Writing a particle system with fields per particle.The example is a simulation of colliding galaxies.
#include <hdf5.h> #include <math.h> #include <F5/F5particles.h> #include <F5/F5coordinates.h> #include <F5/F5X.h> #if 1 #define N 511 #define SHELLS 19 #define T_END 800 #elif 0 #define N 1002 #define SHELLS 30 #define T_END 800 #else #define N 6 #define SHELLS 1 #define T_END 1 #endif #ifndef M_PI #define M_PI 3.141592 #endif int main(int argc, char*argv[]) { /* Needed Variables */ F5_vec3_point_t P[N]; F5_vec3_float_t V[N]; F5_vec3_float_t A[N]; float mass[N], weirdness[N]; int i; hid_t FileID; double t = 0, dt = .1, t_end = T_END; int iteration = 0, out_every = 10; const double G = 1; /* Gravitational Constant */ P[0].x = P[0].y = 0; P[0].z = 10; V[0].x = V[0].y = -0.02; V[0].z = -.05; mass[0] = .01; weirdness[0] = 1; P[1].x = P[1].y = P[1].z = 0; V[1].x = V[1].y = V[1].z = 0; mass[1] = .04; weirdness[1] = -1; for(i=2;i<N;i++) /* Init the Field */ { int ir = (i-2) / SHELLS, ip = (i-2) % SHELLS; double r = 4.0 * (ir+1) / ( (N-2)/SHELLS), p = 2*M_PI * ip / SHELLS, sp = sin(p), cp = cos(p); P[i].x = r*sp; P[i].y = r*cp; P[i].z = 0; /* v^2 / r = M / r^2 --> |v| = M/r Kepler rotation */ V[i].x = cp * sqrt(G*mass[1]/ r); V[i].y = -sp * sqrt(G*mass[1]/ r); V[i].z = 0; mass[i] = .0001; weirdness[i] = r + .1*p; } /* Save Data to F5 File - this is the real magic */ /*-----------------------------------------------*/ /* Create the File */ FileID = H5Fcreate("Particles.f5", /* The FileName */ H5F_ACC_TRUNC, /* Creation Flags */ H5P_DEFAULT, /* File creation property list identifier */ H5P_DEFAULT); /* File access property list identifier */ /* Time iteration (euler integration) */ for(t = 0; t<t_end; t+= dt, iteration++) { for(i=0;i<N;i++) /* Outer Loop: for all particles */ { int j; #if 1 int Ngrav = 2; #else int Ngrav = N; #endif /* Inner loop: compute acceleration */ F5_vec3_float_t a; a.x = a.y = a.z = 0; for(j=0; j<Ngrav; j++) { F5_vec3_float_t Rij; double R2, R3; if (i==j) continue; Rij.x = P[i].x - P[j].x; Rij.y = P[i].y - P[j].y; Rij.z = P[i].z - P[j].z; R2 = Rij.x*Rij.x + Rij.y*Rij.y + Rij.z*Rij.z; R3 = R2 * sqrt(R2); a.x += -G*mass[j] * Rij.x / R3; a.y += -G*mass[j] * Rij.y / R3; a.z += -G*mass[j] * Rij.z / R3; } /* Update velocities */ V[i].x += dt * a.x; V[i].y += dt * a.y; V[i].z += dt * a.z; /* Set acceleration */ A[i].x = a.x; A[i].y = a.y; A[i].z = a.z; } for(i=0;i<N;i++) /* Update positions */ { P[i].x += dt * V[i].x; P[i].y += dt * V[i].y; P[i].z += dt * V[i].z; } if (iteration % out_every == 0) { printf("T=%03.3lg \r", t); /* Write the Data */ F5write_particle_cartesian3Dv(FileID, t*0.01, "GalaxyStars", P, N, 0, "Velocity", F5T_VEC3_FLOAT, V, "Acceleration", F5T_VEC3_FLOAT, A, "mass", H5T_NATIVE_FLOAT, mass, "weirdness", H5T_NATIVE_FLOAT, weirdness, 0); } } /* Close the File */ F5Xclose(FileID); return 0; }
1.6.2