int main()
{
system("cls");
do
{
// requests prime number from the user.
printf("Enter a prime number: ");
scanf("%d",&ptest);
// checks if it is prime before assigning it to the 'p' variable.
flag=prime(ptest);
}while(flag==0);
if(flag==1)
p=ptest;
do
{
// requests another prime number from the user.
printf("\nEnter a second prime number: ");
scanf("%d",&qtest);
// checks if it is prime before assigning it to the 'q' variable.
flag=prime(qtest);
}while(flag==0);
if(flag==1)
q=qtest;
// gets the message from the user.
printf("\nEnter message: ");
fflush(stdin);
scanf("%[^\n]%*c",Msg);
len=strlen(Msg);
for(i=0;i!=len;i++)
m[i]=Msg[i];
// calculates the modulus and phi.
n=p*q;
phi=(p-1)*(q-1);
// then e and d.
calcE();
printf("\nPossible values of e and d: ");
for(i=0;i<j-1;i++)
printf("\n%ld\t%ld",e[i],d[i]);
encrypt();
decrypt();
getch();
return(0);
}
int main() {
Particle particle;
std::ofstream ofs;
ofs.open( "kep" );
for (int i=0;i<1000000;i++) {
double x = particle.qx;
double y = particle.qy;
// for (int s=0;i<sympI;i++) {
symp2(&particle, dT);
/*
particle.px+=calc(x, y) *symp_u[i]* dT;
particle.py+=calc(y, x) *symp_u[i]* dT;
particle.qx+=particle.px/M*symp_k[i]* dT;
particle.qy+=particle.py/M*symp_k[i]* dT;
*/
// }
// std::cout << "px = " << particle.px << ", py = " << particle.py << std::endl;
// std::cout << "qx = " << particle.qx << ", px = " << particle.px << std::endl;
if (i%500==0) {
ofs << particle.qx << " " << particle.qy << " " << 0.0 << " " << calcE(particle) << " " << a_length(particle) << std::endl;
}
}
ofs.close();
}
//Update
static void update(void)
{
calcJD();
calcE();
field_defaultIncidence(Ez);
calcMB();
calcH();
}
static inline void update(void)
{
calcJD();
calcE();
calcMB();
calcH();
field_defaultIncidence(Hz);
}
static inline void update(void)
{
calcJD();
calcE();
scatteredWave(Ey, EPS_EY);
calcMB();
calcH();
}
void reportElement_toFile(FILE* f,FILE* reso, bool J2, double theta, Particle pa) {
double q = hypot(hypot(pa.qx, pa.qy), pa.qz);
double p = hypot(hypot(pa.px, pa.py), pa.pz);
double a = a_length(q, p);
double Energy = 0;
if (J2) {
Energy = calcE_J2(q, p, pa);
} else {
Energy = calcE(q, p);
}
double h = h_moment(pa);
double e = e_anomaly(a, h);
double I = I_anomaly(h, pa);
double OMEGA = OMEGA_anomaly(I, h, pa);
fprintf(f, "%.4f %.4f %.4f %.4f %.4f %.4f %.4f %.4f %.4f\n", pa.qx, pa.qy, pa.qz, Energy, a, h, e, I, theta);
fprintf(reso, "%f %f\n", a*(pa.qx/q*cos(theta)+pa.qy/q*sin(theta)), a*(pa.qy/q*cos(theta)-pa.qx/q*sin(theta)));
}
//Update
static void update(void)
{
// _CalcJD();
calcJD();
calcE();
// MPI_Barrier(MPI_COMM_WORLD); //ăăăȘă?
scatteredWave(Ez, EPS_EZ);
//planeWave(Ez, EPS_EZ);
//Connection_SendRecvE();
Connection_ISend_IRecvE();
// _CalcMB();
calcMB();
calcH();
Connection_ISend_IRecvH();
//Connection_SendRecvH();
ntff();
}