andor4x2.core.cpp File Reference

#include "andor4x2.analogfunction.h"
#include "component.h"
#include "device.h"
#include "andor4x2.core.h"
#include "andor4x2.defs.h"

Include dependency graph for andor4x2.core.cpp:

Go to the source code of this file.

Macros
#define	CIR_andor4x2   -1
#define	A11   0
#define	A12   1
#define	A21   2
#define	A22   3
#define	A31   4
#define	A32   5
#define	A41   6
#define	A42   7
#define	Y   8
#define	n1   9
#define	n2   10
#define	NP(node)   real (getV (node))
#define	BP(pnode, nnode)   (NP(pnode) - NP(nnode))
#define	_load_static_residual2(pnode, nnode, current)
#define	_load_static_augmented_residual2(pnode, nnode, current)
#define	_load_static_residual1(node, current)   _rhs[node] -= current;
#define	_load_static_augmented_residual1(node, current)   _rhs[node] -= current;
#define	_load_static_jacobian4(pnode, nnode, vpnode, vnnode, conductance)
#define	_load_static_jacobian2p(node, vpnode, vnnode, conductance)
#define	_load_static_jacobian2s(pnode, nnode, node, conductance)
#define	_load_static_jacobian1(node, vnode, conductance)
#define	_load_dynamic_residual2(pnode, nnode, charge)
#define	_load_dynamic_residual1(node, charge)
#define	_load_dynamic_jacobian4(pnode, nnode, vpnode, vnnode, capacitance)
#define	_load_dynamic_jacobian2s(pnode, nnode, vnode, capacitance)
#define	_load_dynamic_jacobian2p(node, vpnode, vnnode, capacitance)
#define	_load_dynamic_jacobian1(node, vnode, capacitance)
#define	_save_whitenoise1(n1, pwr, type)   _white_pwr[n1][n1] += pwr;
#define	_save_whitenoise2(n1, n2, pwr, type)   _white_pwr[n1][n2] += pwr;
#define	_save_flickernoise1(n1, pwr, exp, type)
#define	_save_flickernoise2(n1, n2, pwr, exp, type)
#define	_load_whitenoise2(n1, n2, pwr)
#define	_load_whitenoise1(n1, pwr)   cy (n1,n1) += pwr/kB/T0;
#define	_load_flickernoise2(n1, n2, pwr, exp)
#define	_load_flickernoise1(n1, pwr, exp)   cy (n1,n1) += pwr*pow(_freq,-exp)/kB/T0;
#define	m00_hypot(v00, x, y)   v00 = xhypot(x,y);
#define	m10_hypot(v10, v00, x, y)   v10 = (x)/(v00);
#define	m11_hypot(v11, v00, x, y)   v11 = (y)/(v00);
#define	m00_max(v00, x, y)   v00 = ((x)>(y))?(x):(y);
#define	m10_max(v10, v00, x, y)   v10 = ((x)>(y))?1.0:0.0;
#define	m11_max(v11, v00, x, y)   v11 = ((x)>(y))?0.0:1.0;
#define	m00_min(v00, x, y)   v00 = ((x)<(y))?(x):(y);
#define	m10_min(v10, v00, x, y)   v10 = ((x)<(y))?1.0:0.0;
#define	m11_min(v11, v00, x, y)   v11 = ((x)<(y))?0.0:1.0;
#define	m00_pow(v00, x, y)   v00 = pow(x,y);
#define	m10_pow(v10, v00, x, y)   v10 = (x==0.0)?0.0:(v00)*(y)/(x);
#define	m11_pow(v11, v00, x, y)   v11 = (x==0.0)?0.0:(log(x)*(v00));
#define	m00_div(v00, v10, x, y)   double v10=1/(y); double v00=(x)*v10;
#define	m10_div(v10, v00, vv, x, y)
#define	m11_div(v11, v00, vv, x, y)   double v11 = -v00*vv;
#define	m00_mult(v00, v10, v11, x, y)   double v10=(x); double v11=(y); double v00=v10*v11;
#define	m00_add(v00, x, y)   double v00=(x)+(y);
#define	m00_cos(v00, x)   v00 = cos(x);
#define	m10_cos(v10, v00, x)   v10 = (-sin(x));
#define	m00_sin(v00, x)   v00 = sin(x);
#define	m10_sin(v10, v00, x)   v10 = (cos(x));
#define	m00_tan(v00, x)   v00 = tan(x);
#define	m10_tan(v10, v00, x)   v10 = (1.0/cos(x)/cos(x));
#define	m00_cosh(v00, x)   v00 = cosh(x);
#define	m10_cosh(v10, v00, x)   v10 = (sinh(x));
#define	m00_sinh(v00, x)   v00 = sinh(x);
#define	m10_sinh(v10, v00, x)   v10 = (cosh(x));
#define	m00_tanh(v00, x)   v00 = tanh(x);
#define	m10_tanh(v10, v00, x)   v10 = (1.0/cosh(x)/cosh(x));
#define	m00_acos(v00, x)   v00 = acos(x);
#define	m10_acos(v10, v00, x)   v10 = (-1.0/sqrt(1-x*x));
#define	m00_asin(v00, x)   v00 = asin(x);
#define	m10_asin(v10, v00, x)   v10 = (+1.0/sqrt(1-x*x));
#define	m00_atan(v00, x)   v00 = atan(x);
#define	m10_atan(v10, v00, x)   v10 = (+1.0/(1+x*x));
#define	m00_atanh(v00, x)   v00 = atanh(x);
#define	m10_atanh(v10, v00, x)   v10 = (+1.0/(1-x*x));
#define	m00_logE(v00, x)   v00 = log(x);
#define	m10_logE(v10, v00, x)   v10 = (1.0/x);
#define	m00_log10(v00, x)   v00 = log10(x);
#define	m10_log10(v10, v00, x)   v10 = (1.0/x/M_LN10);
#define	m00_sqrt(v00, x)   v00 = sqrt(x);
#define	m10_sqrt(v10, v00, x)   v10 = (0.5/v00);
#define	m00_fabs(v00, x)   v00 = fabs(x);
#define	m10_fabs(v10, v00, x)   v10 = (((x)>=0)?(+1.0):(-1.0));
#define	m00_exp(v00, x)   v00 = exp(x);
#define	m10_exp(v10, v00, x)   v10 = v00;
#define	m00_abs(v00)   ((v00)<(0)?(-(v00)):(v00))
#define	m00_floor(v00, x)   v00 = floor(x);
#define	m00_limexp(v00, x)   v00 = ((x)<80.0?exp(x):exp(80.0)*(x-79.0));
#define	m10_limexp(v10, v00, x)   v10 = ((x)<80.0?(v00):exp(80.0));
#define	m20_logE(v00)   (-1.0/v00/v00)
#define	m20_exp(v00)   exp(v00)
#define	m20_limexp(v00)   ((v00)<80.0?exp(v00):0.0)
#define	m20_sqrt(v00)   (-0.25/(v00)/sqrt(v00))
#define	m20_fabs(v00)   0.0
#define	m20_pow(x, y)   ((y)*((y)-1.0)*pow(x,y)/(x)/(x))
#define	m00_vt(x)   (kBoverQ*(x))
#define	m10_vt(x)   (kBoverQ)
#define	_modelname   "andor4x2"
#define	_instancename   getName()
#define	_circuit_temp   (getPropertyDouble("Temp")+273.15)
#define	_param_given(p)   (isPropertyGiven(p)?1:0)
#define	_vt_nom   (kBoverQ*_circuit_temp)
#define	_DDT(q)   q
#define	_DYNAMIC
#define	_DERIVATE
#define	_DDX
#define	_DERIVATEFORDDX

Macro Definition Documentation

#define _circuit_temp   (getPropertyDouble("Temp")+273.15)

Definition at line 240 of file andor4x2.core.cpp.

#define _DDT

(

q

)

q

Definition at line 332 of file andor4x2.core.cpp.

#define _DDX

Definition at line 335 of file andor4x2.core.cpp.

#define _DERIVATE

Definition at line 334 of file andor4x2.core.cpp.

#define _DERIVATEFORDDX

Definition at line 336 of file andor4x2.core.cpp.

#define _DYNAMIC

Definition at line 333 of file andor4x2.core.cpp.

#define _instancename   getName()

Definition at line 239 of file andor4x2.core.cpp.

#define _load_dynamic_jacobian1	(		node,
			vnode,
			capacitance
	)

Value:

if (doAC) {\
    _jdyna[node][vnode] += capacitance;\
    }\
    if (doTR) {\
    _caps[node][node][vnode][vnode] += capacitance;\
    }\
    if (doHB) {\
    _chs[node] += capacitance * NP(vnode);\
    }

Definition at line 136 of file andor4x2.core.cpp.

#define _load_dynamic_jacobian2p	(		node,
			vpnode,
			vnnode,
			capacitance
	)

Value:

if (doAC) {\
    _jdyna[node][vpnode] += capacitance;\
        _jdyna[node][vnnode] -= capacitance;\
        }\
    if (doTR) {\
        _caps[node][node][vpnode][vnnode] += capacitance;\
    }\
    if (doHB) {\
    _chs[node] += capacitance * BP(vpnode,vnnode);\
    }

Definition at line 125 of file andor4x2.core.cpp.

#define _load_dynamic_jacobian2s	(		pnode,
			nnode,
			vnode,
			capacitance
	)

Value:

if (doAC) {\
    _jdyna[pnode][vnode] += capacitance;\
    _jdyna[nnode][vnode] -= capacitance;\
    }\
    if (doTR) {\
    _caps[pnode][nnode][vnode][vnode] += capacitance;\
    }\
    if (doHB) {\
    _chs[pnode] += capacitance * NP(vnode);\
    _chs[nnode] -= capacitance * NP(vnode);\
    }

Definition at line 113 of file andor4x2.core.cpp.

#define _load_dynamic_jacobian4	(		pnode,
			nnode,
			vpnode,
			vnnode,
			capacitance
	)

Value:

if (doAC) {\
    _jdyna[pnode][vpnode] += capacitance;\
    _jdyna[nnode][vnnode] += capacitance;\
    _jdyna[pnode][vnnode] -= capacitance;\
    _jdyna[nnode][vpnode] -= capacitance;\
    }\
        if (doTR) {\
        _caps[pnode][nnode][vpnode][vnnode] += capacitance;\
    }\
    if (doHB) {\
    _chs[pnode] += capacitance * BP(vpnode,vnnode);\
    _chs[nnode] -= capacitance * BP(vpnode,vnnode);\
    }

Definition at line 99 of file andor4x2.core.cpp.

#define _load_dynamic_residual1	(		node,
			charge
	)

Value:

if (doTR) _charges[node][node] += charge;\
    if (doHB) {\
    _qhs[node] -= charge;\
    }

Definition at line 94 of file andor4x2.core.cpp.

#define _load_dynamic_residual2	(		pnode,
			nnode,
			charge
	)

Value:

if (doTR) _charges[pnode][nnode] += charge;\
    if (doHB) {\
    _qhs[pnode] -= charge;\
    _qhs[nnode] += charge;\
    }

Definition at line 88 of file andor4x2.core.cpp.

#define _load_flickernoise1	(		n1,
			pwr,
			exp
	)		cy (n1,n1) += pwr*pow(_freq,-exp)/kB/T0;

Definition at line 167 of file andor4x2.core.cpp.

#define _load_flickernoise2	(		n1,
			n2,
			pwr,
			exp
	)

Value:

cy (n1,n2) -= pwr*pow(_freq,-exp)/kB/T0;\
    cy (n2,n1) -= pwr*pow(_freq,-exp)/kB/T0;\
    cy (n1,n1) += pwr*pow(_freq,-exp)/kB/T0;\
    cy (n2,n2) += pwr*pow(_freq,-exp)/kB/T0;

Definition at line 162 of file andor4x2.core.cpp.

#define _load_static_augmented_residual1	(		node,
			current
	)		_rhs[node] -= current;

Definition at line 49 of file andor4x2.core.cpp.

#define _load_static_augmented_residual2	(		pnode,
			nnode,
			current
	)

Value:

_rhs[pnode] -= current;\
    _rhs[nnode] += current;

Definition at line 44 of file andor4x2.core.cpp.

#define _load_static_jacobian1	(		node,
			vnode,
			conductance
	)

Value:

_jstat[node][vnode] += conductance;\
    if (doHB) {\
    _ghs[node] += conductance * NP(vnode);\
        } else {\
    _rhs[node] += conductance * NP(vnode);\
    }

Definition at line 81 of file andor4x2.core.cpp.

#define _load_static_jacobian2p	(		node,
			vpnode,
			vnnode,
			conductance
	)

Value:

_jstat[node][vpnode] += conductance;\
    _jstat[node][vnnode] -= conductance;\
    if (doHB) {\
        _ghs[node] += conductance * BP(vpnode,vnnode);\
        } else {\
        _rhs[node] += conductance * BP(vpnode,vnnode);\
    }

Definition at line 63 of file andor4x2.core.cpp.

#define _load_static_jacobian2s	(		pnode,
			nnode,
			node,
			conductance
	)

Value:

_jstat[pnode][node] += conductance;\
    _jstat[nnode][node] -= conductance;\
    if (doHB) {\
    _ghs[pnode] += conductance * NP(node);\
    _ghs[nnode] -= conductance * NP(node);\
        } else {\
    _rhs[pnode] += conductance * NP(node);\
    _rhs[nnode] -= conductance * NP(node);\
    }

Definition at line 71 of file andor4x2.core.cpp.

#define _load_static_jacobian4	(		pnode,
			nnode,
			vpnode,
			vnnode,
			conductance
	)

Value:

_jstat[pnode][vpnode] += conductance;\
    _jstat[nnode][vnnode] += conductance;\
    _jstat[pnode][vnnode] -= conductance;\
    _jstat[nnode][vpnode] -= conductance;\
    if (doHB) {\
    _ghs[pnode] += conductance * BP(vpnode,vnnode);\
    _ghs[nnode] -= conductance * BP(vpnode,vnnode);\
        } else {\
    _rhs[pnode] += conductance * BP(vpnode,vnnode);\
    _rhs[nnode] -= conductance * BP(vpnode,vnnode);\
    }

Definition at line 51 of file andor4x2.core.cpp.

#define _load_static_residual1	(		node,
			current
	)		_rhs[node] -= current;

Definition at line 47 of file andor4x2.core.cpp.

#define _load_static_residual2	(		pnode,
			nnode,
			current
	)

Value:

_rhs[pnode] -= current;\
    _rhs[nnode] += current;

Definition at line 41 of file andor4x2.core.cpp.

#define _load_whitenoise1	(		n1,
			pwr
	)		cy (n1,n1) += pwr/kB/T0;

Definition at line 160 of file andor4x2.core.cpp.

#define _load_whitenoise2	(		n1,
			n2,
			pwr
	)

Value:

cy (n1,n2) -= pwr/kB/T0; cy (n2,n1) -= pwr/kB/T0;\
    cy (n1,n1) += pwr/kB/T0; cy (n2,n2) += pwr/kB/T0;

Definition at line 157 of file andor4x2.core.cpp.

#define _modelname   "andor4x2"

Definition at line 238 of file andor4x2.core.cpp.

#define _param_given

(

p

)

(isPropertyGiven(p)?1:0)

Definition at line 241 of file andor4x2.core.cpp.

#define _save_flickernoise1	(		n1,
			pwr,
			exp,
			type
	)

Value:

_flicker_pwr[n1][n1] += pwr;\
    _flicker_exp[n1][n1] += exp;

Definition at line 151 of file andor4x2.core.cpp.

#define _save_flickernoise2	(		n1,
			n2,
			pwr,
			exp,
			type
	)

Value:

_flicker_pwr[n1][n2] += pwr;\
    _flicker_exp[n1][n2] += exp;

Definition at line 154 of file andor4x2.core.cpp.

#define _save_whitenoise1	(		n1,
			pwr,
			type
	)		_white_pwr[n1][n1] += pwr;

Definition at line 147 of file andor4x2.core.cpp.

#define _save_whitenoise2	(		n1,
			n2,
			pwr,
			type
	)		_white_pwr[n1][n2] += pwr;

Definition at line 149 of file andor4x2.core.cpp.

#define _vt_nom   (kBoverQ*_circuit_temp)

Definition at line 245 of file andor4x2.core.cpp.

#define A11   0

Definition at line 25 of file andor4x2.core.cpp.

#define A12   1

Definition at line 26 of file andor4x2.core.cpp.

#define A21   2

Definition at line 27 of file andor4x2.core.cpp.

#define A22   3

Definition at line 28 of file andor4x2.core.cpp.

#define A31   4

Definition at line 29 of file andor4x2.core.cpp.

#define A32   5

Definition at line 30 of file andor4x2.core.cpp.

#define A41   6

Definition at line 31 of file andor4x2.core.cpp.

#define A42   7

Definition at line 32 of file andor4x2.core.cpp.

#define BP	(		pnode,
			nnode
	)		(NP(pnode) - NP(nnode))

Definition at line 40 of file andor4x2.core.cpp.

#define CIR_andor4x2   -1

Definition at line 21 of file andor4x2.core.cpp.

#define m00_abs

(

v00

)

((v00)<(0)?(-(v00)):(v00))

Definition at line 223 of file andor4x2.core.cpp.

#define m00_acos	(		v00,
			x
	)		v00 = acos(x);

Definition at line 203 of file andor4x2.core.cpp.

#define m00_add	(		v00,
			x,
			y
	)		double v00=(x)+(y);

Definition at line 189 of file andor4x2.core.cpp.

#define m00_asin	(		v00,
			x
	)		v00 = asin(x);

Definition at line 205 of file andor4x2.core.cpp.

#define m00_atan	(		v00,
			x
	)		v00 = atan(x);

Definition at line 207 of file andor4x2.core.cpp.

#define m00_atanh	(		v00,
			x
	)		v00 = atanh(x);

Definition at line 209 of file andor4x2.core.cpp.

#define m00_cos	(		v00,
			x
	)		v00 = cos(x);

Definition at line 191 of file andor4x2.core.cpp.

#define m00_cosh	(		v00,
			x
	)		v00 = cosh(x);

Definition at line 197 of file andor4x2.core.cpp.

#define m00_div	(		v00,
			v10,
			x,
			y
	)		double v10=1/(y); double v00=(x)*v10;

Definition at line 184 of file andor4x2.core.cpp.

#define m00_exp	(		v00,
			x
	)		v00 = exp(x);

Definition at line 220 of file andor4x2.core.cpp.

#define m00_fabs	(		v00,
			x
	)		v00 = fabs(x);

Definition at line 217 of file andor4x2.core.cpp.

#define m00_floor	(		v00,
			x
	)		v00 = floor(x);

Definition at line 224 of file andor4x2.core.cpp.

#define m00_hypot	(		v00,
			x,
			y
	)		v00 = xhypot(x,y);

Definition at line 171 of file andor4x2.core.cpp.

#define m00_limexp	(		v00,
			x
	)		v00 = ((x)<80.0?exp(x):exp(80.0)*(x-79.0));

Definition at line 225 of file andor4x2.core.cpp.

#define m00_log10	(		v00,
			x
	)		v00 = log10(x);

Definition at line 213 of file andor4x2.core.cpp.

#define m00_logE	(		v00,
			x
	)		v00 = log(x);

Definition at line 211 of file andor4x2.core.cpp.

#define m00_max	(		v00,
			x,
			y
	)		v00 = ((x)>(y))?(x):(y);

Definition at line 174 of file andor4x2.core.cpp.

#define m00_min	(		v00,
			x,
			y
	)		v00 = ((x)<(y))?(x):(y);

Definition at line 177 of file andor4x2.core.cpp.

#define m00_mult	(		v00,
			v10,
			v11,
			x,
			y
	)		double v10=(x); double v11=(y); double v00=v10*v11;

Definition at line 188 of file andor4x2.core.cpp.

#define m00_pow	(		v00,
			x,
			y
	)		v00 = pow(x,y);

Definition at line 180 of file andor4x2.core.cpp.

#define m00_sin	(		v00,
			x
	)		v00 = sin(x);

Definition at line 193 of file andor4x2.core.cpp.

#define m00_sinh	(		v00,
			x
	)		v00 = sinh(x);

Definition at line 199 of file andor4x2.core.cpp.

#define m00_sqrt	(		v00,
			x
	)		v00 = sqrt(x);

Definition at line 215 of file andor4x2.core.cpp.

#define m00_tan	(		v00,
			x
	)		v00 = tan(x);

Definition at line 195 of file andor4x2.core.cpp.

#define m00_tanh	(		v00,
			x
	)		v00 = tanh(x);

Definition at line 201 of file andor4x2.core.cpp.

#define m00_vt

(

x

)

(kBoverQ*(x))

Definition at line 234 of file andor4x2.core.cpp.

#define m10_acos	(		v10,
			v00,
			x
	)		v10 = (-1.0/sqrt(1-x*x));

Definition at line 204 of file andor4x2.core.cpp.

#define m10_asin	(		v10,
			v00,
			x
	)		v10 = (+1.0/sqrt(1-x*x));

Definition at line 206 of file andor4x2.core.cpp.

#define m10_atan	(		v10,
			v00,
			x
	)		v10 = (+1.0/(1+x*x));

Definition at line 208 of file andor4x2.core.cpp.

#define m10_atanh	(		v10,
			v00,
			x
	)		v10 = (+1.0/(1-x*x));

Definition at line 210 of file andor4x2.core.cpp.

#define m10_cos	(		v10,
			v00,
			x
	)		v10 = (-sin(x));

Definition at line 192 of file andor4x2.core.cpp.

#define m10_cosh	(		v10,
			v00,
			x
	)		v10 = (sinh(x));

Definition at line 198 of file andor4x2.core.cpp.

#define m10_div	(		v10,
			v00,
			vv,
			x,
			y
	)

Definition at line 185 of file andor4x2.core.cpp.

#define m10_exp	(		v10,
			v00,
			x
	)		v10 = v00;

Definition at line 221 of file andor4x2.core.cpp.

#define m10_fabs	(		v10,
			v00,
			x
	)		v10 = (((x)>=0)?(+1.0):(-1.0));

Definition at line 218 of file andor4x2.core.cpp.

#define m10_hypot	(		v10,
			v00,
			x,
			y
	)		v10 = (x)/(v00);

Definition at line 172 of file andor4x2.core.cpp.

#define m10_limexp	(		v10,
			v00,
			x
	)		v10 = ((x)<80.0?(v00):exp(80.0));

Definition at line 226 of file andor4x2.core.cpp.

#define m10_log10	(		v10,
			v00,
			x
	)		v10 = (1.0/x/M_LN10);

Definition at line 214 of file andor4x2.core.cpp.

#define m10_logE	(		v10,
			v00,
			x
	)		v10 = (1.0/x);

Definition at line 212 of file andor4x2.core.cpp.

#define m10_max	(		v10,
			v00,
			x,
			y
	)		v10 = ((x)>(y))?1.0:0.0;

Definition at line 175 of file andor4x2.core.cpp.

#define m10_min	(		v10,
			v00,
			x,
			y
	)		v10 = ((x)<(y))?1.0:0.0;

Definition at line 178 of file andor4x2.core.cpp.

#define m10_pow	(		v10,
			v00,
			x,
			y
	)		v10 = (x==0.0)?0.0:(v00)*(y)/(x);

Definition at line 181 of file andor4x2.core.cpp.

#define m10_sin	(		v10,
			v00,
			x
	)		v10 = (cos(x));

Definition at line 194 of file andor4x2.core.cpp.

#define m10_sinh	(		v10,
			v00,
			x
	)		v10 = (cosh(x));

Definition at line 200 of file andor4x2.core.cpp.

#define m10_sqrt	(		v10,
			v00,
			x
	)		v10 = (0.5/v00);

Definition at line 216 of file andor4x2.core.cpp.

#define m10_tan	(		v10,
			v00,
			x
	)		v10 = (1.0/cos(x)/cos(x));

Definition at line 196 of file andor4x2.core.cpp.

#define m10_tanh	(		v10,
			v00,
			x
	)		v10 = (1.0/cosh(x)/cosh(x));

Definition at line 202 of file andor4x2.core.cpp.

#define m10_vt

(

x

)

(kBoverQ)

Definition at line 235 of file andor4x2.core.cpp.

#define m11_div	(		v11,
			v00,
			vv,
			x,
			y
	)		double v11 = -v00*vv;

Definition at line 186 of file andor4x2.core.cpp.

#define m11_hypot	(		v11,
			v00,
			x,
			y
	)		v11 = (y)/(v00);

Definition at line 173 of file andor4x2.core.cpp.

#define m11_max	(		v11,
			v00,
			x,
			y
	)		v11 = ((x)>(y))?0.0:1.0;

Definition at line 176 of file andor4x2.core.cpp.

#define m11_min	(		v11,
			v00,
			x,
			y
	)		v11 = ((x)<(y))?0.0:1.0;

Definition at line 179 of file andor4x2.core.cpp.

#define m11_pow	(		v11,
			v00,
			x,
			y
	)		v11 = (x==0.0)?0.0:(log(x)*(v00));

Definition at line 182 of file andor4x2.core.cpp.

#define m20_exp

(

v00

)

exp(v00)

Definition at line 229 of file andor4x2.core.cpp.

#define m20_fabs

(

v00

)

0.0

Definition at line 232 of file andor4x2.core.cpp.

#define m20_limexp

(

v00

)

((v00)<80.0?exp(v00):0.0)

Definition at line 230 of file andor4x2.core.cpp.

#define m20_logE

(

v00

)

(-1.0/v00/v00)

Definition at line 228 of file andor4x2.core.cpp.

#define m20_pow	(		x,
			y
	)		((y)*((y)-1.0)*pow(x,y)/(x)/(x))

Definition at line 233 of file andor4x2.core.cpp.

#define m20_sqrt

(

v00

)

(-0.25/(v00)/sqrt(v00))

Definition at line 231 of file andor4x2.core.cpp.

#define n1   9

Definition at line 35 of file andor4x2.core.cpp.

#define n2   10

Definition at line 36 of file andor4x2.core.cpp.

#define NP

(

node

)

real (getV (node))

Definition at line 39 of file andor4x2.core.cpp.

#define Y   8

Definition at line 33 of file andor4x2.core.cpp.