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pulp_data.cpp
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#include <mpi.h>
#include <omp.h>
#include <stdint.h>
#include <stdlib.h>
#include "pulp_data.h"
#include "util.h"
extern int procid, nprocs;
extern bool verbose, debug, verify;
void init_thread_pulp(thread_pulp_t* tp, pulp_data_t* pulp) {
// if (debug) printf("Task %d init_thread_pulp() start\n", procid);
tp->part_counts = (double*)malloc(pulp->num_parts * sizeof(double));
tp->part_weights = (double*)malloc(pulp->num_parts * sizeof(double));
tp->part_edge_weights = (double*)malloc(pulp->num_parts * sizeof(double));
tp->part_cut_weights = (double*)malloc(pulp->num_parts * sizeof(double));
// if (debug) printf("Task %d init_thread_pulp() success\n", procid);
}
void clear_thread_pulp(thread_pulp_t* tp) {
// if (debug) printf("Task %d clear_thread_pulp() start\n", procid);
free(tp->part_counts);
free(tp->part_weights);
free(tp->part_edge_weights);
free(tp->part_cut_weights);
// if (debug) printf("Task %d clear_thread_pulp() success\n", procid);
}
void init_pulp_data(dist_graph_t* g, pulp_data_t* pulp, int32_t num_parts) {
if (debug) printf("Task %d init_pulp_data() start\n", procid);
pulp->num_parts = num_parts;
if (g->edge_weights == NULL && g->vertex_weights == NULL)
pulp->avg_size = (double)g->n / (double)pulp->num_parts;
else
pulp->avg_size = (double)g->vertex_weights_sum / (double)pulp->num_parts;
pulp->avg_edge_size = (double)g->m * 2 / (double)pulp->num_parts;
pulp->avg_cut_size = 0.0;
pulp->max_v = 0.0;
pulp->max_e = 1.0;
pulp->max_c = 1.0;
pulp->weight_exponent_e = 1.0;
pulp->weight_exponent_c = 1.0;
pulp->running_max_v = 1.0;
pulp->running_max_e = 1.0;
pulp->running_max_c = 1.0;
pulp->local_parts = (int32_t*)malloc(g->n_total * sizeof(int32_t));
pulp->part_sizes = (int64_t*)malloc(pulp->num_parts * sizeof(int64_t));
pulp->part_edge_sizes = (int64_t*)malloc(pulp->num_parts * sizeof(int64_t));
pulp->part_cut_sizes = (int64_t*)malloc(pulp->num_parts * sizeof(int64_t));
pulp->part_size_changes = (int64_t*)malloc(pulp->num_parts * sizeof(int64_t));
pulp->part_edge_size_changes =
(int64_t*)malloc(pulp->num_parts * sizeof(int64_t));
pulp->part_cut_size_changes =
(int64_t*)malloc(pulp->num_parts * sizeof(int64_t));
if (pulp->local_parts == NULL || pulp->part_sizes == NULL ||
pulp->part_edge_sizes == NULL || pulp->part_cut_sizes == NULL ||
pulp->part_size_changes == NULL || pulp->part_edge_size_changes == NULL ||
pulp->part_cut_size_changes == NULL)
throw_err("init_pulp_data(), unable to allocate resources", procid);
pulp->cut_size = 0;
pulp->max_cut = 0;
pulp->cut_size_change = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p) pulp->part_sizes[p] = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p) pulp->part_edge_sizes[p] = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p) pulp->part_cut_sizes[p] = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p) pulp->part_size_changes[p] = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p)
pulp->part_edge_size_changes[p] = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p)
pulp->part_cut_size_changes[p] = 0;
if (debug) printf("Task %d init_pulp_data() success\n", procid);
}
void update_pulp_data(dist_graph_t* g, pulp_data_t* pulp) {
for (int32_t p = 0; p < pulp->num_parts; ++p) {
pulp->part_sizes[p] = 0;
pulp->part_edge_sizes[p] = 0;
pulp->part_cut_sizes[p] = 0;
pulp->part_size_changes[p] = 0;
pulp->part_edge_size_changes[p] = 0;
pulp->part_cut_size_changes[p] = 0;
}
pulp->cut_size = 0;
for (uint64_t i = 0; i < g->n_local; ++i) {
uint64_t vert_index = i;
int32_t part = pulp->local_parts[vert_index];
++pulp->part_sizes[part];
uint64_t out_degree = out_degree(g, vert_index);
uint64_t* outs = out_vertices(g, vert_index);
pulp->part_edge_sizes[part] += (int64_t)out_degree;
for (uint64_t j = 0; j < out_degree; ++j) {
uint64_t out_index = outs[j];
int32_t part_out = pulp->local_parts[out_index];
if (part_out != part) {
++pulp->part_cut_sizes[part];
++pulp->cut_size;
}
}
}
MPI_Allreduce(MPI_IN_PLACE, pulp->part_sizes, pulp->num_parts, MPI_INT64_T,
MPI_SUM, MPI_COMM_WORLD);
MPI_Allreduce(MPI_IN_PLACE, pulp->part_edge_sizes, pulp->num_parts,
MPI_INT64_T, MPI_SUM, MPI_COMM_WORLD);
MPI_Allreduce(MPI_IN_PLACE, pulp->part_cut_sizes, pulp->num_parts,
MPI_INT64_T, MPI_SUM, MPI_COMM_WORLD);
MPI_Allreduce(MPI_IN_PLACE, &pulp->cut_size, 1, MPI_INT64_T, MPI_SUM,
MPI_COMM_WORLD);
pulp->cut_size /= 2;
pulp->avg_cut_size = (double)pulp->cut_size / (double)pulp->num_parts;
pulp->max_v = 0;
pulp->max_e = 0;
pulp->max_c = 0;
pulp->max_cut = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p) {
if ((double)pulp->part_sizes[p] / pulp->avg_size > pulp->max_v)
pulp->max_v = (double)pulp->part_sizes[p] / pulp->avg_size;
if ((double)pulp->part_edge_sizes[p] / pulp->avg_edge_size > pulp->max_e)
pulp->max_e = (double)pulp->part_edge_sizes[p] / pulp->avg_edge_size;
if ((double)pulp->part_cut_sizes[p] / pulp->avg_cut_size > pulp->max_c)
pulp->max_c = (double)pulp->part_cut_sizes[p] / pulp->avg_cut_size;
if (pulp->part_cut_sizes[p] > pulp->max_cut)
pulp->max_cut = pulp->part_cut_sizes[p];
}
}
void update_pulp_data_weighted(dist_graph_t* g, pulp_data_t* pulp) {
bool has_vwgts = (g->vertex_weights != NULL);
bool has_ewgts = (g->edge_weights != NULL);
for (int32_t p = 0; p < pulp->num_parts; ++p) {
pulp->part_sizes[p] = 0;
pulp->part_edge_sizes[p] = 0;
pulp->part_cut_sizes[p] = 0;
pulp->part_size_changes[p] = 0;
pulp->part_edge_size_changes[p] = 0;
pulp->part_cut_size_changes[p] = 0;
}
pulp->cut_size = 0;
for (uint64_t i = 0; i < g->n_local; ++i) {
uint64_t vert_index = i;
int32_t part = pulp->local_parts[vert_index];
if (has_vwgts)
pulp->part_sizes[part] += g->vertex_weights[vert_index];
else
++pulp->part_sizes[part];
uint64_t out_degree = out_degree(g, vert_index);
uint64_t* outs = out_vertices(g, vert_index);
int32_t* weights = out_weights(g, vert_index);
pulp->part_edge_sizes[part] += (int64_t)out_degree;
for (uint64_t j = 0; j < out_degree; ++j) {
uint64_t out_index = outs[j];
int32_t part_out = pulp->local_parts[out_index];
if (part_out != part) {
if (has_ewgts) {
pulp->part_cut_sizes[part] += weights[j];
pulp->cut_size += weights[j];
} else {
++pulp->part_cut_sizes[part];
++pulp->cut_size;
}
}
}
}
MPI_Allreduce(MPI_IN_PLACE, pulp->part_sizes, pulp->num_parts, MPI_INT64_T,
MPI_SUM, MPI_COMM_WORLD);
MPI_Allreduce(MPI_IN_PLACE, pulp->part_edge_sizes, pulp->num_parts,
MPI_INT64_T, MPI_SUM, MPI_COMM_WORLD);
MPI_Allreduce(MPI_IN_PLACE, pulp->part_cut_sizes, pulp->num_parts,
MPI_INT64_T, MPI_SUM, MPI_COMM_WORLD);
MPI_Allreduce(MPI_IN_PLACE, &pulp->cut_size, 1, MPI_INT64_T, MPI_SUM,
MPI_COMM_WORLD);
pulp->cut_size /= 2;
pulp->avg_cut_size = (double)pulp->cut_size / (double)pulp->num_parts;
pulp->max_v = 0;
pulp->max_e = 0;
pulp->max_c = 0;
pulp->max_cut = 0;
for (int32_t p = 0; p < pulp->num_parts; ++p) {
if ((double)pulp->part_sizes[p] / pulp->avg_size > pulp->max_v)
pulp->max_v = (double)pulp->part_sizes[p] / pulp->avg_size;
if ((double)pulp->part_edge_sizes[p] / pulp->avg_edge_size > pulp->max_e)
pulp->max_e = (double)pulp->part_edge_sizes[p] / pulp->avg_edge_size;
if ((double)pulp->part_cut_sizes[p] / pulp->avg_cut_size > pulp->max_c)
pulp->max_c = (double)pulp->part_cut_sizes[p] / pulp->avg_cut_size;
if (pulp->part_cut_sizes[p] > pulp->max_cut)
pulp->max_cut = pulp->part_cut_sizes[p];
}
}
void clear_pulp_data(pulp_data_t* pulp) {
if (debug) printf("Task %d clear_pulp_data() start\n", procid);
free(pulp->local_parts);
free(pulp->part_sizes);
free(pulp->part_edge_sizes);
free(pulp->part_cut_sizes);
free(pulp->part_size_changes);
free(pulp->part_edge_size_changes);
free(pulp->part_cut_size_changes);
if (debug) printf("Task %d clear_pulp_data() success\n", procid);
}