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// 
//  
//  chaos~
//  Copyright (C) 2004  Tim Blechmann
//  
//  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; see the file COPYING.  If not, write to
//  the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
//  Boston, MA 02111-1307, USA.

#include "chaos_base.hpp"

template <class system> class chaos_dsp
	: public flext_dsp
{
	FLEXT_HEADER(chaos_dsp, flext_dsp);

public:

	/* signal functions: */
	/* for frequency = sr/2 */
	void m_signal_(int n, t_sample *const *insigs,t_sample *const *outsigs);
	/* sample & hold */
	void m_signal_n(int n, t_sample *const *insigs,t_sample *const *outsigs);
	/* linear interpolation */
	void m_signal_l(int n, t_sample *const *insigs,t_sample *const *outsigs);
	/* cubic interpolatio */
	void m_signal_c(int n, t_sample *const *insigs,t_sample *const *outsigs);
	
	virtual void m_signal(int n, t_sample *const *insigs,t_sample *const *outsigs)
	{
 		(this->*m_routine)(n,insigs,outsigs);
	}

	virtual void m_dsp(int n, t_sample *const *insigs,t_sample *const *outsigs)
	{
		m_sr = Samplerate();
	}

	void (thisType::*m_routine)(int n, t_sample *const *insigs,t_sample *const *outsigs);
	
	/* local data for system, output and interpolation */
	system * m_system; /* the system */

	t_sample * m_values;   /* actual value */
	t_sample * m_slopes;   /* actual slope for cubic interpolation */

    t_sample * m_nextvalues;
    t_sample * m_nextmidpts;
    t_sample * m_curves;
	
	/* local data for signal functions */
	float m_freq;        /* frequency of oscillations */
	float m_invfreq;     /* inverse frequency */
	int m_phase;         /* phase counter */
	float m_sr;          /* sample rate */
	
	int m_imethod;       /* interpolation method */

	void get_imethod(int &i)
	{
		i = m_imethod;
	}

	void set_imethod(int i)
	{
		if( (i >= 0) && (i <= 2) )
		{
			m_imethod = i;
			switch (i)
			{
			case 0:
				m_routine = &thisType::m_signal_n;
				break;
			case 1:
				m_routine = &thisType::m_signal_l;
				break;
			case 2:
				m_routine = &thisType::m_signal_c;
				break;
			}
		}
		else
		{
			post("interpolation method out of range");
			return;
		}
		if( i != 2)
		{
			for (int j = 0; j != m_system->get_num_eq(); ++j)
			{
				m_nextvalues[i] = 0;
				m_nextmidpts[i] = 0;
				m_curves[i] = 0;
			}
		}

	}

	void get_freq(float &f)
	{
		f = m_freq;
	}

	void set_freq(float f)
	{
		if( (f >= 0) && (f <= m_sr*0.5) )
		{
			m_freq = f;
			m_invfreq = 1.f / f;
		}
		else
			post("frequency out of range");
	}
	
	FLEXT_CALLVAR_F(get_freq, set_freq);
	FLEXT_CALLVAR_I(get_imethod, set_imethod);
};


/* create constructor / destructor */
#define CHAOS_DSP_INIT(SYSTEM, ATTRIBUTES)									\
FLEXT_HEADER(SYSTEM##_dsp, chaos_dsp<SYSTEM>)								\
																			\
SYSTEM##_dsp(int argc, t_atom* argv )										\
{																			\
    m_sr = 44100; /* assume default sampling rate */                    	\
	m_system = new SYSTEM;													\
																			\
	int size = m_system->get_num_eq();										\
																			\
	m_values = new t_float[size];											\
	m_slopes = new t_float[size];											\
	m_nextvalues = new t_float[size];										\
	m_nextmidpts = new t_float[size];										\
	m_curves = new t_float[size];											\
																			\
    /* create inlets and zero arrays*/										\
    for (int i = 0; i != size; ++i)											\
	{																		\
		AddOutSignal();														\
		m_values[i] = 0;													\
		m_slopes[i] = 0;													\
		m_nextvalues[i] = 0;												\
		m_nextmidpts[i] = 0;												\
		m_curves[i] = 0;													\
	}																		\
																			\
    FLEXT_ADDATTR_VAR("frequency", get_freq, set_freq);						\
    FLEXT_ADDATTR_VAR("interpolation_method",get_imethod, set_imethod);		\
																			\
    if (argc > 0)															\
	{																		\
		CHAOS_SYS_INIT(freq, GetAInt(argv[0]));								\
	}																		\
    else																	\
	{																		\
		CHAOS_SYS_INIT(freq, 440);											\
	}																		\
																			\
	if (argc > 1)															\
	{																		\
		CHAOS_SYS_INIT(imethod, GetAInt(argv[1]));							\
	}																		\
    else																	\
    {																		\
		CHAOS_SYS_INIT(imethod, 0);											\
    }																		\
																			\
    m_phase = 0;															\
																			\
    ATTRIBUTES;																\
}																			\
																			\
~SYSTEM##_dsp()																\
{																			\
	delete m_system;														\
	delete m_values;														\
	delete m_slopes;														\
	delete m_nextvalues;													\
	delete m_nextmidpts;													\
	delete m_curves;														\
}																			\
																			\
FLEXT_ATTRVAR_F(m_freq);													\
FLEXT_ATTRVAR_I(m_imethod);



template <class system> 
void chaos_dsp<system>::m_signal_(int n, t_sample *const *insigs,
								 t_sample *const *outsigs)
{
	int outlets = m_system->get_num_eq();

	for (int i = 0; i!=n; ++i)
	{
		m_system->m_perform();
		for (int j = 0; j != outlets; ++j)
		{
			outsigs[j][i] = m_system->get_data(j);
		}
	}
	
}

template <class system> 
void chaos_dsp<system>::m_signal_n(int n, t_sample *const *insigs,
								   t_sample *const *outsigs)
{
	int outlets = m_system->get_num_eq();
	
	int phase = m_phase;

	int i = 0;

	while (n)
	{
		if (phase == 0)
		{
 			m_system->m_perform();
			phase = int (m_sr * m_invfreq);
		}
		
		int next = (phase < n) ? phase : n;
		n -= next;
		phase -=next;
		
		while (next--)
		{
			for (int j = 0; j != outlets; ++j)
			{
				outsigs[j][i] = m_system->get_data(j);
			}
			++i;
		}
	}
	m_phase = phase;
}


/* linear and cubic interpolation adapted from supercollider by James McCartney */
template <class system> 
void chaos_dsp<system>::m_signal_l(int n, t_sample *const *insigs,
								   t_sample *const *outsigs)
{
	int outlets = m_system->get_num_eq();
	
	int phase = m_phase;

	int i = 0;

	while (n)
	{
		if (phase == 0)
		{
			m_system->m_perform();
			phase = int (m_sr * m_invfreq);

			for (int j = 0; j != outlets; ++j)
				m_slopes[j] = (m_system->get_data(j) - m_values[j]) / phase;
		}
		
		int next = (phase < n) ? phase : n;
		n -= next;
		phase -=next;
		
		while (next--)
		{
			for (int j = 0; j != outlets; ++j)
			{
				outsigs[j][i] = m_values[j];
				m_values[j]+=m_slopes[j];
			}
			++i;
		}
	}
	m_phase = phase;
}


template <class system> 
void chaos_dsp<system>::m_signal_c(int n, t_sample *const *insigs,
								   t_sample *const *outsigs)
{
	int outlets = m_system->get_num_eq();
	
	int phase = m_phase;

	int i = 0;

	while (n)
	{
		if (phase == 0)
		{
			m_system->m_perform();
			phase = int (m_sr * m_invfreq);
			phase = (phase > 2) ? phase : 2;
			
			for (int j = 0; j != outlets; ++j)
			{
				t_sample value = m_nextvalues[j];
				m_nextvalues[j]= m_system->get_data(j);
				
				m_values[j] =  m_nextmidpts[j];
				m_nextmidpts[j] = (m_nextvalues[j] + value) * 0.5f;
				
				float fseglen = (float)phase;
				m_curves[j] = 2.f * (m_nextmidpts[j] - m_values[j] - 
									 fseglen * m_slopes[j]) 
					/ (fseglen * fseglen + fseglen);
			}
		}
		
		int next = (phase < n) ? phase : n;
		n -= next;
		phase -=next;
		
		while (next--)
		{
			for (int j = 0; j != outlets; ++j)
			{
				outsigs[j][i] = m_values[j];
				m_slopes[j]+=m_curves[j];
				m_values[j]+=m_slopes[j];
			}
			++i;
		}
	}
	m_phase = phase;
}