#include #include #include #include #include "common.h" #include #include #define RT_CHECK(_expr) \ do { \ int _ret = _expr; \ if (0 == _ret) \ break; \ printf("Error: '%s' returned %d!\n", #_expr, (int)_ret); \ cleanup(); \ exit(-1); \ } while (false) /////////////////////////////////////////////////////////////////////////////// const char* kernel_file = "kernel.bin"; uint32_t count = 0; std::vector test_data; std::vector addr_table; vx_device_h device = nullptr; vx_buffer_h staging_buf = nullptr; static void show_usage() { std::cout << "Vortex Driver Test." << std::endl; std::cout << "Usage: [-k: kernel] [-n words] [-h: help]" << std::endl; } static void parse_args(int argc, char **argv) { int c; while ((c = getopt(argc, argv, "n:k:h?")) != -1) { switch (c) { case 'n': count = atoi(optarg); break; case 'k': kernel_file = optarg; break; case 'h': case '?': { show_usage(); exit(0); } break; default: show_usage(); exit(-1); } } } void cleanup() { if (staging_buf) { vx_buf_release(staging_buf); } if (device) { vx_dev_close(device); } } void gen_input_data(uint32_t num_points) { test_data.resize(num_points); addr_table.resize(num_points + NUM_LOADS - 1); for (uint32_t i = 0; i < test_data.size(); ++i) { test_data[i] = std::rand(); } for (uint32_t i = 0; i < addr_table.size(); ++i) { float r = static_cast(std::rand()) / RAND_MAX; uint32_t index = static_cast(r * num_points); assert(index < num_points); addr_table[i] = index; } } int run_test(const kernel_arg_t& kernel_arg, uint32_t dst_buf_size, uint32_t num_points) { // start device std::cout << "start device" << std::endl; RT_CHECK(vx_start(device)); // wait for completion std::cout << "wait for completion" << std::endl; RT_CHECK(vx_ready_wait(device, -1)); // download destination buffer std::cout << "download destination buffer" << std::endl; RT_CHECK(vx_copy_from_dev(staging_buf, kernel_arg.dst_ptr, dst_buf_size, 0)); // verify result std::cout << "verify result" << std::endl; { int errors = 0; auto buf_ptr = (int32_t*)vx_host_ptr(staging_buf); for (uint32_t i = 0; i < num_points; ++i) { int ref = 0; for (uint32_t j = 0; j < NUM_LOADS; ++j) { uint32_t addr = i + j; uint32_t index = addr_table.at(addr); int value = test_data.at(index); //printf("*** [%d] addr=%d, index=%d, value=%d\n", i, addr, index, value); ref += value; } int cur = buf_ptr[i]; if (cur != ref) { std::cout << "error at result #" << std::dec << i << ": actual " << cur << ", expected " << ref << std::endl; ++errors; } } if (errors != 0) { std::cout << "Found " << std::dec << errors << " errors!" << std::endl; std::cout << "FAILED!" << std::endl; return 1; } } return 0; } int main(int argc, char *argv[]) { size_t value; kernel_arg_t kernel_arg; // parse command arguments parse_args(argc, argv); if (count == 0) { count = 1; } std::srand(50); // open device connection std::cout << "open device connection" << std::endl; RT_CHECK(vx_dev_open(&device)); unsigned max_cores, max_warps, max_threads; RT_CHECK(vx_dev_caps(device, VX_CAPS_MAX_CORES, &max_cores)); RT_CHECK(vx_dev_caps(device, VX_CAPS_MAX_WARPS, &max_warps)); RT_CHECK(vx_dev_caps(device, VX_CAPS_MAX_THREADS, &max_threads)); uint32_t num_tasks = max_cores * max_warps * max_threads; uint32_t num_points = count * num_tasks; // generate input data gen_input_data(num_points); uint32_t addr_buf_size = addr_table.size() * sizeof(int32_t); uint32_t src_buf_size = test_data.size() * sizeof(int32_t); uint32_t dst_buf_size = test_data.size() * sizeof(int32_t); std::cout << "number of points: " << num_points << std::endl; std::cout << "buffer size: " << dst_buf_size << " bytes" << std::endl; // upload program std::cout << "upload program" << std::endl; RT_CHECK(vx_upload_kernel_file(device, kernel_file)); // allocate device memory std::cout << "allocate device memory" << std::endl; RT_CHECK(vx_alloc_dev_mem(device, addr_buf_size, &value)); kernel_arg.addr_ptr = value; RT_CHECK(vx_alloc_dev_mem(device, src_buf_size, &value)); kernel_arg.src_ptr = value; RT_CHECK(vx_alloc_dev_mem(device, dst_buf_size, &value)); kernel_arg.dst_ptr = value; kernel_arg.num_tasks = num_tasks; kernel_arg.stride = count; std::cout << "dev_addr=" << std::hex << kernel_arg.addr_ptr << std::endl; std::cout << "dev_src=" << std::hex << kernel_arg.src_ptr << std::endl; std::cout << "dev_dst=" << std::hex << kernel_arg.dst_ptr << std::endl; // allocate shared memory std::cout << "allocate shared memory" << std::endl; uint32_t staging_buf_size = std::max(src_buf_size, std::max(addr_buf_size, std::max(dst_buf_size, sizeof(kernel_arg_t)))); RT_CHECK(vx_alloc_shared_mem(device, staging_buf_size, &staging_buf)); // upload kernel argument std::cout << "upload kernel argument" << std::endl; { auto buf_ptr = (int*)vx_host_ptr(staging_buf); memcpy(buf_ptr, &kernel_arg, sizeof(kernel_arg_t)); RT_CHECK(vx_copy_to_dev(staging_buf, KERNEL_ARG_DEV_MEM_ADDR, sizeof(kernel_arg_t), 0)); } // upload source buffer0 { auto buf_ptr = (int32_t*)vx_host_ptr(staging_buf); for (uint32_t i = 0; i < addr_table.size(); ++i) { buf_ptr[i] = addr_table.at(i); } } std::cout << "upload address buffer" << std::endl; RT_CHECK(vx_copy_to_dev(staging_buf, kernel_arg.addr_ptr, addr_buf_size, 0)); // upload source buffer1 { auto buf_ptr = (int32_t*)vx_host_ptr(staging_buf); for (uint32_t i = 0; i < test_data.size(); ++i) { buf_ptr[i] = test_data.at(i); } } std::cout << "upload source buffer" << std::endl; RT_CHECK(vx_copy_to_dev(staging_buf, kernel_arg.src_ptr, src_buf_size, 0)); // clear destination buffer { auto buf_ptr = (int32_t*)vx_host_ptr(staging_buf); for (uint32_t i = 0; i < test_data.size(); ++i) { buf_ptr[i] = 0xdeadbeef; } } std::cout << "clear destination buffer" << std::endl; RT_CHECK(vx_copy_to_dev(staging_buf, kernel_arg.dst_ptr, dst_buf_size, 0)); // run tests std::cout << "run tests" << std::endl; RT_CHECK(run_test(kernel_arg, dst_buf_size, num_points)); // cleanup std::cout << "cleanup" << std::endl; cleanup(); std::cout << "PASSED!" << std::endl; return 0; }