diff options
-rw-r--r-- | lib/cluster.h | 12 | ||||
-rw-r--r-- | lib/correlation.h | 14 | ||||
-rw-r--r-- | lib/measure.h | 4 | ||||
-rw-r--r-- | lib/state.h | 16 | ||||
-rw-r--r-- | lib/vector.h | 24 | ||||
-rw-r--r-- | src/wolff_On.cpp | 48 |
6 files changed, 78 insertions, 40 deletions
diff --git a/lib/cluster.h b/lib/cluster.h index 8061d34..2225e2f 100644 --- a/lib/cluster.h +++ b/lib/cluster.h @@ -94,12 +94,15 @@ void flip_cluster(state_t <R_t, X_t> *state, v_t v0, R_t r, gsl_rng *rand) { if (is_ext) { X_t rs_old, rs_new; + v_t non_ghost; if (vn == state->nv) { rs_old = act_inverse (R_old, si_old); rs_new = act_inverse (R_old, si_new); + non_ghost = v; } else { rs_old = act_inverse (R_old, sj); rs_new = act_inverse (R_new, sj); + non_ghost = vn; } double dE = state->H(rs_old) - state->H(rs_new); prob = 1.0 - exp(-dE / state->T); @@ -108,6 +111,15 @@ void flip_cluster(state_t <R_t, X_t> *state, v_t v0, R_t r, gsl_rng *rand) { add (&(state->M), rs_new); state->E += dE; + for (D_t i = 0; i < state->D; i++) { + double x = (double)((non_ghost / (v_t)pow(state->L, state->D - i - 1)) % state->L) / (double)state->L; + scalar_subtract(&(state->ReF[i]), cos(2 * M_PI * x), rs_old); + scalar_add(&(state->ReF[i]), cos(2 * M_PI * x), rs_new); + + scalar_subtract(&(state->ImF[i]), sin(2 * M_PI * x), rs_old); + scalar_add(&(state->ImF[i]), sin(2 * M_PI * x), rs_new); + } + free_spin (rs_old); free_spin (rs_new); } else { diff --git a/lib/correlation.h b/lib/correlation.h index b3b7d86..26c3a99 100644 --- a/lib/correlation.h +++ b/lib/correlation.h @@ -7,15 +7,13 @@ #include <fftw3.h> template <class R_t, class X_t> -double correlation_length(const state_t <R_t, X_t> *s, fftw_plan plan, double *in, double *out) { - for (v_t i = 0; i < s->nv; i++) { - in[i] = correlation_component(s->spins[i]); - } - - fftw_execute(plan); +double correlation_length(const state_t <R_t, X_t> *s) { + double total = 0; - double length = pow(out[0], 2); + for (D_t j = 0; j < s->D; j++) { + total += norm_squared(s->ReF[j]) + norm_squared(s->ImF[j]); + } - return length; + return total / s->D; } diff --git a/lib/measure.h b/lib/measure.h index 3474684..d20c081 100644 --- a/lib/measure.h +++ b/lib/measure.h @@ -36,9 +36,9 @@ std::function <void(const state_t <R_t, X_t> *)> measurement_magnetization_file( } template <class R_t, class X_t> -std::function <void(const state_t <R_t, X_t> *)> measurement_fourier_file(FILE *file, fftw_plan plan, double *fftw_in, double *fftw_out) { +std::function <void(const state_t <R_t, X_t> *)> measurement_fourier_file(FILE *file) { return [=](const state_t <R_t, X_t> *s) { - float smaller_X = (float)correlation_length(s, plan, fftw_in, fftw_out); + float smaller_X = (float)correlation_length(s); fwrite(&smaller_X, sizeof(float), 1, file); }; } diff --git a/lib/state.h b/lib/state.h index 1491938..c70459f 100644 --- a/lib/state.h +++ b/lib/state.h @@ -20,6 +20,8 @@ class state_t { double E; X_t M; // the "sum" of the spins, like the total magnetization v_t last_cluster_size; + X_t *ReF; + X_t *ImF; std::function <double(X_t, X_t)> J; std::function <double(X_t)> H; @@ -36,8 +38,14 @@ class state_t { } init (&R); E = - (double)ne * J(spins[0], spins[0]) - (double)nv * H(spins[0]); - M = scalar_multiple (nv, spins[0]); + M = scalar_multiple(nv, spins[0]); last_cluster_size = 0; + ReF = (X_t *)malloc(D * sizeof(X_t)); + ImF = (X_t *)malloc(D * sizeof(X_t)); + for (D_t i = 0; i < D; i++) { + ReF[i] = scalar_multiple(0, spins[0]); + ImF[i] = scalar_multiple(0, spins[0]); + } } ~state_t() { @@ -48,6 +56,12 @@ class state_t { free(spins); free_spin(R); free_spin(M); + for (D_t i = 0; i < D; i++) { + free_spin(ReF[i]); + free_spin(ImF[i]); + } + free(ReF); + free(ImF); } }; diff --git a/lib/vector.h b/lib/vector.h index 2099d28..a1084e2 100644 --- a/lib/vector.h +++ b/lib/vector.h @@ -37,6 +37,20 @@ void add (vector_t <q, T> *v1, vector_t <q, T> v2) { } template <q_t q, class T> +void scalar_add (vector_t <q, T> *v1, T a, vector_t <q, T> v2) { + for (q_t i = 0; i < q; i++) { + v1->x[i] += a * v2.x[i]; + } +} + +template <q_t q, class T> +void scalar_subtract (vector_t <q, T> *v1, T a, vector_t <q, T> v2) { + for (q_t i = 0; i < q; i++) { + v1->x[i] -= a * v2.x[i]; + } +} + +template <q_t q, class T> void subtract (vector_t <q, T> *v1, vector_t <q, T> v2) { for (q_t i = 0; i < q; i++) { v1->x[i] -= v2.x[i]; @@ -44,6 +58,16 @@ void subtract (vector_t <q, T> *v1, vector_t <q, T> v2) { } template <q_t q, class T> +T norm_squared (vector_t <q, T> v) { + T tmp = 0; + for (q_t i = 0; i < q; i++) { + tmp += v.x[i] * v.x[i]; + } + + return tmp; +} + +template <q_t q, class T> vector_t <q, T> scalar_multiple(v_t a, vector_t <q, T> v) { vector_t <q, T> multiple; multiple.x = (T *)malloc(q * sizeof(T)); diff --git a/src/wolff_On.cpp b/src/wolff_On.cpp index 329f468..d718440 100644 --- a/src/wolff_On.cpp +++ b/src/wolff_On.cpp @@ -115,24 +115,33 @@ int main(int argc, char *argv[]) { FILE *outfile_info = fopen("wolff_metadata.txt", "a"); - fprintf(outfile_info, "<| \"ID\" -> %lu, \"MODEL\" -> \"%s\", \"q\" -> %d, \"D\" -> %" PRID ", \"L\" -> %" PRIL ", \"NV\" -> %" PRIv ", \"NE\" -> %" PRIv ", \"T\" -> %.15f, \"H\" -> {", timestamp, ON_strings[N_COMP], N_COMP, D, L, pow(L, D), D * pow(L, D), T); - - for (q_t i = 0; i < N_COMP; i++) { - fprintf(outfile_info, "%.15f", H_vec[i]); - if (i < N_COMP - 1) { - fprintf(outfile_info, ", "); + fprintf(outfile_info, "<| \"ID\" -> %lu, \"MODEL\" -> \"%s\", \"q\" -> %d, \"D\" -> %" PRID ", \"L\" -> %" PRIL ", \"NV\" -> %" PRIv ", \"NE\" -> %" PRIv ", \"T\" -> %.15f, \"FIELD_TYPE\" -> ", timestamp, ON_strings[N_COMP], N_COMP, D, L, (v_t)pow(L, D), D * (v_t)pow(L, D), T); + if (modulated_field) { + fprintf(outfile_info, "\"MODULATED\", \"ORDER\" -> %d, \"H\" -> %.15f, ", order, H_vec[0]); + } else { + fprintf(outfile_info, "\"VECTOR\", \"H\" -> {"); + for (q_t i = 0; i < N_COMP; i++) { + fprintf(outfile_info, "%.15f", H_vec[i]); + if (i < N_COMP - 1) { + fprintf(outfile_info, ", "); + } } + fprintf(outfile_info, "}, "); } - fprintf(outfile_info, "}, \"GENERATOR\" -> \"%s\", \"EPS\" -> %g |>\n", pert_type, epsilon); + fprintf(outfile_info, "\"GENERATOR\" -> \"%s\"", pert_type); + + if (use_pert) { + fprintf(outfile_info, ", \"EPS\" -> %g", epsilon); + } + + fprintf(outfile_info, " |>\n"); fclose(outfile_info); unsigned int n_measurements = 0; std::function <void(const On_t *)> *measurements = (std::function <void(const On_t *)> *)calloc(POSSIBLE_MEASUREMENTS, sizeof(std::function <void(const On_t *)>)); FILE *outfile_M, *outfile_E, *outfile_S, *outfile_F; - double *fftw_in, *fftw_out; - fftw_plan plan; if (measurement_flags & measurement_energy) { char *filename_E = (char *)malloc(255 * sizeof(char)); @@ -166,22 +175,7 @@ int main(int argc, char *argv[]) { sprintf(filename_F, "wolff_%lu_F.dat", timestamp); outfile_F = fopen(filename_F, "wb"); free(filename_F); - - fftw_in = (double *)fftw_malloc(pow(L, D) * sizeof(double)); - fftw_out = (double *)fftw_malloc(pow(L, D) * sizeof(double)); - int rank = D; - int *n = (int *)malloc(rank * sizeof(int)); - fftw_r2r_kind *kind = (fftw_r2r_kind *)malloc(rank * sizeof(fftw_r2r_kind)); - for (D_t i = 0; i < rank; i++) { - n[i] = L; - kind[i] = FFTW_R2HC; - } - plan = fftw_plan_r2r(rank, n, fftw_in, fftw_out, kind, 0); - - free(n); - free(kind); - - measurements[n_measurements] = measurement_fourier_file<orthogonal_R_t, vector_R_t> (outfile_F, plan, fftw_in, fftw_out); + measurements[n_measurements] = measurement_fourier_file<orthogonal_R_t, vector_R_t> (outfile_F); n_measurements++; } @@ -208,10 +202,6 @@ int main(int argc, char *argv[]) { } if (measurement_flags & measurement_fourierZero) { fclose(outfile_F); - fftw_destroy_plan(plan); - fftw_free(fftw_in); - fftw_free(fftw_out); - fftw_cleanup(); // fftw is only used if fourier modes are measured! } free(H_vec); |