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|
/* sc4pd
CombN~
Copyright (c) 2004 Tim Blechmann.
This code is derived from:
SuperCollider real time audio synthesis system
Copyright (c) 2002 James McCartney. All rights reserved.
http://www.audiosynth.com
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
Based on:
PureData by Miller Puckette and others.
http://www.crca.ucsd.edu/~msp/software.html
FLEXT by Thomas Grill
http://www.parasitaere-kapazitaeten.net/ext
SuperCollider by James McCartney
http://www.audiosynth.com
Coded while listening to: Keith Rowe & John Tilbury: Duos For Doris
*/
#include "sc4pd.hpp"
#include "DelayUnit.hpp"
class CombN_ar : public FeedbackDelay_ar
{
FLEXT_HEADER(CombN_ar,FeedbackDelay_ar);
CombN_ar (int argc, t_atom *argv);
~CombN_ar ();
protected:
virtual void m_signal(int n, t_sample *const *in, t_sample *const *out)
{
m_signal_fun(n,in,out);
}
virtual void m_dsp(int n, t_sample *const *in, t_sample *const *out)
{
delay_changed = decay_changed = false;
FeedbackDelay_Reset();
}
void m_delay(float f)
{
m_delaytime=f;
delay_changed = true;
}
void m_decay(float f)
{
m_decaytime=f;
decay_changed = true;
}
private:
bool delay_changed, decay_changed;
DEFSIGCALL(m_signal_fun);
DEFSIGFUN(m_signal_);
DEFSIGFUN(m_signal_z);
FLEXT_CALLBACK_F(m_delay);
FLEXT_CALLBACK_F(m_decay);
};
FLEXT_LIB_DSP_V("CombN~",CombN_ar);
CombN_ar::CombN_ar (int argc, t_atom *argv)
{
FLEXT_ADDMETHOD_(0,"delaytime",m_delay);
FLEXT_ADDMETHOD_(0,"decaytime",m_decay);
//parse arguments
AtomList Args(argc,argv);
if (Args.Count() != 3)
{
post("3 arguments are needed");
return;
}
m_maxdelaytime = sc_getfloatarg(Args,0);
m_delaytime = sc_getfloatarg(Args,1);
m_decaytime = sc_getfloatarg(Args,2);
SETSIGFUN(m_signal_fun,SIGFUN(m_signal_z));
AddOutSignal();
}
CombN_ar::~CombN_ar ()
{
DelayUnit_Dtor();
}
void CombN_ar::m_signal_z(int n, t_sample *const *in, t_sample *const *out)
{
t_sample *nin = *in;
t_sample *nout = *out;
float *dlybuf = m_dlybuf;
long iwrphase = m_iwrphase;
float dsamp = m_dsamp;
float feedbk = m_feedbk;
long mask = m_mask;
if (delay_changed)
{
float next_dsamp = CalcDelay(m_delaytime);
float dsamp_slope = CALCSLOPE(next_dsamp, dsamp);
float next_feedbk = CalcFeedback(m_delaytime, m_decaytime);
float feedbk_slope = CALCSLOPE(next_feedbk, feedbk);
for (int i = 0; i!= n;++i)
{
dsamp += dsamp_slope;
long irdphase = iwrphase - (long)dsamp;
if (irdphase < 0)
{
dlybuf[iwrphase & mask] = ZXP(nin);
ZXP(nout) = 0.f;
}
else
{
float value = dlybuf[irdphase & mask];
dlybuf[iwrphase & mask] = ZXP(nin) + feedbk * value;
ZXP(nout) = value;
}
feedbk += feedbk_slope;
iwrphase++;
}
m_feedbk = feedbk;
m_dsamp = dsamp;
delay_changed = decay_changed = false;
}
else
{
long irdphase = iwrphase - (long)dsamp;
float* dlybuf1 = dlybuf - ZOFF;
float* dlyN = dlybuf1 + m_idelaylen;
if (decay_changed)
{
float next_feedbk = CalcFeedback(m_delaytime, m_decaytime);
float feedbk_slope = CALCSLOPE(next_feedbk, feedbk);
long remain = n;
while (remain)
{
float* dlyrd = dlybuf1 + (irdphase & mask);
float* dlywr = dlybuf1 + (iwrphase & mask);
long rdspace = dlyN - dlyrd;
long wrspace = dlyN - dlywr;
long nsmps = sc_min(rdspace, wrspace);
nsmps = sc_min(remain, nsmps);
remain -= nsmps;
if (irdphase < 0)
{
feedbk += nsmps * feedbk_slope;
dlyrd += nsmps;
for (int i = 0; i!= nsmps;++i)
{
ZXP(dlywr) = ZXP(nin);
ZXP(nout) = 0.f;
}
}
else
{
for (int i = 0; i!= nsmps;++i)
{
float value = ZXP(dlyrd);
ZXP(dlywr) = value * feedbk + ZXP(nin);
ZXP(nout) = value;
feedbk += feedbk_slope;
}
}
iwrphase += nsmps;
irdphase += nsmps;
}
m_feedbk = feedbk;
decay_changed=false;
}
else
{
long remain = n;
while (remain)
{
float* dlywr = dlybuf1 + (iwrphase & mask);
float* dlyrd = dlybuf1 + (irdphase & mask);
long rdspace = dlyN - dlyrd;
long wrspace = dlyN - dlywr;
long nsmps = sc_min(rdspace, wrspace);
nsmps = sc_min(remain, nsmps);
remain -= nsmps;
if (irdphase < 0)
{
for (int i = 0; i!= nsmps;++i)
{
ZXP(dlywr) = ZXP(nin);
ZXP(nout) = 0.f;
}
}
else
{
for (int i = 0; i!= nsmps;++i)
{
float value = ZXP(dlyrd);
ZXP(dlywr) = value * feedbk + ZXP(nin);
ZXP(nout) = value;
}
}
iwrphase += nsmps;
irdphase += nsmps;
}
}
}
m_iwrphase = iwrphase;
m_numoutput += n;
if (m_numoutput >= m_idelaylen)
{
SETSIGFUN(m_signal_fun,SIGFUN(m_signal_));
}
}
void CombN_ar::m_signal_(int n, t_sample *const *in, t_sample *const *out)
{
t_sample *nin = *in;
t_sample *nout = *out;
float *dlybuf = m_dlybuf;
long iwrphase = m_iwrphase;
float dsamp = m_dsamp;
float feedbk = m_feedbk;
long mask = m_mask;
if(delay_changed)
{
float next_dsamp = CalcDelay(m_delaytime);
float dsamp_slope = CALCSLOPE(next_dsamp, dsamp);
float next_feedbk = CalcFeedback(m_delaytime, m_decaytime);
float feedbk_slope = CALCSLOPE(next_feedbk, feedbk);
for(int i=0; i!= n;++i)
{
dsamp += dsamp_slope;
++iwrphase;
long irdphase = iwrphase - (long)dsamp;
float value = dlybuf[irdphase & mask];
dlybuf[iwrphase & mask] = ZXP(nin) + feedbk * value;
ZXP(nout) = value;
feedbk += feedbk_slope;
}
m_feedbk = feedbk;
m_dsamp = dsamp;
delay_changed = decay_changed = false;
}
else
{
long irdphase = iwrphase - (long)dsamp;
float* dlybuf1 = dlybuf - ZOFF;
float* dlyrd = dlybuf1 + (irdphase & mask);
float* dlywr = dlybuf1 + (iwrphase & mask);
float* dlyN = dlybuf1 + m_idelaylen;
if(decay_changed)
{
float next_feedbk = CalcFeedback(m_delaytime, m_decaytime);
float feedbk_slope = CALCSLOPE(next_feedbk, feedbk);
long remain = n;
while (remain)
{
long rdspace = dlyN - dlyrd;
long wrspace = dlyN - dlywr;
long nsmps = sc_min(rdspace, wrspace);
nsmps = sc_min(remain, nsmps);
remain -= nsmps;
for(int i=0; i!= nsmps;++i)
{
float value = ZXP(dlyrd);
ZXP(dlywr) = value * feedbk + ZXP(nin);
ZXP(nout) = value;
feedbk += feedbk_slope;
}
if (dlyrd == dlyN) dlyrd = dlybuf1;
if (dlywr == dlyN) dlywr = dlybuf1;
}
m_feedbk = feedbk;
decay_changed = false;
}
else
{
long remain = n;
while (remain)
{
long rdspace = dlyN - dlyrd;
long wrspace = dlyN - dlywr;
long nsmps = sc_min(rdspace, wrspace);
nsmps = sc_min(remain, nsmps);
remain -= nsmps;
for (int i = 0; i!= nsmps; ++i)
{
float value = ZXP(dlyrd);
ZXP(dlywr) = value * feedbk + ZXP(nin);
ZXP(nout) = value;
}
if (dlyrd == dlyN) dlyrd = dlybuf1;
if (dlywr == dlyN) dlywr = dlybuf1;
}
}
iwrphase += n;
}
m_iwrphase = iwrphase;
}
/* todo: CombN for control rate ? */
|
