - Automatic file type detection in WvIn ... hosed WavWvIn, AifWvIn, RawWavIn, SndWavIn, and MatWvIn subclasses.
 - New file type specifier argument in WvOut ... hosed WavWvOut, AifWvOut, RawWavOut, SndWavOut, and MatWvOut subclasses.
 - Some simplifications of Messager class (was Controller).
 - New independent RtAudio class.
 - Extensive revisions in code and a significant number of API changes.

 \subsection v3dot2 Version 3.2
 - New input control handling class (Controller)
 - Added AIFF file input/output support.
 - New C++ error handling capabilities.
 - New input/output internet streaming support (StrmWvIn/StrmWvOut).
 - Added native ALSA support for linux.
 - Added optional "device" argument to all "Rt" classes (audio and MIDI) and printout of devices when argument is invalid.
 - WvIn classes rewritten to support very big files (incremental load from disk).
 - Changed WvIn/WvOut classes to work with sample frame buffers.
 - Fixed looping and negative rate calculations in WvIn classes.
 - Fixed interpolation bug in RtWvIn.
 - Windoze RtAudio code rewritten (thank Dave!).
 - Simplified byte-swapping functions (in-place swapping).
 - "Stereo-ized" RagaMatic.
 - Miscellaneous renamings.
 - Probably a bunch more fixes that I've long since forgotten about.

 \subsection v3dot1 Version 3.1
 - New RagaMatic project ... very cool!!!
 - Less clipping in the Shakers class.
 - Added "microphone position" to Mandolin in STKdemo.
 - Fixed MIDI system message exclusion under Irix.
 - Added a few bitmaps for the Shaker instruments.
 - Made destructors virtual for Reverb.h, WvIn.h and Simple.h.
 - Fixed bug setting delay length in DLineA when value too big.
 - Fixed bug in WinMM realtime code (RTSoundIO).
 - Added tick() method to BowTabl, JetTabl, and ReedTabl (same as lookup).
 - Switched to pthread API on SGI platforms.
 - Added some defines to Object.h for random number generation, FPU overflow checking, etc....
 - A few minor changes, some bug fixes ... can't remember all of them.

 \subsection v3 Version 3.0
 - New #define flags for OS and realtime dependencies (this will probably cause problems for old personal STK code, but it was necessary to make future ports easier).
 - Expanded and cleaned the Shakers class.
 - New BowedBar algorithm/class.
 - Fixed Linux MIDI input bug.
 - Fixed MIDI status masking problem in Windows.
 - OS type defines now in Makefile.
 - New RAWWAVE_PATH define in Object.h.
 - Syntmono project pulled out to separate directory and cleaned up.
 - Socketing capabilities under Unix, as well as Windoze.
 - Multiple simultaneous socket client connections to STK servers now possible.
 - MD2SKINI now can merge MIDI and piped messages under Irix and Linux (for TCL->MD2SKINI->syntmono control).
 - Defined INT16 and INT32 types and fixed various WvIn and WvOut classes.
 - Updated MatWvIn and MatWvOut for new MAT-file documentation from Matlab.
 - New demo Tcl/Tk GUI (TclDemo.tcl).
 - Minor fixes to FM behavior.
 - Added record/duplex capabilities to RTSoundIO (Linux, SGI, and Windoze).
 - Fixed bugs in WavWvOut and MatWvOut header specifications.
 - Added RawWvOut class.
 - New WvIn class with RawWvIn, SndWvIn, WavWvIn, MatWvIn, and RTWvIn subclasses.
 - Removed RawWave, RawShot, RawInterp, and RawLoop classes (supplanted by RawWvIn).
 - Multi-channel data support in WvIn and WvOut classes using MY_MULTI data type (pointer to StkFloat) and the methods mtick() and mlastOutput().
 - Now writing to primary buffer under Windoze when allowed by hardware.
 - Cleaned up Object.h a bit.
 - Pulled various utility and thread functions out of syntmono.cpp (to aid readability of the code).

 \subsection v2dot02 Version 2.02
 - Created RawWave abstract class, with subclasses of RawLoop (looping rawwave oscillator), RawShot (non-looping, non-interpolating rawwave player ... used to be RawWvIn), and RawInterp (looping or non-looping, interpolating rawwave player ... used to be RawWave).
 - Modified DrumSynt to correctly handle sample rates different than 22050 Hz.
 - Modified syntmono parsing vs. tick routine so that some ticking occurs between each message.  When multiple messages are waiting to be processed, the time between message updates is inversely proportional to the number of messages in the buffer.
 - Fixed DirectSound playback bug in WinXX distribution.  Sound was being played at 8-bit, 22 kHz in all cases.  Playback is now 16-bit and dependent on SRATE.
 - Fixed bug in MD2SKINI which prevented some NoteOff statements from being output.
 - This distribution includes an example STK project, mus151, which demonstrates a means for keeping a user's personal projects separate from the main distribution.  This is highly recommended, in order to simplify upgrades to future STK releases.

 \subsection v2 Version 2
 - Unification of the capabilities of STK across the various platforms.  All of the previous SGI functionality has been ported to Linux and Windows, including realtime sound output and MIDI input.
 - MIDI input (with optional time-stamping) supported on SGI, Linux (OSS device drivers only), and Windows operating systems.  Time stamping under IRIX and Windows is quantized to milliseconds and under Linux to hundredths of a second.
 - Various Sound Output Options - .wav, .snd, and .mat (Matlab MAT-file) soundfile outputs are supported on all operating systems.  I hacked out the MAT-file structure, so you don't have to include any platform-specific libraries.  Realtime sound output is provided as well, except under NeXTStep.
 - Multiple Reverberator Implementations - Reverb subclasses of JCRev and NRev (popular reverberator implementations from CCRMA) have been written.  Perry's original reverb implementation still exists as PRCRev.  All reverberators now take a T60 initializer argument.
 - MD2SKINI - A program which parses a MIDI input stream and spits out SKINI code.  The output of MD2SKINI is typically piped into an STK instrument executable (eg. <tt>MD2SKINI | syntmono Clarinet -r -i</tt>).  In addition, you can supply a filename argument to MD2SKINI and have it simultaneously record a SKINI score file for future reuse.
 - Modifications to <I>Object.h</I> for OS_TYPE compilation dependencies.  <I>Makefile</I> automatically determines OS_TYPE when invoked (if you have the GNU makefile utilities installed on your system).
 - A single distribution for all platforms.  The Unix and Windows versions have been merged into a single set of classes.  Makefiles and Visual C++ workspace/project files are provided for compiling.

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/faq.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/faq.txt
@@ -0,0 +1,80 @@
 /*! \page faq Frequently Asked Questions

 - \ref license
 - \ref filerate
 - \ref endianness
 - \ref xwindows

 \section license Does STK have a license?

 Yes, we finally made something official for release 4.3.0.  It is listed in the Stk class and a few other places in the distribution, but I'll repeat it here for clarity:

 \verbatim
 The Synthesis ToolKit in C++ (STK) is a set of open source audio
 signal processing and algorithmic synthesis classes written in the
 C++ programming language. STK was designed to facilitate rapid
 development of music synthesis and audio processing software, with
 an emphasis on cross-platform functionality, realtime control,
 ease of use, and educational example code.  STK currently runs
 with realtime support (audio and MIDI) on Linux, Macintosh OS X,
 and Windows computer platforms. Generic, non-realtime support has
 been tested under NeXTStep, Sun, and other platforms and should
 work with any standard C++ compiler.

 STK WWW site: http://ccrma.stanford.edu/software/stk/

 The Synthesis ToolKit in C++ (STK)
 Copyright (c) 1995--2017 Perry R. Cook and Gary P. Scavone

 Permission is hereby granted, free of charge, to any person obtaining
 a copy of this software and associated documentation files (the
 "Software"), to deal in the Software without restriction, including
 without limitation the rights to use, copy, modify, merge, publish,
 distribute, sublicense, and/or sell copies of the Software, and to
 permit persons to whom the Software is furnished to do so, subject to
 the following conditions:

 The above copyright notice and this permission notice shall be
 included in all copies or substantial portions of the Software.

 Any person wishing to distribute modifications to the Software is
 asked to send the modifications to the original developer so that they
 can be incorporated into the canonical version.  This is, however, not
 a binding provision of this license.

 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
 IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
 CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
 TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
 SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 \endverbatim

 \section filerate Why is my file sample rate wrong?

 When the FileWvIn class loads a soundfile, it automatically sets its internal read increment based on the soundfile rate and the current STK sample rate.  For example, if the current STK sample rate is 44100 Hz and the soundfile rate is 22050 Hz, the read increment, or rate, will be set to 0.5 and the file will be interpolated so that is sounds correct at 44100 Hz.  For most cases, this works fine.  However, consider the following example:

 \code
 FileWvIn input( "infile" );                 // read an input soundfile
 StkFloat sampleRate = input.getFileRate();
 Stk::setSampleRate( sampleRate );           // set a new STK sample rate based on the file rate
 \endcode

 With version 4.3 and higher of STK, the FileWvIn class will be notified of a sample rate change and it will automatically adjust its read rate accordingly.  Previous versions of STK did not perform this change and thus, the read rate could end up being incorrect.  If you do not want FileWvIn to perform this automatic adjustment, you can call the \c ignoreSampleRateChange() function for a given class instance.

 \section endianness Why does the sound I generated with STK sound like *&#@!?

 If the resultant sound generated by an STK program sounds like noise (and you're not doing an MLS experiment), the problem is likely related to the byte "endianness" of your computer.  By default, STK assumes "big endian" byte order.  If you are working with STK classes on a PC (Windows or Linux), you \e must define the <TT>__LITTLE_ENDIAN__</TT> preprocessor definition \e before compiling.  If after reading this you realize you need to make this change, do not forget to recompile all STK classes from scratch.

 \section xwindows Why do I get a Tk display error message?

 The following error may be printed to your terminal window (depending on the version of the tcl/tk interpreter you are running) if you attempt to start an STK tcl/tk interface without the X Server first running:

 \code
 Application initialization failed: this isn't a Tk applicationcouldn't connect to display ":0.0"
 \endcode

 Simply start your X server and then try the command again.

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/filtering.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/filtering.txt
@@ -0,0 +1,91 @@
 /*! \page filtering Using Filters

 In this section, we demonstrate the use of a few of the STK filter classes.  The stk::Iir class provides functionality to implement a generalized infinite impulse response (IIR) digital filter, similar to the \c filter function in Matlab.  In this example, we create an stk::Iir instance and initialize it with specific numerator and denominator coefficients.  We then compute its impulse response for 20 samples.

 \code
 #include "Iir.h"
 using namespace stk;

 int main()
 {
  StkFrames output( 20, 1 );   // initialize StkFrames to 20 frames and 1 channel (default: interleaved)
  output[0] = 1.0;

  std::vector<StkFloat> numerator( 5, 0.1 ); // create and initialize numerator coefficients
  std::vector<StkFloat> denominator;         // create empty denominator coefficients
  denominator.push_back( 1.0 );              // populate our denomintor values
  denominator.push_back( 0.3 );
  denominator.push_back( -0.5 );

  Iir filter( numerator, denominator );

  filter.tick( output );
  for ( unsigned int i=0; i<output.size(); i++ ) {
    std::cout << "i = " << i << " : output = " << output[i] << std::endl;
  }

  return 0;
 }
 \endcode

 The stk::Iir class implements the standard difference equation
 \code
 a[0]*y[n] = b[0]*x[n] + ... + b[nb]*x[n-nb] - a[1]*y[n-1] - ... - a[na]*y[n-na],
 \endcode

 where "b" values are numerator coefficients and "a" values are denominator coefficients.  Note that if the first denominator coefficient is not 1.0, the Iir class automatically normalizes all filter coefficients by that value.  The coefficient values are passed to the Iir class via a C++ <a href="http://www.roguewave.com/support/docs/sourcepro/stdlibref/vector.html">vector</a>, a container object provided by the C++ Standard Library.

 Most STK classes use more specific types of digital filters, such as the stk::OneZero, stk::OnePole, stk::TwoPole, or stk::BiQuad varieties.  These classes inherit from the stk::Filter abstract base class and provide specific functionality particular to their use, as well as functions to independently control individual coefficient values.

 \section reson Resonances:

 The STK stk::BiQuad and stk::TwoPole classes provide functionality for creating resonance filters.  The following example demonstrates how to create a resonance centered at 440 Hz that is used to filter the output of a stk::Noise generator.

 \code
 #include "BiQuad.h"
 #include "Noise.h"
 using namespace stk;

 int main()
 {
  StkFrames output( 20, 1 );   // initialize StkFrames to 20 frames and 1 channel (default: interleaved)
  Noise noise;

  BiQuad biquad;
  biquad.setResonance( 440.0, 0.98, true ); // automatically normalize for unity peak gain

  for ( unsigned int i=0; i<output.size(); i++ ) {
    output[i] = biquad.tick( noise.tick() );  // single-sample computations
    std::cout << "i = " << i << " : output = " << output[i] << std::endl;
  }

  return 0;
 }
 \endcode

 By passing a boolian value of \c true as the third argument to the stk::BiQuad::setResonance() function, the filter coefficients are automatically scaled to achieve unity gain at the resonance peak frequency.  The previous code could be easily modified for "vector-based" calculations:

 \code
 #include "BiQuad.h"
 #include "Noise.h"
 using namespace stk;

 int main()
 {
  StkFrames output( 20, 1 );   // initialize StkFrames to 20 frames and 1 channel (default: interleaved)
  Noise noise;

  BiQuad biquad;
  biquad.setResonance( 440.0, 0.98, true ); // automatically normalize for unity peak gain

  biquad.tick( noise.tick( output ) );      // vector-based computations
  for ( unsigned int i=0; i<output.size(); i++ ) {
    std::cout << "i = " << i << " : output = " << output[i] << std::endl;
  }

  return 0;
 }
 \endcode

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="realtime.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/footer.html
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/footer.html
@@ -0,0 +1,9 @@
 <HR>

 <table>
  <tr><td><A HREF="http://ccrma.stanford.edu/software/stk/"><I>The Synthesis ToolKit in C++ (STK)</I></A></td></tr>
  <tr><td>&copy;1995--2017 Perry R. Cook and Gary P. Scavone. All Rights Reserved.</td></tr>
 </table>

 </BODY>
 </HTML>
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/fundamentals.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/fundamentals.txt
@@ -0,0 +1,65 @@
 /*! \page fundamentals STK Fundamentals

 The Synthesis ToolKit is implemented in the C++ programming language.  STK does not attempt to provide a new programming environment or paradigm but rather provides a set of objects that can be used within a normal C++ programming framework.  Therefore, it is expected that users of STK will have some familiarity with C/C++ programming concepts.  That said, the STK classes do have some particular idiosyncrasies that we will mention here.  Starting with STK version 4.4, all STK classes except RtAudio and RtMidi are defined within the stk namespace.

 \section Signal Computations:

 Audio and control signals throughout STK use a floating-point data type, <tt>StkFloat</tt>, the exact precision of which can be controlled via a typedef statement in Stk.h.  By default, an StkFloat is a double-precision floating-point value.  Thus, the ToolKit can use any normalization scheme desired. The base instruments and algorithms are implemented with a general audio sample dynamic maximum of +/-1.0.

 In general, the computation and/or passing of values is performed on a "single-sample" basis.  For example, the stk::Noise class outputs random floating-point numbers in the range +/-1.0.  The computation of such values occurs in the stk::Noise::tick() function.  The following program will generate 20 random floating-point (<tt>StkFloat</tt>) values in the range -1.0 to +1.0:

 \code
 #include "Noise.h"
 using namespace stk;

 int main()
 {
  StkFloat output;
  Noise noise;

  for ( unsigned int i=0; i<20; i++ ) {
    output = noise.tick();
    std::cout << "i = " << i << " : output = " << output << std::endl;
  }

  return 0;
 }
 \endcode

 Nearly all STK classes implement <TT>tick()</TT> functions that take and/or return sample values. Within the <TT>tick()</TT> function, the fundamental sample calculations are performed for a given class.  Most STK classes consume/generate a single sample per operation and their <TT>tick()</TT> method takes/returns each sample "by value".  In addition, every class implementing a <TT>tick()</TT> function also provides one or more overloaded <TT>tick()</TT> functions that can be used for vectorized computations, as shown in the next example.

 \code
 #include "Noise.h"
 using namespace stk;

 int main()
 {
  StkFrames output(20, 1);   // initialize StkFrames to 20 frames and 1 channel (default: interleaved)
  Noise noise;

  noise.tick( output );
  for ( unsigned int i=0; i<output.size(); i++ ) {
    std::cout << "i = " << i << " : output = " << output[i] << std::endl;
  }

  return 0;
 }
 \endcode

 In this way, it might be possible to achieve improved processing efficiency using vectorized computations.  The StkFrames class is a relatively new addition to the ToolKit to provide a general "mechanism" for handling and passing vectorized, multi-channel audio data.  The StkFrames "type" provides functions to set and/or determine the number of audio channels and sample frames it holds.  Further, the StkFrames class provides data interpolation and subscripting functionality by frame/channel values.

 \section STK Inheritance:

 Nearly all STK classes inherit from the Stk abstract base class, which provides common functionality related to error reporting, sample rate control, and byte swapping.  Several other base classes exist that roughly group many of the classes according to function as follows:

 - stk::Generator: source signal unit generator classes [stk::Envelope, stk::ADSR, stk::Asymp, stk::Noise, stk::SubNoise, stk::Modulate, stk::SingWave, stk::SineWave, stk::Blit, stk::BlitSaw, stk::BlitSquare, stk::Granulate]
 - stk::Filter: digital filtering classes [stk::OneZero, stk::OnePole, stk::PoleZero, stk::TwoZero, stk::TwoPole, stk::BiQuad, stk::FormSwep, stk::Delay, stk::DelayL, stk::DelayA, stk::TapDelay]
 - stk::Function: input to output function mappings [stk::BowTable, stk::JetTable, stk::ReedTable]
 - stk::Instrmnt: sound synthesis algorithms, including physical, FM, modal, and particle models
 - stk::Effect: sound processing effect classes [stk::Echo, stk::Chorus, stk::PitShift, stk::PRCRev, stk::JCRev, stk::NRev]
 - stk::WvOut: audio data output classes [stk::FileWvOut, stk::RtWvOut, stk::InetWvOut]
 - stk::WvIn: audio data input classes [stk::FileWvIn, stk::FileLoop, stk::RtWvIn, stk::InetWvIn]


 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="hello.html">Next tutorial</A>] 
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/header.html
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/header.html
@@ -0,0 +1,10 @@
 <HTML>
 <HEAD>
 <TITLE>The Synthesis ToolKit in C++ (STK)</TITLE>
 <LINK HREF="doxygen.css" REL="stylesheet" TYPE="text/css">
 </HEAD>
 <BODY BGCOLOR="#FFFFFF">
 <CENTER>
 <img src="princeton.gif"> &nbsp; <img src="ccrma.gif"> &nbsp; <img src="mcgill.gif"><P>
 <a class="qindex" href="index.html">Home</a> &nbsp; <a class="qindex" href="information.html">Information</a> &nbsp; <a class="qindex" href="classes.html">Classes</a> &nbsp; <a class="qindex" href="download.html">Download</a> &nbsp; <a class="qindex" href="usage.html">Usage</a> &nbsp; <a class="qindex" href="maillist.html">Mail List</a> &nbsp; <a class="qindex" href="system.html">Requirements</a> &nbsp; <a class="qindex" href="links.html">Links</a> &nbsp; <a class="qindex" href="faq.html">FAQ</a> &nbsp; <a class="qindex" href="tutorial.html">Tutorial</a></CENTER>
 <HR>
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/header.tex
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/header.tex
@@ -0,0 +1,31 @@
 \documentclass[letter]{book}
 \usepackage{makeidx}
 \usepackage{fancyhdr}
 \usepackage{graphicx}
 \usepackage{float}
 \usepackage{alltt}
 \usepackage{doxygen}
 \usepackage{hyperref}
 \makeindex
 \setcounter{tocdepth}{1}
 \setlength{\footrulewidth}{0.4pt}
 \begin{document}
 \begin{titlepage}
 \vspace*{7cm}
 \begin{center}
 {\Large User Manual}\\
 \vspace*{0.5cm}
 {\Large The Synthesis ToolKit in C++}\\
 \vspace*{1cm}
 {\large by Perry R. Cook and Gary P. Scavone}\\
 \vspace*{0.5cm}
 {\small \copyright 1995--2007}\\
 \end{center}
 \end{titlepage}
 \clearemptydoublepage
 \pagenumbering{roman}
 \rfoot[\fancyplain{}{\bfseries\scriptsize The Synthesis ToolKit in C++ by Perry R. Cook and Gary P. Scavone, \copyright~1995--2007}]{}
 \lfoot[]{\fancyplain{}{\bfseries\scriptsize The Synthesis ToolKit in C++ by Perry R. Cook and Gary P. Scavone, \copyright~1995--2007}}
 \tableofcontents
 \clearemptydoublepage
 \pagenumbering{arabic}
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/hello.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/hello.txt
@@ -0,0 +1,94 @@
 /*! \page hello Hello Sine!

 We'll continue our introduction to the Synthesis ToolKit with a simple
 sine-wave oscillator program.  STK provides two different classes for
 sine-wave generation.  We will first look at a generic waveform
 oscillator class, stk::FileLoop, that can load a variety of common file
 types.  In this example, we load a sine "table" from an STK RAW file
 (defined as monophonic, 16-bit, big-endian data).  We use the class
 stk::FileWvOut to write the result to a 16-bit, WAV formatted audio file.

 \code

 // sineosc.cpp

 #include "FileLoop.h"
 #include "FileWvOut.h"
 using namespace stk;

 int main()
 {
  // Set the global sample rate before creating class instances.
  Stk::setSampleRate( 44100.0 );

  FileLoop input;
  FileWvOut output;

  // Load the sine wave file.
  input.openFile( "rawwaves/sinewave.raw", true );

  // Open a 16-bit, one-channel WAV formatted output file
  output.openFile( "hellosine.wav", 1, FileWrite::FILE_WAV, Stk::STK_SINT16 );

  input.setFrequency( 440.0 );

  // Run the oscillator for 40000 samples, writing to the output file
  for ( int i=0; i<40000; i++ )
    output.tick( input.tick() );

  return 0;
 }
 \endcode

 stk::FileLoop is a subclass of stk::FileWvIn, which supports WAV, SND
 (AU), AIFF, MAT-file (Matlab), and RAW file formats with 8-, 16-, and
 32-bit integer and 32- and 64-bit floating-point data types.
 stk::FileWvIn provides interpolating, read-once ("oneshot")
 functionality, as well as methods for setting the read rate and read
 position.

 stk::FileWvIn provides a "tick level" and interpolating interface to
 the stk::FileRead class.  Likewise, stk::FileWvOut provides a "tick
 level" interface to the stk::FileWrite class.  stk::FileRead and
 FileWrite both support WAV, SND(AU), AIFF, MAT-file (Matlab), and RAW
 file formats with 8-, 16-, and 32-bit integer and 32- and 64-bit
 floating-point data types.  stk::FileWvOut does not currently offer
 data interpolation functionality.

 A number of STK parent classes, including stk::WvIn, stk::WvOut,
 stk::Instrmnt, stk::Generator, and stk::Effect, (and some or all of
 their subclasses) support multi-channel sample frames.  If a
 single-sample version of the <TT>tick()</TT> function is called for
 these classes, a full sample frame is computed but only a single value
 is either input and/or output.  For example, if the single-sample
 <TT>tick()</TT> function is called for subclasses of stk::WvOut, the
 sample argument is written to all channels in the one computed frame.
 For classes returning values, an optional \c channel argument
 specifies which channel value is returned from the computed frame (the
 default is always channel 0). To input and/or output multichannel data
 to these classes, the overloaded <TT>tick()</TT> functions taking
 StkFrames reference arguments should be used.

 Nearly all STK classes inherit from the stk::Stk base class.  Stk
 provides a static sample rate that is queried by subclasses as needed.
 Because many classes use the current sample rate value during
 instantiation, it is important that the desired value be set at the
 beginning of a program.  The default STK sample rate is 44100 Hz.

 \section error Error Handling

 The ToolKit has some basic C++ error handling functionality built in.
 Classes that access files and/or hardware are most prone to runtime
 errors.  To properly "catch" such errors, the above example should be
 rewritten as shown below.

 \include sineosc.cpp

 In this particular case, we simply exit the program if an error occurs
 (an error message is automatically printed to stderr).  A more refined
 program might attempt to recover from or fix a particular problem and,
 if successful, continue processing.  See the \ref classes to determine
 which constructors and functions can throw an error.

 [<A HREF="fundamentals.html">Main tutorial page</A>] &nbsp; [<A HREF="compile.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/images/ccrma.gif
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/images/ccrma.gif
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/images/mcgill.gif
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/images/mcgill.gif
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/images/princeton.gif
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/images/princeton.gif
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/index.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/index.txt
@@ -0,0 +1,40 @@
 /*! \mainpage The Synthesis ToolKit in C++ (STK)

 \htmlonly
 <BODY BGCOLOR="white">
 <h3><center><a href="http://www.cs.princeton.edu/~prc/">Perry R. Cook</a> & <a href="http://music.mcgill.ca/~gary/">Gary P. Scavone</a></center></h3>
 \endhtmlonly

 The <B>Synthesis ToolKit in C++ (STK)</B> is a set of open source
 audio signal processing and algorithmic synthesis classes written in
 the C++ programming language.  STK was designed to facilitate rapid
 development of music synthesis and audio processing software, with an
 emphasis on cross-platform functionality, realtime control, ease of
 use, and educational example code.  The Synthesis ToolKit is extremely
 portable (it's mostly platform-independent C and C++ code), and it's
 completely user-extensible (all source included, no unusual libraries,
 and no hidden drivers).  We like to think that this increases the
 chances that our programs will still work in another 5-10 years.  In
 fact, the ToolKit has been working continuously for nearly 20 years
 now.  STK currently runs with realtime support (audio and MIDI) on
 Linux, Macintosh OS X, and Windows computer platforms.  Generic,
 non-realtime support has been tested under NeXTStep, Sun, and other
 platforms and should work with any standard C++ compiler.

 - \ref information
 - \ref classes
 - \ref download
 - \ref usage
 - \ref maillist
 - \ref system
 - \ref links
 - \ref faq
 - \ref tutorial

 */

 <P>
 <FONT SIZE=-1>
 STK is a registered trademark of Analytical Graphics, Inc., 40 General Warren Blvd., Malvern, PA 19355, the manufacturer of the Satellite Tool Kit® (STK®) family of satellite simulation software.  Although the term "STK" is used in this website, the content of this site is in no way related to Analytical Graphics, Inc, or its registered STK mark.  Nothing in this website should be construed to mean that a business relationship, either past or present, exists between Analytical Graphics, Inc. and the owners of this particular website.
 </FONT>

--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/information.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/information.txt
@@ -0,0 +1,133 @@
 /*! \page information General Information

 <H3>References</H3>
 <UL>
 <LI><A HREF="papers/stkupdate.pdf">ICMC2005 Paper</A></LI>
 <BR>
 A paper by Gary and Perry detailing recent updates to the Synthesis ToolKit in C++.
 <P>
 <LI><A HREF="papers/stkicmc99.pdf">ICMC99 Paper</A></LI>
 <BR>
 A not-so-recent paper by Perry and Gary about the Synthesis ToolKit in C++.
 <P>
 <LI>Book Chapter: <A HREF="http://www.akpeters.com/product.asp?ProdCode=1047">Audio Anecdotes</A></LI>
 <BR>
 Here's a link to a book that includes an chapter on STK.
 </UL>


 <H4>What is the <I>Synthesis ToolKit</I>?</H4>

 The Synthesis ToolKit in C++ (STK) is a set of open source audio signal processing and algorithmic synthesis classes written in the C++ programming language.  STK was designed to facilitate rapid development of music synthesis and audio processing software, with an emphasis on cross-platform functionality, realtime control, ease of use, and educational example code.  The Synthesis ToolKit is extremely portable (it's mostly platform-independent C and C++ code), and it's completely user-extensible (all source included, no unusual libraries, and no hidden drivers).  We like to think that this increases the chances that our programs will still work in another 5-10 years.  In fact, the ToolKit has been working continuously for nearly 20 years now.  STK currently runs with realtime support (audio and MIDI) on Linux, Macintosh OS X, and Windows computer platforms.  Generic, non-realtime support has been tested under NeXTStep, Sun, and other platforms and should work with any standard C++ compiler.

 The Synthesis ToolKit is free.  The only parts of the Synthesis ToolKit that are platform-dependent concern real-time audio and MIDI input and output, and that is taken care of with a few special classes.  The interface for MIDI input and the simple <A HREF="http://dev.scriptics.com">Tcl/Tk</A> graphical user interfaces (GUIs) provided is the same, so it's easy to experiment in real time using either the GUIs or MIDI.  The Synthesis ToolKit can generate simultaneous SND (AU), WAV, AIFF, and MAT-file output soundfile formats (as well as realtime sound output), so you can view your results using one of a large variety of sound/signal analysis tools already available (e.g. <A HREF="http://www-ccrma.stanford.edu/software/snd/">Snd</A>, Cool Edit, Matlab). 


 <H4>What the <I>Synthesis ToolKit</I> is not.</H4>

 The Synthesis Toolkit is not one particular program.  Rather, it is a set of C++ classes that you can use to create your own programs.  A few example applications are provided to demonstrate some of the ways to use the classes.  If you have specific needs, you will probably have to either modify the example programs or write a new program altogether. Further, the example programs don't have a fancy GUI wrapper.  It is easy to embed STK classes inside a GUI environment but we have chosen to focus our energy on the audio signal processing issues.  Spending hundreds of hours making platform-dependent graphical user interfaces would go against one of the fundamental design goals of the ToolKit - platform independence.

 For those instances where a simple GUI with sliders and buttons is helpful, we use <A HREF="http://dev.scriptics.com">Tcl/Tk</A> (that is freely distributed for all the supported ToolKit platforms). A number of Tcl/Tk GUI scripts are distributed with the ToolKit release.  For control, the Synthesis Toolkit uses raw MIDI (on supported platforms), and SKINI (Synthesis ToolKit Instrument Network Interface, a MIDI-like text message synthesis control format).

 <H4>A brief history of the <I>Synthesis ToolKit in C++.</I></H4>

 Perry Cook began developing a pre-cursor to the Synthesis ToolKit
 (also called STK) under NeXTStep at the Center for Computer Research
 in Music and Acoustics (CCRMA) at Stanford University in the
 early-1990s.  With his move to Princeton University in 1996, he ported
 everything to C++ on SGI hardware, added real-time capabilities, and
 greatly expanded the synthesis techniques available.  With the help of
 Bill Putnam, Perry also made a port of STK to Windows95.  Gary Scavone
 began using STK extensively in the summer of 1997 and completed a full
 port of STK to Linux early in 1998. He finished the fully compatable
 Windows port (using Direct Sound API) in June 1998.  Numerous
 improvements and extensions have been made since then.

 The Toolkit has been distributed continuously since 1996 via the <A
 HREF="http://www.music.princeton.edu/psk">Princeton Sound Kitchen</A>,
 <A HREF="http://www.cs.princeton.edu/~prc">Perry Cook's home page</A>
 at Princeton, <A HREF="http://www.music.mcgill.ca/~gary/">Gary
 Scavone's home page</A> at McGill University, and the <A HREF="http://ccrma.stanford.edu/software/stk">Synthesis ToolKit
 home page</A>.  The ToolKit has been included in various collections
 of software.  Much of it has also been ported to Max/MSP on Macintosh
 computers by Dan Trueman and Luke Dubois of Columbia University, and
 is distributed as <A
 HREF="http://music.columbia.edu/PeRColate">PeRColate</A>.  Help on
 real-time sound and MIDI has been provided over the years by Tim
 Stilson, Bill Putnam, and Gabriel Maldonado.

 <H4>Legal and Ethical Notes</H4>

 This software was designed and created to be made publicly available
 for free, primarily for academic purposes, so if you use it, pass it
 on with this documentation, and for free.  If you make a million
 dollars with it, it would be nice if you would share.  If you make
 compositions with it, put us in the program notes.

 Some of the concepts are covered by various patents, some known to us
 and likely others that are unknown.  Many of the ones known to us are
 administered by the Stanford Office of Technology and Licensing.  The
 good news is that large hunks of the techniques used here are public
 domain.  To avoid subtle legal issues, we will not state what's freely
 useable here, but we will try to note within the various classes where
 certain things are likely to be protected by patents.

 <H4>License</H4>

 Permission is hereby granted, free of charge, to any person obtaining
 a copy of this software and associated documentation files (the
 "Software"), to deal in the Software without restriction, including
 without limitation the rights to use, copy, modify, merge, publish,
 distribute, sublicense, and/or sell copies of the Software, and to
 permit persons to whom the Software is furnished to do so, subject to
 the following conditions:

 The above copyright notice and this permission notice shall be
 included in all copies or substantial portions of the Software.

 Any person wishing to distribute modifications to the Software is
 asked to send the modifications to the original developer so that they
 can be incorporated into the canonical version.  This is, however, not
 a binding provision of this license.

 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
 IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR
 ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF
 CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

 <H4>Disclaimer</H4>

 STK is free and we do not guarantee anything.  We've been hacking on this code for a while now and most of it seems to work pretty well.  But, there surely are some bugs floating around.  Sometimes things work fine on one computer platform but not so fine on another.  FPU overflows and underflows cause <I>very</I> weird behavior that also depends on the particular CPU and OS.  Let us know about bugs you find and we'll do our best to correct them.

 <H4>Perry's Notes From the Original Distribution of STK</H4>

 This whole world was created with no particular hardware in mind.  These examples are intended to be tutorial in nature, as a platform for the continuation of my research, and as a possible starting point for a software synthesis system.  The basic motivation was to create the necessary unit generators to do the synthesis, processing, and control that I want to do and teach about.  Little thought for optimization was given and therefore improvements, especially speed enhancements, should be possible with these classes.  It was written with some basic concepts in mind about how to let compilers optimize.

 Your question at this point might be, "But Perry, with CMix, CMusic, CSound, CShells, CMonkeys, etc. already cluttering the landscape, why a new set of stupid C functions for music synthesis and processing?"  The answers lie below.

 <ol>
 <li>I needed to port many of the things I've done into something that is generic enough to port further to different machines.</li>

 <li>I really plan to document this stuff, so that you don't have to be me to figure out what's going on. (I'll probably be sorry I said this in a couple of years, when even I can't figure out what I was thinking.)</li>

 <li>The classic difficulties most people have in trying to implement physical models are:

 <ul>
 <li>They have trouble understanding the papers, and/or in turning the theory into practice.</li>

 <li>The physical model instruments are a pain to get to oscillate, and coming up with stable and meaningful parameter values is required to get the models to work at all.</li>
 </ul>

 This set of C++ unit generators and instruments might help to diminish the scores of emails I get asking what to do with those block diagrams I put in my papers.</li>

 <li>I wanted to try some new stuff with modal synthesis, and implement some classic FM patches as well.</li>

 <li>I wanted to reimplement, and newly implement more of the intelligent and physical performer models I've talked about in some of my papers. But I wanted to do it in a portable way, and in such a way that I can hook up modules quickly.  I also wanted to make these instruments connectable to such player objects, so folks like Brad Garton who really think a lot about the players can connect them to my instruments, a lot about which I think.</li>

 <li>More rationalizations to follow ...</li>
 </ol>

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/instruments.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/instruments.txt
@@ -0,0 +1,19 @@
 /*! \page instruments Instruments

 The ToolKit comes with a wide variety of synthesis algorithms, all of which inherit from the stk::Instrmnt class.  In this example, we'll fire up an instance of the stk::BeeThree FM synthesis class and show how its frequency can be modified over time.

 \include bethree.cpp

 We have used an Instrmnt pointer when referencing the BeeThree
 instance above, so it would be simple to replace the BeeThree class
 with any other STK instrument class.  It should be noted, however,
 that a few classes do not respond to the setFrequency() function
 (e.g., Shakers, Drummer).

 The noteOn() function initiates an instrument attack.  Instruments that are continuously excited (e.g., stk::Clarinet, stk::BeeThree) will continue to sound until stopped with a noteOff().  Impulsively excited instrument sounds (e.g., stk::Plucked, stk::Wurley) typically decay within a few seconds time, requiring subsequent noteOn() messages for re-attack.

 Instrument parameters can be precisely controlled as demonstrated above.  A more flexible approach to instrument control, allowing arbitrary scorefile or realtime updates, is described in the next tutorial chapter.

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="controlin.html">Next tutorial</A>]
 */

--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/links.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/links.txt
@@ -0,0 +1,25 @@
 /*! \page links Miscellaneous Links

 - <A HREF="http://www.music.mcgill.ca/~gary/rtaudio/">The %RtAudio WWW site</A>

 - <A HREF="http://www.music.mcgill.ca/~gary/rtmidi/">The %RtMidi WWW site</A>

 - <A HREF="http://momu.stanford.edu/stk/">MoMu-Stk: A lightly modified version of STK that supports the iPhone platform (iPhone, iPad, iPod Touches)</A>

 - <A HREF="http://ccrma.stanford.edu/~woony/software/stkx/">StkX: A Cocoa STK Framework for Mac OS X by Woon Seung Yeo</A>

 - <A HREF="http://sourceforge.net/projects/mobilestk">Mobile STK: A port of STK for mobile devices by Georg Essl and Michael Rohs</A>

 - <A HREF="http://chuck.cs.princeton.edu/">ChucK: Concurrent, On-the-fly Audio Programming Language</A> using STK unit generators

 - <A HREF="http://kern.ccarh.org">Kern Scores: A Library of Electronic Musical Scores</A> (with automatic conversion to SKINI format)

 - <A HREF="http://stk.sapp.org/midi2skini">MIDI to SKINI file converter</A> by Craig Sapp

 - <A HREF="http://extra.humdrum.org/example/kern2skini/">Kern Score to SKINI file converter</A> by Craig Sapp

 - <A HREF="http://www.music.columbia.edu/PeRColate/">PeRColate: A Port of STK for Max/MSP</A>

 - <a href="http://airy.andre.online.fr/AU/index.html">AUStk: a demo of integration of STK instruments into an AudioUnit</a> by Airy Andre

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/maillist.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/maillist.txt
@@ -0,0 +1,14 @@
 /*! \page maillist The Mail List

 An <A HREF="mailto:stk-request@ccrma.stanford.edu">STK</A> mailing list has been set up to facilitate communication among STK users.  Subscribing to this list is your best way of keeping on top of new releases, bug fixes, and various user developments. 
 <P>
 For answers to frequently asked questions, check the list <A HREF="http://ccrma-mail.stanford.edu/pipermail/stk/">archives</A>.
 <P>
 To join send a message to <A HREF="mailto:stk-request@ccrma.stanford.edu">&lt;stk-request@ccrma.stanford.edu&gt;</A>
 with the contents:   <TT>subscribe</TT>

 <P>
 To be removed from the list send a message to <A HREF="mailto:stk-request@ccrma.stanford.edu">&lt;stk-request@ccrma.stanford.edu&gt;</A>
 with the contents:  <TT>unsubscribe</TT>

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/multichannel.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/multichannel.txt
@@ -0,0 +1,30 @@
 /*! \page multichannel Multi-Channel I/O

 The ToolKit stk::WvIn and stk::WvOut classes (and their subclasses) support multi-channel audio data input and output.  Several other abstract base classes, such as stk::Instrmnt, stk::Generator, and stk::Effect, also support multi-channel computations though not all of their subclasses produce or take multi-channel data.  A set of interleaved audio samples representing a single time "slice" is referred to as a <I>sample frame</I>.  At a sample rate of 44.1 kHz, a four-channel audio stream will have 44100 sample frames per second and a total of 176400 individual samples per second.

 Most STK classes process single-sample data streams via their
 <TT>tick()</TT> function.  For classes supporting multi-channel data,
 one must distinguish the <TT>tick()</TT> functions taking or producing
 single \c StkFloat arguments from those taking stk::StkFrames& arguments.  If
 a single-sample version of the <TT>tick()</TT> function is called for
 these classes, a full sample frame is computed but only a single value
 is either input and/or output.  For example, if the single-sample
 <TT>tick()</TT> function is called for subclasses of WvOut, the sample
 argument is written to all channels in the one computed frame.  For
 classes returning values, an optional \c channel argument specifies
 which channel value is returned from the computed frame (the default
 is always channel 0). To input and/or output multichannel data to
 these classes, the overloaded <TT>tick()</TT> functions taking
 StkFrames reference arguments should be used.

 Multi-channel support for realtime audio input and output is dependent on the audio device(s) available on your system.

 The following example demonstrates the use of the stk::FileWvOut class for
 creating a four channel, 16-bit AIFF formatted audio file.  We will
 use four sinewaves of different frequencies for the first two seconds
 and then a single sinewave for the last two seconds.

 \include foursine.cpp

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="polyvoices.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/polyvoices.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/polyvoices.txt
@@ -0,0 +1,22 @@
 /*! \page polyvoices Voice Management

 The previous tutorial chapters were concerned only with monophonic ToolKit instrument playback and control.  At this point, it should be relatively clear that one can instantiate multiple instruments and perhaps sum together their outputs or even direct their outputs to separate channels.  It is less clear how one might go about controlling a group of instruments.  The stk::Voicer class is designed to serve just this purpose.

 The stk::Voicer class is a relatively simple voice manager.  The user can dynamically add and delete instruments to/from its "control", with the option of controlling specific instruments via unique note tags and/or grouping sets of instruments via a "group" number.  All sounding instrument outputs are summed and returned via the <TT>tick()</TT> function.  The stk::Voicer class responds to noteOn, noteOff, setFrequency, pitchBend, and controlChange messages, automatically assigning incoming messages to the voices in its control.  When all voices are sounding and a new noteOn is encountered, the stk::Voicer interrupts the oldest sounding voice.  The user is responsible for creating and deleting all instrument instances.

 In the following example, we modify the <TT>controlbee.cpp</TT> program to make use of three stk::BeeThree instruments, all controlled using a stk::Voicer.

 \include threebees.cpp

 We have written this program to accept control messages from \c STDIN.  Assuming the program is compiled as <TT>threebees</TT>, the three-voice SKINI scorefile <A HREF="tutorial/bachfugue.ski"><TT>bachfugue.ski</TT></A> (located in the <tt>scores</tt> directory with the examples) can be redirected to the program as:

 \code
 threebees < scores/bachfugue.ski
 \endcode

 For more fun, surf to <A HREF="http://kern.humdrum.net/">Kern Scores</A> for a huge assortment of other scorefiles that can be downloaded in the SKINI format.

 Another easy extension would be to add the \c stk::Messager::startMidiInput() function to the program and then play the instruments via a MIDI keyboard.

 [<A HREF="tutorial.html">Main tutorial page</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/realtime.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/realtime.txt
@@ -0,0 +1,49 @@
 /*! \page realtime Realtime Audio (blocking)

 In this section, we modify the <TT>sineosc.cpp</TT> program in order
 to send the output to the default audio playback device on your
 computer system.  We also make use of the stk::SineWave class as a
 sine-wave oscillator.  stk::SineWave computes an internal, static sine-wave
 table when its first instance is created.  Subsequent instances make
 use of the same table.  The default table length, specified in
 SineWave.h, is 2048 samples.

 \include rtsine.cpp

 The class stk::RtWvOut is a protected subclass of stk::WvOut.  A number of
 optional constructor arguments can be used to fine tune its
 performance for a given system.  stk::RtWvOut provides a "single-sample",
 blocking interface to the RtAudio class.  Note that stk::RtWvOut (as well
 as the stk::RtWvIn class described below) makes use of RtAudio's callback
 input/output functionality by creating a large ring-buffer into which
 data is written.  These classes should not be used when low-latency
 and robust performance is necessary

 Though not used here, an stk::RtWvIn class exists as well that can be used
 to read realtime audio data from an input device.  See the
 <TT>record.cpp</TT> example program in the <TT>examples</TT> project
 for more information.

 It may be possible to use an instance of stk::RtWvOut and an instance of
 stk::RtWvIn to simultaneously read and write realtime audio to and from a
 hardware device or devices.  However, it is recommended to instead use
 a single instance of RtAudio to achieve this behavior, as described in the next section.
 See the <TT>effects</TT> project or the <TT>duplex.cpp</TT> example
 program in the <TT>examples</TT> project for more information.

 When using any realtime STK class (RtAudio, stk::RtWvOut, stk::RtWvIn, RtMidi, stk::InetWvIn, stk::InetWvOut, stk::Socket, stk::UdpSocket, stk::TcpServer, stk::TcpClient, and stk::Thread), it is necessary to specify an audio/MIDI API preprocessor definition and link with the appropriate libraries or frameworks.  For example, the above program could be compiled on a Linux system using the GNU g++ compiler and the ALSA audio API as follows (assuming all necessary files exist in the project directory):

 \code
 g++ -Wall -D__LINUX_ALSA__ -D__LITTLE_ENDIAN__ -o rtsine Stk.cpp Generator.cpp SineWave.cpp WvOut.cpp \
    RtWvOut.cpp RtAudio.cpp rtsine.cpp -lpthread -lasound
 \endcode

 On a Macintosh OS X system, the syntax would be:

 \code
 g++ -Wall -D__MACOSX_CORE__ -o rtsine Stk.cpp Generator.cpp SineWave.cpp WvOut.cpp RtWvOut.cpp RtAudio.cpp \
   rtsine.cpp -lpthread -framework CoreAudio -framework CoreMIDI -framework CoreFoundation
 \endcode

 [<A HREF="tutorial.html">Main tutorial page</A>] &nbsp; [<A HREF="crealtime.html">Next tutorial</A>]
 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/skini.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/skini.txt
@@ -0,0 +1,226 @@
 /*! \page skini Synthesis toolKit Instrument Network Interface (SKINI)

 This describes the latest (version 1.1) implementation of SKINI for the Synthesis ToolKit in C++ (STK) by Perry R. Cook.

 \code
        Too good to be true?
    Have control and read it too?
          A SKINI haiku.
 \endcode

 Profound thanks to Dan trueman, Brad Garton, and Gary Scavone for input on this revision.  Thanks also to MIDI, the NeXT MusicKit, ZIPI and all the creators and modifiers of these for good bases upon/from which to build and depart.

 \section compatibility MIDI Compatibility

 SKINI was designed to be MIDI compatible wherever possible, and extend MIDI in incremental, then maybe profound ways.

 Differences from MIDI, and motivations, include:

 - Text-based messages are used, with meaningful names wherever possible.  This allows any language or system capable of formatted printing to generate SKINI. Similarly, any system capable of reading in a string and turning delimited fields into strings, floats, and ints can consume SKINI for control.  More importantly, humans can actually read, and even write if they want, SKINI files and streams.  Use an editor and search/replace or macros to change a channel or control number.  Load a SKINI score into a spread sheet to apply transformations to time, control parameters, MIDI velocities, etc.  Put a monkey on a special typewriter and get your next great work.  Life's too short to debug bit/nybble packed variable length mumble messages.  Disk space gets cheaper, available bandwidth increases, music takes up so little space and bandwidth compared to video and graphics.  Live a little.

 - Floating point numbers are used wherever possible. Note Numbers, Velocities, Controller Values, and Delta and Absolute Times are all represented and scanned as ASCII double-precision floats.  MIDI byte values are preserved, so that incoming MIDI bytes from an interface can be put directly into SKINI messages.  60.0 or 60 is middle C, 127.0 or 127 is maximum velocity etc.  But, unlike MIDI, 60.5 can cause a 50 cent sharp middle C to be played.  As with MIDI byte values like velocity, use of the integer and SKINI-added fractional parts is up to the implementor of the algorithm being controlled by SKINI messages. But the extra precision is there to be used or ignored.

 \section why Why SKINI?

 SKINI was designed to be extensable and hackable for a number of applications: imbedded synthesis in a game or VR simulation, scoring and mixing tasks, real-time and non-real time applications which could benefit from controllable sound synthesis, JAVA controlled synthesis, or eventually maybe JAVA synthesis, etc.  SKINI is not intended to be "the mother of scorefiles," but since the entire system is based on text representations of names, floats, and ints, converters from one scorefile language to SKINI, or back, should be easily created.

 I am basically a bottom-up designer with an awareness of top-down design ideas, so SKINI above all reflects the needs of my particular research and creative projects as they have arisen and developed.  SKINI 1.1 represents a profound advance beyond versions 0.8 and 0.9 (the first versions), future SKINI's might reflect some changes.  Compatibility with prior scorefiles will be attempted, but there aren't that many scorefiles out there yet.

 \section messages SKINI Messages

 A basic SKINI message is a line of text.  There are only three required fields, the message type (an ASCII name), the time (either delta or absolute), and the channel number.  Don't freak out and think that this is MIDI channel 0-15 (which is supported), because the channel number is scanned as a long int.  Channels could be socket numbers, machine IDs, serial numbers, or even unique tags for each event in a synthesis.  Other fields might be used, as specified in the \c SKINI.tbl file.  This is described in more detail later.

 Fields in a SKINI line are delimited by spaces, commas, or tabs.  The SKINI parser only operates on a line at a time, so a newline means the message is over.  Multiple messages are NOT allowed directly on a single line (by use of the ; for example in C).  This could be supported, but it isn't in version 1.1.

 Message types include standard MIDI types like NoteOn, NoteOff, ControlChange, etc.  MIDI extension message types (messages which look better than MIDI but actually get turned into MIDI-like messages) include LipTension, StringDamping, etc. Non-MIDI message types include SetPath (sets a path for file use later), and OpenReadFile (for streaming, mixing, and applying effects to soundfiles along with synthesis, for example).  Other non-MIDI message types include Trilling, HammerOn, etc. (these translate to gestures, behaviors, and contexts for use by intelligent players and instruments using SKINI).  Where possible I will still use these as MIDI extension messages, so foot switches, etc. can be used to control them in real time.

 All fields other than type, time, and channel are optional, and the
 types and useage of the additional fields is defined in the file \c
 SKINI.tbl.

 The other important file used by SKINI is \c SKINI.msg, which is a set of #defines to make C code more readable, and to allow reasonably quick re-mapping of control numbers, etc..  All of these defined symbols are assigned integer values.  For Java, the #defines could be replaced by declaration and assignment statements, preserving the look and behavior of the rest of the code.

 \section cfiles Files Used To Implement SKINI

 Skini is a C++ class which can either open a SKINI file and successively read and parse lines of text as SKINI strings, or accept strings from another object and parse them.  The latter functionality would be used by a socket, pipe, or other connection receiving SKINI messages a line at a time, usually in real time, but not restricted to real time.

 \c SKINI.msg should be included by anything wanting to use the Skini object.  This is not mandatory, but use of the __SK_blah_ symbols which are defined in the .msg file will help to ensure clarity and consistency when messages are added and changed.

 \c SKINI.tbl is used only by the Skini parser object (Skini.cpp). In the file \c SKINI.tbl, an array of structures is declared and assigned values which instruct the parser as to what the message types are, and what the fields mean for those message types.  This table is compiled and linked into applications using SKINI, but could be dynamically loaded and changed in a future version of SKINI.

 \section parser SKINI Messages and the SKINI Parser:

 The parser isn't all that smart, but neither am I.  Here are the basic rules governing a valid SKINI message:

 - If the first (non-delimiter ... see below) character in a SKINI string is '/' that line is treated as a comment and echoed to stdout.

 - Spaces, commas, and tabs delimit the fields in a SKINI message line.  (We might allow for multiple messages per line later using the semicolon, but probably not.  A series of lines with deltaTimes of 0.0 denotes simultaneous events.  For read-ability, multiple messages per line doesn't help much, so it's unlikely to be supported later).

 - The first field must be a SKINI message name (like NoteOn).  These might become case-insensitive in future versions, so don't plan on exciting clever overloading of names (like noTeOn being different from NoTeON).  There can be a number of leading spaces or tabs, but don't exceed 32 or so.

 - The second field must be a time specification in seconds.  A time field can be either delta-time (most common and the only one supported in version 0.8), or absolute time.  Absolute time messages have an '=' appended to the beginning of the floating point number with no space.  So 0.10000 means delta time of 100 ms, while =0.10000 means absolute time of 100 ms.  Absolute time messages make most sense in score files, but could also be used for (loose) synchronization in a real-time context.  Real-time messages should be time-ordered AND time-correct.  That is, if you've sent 100 total delta-time messages of 1.0 seconds, and then send an absolute time message of =90.0 seconds, or if you send two absolute time messages of =100.0 and =90.0 in that order, things will get really fouled up.  The SKINI parser doesn't know about time, however.  The WvOut device is the master time keeper in the Synthesis Toolkit, so it should be queried to see if absolute time messages are making sense.  There's an example of how to do that later in this document.  Absolute times are returned by the parser as negative numbers (since negative deltaTimes are not allowed).

 - The third field must be an integer channel number.  Don't go crazy and think that this is just MIDI channel 0-15 (which is supported).  The channel number is scanned as a long int.  Channels 0-15 are in general to be treated as MIDI channels.  After that it's wide open.  Channels could be socket numbers, machine IDs, serial numbers, or even unique tags for each event in a synthesis.  A -1 channel can be used as don't care, omni, or other functions depending on your needs and taste.

 - All remaining fields are specified in the \c SKINI.tbl file.  In general, there are maximum two more fields, which are either SK_INT (long), SK_DBL (double float), or SK_STR (string).  The latter is the mechanism by which more arguments can be specified on the line, but the object using SKINI must take that string apart (retrived by using getRemainderString()) and scan it.  Any excess fields are stashed in remainderString.

 \section file A Short SKINI File:

 \code
        /*  Howdy!!! Welcome to SKINI, by P. Cook 1999

        NoteOn          0.000082 2 55 82
        NoteOff         1.000000 2 55 0
        NoteOn          0.000082 2 69 82
        StringDetune    0.100000 2    10
        StringDetune    0.100000 2    30
        StringDetune    0.100000 2    50
        NoteOn          0.000000 2 69 82
        StringDetune    0.100000 2    40
        StringDetune    0.100000 2    22
        StringDetune    0.100000 2    12
        //
        StringDamping   0.000100 2 0.0
        NoteOn          0.000082 2 55 82
        NoteOn          0.200000 2 62 82
        NoteOn          0.100000 2 71 82
        NoteOn          0.200000 2 79 82
        NoteOff         1.000000 2 55 82
        NoteOff         0.000000 2 62 82
        NoteOff         0.000000 2 71 82
        NoteOff         0.000000 2 79 82
        StringDamping  =4.000000 2 0.0
        NoteOn          0.000082 2 55 82
        NoteOn          0.200000 2 62 82
        NoteOn          0.100000 2 71 82
        NoteOn          0.200000 2 79 82
        NoteOff         1.000000 2 55 82
        NoteOff         0.000000 2 62 82
        NoteOff         0.000000 2 71 82
        NoteOff         0.000000 2 79 82
 \endcode

 \section table  The SKINI.tbl File and Message Parsing:

 The \c SKINI.tbl file contains an array of structures which are accessed by the parser object Skini.cpp.  The struct is:

 \code
 struct SKINISpec {
   char messageString[32];
   long  type;
   long data2;
   long data3;
 };
 \endcode

 so an assignment of one of these structs looks like:

 \code
        MessageStr$      ,type, data2, data3,
 \endcode

 <TT>type</TT> is the message type sent back from the SKINI line parser.

 <TT>data<n></TT> is either:

 - NOPE    : field not used, specifically, there aren't going to be any more fields on this line.  So if there is is NOPE in data2, data3 won't even be checked.

 - SK_INT  : byte (actually scanned as 32 bit signed long int).  If it's a MIDI data field which is required to be an integer, like a controller number, it's 0-127.  Otherwise, get creative with SK_INTs.

 - SK_DBL  : double precision floating point.  SKINI uses these in the MIDI context for note numbers with micro tuning, velocities, controller values, etc.

 - SK_STR  : only valid in final field.  This allows (nearly) arbitrary message types to be supported by simply scanning the string to EOL (End Of Line) and then passing it to a more intelligent handler.  For example, MIDI SYSEX (system exclusive) messages can be read as space-delimited integers into the SK_STR buffer.  Longer bulk dumps, soundfiles, etc. should be handled as a new message type pointing to a FileName, Socket, or something else stored in the SK_STR field, or as a new type of multi-line message.

 Each individual SKINI message is parsed and saved to a Skini::Message structure of the form:
 \code
  struct Message { 
    long type;                         /*!< The message type, as defined in SKINI.msg. */
    long channel;                      /*!< The message channel (not limited to 16!). */
    StkFloat time;                     /*!< The message time stamp in seconds (delta or absolute). */
    std::vector<StkFloat> floatValues; /*!< The message values read as floats (values are type-specific). */
    std::vector<long> intValues;       /*!< The message values read as ints (number and values are type-specific). */
    std::string remainder;             /*!< Any remaining message data, read as ascii text. */
  };
 \endcode

 Here's a couple of lines from the \c SKINI.tbl file

 \code
 {"NoteOff"          ,        __SK_NoteOff_,               SK_DBL,  SK_DBL},
 {"NoteOn"           ,         __SK_NoteOn_,               SK_DBL,  SK_DBL},

 {"ControlChange"    ,  __SK_ControlChange_,               SK_INT,  SK_DBL},
 {"Volume"           ,  __SK_ControlChange_, __SK_Volume_        ,  SK_DBL},

 {"StringDamping"    ,   __SK_ControlChange_, __SK_StringDamping_,  SK_DBL},
 {"StringDetune"     ,    __SK_ControlChange_, __SK_StringDetune_,  SK_DBL},
 \endcode

 The first three are basic MIDI messages.  The first two would cause the parser, after recognizing a match of the string "NoteOff" or "NoteOn", to set the message type to 128 or 144 (__SK_NoteOff_ and __SK_NoteOn_ are #defined in the file \c SKINI.msg to be the MIDI byte value, without channel, of the actual MIDI messages for NoteOn and NoteOff).  The parser would then set the time or delta time (this is always done and is therefore not described in the SKINI Message Struct).  The next two fields would be scanned either as double-precision \c floats or as <tt>long ints</tt>, depending on the format specified in \c SKINI.tbl, and saved to the corresponding C++ vector variables in the Skini::Message structure (either \c floatValues or \c intValues).  Floating-point values are also cast to <tt>ints</tt> (and vice-versa) and stored to their respective variables.  For example, an expected integer value of 64 will also be saved as 64.0 in the corresponding \c floatValues variable of the Skini::Message structure.  The remainder of the line is stashed in the remainderString variable.

 The ControlChange spec is basically the same as NoteOn and NoteOff, but the second data byte is set to an integer (for checking later as to what MIDI control is being changed).

 The Volume spec is a MIDI Extension message, which behaves like a ControlChange message with the controller number set explicitly to the value for MIDI Volume (7).  Thus the following two lines would accomplish the same changing of MIDI volume on channel 2:

 \code
    ControlChange  0.000000 2 7 64.1
    Volume         0.000000 2   64.1
 \endcode

 I like the second line better, thus my motivation for SKINI in the first place.

 The StringDamping and StringDetune messages behave the same as the Volume message, but use Control Numbers which aren't specifically nailed-down in MIDI.  Note that these Control Numbers are carried around as long ints, so we're not limited to 0-127.  If, however, you want to use a MIDI controller to play an instrument, using controller numbers in the 0-127 range might make sense.

 \section using Using SKINI:

 Here's a simple example of code which uses the Skini object to read a SKINI file and control a single instrument.

 \code
        Skini score;
        Skini::Message message;
        instrument = new Mandolin(50.0);
        score.setFile( argv[1] );
        while ( score.nextMessage( message ) != 0 ) {
          tempDouble = message.time;
          if (tempDouble < 0)     {
            tempDouble = - tempDouble;
            tempDouble = tempDouble - output.getTime();
            if (tempDouble < 0) {
              printf("Bad News Here!!!  Backward Absolute Time Required.\n");
              tempDouble = 0.0;
            }
          }
          tempLong = (long) ( tempDouble * Stk::sampleRate() );
          for ( i=0; i<tempLong; i++ ) {
            output.tick( instrument->tick() );
          }

          tempDouble3 = message.floatValues[1] * NORM_MIDI;
          if ( message.type == __SK_NoteOn_ ) {
            if ( tempDouble3 == 0.0 ) {
              tempDouble3 = 0.5;
              instrument->noteOff( tempDouble3 );
            }
            else {
              tempLong = message.intValues[0];
              tempDouble2 = Midi2Pitch[tempLong];
              instrument->noteOn( tempDouble2, tempDouble3 );
            }
          }
          else if ( message.type == __SK_NoteOff_ ) {
            instrument->noteOff( tempDouble3 );
          }
          else if ( message.type == __SK_ControlChange_ ) {
            tempLong = message.intValues[0];
            instrument->controlChange( tempLong, tempDouble3 );
          }
        }
 \endcode

 When a SKINI score is passed to a Skini object using the Skini::setFile() function, valid messages are read from the file and returned using the Skini::nextMessage() function.

 The "time" member of a Skini::Message is the deltaTime until the current message should occur.  If this is greater than 0, synthesis occurs until the deltaTime has elapsed.  If deltaTime is less than zero, the time is interpreted as absolute time and the output device is queried as to what time it is now.  That is used to form a deltaTime, and if it's positive we synthesize.  If it's negative, we print an error, pretend this never happened and we hang around hoping to eventually catch up.

 The rest of the code sorts out message types NoteOn, NoteOff (including NoteOn with velocity 0), and ControlChange.  The code implicitly takes into account the integer type of the control number, but all other data is treated as double float.

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/system.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/system.txt
@@ -0,0 +1,35 @@
 /*! \page system System Requirements

 <B>General:</B>
 <UL>
 <LI>A MIDI interface to use MIDI input/output controls. (NOTE: This may be built into the soundcard on your computer.)</LI>
 <LI><A HREF="http://dev.scriptics.com">Tcl/Tk</A> version 8.0 or higher to use the simple Tcl/Tk GUIs provided with the STK distribution (available free over the WWW for all supported realtime platforms).</LI>
 </UL>

 <B>Linux (specific):</B>
 <UL>
 <LI>A soundcard to use realtime audio input/output capabilities.  In order to use the <I><B>effects</B></I> project, the soundcard and drivers must support full duplex mode.</LI>
 <LI><A HREF="http://www.alsa-project.org/">ALSA</A> device drivers and library for realtime sound and MIDI input/output.</LI>
 <LI><A HREF="http://www.opensound.com">OSS</A> device drivers (version 4.0 and higher only) can be used for audio input/output, but MIDI support requires the ALSA library to compile.</LI>
 </UL>

 <B>Macintosh OS X (specific):</B>
 <UL>
 <LI>A C++ compiler is not installed by default with OS X.  It is necessary to download the Developer Kit from the Apple WWW site in order to compile STK or load it from the installation CD-ROM.</LI>
 <LI>If you experience frequent audio input/output "glitches", try increasing the RT_BUFFER_SIZE specified in Stk.h.</LI>
 <LI>The tcl/tk interpreter does not ship by default with OS X and must be downloaded from the internet.  The latest Tcl/Tk Aqua distribution (http://www.apple.com/downloads/macosx/unix_open_source/tcltk.html) has been successfully tested on 10.2 and 10.3 systems.  The default installation will place a link to the wish interpretor at /usr/bin/wish.

 It appears that socket support in Tcl/Tk uses the Nagle algorithm, which produces poor response between changes made in the tcl/tk script and the resulting audio updates.  Note that this is only a problem when using a socket connection from a Tcl/Tk script.</LI>

 </UL>

 <B>Windows95/98/2000/XP/7 (specific):</B>
 <UL>
 <LI>A soundcard to use realtime audio input/output capabilities.  In order to use the <I><B>effects</B></I> project, the soundcard and drivers must support full duplex mode.</LI>
 <LI><A HREF="http://www.microsoft.com/directx/">DirectX</A> 5.0 (or higher) runtime libraries.</LI>
 <LI>For compiling the source (if not already in your system): <UL><LI><A HREF="Misc/dsound.h">dsound.h</A> header file (DirectX 6.1) - put somewhere in your header search path</LI><LI><A HREF="Misc/dsound.lib">dsound.lib</A> library file (DirectX 6.1) - put somewhere in your library search path</LI></UL></LI>
 </UL>

 <P>

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/tutorial.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/tutorial.txt
@@ -0,0 +1,24 @@
 /*! \page tutorial Tutorial

 The Synthesis ToolKit is a set of C++ classes.  In order to go beyond the simple example programs we provide, it is necessary to know some basics about programming in C and C++.  STK's "target audience" includes people who:
 - want to create audio DSP and/or synthesis programs
 - want to use our unit generators and input/output routines rather than code their own
 - want to learn about synthesis and processing algorithms
 - wish to teach real-time synthesis and processing and wish to use some of our classes and examples

 Most ToolKit programmers will likely end up writing a class or two for their own particular needs, but this task is typically simplified by making use of pre-existing STK classes (filters, oscillators, etc.).

 The following tutorial chapters describe many of the fundamental ToolKit concepts and classes.  All tutorial programs are included in the <TT>projects/examples</TT> directory.

 -# \ref fundamentals
 -# \ref hello
 -# \ref compile
 -# \ref filtering
 -# \ref realtime
 -# \ref crealtime
 -# \ref instruments
 -# \ref controlin
 -# \ref multichannel
 -# \ref polyvoices

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/usage.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/doxygen/usage.txt
@@ -0,0 +1,205 @@
 /*! \page usage Usage Documentation

 - \ref directory
 - \ref compiling
 - \ref debug
 - \ref control
 - \ref voices
 - \ref nort
 - \ref rt
 - \ref tcl
 - \ref midi
 - \ref polyphony

 <HR>

 \section directory Directory Structure:

 The top level distribution contains the following directories:

 <UL>
 <LI> The <I><B>src</B></I> directory contains the source .cpp files for all the STK unit generator and algorithm classes.</LI><P>

 <LI> The <I><B>include</B></I> directory contains the header files for all the STK unit generator and algorithm classes.</LI><P>

 <LI> The <I><B>rawwaves</B></I> directory contains various raw, monophonic, 16-bit, big-endian, 22050 Hz soundfiles used with the STK classes.</LI><P>

 <LI> The <I><B>doc</B></I> directory contains documentation about STK.</LI><P>

 <LI> The <I><B>projects</B></I> directory contains various demo and example STK programs.</LI><P>
 </UL>

 This release of STK comes with four separate "project" directories:

 <OL>
 <LI> The <I><B>demo</B></I> project is used to demonstrate nearly all of the STK instruments.  The <I><B>stk-demo</B></I> program has been written to allow a variety of control input and sound data output options.  Simple graphical user interfaces (GUIs) are also provided.<P></LI>

 <LI> The <I><B>effects</B></I> project demonstrates realtime duplex mode (simultaneous audio input and output) operation, when available, as well as various delay-line based effects algorithms.<P></LI>

 <LI> The <I><B>ragamatic</B></I> project is just cool.  Fire it up and be enlightened.<P></LI>

 <LI> The <I><B>eguitar</B></I> project demonstrates how to make an electric guitar with feedback and distortion.<P></LI>

 <LI> The <I><B>examples</B></I> project contains several simple programs that demonstrate audio input/output, including the audio internet streaming classes, as well as most of the tutorial programs.</LI>
 </OL>

 \section compiling Compiling:

 <UL>
 <LI><B>Windows95/98/2000/XP/7:</B> Realtime support is available using either DirectSound, ASIO or WASAPI audio drivers.  For DirectSound support, use the <TT>__WINDOWS_DS__</TT> preprocessor definition and link with the <TT>dsound.lib</TT>, <TT>winmm.lib</TT>, and <TT>Wsock32.lib</TT> libraries. For ASIO support, use the <TT>__WINDOWS_ASIO__</TT> preprocessor definition, include all the files in the <TT>src/asio/</TT> directory (i.e. <TT>asio.h,cpp</TT>, <TT>asiodrivers.h,cpp</TT>, ...), and link with the <TT>winmm.lib</TT>, and <TT>Wsock32.lib</TT> libraries.  For WASAPI support, use the <TT>__WINDOWS_WASAPI__</TT> preprocessor definition.  In addition, the <TT>__LITTLE_ENDIAN__</TT> and <TT>__WINDOWS_MM__</TT> preprocessor definitions are necessary for all Windows systems (RtMidi uses the Windows MultiMedia MIDI API).  Fairly old Visual C++ project files are provided in each project directory, though they may not work on newer versions of MSVS.  As well, the MinGW compiler is supported (see below).  It is important to link with the non-debug libraries when compiling "release" program versions and debug libraries when compiling "debug" program versions.</LI>

 <LI><B>Unix (and MinGW) Systems:</B> A GNU <TT>configure</TT> shell script is included in the distribution for unix-based systems.  From the top-level distribution directory, type <TT>'./configure'</TT> and the script will create <TT>Makefiles</TT> in each project directory specific to the characteristics of the host computer.  Then from within any given project directory (example <TT>demo</TT>), type <TT>'make'</TT> to compile the project.  In addition, an STK library can be compiled from within the <TT>src</TT> directory.

 Several options can be supplied to the <TT>configure</TT> script to customize the build behavior:
 <UL>
 <LI><TT>--disable-realtime</TT> to only compile generic non-realtime classes</LI>
 <LI><TT>--enable-debug</TT> to enable various debug output</LI>
 <LI><TT>--with-alsa</TT> to choose native ALSA API support (default, linux only)</LI>
 <LI><TT>--with-oss</TT> to choose native OSS audio API support (linux only, no native OSS MIDI support)</LI>
 <LI><TT>--with-jack</TT> to choose native JACK API support (linux and Macintosh OS-X)</LI>
 <LI><TT>--with-core</TT> to choose Core Audio API support (Macintosh OS-X)</LI>
 <LI><TT>--with-asio</TT> to choose ASIO Audio API support (Windows)</LI>
 <LI><TT>--with-ds</TT> to choose Windows Direct Sound Audio API support (Windows)</LI>
 </UL>
 <P>
 Note that it is possible to specify as many of the "--with-" options as desired to compile multi-API support.  In addition, it is possible to specify the location of the STK rawwaves and the STK include path as follows:
 \code
 ./configure RAWWAVE_PATH="/home/gary/rawwaves/"
 ./configure INCLUDE_PATH="/home/gary/include/"
 \endcode

 For novice STK users, the default configuration should be adequate.
 </UL>

 For those who wish to create their own system-specific <TT>Makefiles</TT>:
 <UL>
 <LI><B>Linux:</B> Realtime audio support is enabled with either the <TT>__LINUX_ALSA__</TT>, <TT>__UNIX_JACK__</TT>, and/or <TT>__LINUX_OSS__</TT> preprocessor definitions, which are used to select the underlying audio system API(s).  Because the ALSA library is now integrated into the standard Linux kernel, it is the default audio/MIDI API with STK versions 4.2 and higher.  The <TT>__LINUX_ALSASEQ__</TT> preprocessor definition must be included for MIDI support.  Note that native OSS MIDI support no longer exists in RtMidi.  If the <TT>__LINUX_OSS__</TT> preprocessor definition is specified, only OSS (version 4.0) audio support will be compiled and RtMidi will still be compiled using the ALSA API (assuming the <TT>__LINUX_ALSASEQ__</TT> definition is defined).  For this reason, STK now requires the <TT>asound</TT> library for realtime support.  Realtime programs must also link with the <TT>pthread</TT> library.  In addition, the <TT>__LITTLE_ENDIAN__</TT> preprocessor definition is necessary if compiling on a little-endian system.  See the README-Linux file for further system configuration information.</LI>

 <LI><B>Macintosh OS X:</B> Realtime support is enabled with the <TT>__MACOSX_CORE__</TT> and <TT>__UNIX_JACK__</TT> preprocessor definitions, which incorporate the CoreAudio audio/MIDI API and/or the JACK API.  Realtime programs must also link with the <TT>pthread</TT> library and the <TT>CoreAudio</TT>, <TT>CoreMIDI</TT>, and <TT>CoreFoundation</TT> frameworks (for Core Audio support) and/or the JACK library.  See the README-MacOSX file for further system configuration information.</LI>

 <LI><B>Generic (non-realtime):</B> Most STK classes are operating system <I>independent</I> and can be compiled using any current C++ compiler. STK assumes big-endian host byte order by default, so if your system is little-endian (i.e. Intel processor), you must provide the <TT>__LITTLE_ENDIAN__</TT> preprocessor definition to your compiler.  The <I><B>demo</B></I> project will compile without realtime support, allowing the use of SKINI scorefiles for input control and output to a variety of soundfile formats.  The following classes <I>cannot</I> be used without realtime support: RtAudio, RtWvIn, RtWvOut, RtDuplex, RtMidi, Socket, Thread, Mutex, TcpWvIn, TcpWvOut.  Because of this, it is not possible to compile the <I><B>effects</B></I>, <I><B>ragamatic</B></I>, and most of the <I><B>examples</B></I> projects for non-realtime use.</LI>
 </UL>

 \section debug Debugging:

 When developing applications with STK, it is recommended that you define the preprocessor definition <TT>_STK_DEBUG_</TT> when compiling (or specify the <TT>--enable-debug</TT> option to the <TT>configure</TT> script).  This will enable all levels of function argument and error checking within the STK classes.  Without this definition, argument checking does not occur in functions that are expected to be called frequently in an iterative manner.

 \section control Control Data:

 All STK programs in this distribution take input control data in the form of <A HREF="skini.html">SKINI</A> or MIDI messages only.  The Messager class unifies the various means of acquiring control data under a single, easy to use set of functions.  The way that SKINI messages can be sent to the programs is dependent upon the operating system in use, as well as whether the program is running in realtime or not.  In general, it is possible to:

 <OL>
 <LI>Redirect or pipe SKINI scorefiles to an executable.</LI>
 <LI>Pipe realtime SKINI input messages to an executable (not possible under Windows95/98).</LI>
 <LI>Acquire realtime MIDI messages from a MIDI port on your computer.</LI>
 </OL>

 <A HREF="http://dev.scriptics.com">Tcl/Tk</A> graphical user interfaces (GUI) are provided with this distribution that can generate realtime SKINI messages.  Note that the Messager class allows multiple simultaneous socket client connections, together with MIDI and/or piped input.  The <I><B>Md2Skini</B></I> program (in the <I><B>demo</B></I> directory) is mostly obsolete but can be used to create SKINI scorefiles from realtime MIDI input.  


 \section voices Demo: STK Instruments

 The <I><B>demo</B></I> project demonstrates the behavior of all the distributed STK instruments.  The instruments available with this release include:
 <UL>
 <LI>Clarinet: Pretty good physical model of the clarinet</LI>
 <LI>BlowHole: A clarinet physical model with one tonehole and one register vent</LI>
 <LI>Saxofony: A psuedo-conical bore reed instrument that sometimes sounds like a saxophone</LI>
 <LI>Flute: Pretty good physical model of the flute</LI>
 <LI>Brass: Not so bad physical model of a brass instrument</LI>
 <LI>BlowBotl: A basic helmholtz resonator and air jet model</LI>
 <LI>Bowed: Not hideous physical model of a bowed string instrument</LI>
 <LI>Plucked: Yer basic plucked string physical model</LI>
 <LI>StifKarp: A simple plucked, stiff string physical model</LI>
 <LI>Sitar: A simple sitar/plucked string physical model</LI>
 <LI>Mandolin: Two-string mandolin physical model</LI>
 <LI>Rhodey: Rhodes-like electric piano FM synthesis model</LI>
 <LI>Wurley: Wurlitzer-like electric piano FM synthesis model</LI>
 <LI>TubeBell: FM synthesis model</LI>
 <LI>HevyMetl: Distorted synthesizer FM synthesis model</LI>
 <LI>PercFlut: Percussive flute-like FM synthesis model</LI>
 <LI>BeeThree: Cheezy organ FM synthesis model</LI>
 <LI>Moog: Swept filter sampler</LI>
 <LI>FMVoices: Three-formant FM voice synthesis</LI>
 <LI>VoicForm: Four-formant resonance filter voice synthesis</LI>
 <LI>Resonate: Noise through a BiQuad filter</LI>
 <LI>Drummer: Sampling synthesis</LI>
 <LI>BandedWG: Banded waveguide meta-object for bowed bars, tibetan bowls, etc.</LI>
 <LI>Shakers: Various stochastic event models of shaker instruments</LI>
 <LI>ModalBar: Various four-resonance presets (marimba, vibraphone, etc...)</LI>
 <LI>Mesh2D: Two-dimensional, rectilinear digital waveguide mesh</LI>
 <LI>Whistle: Hybrid physical/spectral model of a police whistle</LI>
 </UL>

 \section nort Demo: Non-Realtime Use

 See the information above with respect to compiling STK for non-realtime use.

 In non-realtime mode, it is assumed that input control messages are provided from a SKINI scorefile and that audio output is written to a soundfile (.snd, .wav, .aif, .mat, .raw).  A number of SKINI scorefiles are provided in the <I>scores</I> directory of the <I><B>demo</B></I> project.  Assuming a successful compilation of the <I><B>stk-demo</B></I> program, typing:

 \code
 stk-demo BeeThree -ow myfile.wav -if scores/bookert.ski
 \endcode

 from the <I><B>demo</B></I> directory will play the scorefile <I>bookert.ski</I> using the STK BeeThree instrument and write the resulting audio data to a WAV formatted soundfile called "myfile.wav" (note that you may need to append <TT>./</TT> to the program name if your default shell setup is not set to look in the current directory).  Typing <TT>stk-demo</TT> without any arguments will provide a full program usage description.


 \section rt Demo: Realtime Use

 STK realtime audio and MIDI input/output and realtime SKINI control input via socketing support is provided for Linux, Mac OS-X, and Windows95/98/2000/XP operating systems.  STK realtime SKINI control input via piping is possible under Linux, Mac OS X, and Windows2000/XP only.
 <P>
 Control input and audio output options are typically specified as command-line arguments to STK programs.  For example, the <I><B>stk-demo</B></I> program is invoked as:

 \code
 stk-demo instrument flags
 \endcode

 where instruments include those described above and flags can be any or all of:
 <UL>
 <LI><I>-or</I> for realtime audio output,</LI>
 <LI><I>-ow \<file name\></I> for WAV soundfile output,</LI>
 <LI><I>-os \<file name\></I> for SND (AU) soundfile output,</LI>
 <LI><I>-om \<file name\></I> for MAT-file output,</LI>
 <LI><I>-if \<file name\></I> for a SKINI formatted control file,</LI>
 <LI><I>-ip</I> for realtime SKINI control input via piping,</LI>
 <LI><I>-im \<port\></I> for MIDI control input (with optional port, -1 = virtual port where possible),</LI>
 <LI><I>-s RATE</I> to specify a sample rate,</LI>
 <LI><I>-n NUMBER</I> to specify multivoice polyphony</LI>
 </UL>
 The <i>-ip</i> flag must be used when piping realtime SKINI control data to an STK program.  The <i>-im</i> flag must be used to read MIDI control input from your MIDI port.  Note that you can use both input types simultaneously.

 Assuming a successful compilation of the <I><B>stk-demo</B></I> program, typing:

 \code
 stk-demo BeeThree -or -if scores/bookert.ski
 \endcode

 from the <I><B>demo</B></I> directory will play the scorefile <I>bookert.ski</I> using the STK BeeThree instrument and stream the resulting audio data in realtime to the audio output channel of your computer.  Typing <TT>stk-demo</TT> without any arguments will provide a full program usage description.


 \section tcl Realtime Control Input using Tcl/Tk Graphical User Interfaces:

 There are a number of <A HREF="http://dev.scriptics.com">Tcl/Tk</A> GUIs supplied with the STK projects.  These scripts require Tcl/Tk version 8.0 or later, which can be downloaded for free over the WWW.  On Unix and Windows2000/XP platforms, you can run the various executable scripts (e.g. StkDemo.bat) provided with each project to start everything up (you may need to symbolically link the wishXX executable to the name <I>wish</I>).  The Physical.bat script just implements the following command-line sequence:

 \code
 wish < tcl/Physical.tcl | stk-demo Clarinet -or -ip
 \endcode

 \section midi Realtime MIDI Control Input:

 On all supported realtime platforms, you can direct realtime MIDI input to the STK Clarinet by typing:

 \code
 stk-demo Clarinet -or -im
 \endcode

 This will attempt to use the default MIDI port for input.  An optional MIDI port number can be specified after the <TT>-im</TT> flag.  Valid MIDI ports are numbered from 0 (default) and higher.  On Linux and Macintosh OS-X systems, it is possible to open a virtual MIDI input port (that other software applications can connect to) by specifying a port identifier of -1.

 \section polyphony Polyphony:

 The <I><B>stk-demo</B></I> program supports an arbitrary number of voices via the <TT>-n NUMBER</TT> command-line flag and argument.  For example, you can play eight BeeThree instruments with realtime output and control them from a MIDI device by typing:

 \code
 stk-demo BeeThree -n 8 -or -im
 \endcode

 */
--- a/plugins/community/repos/Autodafe/dep/stk/doc/hierarchy.txt
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/hierarchy.txt
@@ -0,0 +1,179 @@
 STK: A ToolKit of Audio Synthesis Classes and Instruments in C++

 By Perry R. Cook and Gary P. Scavone, 1995--2017.

 STK Classes - See the HTML documentation in the html directory for complete information.


     .- Generator - (Modulate, Noise, SingWave, Envelope, ADSR, Asymp, SineWave, Blit, BlitSaw, BlitSquare, Granulate)
     |
     |- Function - (BowTable, JetTable, ReedTable)
     |
     |- FileRead, FileWrite
     |
     |- WvIn - (FileWvIn, RtWvIn, InetWvIn)
     |             |
     |          FileLoop
     |
     |- WvOut - (FileWvOut, RtWvOut, TcpWvOut)
     |
     |- Filter - (OnePole, OneZero, TwoPole, TwoZero, PoleZero, Biquad, FormSwep, Delay, DelayL, DelayA, TapDelay)
     |
     |- RtAudio, RtMidi, Socket, Thread, Mutex
     |                      |
 Stk -|                  UdpSocket
     |                  TcpServer
     |                  TcpClient
     |
     |- StkFrames
     |
     |- Effect - (Echo, Chorus, PitShift, LentPitShift, PRCRev, JCRev, NRev, FreeVerb)
     |
     |- Voicer, Message, Skini, MidiFileIn, Phonemes, Sphere, Vector3D
     |
     |- Messager
     |
     |- Twang, Guitar
     |
     |            .- FM - (HevyMetl, PercFlut, Rhodey, Wurley, TubeBell, BeeThree, FMVoices)
     |            |
     |            |- Modal - ModalBar
     |            |
     |            |- VoicForm
     |            |
     |            |- Sampler - Moog
     |            |
     |            |- Resonate
     |            |
     |            |- Mandolin
     .- Instrmnt -|
                  |- Drummer
                  |
                  |- Clarinet, BlowHole, Saxofony, Flute, Brass, BlowBotl, Bowed, Plucked, StifKarp, Sitar
                  |
                  |- Shakers
                  |
                  |- BandedWG
                  |
                  |- Mesh2D
                  |
                  .- Whistle


 ***********   UNIT GENERATORS   **************

 Master Class:  Stk.cpp         Sample rate, byte-swapping, error handling functionality

 Sources:       Generator.h     Abstract base class for various source signal classes
               Function.h      Abstract base class for various input/output mapping classes
               Envelope.cpp    Linearly goes to target by rate
               ADSR.cpp        ADSR envelope
               Asymp.cpp       Exponentially approaches target
               Noise.cpp       Random number generator
               SineWave.cpp    Sinusoidal oscillator with internally computed static table
               Blit.cpp        Bandlimited impulse train
               BlitSaw.cpp     Bandlimited sawtooth generator
               BlitSquare.cpp  Bandlimited square wave generator
               Granulate.cpp   Granular synthesis class that processes a monophonic audio file
               FileRead.cpp    Audio file input class (no internal data storage) for RAW, WAV, SND (AU), AIFF, MAT-file files
               WvIn.h          Abstract base class for audio data input classes
               FileWvIn.cpp    Audio file input interface class with interpolation
               FileLoop.cpp    Wavetable looping (subclass of FileWvIn)
               RtWvIn.cpp      Realtime audio input class (subclass of WvIn)
               InetWvIn.cpp    Audio streaming (socket server) input class (subclass of WvIn)

 Sinks:         FileWrite.cpp   Audio file output class (no internal data storage) for RAW, WAV, SND (AU), AIFF, MAT-file files
               WvOut.h         Abstract base class for audio data output classes
               FileWvOut.cpp   Audio file output interface class to FileWrite
               RtWvOut.cpp     Realtime audio output class (subclass of WvOut)
               InetWvOut.cpp   Audio streaming (socket client) output class (subclass of WvOut)

 Filters:       Filter.h        Filter master class
               Iir.h           General infinite-impulse response filter
               Fir.h           General finite-impulse response filter
               OneZero.cpp     One zero filter
               OnePole.cpp     One pole filter
               PoleZero.cpp    One pole/one zero filter
               TwoZero.cpp     Two zero filter
               TwoPole.cpp     Two pole filter
               BiQuad.cpp      Two pole/two zero filter
               FormSwep.cpp    Sweepable biquad filter (goes to target by rate)
               Delay.cpp       Non-interpolating delay line class
               DelayL.cpp      Linearly interpolating delay line
               DelayA.cpp      Allpass interpolating delay line
               TapDelay.cpp    Multi-tap non-interpolating delay line class

 Non-Linear:    JetTabl.h       Cubic jet non-linearity
               BowTabl.h       x^(-3) Bow non-linearity
               ReedTabl.h      One breakpoint saturating reed non-linearity
                                
 Derived:       Modulate.cpp    Periodic and random vibrato: WvIn, Noise, OnePole
               SingWave.cpp    Looping wave table with randomness: Modulate, FileLoop, Envelope


 ********** INSTRUMENTS AND ALGORITHMS **************

 Each class is listed either with some of the unit generators it uses, 
 or in terms of the algorithm it implements.  All inherit from Instrmnt,
 which inherits from Stk.

 Simple.cpp       Simple Instrument              Pulse oscillator + resonant filtered noise
 Plucked.cpp      Basic Plucked String           DelayA, OneZero, OnePole, Noise
 Twang.cpp        Not So Basic Pluck             DelayL, DlineA, Fir, allows commuted synthesis
 Mandolin.cpp     Commuted Mandolin              2 Twangs
 Guitar.cpp       N-String Guitar                N Twangs, bridge coupling, allows feedback and body filter
 StifKarp.cpp     Plucked String with Stiffness  DelayA, DelayL, OneZero, BiQuad, Noise
 Bowed.cpp        So So Bowed String             DelayL, BowTabl, OnePole, BiQuad, WaveLoop, ADSR
 Brass.cpp        Not So Bad Brass Instrument    DelayA, BiQuad, PoleZero, ADSR, WaveLoop
 Clarinet.cpp     Pretty Good Clarinet           DelayL, ReedTabl, OneZero, Envelope, Noise, WaveLoop
 BlowHole.cpp     Clarinet w/ Tone & Vent Holes  DelayL, ReedTabl, OneZero, Envelope, Noise, WaveLoop, PoleZero
 Saxofony.cpp     A Faux Saxophone               DelayL, ReedTabl, OneZero, Envelope, Noise, WaveLoop
 Flute.cpp        Pretty Good Flute              JetTabl, DelayL, OnePole, PoleZero, Noise, ADSR, WaveLoop
 BlowBotl.cpp     Blown Bottle                   JetTabl, BiQuad, PoleZero, Noise, ADSR, WaveLoop
 BandedWG.cpp     Banded Waveguide Meta-Object   Delay, BowTabl, ADSR, BiQuad
 Modal.cpp        N Resonances                   Envelope, WaveLoop, BiQuad, OnePole
 ModalBar.cpp     Various presets                4 Resonance Models
 FM.cpp           N Operator FM Master           ADSR, WaveLoop, TwoZero
 HevyMetl.cpp     Distorted FM Synthesizer       3 Cascade with FB Modulator
 PercFlut.cpp     Percussive Flute               3 Cascade Operators
 Rhodey.cpp       Rhodes-Like Electric Piano     2 Parallel Simple FMs
 Wurley.cpp       Wurlitzer Electric Piano       2 Parallel Simple FMs
 TubeBell.cpp     Classic FM Bell                2 Parallel Simple FMs
 FMVoices.cpp     3 Formant FM Voice             3 Carriers Share 1 Modulator
 VoicForm.cpp     4 Formant Voice Synthesis      FormSwep, SingWave, OnePole, OneZero, Envelope, Noise
 BeeThree.cpp     Cheezy Additive Organ          4 Oscillators Additive
 Sampler.cpp      Sampling Synthesizer           5 each ADSR, WvIn, WaveLoop, OnePole
 Moog.cpp         Swept Filter                   Sampler with Swept Filter
 Resonate.cpp     Filtered Noise                 ADSR, BiQuad, Noise
 Drummer.cpp      Drum Synthesizer               Bunch of WvIns, and OnePole
 Shakers.cpp      PhISM statistical model for shakers and real-world sound effects
 Mesh2D.cpp       Two-dimensional, rectilinear digital waveguide mesh.
 Whistle.cpp      Hybrid physical/spectral model of a police whistle.

 Effect.h         Effects Processor Base Class
 JCRev.cpp        Chowning Reverberator           3 series allpass units, 4 parallel combs, 2 stereo delays
 NRev.cpp         Another famous CCRMA Reverb	    8 allpass, 6 parallel comb filters
 PRCRev.cpp       Dirt Cheap Reverb by Cook	      2 allpass, 2 comb filters
 FreeVerb.cpp     Jezar at Dreampoint's FreeVerb  4 allpass, 8 lowpass comb filters
 Flanger.cpp      Flanger Effects Processor       DelayL, WaveLoop
 Chorus.cpp       Chorus Effects Processor        DelayL, WaveLoop
 PitShift.cpp     Cheap Pitch Shifter             DelayL
 LentPitShift.cpp Pitch Shifter based Lent Algorithm


 ***********   OTHER SUPPORT CLASSES AND FILES   **************

 RtAudio.cpp     Multi-OS/API audio I/O routines
 RtMidi.cpp      Multi-OS/API MIDI I/O routines
 Messager.cpp    Pipe, socket, and MIDI control message handling
 Voicer.cpp      Multi-instrument voice manager

 demo.cpp        Demonstration program for most synthesis algorithms
 effects.cpp     Effects demonstration program
 ragamatic.cpp   Nirvana just waiting to happen

 Skini.cpp	      SKINI file/message parser object
 SKINImsg.h	      #defines for often used and universal MIDI/SKINI symbols
 SKINItbl.h	      Table of SKINI messages


--- a/plugins/community/repos/Autodafe/dep/stk/doc/treesed.html
+++ b/plugins/community/repos/Autodafe/dep/stk/doc/treesed.html
@@ -0,0 +1,175 @@
 <html>
 <head>
 <title>Treesed Usage</title>
 </head>
 <body>
 <table border="0" width="660" cellpadding="0" cellspacing="0">
 <tbody><tr valign="top"><td width="165">

 <h3>How to Use Treesed</h3>

 Go to the directory where you want to search or make changes.  

 <p>
 There are two choices you can make when using treesed:
 </p><ol>
 <li>Do I just want to search for a text, or do I want to search for a
 text and replace it with something else?  
 <br>
 If you are just searching you are using Treesed in "search mode", otherwise it is in
 "replace mode."
 </li><li>Do I want to search/replace only in files in my current directory,
 or should files in all subdirectories (and all directories below that)
 also be done?
 </li></ol>
 Some examples will make this clear.

 <h4>Searching</h4>
 Say you are faced with the situation that the author of a slew of web-pages, Nathan Brazil, has left and has been succeeded by Mavra Chang.  First, let us see which files are affected by this (what you type in is shown in <b><tt>bold</tt></b>):
 <blockquote>
 <pre>[localhost] <b>treesed "Nathan Brazil" -files *.html</b>
 search_pattern: Nathan\ Brazil
 replacement_pattern: 

 ** Search mode

 .
 midnight.html: 1 lines on: 2
 ..
 well.html: 1 lines on: 3
 </pre>
 </blockquote>
 We notice the following:
 <ul>
 <li>The search text <tt>"Nathan Brazil"</tt> is enclosed in
 double-quotes (<tt>"</tt>).
 </li><li>You specify which files to search with <tt>-files</tt> followed by a
 list of file names--in this case <tt>*.html</tt>.
 </li><li>Treesed reports the search pattern ("pattern" is just a fancy word
 for "text") you specified (you can ignore
 that \).
 </li><li>Treesed reports an empty <tt>replacement_pattern</tt>.  This is
 correct, because you haven't entered one.
 </li><li>It therefore deduces that is is in search mode.
 </li><li>It finds two files containing "Nathan Brazil", and reports on which
 lines of these files it found it; it does not show the lines themselves.
 </li></ul>
 Because you used <tt>-files</tt>, Treesed will search in the files you
 specify <i>in the current directory</i>.  You can also search files in
 the current directory <i>and</i> all directories below it.  However, in
 that case you can not specify which file names to use, all files will be
 searched:
 <blockquote>
 <pre>[localhost] <b>treesed "Nathan Brazil" -tree</b>
 search_pattern: Nathan\ Brazil
 replacement_pattern: 

 ** Search mode

 .
 midnight.html: 1 lines on: 2
 ...
 well.html: 1 lines on: 3
 .
 new/echoes.html: 1 lines on: 2
 </pre>
 </blockquote>
 We notice the following:
 <ul>
 <li>Instead of <tt>-files</tt> we now see <tt>-tree</tt>.
 </li><li>We do not see a specification of file names.
 </li><li>Treesed finds an occurence of "Nathan Brazil" in the file
 <tt>echoes.html</tt> in the subdirectory <tt>new</tt>; it did not
 find this file in the previous example (as it shouldn't).
 </li></ul>

 <h4>Replacing</h4>
 To replace a text you simply add the replacement text right after the
 search text:
 <blockquote>
 <pre>[localhost] <b>treesed "Nathan Brazil" "Mavra Change" -files *.html</b>
 search_pattern: Nathan\ Brazil
 replacement_pattern: Mavra Chang

 ** EDIT MODE!

 .
 midnight.html: 1 lines on: 2

 Replaced Nathan\ Brazil by Mavra Chang on 1 lines in midnight.html
 ..
 well.html: 1 lines on: 3

 Replaced Nathan\ Brazil by Mavra Chang on 1 lines in well.html
 </pre>
 </blockquote>
 We notice the following:
 <ul>
 <li>Right after the search text "Nathan Brazil" you specify the
 replacement text "Mavra Chang".
 </li><li>As a result, Treesed now reports a non-empty
 <tt>replacement_pattern</tt>.
 </li><li>Hence it concludes it is in "edit mode", which means replacment mode.
 </li><li>Treesed dutifully reports on which lines in which files it did the
 replacement.
 </li></ul>
 To replace a text in all files in the current directory and the ones
 below it, we do the following:
 <blockquote>
 <pre>[localhost] <b>treesed "Nathan Brazil" "Mavra Chang" -tree</b>
 search_pattern: Nathan\ Brazil
 replacement_pattern: Mavra Chang

 ** EDIT MODE!

 .
 midnight.html: 1 lines on: 2

 Replaced Nathan\ Brazil by Mavra Chang on 1 lines in midnight.html

 ....
 well.html: 1 lines on: 3

 Replaced Nathan\ Brazil by Mavra Chang on 1 lines in well.html
 .
 new/echoes.html: 1 lines on: 2

 Replaced Nathan\ Brazil by Mavra Chang on 1 lines in new/echoes.html
 </pre>
 </blockquote>
 and we get the expected results, including the replace in
 <tt>new/echoes.html</tt>.

 <h4>Old Versions</h4>
 Treesed leaves behind quite a mess of old versions of the files it
 changed (only in change-mode, of course).  These old files have the same
 name as the original file, with <tt>.ddddd</tt> appended to it.  For
 example, if treesed makes a change to <tt>midnight.html</tt> it will
 leave the original version as something like
 <tt>midnight.html.26299</tt>.  You'll have to remove these files lest
 your disk area clutters up.  Here is a command that does that, <b>but
 beware!</b>  This command removes all files in the current directory and
 all below it, that end in a period followed by one or more 
 digits:
 <blockquote>
 <pre>find . -name "*.[0-9]*" -exec rm {} \;
 </pre>
 </blockquote>

 It is interesting to note that if you use treesed again without cleaning
 up, you may get files like <tt>midnight.html.26299.27654</tt>.  These
 will also be cleaned up by the above slightly dangerous command.


 <h3>About Treesed</h3>
 <tt>treesed</tt> is public domain software developed
 and designed by Rick Jansen from Sara, Amsterdam, Netherlands, January
 1996.

 <p>

 <h3>About This Document</h3>
 This usage document was created by the Division of Information Technology Services at The
 University of Western Ontario.

 </body></html>
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/README-iOS.md
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/README-iOS.md
@@ -0,0 +1,94 @@
 This file contains instructions for integrating the STK in Xcode projects and solutions to common integration issues. 

 ## Setup

 ### If you have [Cocoapods](http://cocoapods.org/)

 1. Add `pod 'STK', '~> 4.5'` to your Podfile.

 1. Run `pod install`

 ### If you don't have Cocoapods

 1. Clone or [download][download_link] the STK into your project's directory.

 1. Open the **STK for iOS** folder, and drag and drop **STK.xcodeproj** into your Xcode project.

 1. Open your project's settings, open the *Build Phases* tab. In the *Link Binary with Libraries* section, add **libSTK.a**. 
 ![][linking_libSTK_screenshot]

 1. In your project's settings, open the *Build Settings* tab. In the *Search Paths* section, double click on the field to the right of *Header Search Paths*, and add the path to the STK's **include** directory relative to your Xcode project's directory.
 ![][header_search_paths_screenshot]


 ## Usage

 1. Import the STK classes in the source files you require. 
  * E.g. `#import "SineWave.h"`

 1. Change the extension of Objective-C files that import STK files to **.mm**. 
  * E.g. **ViewController.m** —> **ViewController.mm**

 You can also look at the [iOS Demo project](..projects/demo/iOS%20Demo) for a sample usage. 


 ## Troubleshooting

 ### 'FileName.h' file not found

 If you get this error when `#import`ing an STK header, you have added the wrong header search path for the STK in your project's settings (see Step 4 in Setup)

 The STK's header search path you need to add is the path to the STK's **include** directory relative to your project's directory (as if you were `cd`ing into it). For example, it is `stk/include/` if the stk directory is inside your project's directory, but it is `../stk/include/` if both share the same directory. 

 If this problem doesn't go away:

 1. Delete **STK.xcodeproj** from your Xcode project
 1. Move the STK directory within your project's directory. 
 1. Follow step 1 from **Setup**, add `stk/include` to the *Header Search Paths*.

 If that doesn't solve it:
 Install Cocoapods and use it to install the STK. It takes one minute and will make your life easier. Visit the [Cocoapods website](http://cocoapods.org/) for installation instructions. 

 ### FileRead::open: could not open or find file (../../rawwaves/filename.raw)!

 If you use a class that makes use of raw waves (such as `Mandolin`, `Wurley`, or `Rhodey`) you need to make sure that the STK's raw wave files are copied into your bundle and that the STK knows where they are. You'll know you need to if you get this runtime error:
 `FileRead::open: could not open or find file (../../rawwaves/filename.raw)!`

 #### If you're using Cocoapods

 Add this code before using a class that needs the raw waves: 
 ```objective-c
 stk::Stk::setRawwavePath([[[NSBundle mainBundle] pathForResource:@"rawwaves" ofType:@"bundle"] UTF8String]);
 ```

 #### If you're not using Cocoapods

 1. Open your project's settings, open the *Build Phases* tab. 
 1. In the *Copy Bundle Resources*, drag and drop **rawwaves.bundle** (it's located in **STK.xcodeproj**'s **Helpers** folder). 
 1. Then add this code before using a class that needs the raw waves: 

 ```objective-c
 NSBundle *rawwaveBundle = [NSBundle bundleWithURL:[[NSBundle mainBundle] URLForResource:@"rawwaves" withExtension:@"bundle"]];
 stk::Stk::setRawwavePath([[rawwaveBundle resourcePath] UTF8String]);
 ```


 ### rawwaves.bundle: No such file or directory

 This means that **rawwaves.bundle** hasn't been copied to the build folder, so you'll need to do it manually:

 Select the rawwaves scheme:

 ![][rawwaves_scheme_screenshot]
  
 Build it (⌘+B)  then build your project's main scheme. 

 ### Apple Mach-O Linker Error

 This means that **STKLib.a** isn't being linked to your binary. Follow step 2 above in [Setup](#setup). 


 [download_link]: https://github.com/thestk/stk/archive/master.zip
 [linking_libSTK_screenshot]: http://i.imgur.com/cLbGrtq.png
 [header_search_paths_screenshot]: http://i.imgur.com/iBTC06h.png
 [rawwaves_scheme_screenshot]: http://i.imgur.com/PKd7epf.png
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/STK.xcodeproj/project.pbxproj
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/STK.xcodeproj/project.pbxproj
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/STK.xcodeproj/project.xcworkspace/contents.xcworkspacedata
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/STK.xcodeproj/project.xcworkspace/contents.xcworkspacedata
@@ -0,0 +1,7 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <Workspace
   version = "1.0">
   <FileRef
      location = "self:STK for iOS.xcodeproj">
   </FileRef>
 </Workspace>
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/README.MD
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/README.MD
@@ -0,0 +1,10 @@
 ##iOS Demo Xcode project

 This project briefly shows how to manually integrate the STK static library into an Xcode project. See the **README** file in the STK's `iOS` directory for precise instructions.

 Currently, this project does not output sound, it only shows how to generate audio samples from the STK classes within an iOS project, and how to control STK objects via UI controls.

 Note the following:

 * ViewController needs to be renamed with the **.mm** extension as it's importing STK files, which are C++.
 * The header search paths in the *Build Settings* of **iOS Demo.xcodeproj** point to `../../include/` because the STK's `include` directory is two directories up relative to it.
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,524 @@
 // !$*UTF8*$!
 {
 	archiveVersion = 1;
 	classes = {
 	};
 	objectVersion = 46;
 	objects = {

 /* Begin PBXBuildFile section */
 		B02FD53618C520D60009ECA9 /* Foundation.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = B02FD53518C520D60009ECA9 /* Foundation.framework */; };
 		B02FD53818C520D60009ECA9 /* CoreGraphics.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = B02FD53718C520D60009ECA9 /* CoreGraphics.framework */; };
 		B02FD53A18C520D60009ECA9 /* UIKit.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = B02FD53918C520D60009ECA9 /* UIKit.framework */; };
 		B02FD54018C520D60009ECA9 /* InfoPlist.strings in Resources */ = {isa = PBXBuildFile; fileRef = B02FD53E18C520D60009ECA9 /* InfoPlist.strings */; };
 		B02FD54218C520D60009ECA9 /* main.m in Sources */ = {isa = PBXBuildFile; fileRef = B02FD54118C520D60009ECA9 /* main.m */; };
 		B02FD54618C520D60009ECA9 /* AppDelegate.m in Sources */ = {isa = PBXBuildFile; fileRef = B02FD54518C520D60009ECA9 /* AppDelegate.m */; };
 		B02FD54818C520D60009ECA9 /* Images.xcassets in Resources */ = {isa = PBXBuildFile; fileRef = B02FD54718C520D60009ECA9 /* Images.xcassets */; };
 		B02FD54F18C520D70009ECA9 /* XCTest.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = B02FD54E18C520D70009ECA9 /* XCTest.framework */; };
 		B02FD55018C520D70009ECA9 /* Foundation.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = B02FD53518C520D60009ECA9 /* Foundation.framework */; };
 		B02FD55118C520D70009ECA9 /* UIKit.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = B02FD53918C520D60009ECA9 /* UIKit.framework */; };
 		B02FD55918C520D70009ECA9 /* InfoPlist.strings in Resources */ = {isa = PBXBuildFile; fileRef = B02FD55718C520D70009ECA9 /* InfoPlist.strings */; };
 		B02FD55B18C520D70009ECA9 /* iOS_DemoTests.m in Sources */ = {isa = PBXBuildFile; fileRef = B02FD55A18C520D70009ECA9 /* iOS_DemoTests.m */; };
 		B02FD57018C521560009ECA9 /* ViewController.mm in Sources */ = {isa = PBXBuildFile; fileRef = B02FD56F18C521560009ECA9 /* ViewController.mm */; };
 		B0779A8718D376F5004DA9B7 /* libSTK.a in Frameworks */ = {isa = PBXBuildFile; fileRef = B0779A8418D376A6004DA9B7 /* libSTK.a */; };
 		B0779A8B18D37C13004DA9B7 /* rawwaves.bundle in Resources */ = {isa = PBXBuildFile; fileRef = B0779A8618D376A6004DA9B7 /* rawwaves.bundle */; };
 /* End PBXBuildFile section */

 /* Begin PBXContainerItemProxy section */
 		B02FD55218C520D70009ECA9 /* PBXContainerItemProxy */ = {
 			isa = PBXContainerItemProxy;
 			containerPortal = B02FD52A18C520D60009ECA9 /* Project object */;
 			proxyType = 1;
 			remoteGlobalIDString = B02FD53118C520D60009ECA9;
 			remoteInfo = "iOS Demo";
 		};
 		B0779A8318D376A6004DA9B7 /* PBXContainerItemProxy */ = {
 			isa = PBXContainerItemProxy;
 			containerPortal = B0779A7E18D376A5004DA9B7 /* STK.xcodeproj */;
 			proxyType = 2;
 			remoteGlobalIDString = B0AC5BEE18CB31DE00D860C0;
 			remoteInfo = STK;
 		};
 		B0779A8518D376A6004DA9B7 /* PBXContainerItemProxy */ = {
 			isa = PBXContainerItemProxy;
 			containerPortal = B0779A7E18D376A5004DA9B7 /* STK.xcodeproj */;
 			proxyType = 2;
 			remoteGlobalIDString = B0EC33B718CB73A70005787B;
 			remoteInfo = rawwaves;
 		};
 /* End PBXContainerItemProxy section */

 /* Begin PBXFileReference section */
 		B02FD53218C520D60009ECA9 /* iOS Demo.app */ = {isa = PBXFileReference; explicitFileType = wrapper.application; includeInIndex = 0; path = "iOS Demo.app"; sourceTree = BUILT_PRODUCTS_DIR; };
 		B02FD53518C520D60009ECA9 /* Foundation.framework */ = {isa = PBXFileReference; lastKnownFileType = wrapper.framework; name = Foundation.framework; path = System/Library/Frameworks/Foundation.framework; sourceTree = SDKROOT; };
 		B02FD53718C520D60009ECA9 /* CoreGraphics.framework */ = {isa = PBXFileReference; lastKnownFileType = wrapper.framework; name = CoreGraphics.framework; path = System/Library/Frameworks/CoreGraphics.framework; sourceTree = SDKROOT; };
 		B02FD53918C520D60009ECA9 /* UIKit.framework */ = {isa = PBXFileReference; lastKnownFileType = wrapper.framework; name = UIKit.framework; path = System/Library/Frameworks/UIKit.framework; sourceTree = SDKROOT; };
 		B02FD53D18C520D60009ECA9 /* iOS Demo-Info.plist */ = {isa = PBXFileReference; lastKnownFileType = text.plist.xml; path = "iOS Demo-Info.plist"; sourceTree = "<group>"; };
 		B02FD53F18C520D60009ECA9 /* en */ = {isa = PBXFileReference; lastKnownFileType = text.plist.strings; name = en; path = en.lproj/InfoPlist.strings; sourceTree = "<group>"; };
 		B02FD54118C520D60009ECA9 /* main.m */ = {isa = PBXFileReference; lastKnownFileType = sourcecode.c.objc; path = main.m; sourceTree = "<group>"; };
 		B02FD54318C520D60009ECA9 /* iOS Demo-Prefix.pch */ = {isa = PBXFileReference; lastKnownFileType = sourcecode.c.h; path = "iOS Demo-Prefix.pch"; sourceTree = "<group>"; };
 		B02FD54418C520D60009ECA9 /* AppDelegate.h */ = {isa = PBXFileReference; lastKnownFileType = sourcecode.c.h; path = AppDelegate.h; sourceTree = "<group>"; };
 		B02FD54518C520D60009ECA9 /* AppDelegate.m */ = {isa = PBXFileReference; lastKnownFileType = sourcecode.c.objc; path = AppDelegate.m; sourceTree = "<group>"; };
 		B02FD54718C520D60009ECA9 /* Images.xcassets */ = {isa = PBXFileReference; lastKnownFileType = folder.assetcatalog; path = Images.xcassets; sourceTree = "<group>"; };
 		B02FD54D18C520D70009ECA9 /* iOS DemoTests.xctest */ = {isa = PBXFileReference; explicitFileType = wrapper.cfbundle; includeInIndex = 0; path = "iOS DemoTests.xctest"; sourceTree = BUILT_PRODUCTS_DIR; };
 		B02FD54E18C520D70009ECA9 /* XCTest.framework */ = {isa = PBXFileReference; lastKnownFileType = wrapper.framework; name = XCTest.framework; path = Library/Frameworks/XCTest.framework; sourceTree = DEVELOPER_DIR; };
 		B02FD55618C520D70009ECA9 /* iOS DemoTests-Info.plist */ = {isa = PBXFileReference; lastKnownFileType = text.plist.xml; path = "iOS DemoTests-Info.plist"; sourceTree = "<group>"; };
 		B02FD55818C520D70009ECA9 /* en */ = {isa = PBXFileReference; lastKnownFileType = text.plist.strings; name = en; path = en.lproj/InfoPlist.strings; sourceTree = "<group>"; };
 		B02FD55A18C520D70009ECA9 /* iOS_DemoTests.m */ = {isa = PBXFileReference; lastKnownFileType = sourcecode.c.objc; path = iOS_DemoTests.m; sourceTree = "<group>"; };
 		B02FD56E18C521560009ECA9 /* ViewController.h */ = {isa = PBXFileReference; fileEncoding = 4; lastKnownFileType = sourcecode.c.h; path = ViewController.h; sourceTree = "<group>"; };
 		B02FD56F18C521560009ECA9 /* ViewController.mm */ = {isa = PBXFileReference; fileEncoding = 4; lastKnownFileType = sourcecode.cpp.objcpp; path = ViewController.mm; sourceTree = "<group>"; };
 		B0779A7E18D376A5004DA9B7 /* STK.xcodeproj */ = {isa = PBXFileReference; lastKnownFileType = "wrapper.pb-project"; name = STK.xcodeproj; path = ../STK.xcodeproj; sourceTree = "<group>"; };
 		B0779A8918D37977004DA9B7 /* README.MD */ = {isa = PBXFileReference; fileEncoding = 4; lastKnownFileType = text; path = README.MD; sourceTree = "<group>"; };
 /* End PBXFileReference section */

 /* Begin PBXFrameworksBuildPhase section */
 		B02FD52F18C520D60009ECA9 /* Frameworks */ = {
 			isa = PBXFrameworksBuildPhase;
 			buildActionMask = 2147483647;
 			files = (
 				B0779A8718D376F5004DA9B7 /* libSTK.a in Frameworks */,
 				B02FD53818C520D60009ECA9 /* CoreGraphics.framework in Frameworks */,
 				B02FD53A18C520D60009ECA9 /* UIKit.framework in Frameworks */,
 				B02FD53618C520D60009ECA9 /* Foundation.framework in Frameworks */,
 			);
 			runOnlyForDeploymentPostprocessing = 0;
 		};
 		B02FD54A18C520D70009ECA9 /* Frameworks */ = {
 			isa = PBXFrameworksBuildPhase;
 			buildActionMask = 2147483647;
 			files = (
 				B02FD54F18C520D70009ECA9 /* XCTest.framework in Frameworks */,
 				B02FD55118C520D70009ECA9 /* UIKit.framework in Frameworks */,
 				B02FD55018C520D70009ECA9 /* Foundation.framework in Frameworks */,
 			);
 			runOnlyForDeploymentPostprocessing = 0;
 		};
 /* End PBXFrameworksBuildPhase section */

 /* Begin PBXGroup section */
 		B02FD52918C520D60009ECA9 = {
 			isa = PBXGroup;
 			children = (
 				B0779A8918D37977004DA9B7 /* README.MD */,
 				B0779A7E18D376A5004DA9B7 /* STK.xcodeproj */,
 				B02FD53B18C520D60009ECA9 /* iOS Demo */,
 				B02FD55418C520D70009ECA9 /* iOS DemoTests */,
 				B02FD53418C520D60009ECA9 /* Frameworks */,
 				B02FD53318C520D60009ECA9 /* Products */,
 			);
 			sourceTree = "<group>";
 		};
 		B02FD53318C520D60009ECA9 /* Products */ = {
 			isa = PBXGroup;
 			children = (
 				B02FD53218C520D60009ECA9 /* iOS Demo.app */,
 				B02FD54D18C520D70009ECA9 /* iOS DemoTests.xctest */,
 			);
 			name = Products;
 			sourceTree = "<group>";
 		};
 		B02FD53418C520D60009ECA9 /* Frameworks */ = {
 			isa = PBXGroup;
 			children = (
 				B02FD53518C520D60009ECA9 /* Foundation.framework */,
 				B02FD53718C520D60009ECA9 /* CoreGraphics.framework */,
 				B02FD53918C520D60009ECA9 /* UIKit.framework */,
 				B02FD54E18C520D70009ECA9 /* XCTest.framework */,
 			);
 			name = Frameworks;
 			sourceTree = "<group>";
 		};
 		B02FD53B18C520D60009ECA9 /* iOS Demo */ = {
 			isa = PBXGroup;
 			children = (
 				B02FD54418C520D60009ECA9 /* AppDelegate.h */,
 				B02FD54518C520D60009ECA9 /* AppDelegate.m */,
 				B02FD56E18C521560009ECA9 /* ViewController.h */,
 				B02FD56F18C521560009ECA9 /* ViewController.mm */,
 				B02FD54718C520D60009ECA9 /* Images.xcassets */,
 				B02FD53C18C520D60009ECA9 /* Supporting Files */,
 			);
 			path = "iOS Demo";
 			sourceTree = "<group>";
 		};
 		B02FD53C18C520D60009ECA9 /* Supporting Files */ = {
 			isa = PBXGroup;
 			children = (
 				B02FD53D18C520D60009ECA9 /* iOS Demo-Info.plist */,
 				B02FD53E18C520D60009ECA9 /* InfoPlist.strings */,
 				B02FD54118C520D60009ECA9 /* main.m */,
 				B02FD54318C520D60009ECA9 /* iOS Demo-Prefix.pch */,
 			);
 			name = "Supporting Files";
 			sourceTree = "<group>";
 		};
 		B02FD55418C520D70009ECA9 /* iOS DemoTests */ = {
 			isa = PBXGroup;
 			children = (
 				B02FD55A18C520D70009ECA9 /* iOS_DemoTests.m */,
 				B02FD55518C520D70009ECA9 /* Supporting Files */,
 			);
 			path = "iOS DemoTests";
 			sourceTree = "<group>";
 		};
 		B02FD55518C520D70009ECA9 /* Supporting Files */ = {
 			isa = PBXGroup;
 			children = (
 				B02FD55618C520D70009ECA9 /* iOS DemoTests-Info.plist */,
 				B02FD55718C520D70009ECA9 /* InfoPlist.strings */,
 			);
 			name = "Supporting Files";
 			sourceTree = "<group>";
 		};
 		B0779A7F18D376A5004DA9B7 /* Products */ = {
 			isa = PBXGroup;
 			children = (
 				B0779A8418D376A6004DA9B7 /* libSTK.a */,
 				B0779A8618D376A6004DA9B7 /* rawwaves.bundle */,
 			);
 			name = Products;
 			sourceTree = "<group>";
 		};
 /* End PBXGroup section */

 /* Begin PBXNativeTarget section */
 		B02FD53118C520D60009ECA9 /* iOS Demo */ = {
 			isa = PBXNativeTarget;
 			buildConfigurationList = B02FD55E18C520D70009ECA9 /* Build configuration list for PBXNativeTarget "iOS Demo" */;
 			buildPhases = (
 				B02FD52E18C520D60009ECA9 /* Sources */,
 				B02FD52F18C520D60009ECA9 /* Frameworks */,
 				B02FD53018C520D60009ECA9 /* Resources */,
 			);
 			buildRules = (
 			);
 			dependencies = (
 			);
 			name = "iOS Demo";
 			productName = "iOS Demo";
 			productReference = B02FD53218C520D60009ECA9 /* iOS Demo.app */;
 			productType = "com.apple.product-type.application";
 		};
 		B02FD54C18C520D70009ECA9 /* iOS DemoTests */ = {
 			isa = PBXNativeTarget;
 			buildConfigurationList = B02FD56118C520D70009ECA9 /* Build configuration list for PBXNativeTarget "iOS DemoTests" */;
 			buildPhases = (
 				B02FD54918C520D70009ECA9 /* Sources */,
 				B02FD54A18C520D70009ECA9 /* Frameworks */,
 				B02FD54B18C520D70009ECA9 /* Resources */,
 			);
 			buildRules = (
 			);
 			dependencies = (
 				B02FD55318C520D70009ECA9 /* PBXTargetDependency */,
 			);
 			name = "iOS DemoTests";
 			productName = "iOS DemoTests";
 			productReference = B02FD54D18C520D70009ECA9 /* iOS DemoTests.xctest */;
 			productType = "com.apple.product-type.bundle.unit-test";
 		};
 /* End PBXNativeTarget section */

 /* Begin PBXProject section */
 		B02FD52A18C520D60009ECA9 /* Project object */ = {
 			isa = PBXProject;
 			attributes = {
 				LastUpgradeCheck = 0510;
 				ORGANIZATIONNAME = "Ariel Elkin";
 				TargetAttributes = {
 					B02FD54C18C520D70009ECA9 = {
 						TestTargetID = B02FD53118C520D60009ECA9;
 					};
 				};
 			};
 			buildConfigurationList = B02FD52D18C520D60009ECA9 /* Build configuration list for PBXProject "iOS Demo" */;
 			compatibilityVersion = "Xcode 3.2";
 			developmentRegion = English;
 			hasScannedForEncodings = 0;
 			knownRegions = (
 				en,
 			);
 			mainGroup = B02FD52918C520D60009ECA9;
 			productRefGroup = B02FD53318C520D60009ECA9 /* Products */;
 			projectDirPath = "";
 			projectReferences = (
 				{
 					ProductGroup = B0779A7F18D376A5004DA9B7 /* Products */;
 					ProjectRef = B0779A7E18D376A5004DA9B7 /* STK.xcodeproj */;
 				},
 			);
 			projectRoot = "";
 			targets = (
 				B02FD53118C520D60009ECA9 /* iOS Demo */,
 				B02FD54C18C520D70009ECA9 /* iOS DemoTests */,
 			);
 		};
 /* End PBXProject section */

 /* Begin PBXReferenceProxy section */
 		B0779A8418D376A6004DA9B7 /* libSTK.a */ = {
 			isa = PBXReferenceProxy;
 			fileType = archive.ar;
 			path = libSTK.a;
 			remoteRef = B0779A8318D376A6004DA9B7 /* PBXContainerItemProxy */;
 			sourceTree = BUILT_PRODUCTS_DIR;
 		};
 		B0779A8618D376A6004DA9B7 /* rawwaves.bundle */ = {
 			isa = PBXReferenceProxy;
 			fileType = wrapper.cfbundle;
 			path = rawwaves.bundle;
 			remoteRef = B0779A8518D376A6004DA9B7 /* PBXContainerItemProxy */;
 			sourceTree = BUILT_PRODUCTS_DIR;
 		};
 /* End PBXReferenceProxy section */

 /* Begin PBXResourcesBuildPhase section */
 		B02FD53018C520D60009ECA9 /* Resources */ = {
 			isa = PBXResourcesBuildPhase;
 			buildActionMask = 2147483647;
 			files = (
 				B0779A8B18D37C13004DA9B7 /* rawwaves.bundle in Resources */,
 				B02FD54018C520D60009ECA9 /* InfoPlist.strings in Resources */,
 				B02FD54818C520D60009ECA9 /* Images.xcassets in Resources */,
 			);
 			runOnlyForDeploymentPostprocessing = 0;
 		};
 		B02FD54B18C520D70009ECA9 /* Resources */ = {
 			isa = PBXResourcesBuildPhase;
 			buildActionMask = 2147483647;
 			files = (
 				B02FD55918C520D70009ECA9 /* InfoPlist.strings in Resources */,
 			);
 			runOnlyForDeploymentPostprocessing = 0;
 		};
 /* End PBXResourcesBuildPhase section */

 /* Begin PBXSourcesBuildPhase section */
 		B02FD52E18C520D60009ECA9 /* Sources */ = {
 			isa = PBXSourcesBuildPhase;
 			buildActionMask = 2147483647;
 			files = (
 				B02FD57018C521560009ECA9 /* ViewController.mm in Sources */,
 				B02FD54618C520D60009ECA9 /* AppDelegate.m in Sources */,
 				B02FD54218C520D60009ECA9 /* main.m in Sources */,
 			);
 			runOnlyForDeploymentPostprocessing = 0;
 		};
 		B02FD54918C520D70009ECA9 /* Sources */ = {
 			isa = PBXSourcesBuildPhase;
 			buildActionMask = 2147483647;
 			files = (
 				B02FD55B18C520D70009ECA9 /* iOS_DemoTests.m in Sources */,
 			);
 			runOnlyForDeploymentPostprocessing = 0;
 		};
 /* End PBXSourcesBuildPhase section */

 /* Begin PBXTargetDependency section */
 		B02FD55318C520D70009ECA9 /* PBXTargetDependency */ = {
 			isa = PBXTargetDependency;
 			target = B02FD53118C520D60009ECA9 /* iOS Demo */;
 			targetProxy = B02FD55218C520D70009ECA9 /* PBXContainerItemProxy */;
 		};
 /* End PBXTargetDependency section */

 /* Begin PBXVariantGroup section */
 		B02FD53E18C520D60009ECA9 /* InfoPlist.strings */ = {
 			isa = PBXVariantGroup;
 			children = (
 				B02FD53F18C520D60009ECA9 /* en */,
 			);
 			name = InfoPlist.strings;
 			sourceTree = "<group>";
 		};
 		B02FD55718C520D70009ECA9 /* InfoPlist.strings */ = {
 			isa = PBXVariantGroup;
 			children = (
 				B02FD55818C520D70009ECA9 /* en */,
 			);
 			name = InfoPlist.strings;
 			sourceTree = "<group>";
 		};
 /* End PBXVariantGroup section */

 /* Begin XCBuildConfiguration section */
 		B02FD55C18C520D70009ECA9 /* Debug */ = {
 			isa = XCBuildConfiguration;
 			buildSettings = {
 				ALWAYS_SEARCH_USER_PATHS = NO;
 				CLANG_CXX_LANGUAGE_STANDARD = "gnu++0x";
 				CLANG_CXX_LIBRARY = "libc++";
 				CLANG_ENABLE_MODULES = YES;
 				CLANG_ENABLE_OBJC_ARC = YES;
 				CLANG_WARN_BOOL_CONVERSION = YES;
 				CLANG_WARN_CONSTANT_CONVERSION = YES;
 				CLANG_WARN_DIRECT_OBJC_ISA_USAGE = YES_ERROR;
 				CLANG_WARN_EMPTY_BODY = YES;
 				CLANG_WARN_ENUM_CONVERSION = YES;
 				CLANG_WARN_INT_CONVERSION = YES;
 				CLANG_WARN_OBJC_ROOT_CLASS = YES_ERROR;
 				CLANG_WARN__DUPLICATE_METHOD_MATCH = YES;
 				"CODE_SIGN_IDENTITY[sdk=iphoneos*]" = "iPhone Developer";
 				COPY_PHASE_STRIP = NO;
 				GCC_C_LANGUAGE_STANDARD = gnu99;
 				GCC_DYNAMIC_NO_PIC = NO;
 				GCC_OPTIMIZATION_LEVEL = 0;
 				GCC_PREPROCESSOR_DEFINITIONS = (
 					"DEBUG=1",
 					"$(inherited)",
 				);
 				GCC_SYMBOLS_PRIVATE_EXTERN = NO;
 				GCC_WARN_64_TO_32_BIT_CONVERSION = YES;
 				GCC_WARN_ABOUT_RETURN_TYPE = YES_ERROR;
 				GCC_WARN_UNDECLARED_SELECTOR = YES;
 				GCC_WARN_UNINITIALIZED_AUTOS = YES;
 				GCC_WARN_UNUSED_FUNCTION = YES;
 				GCC_WARN_UNUSED_VARIABLE = YES;
 				IPHONEOS_DEPLOYMENT_TARGET = 7.0;
 				ONLY_ACTIVE_ARCH = YES;
 				SDKROOT = iphoneos;
 			};
 			name = Debug;
 		};
 		B02FD55D18C520D70009ECA9 /* Release */ = {
 			isa = XCBuildConfiguration;
 			buildSettings = {
 				ALWAYS_SEARCH_USER_PATHS = NO;
 				CLANG_CXX_LANGUAGE_STANDARD = "gnu++0x";
 				CLANG_CXX_LIBRARY = "libc++";
 				CLANG_ENABLE_MODULES = YES;
 				CLANG_ENABLE_OBJC_ARC = YES;
 				CLANG_WARN_BOOL_CONVERSION = YES;
 				CLANG_WARN_CONSTANT_CONVERSION = YES;
 				CLANG_WARN_DIRECT_OBJC_ISA_USAGE = YES_ERROR;
 				CLANG_WARN_EMPTY_BODY = YES;
 				CLANG_WARN_ENUM_CONVERSION = YES;
 				CLANG_WARN_INT_CONVERSION = YES;
 				CLANG_WARN_OBJC_ROOT_CLASS = YES_ERROR;
 				CLANG_WARN__DUPLICATE_METHOD_MATCH = YES;
 				"CODE_SIGN_IDENTITY[sdk=iphoneos*]" = "iPhone Developer";
 				COPY_PHASE_STRIP = YES;
 				ENABLE_NS_ASSERTIONS = NO;
 				GCC_C_LANGUAGE_STANDARD = gnu99;
 				GCC_WARN_64_TO_32_BIT_CONVERSION = YES;
 				GCC_WARN_ABOUT_RETURN_TYPE = YES_ERROR;
 				GCC_WARN_UNDECLARED_SELECTOR = YES;
 				GCC_WARN_UNINITIALIZED_AUTOS = YES;
 				GCC_WARN_UNUSED_FUNCTION = YES;
 				GCC_WARN_UNUSED_VARIABLE = YES;
 				IPHONEOS_DEPLOYMENT_TARGET = 7.0;
 				SDKROOT = iphoneos;
 				VALIDATE_PRODUCT = YES;
 			};
 			name = Release;
 		};
 		B02FD55F18C520D70009ECA9 /* Debug */ = {
 			isa = XCBuildConfiguration;
 			buildSettings = {
 				ASSETCATALOG_COMPILER_APPICON_NAME = AppIcon;
 				ASSETCATALOG_COMPILER_LAUNCHIMAGE_NAME = LaunchImage;
 				GCC_PRECOMPILE_PREFIX_HEADER = YES;
 				GCC_PREFIX_HEADER = "iOS Demo/iOS Demo-Prefix.pch";
 				HEADER_SEARCH_PATHS = (
 					../../include/,
 					"$(inherited)",
 					/Applications/Xcode.app/Contents/Developer/Toolchains/XcodeDefault.xctoolchain/usr/include,
 				);
 				INFOPLIST_FILE = "iOS Demo/iOS Demo-Info.plist";
 				PRODUCT_NAME = "$(TARGET_NAME)";
 				WRAPPER_EXTENSION = app;
 			};
 			name = Debug;
 		};
 		B02FD56018C520D70009ECA9 /* Release */ = {
 			isa = XCBuildConfiguration;
 			buildSettings = {
 				ASSETCATALOG_COMPILER_APPICON_NAME = AppIcon;
 				ASSETCATALOG_COMPILER_LAUNCHIMAGE_NAME = LaunchImage;
 				GCC_PRECOMPILE_PREFIX_HEADER = YES;
 				GCC_PREFIX_HEADER = "iOS Demo/iOS Demo-Prefix.pch";
 				HEADER_SEARCH_PATHS = (
 					../../include/,
 					"$(inherited)",
 					/Applications/Xcode.app/Contents/Developer/Toolchains/XcodeDefault.xctoolchain/usr/include,
 				);
 				INFOPLIST_FILE = "iOS Demo/iOS Demo-Info.plist";
 				PRODUCT_NAME = "$(TARGET_NAME)";
 				WRAPPER_EXTENSION = app;
 			};
 			name = Release;
 		};
 		B02FD56218C520D70009ECA9 /* Debug */ = {
 			isa = XCBuildConfiguration;
 			buildSettings = {
 				BUNDLE_LOADER = "$(BUILT_PRODUCTS_DIR)/iOS Demo.app/iOS Demo";
 				FRAMEWORK_SEARCH_PATHS = (
 					"$(SDKROOT)/Developer/Library/Frameworks",
 					"$(inherited)",
 					"$(DEVELOPER_FRAMEWORKS_DIR)",
 				);
 				GCC_PRECOMPILE_PREFIX_HEADER = YES;
 				GCC_PREFIX_HEADER = "iOS Demo/iOS Demo-Prefix.pch";
 				GCC_PREPROCESSOR_DEFINITIONS = (
 					"DEBUG=1",
 					"$(inherited)",
 				);
 				INFOPLIST_FILE = "iOS DemoTests/iOS DemoTests-Info.plist";
 				PRODUCT_NAME = "$(TARGET_NAME)";
 				TEST_HOST = "$(BUNDLE_LOADER)";
 				WRAPPER_EXTENSION = xctest;
 			};
 			name = Debug;
 		};
 		B02FD56318C520D70009ECA9 /* Release */ = {
 			isa = XCBuildConfiguration;
 			buildSettings = {
 				BUNDLE_LOADER = "$(BUILT_PRODUCTS_DIR)/iOS Demo.app/iOS Demo";
 				FRAMEWORK_SEARCH_PATHS = (
 					"$(SDKROOT)/Developer/Library/Frameworks",
 					"$(inherited)",
 					"$(DEVELOPER_FRAMEWORKS_DIR)",
 				);
 				GCC_PRECOMPILE_PREFIX_HEADER = YES;
 				GCC_PREFIX_HEADER = "iOS Demo/iOS Demo-Prefix.pch";
 				INFOPLIST_FILE = "iOS DemoTests/iOS DemoTests-Info.plist";
 				PRODUCT_NAME = "$(TARGET_NAME)";
 				TEST_HOST = "$(BUNDLE_LOADER)";
 				WRAPPER_EXTENSION = xctest;
 			};
 			name = Release;
 		};
 /* End XCBuildConfiguration section */

 /* Begin XCConfigurationList section */
 		B02FD52D18C520D60009ECA9 /* Build configuration list for PBXProject "iOS Demo" */ = {
 			isa = XCConfigurationList;
 			buildConfigurations = (
 				B02FD55C18C520D70009ECA9 /* Debug */,
 				B02FD55D18C520D70009ECA9 /* Release */,
 			);
 			defaultConfigurationIsVisible = 0;
 			defaultConfigurationName = Release;
 		};
 		B02FD55E18C520D70009ECA9 /* Build configuration list for PBXNativeTarget "iOS Demo" */ = {
 			isa = XCConfigurationList;
 			buildConfigurations = (
 				B02FD55F18C520D70009ECA9 /* Debug */,
 				B02FD56018C520D70009ECA9 /* Release */,
 			);
 			defaultConfigurationIsVisible = 0;
 			defaultConfigurationName = Release;
 		};
 		B02FD56118C520D70009ECA9 /* Build configuration list for PBXNativeTarget "iOS DemoTests" */ = {
 			isa = XCConfigurationList;
 			buildConfigurations = (
 				B02FD56218C520D70009ECA9 /* Debug */,
 				B02FD56318C520D70009ECA9 /* Release */,
 			);
 			defaultConfigurationIsVisible = 0;
 			defaultConfigurationName = Release;
 		};
 /* End XCConfigurationList section */
 	};
 	rootObject = B02FD52A18C520D60009ECA9 /* Project object */;
 }
--- a/Demo.xcodeproj/project.xcworkspace/contents.xcworkspacedata
+++ b/Demo.xcodeproj/project.xcworkspace/contents.xcworkspacedata
@@ -0,0 +1,7 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <Workspace
   version = "1.0">
   <FileRef
      location = "self:iOS Demo.xcodeproj">
   </FileRef>
 </Workspace>
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,41 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <!DOCTYPE plist PUBLIC "-//Apple//DTD PLIST 1.0//EN" "http://www.apple.com/DTDs/PropertyList-1.0.dtd">
 <plist version="1.0">
 <dict>
 	<key>IDESourceControlProjectFavoriteDictionaryKey</key>
 	<false/>
 	<key>IDESourceControlProjectIdentifier</key>
 	<string>4E1BA790-84C0-4F40-AECE-98269B537CE6</string>
 	<key>IDESourceControlProjectName</key>
 	<string>iOS Demo</string>
 	<key>IDESourceControlProjectOriginsDictionary</key>
 	<dict>
 		<key>CB047168-D1C4-40BC-85A3-6EB0A20AD217</key>
 		<string>ssh://github.com/arielelkin/stk.git</string>
 	</dict>
 	<key>IDESourceControlProjectPath</key>
 	<string>iOS/Demo/iOS Demo.xcodeproj/project.xcworkspace</string>
 	<key>IDESourceControlProjectRelativeInstallPathDictionary</key>
 	<dict>
 		<key>CB047168-D1C4-40BC-85A3-6EB0A20AD217</key>
 		<string>../../../..</string>
 	</dict>
 	<key>IDESourceControlProjectURL</key>
 	<string>ssh://github.com/arielelkin/stk.git</string>
 	<key>IDESourceControlProjectVersion</key>
 	<integer>110</integer>
 	<key>IDESourceControlProjectWCCIdentifier</key>
 	<string>CB047168-D1C4-40BC-85A3-6EB0A20AD217</string>
 	<key>IDESourceControlProjectWCConfigurations</key>
 	<array>
 		<dict>
 			<key>IDESourceControlRepositoryExtensionIdentifierKey</key>
 			<string>public.vcs.git</string>
 			<key>IDESourceControlWCCIdentifierKey</key>
 			<string>CB047168-D1C4-40BC-85A3-6EB0A20AD217</string>
 			<key>IDESourceControlWCCName</key>
 			<string>stk</string>
 		</dict>
 	</array>
 </dict>
 </plist>
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,14 @@
 //
 //  AppDelegate.h
 //  iOS Demo
 //
 //  Created by Ariel Elkin on 03/03/2014.
 //

 #import <UIKit/UIKit.h>

@interface AppDelegate : UIResponder <UIApplicationDelegate>

@property (strong, nonatomic) UIWindow *window;

@end
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,25 @@
 //
 //  AppDelegate.m
 //  iOS Demo
 //
 //  Created by Ariel Elkin on 03/03/2014.
 //

 #import "AppDelegate.h"
 #import "ViewController.h"

@implementation AppDelegate

 - (BOOL)application:(UIApplication *)application didFinishLaunchingWithOptions:(NSDictionary *)launchOptions
 {
    self.window = [[UIWindow alloc] initWithFrame:[[UIScreen mainScreen] bounds]];
    
    ViewController *vc = [[ViewController alloc] initWithNibName:nil bundle:nil];
    [self.window setRootViewController:vc];
    
    [self.window makeKeyAndVisible];
    
    return YES;
 }

@end
--- a/Demo/Images.xcassets/AppIcon.appiconset/Contents.json
+++ b/Demo/Images.xcassets/AppIcon.appiconset/Contents.json
@@ -0,0 +1,23 @@
 {
  "images" : [
    {
      "idiom" : "iphone",
      "size" : "29x29",
      "scale" : "2x"
    },
    {
      "idiom" : "iphone",
      "size" : "40x40",
      "scale" : "2x"
    },
    {
      "idiom" : "iphone",
      "size" : "60x60",
      "scale" : "2x"
    }
  ],
  "info" : {
    "version" : 1,
    "author" : "xcode"
  }
 }
--- a/Demo/Images.xcassets/LaunchImage.launchimage/Contents.json
+++ b/Demo/Images.xcassets/LaunchImage.launchimage/Contents.json
@@ -0,0 +1,23 @@
 {
  "images" : [
    {
      "orientation" : "portrait",
      "idiom" : "iphone",
      "extent" : "full-screen",
      "minimum-system-version" : "7.0",
      "scale" : "2x"
    },
    {
      "orientation" : "portrait",
      "idiom" : "iphone",
      "subtype" : "retina4",
      "extent" : "full-screen",
      "minimum-system-version" : "7.0",
      "scale" : "2x"
    }
  ],
  "info" : {
    "version" : 1,
    "author" : "xcode"
  }
 }
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,12 @@
 //
 //  ViewController.h
 //  iOS Demo
 //
 //  Created by Ariel Elkin on 03/03/2014.
 //

 #import <UIKit/UIKit.h>

@interface ViewController : UIViewController

@end
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,108 @@
 //
 //  ViewController.m
 //  iOS Demo
 //
 //  Created by Ariel Elkin on 03/03/2014.
 //

 #import "ViewController.h"

 #import "SineWave.h"
 #import "Brass.h"
 #import "Mandolin.h"

@implementation ViewController {
    stk::SineWave *sineWave;
    stk::Brass *brass;
 }

 - (void)loadView {
    self.view = [UIView new];
    [self.view setBackgroundColor:[UIColor whiteColor]];
    [self setupUI];
 }

 - (void)viewDidAppear:(BOOL)animated {
    [super viewDidAppear:animated];
    
    NSUInteger samplesToGenerate = 1000;
    
    //Test SineWave:
    sineWave = new stk::SineWave();
    
    for (NSUInteger i = 0; i < samplesToGenerate; i ++) {
        float sample = sineWave->tick();
        NSLog(@"SineWave sample: %f", sample);
    }
    
    //Test Brass:
    brass = new stk::Brass();
    
    brass->noteOn(400, 1);
    
    for (NSUInteger i = 0; i < samplesToGenerate; i ++) {
        float sample = brass->tick();
        NSLog(@"Brass sample: %f", sample);
    }

    //We're going to be making use of a class that needs
    //raw wave files, we need to tell the STK where
    //the files are:
    stk::Stk::setRawwavePath([[[NSBundle mainBundle] pathForResource:@"rawwaves" ofType:@"bundle"] UTF8String]);


    //Test Mandolin:
    stk::Mandolin *mandolin = new stk::Mandolin(400);
    
    mandolin->pluck(1);
    
    for (NSUInteger i = 0; i < samplesToGenerate; i ++) {
        float sample = mandolin->tick();
        NSLog(@"Mandolin sample: %f", sample);
    }
    
    
    #pragma mark TODO - Audio playback
 }


 - (void)sineSliderMoved:(UISlider *)slider {
    sineWave->setFrequency(slider.value);
    NSLog(@"Setting SineWave frequency to %.2f", slider.value);
 }

 - (void)brassSliderMoved:(UISlider *)slider {
    brass->setFrequency(slider.value);
    NSLog(@"Setting Brass frequency to %.2f", slider.value);
 }

 - (void)setupUI {
    
    //Add slider to control sine wave frequency:
    UISlider *sineSlider = [[UISlider alloc] init];
    [sineSlider addTarget:self action:@selector(sineSliderMoved:) forControlEvents:UIControlEventValueChanged];
    [sineSlider setMinimumValue:0];
    [sineSlider setMaximumValue:800];
    [sineSlider setTranslatesAutoresizingMaskIntoConstraints:NO];
    [self.view addSubview:sineSlider];
    
    NSDictionary *metrics = @{@"sliderWidth": @200};
    
    NSArray *sliderConstraints = [NSLayoutConstraint constraintsWithVisualFormat:@"H:|-40-[sineSlider(sliderWidth)]" options:0 metrics:metrics views:@{@"sineSlider": sineSlider}];
    [self.view addConstraints:sliderConstraints];
    
    //Add slider to control brass's frequency:
    UISlider *brassSlider = [[UISlider alloc] init];
    [brassSlider addTarget:self action:@selector(brassSliderMoved:) forControlEvents:UIControlEventValueChanged];
    [brassSlider setMinimumValue:0];
    [brassSlider setMaximumValue:800];
    [brassSlider setTranslatesAutoresizingMaskIntoConstraints:NO];
    [self.view addSubview:brassSlider];
    
    sliderConstraints = [NSLayoutConstraint constraintsWithVisualFormat:@"H:|-40-[brassSlider(sliderWidth)]" options:0 metrics:metrics views:@{@"brassSlider": brassSlider}];
    [self.view addConstraints:sliderConstraints];
    sliderConstraints = [NSLayoutConstraint constraintsWithVisualFormat:@"V:|-40-[sineSlider]-[brassSlider]" options:0 metrics:nil views:@{@"sineSlider": sineSlider, @"brassSlider": brassSlider}];
    [self.view addConstraints:sliderConstraints];
 }

@end
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,2 @@
 /* Localized versions of Info.plist keys */

--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,38 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <!DOCTYPE plist PUBLIC "-//Apple//DTD PLIST 1.0//EN" "http://www.apple.com/DTDs/PropertyList-1.0.dtd">
 <plist version="1.0">
 <dict>
 	<key>CFBundleDevelopmentRegion</key>
 	<string>en</string>
 	<key>CFBundleDisplayName</key>
 	<string>${PRODUCT_NAME}</string>
 	<key>CFBundleExecutable</key>
 	<string>${EXECUTABLE_NAME}</string>
 	<key>CFBundleIdentifier</key>
 	<string>stk.${PRODUCT_NAME:rfc1034identifier}</string>
 	<key>CFBundleInfoDictionaryVersion</key>
 	<string>6.0</string>
 	<key>CFBundleName</key>
 	<string>${PRODUCT_NAME}</string>
 	<key>CFBundlePackageType</key>
 	<string>APPL</string>
 	<key>CFBundleShortVersionString</key>
 	<string>1.0</string>
 	<key>CFBundleSignature</key>
 	<string>????</string>
 	<key>CFBundleVersion</key>
 	<string>1.0</string>
 	<key>LSRequiresIPhoneOS</key>
 	<true/>
 	<key>UIRequiredDeviceCapabilities</key>
 	<array>
 		<string>armv7</string>
 	</array>
 	<key>UISupportedInterfaceOrientations</key>
 	<array>
 		<string>UIInterfaceOrientationPortrait</string>
 		<string>UIInterfaceOrientationLandscapeLeft</string>
 		<string>UIInterfaceOrientationLandscapeRight</string>
 	</array>
 </dict>
 </plist>
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,16 @@
 //
 //  Prefix header
 //
 //  The contents of this file are implicitly included at the beginning of every source file.
 //

 #import <Availability.h>

 #ifndef __IPHONE_3_0
 #warning "This project uses features only available in iOS SDK 3.0 and later."
 #endif

 #ifdef __OBJC__
    #import <UIKit/UIKit.h>
    #import <Foundation/Foundation.h>
 #endif
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,18 @@
 //
 //  main.m
 //  iOS Demo
 //
 //  Created by Ariel Elkin on 03/03/2014.
 //  Copyright (c) 2014 Ariel Elkin. All rights reserved.
 //

 #import <UIKit/UIKit.h>

 #import "AppDelegate.h"

 int main(int argc, char * argv[])
 {
    @autoreleasepool {
        return UIApplicationMain(argc, argv, nil, NSStringFromClass([AppDelegate class]));
    }
 }
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,2 @@
 /* Localized versions of Info.plist keys */

--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,22 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <!DOCTYPE plist PUBLIC "-//Apple//DTD PLIST 1.0//EN" "http://www.apple.com/DTDs/PropertyList-1.0.dtd">
 <plist version="1.0">
 <dict>
 	<key>CFBundleDevelopmentRegion</key>
 	<string>en</string>
 	<key>CFBundleExecutable</key>
 	<string>${EXECUTABLE_NAME}</string>
 	<key>CFBundleIdentifier</key>
 	<string>stk.${PRODUCT_NAME:rfc1034identifier}</string>
 	<key>CFBundleInfoDictionaryVersion</key>
 	<string>6.0</string>
 	<key>CFBundlePackageType</key>
 	<string>BNDL</string>
 	<key>CFBundleShortVersionString</key>
 	<string>1.0</string>
 	<key>CFBundleSignature</key>
 	<string>????</string>
 	<key>CFBundleVersion</key>
 	<string>1</string>
 </dict>
 </plist>
--- a/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
+++ b/plugins/community/repos/Autodafe/dep/stk/iOS/demo/iOS
@@ -0,0 +1,34 @@
 //
 //  iOS_DemoTests.m
 //  iOS DemoTests
 //
 //  Created by Ariel Elkin on 03/03/2014.
 //  Copyright (c) 2014 Ariel Elkin. All rights reserved.
 //

 #import <XCTest/XCTest.h>

@interface iOS_DemoTests : XCTestCase

@end

@implementation iOS_DemoTests

 - (void)setUp
 {
    [super setUp];
    // Put setup code here. This method is called before the invocation of each test method in the class.
 }

 - (void)tearDown
 {
    // Put teardown code here. This method is called after the invocation of each test method in the class.
    [super tearDown];
 }

 - (void)testExample
 {
    XCTFail(@"No implementation for \"%s\"", __PRETTY_FUNCTION__);
 }

@end
--- a/plugins/community/repos/Autodafe/dep/stk/include/ADSR.h
+++ b/plugins/community/repos/Autodafe/dep/stk/include/ADSR.h
@@ -0,0 +1,179 @@
 #ifndef STK_ADSR_H
 #define STK_ADSR_H

 #include "Generator.h"

 namespace stk {

 /***************************************************/
 /*! \class ADSR
    \brief STK ADSR envelope class.

    This class implements a traditional ADSR (Attack, Decay, Sustain,
    Release) envelope.  It responds to simple keyOn and keyOff
    messages, keeping track of its state.  The \e state = ADSR::IDLE
    before being triggered and after the envelope value reaches 0.0 in
    the ADSR::RELEASE state.  All rate, target and level settings must
    be non-negative.  All time settings are in seconds and must be
    positive.

    by Perry R. Cook and Gary P. Scavone, 1995--2017.
 */
 /***************************************************/

 class ADSR : public Generator
 {
 public:

  //! ADSR envelope states.
  enum {
    ATTACK,   /*!< Attack */
    DECAY,    /*!< Decay */
    SUSTAIN,  /*!< Sustain */
    RELEASE,  /*!< Release */
    IDLE      /*!< Before attack / after release */
  };

  //! Default constructor.
  ADSR( void );

  //! Class destructor.
  ~ADSR( void );

  //! Set target = 1, state = \e ADSR::ATTACK.
  void keyOn( void );

  //! Set target = 0, state = \e ADSR::RELEASE.
  void keyOff( void );

  //! Set the attack rate (gain / sample).
  void setAttackRate( StkFloat rate );

  //! Set the target value for the attack (default = 1.0).
  void setAttackTarget( StkFloat target );

  //! Set the decay rate (gain / sample).
  void setDecayRate( StkFloat rate );

  //! Set the sustain level.
  void setSustainLevel( StkFloat level );

  //! Set the release rate (gain / sample).
  void setReleaseRate( StkFloat rate );

  //! Set the attack rate based on a time duration (seconds).
  void setAttackTime( StkFloat time );

  //! Set the decay rate based on a time duration (seconds).
  void setDecayTime( StkFloat time );

  //! Set the release rate based on a time duration (seconds).
  void setReleaseTime( StkFloat time );

  //! Set sustain level and attack, decay, and release time durations (seconds).
  void setAllTimes( StkFloat aTime, StkFloat dTime, StkFloat sLevel, StkFloat rTime );

  //! Set a sustain target value and attack or decay from current value to target.
  void setTarget( StkFloat target );

  //! Return the current envelope \e state (ATTACK, DECAY, SUSTAIN, RELEASE, IDLE).
  int getState( void ) const { return state_; };

  //! Set to state = ADSR::SUSTAIN with current and target values of \e value.
  void setValue( StkFloat value );

  //! Return the last computed output value.
  StkFloat lastOut( void ) const { return lastFrame_[0]; };

  //! Compute and return one output sample.
  StkFloat tick( void );

  //! Fill a channel of the StkFrames object with computed outputs.
  /*!
    The \c channel argument must be less than the number of
    channels in the StkFrames argument (the first channel is specified
    by 0).  However, range checking is only performed if _STK_DEBUG_
    is defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& frames, unsigned int channel = 0 );

 protected:  

  void sampleRateChanged( StkFloat newRate, StkFloat oldRate );

  int state_;
  StkFloat value_;
  StkFloat target_;
  StkFloat attackRate_;
  StkFloat decayRate_;
  StkFloat releaseRate_;
  StkFloat releaseTime_;
  StkFloat sustainLevel_;
 };

 inline StkFloat ADSR :: tick( void )
 {
  switch ( state_ ) {

  case ATTACK:
    value_ += attackRate_;
    if ( value_ >= target_ ) {
      value_ = target_;
      target_ = sustainLevel_;
 	    state_ = DECAY;
    }
    lastFrame_[0] = value_;
    break;

  case DECAY:
    if ( value_ > sustainLevel_ ) {
      value_ -= decayRate_;
      if ( value_ <= sustainLevel_ ) {
        value_ = sustainLevel_;
        state_ = SUSTAIN;
      }
    }
    else {
      value_ += decayRate_; // attack target < sustain level
      if ( value_ >= sustainLevel_ ) {
        value_ = sustainLevel_;
        state_ = SUSTAIN;
      }
    }
    lastFrame_[0] = value_;
    break;

  case RELEASE:
    value_ -= releaseRate_;
    if ( value_ <= 0.0 ) {
      value_ = 0.0;
      state_ = IDLE;
    }
    lastFrame_[0] = value_;

  }

  return value_;
 }

 inline StkFrames& ADSR :: tick( StkFrames& frames, unsigned int channel )
 {
 #if defined(_STK_DEBUG_)
  if ( channel >= frames.channels() ) {
    oStream_ << "ADSR::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *samples = &frames[channel];
  unsigned int hop = frames.channels();
  for ( unsigned int i=0; i<frames.frames(); i++, samples += hop )
    *samples = ADSR::tick();

  return frames;
 }

 } // stk namespace

 #endif
--- a/plugins/community/repos/Autodafe/dep/stk/include/Asymp.h
+++ b/plugins/community/repos/Autodafe/dep/stk/include/Asymp.h
@@ -0,0 +1,146 @@
 #ifndef STK_ASYMP_H
 #define STK_ASYMP_H

 #include "Generator.h"

 namespace stk {

 /***************************************************/
 /*! \class Asymp
    \brief STK asymptotic curve envelope class

    This class implements a simple envelope generator
    which asymptotically approaches a target value.
    The algorithm used is of the form:

    y[n] = a y[n-1] + (1-a) target,

    where a = exp(-T/tau), T is the sample period, and
    tau is a time constant.  The user can set the time
    constant (default value = 0.3) and target value.
    Theoretically, this recursion never reaches its
    target, though the calculations in this class are
    stopped when the current value gets within a small
    threshold value of the target (at which time the
    current value is set to the target).  It responds
    to \e keyOn and \e keyOff messages by ramping to
    1.0 on keyOn and to 0.0 on keyOff.

    by Perry R. Cook and Gary P. Scavone, 1995--2017.
 */
 /***************************************************/

 const StkFloat TARGET_THRESHOLD = 0.000001;

 class Asymp : public Generator
 {
 public:

  //! Default constructor.
  Asymp( void );

  //! Class destructor.
  ~Asymp( void );

  //! Set target = 1.
  void keyOn( void );

  //! Set target = 0.
  void keyOff( void );

  //! Set the asymptotic rate via the time factor \e tau (must be > 0).
  /*!
    The rate is computed as described above.  The value of \e tau
    must be greater than zero.  Values of \e tau close to zero produce
    fast approach rates, while values greater than 1.0 produce rather
    slow rates.
  */
  void setTau( StkFloat tau );

  //! Set the asymptotic rate based on a time duration (must be > 0).
  void setTime( StkFloat time );

  //! Set the asymptotic rate such that the target value is perceptually reached (to within -60dB of the target) in \e t60 seconds.
  void setT60( StkFloat t60 );

  //! Set the target value.
  void setTarget( StkFloat target );

  //! Set current and target values to \e value.
  void setValue( StkFloat value );

  //! Return the current envelope \e state (0 = at target, 1 otherwise).
  int getState( void ) const { return state_; };

  //! Return the last computed output value.
  StkFloat lastOut( void ) const { return lastFrame_[0]; };

  //! Compute and return one output sample.
  StkFloat tick( void );

  //! Fill a channel of the StkFrames object with computed outputs.
  /*!
    The \c channel argument must be less than the number of
    channels in the StkFrames argument (the first channel is specified
    by 0).  However, range checking is only performed if _STK_DEBUG_
    is defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& frames, unsigned int channel = 0 );

 protected:

  void sampleRateChanged( StkFloat newRate, StkFloat oldRate );

  StkFloat value_;
  StkFloat target_;
  StkFloat factor_;
  StkFloat constant_;
  int state_;
 };

 inline StkFloat Asymp :: tick( void )
 {
  if ( state_ ) {

    value_ = factor_ * value_ + constant_;

    // Check threshold.
    if ( target_ > value_ ) {
      if ( target_ - value_ <= TARGET_THRESHOLD ) {
        value_ = target_;
        state_ = 0;
      }
    }
    else {
      if ( value_ - target_ <= TARGET_THRESHOLD ) {
        value_ = target_;
        state_ = 0;
      }
    }
    lastFrame_[0] = value_;
  }

  return value_;
 }

 inline StkFrames& Asymp :: tick( StkFrames& frames, unsigned int channel )
 {
 #if defined(_STK_DEBUG_)
  if ( channel >= frames.channels() ) {
    oStream_ << "Asymp::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *samples = &frames[channel];
  unsigned int hop = frames.channels();
  for ( unsigned int i=0; i<frames.frames(); i++, samples += hop )
    *samples = Asymp::tick();

  return frames;
 }

 } // stk namespace

 #endif
--- a/plugins/community/repos/Autodafe/dep/stk/include/BandedWG.h
+++ b/plugins/community/repos/Autodafe/dep/stk/include/BandedWG.h
@@ -0,0 +1,153 @@
 #ifndef STK_BANDEDWG_H
 #define STK_BANDEDWG_H

 #include "Instrmnt.h"
 #include "DelayL.h"
 #include "BowTable.h"
 #include "ADSR.h"
 #include "BiQuad.h"

 namespace stk {

 /***************************************************/
 /*! \class BandedWG
    \brief Banded waveguide modeling class.

    This class uses banded waveguide techniques to
    model a variety of sounds, including bowed
    bars, glasses, and bowls.  For more
    information, see Essl, G. and Cook, P. "Banded
    Waveguides: Towards Physical Modelling of Bar
    Percussion Instruments", Proceedings of the
    1999 International Computer Music Conference.

    Control Change Numbers: 
       - Bow Pressure = 2
       - Bow Motion = 4
       - Strike Position = 8 (not implemented)
       - Vibrato Frequency = 11
       - Gain = 1
       - Bow Velocity = 128
       - Set Striking = 64
       - Instrument Presets = 16
         - Uniform Bar = 0
         - Tuned Bar = 1
         - Glass Harmonica = 2
         - Tibetan Bowl = 3

    by Georg Essl, 1999 - 2004.
    Modified for STK 4.0 by Gary Scavone.
 */
 /***************************************************/

 const int MAX_BANDED_MODES = 20;

 class BandedWG : public Instrmnt
 {
 public:
  //! Class constructor.
  BandedWG( void );

  //! Class destructor.
  ~BandedWG( void );

  //! Reset and clear all internal state.
  void clear( void );

  //! Set strike position (0.0 - 1.0).
  void setStrikePosition( StkFloat position );

  //! Select a preset.
  void setPreset( int preset );

  //! Set instrument parameters for a particular frequency.
  void setFrequency( StkFloat frequency );

  //! Apply bow velocity/pressure to instrument with given amplitude and rate of increase.
  void startBowing( StkFloat amplitude, StkFloat rate );

  //! Decrease bow velocity/breath pressure with given rate of decrease.
  void stopBowing( StkFloat rate );

  //! Pluck the instrument with given amplitude.
  void pluck( StkFloat amp );

  //! Start a note with the given frequency and amplitude.
  void noteOn( StkFloat frequency, StkFloat amplitude );

  //! Stop a note with the given amplitude (speed of decay).
  void noteOff( StkFloat amplitude );

  //! Perform the control change specified by \e number and \e value (0.0 - 128.0).
  void controlChange( int number, StkFloat value );

  //! Compute and return one output sample.
  StkFloat tick( unsigned int channel = 0 );

  //! Fill a channel of the StkFrames object with computed outputs.
  /*!
    The \c channel argument must be less than the number of
    channels in the StkFrames argument (the first channel is specified
    by 0).  However, range checking is only performed if _STK_DEBUG_
    is defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& frames, unsigned int channel = 0 );

 protected:

  bool doPluck_;
  bool trackVelocity_;
  int nModes_;
  int presetModes_;
  BowTable bowTable_;
  ADSR     adsr_;
  BiQuad   bandpass_[MAX_BANDED_MODES];
  DelayL   delay_[MAX_BANDED_MODES];
  StkFloat maxVelocity_;
  StkFloat modes_[MAX_BANDED_MODES];
  StkFloat frequency_;
  StkFloat baseGain_;
  StkFloat gains_[MAX_BANDED_MODES];
  StkFloat basegains_[MAX_BANDED_MODES];
  StkFloat excitation_[MAX_BANDED_MODES];
  StkFloat integrationConstant_;
  StkFloat velocityInput_;
  StkFloat bowVelocity_;
  StkFloat bowTarget_;
  StkFloat bowPosition_;
  StkFloat strikeAmp_;
  int strikePosition_;

 };

 inline StkFrames& BandedWG :: tick( StkFrames& frames, unsigned int channel )
 {
  unsigned int nChannels = lastFrame_.channels();
 #if defined(_STK_DEBUG_)
  if ( channel > frames.channels() - nChannels ) {
    oStream_ << "BandedWG::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *samples = &frames[channel];
  unsigned int j, hop = frames.channels() - nChannels;
  if ( nChannels == 1 ) {
    for ( unsigned int i=0; i<frames.frames(); i++, samples += hop )
      *samples++ = tick();
  }
  else {
    for ( unsigned int i=0; i<frames.frames(); i++, samples += hop ) {
      *samples++ = tick();
      for ( j=1; j<nChannels; j++ )
        *samples++ = lastFrame_[j];
    }
  }

  return frames;
 }

 } // stk namespace

 #endif
--- a/plugins/community/repos/Autodafe/dep/stk/include/BeeThree.h
+++ b/plugins/community/repos/Autodafe/dep/stk/include/BeeThree.h
@@ -0,0 +1,127 @@
 #ifndef STK_BEETHREE_H
 #define STK_BEETHREE_H

 #include "FM.h"

 namespace stk {

 /***************************************************/
 /*! \class BeeThree
    \brief STK Hammond-oid organ FM synthesis instrument.

    This class implements a simple 4 operator
    topology, also referred to as algorithm 8 of
    the TX81Z.

    \code
    Algorithm 8 is :
                     1 --.
                     2 -\|
                         +-> Out
                     3 -/|
                     4 --
    \endcode

    Control Change Numbers: 
       - Operator 4 (feedback) Gain = 2
       - Operator 3 Gain = 4
       - LFO Speed = 11
       - LFO Depth = 1
       - ADSR 2 & 4 Target = 128

    The basic Chowning/Stanford FM patent expired
    in 1995, but there exist follow-on patents,
    mostly assigned to Yamaha.  If you are of the
    type who should worry about this (making
    money) worry away.

    by Perry R. Cook and Gary P. Scavone, 1995--2017.
 */
 /***************************************************/

 class BeeThree : public FM
 {
 public:
  //! Class constructor.
  /*!
    An StkError will be thrown if the rawwave path is incorrectly set.
  */
  BeeThree( void );

  //! Class destructor.
  ~BeeThree( void );

  //! Start a note with the given frequency and amplitude.
  void noteOn( StkFloat frequency, StkFloat amplitude );

  //! Compute and return one output sample.
  StkFloat tick( unsigned int channel = 0 );

  //! Fill a channel of the StkFrames object with computed outputs.
  /*!
    The \c channel argument must be less than the number of
    channels in the StkFrames argument (the first channel is specified
    by 0).  However, range checking is only performed if _STK_DEBUG_
    is defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& frames, unsigned int channel = 0 );

 protected:

 };

 inline StkFloat BeeThree :: tick( unsigned int )
 {
  StkFloat temp;

  if ( modDepth_ > 0.0 )	{
    temp = 1.0 + ( modDepth_ * vibrato_.tick() * 0.1 );
    waves_[0]->setFrequency( baseFrequency_ * temp * ratios_[0] );
    waves_[1]->setFrequency( baseFrequency_ * temp * ratios_[1] );
    waves_[2]->setFrequency( baseFrequency_ * temp * ratios_[2] );
    waves_[3]->setFrequency( baseFrequency_ * temp * ratios_[3] );
  }

  waves_[3]->addPhaseOffset( twozero_.lastOut() );
  temp = control1_ * 2.0 * gains_[3] * adsr_[3]->tick() * waves_[3]->tick();
  twozero_.tick( temp );

  temp += control2_ * 2.0 * gains_[2] * adsr_[2]->tick() * waves_[2]->tick();
  temp += gains_[1] * adsr_[1]->tick() * waves_[1]->tick();
  temp += gains_[0] * adsr_[0]->tick() * waves_[0]->tick();

  lastFrame_[0] = temp * 0.125;
  return lastFrame_[0];
 }

 inline StkFrames& BeeThree :: tick( StkFrames& frames, unsigned int channel )
 {
  unsigned int nChannels = lastFrame_.channels();
 #if defined(_STK_DEBUG_)
  if ( channel > frames.channels() - nChannels ) {
    oStream_ << "BeeThree::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *samples = &frames[channel];
  unsigned int j, hop = frames.channels() - nChannels;
  if ( nChannels == 1 ) {
    for ( unsigned int i=0; i<frames.frames(); i++, samples += hop )
      *samples++ = tick();
  }
  else {
    for ( unsigned int i=0; i<frames.frames(); i++, samples += hop ) {
      *samples++ = tick();
      for ( j=1; j<nChannels; j++ )
        *samples++ = lastFrame_[j];
    }
  }

  return frames;
 }

 } // stk namespace

 #endif
--- a/plugins/community/repos/Autodafe/dep/stk/include/BiQuad.h
+++ b/plugins/community/repos/Autodafe/dep/stk/include/BiQuad.h
@@ -0,0 +1,186 @@
 #ifndef STK_BIQUAD_H
 #define STK_BIQUAD_H

 #include "Filter.h"

 namespace stk {

 /***************************************************/
 /*! \class BiQuad
    \brief STK biquad (two-pole, two-zero) filter class.

    This class implements a two-pole, two-zero digital filter.
    Methods are provided for creating a resonance or notch in the
    frequency response while maintaining a constant filter gain.

    by Perry R. Cook and Gary P. Scavone, 1995--2017.
 */
 /***************************************************/

 class BiQuad : public Filter
 {
 public:

  //! Default constructor creates a second-order pass-through filter.
  BiQuad();

  //! Class destructor.
  ~BiQuad();

  //! A function to enable/disable the automatic updating of class data when the STK sample rate changes.
  void ignoreSampleRateChange( bool ignore = true ) { ignoreSampleRateChange_ = ignore; };

  //! Set all filter coefficients.
  void setCoefficients( StkFloat b0, StkFloat b1, StkFloat b2, StkFloat a1, StkFloat a2, bool clearState = false );

  //! Set the b[0] coefficient value.
  void setB0( StkFloat b0 ) { b_[0] = b0; };

  //! Set the b[1] coefficient value.
  void setB1( StkFloat b1 ) { b_[1] = b1; };

  //! Set the b[2] coefficient value.
  void setB2( StkFloat b2 ) { b_[2] = b2; };

  //! Set the a[1] coefficient value.
  void setA1( StkFloat a1 ) { a_[1] = a1; };

  //! Set the a[2] coefficient value.
  void setA2( StkFloat a2 ) { a_[2] = a2; };

  //! Sets the filter coefficients for a resonance at \e frequency (in Hz).
  /*!
    This method determines the filter coefficients corresponding to
    two complex-conjugate poles with the given \e frequency (in Hz)
    and \e radius from the z-plane origin.  If \e normalize is true,
    the filter zeros are placed at z = 1, z = -1, and the coefficients
    are then normalized to produce a constant unity peak gain
    (independent of the filter \e gain parameter).  The resulting
    filter frequency response has a resonance at the given \e
    frequency.  The closer the poles are to the unit-circle (\e radius
    close to one), the narrower the resulting resonance width.
    An unstable filter will result for \e radius >= 1.0.  The
    \e frequency value should be between zero and half the sample rate.
  */
  void setResonance( StkFloat frequency, StkFloat radius, bool normalize = false );

  //! Set the filter coefficients for a notch at \e frequency (in Hz).
  /*!
    This method determines the filter coefficients corresponding to
    two complex-conjugate zeros with the given \e frequency (in Hz)
    and \e radius from the z-plane origin.  No filter normalization is
    attempted.  The \e frequency value should be between zero and half
    the sample rate.  The \e radius value should be positive.
  */
  void setNotch( StkFloat frequency, StkFloat radius );

  //! Sets the filter zeroes for equal resonance gain.
  /*!
    When using the filter as a resonator, zeroes places at z = 1, z
    = -1 will result in a constant gain at resonance of 1 / (1 - R),
    where R is the pole radius setting.

  */
  void setEqualGainZeroes( void );

  //! Return the last computed output value.
  StkFloat lastOut( void ) const { return lastFrame_[0]; };

  //! Input one sample to the filter and return a reference to one output.
  StkFloat tick( StkFloat input );

  //! Take a channel of the StkFrames object as inputs to the filter and replace with corresponding outputs.
  /*!
    The StkFrames argument reference is returned.  The \c channel
    argument must be less than the number of channels in the
    StkFrames argument (the first channel is specified by 0).
    However, range checking is only performed if _STK_DEBUG_ is
    defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& frames, unsigned int channel = 0 );

  //! Take a channel of the \c iFrames object as inputs to the filter and write outputs to the \c oFrames object.
  /*!
    The \c iFrames object reference is returned.  Each channel
    argument must be less than the number of channels in the
    corresponding StkFrames argument (the first channel is specified
    by 0).  However, range checking is only performed if _STK_DEBUG_
    is defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& iFrames, StkFrames &oFrames, unsigned int iChannel = 0, unsigned int oChannel = 0 );

 protected:

  virtual void sampleRateChanged( StkFloat newRate, StkFloat oldRate );
 };

 inline StkFloat BiQuad :: tick( StkFloat input )
 {
  inputs_[0] = gain_ * input;
  lastFrame_[0] = b_[0] * inputs_[0] + b_[1] * inputs_[1] + b_[2] * inputs_[2];
  lastFrame_[0] -= a_[2] * outputs_[2] + a_[1] * outputs_[1];
  inputs_[2] = inputs_[1];
  inputs_[1] = inputs_[0];
  outputs_[2] = outputs_[1];
  outputs_[1] = lastFrame_[0];

  return lastFrame_[0];
 }

 inline StkFrames& BiQuad :: tick( StkFrames& frames, unsigned int channel )
 {
 #if defined(_STK_DEBUG_)
  if ( channel >= frames.channels() ) {
    oStream_ << "BiQuad::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *samples = &frames[channel];
  unsigned int hop = frames.channels();
  for ( unsigned int i=0; i<frames.frames(); i++, samples += hop ) {
    inputs_[0] = gain_ * *samples;
    *samples = b_[0] * inputs_[0] + b_[1] * inputs_[1] + b_[2] * inputs_[2];
    *samples -= a_[2] * outputs_[2] + a_[1] * outputs_[1];
    inputs_[2] = inputs_[1];
    inputs_[1] = inputs_[0];
    outputs_[2] = outputs_[1];
    outputs_[1] = *samples;
  }

  lastFrame_[0] = outputs_[1];
  return frames;
 }

 inline StkFrames& BiQuad :: tick( StkFrames& iFrames, StkFrames& oFrames, unsigned int iChannel, unsigned int oChannel )
 {
 #if defined(_STK_DEBUG_)
  if ( iChannel >= iFrames.channels() || oChannel >= oFrames.channels() ) {
    oStream_ << "BiQuad::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *iSamples = &iFrames[iChannel];
  StkFloat *oSamples = &oFrames[oChannel];
  unsigned int iHop = iFrames.channels(), oHop = oFrames.channels();
  for ( unsigned int i=0; i<iFrames.frames(); i++, iSamples += iHop, oSamples += oHop ) {
    inputs_[0] = gain_ * *iSamples;
    *oSamples = b_[0] * inputs_[0] + b_[1] * inputs_[1] + b_[2] * inputs_[2];
    *oSamples -= a_[2] * outputs_[2] + a_[1] * outputs_[1];
    inputs_[2] = inputs_[1];
    inputs_[1] = inputs_[0];
    outputs_[2] = outputs_[1];
    outputs_[1] = *oSamples;
  }

  lastFrame_[0] = outputs_[1];
  return iFrames;
 }

 } // stk namespace

 #endif

--- a/plugins/community/repos/Autodafe/dep/stk/include/Blit.h
+++ b/plugins/community/repos/Autodafe/dep/stk/include/Blit.h
@@ -0,0 +1,151 @@
 #ifndef STK_BLIT_H
 #define STK_BLIT_H

 #include "Generator.h"
 #include <cmath>
 #include <limits>

 namespace stk {

 /***************************************************/
 /*! \class Blit
    \brief STK band-limited impulse train class.

    This class generates a band-limited impulse train using a
    closed-form algorithm reported by Stilson and Smith in "Alias-Free
    Digital Synthesis of Classic Analog Waveforms", 1996.  The user
    can specify both the fundamental frequency of the impulse train
    and the number of harmonics contained in the resulting signal.

    The signal is normalized so that the peak value is +/-1.0.

    If nHarmonics is 0, then the signal will contain all harmonics up
    to half the sample rate.  Note, however, that this setting may
    produce aliasing in the signal when the frequency is changing (no
    automatic modification of the number of harmonics is performed by
    the setFrequency() function).

    Original code by Robin Davies, 2005.
    Revisions by Gary Scavone for STK, 2005.
 */
 /***************************************************/

 class Blit: public Generator
 {
 public:
  //! Default constructor that initializes BLIT frequency to 220 Hz.
  Blit( StkFloat frequency = 220.0 );

  //! Class destructor.
  ~Blit();

  //! Resets the oscillator state and phase to 0.
  void reset();

  //! Set the phase of the signal.
  /*!
    Set the phase of the signal, in the range 0 to 1.
  */
  void setPhase( StkFloat phase ) { phase_ = PI * phase; };

  //! Get the current phase of the signal.
  /*!
    Get the phase of the signal, in the range [0 to 1.0).
  */
  StkFloat getPhase() const { return phase_ / PI; };

  //! Set the impulse train rate in terms of a frequency in Hz.
  void setFrequency( StkFloat frequency );

  //! Set the number of harmonics generated in the signal.
  /*!
    This function sets the number of harmonics contained in the
    resulting signal.  It is equivalent to (2 * M) + 1 in the BLIT
    algorithm.  The default value of 0 sets the algorithm for maximum
    harmonic content (harmonics up to half the sample rate).  This
    parameter is not checked against the current sample rate and
    fundamental frequency.  Thus, aliasing can result if one or more
    harmonics for a given fundamental frequency exceeds fs / 2.  This
    behavior was chosen over the potentially more problematic solution
    of automatically modifying the M parameter, which can produce
    audible clicks in the signal.
  */
  void setHarmonics( unsigned int nHarmonics = 0 );

  //! Return the last computed output value.
  StkFloat lastOut( void ) const { return lastFrame_[0]; };

  //! Compute and return one output sample.
  StkFloat tick( void );

  //! Fill a channel of the StkFrames object with computed outputs.
  /*!
    The \c channel argument must be less than the number of
    channels in the StkFrames argument (the first channel is specified
    by 0).  However, range checking is only performed if _STK_DEBUG_
    is defined during compilation, in which case an out-of-range value
    will trigger an StkError exception.
  */
  StkFrames& tick( StkFrames& frames, unsigned int channel = 0 );

 protected:

  void updateHarmonics( void );

  unsigned int nHarmonics_;
  unsigned int m_;
  StkFloat rate_;
  StkFloat phase_;
  StkFloat p_;

 };

 inline StkFloat Blit :: tick( void )
 {
  // The code below implements the SincM algorithm of Stilson and
  // Smith with an additional scale factor of P / M applied to
  // normalize the output.

  // A fully optimized version of this code would replace the two sin
  // calls with a pair of fast sin oscillators, for which stable fast
  // two-multiply algorithms are well known. In the spirit of STK,
  // which favors clarity over performance, the optimization has not
  // been made here.

  // Avoid a divide by zero at the sinc peak, which has a limiting
  // value of 1.0.
  StkFloat tmp, denominator = sin( phase_ );
  if ( denominator <= std::numeric_limits<StkFloat>::epsilon() )
    tmp = 1.0;
  else {
    tmp =  sin( m_ * phase_ );
    tmp /= m_ * denominator;
  }

  phase_ += rate_;
  if ( phase_ >= PI ) phase_ -= PI;

  lastFrame_[0] = tmp;
 	return lastFrame_[0];
 }

 inline StkFrames& Blit :: tick( StkFrames& frames, unsigned int channel )
 {
 #if defined(_STK_DEBUG_)
  if ( channel >= frames.channels() ) {
    oStream_ << "Blit::tick(): channel and StkFrames arguments are incompatible!";
    handleError( StkError::FUNCTION_ARGUMENT );
  }
 #endif

  StkFloat *samples = &frames[channel];
  unsigned int hop = frames.channels();
  for ( unsigned int i=0; i<frames.frames(); i++, samples += hop )
    *samples = Blit::tick();

  return frames;
 }

 } // stk namespace

 #endif