/* Copyright (c) 2019, NVIDIA CORPORATION. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of NVIDIA CORPORATION nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * This is a simple test program to measure the memcopy bandwidth of the GPU. * It can measure device to device copy bandwidth, host to device copy bandwidth * for pageable and pinned memory, and device to host copy bandwidth for * pageable and pinned memory. * * Usage: * ./bandwidthTest [option]... */ // CUDA runtime #include // includes #include // helper functions for CUDA error checking and initialization #include // helper for shared functions common to CUDA Samples #include #include #include #include static const char *sSDKsample = "CUDA Bandwidth Test"; // defines, project #define MEMCOPY_ITERATIONS 100 #define DEFAULT_SIZE (32 * (1e6)) // 32 M #define DEFAULT_INCREMENT (4 * (1e6)) // 4 M #define CACHE_CLEAR_SIZE (16 * (1e6)) // 16 M // shmoo mode defines #define SHMOO_MEMSIZE_MAX (64 * (1e6)) // 64 M #define SHMOO_MEMSIZE_START (1e3) // 1 KB #define SHMOO_INCREMENT_1KB (1e3) // 1 KB #define SHMOO_INCREMENT_2KB (2 * 1e3) // 2 KB #define SHMOO_INCREMENT_10KB (10 * (1e3)) // 10KB #define SHMOO_INCREMENT_100KB (100 * (1e3)) // 100 KB #define SHMOO_INCREMENT_1MB (1e6) // 1 MB #define SHMOO_INCREMENT_2MB (2 * 1e6) // 2 MB #define SHMOO_INCREMENT_4MB (4 * 1e6) // 4 MB #define SHMOO_LIMIT_20KB (20 * (1e3)) // 20 KB #define SHMOO_LIMIT_50KB (50 * (1e3)) // 50 KB #define SHMOO_LIMIT_100KB (100 * (1e3)) // 100 KB #define SHMOO_LIMIT_1MB (1e6) // 1 MB #define SHMOO_LIMIT_16MB (16 * 1e6) // 16 MB #define SHMOO_LIMIT_32MB (32 * 1e6) // 32 MB // CPU cache flush #define FLUSH_SIZE (256 * 1024 * 1024) char *flush_buf; // enums, project enum testMode { QUICK_MODE, RANGE_MODE, SHMOO_MODE }; enum memcpyKind { DEVICE_TO_HOST, HOST_TO_DEVICE, DEVICE_TO_DEVICE }; enum printMode { USER_READABLE, CSV }; enum memoryMode { PINNED, PAGEABLE }; const char *sMemoryCopyKind[] = {"Device to Host", "Host to Device", "Device to Device", NULL}; const char *sMemoryMode[] = {"PINNED", "PAGEABLE", NULL}; // if true, use CPU based timing for everything static bool bDontUseGPUTiming; int *pArgc = NULL; char **pArgv = NULL; //////////////////////////////////////////////////////////////////////////////// // declaration, forward int runTest(const int argc, const char **argv); void testBandwidth(unsigned int start, unsigned int end, unsigned int increment, testMode mode, memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc); void testBandwidthQuick(unsigned int size, memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc); void testBandwidthRange(unsigned int start, unsigned int end, unsigned int increment, memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc); void testBandwidthShmoo(memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc); float testDeviceToHostTransfer(unsigned int memSize, memoryMode memMode, bool wc); float testHostToDeviceTransfer(unsigned int memSize, memoryMode memMode, bool wc); float testDeviceToDeviceTransfer(unsigned int memSize); void printResultsReadable(unsigned int *memSizes, double *bandwidths, unsigned int count, memcpyKind kind, memoryMode memMode, int iNumDevs, bool wc); void printResultsCSV(unsigned int *memSizes, double *bandwidths, unsigned int count, memcpyKind kind, memoryMode memMode, int iNumDevs, bool wc); void printHelp(void); //////////////////////////////////////////////////////////////////////////////// // Program main //////////////////////////////////////////////////////////////////////////////// int main(int argc, char **argv) { pArgc = &argc; pArgv = argv; flush_buf = (char *)malloc(FLUSH_SIZE); // set logfile name and start logs printf("[%s] - Starting...\n", sSDKsample); int iRetVal = runTest(argc, (const char **)argv); if (iRetVal < 0) { checkCudaErrors(cudaSetDevice(0)); } // finish printf("%s\n", (iRetVal == 0) ? "Result = PASS" : "Result = FAIL"); printf( "\nNOTE: The CUDA Samples are not meant for performance measurements. " "Results may vary when GPU Boost is enabled.\n"); free(flush_buf); exit((iRetVal == 0) ? EXIT_SUCCESS : EXIT_FAILURE); } /////////////////////////////////////////////////////////////////////////////// // Parse args, run the appropriate tests /////////////////////////////////////////////////////////////////////////////// int runTest(const int argc, const char **argv) { int start = DEFAULT_SIZE; int end = DEFAULT_SIZE; int startDevice = 0; int endDevice = 0; int increment = DEFAULT_INCREMENT; testMode mode = QUICK_MODE; bool htod = false; bool dtoh = false; bool dtod = false; bool wc = false; char *modeStr; char *device = NULL; printMode printmode = USER_READABLE; char *memModeStr = NULL; memoryMode memMode = PINNED; // process command line args if (checkCmdLineFlag(argc, argv, "help")) { printHelp(); return 0; } if (checkCmdLineFlag(argc, argv, "csv")) { printmode = CSV; } if (getCmdLineArgumentString(argc, argv, "memory", &memModeStr)) { if (strcmp(memModeStr, "pageable") == 0) { memMode = PAGEABLE; } else if (strcmp(memModeStr, "pinned") == 0) { memMode = PINNED; } else { printf("Invalid memory mode - valid modes are pageable or pinned\n"); printf("See --help for more information\n"); return -1000; } } else { // default - pinned memory memMode = PINNED; } if (getCmdLineArgumentString(argc, argv, "device", &device)) { int deviceCount; cudaError_t error_id = cudaGetDeviceCount(&deviceCount); if (error_id != cudaSuccess) { printf("cudaGetDeviceCount returned %d\n-> %s\n", (int)error_id, cudaGetErrorString(error_id)); exit(EXIT_FAILURE); } if (deviceCount == 0) { printf("!!!!!No devices found!!!!!\n"); return -2000; } if (strcmp(device, "all") == 0) { printf( "\n!!!!!Cumulative Bandwidth to be computed from all the devices " "!!!!!!\n\n"); startDevice = 0; endDevice = deviceCount - 1; } else { startDevice = endDevice = atoi(device); if (startDevice >= deviceCount || startDevice < 0) { printf( "\n!!!!!Invalid GPU number %d given hence default gpu %d will be " "used !!!!!\n", startDevice, 0); startDevice = endDevice = 0; } } } printf("Running on...\n\n"); for (int currentDevice = startDevice; currentDevice <= endDevice; currentDevice++) { cudaDeviceProp deviceProp; cudaError_t error_id = cudaGetDeviceProperties(&deviceProp, currentDevice); if (error_id == cudaSuccess) { printf(" Device %d: %s\n", currentDevice, deviceProp.name); if (deviceProp.computeMode == cudaComputeModeProhibited) { fprintf(stderr, "Error: device is running in , no " "threads can use ::cudaSetDevice().\n"); checkCudaErrors(cudaSetDevice(currentDevice)); exit(EXIT_FAILURE); } } else { printf("cudaGetDeviceProperties returned %d\n-> %s\n", (int)error_id, cudaGetErrorString(error_id)); checkCudaErrors(cudaSetDevice(currentDevice)); exit(EXIT_FAILURE); } } if (getCmdLineArgumentString(argc, argv, "mode", &modeStr)) { // figure out the mode if (strcmp(modeStr, "quick") == 0) { printf(" Quick Mode\n\n"); mode = QUICK_MODE; } else if (strcmp(modeStr, "shmoo") == 0) { printf(" Shmoo Mode\n\n"); mode = SHMOO_MODE; } else if (strcmp(modeStr, "range") == 0) { printf(" Range Mode\n\n"); mode = RANGE_MODE; } else { printf("Invalid mode - valid modes are quick, range, or shmoo\n"); printf("See --help for more information\n"); return -3000; } } else { // default mode - quick printf(" Quick Mode\n\n"); mode = QUICK_MODE; } if (checkCmdLineFlag(argc, argv, "htod")) { htod = true; } if (checkCmdLineFlag(argc, argv, "dtoh")) { dtoh = true; } if (checkCmdLineFlag(argc, argv, "dtod")) { dtod = true; } #if CUDART_VERSION >= 2020 if (checkCmdLineFlag(argc, argv, "wc")) { wc = true; } #endif if (checkCmdLineFlag(argc, argv, "cputiming")) { bDontUseGPUTiming = true; } if (!htod && !dtoh && !dtod) { // default: All htod = true; dtoh = true; dtod = true; } if (RANGE_MODE == mode) { if (checkCmdLineFlag(argc, (const char **)argv, "start")) { start = getCmdLineArgumentInt(argc, argv, "start"); if (start <= 0) { printf("Illegal argument - start must be greater than zero\n"); return -4000; } } else { printf("Must specify a starting size in range mode\n"); printf("See --help for more information\n"); return -5000; } if (checkCmdLineFlag(argc, (const char **)argv, "end")) { end = getCmdLineArgumentInt(argc, argv, "end"); if (end <= 0) { printf("Illegal argument - end must be greater than zero\n"); return -6000; } if (start > end) { printf("Illegal argument - start is greater than end\n"); return -7000; } } else { printf("Must specify an end size in range mode.\n"); printf("See --help for more information\n"); return -8000; } if (checkCmdLineFlag(argc, argv, "increment")) { increment = getCmdLineArgumentInt(argc, argv, "increment"); if (increment <= 0) { printf("Illegal argument - increment must be greater than zero\n"); return -9000; } } else { printf("Must specify an increment in user mode\n"); printf("See --help for more information\n"); return -10000; } } if (htod) { testBandwidth((unsigned int)start, (unsigned int)end, (unsigned int)increment, mode, HOST_TO_DEVICE, printmode, memMode, startDevice, endDevice, wc); } if (dtoh) { testBandwidth((unsigned int)start, (unsigned int)end, (unsigned int)increment, mode, DEVICE_TO_HOST, printmode, memMode, startDevice, endDevice, wc); } if (dtod) { testBandwidth((unsigned int)start, (unsigned int)end, (unsigned int)increment, mode, DEVICE_TO_DEVICE, printmode, memMode, startDevice, endDevice, wc); } // Ensure that we reset all CUDA Devices in question for (int nDevice = startDevice; nDevice <= endDevice; nDevice++) { cudaSetDevice(nDevice); } return 0; } /////////////////////////////////////////////////////////////////////////////// // Run a bandwidth test /////////////////////////////////////////////////////////////////////////////// void testBandwidth(unsigned int start, unsigned int end, unsigned int increment, testMode mode, memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc) { switch (mode) { case QUICK_MODE: testBandwidthQuick(DEFAULT_SIZE, kind, printmode, memMode, startDevice, endDevice, wc); break; case RANGE_MODE: testBandwidthRange(start, end, increment, kind, printmode, memMode, startDevice, endDevice, wc); break; case SHMOO_MODE: testBandwidthShmoo(kind, printmode, memMode, startDevice, endDevice, wc); break; default: break; } } ////////////////////////////////////////////////////////////////////// // Run a quick mode bandwidth test ////////////////////////////////////////////////////////////////////// void testBandwidthQuick(unsigned int size, memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc) { testBandwidthRange(size, size, DEFAULT_INCREMENT, kind, printmode, memMode, startDevice, endDevice, wc); } /////////////////////////////////////////////////////////////////////// // Run a range mode bandwidth test ////////////////////////////////////////////////////////////////////// void testBandwidthRange(unsigned int start, unsigned int end, unsigned int increment, memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc) { // count the number of copies we're going to run unsigned int count = 1 + ((end - start) / increment); unsigned int *memSizes = (unsigned int *)malloc(count * sizeof(unsigned int)); double *bandwidths = (double *)malloc(count * sizeof(double)); // Before calculating the cumulative bandwidth, initialize bandwidths array to // NULL for (unsigned int i = 0; i < count; i++) { bandwidths[i] = 0.0; } // Use the device asked by the user for (int currentDevice = startDevice; currentDevice <= endDevice; currentDevice++) { cudaSetDevice(currentDevice); // run each of the copies for (unsigned int i = 0; i < count; i++) { memSizes[i] = start + i * increment; switch (kind) { case DEVICE_TO_HOST: bandwidths[i] += testDeviceToHostTransfer(memSizes[i], memMode, wc); break; case HOST_TO_DEVICE: bandwidths[i] += testHostToDeviceTransfer(memSizes[i], memMode, wc); break; case DEVICE_TO_DEVICE: bandwidths[i] += testDeviceToDeviceTransfer(memSizes[i]); break; } } } // Complete the bandwidth computation on all the devices // print results if (printmode == CSV) { printResultsCSV(memSizes, bandwidths, count, kind, memMode, (1 + endDevice - startDevice), wc); } else { printResultsReadable(memSizes, bandwidths, count, kind, memMode, (1 + endDevice - startDevice), wc); } // clean up free(memSizes); free(bandwidths); } ////////////////////////////////////////////////////////////////////////////// // Intense shmoo mode - covers a large range of values with varying increments ////////////////////////////////////////////////////////////////////////////// void testBandwidthShmoo(memcpyKind kind, printMode printmode, memoryMode memMode, int startDevice, int endDevice, bool wc) { // count the number of copies to make unsigned int count = 1 + (SHMOO_LIMIT_20KB / SHMOO_INCREMENT_1KB) + ((SHMOO_LIMIT_50KB - SHMOO_LIMIT_20KB) / SHMOO_INCREMENT_2KB) + ((SHMOO_LIMIT_100KB - SHMOO_LIMIT_50KB) / SHMOO_INCREMENT_10KB) + ((SHMOO_LIMIT_1MB - SHMOO_LIMIT_100KB) / SHMOO_INCREMENT_100KB) + ((SHMOO_LIMIT_16MB - SHMOO_LIMIT_1MB) / SHMOO_INCREMENT_1MB) + ((SHMOO_LIMIT_32MB - SHMOO_LIMIT_16MB) / SHMOO_INCREMENT_2MB) + ((SHMOO_MEMSIZE_MAX - SHMOO_LIMIT_32MB) / SHMOO_INCREMENT_4MB); unsigned int *memSizes = (unsigned int *)malloc(count * sizeof(unsigned int)); double *bandwidths = (double *)malloc(count * sizeof(double)); // Before calculating the cumulative bandwidth, initialize bandwidths array to // NULL for (unsigned int i = 0; i < count; i++) { bandwidths[i] = 0.0; } // Use the device asked by the user for (int currentDevice = startDevice; currentDevice <= endDevice; currentDevice++) { cudaSetDevice(currentDevice); // Run the shmoo int iteration = 0; unsigned int memSize = 0; while (memSize <= SHMOO_MEMSIZE_MAX) { if (memSize < SHMOO_LIMIT_20KB) { memSize += SHMOO_INCREMENT_1KB; } else if (memSize < SHMOO_LIMIT_50KB) { memSize += SHMOO_INCREMENT_2KB; } else if (memSize < SHMOO_LIMIT_100KB) { memSize += SHMOO_INCREMENT_10KB; } else if (memSize < SHMOO_LIMIT_1MB) { memSize += SHMOO_INCREMENT_100KB; } else if (memSize < SHMOO_LIMIT_16MB) { memSize += SHMOO_INCREMENT_1MB; } else if (memSize < SHMOO_LIMIT_32MB) { memSize += SHMOO_INCREMENT_2MB; } else { memSize += SHMOO_INCREMENT_4MB; } memSizes[iteration] = memSize; switch (kind) { case DEVICE_TO_HOST: bandwidths[iteration] += testDeviceToHostTransfer(memSizes[iteration], memMode, wc); break; case HOST_TO_DEVICE: bandwidths[iteration] += testHostToDeviceTransfer(memSizes[iteration], memMode, wc); break; case DEVICE_TO_DEVICE: bandwidths[iteration] += testDeviceToDeviceTransfer(memSizes[iteration]); break; } iteration++; printf("."); fflush(0); } } // Complete the bandwidth computation on all the devices // print results printf("\n"); if (CSV == printmode) { printResultsCSV(memSizes, bandwidths, count, kind, memMode, (1 + endDevice - startDevice), wc); } else { printResultsReadable(memSizes, bandwidths, count, kind, memMode, (1 + endDevice - startDevice), wc); } // clean up free(memSizes); free(bandwidths); } /////////////////////////////////////////////////////////////////////////////// // test the bandwidth of a device to host memcopy of a specific size /////////////////////////////////////////////////////////////////////////////// float testDeviceToHostTransfer(unsigned int memSize, memoryMode memMode, bool wc) { StopWatchInterface *timer = NULL; float elapsedTimeInMs = 0.0f; float bandwidthInGBs = 0.0f; unsigned char *h_idata = NULL; unsigned char *h_odata = NULL; cudaEvent_t start, stop; sdkCreateTimer(&timer); checkCudaErrors(cudaEventCreate(&start)); checkCudaErrors(cudaEventCreate(&stop)); // allocate host memory if (PINNED == memMode) { // pinned memory mode - use special function to get OS-pinned memory #if CUDART_VERSION >= 2020 checkCudaErrors(cudaHostAlloc((void **)&h_idata, memSize, (wc) ? cudaHostAllocWriteCombined : 0)); checkCudaErrors(cudaHostAlloc((void **)&h_odata, memSize, (wc) ? cudaHostAllocWriteCombined : 0)); #else checkCudaErrors(cudaMallocHost((void **)&h_idata, memSize)); checkCudaErrors(cudaMallocHost((void **)&h_odata, memSize)); #endif } else { // pageable memory mode - use malloc h_idata = (unsigned char *)malloc(memSize); h_odata = (unsigned char *)malloc(memSize); if (h_idata == 0 || h_odata == 0) { fprintf(stderr, "Not enough memory avaialable on host to run test!\n"); exit(EXIT_FAILURE); } } // initialize the memory for (unsigned int i = 0; i < memSize / sizeof(unsigned char); i++) { h_idata[i] = (unsigned char)(i & 0xff); } // allocate device memory unsigned char *d_idata; checkCudaErrors(cudaMalloc((void **)&d_idata, memSize)); // initialize the device memory checkCudaErrors( cudaMemcpy(d_idata, h_idata, memSize, cudaMemcpyHostToDevice)); // copy data from GPU to Host if (PINNED == memMode) { if (bDontUseGPUTiming) sdkStartTimer(&timer); checkCudaErrors(cudaEventRecord(start, 0)); for (unsigned int i = 0; i < MEMCOPY_ITERATIONS; i++) { checkCudaErrors(cudaMemcpyAsync(h_odata, d_idata, memSize, cudaMemcpyDeviceToHost, 0)); } checkCudaErrors(cudaEventRecord(stop, 0)); checkCudaErrors(cudaDeviceSynchronize()); checkCudaErrors(cudaEventElapsedTime(&elapsedTimeInMs, start, stop)); if (bDontUseGPUTiming) { sdkStopTimer(&timer); elapsedTimeInMs = sdkGetTimerValue(&timer); sdkResetTimer(&timer); } } else { elapsedTimeInMs = 0; for (unsigned int i = 0; i < MEMCOPY_ITERATIONS; i++) { sdkStartTimer(&timer); checkCudaErrors( cudaMemcpy(h_odata, d_idata, memSize, cudaMemcpyDeviceToHost)); sdkStopTimer(&timer); elapsedTimeInMs += sdkGetTimerValue(&timer); sdkResetTimer(&timer); memset(flush_buf, i, FLUSH_SIZE); } } // calculate bandwidth in GB/s double time_s = elapsedTimeInMs / 1e3; bandwidthInGBs = (memSize * (float)MEMCOPY_ITERATIONS) / (double)1e9; bandwidthInGBs = bandwidthInGBs / time_s; // clean up memory checkCudaErrors(cudaEventDestroy(stop)); checkCudaErrors(cudaEventDestroy(start)); sdkDeleteTimer(&timer); if (PINNED == memMode) { checkCudaErrors(cudaFreeHost(h_idata)); checkCudaErrors(cudaFreeHost(h_odata)); } else { free(h_idata); free(h_odata); } checkCudaErrors(cudaFree(d_idata)); return bandwidthInGBs; } /////////////////////////////////////////////////////////////////////////////// //! test the bandwidth of a host to device memcopy of a specific size /////////////////////////////////////////////////////////////////////////////// float testHostToDeviceTransfer(unsigned int memSize, memoryMode memMode, bool wc) { StopWatchInterface *timer = NULL; float elapsedTimeInMs = 0.0f; float bandwidthInGBs = 0.0f; cudaEvent_t start, stop; sdkCreateTimer(&timer); checkCudaErrors(cudaEventCreate(&start)); checkCudaErrors(cudaEventCreate(&stop)); // allocate host memory unsigned char *h_odata = NULL; if (PINNED == memMode) { #if CUDART_VERSION >= 2020 // pinned memory mode - use special function to get OS-pinned memory checkCudaErrors(cudaHostAlloc((void **)&h_odata, memSize, (wc) ? cudaHostAllocWriteCombined : 0)); #else // pinned memory mode - use special function to get OS-pinned memory checkCudaErrors(cudaMallocHost((void **)&h_odata, memSize)); #endif } else { // pageable memory mode - use malloc h_odata = (unsigned char *)malloc(memSize); if (h_odata == 0) { fprintf(stderr, "Not enough memory available on host to run test!\n"); exit(EXIT_FAILURE); } } unsigned char *h_cacheClear1 = (unsigned char *)malloc(CACHE_CLEAR_SIZE); unsigned char *h_cacheClear2 = (unsigned char *)malloc(CACHE_CLEAR_SIZE); if (h_cacheClear1 == 0 || h_cacheClear2 == 0) { fprintf(stderr, "Not enough memory available on host to run test!\n"); exit(EXIT_FAILURE); } // initialize the memory for (unsigned int i = 0; i < memSize / sizeof(unsigned char); i++) { h_odata[i] = (unsigned char)(i & 0xff); } for (unsigned int i = 0; i < CACHE_CLEAR_SIZE / sizeof(unsigned char); i++) { h_cacheClear1[i] = (unsigned char)(i & 0xff); h_cacheClear2[i] = (unsigned char)(0xff - (i & 0xff)); } // allocate device memory unsigned char *d_idata; checkCudaErrors(cudaMalloc((void **)&d_idata, memSize)); // copy host memory to device memory if (PINNED == memMode) { if (bDontUseGPUTiming) sdkStartTimer(&timer); checkCudaErrors(cudaEventRecord(start, 0)); for (unsigned int i = 0; i < MEMCOPY_ITERATIONS; i++) { checkCudaErrors(cudaMemcpyAsync(d_idata, h_odata, memSize, cudaMemcpyHostToDevice, 0)); } checkCudaErrors(cudaEventRecord(stop, 0)); checkCudaErrors(cudaDeviceSynchronize()); checkCudaErrors(cudaEventElapsedTime(&elapsedTimeInMs, start, stop)); if (bDontUseGPUTiming) { sdkStopTimer(&timer); elapsedTimeInMs = sdkGetTimerValue(&timer); sdkResetTimer(&timer); } } else { elapsedTimeInMs = 0; for (unsigned int i = 0; i < MEMCOPY_ITERATIONS; i++) { sdkStartTimer(&timer); checkCudaErrors( cudaMemcpy(d_idata, h_odata, memSize, cudaMemcpyHostToDevice)); sdkStopTimer(&timer); elapsedTimeInMs += sdkGetTimerValue(&timer); sdkResetTimer(&timer); memset(flush_buf, i, FLUSH_SIZE); } } // calculate bandwidth in GB/s double time_s = elapsedTimeInMs / 1e3; bandwidthInGBs = (memSize * (float)MEMCOPY_ITERATIONS) / (double)1e9; bandwidthInGBs = bandwidthInGBs / time_s; // clean up memory checkCudaErrors(cudaEventDestroy(stop)); checkCudaErrors(cudaEventDestroy(start)); sdkDeleteTimer(&timer); if (PINNED == memMode) { checkCudaErrors(cudaFreeHost(h_odata)); } else { free(h_odata); } free(h_cacheClear1); free(h_cacheClear2); checkCudaErrors(cudaFree(d_idata)); return bandwidthInGBs; } /////////////////////////////////////////////////////////////////////////////// //! test the bandwidth of a device to device memcopy of a specific size /////////////////////////////////////////////////////////////////////////////// float testDeviceToDeviceTransfer(unsigned int memSize) { StopWatchInterface *timer = NULL; float elapsedTimeInMs = 0.0f; float bandwidthInGBs = 0.0f; cudaEvent_t start, stop; sdkCreateTimer(&timer); checkCudaErrors(cudaEventCreate(&start)); checkCudaErrors(cudaEventCreate(&stop)); // allocate host memory unsigned char *h_idata = (unsigned char *)malloc(memSize); if (h_idata == 0) { fprintf(stderr, "Not enough memory avaialable on host to run test!\n"); exit(EXIT_FAILURE); } // initialize the host memory for (unsigned int i = 0; i < memSize / sizeof(unsigned char); i++) { h_idata[i] = (unsigned char)(i & 0xff); } // allocate device memory unsigned char *d_idata; checkCudaErrors(cudaMalloc((void **)&d_idata, memSize)); unsigned char *d_odata; checkCudaErrors(cudaMalloc((void **)&d_odata, memSize)); // initialize memory checkCudaErrors( cudaMemcpy(d_idata, h_idata, memSize, cudaMemcpyHostToDevice)); // run the memcopy sdkStartTimer(&timer); checkCudaErrors(cudaEventRecord(start, 0)); for (unsigned int i = 0; i < MEMCOPY_ITERATIONS; i++) { checkCudaErrors( cudaMemcpy(d_odata, d_idata, memSize, cudaMemcpyDeviceToDevice)); } checkCudaErrors(cudaEventRecord(stop, 0)); // Since device to device memory copies are non-blocking, // cudaDeviceSynchronize() is required in order to get // proper timing. checkCudaErrors(cudaDeviceSynchronize()); // get the total elapsed time in ms sdkStopTimer(&timer); checkCudaErrors(cudaEventElapsedTime(&elapsedTimeInMs, start, stop)); if (bDontUseGPUTiming) { elapsedTimeInMs = sdkGetTimerValue(&timer); } // calculate bandwidth in GB/s double time_s = elapsedTimeInMs / 1e3; bandwidthInGBs = (2.0f * memSize * (float)MEMCOPY_ITERATIONS) / (double)1e9; bandwidthInGBs = bandwidthInGBs / time_s; // clean up memory sdkDeleteTimer(&timer); free(h_idata); checkCudaErrors(cudaEventDestroy(stop)); checkCudaErrors(cudaEventDestroy(start)); checkCudaErrors(cudaFree(d_idata)); checkCudaErrors(cudaFree(d_odata)); return bandwidthInGBs; } ///////////////////////////////////////////////////////// // print results in an easily read format //////////////////////////////////////////////////////// void printResultsReadable(unsigned int *memSizes, double *bandwidths, unsigned int count, memcpyKind kind, memoryMode memMode, int iNumDevs, bool wc) { printf(" %s Bandwidth, %i Device(s)\n", sMemoryCopyKind[kind], iNumDevs); printf(" %s Memory Transfers\n", sMemoryMode[memMode]); if (wc) { printf(" Write-Combined Memory Writes are Enabled"); } printf(" Transfer Size (Bytes)\tBandwidth(GB/s)\n"); unsigned int i; for (i = 0; i < (count - 1); i++) { printf(" %u\t\t\t%s%.1f\n", memSizes[i], (memSizes[i] < 10000) ? "\t" : "", bandwidths[i]); } printf(" %u\t\t\t%s%.1f\n\n", memSizes[i], (memSizes[i] < 10000) ? "\t" : "", bandwidths[i]); } /////////////////////////////////////////////////////////////////////////// // print results in a database format /////////////////////////////////////////////////////////////////////////// void printResultsCSV(unsigned int *memSizes, double *bandwidths, unsigned int count, memcpyKind kind, memoryMode memMode, int iNumDevs, bool wc) { std::string sConfig; // log config information if (kind == DEVICE_TO_DEVICE) { sConfig += "D2D"; } else { if (kind == DEVICE_TO_HOST) { sConfig += "D2H"; } else if (kind == HOST_TO_DEVICE) { sConfig += "H2D"; } if (memMode == PAGEABLE) { sConfig += "-Paged"; } else if (memMode == PINNED) { sConfig += "-Pinned"; if (wc) { sConfig += "-WriteCombined"; } } } unsigned int i; double dSeconds = 0.0; for (i = 0; i < count; i++) { dSeconds = (double)memSizes[i] / (bandwidths[i] * (double)(1e9)); printf( "bandwidthTest-%s, Bandwidth = %.1f GB/s, Time = %.5f s, Size = %u " "bytes, NumDevsUsed = %d\n", sConfig.c_str(), bandwidths[i], dSeconds, memSizes[i], iNumDevs); } } /////////////////////////////////////////////////////////////////////////// // Print help screen /////////////////////////////////////////////////////////////////////////// void printHelp(void) { printf("Usage: bandwidthTest [OPTION]...\n"); printf( "Test the bandwidth for device to host, host to device, and device to " "device transfers\n"); printf("\n"); printf( "Example: measure the bandwidth of device to host pinned memory copies " "in the range 1024 Bytes to 102400 Bytes in 1024 Byte increments\n"); printf( "./bandwidthTest --memory=pinned --mode=range --start=1024 --end=102400 " "--increment=1024 --dtoh\n"); printf("\n"); printf("Options:\n"); printf("--help\tDisplay this help menu\n"); printf("--csv\tPrint results as a CSV\n"); printf("--device=[deviceno]\tSpecify the device device to be used\n"); printf(" all - compute cumulative bandwidth on all the devices\n"); printf(" 0,1,2,...,n - Specify any particular device to be used\n"); printf("--memory=[MEMMODE]\tSpecify which memory mode to use\n"); printf(" pageable - pageable memory\n"); printf(" pinned - non-pageable system memory\n"); printf("--mode=[MODE]\tSpecify the mode to use\n"); printf(" quick - performs a quick measurement\n"); printf(" range - measures a user-specified range of values\n"); printf(" shmoo - performs an intense shmoo of a large range of values\n"); printf("--htod\tMeasure host to device transfers\n"); printf("--dtoh\tMeasure device to host transfers\n"); printf("--dtod\tMeasure device to device transfers\n"); #if CUDART_VERSION >= 2020 printf("--wc\tAllocate pinned memory as write-combined\n"); #endif printf("--cputiming\tForce CPU-based timing always\n"); printf("Range mode options\n"); printf("--start=[SIZE]\tStarting transfer size in bytes\n"); printf("--end=[SIZE]\tEnding transfer size in bytes\n"); printf("--increment=[SIZE]\tIncrement size in bytes\n"); }