Generated Code
The following is c code generated by the CellML API from this CellML file. (Back to language selection)
The raw code is available.
/*
There are a total of 11 entries in the algebraic variable array.
There are a total of 4 entries in each of the rate and state variable arrays.
There are a total of 23 entries in the constant variable array.
*/
/*
* VOI is time in component environment (millisecond).
* STATES[0] is V in component membrane (millivolt).
* CONSTANTS[0] is C in component membrane (picofarad).
* ALGEBRAIC[5] is I_Ca in component I_Ca (picoampere).
* ALGEBRAIC[0] is I_K in component I_K (picoampere).
* ALGEBRAIC[7] is I_SK in component I_SK (picoampere).
* ALGEBRAIC[10] is I_DA in component I_DA (picoampere).
* CONSTANTS[1] is gK in component I_K (nanosiemens).
* CONSTANTS[2] is VK in component model_parameters (millivolt).
* STATES[1] is n in component n (dimensionless).
* ALGEBRAIC[1] is n_infinity in component n (dimensionless).
* CONSTANTS[3] is lambda in component n (dimensionless).
* CONSTANTS[4] is tau_n in component n (millisecond).
* CONSTANTS[5] is vn in component n (millivolt).
* CONSTANTS[6] is sn in component n (millivolt).
* CONSTANTS[7] is gCa in component I_Ca (nanosiemens).
* CONSTANTS[8] is VCa in component model_parameters (millivolt).
* ALGEBRAIC[4] is m_infinity in component m (dimensionless).
* CONSTANTS[9] is vm in component m (millivolt).
* CONSTANTS[10] is sm in component m (millivolt).
* CONSTANTS[11] is gSK in component I_SK (nanosiemens).
* ALGEBRAIC[6] is s_infinity in component I_SK (dimensionless).
* CONSTANTS[12] is ks in component I_SK (micromolar).
* STATES[2] is Ca in component Ca (micromolar).
* ALGEBRAIC[9] is I_BK in component I_DA (picoampere).
* CONSTANTS[13] is gBK in component I_DA (nanosiemens).
* ALGEBRAIC[8] is f_infinity in component f (dimensionless).
* CONSTANTS[14] is vf in component f (millivolt).
* CONSTANTS[15] is sf in component f (millivolt).
* STATES[3] is h in component h (dimensionless).
* ALGEBRAIC[2] is h_infinity in component h (dimensionless).
* CONSTANTS[16] is tau_h in component h (millisecond).
* CONSTANTS[17] is vh in component h (millivolt).
* CONSTANTS[18] is sh in component h (millivolt).
* CONSTANTS[19] is fc in component Ca (dimensionless).
* CONSTANTS[20] is alpha in component Ca (micromolar_femtocoulomb).
* CONSTANTS[21] is kc in component Ca (first_order_rate_constant).
* ALGEBRAIC[3] is PRL in component PRL (dimensionless).
* CONSTANTS[22] is kPRL in component PRL (micromolar_4).
* RATES[0] is d/dt V in component membrane (millivolt).
* RATES[1] is d/dt n in component n (dimensionless).
* RATES[3] is d/dt h in component h (dimensionless).
* RATES[2] is d/dt Ca in component Ca (micromolar).
*/
void
initConsts(double* CONSTANTS, double* RATES, double *STATES)
{
STATES[0] = -60;
CONSTANTS[0] = 10;
CONSTANTS[1] = 4;
CONSTANTS[2] = -75;
STATES[1] = 0.1;
CONSTANTS[3] = 0.7;
CONSTANTS[4] = 30;
CONSTANTS[5] = -5;
CONSTANTS[6] = 10;
CONSTANTS[7] = 2;
CONSTANTS[8] = 50;
CONSTANTS[9] = -20;
CONSTANTS[10] = 12;
CONSTANTS[11] = 1.7;
CONSTANTS[12] = 0.5;
STATES[2] = 0.1;
CONSTANTS[13] = 0.2;
CONSTANTS[14] = -20;
CONSTANTS[15] = 5.6;
STATES[3] = 0.1;
CONSTANTS[16] = 20;
CONSTANTS[17] = -60;
CONSTANTS[18] = 5;
CONSTANTS[19] = 0.01;
CONSTANTS[20] = 0.0015;
CONSTANTS[21] = 0.16;
CONSTANTS[22] = 1;
}
void
computeRates(double VOI, double* CONSTANTS, double* RATES, double* STATES, double* ALGEBRAIC)
{
ALGEBRAIC[1] = 1.00000/(1.00000+exp((CONSTANTS[5] - STATES[0])/CONSTANTS[6]));
RATES[1] = ( CONSTANTS[3]*(ALGEBRAIC[1] - STATES[1]))/CONSTANTS[4];
ALGEBRAIC[2] = 1.00000/(1.00000+exp((STATES[0] - CONSTANTS[17])/CONSTANTS[18]));
RATES[3] = (ALGEBRAIC[2] - STATES[3])/CONSTANTS[16];
ALGEBRAIC[4] = 1.00000/(1.00000+exp((CONSTANTS[9] - STATES[0])/CONSTANTS[10]));
ALGEBRAIC[5] = CONSTANTS[7]*ALGEBRAIC[4]*(STATES[0] - CONSTANTS[8]);
RATES[2] = - CONSTANTS[19]*( CONSTANTS[20]*ALGEBRAIC[5]+ CONSTANTS[21]*STATES[2]);
ALGEBRAIC[0] = CONSTANTS[1]*STATES[1]*(STATES[0] - CONSTANTS[2]);
ALGEBRAIC[6] = pow(STATES[2], 2.00000)/(pow(STATES[2], 2.00000)+pow(CONSTANTS[12], 2.00000));
ALGEBRAIC[7] = CONSTANTS[11]*ALGEBRAIC[6]*(STATES[0] - CONSTANTS[2]);
ALGEBRAIC[8] = 1.00000/(1.00000+exp((CONSTANTS[14] - STATES[0])/CONSTANTS[15]));
ALGEBRAIC[9] = CONSTANTS[13]*ALGEBRAIC[8]*(STATES[0] - CONSTANTS[2]);
ALGEBRAIC[10] = ALGEBRAIC[9];
RATES[0] = - (ALGEBRAIC[5]+ALGEBRAIC[0]+ALGEBRAIC[7]+ALGEBRAIC[10])/CONSTANTS[0];
}
void
computeVariables(double VOI, double* CONSTANTS, double* RATES, double* STATES, double* ALGEBRAIC)
{
ALGEBRAIC[1] = 1.00000/(1.00000+exp((CONSTANTS[5] - STATES[0])/CONSTANTS[6]));
ALGEBRAIC[2] = 1.00000/(1.00000+exp((STATES[0] - CONSTANTS[17])/CONSTANTS[18]));
ALGEBRAIC[4] = 1.00000/(1.00000+exp((CONSTANTS[9] - STATES[0])/CONSTANTS[10]));
ALGEBRAIC[5] = CONSTANTS[7]*ALGEBRAIC[4]*(STATES[0] - CONSTANTS[8]);
ALGEBRAIC[0] = CONSTANTS[1]*STATES[1]*(STATES[0] - CONSTANTS[2]);
ALGEBRAIC[6] = pow(STATES[2], 2.00000)/(pow(STATES[2], 2.00000)+pow(CONSTANTS[12], 2.00000));
ALGEBRAIC[7] = CONSTANTS[11]*ALGEBRAIC[6]*(STATES[0] - CONSTANTS[2]);
ALGEBRAIC[8] = 1.00000/(1.00000+exp((CONSTANTS[14] - STATES[0])/CONSTANTS[15]));
ALGEBRAIC[9] = CONSTANTS[13]*ALGEBRAIC[8]*(STATES[0] - CONSTANTS[2]);
ALGEBRAIC[10] = ALGEBRAIC[9];
ALGEBRAIC[3] = CONSTANTS[22]*pow(STATES[2], 4.00000);
}