void appendFile(FILE* graveur, Fichier* queue){
FILE* lecteur = ouvrirLecture(queue);
unsigned long tailleFichier = fsize(queue);
unsigned long nbrDivisions = tailleFichier/TAILLE_BUFFER;
TabOfChar* buffer = newTabOfChar(TAILLE_BUFFER);
TabOfChar* reste = newTabOfChar(tailleFichier % TAILLE_BUFFER);
for (unsigned long i = 0; i<nbrDivisions; i++) {
readFlux(lecteur, buffer);
writeFlux(graveur, buffer);
}
readFlux(lecteur, reste);
writeFlux(graveur, reste);
terminateTableau((Tableau*) buffer);
terminateTableau((Tableau*) reste);
fclose(lecteur);
}
int main(int argc, char *argv[])
{
bool_t analyze_output, equilibria_only;
int niter, nact;
Atom *atom;
Molecule *molecule;
/* --- Read input data and initialize -- -------------- */
setOptions(argc, argv);
getCPU(0, TIME_START, NULL);
SetFPEtraps();
readInput();
spectrum.updateJ = TRUE;
getCPU(1, TIME_START, NULL);
readAtmos(&atmos, &geometry);
if (atmos.Stokes) Bproject();
fillMesh(&geometry);
readAtomicModels();
readMolecularModels();
SortLambda();
getBoundary(&atmos, &geometry);
Background(analyze_output=TRUE, equilibria_only=FALSE);
getProfiles();
initSolution();
initScatter();
getCPU(1, TIME_POLL, "Total initialize");
/* --- Solve radiative transfer for active ingredients -- --------- */
Iterate(input.NmaxIter, input.iterLimit);
adjustStokesMode(atom);
niter = 0;
while (niter < input.NmaxScatter) {
if (solveSpectrum(FALSE, FALSE) <= input.iterLimit) break;
niter++;
}
/* --- Write output files -- ------------------ */
getCPU(1, TIME_START, NULL);
writeInput();
writeAtmos(&atmos);
writeGeometry(&geometry);
writeSpectrum(&spectrum);
writeFlux(FLUX_DOT_OUT);
for (nact = 0; nact < atmos.Nactiveatom; nact++) {
atom = atmos.activeatoms[nact];
writeAtom(atom);
writePopulations(atom);
writeRadRate(atom);
writeCollisionRate(atom);
writeDamping(atom);
}
for (nact = 0; nact < atmos.Nactivemol; nact++) {
molecule = atmos.activemols[nact];
writeMolPops(molecule);
}
writeOpacity();
getCPU(1, TIME_POLL, "Write output");
printTotalCPU();
}
