예제 #1
0
int main(int argc, char *argv[]) {
	int loops = 100, inner_loops = 100;
	int smin = 0, smax = 100000, sstep = 5000;
	int *values[] = { &loops, &smin, &smin, &smax, &smax, &sstep, &sstep };
	const char *identifier[] = { "-l", "-smin", "-rmin", "-smax", "-rmax",
			"-sstep", "-rstep" };
	handle_args(argc, argv, 7, values, identifier);

	printf("Loops: %d\n", loops);
	printf("Sizes: %d - %d, steps of %d\n", smin, smax, sstep);

	printf("Size;Expected Value;Standard deviation\n");
	for (int size = smin; size <= smax; size += sstep) {
		printf("%d", size);

		Stats stats;
		for (int l = 0; l < loops; l++) {
			int failures = 0;
			for (int il = 0; il < inner_loops; il++) {
				// init
				unsigned char a[size];
				for (int i = 0; i < size; i++)
					a[i] = 0;

				// run
				int flip = 0; // alternates between 0 (read) and 1 (write)
				int dummy;

				if (_xbegin() == _XBEGIN_STARTED) {
					for (int i = 0; i < size; i++) {
						if (flip)
							dummy = a[i]; // -O0!
						else
							a[i]++;

						flip ^= 1;
					}
					_xend();
				} else {
					failures++;
				}
			}
			float failure_rate = (float) failures * 100 / inner_loops;
			stats.addValue(failure_rate);
		}
		printf(";%.2f;%.2f\n", stats.getExpectedValue(),
				stats.getStandardDeviation());
	}
}
예제 #2
0
int main(int argc, char *argv[]) {
	int num_threads = 4;
	int loops = 10;
	int lockFunction = 0;
	int partitioned = 0, duration = 10000, warmup = duration / 10;
	int *values[] = { &num_threads, &loops, &partitioned, &lockFunction,
			&sleep_time, &pin, &duration, &warmup };
	const char *identifier[] = { "-n", "-l", "-partition", "-t", "-sleep",
			"-pin", "-d", "-w" };
	handle_args(argc, argv, 9, values, identifier);

	printf("Threads:         %d\n", num_threads);
	printf("sizeof(type):    %lu | padded: %lu\n",
			sizeof(((mutex_type *) 0)->value), sizeof(mutex_type));
	printf("Loops:           %d\n", loops);
	printf("Partitioned:     %s\n", partitioned ? "yes" : "no");
	printf("Pinned:          %s\n", pin ? "yes" : "no");
	printf("sleep:           %d\n", sleep_time);
	printf("Duration:        %d microseconds (%d microseconds warmup)\n",
			duration, warmup);
	int sizes[] = { 10 }; //{ 1, 10, 100 }; //{ 1000, 5500, 10000 }; // {10, 55, 100}; //

	int lockFunctionsMin, lockFunctionsMax;
	switch (lockFunction) {
	case -1:
	case 2:
	case 3:
		lockFunctionsMin = 0;
		lockFunctionsMax = LOCK_FUNCTIONS_LENGTH;
		break;
	default:
		lockFunctionsMin = lockFunction;
		lockFunctionsMax = lockFunction + 1;
		break;
	}

	// init
	int lock_accesses_size = 1000000;

	pthread_t threads[num_threads];

	printHeader(lockFunction);
	for (int s = 0; s < sizeof(sizes) / sizeof(sizes[0]); s++) {
		int mutexes_array_size = sizes[s];
		printf("%d", mutexes_array_size);
		std::cout.flush();
		mutexes = (mutex_type *) calloc(
				sizes[sizeof(sizes) / sizeof(sizes[0]) - 1], // always allocate maximum amount
				sizeof(mutex_type));

		// loop over functions, loops, threads
		for (int f = lockFunctionsMin; f < lockFunctionsMax; f++) {
			Stats stats;
			for (int l = 0; l < loops; l++) {
				// create random access values for each thread
				int ** lock_accesses = new int*[num_threads];
				for (int t = 0; t < num_threads; t++) {
					lock_accesses[t] = new int[lock_accesses_size];
					// partitioned
					int partition_left, partition_size;
					if (partitioned) {
						partition_size = mutexes_array_size / num_threads;
						partition_left = t * partition_size;
					}
					for (int a = 0; a < lock_accesses_size; a++) {
						if (partitioned) {
							lock_accesses[t][a] = partition_left
									+ (rand() % partition_size);
//							printf("lock_accesses[%d][%d] = %d\n", t, a, lock_accesses[t][a]);
						} else { // shared
							lock_accesses[t][a] = rand() % mutexes_array_size;
						}
					}
				} // measure
				operations_count = new int[num_threads];
				stop_run = 0;

				// BEGIN: run
				std::thread threads[num_threads];
				for (int t = 0; t < num_threads; t++) {
					threads[t] = std::thread(run, t, lock_functions[f],
							unlock_function, lock_accesses[t],
							lock_accesses_size);
				} // end threads loop
				  // warmup
				usleep(warmup);
				for (int i = 0; i < num_threads; i++) {
					operations_count[i] = 0; // reset
				}
				usleep(duration);
				stop_run = 1; // stop runs
				for (int i = 0; i < num_threads; i++) {
					threads[i].join(); // make sure result has been written
				}

				int total_operations = 0;
				for (int i = 0; i < num_threads; i++) {
					total_operations += operations_count[i];
				}

				// measure time
				int time_in_millis = duration / 1000;
				float throughput_total = ((float) total_operations)
						/ time_in_millis;
				stats.addValue(throughput_total);

				// clean up
				delete[] operations_count;
				for (int t = 0; t < num_threads; t++) {
					delete[] lock_accesses[t];
				}
				// TODO corruption error (double free) for uchar size 1000 and ushort size 100
			}
			printf(";%.2f;%.2f", stats.getExpectedValue(),
					stats.getStandardDeviation());
			std::cout.flush();
		} // end lock functions loop
		printf("\n");
		free(mutexes);
	}

}
예제 #3
0
파일: suite.cpp 프로젝트: mschrimpf/htmsql
int main(int argc, char *argv[]) {
	// arguments
	int loops = 10, sizes_min = 1, sizes_max = 1000000, sizes_step = 5000,
			write = 0;
	int *values[] = { &loops, &sizes_min, &sizes_min, &sizes_max, &sizes_max,
			&sizes_step, &sizes_step, &write, &max_retries };
	const char *identifier[] = { "-l", "-smin", "-rmin", "-smax", "-rmax",
			"-sstep", "-rstep", "-w", "-max_retries" };
	handle_args(argc, argv, 9, values, identifier);

	printf("%d - %d runs with steps of %d\n", sizes_min, sizes_max, sizes_step);
	printf("Maximum %d retries\n", max_retries);
	printf("Looped %d times\n", loops);
	printf("Printing to %s\n", write ? "files" : "stdout");
	printf("\n");

	const MeasureType *measureTypes[] = {
	// write sequential
//			&MeasureType::NOINIT_SEQ_WRITE, &MeasureType::INIT_SEQ_WRITE,
			// read sequential
			&MeasureType::NOINIT_SEQ_READ, &MeasureType::INIT_SEQ_READ,
			// write random
//			&MeasureType::NOINIT_RND_WRITE, &MeasureType::INIT_RND_WRITE,
	// read random
//			&MeasureType::NOINIT_RND_READ, &MeasureType::INIT_RND_READ
			//
			};

	// open files
	char retries_str[21]; // enough to hold all numbers up to 64-bits
	sprintf(retries_str, "%d", max_retries);
	std::string file_prefix = "read-seq-", failures_file_suffix =
			"retries-failures.csv", time_file_suffix = "retries-time.csv";
	std::string failures_filename = file_prefix + retries_str
			+ failures_file_suffix; //"write-seq-failures.csv"; //
	std::string time_filename = file_prefix + retries_str + time_file_suffix; //"write-seq-time.csv"; //
	FILE * failures_out =
			write ? fopen(failures_filename.c_str(), "w") : stdout;
	FILE * time_out = fopen(time_filename.c_str(), "w");

	// info
	fprintf(failures_out, "Size (Byte);");
	printHeader(measureTypes, sizeof(measureTypes) / sizeof(measureTypes[0]),
			failures_out);
	fprintf(time_out, "Size (Byte);");
	printHeader(measureTypes, sizeof(measureTypes) / sizeof(measureTypes[0]),
			time_out);

	// run suite
	srand(time(0));
	for (int s = sizes_min; s <= sizes_max; s += sizes_step) {
		fprintf(failures_out, "%lu", s * sizeof(type));
		fprintf(time_out, "%lu", s * sizeof(type));
		for (int t = 0; t < sizeof(measureTypes) / sizeof(measureTypes[0]);
				t++) {
			Stats failureStats;
			Stats timeStats;
			float failure_expected_value_sum = 0, failure_variance_sum = 0;
			float time_expected_value_sum = 0, time_variance_sum = 0;
			for (int l = 0; l < loops; l++) {
				int failures = 0;
				int attempts = 0;
				std::vector<double> times;
				for (int il = 0; il < 100; il++) {
					// init
					volatile type* array = measureTypes[t]->init(s);

					// run
					attempts++;
					struct timeval start, end;
					gettimeofday(&start, NULL);
					int res = measureTypes[t]->run(&array, s);
					gettimeofday(&end, NULL);
					double elapsed = ((end.tv_sec - start.tv_sec) * 1000000)
							+ (end.tv_usec - start.tv_usec);
					times.push_back(elapsed);
					if (!res) {
						failures++;
					}

					free((void*) array);
				} // end inner loops loop
				float failure_rate = (float) failures * 100 / attempts;
				failureStats.addValue(failure_rate);
				float time_avg = average(times);
				timeStats.addValue(time_avg);
			} // end loops loop
			fprintf(failures_out, ";%.4f;%.4f", failureStats.getExpectedValue(),
					failureStats.getStandardDeviation());
			fprintf(time_out, ";%.4f;%.4f", timeStats.getExpectedValue(),
					timeStats.getStandardDeviation());
		} // end types loop
		fprintf(failures_out, "\n");
		fprintf(time_out, "\n");
	} // end sizes loop

	fclose(failures_out);
	fclose(time_out);
}