def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
oclks = [[5, '16', 0], [7, 'T8', 1], [11, '8', 2]]
clks = oclks[:]
while len(clks):
clk = clks.pop(0)
if len(getattr(nmm.outputs, clk[1]).cables) != 0:
break
if len(clks) == 0:
clk = oclks[0]
g2m.modes.DivMode.value = 1
setv(g2mp.Divider, clk[0])
g2m.name = clk[1]
self.outputs[clk[2]] = g2m.outputs.Out
rst, midiclk = g2m.inputs.Rst, g2m.inputs.Clk
for div, nm, out in clks:
if len(getattr(nmm.outputs, nm).cables) == 0:
continue
clk = self.add_module('ClkDiv', name=nm)
clk.modes.DivMode.value = 1
setv(clk.params.Divider, div)
self.connect(rst, clk.inputs.Rst)
self.connect(midiclk, clk.inputs.Clk)
rst, midiclk = clk.inputs.Rst, clk.inputs.Clk
self.outputs[out] = clk.outputs.Out
def updatevals(g2mp, params, nm1g2_map):
'''updatevals(g2mp, params, nm1g2_map) -> None
change the time values of g2 module based on tables in ./units.py.
'''
for param in params:
midival = getv(getattr(g2mp, param))
setv(getattr(g2mp, param), nm1g2_map[midival])
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
# handle special special parameters
setv(g2mp.Active, 1 - getv(nmmp.Mute))
setv(g2mp.FreqMode, [1, 0][nmm.modes[0].value])
setv(g2mp.Shape, 0)
if getv(g2mp.Waveform) == 3:
pwmod = handlepw(self, 64, 0, -1, 7)
if pwmod:
notequant = self.add_module('NoteQuant', name='BlueRate')
self.connect(notequant.outputs.Out, pwmod)
setv(notequant.params.Range, 127)
setv(notequant.params.Notes, 0)
self.inputs[3] = notequant.inputs.In
# handle special inputs
self.outputs[1], inputmod = handleslv(self)
self.inputmod = inputmod
inp = inputmod.params
self.params[:3] = inp.FreqCoarse, inp.FreqFine, inp.Kbt
p1, p2 = handledualpitchmod(self, inputmod.inputs.PitchVar,
inputmod.params.PitchMod, 4, 5)
self.inputs[1:3] = p1, p2
self.inputs[0] = handlefm(self, g2m.inputs.FmMod, g2mp.FmAmount,
fmamod)
handlekbt(self, self.inputmod.inputs.Pitch, 1) # 0=off, 1=on
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if self.maing2module == 'Mix1-1A':
setv(g2mp.On, 1)
setv(g2mp.ExpLin, 2)
setv(g2mp.Lev, modtable[getv(nmmp.Level)][0])
out2 = self.add_module('2-Out')
lev = g2m.params.Lev
else:
out2 = g2m
lev = None
dest = getv(nmmp.Destination)
setv(out2.params.Destination, dest / 2)
setv(out2.params.Active, 1 - getv(nmmp.Mute))
inp = [out2.inputs.InL, out2.inputs.InR][dest % 2]
if self.maing2module == 'Mix1-1A':
self.connect(g2m.outputs.Out, inp)
else:
self.inputs = [inp]
self.params = [lev, out2.params.Destination, out2.params.Active]
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
g2mp.Sel.labels = ['In', 'SideAct']
setv(g2mp.Sel, getv(nmmp.Act))
self.params[6] = g2mp.Sel
envfollow = self.add_module('EnvFollow')
setv(envfollow.params.Attack, getv(nmmp.Attack))
setv(envfollow.params.Release, getv(nmmp.Release))
self.params[:2] = envfollow.params.Attack, envfollow.params.Release
ratio = self.add_module('ShpExp', name='Ratio/Thresh')
setv(ratio.params.Curve, 2) # x4
setv(ratio.params.Amount, getv(nmmp.Ratio))
self.params[3] = ratio.params.Amount
left = self.add_module('LevMult', name='Left')
right = self.add_module('LevMult', name='Right')
# MISSING Gate, Hold, Mon, and Bypass parameters
self.connect(g2m.inputs.In1, left.inputs.In)
self.connect(g2m.outputs.Out, envfollow.inputs.In)
self.connect(envfollow.outputs.Out, ratio.inputs.In)
self.connect(ratio.outputs.Out, left.inputs.Mod)
self.connect(left.inputs.Mod, right.inputs.Mod)
self.inputs[:] = left.inputs.In, right.inputs.In, g2m.inputs.In2
self.outputs = left.outputs.Out, right.outputs.Out
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
g2mp.Sel.labels = ['In', 'SideAct']
setv(g2mp.Sel, getv(nmmp.Act))
self.params[6] = g2mp.Sel
envfollow = self.add_module('EnvFollow')
setv(envfollow.params.Attack, getv(nmmp.Attack))
setv(envfollow.params.Release, getv(nmmp.Release))
self.params[:2] = envfollow.params.Attack, envfollow.params.Release
ratio = self.add_module('ShpExp', name='Ratio/Thresh')
setv(ratio.params.Curve, 2) # x4
setv(ratio.params.Amount, getv(nmmp.Ratio))
self.params[3] = ratio.params.Amount
left = self.add_module('LevMult', name='Left')
right = self.add_module('LevMult', name='Right')
# MISSING Gate, Hold, Mon, and Bypass parameters
self.connect(g2m.inputs.In1, left.inputs.In)
self.connect(g2m.outputs.Out, envfollow.inputs.In)
self.connect(envfollow.outputs.Out, ratio.inputs.In)
self.connect(ratio.outputs.Out, left.inputs.Mod)
self.connect(left.inputs.Mod, right.inputs.Mod)
self.inputs[:] = left.inputs.In, right.inputs.In, g2m.inputs.In2
self.outputs = left.outputs.Out, right.outputs.Out
def updatevals(g2mp, params, nm1g2_map):
"""updatevals(g2mp, params, nm1g2_map) -> None
change the time values of g2 module based on tables in ./units.py.
"""
for param in params:
midival = getv(getattr(g2mp, param))
setv(getattr(g2mp, param), nm1g2_map[midival])
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if self.maing2module == 'Mix1-1A':
setv(g2mp.On, 1)
setv(g2mp.ExpLin, 2)
setv(g2mp.Lev, modtable[getv(nmmp.Level)][0])
out2 = self.add_module('2-Out')
lev = g2m.params.Lev
else:
out2 = g2m
lev = None
dest = getv(nmmp.Destination)
setv(out2.params.Destination, dest/2)
setv(out2.params.Active, 1-getv(nmmp.Mute))
inp = [out2.inputs.InL, out2.inputs.InR][dest % 2]
if self.maing2module == 'Mix1-1A':
self.connect(g2m.outputs.Out, inp)
else:
self.inputs = [inp]
self.params = [lev, out2.params.Destination, out2.params.Active]
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
oclks = [[5, '16', 0], [7, 'T8', 1], [11, '8', 2]]
clks = oclks[:]
while len(clks):
clk = clks.pop(0)
if len(getattr(nmm.outputs, clk[1]).cables) != 0:
break
if len(clks) == 0:
clk = oclks[0]
g2m.modes.DivMode.value = 1
setv(g2mp.Divider, clk[0])
g2m.name = clk[1]
self.outputs[clk[2]] = g2m.outputs.Out
rst, midiclk = g2m.inputs.Rst, g2m.inputs.Clk
for div, nm, out in clks:
if len(getattr(nmm.outputs, nm).cables) == 0:
continue
clk = self.add_module('ClkDiv', name=nm)
clk.modes.DivMode.value = 1
setv(clk.params.Divider, div)
self.connect(rst, clk.inputs.Rst)
self.connect(midiclk, clk.inputs.Clk)
rst, midiclk = clk.inputs.Rst, clk.inputs.Clk
self.outputs[out] = clk.outputs.Out
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
# handle special special parameters
setv(g2mp.Active, 1-getv(nmmp.Mute))
setv(g2mp.FreqMode, [1, 0][nmm.modes[0].value])
setv(g2mp.Shape, 0)
if getv(g2mp.Waveform) == 3:
pwmod = handlepw(self, 64, 0, -1, 7)
if pwmod:
notequant = self.add_module('NoteQuant', name='BlueRate')
self.connect(notequant.outputs.Out, pwmod)
setv(notequant.params.Range, 127)
setv(notequant.params.Notes, 0)
self.inputs[3] = notequant.inputs.In
# handle special inputs
self.outputs[1], inputmod = handleslv(self)
self.inputmod = inputmod
inp = inputmod.params
self.params[:3] = inp.FreqCoarse, inp.FreqFine, inp.Kbt
p1, p2 = handledualpitchmod(self, inputmod.inputs.PitchVar,
inputmod.params.PitchMod, 4, 5)
self.inputs[1:3] = p1, p2
self.inputs[0] = handlefm(self, g2m.inputs.FmMod, g2mp.FmAmount, fmamod)
handlekbt(self, self.inputmod.inputs.Pitch, 1) # 0=off, 1=on
def handlegate(conv, name='Gate'):
gate = getattr(conv.nmmodule.inputs, name)
# if gate source Keyboard, disconnect and set KB
if not gate or not gate.net or not gate.net.output:
return
if gate.net.output.module.type.shortnm == 'Keyboard':
conv.nmmodule.area.removeconnector(gate)
setv(conv.g2module.params.KB, 1)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.InputType, 0) # Pos
mode = getv(nmmp.Mode)
inv = getv(nmmp.Inv)
setv(g2mp.OutputType, [4, 2, 0, 5, 3, 1][inv * 3 + mode])
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
mode = getv(nmmp.Mode)
setv(g2mp.Mode, [0, 1, 0, 2, 3][mode])
if mode == 2:
setv(g2mp.Active, 0)
def handlegate(conv, name='Gate'):
gate = getattr(conv.nmmodule.inputs, name)
# if gate source Keyboard, disconnect and set KB
if not gate or not gate.net or not gate.net.output:
return
if gate.net.output.module.type.shortnm == 'Keyboard':
conv.nmmodule.area.removeconnector(gate)
setv(conv.g2module.params.KB, 1)
def domodule(self): nmm, g2m = self.nmmodule, self.g2module nmmp, g2mp = nmm.params, g2m.params setv(g2mp.InputType, 0) # Pos mode = getv(nmmp.Mode) inv = getv(nmmp.Inv) setv(g2mp.OutputType, [4, 2, 0, 5, 3, 1][inv*3+mode])
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if getv(nmmp.Color) == 1:
setv(g2mp.StepProb, 43)
else:
setv(g2mp.StepProb, 127)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
mode = getv(nmmp.Mode)
setv(g2mp.Mode, [0, 1, 0, 2, 3][mode])
if mode == 2:
setv(g2mp.Active, 0)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if getv(nmmp.Color) == 1:
setv(g2mp.StepProb, 43)
else:
setv(g2mp.StepProb, 127)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.StepProb, 96)
lfoc = self.add_module('LfoC', name='Clk')
self.connect(lfoc.outputs.Out, g2m.inputs.Clk)
setv(lfoc.params.Rate, getv(nmmp.Density))
self.params[0] = lfoc.params.Rate
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
handlegate(self)
# handle special parameters
updatevals(g2mp, ['Attack', 'Decay', 'Release'], adsrtime_map)
setv(g2mp.OutputType, [0, 3][getv(nmmp.Invert)])
self.inputs[1:3] = handleretrig(self)
def domodule(self): nmm, g2m = self.nmmodule, self.g2module nmmp, g2mp = nmm.params, g2m.params porttime = [ .5*val for val in g2adsrtime] nm1midival = getv(nmmp.Time) g2midival = nm2g2val(nm1midival, nm1adsrtime, porttime) setv(g2mp.Time, g2midival) setv(g2mp.Glide, 0)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.StepProb, 96)
lfoc = self.add_module('LfoC', name='Clk')
self.connect(lfoc.outputs.Out, g2m.inputs.Clk)
setv(lfoc.params.Rate, getv(nmmp.Density))
self.params[0] = lfoc.params.Rate
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
handlegate(self)
# handle special parameters
updatevals(g2mp, ['Attack', 'Decay', 'Release'], adsrtime_map)
setv(g2mp.OutputType, [0, 3][getv(nmmp.Invert)])
self.inputs[1:3] = handleretrig(self)
def handledualpitchmod(conv, modinput, modinputparam, mod1param, mod2param):
global modindex
nmm, g2m = conv.nmmodule, conv.g2module
p1 = p2 = None
mix21b = None
pmod1 = getv(nmm.params.PitchMod1)
pmod2 = getv(nmm.params.PitchMod2)
if len(nmm.inputs.PitchMod1.cables) and len(nmm.inputs.PitchMod2.cables):
setv(modinputparam, 127)
mix21b = conv.add_module('Mix2-1B',
name='PitchMod%d' % modindex.pitchmod)
conv.connect(mix21b.outputs.Out, modinput)
if pmod1 == 0 or pmod1 == 127:
setv(mix21b.params.Lev1, pmod1)
p1 = mix21b.inputs.In1
elif pmod1:
p1 = pitchadj(conv, mix21b.params.Lev1, mix21b.inputs.In1,
modtable[pmod1])
else:
p1 = mix21b.inputs.In1
if pmod2 == 0 or pmod2 == 127:
setv(mix21b.params.Lev2, pmod2)
p2 = mix21b.inputs.In2
elif pmod2:
p2 = pitchadj(conv, mix21b.params.Lev2, mix21b.inputs.In2,
modtable[pmod2])
conv.params[mod1param] = mix21b.params.Lev1
conv.params[mod2param] = mix21b.params.Lev2
elif len(nmm.inputs.PitchMod1.cables):
if pmod1 == 0 or pmod1 == 127:
setv(modinputparam, pmod1)
p1 = modinput
else:
p1 = pitchadj(conv, modinputparam, modinput, modtable[pmod1])
conv.params[mod1param] = modinputparam
elif len(nmm.inputs.PitchMod2.cables):
if pmod2 == 0 or pmod2 == 127:
setv(modinputparam, pmod2)
p2 = modinput
else:
p2 = pitchadj(conv, modinputparam, modinput, modtable[pmod2])
conv.params[mod2param] = modinputparam
return p1, p2
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
handlegate(self, 'Trigger')
# handle special parameters
updatevals(g2mp, ['Attack', 'Release'], adsrtime_map)
if self.options.adsrforad:
printf('%s\n', g2m.type.shortnm)
setv(g2mp.Sustain, 0)
setv(g2mp.Decay, getv(g2mp.Release))
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
shift = getv(nmmp.Shift)
if shift:
conv = self.add_module('LevConv')
self.connect(conv.outputs.Out, g2m.inputs.Mod)
setv(conv.params.OutputType, 0) # Pos
self.params[0] = conv.params.OutputType
self.inputs[0] = conv.inputs.In
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
handlegate(self, 'Trigger')
# handle special parameters
updatevals(g2mp, ['Attack', 'Release'], adsrtime_map)
if self.options.adsrforad:
printf('%s\n', g2m.type.shortnm)
setv(g2mp.Sustain, 0)
setv(g2mp.Decay, getv(g2mp.Release))
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if self.maing2module == 'DelayDual':
setv(g2mp.Time2, 63) # 2.64mS
setv(g2mp.Time1, (getv(nmmp.Time)+1)/2)
setv(g2mp.Time1Mod, (getv(nmmp.Modulation)+1)/2)
else:
setv(g2mp.Time, (getv(nmmp.Time)+1)/2)
setv(g2mp.TimeMod, (getv(nmmp.Modulation)+1)/2)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.FreqMode, [1, 0][nmm.modes[0].value])
# handle special inputs
p1, p2 = handledualpitchmod(self, g2m.inputs.PitchVar,
g2m.params.PitchMod, 3, 4)
self.inputs[:2] = [p1, p2]
self.outputs[0] = handleoscmasterslv(self, g2m, 44, 64, 69, 103, 42)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
shift = getv(nmmp.Shift)
if shift:
conv = self.add_module('LevConv')
self.connect(conv.outputs.Out, g2m.inputs.Mod)
setv(conv.params.OutputType, 0) # Pos
self.params[0] = conv.params.OutputType
self.inputs[0] = conv.inputs.In
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if self.maing2module == 'DelayDual':
setv(g2mp.Time2, 63) # 2.64mS
setv(g2mp.Time1, (getv(nmmp.Time) + 1) / 2)
setv(g2mp.Time1Mod, (getv(nmmp.Modulation) + 1) / 2)
else:
setv(g2mp.Time, (getv(nmmp.Time) + 1) / 2)
setv(g2mp.TimeMod, (getv(nmmp.Modulation) + 1) / 2)
def handledualpitchmod(conv, modinput, modinputparam, mod1param, mod2param):
global modindex
nmm, g2m = conv.nmmodule, conv.g2module
p1 = p2 = None
mix21b = None
pmod1 = getv(nmm.params.PitchMod1)
pmod2 = getv(nmm.params.PitchMod2)
if len(nmm.inputs.PitchMod1.cables) and len(nmm.inputs.PitchMod2.cables):
setv(modinputparam, 127)
mix21b = conv.add_module('Mix2-1B', name='PitchMod%d' % modindex.pitchmod)
conv.connect(mix21b.outputs.Out, modinput)
if pmod1 == 0 or pmod1 == 127:
setv(mix21b.params.Lev1, pmod1)
p1 = mix21b.inputs.In1
elif pmod1:
p1 = pitchadj(conv, mix21b.params.Lev1, mix21b.inputs.In1,
modtable[pmod1])
else:
p1 = mix21b.inputs.In1
if pmod2 == 0 or pmod2 == 127:
setv(mix21b.params.Lev2, pmod2)
p2 = mix21b.inputs.In2
elif pmod2:
p2 = pitchadj(conv, mix21b.params.Lev2, mix21b.inputs.In2,
modtable[pmod2])
conv.params[mod1param] = mix21b.params.Lev1
conv.params[mod2param] = mix21b.params.Lev2
elif len(nmm.inputs.PitchMod1.cables):
if pmod1 == 0 or pmod1 == 127:
setv(modinputparam, pmod1)
p1 = modinput
else:
p1 = pitchadj(conv, modinputparam, modinput, modtable[pmod1])
conv.params[mod1param] = modinputparam
elif len(nmm.inputs.PitchMod2.cables):
if pmod2 == 0 or pmod2 == 127:
setv(modinputparam, pmod2)
p2 = modinput
else:
p2 = pitchadj(conv, modinputparam, modinput, modtable[pmod2])
conv.params[mod2param] = modinputparam
return p1, p2
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.FreqMode, [1, 0][nmm.modes[0].value])
# handle special inputs
p1, p2 = handledualpitchmod(self, g2m.inputs.PitchVar, g2m.params.PitchMod,
3, 4)
self.inputs[:2] = [p1, p2]
self.outputs[0] = handleoscmasterslv(self, g2m, 44, 64, 69, 103, 42)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
for j in xrange(2):
for i in xrange(16):
s = 'Seq%dStep%d' % (j+1, i+1)
step = getattr(g2mp, s)
setv(step, getv(getattr(nmmp, s)))
self.params[4+j*16+i] = step
self.outputs[3] = handlelength(self)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
# handle special parameters
g2m.modes.Waveform.value = self.waveform
if self.waveform != 2:
setv(g2mp.OutputType, 4) # Bip
else:
setv(g2mp.OutputType, 5) # BipInv
postmst(self, 0)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
# handle special parameters
g2m.modes.Waveform.value = self.waveform
if self.waveform != 2:
setv(g2mp.OutputType, 4) # Bip
else:
setv(g2mp.OutputType, 5) # BipInv
postmst(self, 0)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
for j in xrange(2):
for i in xrange(16):
s = 'Seq%dStep%d' % (j + 1, i + 1)
step = getattr(g2mp, s)
setv(step, getv(getattr(nmmp, s)))
self.params[4 + j * 16 + i] = step
self.outputs[3] = handlelength(self)
def domodule(self):
ConvFilter.domodule(self)
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.Active, 1-getv(nmmp.Bypass))
# handle special inputs
p1, p2 = fltdualpitchmod(nmm, g2m, self, 3, 4)
self.inputs[0:2] = p1, p2
self.kbt = g2mp.Kbt
handlekbt(self, g2m.inputs.Pitch, 4) # 4=Kbt 100%
def domodule(self):
ConvFilter.domodule(self)
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.Active, 1 - getv(nmmp.Bypass))
# handle special inputs
p1, p2 = fltdualpitchmod(nmm, g2m, self, 3, 4)
self.inputs[0:2] = p1, p2
self.kbt = g2mp.Kbt
handlekbt(self, g2m.inputs.Pitch, 4) # 4=Kbt 100%
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
for i in xrange(16):
s = 'Seq1Step%d' % (i+1)
step = getattr(g2mp, s)
t = 'Ctrl%d' % (i+1)
setv(step, getv(getattr(nmmp, t)))
self.params[i] = step
self.outputs[2] = handlelength(self)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
for i in xrange(16):
s = 'Seq1Step%d' % (i + 1)
step = getattr(g2mp, s)
t = 'Ctrl%d' % (i + 1)
setv(step, getv(getattr(nmmp, t)))
self.params[i] = step
self.outputs[2] = handlelength(self)
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if self.maing2module == 'Sw4-1':
# add a LevAmp and reorient inputs
for i in xrange(1, 5):
level = getv(getattr(nmmp, 'Level%d' % i))
if level == 0 or level == 127:
continue
if len(nmm.inputs[i - 1].cables):
mix11a = self.add_module('Mix1-1A')
self.connect(mix11a.outputs.Out,
getattr(g2m.inputs, 'In%d' % i))
setv(mix11a.params.On, 1)
setv(mix11a.params.Lev, modtable[level][0])
self.params[i] = mix11a.params.Lev
self.inputs[i - 1] = mix11a.inputs.In
else:
sel = getv(nmmp.Sel)
for i in xrange(1, 5):
level = getv(getattr(nmmp, 'Level%d' % i))
lev = getattr(g2mp, 'Lev%d' % i)
setv(lev, modtable[level][0])
setv(getattr(g2mp, 'On%d' % i), sel == i - 1)
self.params[i] = lev
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
shpexp = self.add_module('ShpExp')
setv(shpexp.params.Curve, 2) # x4
setv(shpexp.params.Amount, 127)
constswt = self.add_module('ConstSwT')
setv(constswt.params.On, 1)
setv(constswt.params.Lev, getv(nmmp.Gain))
setv(constswt.params.BipUni, getv(nmmp.Unipolar))
self.connect(shpexp.outputs.Out, g2m.inputs.Mod)
self.connect(constswt.outputs.Out, shpexp.inputs.In)
self.params = constswt.params.Lev, constswt.params.BipUni
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
if self.maing2module == 'Sw4-1':
# add a LevAmp and reorient inputs
for i in xrange(1, 5):
level = getv(getattr(nmmp, 'Level%d' % i))
if level == 0 or level == 127:
continue
if len(nmm.inputs[i-1].cables):
mix11a = self.add_module('Mix1-1A')
self.connect(mix11a.outputs.Out, getattr(g2m.inputs, 'In%d' % i))
setv(mix11a.params.On, 1)
setv(mix11a.params.Lev, modtable[level][0])
self.params[i] = mix11a.params.Lev
self.inputs[i-1] = mix11a.inputs.In
else:
sel = getv(nmmp.Sel)
for i in xrange(1, 5):
level = getv(getattr(nmmp, 'Level%d' % i))
lev = getattr(g2mp, 'Lev%d' % i)
setv(lev, modtable[level][0])
setv(getattr(g2mp, 'On%d' % i), sel == i-1)
self.params[i] = lev
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
shpexp = self.add_module('ShpExp')
setv(shpexp.params.Curve, 2) # x4
setv(shpexp.params.Amount, 127)
constswt = self.add_module('ConstSwT')
setv(constswt.params.On, 1)
setv(constswt.params.Lev, getv(nmmp.Gain))
setv(constswt.params.BipUni, getv(nmmp.Unipolar))
self.connect(shpexp.outputs.Out, g2m.inputs.Mod)
self.connect(constswt.outputs.Out, shpexp.inputs.In)
self.params = constswt.params.Lev, constswt.params.BipUni
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.Pad, [2, 1][getv(getattr(nmmp, '+6Db'))])
lboost = self.add_module('LevAmp', name='L-Boost')
setv(lboost.params.Type, 0) # Lin
setv(lboost.params.Gain, 96) # x2.00
self.connect(g2m.outputs.OutL, lboost.inputs.In)
self.outputs[0] = lboost.outputs.Out
rboost = self.add_module('LevAmp', name='R-Boost')
setv(rboost.params.Type, 0) # Lin
setv(rboost.params.Gain, 96) # x2.00
self.connect(g2m.outputs.OutR, rboost.inputs.In)
self.outputs[1] = rboost.outputs.Out
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.Pad, [2, 1][getv(getattr(nmmp, '+6Db'))])
lboost = self.add_module('LevAmp', name='L-Boost')
setv(lboost.params.Type, 0) # Lin
setv(lboost.params.Gain, 96) # x2.00
self.connect(g2m.outputs.OutL, lboost.inputs.In)
self.outputs[0] = lboost.outputs.Out
rboost = self.add_module('LevAmp', name='R-Boost')
setv(rboost.params.Type, 0) # Lin
setv(rboost.params.Gain, 96) # x2.00
self.connect(g2m.outputs.OutR, rboost.inputs.In)
self.outputs[1] = rboost.outputs.Out
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
g2m.name = 'KbdSplit'
# now lets create the structure
struct = [
['Constant', 'Upper'],
['CompLev', 'Lower'],
['CompSig', '<=Upper'],
['Gate', 'Gate'],
]
for mod, nm in struct:
self.add_module(mod, name=nm)
u, l, lu, g = self.g2modules
setv(u.params.Level, getv(nmmp.Upper))
setv(l.params.C, getv(nmmp.Lower))
self.connect(u.outputs.Out, lu.inputs.A)
self.connect(l.inputs.In, lu.inputs.B)
self.connect(l.outputs.Out, g.inputs.In1_1)
self.connect(lu.outputs.Out, g.inputs.In1_2)
self.connect(g.outputs.Out1, g.inputs.In2_2)
gout = g.outputs.Out2
nout = None
if len(nmm.outputs.Note.cables):
n = self.add_module('DlyClock', name='Note')
self.connect(gout, n.inputs.Clk)
self.connect(lu.inputs.B, n.inputs.In)
gout = n.inputs.Clk
nout = n.outputs.Out
vin = vout = None
if len(nmm.outputs.Vel.cables) or len(nmm.inputs.Vel.cables):
v = self.add_module('DlyClock', name='Vel')
self.connect(gout, v.inputs.Clk)
vin = v.inputs.In
vout = v.outputs.Out
self.params = [l.params.C, u.params.Level]
self.outputs = [nout, g.outputs.Out2, vout]
self.inputs = [l.inputs.In, g.inputs.In2_1, vin]
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
# note going to handle this as there is no Active.
#setv(g2mp.Active, 1-getv(nmmp.Mute))
level = getv(nmmp.Level)
if level != 0 or level != 127 or \
nmmp.Level.knob or nmmp.Level.morph or nmmp.Level.ctrl:
# add LevAmp module
mix11a = self.add_module('Mix1-1A')
self.connect(mix11a.outputs.Out, g2m.inputs.In)
setv(mix11a.params.On, 1)
setv(mix11a.params.Lev, modtable[level][0])
self.params[1] = mix11a.params.Lev
self.inputs[0] = mix11a.inputs.In
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
# note going to handle this as there is no Active.
#setv(g2mp.Active, 1-getv(nmmp.Mute))
level = getv(nmmp.Level)
if level != 0 or level != 127 or \
nmmp.Level.knob or nmmp.Level.morph or nmmp.Level.ctrl:
# add LevAmp module
mix11a = self.add_module('Mix1-1A')
self.connect(mix11a.outputs.Out, g2m.inputs.In)
setv(mix11a.params.On, 1)
setv(mix11a.params.Lev, modtable[level][0])
self.params[1] = mix11a.params.Lev
self.inputs[0] = mix11a.inputs.In
def __init__(self, nmarea, g2area, nmmodule, options):
'''Convert(nmarea, g2area, nmmodule, options) -> Convert
create a convert object from a nm1 module in nmarea to g2area.
'''
self.nmarea = nmarea
self.g2area = g2area
nmm = self.nmmodule = nmmodule
nmm.conv = self # to get back here when needed (cables)
self.options = options
# use for cabling
for output in nmmodule.outputs:
output.conv = self
for input in nmmodule.inputs:
input.conv = self
self.g2modules = []
self.params = []
self.outputs = []
self.inputs = []
# create main module and setup size requirements
g2m = self.g2module = g2area.add_module(self.maing2module)
g2m.name = toascii(nmm.name)
self.horiz = g2m.horiz = nmm.horiz
self.height = g2m.type.height
# setup parameters from parammap static member of convert module class
self.params = [None] * len(self.parammap)
for i, param in enumerate(self.parammap):
if type(param) == type(''):
setv(getattr(g2m.params, param),
getv(getattr(nmm.params, param)))
self.params[i] = getattr(g2m.params, param)
elif type(param) == type([]):
setv(getattr(g2m.params, param[0]),
getv(getattr(nmm.params, param[1])))
self.params[i] = getattr(g2m.params, param[0])
else:
self.params[
i] = param # None: placeholder for other parameters
# setup inputs from inputmap static member of convert module class
self.inputs = [getattr(g2m.inputs, i, None) for i in self.inputmap]
# setup outputs from outputmap static member of convert module class
self.outputs = [getattr(g2m.outputs, o, None) for o in self.outputmap]
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
g2m.name = 'KbdSplit'
# now lets create the structure
struct = [ ['Constant', 'Upper'],
['CompLev', 'Lower'],
['CompSig', '<=Upper'],
['Gate', 'Gate'], ]
for mod, nm in struct:
self.add_module(mod, name=nm)
u, l, lu, g = self.g2modules
setv(u.params.Level, getv(nmmp.Upper))
setv(l.params.C, getv(nmmp.Lower))
self.connect(u.outputs.Out, lu.inputs.A)
self.connect(l.inputs.In, lu.inputs.B)
self.connect(l.outputs.Out, g.inputs.In1_1)
self.connect(lu.outputs.Out, g.inputs.In1_2)
self.connect(g.outputs.Out1, g.inputs.In2_2)
gout = g.outputs.Out2
nout = None
if len(nmm.outputs.Note.cables):
n = self.add_module('DlyClock', name='Note')
self.connect(gout, n.inputs.Clk)
self.connect(lu.inputs.B, n.inputs.In)
gout = n.inputs.Clk
nout = n.outputs.Out
vin = vout = None
if len(nmm.outputs.Vel.cables) or len(nmm.inputs.Vel.cables):
v = self.add_module('DlyClock', name='Vel')
self.connect(gout, v.inputs.Clk)
vin = v.inputs.In
vout = v.outputs.Out
self.params = [l.params.C, u.params.Level]
self.outputs = [nout, g.outputs.Out2, vout]
self.inputs = [l.inputs.In, g.inputs.In2_1, vin]
def __init__(self, nmarea, g2area, nmmodule, options):
"""Convert(nmarea, g2area, nmmodule, options) -> Convert
create a convert object from a nm1 module in nmarea to g2area.
"""
self.nmarea = nmarea
self.g2area = g2area
nmm = self.nmmodule = nmmodule
nmm.conv = self # to get back here when needed (cables)
self.options = options
# use for cabling
for output in nmmodule.outputs:
output.conv = self
for input in nmmodule.inputs:
input.conv = self
self.g2modules = []
self.params = []
self.outputs = []
self.inputs = []
# create main module and setup size requirements
g2m = self.g2module = g2area.add_module(self.maing2module)
g2m.name = toascii(nmm.name)
self.horiz = g2m.horiz = nmm.horiz
self.height = g2m.type.height
# setup parameters from parammap static member of convert module class
self.params = [None] * len(self.parammap)
for i, param in enumerate(self.parammap):
if type(param) == type(""):
setv(getattr(g2m.params, param), getv(getattr(nmm.params, param)))
self.params[i] = getattr(g2m.params, param)
elif type(param) == type([]):
setv(getattr(g2m.params, param[0]), getv(getattr(nmm.params, param[1])))
self.params[i] = getattr(g2m.params, param[0])
else:
self.params[i] = param # None: placeholder for other parameters
# setup inputs from inputmap static member of convert module class
self.inputs = [getattr(g2m.inputs, i, None) for i in self.inputmap]
# setup outputs from outputmap static member of convert module class
self.outputs = [getattr(g2m.outputs, o, None) for o in self.outputmap]
def pitchadj(conv, pitchparam, pitchinput, tableentry):
global modindex
setv(pitchparam, tableentry[0])
if tableentry[1] == 0 and tableentry[2] == 0:
return pitchinput
adj1 = conv.add_module('Mix2-1B', name='PitchAdj%d' % modindex.pitchadj)
conv.connect(adj1.inputs.Chain, adj1.inputs.In1)
conv.connect(adj1.inputs.In1, adj1.inputs.In2)
conv.connect(adj1.outputs.Out, pitchinput)
setv(adj1.params.Inv2, 1)
setv(adj1.params.Lev1, tableentry[1])
setv(adj1.params.Lev2, tableentry[2])
return adj1.inputs.Chain
def pitchadj(conv, pitchparam, pitchinput, tableentry):
global modindex
setv(pitchparam, tableentry[0])
if tableentry[1] == 0 and tableentry[2] == 0:
return pitchinput
adj1 = conv.add_module('Mix2-1B', name='PitchAdj%d' % modindex.pitchadj)
conv.connect(adj1.inputs.Chain, adj1.inputs.In1)
conv.connect(adj1.inputs.In1, adj1.inputs.In2)
conv.connect(adj1.outputs.Out, pitchinput)
setv(adj1.params.Inv2, 1)
setv(adj1.params.Lev1, tableentry[1])
setv(adj1.params.Lev2, tableentry[2])
return adj1.inputs.Chain
def convert(self):
# loop through each module
# determine and store separation from module above >= 0
# if mod in convertion table
# call convertion table module function
# loop through each cable
# if source and dest in convertion table
# create new connection
# update midi controller assignments
# update knob assignments (on pags A1:1, A1:2 and A1:3)
# update morph assignments
# reorder modules top to bottom, left to right
# relocate modules top to bottom, left to right based on separation
# add name bar with my name and convertion info
# add name bar with errors/comments etc.
# save g2 file
# other ideas:
# create patch equal function
# create patch merge function that updates variations
# of one patch from another.
g2patch, nmpatch = self.g2patch, self.nmpatch
setv(g2patch.settings.patchvol, 127)
for color in ['red', 'blue', 'yellow', 'green', 'purple']:
setattr(g2patch.description, color, getattr(nmpatch.header, color))
if nmpatch.header.voices > 1:
g2patch.description.monopoly = 0
g2patch.description.voices = nmpatch.header.voices - 1
setv(g2patch.settings.glide, nmpatch.header.porta)
setv(g2patch.settings.glidetime, nmpatch.header.portatime)
setv(g2patch.settings.octaveshift, nmpatch.header.octshift)
self.log.info('--- area voice: ---')
self.voiceconverters = self.doarea(nmpatch.voice, g2patch.voice)
self.log.info('--- area fx: ---')
self.fxconverters = self.doarea(nmpatch.fx, g2patch.fx)
self.domorphs()
self.doknobs()
self.domidiccs()
self.docurrentnotes()
self.dofinalize()
# handle text pad
self.pch2.patch.textpad = self.pch.patch.textpad
self.dotitleblock()
self.log.info('Writing patch "%s2"' % (self.pch.filename))
self.pch2.write(self.pch.filename+'2')
def convert(self):
# loop through each module
# determine and store separation from module above >= 0
# if mod in convertion table
# call convertion table module function
# loop through each cable
# if source and dest in convertion table
# create new connection
# update midi controller assignments
# update knob assignments (on pags A1:1, A1:2 and A1:3)
# update morph assignments
# reorder modules top to bottom, left to right
# relocate modules top to bottom, left to right based on separation
# add name bar with my name and convertion info
# add name bar with errors/comments etc.
# save g2 file
# other ideas:
# create patch equal function
# create patch merge function that updates variations
# of one patch from another.
g2patch, nmpatch = self.g2patch, self.nmpatch
setv(g2patch.settings.patchvol, 127)
for color in ['red', 'blue', 'yellow', 'green', 'purple']:
setattr(g2patch.description, color, getattr(nmpatch.header, color))
if nmpatch.header.voices > 1:
g2patch.description.monopoly = 0
g2patch.description.voices = nmpatch.header.voices - 1
setv(g2patch.settings.glide, nmpatch.header.porta)
setv(g2patch.settings.glidetime, nmpatch.header.portatime)
setv(g2patch.settings.octaveshift, nmpatch.header.octshift)
self.log.info('--- area voice: ---')
self.voiceconverters = self.doarea(nmpatch.voice, g2patch.voice)
self.log.info('--- area fx: ---')
self.fxconverters = self.doarea(nmpatch.fx, g2patch.fx)
self.domorphs()
self.doknobs()
self.domidiccs()
self.docurrentnotes()
self.dofinalize()
# handle text pad
self.pch2.patch.textpad = self.pch.patch.textpad
self.dotitleblock()
self.log.info('Writing patch "%s2"' % (self.pch.filename))
self.pch2.write(self.pch.filename + '2')
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.Active, getv(getattr(nmmp, 'On/Off')))
setv(g2mp.Source, 0) # Internal
if len(nmm.outputs.Sync.cables) != 0:
pulse = self.add_module('Pulse')
setv(pulse.params.Time, 32)
self.connect(g2m.outputs.ClkActive, pulse.inputs.In)
self.outputs[3] = pulse.outputs.Out
#handle Slv connections
if len(nmm.outputs.Slv.cables):
zerocnt = self.add_module('ZeroCnt', name='96th In')
oscmaster = self.add_module('OscMaster', name='26-241 BPM')
setv(oscmaster.params.FreqCoarse, 9) # -55 semi
setv(oscmaster.params.Kbt, 0) # off
self.connect(getattr(g2m.outputs, '1/96'), zerocnt.inputs.In)
self.connect(zerocnt.outputs.Out, oscmaster.inputs.Pitch)
self.outputs[2] = oscmaster.outputs.Out
def domodule(self):
nmm, g2m = self.nmmodule, self.g2module
nmmp, g2mp = nmm.params, g2m.params
setv(g2mp.Active, getv(getattr(nmmp, 'On/Off')))
setv(g2mp.Source, 0) # Internal
if len(nmm.outputs.Sync.cables) != 0:
pulse = self.add_module('Pulse')
setv(pulse.params.Time, 32)
self.connect(g2m.outputs.ClkActive, pulse.inputs.In)
self.outputs[3] = pulse.outputs.Out
#handle Slv connections
if len(nmm.outputs.Slv.cables):
zerocnt = self.add_module('ZeroCnt', name='96th In')
oscmaster = self.add_module('OscMaster', name='26-241 BPM')
setv(oscmaster.params.FreqCoarse, 9) # -55 semi
setv(oscmaster.params.Kbt, 0) # off
self.connect(getattr(g2m.outputs, '1/96'), zerocnt.inputs.In)
self.connect(zerocnt.outputs.Out, oscmaster.inputs.Pitch)
self.outputs[2] = oscmaster.outputs.Out
