cuda-samples/Samples/2_Concepts_and_Techniques/threadFenceReduction/threadFenceReduction.cu

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/* Copyright (c) 2022, NVIDIA CORPORATION. All rights reserved.
2021-10-21 19:04:49 +08:00
*
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/*
Parallel reduction
This sample shows how to perform a reduction operation on an array of values
to produce a single value in a single kernel (as opposed to two or more
kernel calls as shown in the "reduction" CUDA Sample). Single-pass
reduction requires global atomic instructions (Compute Capability 1.1 or
later) and the __threadfence() intrinsic (CUDA 2.2 or later).
Reductions are a very common computation in parallel algorithms. Any time
an array of values needs to be reduced to a single value using a binary
associative operator, a reduction can be used. Example applications include
statistics computations such as mean and standard deviation, and image
processing applications such as finding the total luminance of an
image.
This code performs sum reductions, but any associative operator such as
min() or max() could also be used.
It assumes the input size is a power of 2.
COMMAND LINE ARGUMENTS
"--shmoo": Test performance for 1 to 32M elements with each of the
7 different kernels
"--n=<N>": Specify the number of elements to reduce (default 1048576)
"--threads=<N>": Specify the number of threads per block (default 128)
"--maxblocks=<N>": Specify the maximum number of thread blocks to launch
(kernel 6 only, default 64)
"--cpufinal": Read back the per-block results and do final sum of block
sums on CPU (default false)
"--cputhresh=<N>": The threshold of number of blocks sums below which to
perform a CPU final reduction (default 1)
"--multipass": Use a multipass reduction instead of a single-pass reduction
*/
// includes, system
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <math.h>
// includes, project
#include <helper_functions.h>
#include <helper_cuda.h>
#define VERSION_MAJOR (CUDART_VERSION / 1000)
#define VERSION_MINOR (CUDART_VERSION % 100) / 10
const char *sSDKsample = "threadFenceReduction";
#if CUDART_VERSION >= 2020
#include "threadFenceReduction_kernel.cuh"
#else
#pragma comment(user, "CUDA 2.2 is required to build for threadFenceReduction")
#endif
////////////////////////////////////////////////////////////////////////////////
// declaration, forward
bool runTest(int argc, char **argv);
extern "C" {
void reduce(int size, int threads, int blocks, float *d_idata, float *d_odata);
void reduceSinglePass(int size, int threads, int blocks, float *d_idata,
float *d_odata);
}
#if CUDART_VERSION < 2020
void reduce(int size, int threads, int blocks, float *d_idata, float *d_odata) {
printf("reduce(), compiler not supported, aborting tests\n");
}
void reduceSinglePass(int size, int threads, int blocks, float *d_idata,
float *d_odata) {
printf("reduceSinglePass(), compiler not supported, aborting tests\n");
}
#endif
////////////////////////////////////////////////////////////////////////////////
// Program main
////////////////////////////////////////////////////////////////////////////////
int main(int argc, char **argv) {
cudaDeviceProp deviceProp;
deviceProp.major = 0;
deviceProp.minor = 0;
int dev;
printf("%s Starting...\n\n", sSDKsample);
dev = findCudaDevice(argc, (const char **)argv);
checkCudaErrors(cudaGetDeviceProperties(&deviceProp, dev));
printf("GPU Device supports SM %d.%d compute capability\n\n",
deviceProp.major, deviceProp.minor);
bool bTestResult = false;
#if CUDART_VERSION >= 2020
bTestResult = runTest(argc, argv);
#else
print_NVCC_min_spec(sSDKsample, "2.2", "Version 185");
exit(EXIT_SUCCESS);
#endif
exit(bTestResult ? EXIT_SUCCESS : EXIT_FAILURE);
}
////////////////////////////////////////////////////////////////////////////////
//! Compute sum reduction on CPU
//! We use Kahan summation for an accurate sum of large arrays.
//! http://en.wikipedia.org/wiki/Kahan_summation_algorithm
//!
//! @param data pointer to input data
//! @param size number of input data elements
////////////////////////////////////////////////////////////////////////////////
template <class T>
T reduceCPU(T *data, int size) {
T sum = data[0];
T c = (T)0.0;
for (int i = 1; i < size; i++) {
T y = data[i] - c;
T t = sum + y;
c = (t - sum) - y;
sum = t;
}
return sum;
}
unsigned int nextPow2(unsigned int x) {
--x;
x |= x >> 1;
x |= x >> 2;
x |= x >> 4;
x |= x >> 8;
x |= x >> 16;
return ++x;
}
////////////////////////////////////////////////////////////////////////////////
// Compute the number of threads and blocks to use for the reduction
// We set threads / block to the minimum of maxThreads and n/2.
////////////////////////////////////////////////////////////////////////////////
void getNumBlocksAndThreads(int n, int maxBlocks, int maxThreads, int &blocks,
int &threads) {
if (n == 1) {
threads = 1;
blocks = 1;
} else {
threads = (n < maxThreads * 2) ? nextPow2(n / 2) : maxThreads;
blocks = max(1, n / (threads * 2));
}
blocks = min(maxBlocks, blocks);
}
////////////////////////////////////////////////////////////////////////////////
// This function performs a reduction of the input data multiple times and
// measures the average reduction time.
////////////////////////////////////////////////////////////////////////////////
float benchmarkReduce(int n, int numThreads, int numBlocks, int maxThreads,
int maxBlocks, int testIterations, bool multiPass,
bool cpuFinalReduction, int cpuFinalThreshold,
StopWatchInterface *timer, float *h_odata, float *d_idata,
float *d_odata) {
float gpu_result = 0;
bool bNeedReadback = true;
cudaError_t error;
for (int i = 0; i < testIterations; ++i) {
gpu_result = 0;
unsigned int retCnt = 0;
error = setRetirementCount(retCnt);
checkCudaErrors(error);
cudaDeviceSynchronize();
sdkStartTimer(&timer);
if (multiPass) {
// execute the kernel
reduce(n, numThreads, numBlocks, d_idata, d_odata);
// check if kernel execution generated an error
getLastCudaError("Kernel execution failed");
if (cpuFinalReduction) {
// sum partial sums from each block on CPU
// copy result from device to host
error = cudaMemcpy(h_odata, d_odata, numBlocks * sizeof(float),
cudaMemcpyDeviceToHost);
checkCudaErrors(error);
for (int i = 0; i < numBlocks; i++) {
gpu_result += h_odata[i];
}
bNeedReadback = false;
} else {
// sum partial block sums on GPU
int s = numBlocks;
while (s > cpuFinalThreshold) {
int threads = 0, blocks = 0;
getNumBlocksAndThreads(s, maxBlocks, maxThreads, blocks, threads);
reduce(s, threads, blocks, d_odata, d_odata);
s = s / (threads * 2);
}
if (s > 1) {
// copy result from device to host
error = cudaMemcpy(h_odata, d_odata, s * sizeof(float),
cudaMemcpyDeviceToHost);
checkCudaErrors(error);
for (int i = 0; i < s; i++) {
gpu_result += h_odata[i];
}
bNeedReadback = false;
}
}
} else {
getLastCudaError("Kernel execution failed");
// execute the kernel
reduceSinglePass(n, numThreads, numBlocks, d_idata, d_odata);
// check if kernel execution generated an error
getLastCudaError("Kernel execution failed");
}
cudaDeviceSynchronize();
sdkStopTimer(&timer);
}
if (bNeedReadback) {
// copy final sum from device to host
error =
cudaMemcpy(&gpu_result, d_odata, sizeof(float), cudaMemcpyDeviceToHost);
checkCudaErrors(error);
}
return gpu_result;
}
////////////////////////////////////////////////////////////////////////////////
// This function calls benchmarkReduce multiple times for a range of array sizes
// and prints a report in CSV (comma-separated value) format that can be used
// for generating a "shmoo" plot showing the performance for each kernel
// variation over a wide range of input sizes.
////////////////////////////////////////////////////////////////////////////////
void shmoo(int minN, int maxN, int maxThreads, int maxBlocks) {
// create random input data on CPU
unsigned int bytes = maxN * sizeof(float);
float *h_idata = (float *)malloc(bytes);
for (int i = 0; i < maxN; i++) {
// Keep the numbers small so we don't get truncation error in the sum
h_idata[i] = (rand() & 0xFF) / (float)RAND_MAX;
}
int maxNumBlocks = min(65535, maxN / maxThreads);
// allocate mem for the result on host side
float *h_odata = (float *)malloc(maxNumBlocks * sizeof(float));
// allocate device memory and data
float *d_idata = NULL;
float *d_odata = NULL;
checkCudaErrors(cudaMalloc((void **)&d_idata, bytes));
checkCudaErrors(cudaMalloc((void **)&d_odata, maxNumBlocks * sizeof(float)));
// copy data directly to device memory
checkCudaErrors(cudaMemcpy(d_idata, h_idata, bytes, cudaMemcpyHostToDevice));
checkCudaErrors(cudaMemcpy(d_odata, h_idata, maxNumBlocks * sizeof(float),
cudaMemcpyHostToDevice));
// warm-up
reduce(maxN, maxThreads, maxNumBlocks, d_idata, d_odata);
int testIterations = 100;
StopWatchInterface *timer = NULL;
sdkCreateTimer(&timer);
// print headers
printf("N, %d blocks one pass, %d blocks multipass\n", maxBlocks, maxBlocks);
for (int i = minN; i <= maxN; i *= 2) {
printf("%d, ", i);
for (int multiPass = 0; multiPass <= 1; multiPass++) {
sdkResetTimer(&timer);
int numBlocks = 0;
int numThreads = 0;
getNumBlocksAndThreads(i, maxBlocks, maxThreads, numBlocks, numThreads);
benchmarkReduce(i, numThreads, numBlocks, maxThreads, maxBlocks,
testIterations, multiPass == 1, false, 1, timer, h_odata,
d_idata, d_odata);
float reduceTime = sdkGetAverageTimerValue(&timer);
printf("%f%s", reduceTime, multiPass == 0 ? ", " : "\n");
}
}
printf("\n");
// cleanup
sdkDeleteTimer(&timer);
free(h_idata);
free(h_odata);
cudaFree(d_idata);
cudaFree(d_odata);
}
////////////////////////////////////////////////////////////////////////////////
// The main function which runs the reduction test.
////////////////////////////////////////////////////////////////////////////////
bool runTest(int argc, char **argv) {
int size = 1 << 20; // number of elements to reduce
int maxThreads = 128; // number of threads per block
int maxBlocks = 64;
bool cpuFinalReduction = false;
int cpuFinalThreshold = 1;
bool multipass = false;
bool bTestResult = false;
if (checkCmdLineFlag(argc, (const char **)argv, "n")) {
size = getCmdLineArgumentInt(argc, (const char **)argv, "n");
}
if (checkCmdLineFlag(argc, (const char **)argv, "threads")) {
maxThreads = getCmdLineArgumentInt(argc, (const char **)argv, "threads");
}
if (checkCmdLineFlag(argc, (const char **)argv, "maxblocks")) {
maxBlocks = getCmdLineArgumentInt(argc, (const char **)argv, "maxblocks");
}
printf("%d elements\n", size);
printf("%d threads (max)\n", maxThreads);
cpuFinalReduction = checkCmdLineFlag(argc, (const char **)argv, "cpufinal");
multipass = checkCmdLineFlag(argc, (const char **)argv, "multipass");
if (checkCmdLineFlag(argc, (const char **)argv, "cputhresh")) {
cpuFinalThreshold =
getCmdLineArgumentInt(argc, (const char **)argv, "cputhresh");
}
bool runShmoo = checkCmdLineFlag(argc, (const char **)argv, "shmoo");
if (runShmoo) {
shmoo(1, 33554432, maxThreads, maxBlocks);
} else {
// create random input data on CPU
unsigned int bytes = size * sizeof(float);
float *h_idata = (float *)malloc(bytes);
for (int i = 0; i < size; i++) {
// Keep the numbers small so we don't get truncation error in the sum
h_idata[i] = (rand() & 0xFF) / (float)RAND_MAX;
}
int numBlocks = 0;
int numThreads = 0;
getNumBlocksAndThreads(size, maxBlocks, maxThreads, numBlocks, numThreads);
if (numBlocks == 1) {
cpuFinalThreshold = 1;
}
// allocate mem for the result on host side
float *h_odata = (float *)malloc(numBlocks * sizeof(float));
printf("%d blocks\n", numBlocks);
// allocate device memory and data
float *d_idata = NULL;
float *d_odata = NULL;
checkCudaErrors(cudaMalloc((void **)&d_idata, bytes));
checkCudaErrors(cudaMalloc((void **)&d_odata, numBlocks * sizeof(float)));
// copy data directly to device memory
checkCudaErrors(
cudaMemcpy(d_idata, h_idata, bytes, cudaMemcpyHostToDevice));
checkCudaErrors(cudaMemcpy(d_odata, h_idata, numBlocks * sizeof(float),
cudaMemcpyHostToDevice));
// warm-up
reduce(size, numThreads, numBlocks, d_idata, d_odata);
int testIterations = 100;
StopWatchInterface *timer = 0;
sdkCreateTimer(&timer);
float gpu_result = 0;
gpu_result =
benchmarkReduce(size, numThreads, numBlocks, maxThreads, maxBlocks,
testIterations, multipass, cpuFinalReduction,
cpuFinalThreshold, timer, h_odata, d_idata, d_odata);
float reduceTime = sdkGetAverageTimerValue(&timer);
printf("Average time: %f ms\n", reduceTime);
printf("Bandwidth: %f GB/s\n\n",
(size * sizeof(int)) / (reduceTime * 1.0e6));
// compute reference solution
float cpu_result = reduceCPU<float>(h_idata, size);
printf("GPU result = %0.12f\n", gpu_result);
printf("CPU result = %0.12f\n", cpu_result);
double threshold = 1e-8 * size;
double diff = abs((double)gpu_result - (double)cpu_result);
bTestResult = (diff < threshold);
// cleanup
sdkDeleteTimer(&timer);
free(h_idata);
free(h_odata);
cudaFree(d_idata);
cudaFree(d_odata);
}
return bTestResult;
}