static int state (double* _p, Datum* _ppvar, Datum* _thread, _NrnThread* _nt) {int _reset=0; int error = 0;
{ double* _savstate1 = _thread[_dith1]._pval;
double* _dlist2 = _thread[_dith1]._pval + 1;
int _counte = -1;
if (!_recurse) {
_recurse = 1;
{int _id; for(_id=0; _id < 1; _id++) { _savstate1[_id] = _p[_slist1[_id]];}}
error = nrn_newton_thread(_newtonspace1, 1,_slist2, _p, state, _dlist2, _ppvar, _thread, _nt);
_recurse = 0; if(error) {abort_run(error);}}
{
Dcai = ( - beta * ica ) - ( phi * ( cai - caiBase ) ) ;
{int _id; for(_id=0; _id < 1; _id++) {
if (_deriv1_advance) {
_dlist2[++_counte] = _p[_dlist1[_id]] - (_p[_slist1[_id]] - _savstate1[_id])/dt;
}else{
_dlist2[++_counte] = _p[_slist1[_id]] - _savstate1[_id];}}}
} }
return _reset;}
static int state (double* _p, Datum* _ppvar, Datum* _thread, _NrnThread* _nt) {int _reset=0; int error = 0;
{ double* _savstate1 = _thread[_dith1]._pval;
double* _dlist2 = _thread[_dith1]._pval + 2;
int _counte = -1;
if (!_recurse) {
_recurse = 1;
{int _id; for(_id=0; _id < 2; _id++) { _savstate1[_id] = _p[_slist1[_id]];}}
error = nrn_newton_thread(_newtonspace1, 2,_slist2, _p, state, _dlist2, _ppvar, _thread, _nt);
_recurse = 0; if(error) {abort_run(error);}}
{
Dko = ( 1e8 ) * ik / ( fhspace * FARADAY ) + ( kbath - ko ) / txfer ;
Dnai = - ( 1e8 ) * ina / ( inspace * FARADAY ) + ( narest - nai ) / naxfer ;
{int _id; for(_id=0; _id < 2; _id++) {
if (_deriv1_advance) {
_dlist2[++_counte] = _p[_dlist1[_id]] - (_p[_slist1[_id]] - _savstate1[_id])/dt;
}else{
_dlist2[++_counte] = _p[_slist1[_id]] - _savstate1[_id];}}}
} }
return _reset;}
static int states (double* _p, Datum* _ppvar, Datum* _thread, _NrnThread* _nt) {int _reset=0; int error = 0;
{ double* _savstate1 = _thread[_dith1]._pval;
double* _dlist2 = _thread[_dith1]._pval + 2;
int _counte = -1;
if (!_recurse) {
_recurse = 1;
{int _id; for(_id=0; _id < 2; _id++) { _savstate1[_id] = _p[_slist1[_id]];}}
error = nrn_newton_thread(_newtonspace1, 2,_slist2, _p, states, _dlist2, _ppvar, _thread, _nt);
_recurse = 0; if(error) {abort_run(error);}}
{
rates ( _threadargscomma_ v ) ;
Dm = ( minf - m ) / mtau ;
Dn = ( ninf - n ) / ntau ;
{int _id; for(_id=0; _id < 2; _id++) {
if (_deriv1_advance) {
_dlist2[++_counte] = _p[_dlist1[_id]] - (_p[_slist1[_id]] - _savstate1[_id])/dt;
}else{
_dlist2[++_counte] = _p[_slist1[_id]] - _savstate1[_id];}}}
} }
return _reset;}
static int state (double* _p, Datum* _ppvar, Datum* _thread, _NrnThread* _nt) {int _reset=0; int error = 0;
{ double* _savstate1 = _thread[_dith1]._pval;
double* _dlist2 = _thread[_dith1]._pval + 1;
int _counte = -1;
if (!_recurse) {
_recurse = 1;
{int _id; for(_id=0; _id < 1; _id++) { _savstate1[_id] = _p[_slist1[_id]];}}
error = nrn_newton_thread(_newtonspace1, 1,_slist2, _p, state, _dlist2, _ppvar, _thread, _nt);
_recurse = 0; if(error) {abort_run(error);}}
{
drive_channel = - ( 10000.0 ) * ica / ( 2.0 * FARADAY * depth ) ;
if ( drive_channel <= 0. ) {
drive_channel = 0. ;
}
Dca = drive_channel / 18.0 + ( cainf - ca ) / taur * 7.0 ;
cai = ca ;
{int _id; for(_id=0; _id < 1; _id++) {
if (_deriv1_advance) {
_dlist2[++_counte] = _p[_dlist1[_id]] - (_p[_slist1[_id]] - _savstate1[_id])/dt;
}else{
_dlist2[++_counte] = _p[_slist1[_id]] - _savstate1[_id];}}}
} }
return _reset;}
