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cc.cu
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cc.cu
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/* References:
*
* Hong, Sungpack, et al.
* "Accelerating CUDA graph algorithms at maximum warp."
* Acm Sigplan Notices 46.8 (2011): 267-276.
*
* Zhen Xu, Xuhao Chen, Jie Shen, Yang Zhang, Cheng Chen, Canqun Yang,
* GARDENIA: A Domain-specific Benchmark Suite for Next-generation Accelerators,
* ACM Journal on Emerging Technologies in Computing Systems, 2018.
*
*/
#include "helper_emogi.h"
#define MEM_ALIGN MEM_ALIGN_64
typedef uint64_t EdgeT;
__global__ void kernel_coalesce(bool *curr_visit, bool *next_visit, uint64_t vertex_count, uint64_t *vertexList, EdgeT *edgeList, unsigned long long *comp, bool *changed) {
const uint64_t tid = blockDim.x * BLOCK_SIZE * blockIdx.y + blockDim.x * blockIdx.x + threadIdx.x;
const uint64_t warpIdx = tid >> WARP_SHIFT;
const uint64_t laneIdx = tid & ((1 << WARP_SHIFT) - 1);
if (warpIdx < vertex_count && curr_visit[warpIdx] == true) {
const uint64_t start = vertexList[warpIdx];
const uint64_t shift_start = start & MEM_ALIGN;
const uint64_t end = vertexList[warpIdx+1];
for(uint64_t i = shift_start + laneIdx; i < end; i += WARP_SIZE) {
if (i >= start) {
unsigned long long comp_src = comp[warpIdx];
const EdgeT next = edgeList[i];
unsigned long long comp_next = comp[next];
unsigned long long comp_target;
EdgeT next_target;
if (comp_next != comp_src) {
if (comp_src < comp_next) {
next_target = next;
comp_target = comp_src;
}
else {
next_target = warpIdx;
comp_target = comp_next;
}
atomicMin(&comp[next_target], comp_target);
next_visit[next_target] = true;
*changed = true;
}
}
}
}
}
__global__ void kernel_coalesce_chunk(bool *curr_visit, bool *next_visit, uint64_t vertex_count, uint64_t *vertexList, EdgeT *edgeList, unsigned long long *comp, bool *changed) {
const uint64_t tid = blockDim.x * BLOCK_SIZE * blockIdx.y + blockDim.x * blockIdx.x + threadIdx.x;
const uint64_t warpIdx = tid >> WARP_SHIFT;
const uint64_t laneIdx = tid & ((1 << WARP_SHIFT) - 1);
const uint64_t chunkIdx = warpIdx * CHUNK_SIZE;
uint64_t chunk_size = CHUNK_SIZE;
if((chunkIdx + CHUNK_SIZE) > vertex_count) {
if ( vertex_count > chunkIdx )
chunk_size = vertex_count - chunkIdx;
else
return;
}
for(uint32_t i = chunkIdx; i < chunk_size + chunkIdx; i++) {
if(curr_visit[i]) {
const uint64_t start = vertexList[i];
const uint64_t shift_start = start & MEM_ALIGN;
const uint64_t end = vertexList[i+1];
for(uint64_t j = shift_start + laneIdx; j < end; j += WARP_SIZE) {
if (j >= start) {
unsigned long long comp_src = comp[i];
const EdgeT next = edgeList[j];
unsigned long long comp_next = comp[next];
unsigned long long comp_target;
EdgeT next_target;
if (comp_next != comp_src) {
if (comp_src < comp_next) {
next_target = next;
comp_target = comp_src;
}
else {
next_target = i;
comp_target = comp_next;
}
atomicMin(&comp[next_target], comp_target);
next_visit[next_target] = true;
*changed = true;
}
}
}
}
}
}
int main(int argc, char *argv[]) {
std::ifstream file;
std::string vertex_file, edge_file;
std::string filename;
bool changed_h, *changed_d;
bool *curr_visit_d, *next_visit_d, *comp_check;
int c, arg_num = 0, device = 0;
impl_type type;
mem_type mem;
uint32_t iter, comp_total = 0;
unsigned long long *comp_d, *comp_h;
uint64_t *vertexList_h, *vertexList_d;
EdgeT *edgeList_h, *edgeList_d;
uint64_t vertex_count, edge_count, vertex_size, edge_size;
uint64_t typeT;
uint64_t numblocks, numthreads;
float milliseconds;
cudaEvent_t start, end;
while ((c = getopt(argc, argv, "f:t:m:d:h")) != -1) {
switch (c) {
case 'f':
filename = optarg;
arg_num++;
break;
case 't':
type = (impl_type)atoi(optarg);
arg_num++;
break;
case 'm':
mem = (mem_type)atoi(optarg);
arg_num++;
break;
case 'd':
device = atoi(optarg);
break;
case 'h':
printf("8-byte edge CC, only works correctly with undirected graphs\n");
printf("\t-f | input file name (must end with .bel)\n");
printf("\t-t | type of CC to run\n");
printf("\t | COALESCE = 1, COALESCE_CHUNK = 2\n");
printf("\t-m | memory allocation\n");
printf("\t | GPUMEM = 0, UVM_READONLY = 1, UVM_DIRECT = 2\n");
printf("\t-h | help message\n");
return 0;
case '?':
break;
default:
break;
}
}
if (arg_num < 3) {
printf("8-byte edge CC, only works correctly with undirected graphs\n");
printf("\t-f | input file name (must end with .bel)\n");
printf("\t-t | type of CC to run\n");
printf("\t | COALESCE = 1, COALESCE_CHUNK = 2\n");
printf("\t-m | memory allocation\n");
printf("\t | GPUMEM = 0, UVM_READONLY = 1, UVM_DIRECT = 2\n");
printf("\t-h | help message\n");
return 0;
}
checkCudaErrors(cudaEventCreate(&start));
checkCudaErrors(cudaEventCreate(&end));
vertex_file = filename + ".col";
edge_file = filename + ".dst";
std::cout << filename << std::endl;
// Read files
file.open(vertex_file.c_str(), std::ios::in | std::ios::binary);
if (!file.is_open()) {
printf("vertex file open failed\n");
exit(1);
}
file.read((char*)(&vertex_count), 8);
file.read((char*)(&typeT), 8);
vertex_count--;
printf("Vertex: %lu, ", vertex_count);
vertex_size = (vertex_count+1) * sizeof(uint64_t);
vertexList_h = (uint64_t*)malloc(vertex_size);
file.read((char*)vertexList_h, vertex_size);
file.close();
file.open(edge_file.c_str(), std::ios::in | std::ios::binary);
if (!file.is_open()) {
printf("edge file open failed\n");
exit(1);
}
file.read((char*)(&edge_count), 8);
file.read((char*)(&typeT), 8);
printf("Edge: %lu\n", edge_count);
fflush(stdout);
edge_size = edge_count * sizeof(EdgeT);
edgeList_h = NULL;
switch (mem) {
case GPUMEM:
edgeList_h = (EdgeT*)malloc(edge_size);
file.read((char*)edgeList_h, edge_size);
checkCudaErrors(cudaMalloc((void**)&edgeList_d, edge_size));
break;
case UVM_READONLY:
checkCudaErrors(cudaMallocManaged((void**)&edgeList_d, edge_size));
file.read((char*)edgeList_d, edge_size);
checkCudaErrors(cudaMemAdvise(edgeList_d, edge_size, cudaMemAdviseSetReadMostly, device));
break;
case UVM_DIRECT:
checkCudaErrors(cudaMallocManaged((void**)&edgeList_d, edge_size));
file.read((char*)edgeList_d, edge_size);
checkCudaErrors(cudaMemAdvise(edgeList_d, edge_size, cudaMemAdviseSetAccessedBy, device));
break;
}
file.close();
// Allocate memory for GPU
comp_h = (unsigned long long*)malloc(vertex_count * sizeof(unsigned long long));
comp_check = (bool*)malloc(vertex_count * sizeof(bool));
checkCudaErrors(cudaMalloc((void**)&vertexList_d, vertex_size));
checkCudaErrors(cudaMalloc((void**)&curr_visit_d, vertex_count * sizeof(bool)));
checkCudaErrors(cudaMalloc((void**)&next_visit_d, vertex_count * sizeof(bool)));
checkCudaErrors(cudaMalloc((void**)&comp_d, vertex_count * sizeof(unsigned long long)));
checkCudaErrors(cudaMalloc((void**)&changed_d, sizeof(bool)));
printf("Allocation finished\n");
fflush(stdout);
// Initialize values
for (uint64_t i = 0; i < vertex_count; i++)
comp_h[i] = i;
memset(comp_check, 0, vertex_count * sizeof(bool));
checkCudaErrors(cudaMemset(curr_visit_d, 0x01, vertex_count * sizeof(bool)));
checkCudaErrors(cudaMemset(next_visit_d, 0x00, vertex_count * sizeof(bool)));
checkCudaErrors(cudaMemcpy(comp_d, comp_h, vertex_count * sizeof(uint64_t), cudaMemcpyHostToDevice));
checkCudaErrors(cudaMemcpy(vertexList_d, vertexList_h, vertex_size, cudaMemcpyHostToDevice));
if (mem == GPUMEM)
checkCudaErrors(cudaMemcpy(edgeList_d, edgeList_h, edge_size, cudaMemcpyHostToDevice));
numthreads = BLOCK_SIZE;
switch (type) {
case COALESCE:
numblocks = ((vertex_count * WARP_SIZE + numthreads) / numthreads);
break;
case COALESCE_CHUNK:
numblocks = ((vertex_count * (WARP_SIZE / CHUNK_SIZE) + numthreads) / numthreads);
break;
default:
fprintf(stderr, "Invalid type\n");
exit(1);
break;
}
dim3 blockDim(BLOCK_SIZE, (numblocks+BLOCK_SIZE)/BLOCK_SIZE);
printf("Initialization done\n");
fflush(stdout);
iter = 0;
checkCudaErrors(cudaEventRecord(start, 0));
// Run CC
do {
changed_h = false;
checkCudaErrors(cudaMemcpy(changed_d, &changed_h, sizeof(bool), cudaMemcpyHostToDevice));
switch (type) {
case COALESCE:
kernel_coalesce<<<blockDim, numthreads>>>(curr_visit_d, next_visit_d, vertex_count, vertexList_d, edgeList_d, comp_d, changed_d);
break;
case COALESCE_CHUNK:
kernel_coalesce_chunk<<<blockDim, numthreads>>>(curr_visit_d, next_visit_d, vertex_count, vertexList_d, edgeList_d, comp_d, changed_d);
break;
default:
fprintf(stderr, "Invalid type\n");
exit(1);
break;
}
checkCudaErrors(cudaMemset(curr_visit_d, 0x00, vertex_count * sizeof(bool)));
bool *temp = curr_visit_d;
curr_visit_d = next_visit_d;
next_visit_d = temp;
iter++;
checkCudaErrors(cudaMemcpy(&changed_h, changed_d, sizeof(bool), cudaMemcpyDeviceToHost));
} while(changed_h);
checkCudaErrors(cudaEventRecord(end, 0));
checkCudaErrors(cudaEventSynchronize(end));
checkCudaErrors(cudaEventElapsedTime(&milliseconds, start, end));
checkCudaErrors(cudaMemcpy(comp_h, comp_d, vertex_count * sizeof(unsigned long long), cudaMemcpyDeviceToHost));
for (uint64_t i = 0; i < vertex_count; i++) {
if (comp_check[comp_h[i]] == false) {
comp_check[comp_h[i]] = true;
comp_total++;
}
}
printf("total iterations: %u\n", iter);
printf("total components: %u\n", comp_total);
printf("total time: %f ms\n", milliseconds);
fflush(stdout);
free(vertexList_h);
if (edgeList_h)
free(edgeList_h);
free(comp_check);
free(comp_h);
checkCudaErrors(cudaFree(vertexList_d));
checkCudaErrors(cudaFree(edgeList_d));
checkCudaErrors(cudaFree(changed_d));
checkCudaErrors(cudaFree(comp_d));
checkCudaErrors(cudaFree(curr_visit_d));
checkCudaErrors(cudaFree(next_visit_d));
return 0;
}