/** ****************************************************************************** * Xenia : Xbox 360 Emulator Research Project * ****************************************************************************** * Copyright 2013 Ben Vanik. All rights reserved. * * Released under the BSD license - see LICENSE in the root for more details. * ****************************************************************************** */ #include #if !XE_LIKE(WIN32) #include #endif // !WIN32 #include #include using namespace std; using namespace xe; using namespace xe::cpu; using namespace xe::kernel; #if XE_LIKE(WIN32) DEFINE_string(test_path, "test\\codegen\\", "Directory scanned for test files."); #else DEFINE_string(test_path, "test/codegen/", "Directory scanned for test files."); #endif // WIN32 typedef vector > annotations_list_t; int read_annotations(string& src_file_path, annotations_list_t& annotations) { // TODO(benvanik): use PAL instead of this FILE* f = fopen(src_file_path.c_str(), "r"); char line_buffer[BUFSIZ]; while (fgets(line_buffer, sizeof(line_buffer), f)) { if (strlen(line_buffer) > 3 && line_buffer[0] == '#' && line_buffer[1] == ' ') { // Comment - check if formed like an annotation. // We don't actually verify anything here. char* next_space = strchr(line_buffer + 3, ' '); if (next_space) { // Looks legit. string key = string(line_buffer + 2, next_space); string value = string(next_space + 1); while (value.find_last_of(" \t\n") == value.size() - 1) { value.erase(value.end() - 1); } annotations.push_back(pair(key, value)); } } } fclose(f); return 0; } int setup_test_state(xe_memory_ref memory, Processor* processor, ThreadState* thread_state, annotations_list_t& annotations) { xe_ppc_state_t* ppc_state = thread_state->ppc_state(); for (annotations_list_t::iterator it = annotations.begin(); it != annotations.end(); ++it) { if (it->first == "REGISTER_IN") { size_t space_pos = it->second.find(" "); string reg_name = it->second.substr(0, space_pos); string reg_value = it->second.substr(space_pos + 1); ppc_state->SetRegFromString(reg_name.c_str(), reg_value.c_str()); } } return 0; } int check_test_results(xe_memory_ref memory, Processor* processor, ThreadState* thread_state, annotations_list_t& annotations) { xe_ppc_state_t* ppc_state = thread_state->ppc_state(); char actual_value[2048]; bool any_failed = false; for (annotations_list_t::iterator it = annotations.begin(); it != annotations.end(); ++it) { if (it->first == "REGISTER_OUT") { size_t space_pos = it->second.find(" "); string reg_name = it->second.substr(0, space_pos); string reg_value = it->second.substr(space_pos + 1); if (!ppc_state->CompareRegWithString( reg_name.c_str(), reg_value.c_str(), actual_value, XECOUNT(actual_value))) { any_failed = true; printf("Register %s assert failed:\n", reg_name.c_str()); printf(" Expected: %s == %s\n", reg_name.c_str(), reg_value.c_str()); printf(" Actual: %s == %s\n", reg_name.c_str(), actual_value); } } } return any_failed; } int run_test(string& src_file_path) { int result_code = 1; // test.s -> test.bin string bin_file_path; size_t dot = src_file_path.find_last_of(".s"); bin_file_path = src_file_path; bin_file_path.replace(dot - 1, 2, ".bin"); xe_memory_ref memory = NULL; shared_ptr backend; shared_ptr processor; shared_ptr runtime; annotations_list_t annotations; ThreadState* thread_state = NULL; XEEXPECTZERO(read_annotations(src_file_path, annotations)); while (!memory) { xe_memory_options_t memory_options; xe_zero_struct(&memory_options, sizeof(memory_options)); memory = xe_memory_create(memory_options); } backend = shared_ptr(new xe::cpu::x64::X64Backend()); processor = shared_ptr(new Processor(memory, backend)); XEEXPECTZERO(processor->Setup()); runtime = shared_ptr(new Runtime(processor, XT(""))); // Load the binary module. #if XE_WCHAR xechar_t bin_file_path_str[XE_MAX_PATH]; XEEXPECTTRUE(xestrwiden(bin_file_path_str, XECOUNT(bin_file_path_str), bin_file_path.c_str())); #else const xechar_t* bin_file_path_str = bin_file_path.c_str(); #endif // XE_CHAR XEEXPECTZERO(processor->LoadRawBinary(bin_file_path_str, 0x82010000)); // Simulate a thread. thread_state = processor->AllocThread(256 * 1024, 0, 100); // Setup test state from annotations. XEEXPECTZERO(setup_test_state(memory, processor.get(), thread_state, annotations)); // Execute test. XEEXPECTZERO(processor->Execute(thread_state, 0x82010000)); // Assert test state expectations. XEEXPECTZERO(check_test_results(memory, processor.get(), thread_state, annotations)); result_code = 0; XECLEANUP: if (processor && thread_state) { processor->DeallocThread(thread_state); } runtime.reset(); processor.reset(); xe_memory_release(memory); return result_code; } int discover_tests(string& test_path, vector& test_files) { // TODO(benvanik): use PAL instead of this. #if XE_LIKE(WIN32) string search_path = test_path; search_path.append("\\*.s"); WIN32_FIND_DATAA ffd; HANDLE hFind = FindFirstFileA(search_path.c_str(), &ffd); if (hFind == INVALID_HANDLE_VALUE) { XELOGE("Unable to find test path %s", test_path.c_str()); return 1; } do { if (!(ffd.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY)) { string file_name = string(ffd.cFileName); string file_path = test_path; if (*(test_path.end() - 1) != '\\') { file_path += "\\"; } file_path += file_name; test_files.push_back(file_path); } } while (FindNextFileA(hFind, &ffd)); FindClose(hFind); #else DIR* d = opendir(test_path.c_str()); if (!d) { XELOGE("Unable to find test path %s", test_path.c_str()); return 1; } struct dirent* dir; while ((dir = readdir(d))) { if (dir->d_type == DT_REG) { // Only return .s files. string file_name = string(dir->d_name); if (file_name.rfind(".s") != string::npos) { string file_path = test_path; if (*(test_path.end() - 1) != '/') { file_path += "/"; } file_path += file_name; test_files.push_back(file_path); } } } closedir(d); #endif // WIN32 return 0; } int run_tests(std::string& test_name) { int result_code = 1; int failed_count = 0; int passed_count = 0; vector test_files; XEEXPECTZERO(discover_tests(FLAGS_test_path, test_files)); if (!test_files.size()) { printf("No tests discovered - invalid path?\n"); XEFAIL(); } printf("%d tests discovered.\n", (int)test_files.size()); printf("\n"); for (vector::iterator it = test_files.begin(); it != test_files.end(); ++it) { if (test_name.length() && *it != test_name) { continue; } printf("Running %s...\n", (*it).c_str()); if (run_test(*it)) { printf("TEST FAILED\n"); failed_count++; } else { printf("Passed\n"); passed_count++; } } printf("\n"); printf("Total tests: %d\n", failed_count + passed_count); printf("Passed: %d\n", passed_count); printf("Failed: %d\n", failed_count); result_code = failed_count ? 1 : 0; XECLEANUP: return result_code; } int xenia_test(int argc, xechar_t **argv) { int result_code = 1; // Grab test name, if present. const xechar_t* test_name = NULL; if (argc >= 2) { test_name = argv[1]; } string test_name_str; if (test_name) { #if XE_WCHAR char test_name_buffer[XE_MAX_PATH]; XEIGNORE(xestrnarrow(test_name_buffer, XECOUNT(test_name_buffer), test_name)); test_name_str = test_name_buffer; #else test_name_str = test_name; #endif // XE_WCHAR } result_code = run_tests(test_name_str); return result_code; } DEFINE_ENTRY_POINT(L"xenia-test", L"xenia-test some.xex", xenia_test);