// Protocol Buffers - Google's data interchange format // Copyright 2008 Google Inc. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file or at // https://developers.google.com/open-source/licenses/bsd // This file contains a program for running the test suite in a separate // process. The other alternative is to run the suite in-process. See // conformance.proto for pros/cons of these two options. // // This program will fork the process under test and communicate with it over // its stdin/stdout: // // +--------+ pipe +----------+ // | tester | <------> | testee | // | | | | // | C++ | | any lang | // +--------+ +----------+ // // The tester contains all of the test cases and their expected output. // The testee is a simple program written in the target language that reads // each test case and attempts to produce acceptable output for it. // // Every test consists of a ConformanceRequest/ConformanceResponse // request/reply pair. The protocol on the pipe is simply: // // 1. tester sends 4-byte length N (little endian) // 2. tester sends N bytes representing a ConformanceRequest proto // 3. testee sends 4-byte length M (little endian) // 4. testee sends M bytes representing a ConformanceResponse proto #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "absl/container/flat_hash_set.h" #include "absl/log/absl_log.h" #include "absl/strings/ascii.h" #include "absl/strings/str_cat.h" #include "absl/strings/str_format.h" #include "conformance/conformance.pb.h" #include "conformance_test.h" #include "google/protobuf/endian.h" using google::protobuf::ConformanceTestSuite; using std::string; using std::vector; #define STRINGIFY(x) #x #define TOSTRING(x) STRINGIFY(x) #define CHECK_SYSCALL(call) \ if (call < 0) { \ perror(#call " " __FILE__ ":" TOSTRING(__LINE__)); \ exit(1); \ } namespace google { namespace protobuf { void ParseFailureList(const char *filename, conformance::FailureSet *failure_list) { std::ifstream infile(filename); if (!infile.is_open()) { fprintf(stderr, "Couldn't open failure list file: %s\n", filename); exit(1); } for (string line; std::getline(infile, line);) { // Remove comments. string test_name = line.substr(0, line.find('#')); test_name.erase( std::remove_if(test_name.begin(), test_name.end(), ::isspace), test_name.end()); if (test_name.empty()) { // Skip empty lines. continue; } // If we remove whitespace from the beginning of a line, and what we have // left at first is a '#', then we have a comment. if (test_name[0] != '#') { // Find our failure message if it exists. Will be set to an empty string // if no message is found. Empty failure messages also pass our tests. size_t check_message = line.find('#'); string message; if (check_message != std::string::npos) { message = line.substr(check_message + 1); // +1 to skip the delimiter // If we had only whitespace after the delimiter, we will have an empty // failure message and the test will still pass. message = std::string(absl::StripAsciiWhitespace(message)); } conformance::TestStatus *test = failure_list->add_test(); test->set_name(test_name); test->set_failure_message(message); } } } void UsageError() { fprintf(stderr, "Usage: conformance-test-runner [options] \n"); fprintf(stderr, "\n"); fprintf(stderr, "Options:\n"); fprintf(stderr, " --failure_list Use to specify list of tests\n"); fprintf(stderr, " that are expected to fail. File\n"); fprintf(stderr, " should contain one test name per\n"); fprintf(stderr, " line. Use '#' for comments.\n\n"); fprintf(stderr, " --text_format_failure_list Use to specify list \n"); fprintf(stderr, " of tests that are expected to \n"); fprintf(stderr, " fail in the \n"); fprintf(stderr, " text_format_conformance_suite. \n"); fprintf(stderr, " File should contain one test name \n"); fprintf(stderr, " per line. Use '#' for comments.\n\n"); fprintf(stderr, " --enforce_recommended Enforce that recommended test\n"); fprintf(stderr, " cases are also passing. Specify\n"); fprintf(stderr, " this flag if you want to be\n"); fprintf(stderr, " strictly conforming to protobuf\n"); fprintf(stderr, " spec.\n\n"); fprintf(stderr, " --maximum_edition Only run conformance tests up to\n"); fprintf(stderr, " and including the specified\n"); fprintf(stderr, " edition.\n\n"); fprintf(stderr, " --output_dir Directory to write\n" " output files.\n\n"); fprintf(stderr, " --test Only run\n"); fprintf(stderr, " the specified test. Multiple tests\n" " can be specified by repeating the \n" " flag.\n\n"); fprintf(stderr, " --debug Enable debug mode\n" " to produce octal serialized\n" " ConformanceRequest for the tests\n" " passed to --test (required)\n\n"); fprintf(stderr, " --performance Boolean option\n"); fprintf(stderr, " for enabling run of\n"); fprintf(stderr, " performance tests.\n"); exit(1); } void ForkPipeRunner::RunTest(const std::string &test_name, uint32_t len, const std::string &request, std::string *response) { if (child_pid_ < 0) { SpawnTestProgram(); } current_test_name_ = test_name; CheckedWrite(write_fd_, &len, sizeof(uint32_t)); CheckedWrite(write_fd_, request.c_str(), request.size()); if (!TryRead(read_fd_, &len, sizeof(uint32_t))) { // We failed to read from the child, assume a crash and try to reap. ABSL_LOG(INFO) << "Trying to reap child, pid=" << child_pid_; int status = 0; waitpid(child_pid_, &status, WEXITED); string error_msg; conformance::ConformanceResponse response_obj; if (WIFEXITED(status)) { if (WEXITSTATUS(status) == 0) { absl::StrAppendFormat(&error_msg, "child timed out, killed by signal %d", WTERMSIG(status)); response_obj.set_timeout_error(error_msg); } else { absl::StrAppendFormat(&error_msg, "child exited, status=%d", WEXITSTATUS(status)); response_obj.set_runtime_error(error_msg); } } else if (WIFSIGNALED(status)) { absl::StrAppendFormat(&error_msg, "child killed by signal %d", WTERMSIG(status)); } ABSL_LOG(INFO) << error_msg; child_pid_ = -1; response_obj.SerializeToString(response); return; } len = internal::little_endian::ToHost(len); response->resize(len); CheckedRead(read_fd_, (void *)response->c_str(), len); } int ForkPipeRunner::Run(int argc, char *argv[], const std::vector &suites) { if (suites.empty()) { fprintf(stderr, "No test suites found.\n"); return EXIT_FAILURE; } string program; string testee; std::vector program_args; bool performance = false; bool debug = false; absl::flat_hash_set names_to_test; bool enforce_recommended = false; Edition maximum_edition = EDITION_UNKNOWN; std::string output_dir; bool verbose = false; bool isolated = false; for (int arg = 1; arg < argc; ++arg) { if (strcmp(argv[arg], "--performance") == 0) { performance = true; } else if (strcmp(argv[arg], "--debug") == 0) { debug = true; } else if (strcmp(argv[arg], "--verbose") == 0) { verbose = true; } else if (strcmp(argv[arg], "--enforce_recommended") == 0) { enforce_recommended = true; } else if (strcmp(argv[arg], "--maximum_edition") == 0) { if (++arg == argc) UsageError(); Edition edition = EDITION_UNKNOWN; if (!Edition_Parse(absl::StrCat("EDITION_", argv[arg]), &edition)) { fprintf(stderr, "Unknown edition: %s\n", argv[arg]); UsageError(); } maximum_edition = edition; } else if (strcmp(argv[arg], "--output_dir") == 0) { if (++arg == argc) UsageError(); output_dir = argv[arg]; } else if (strcmp(argv[arg], "--test") == 0) { if (++arg == argc) UsageError(); names_to_test.insert(argv[arg]); } else if (argv[arg][0] == '-') { bool recognized_flag = false; for (ConformanceTestSuite *suite : suites) { if (strcmp(argv[arg], suite->GetFailureListFlagName().c_str()) == 0) { if (++arg == argc) UsageError(); recognized_flag = true; } } if (!recognized_flag) { fprintf(stderr, "Unknown option: %s\n", argv[arg]); UsageError(); } } else { program += argv[arg++]; while (arg < argc) { program_args.push_back(argv[arg]); arg++; } } } if (debug && names_to_test.empty()) { UsageError(); } if (!names_to_test.empty()) { isolated = true; } bool all_ok = true; for (ConformanceTestSuite *suite : suites) { string failure_list_filename; conformance::FailureSet failure_list; for (int arg = 1; arg < argc; ++arg) { if (strcmp(argv[arg], suite->GetFailureListFlagName().c_str()) == 0) { if (++arg == argc) UsageError(); failure_list_filename = argv[arg]; ParseFailureList(argv[arg], &failure_list); } } suite->SetPerformance(performance); suite->SetVerbose(verbose); suite->SetEnforceRecommended(enforce_recommended); suite->SetMaximumEdition(maximum_edition); suite->SetOutputDir(output_dir); suite->SetDebug(debug); suite->SetNamesToTest(names_to_test); suite->SetTestee(program); suite->SetIsolated(isolated); ForkPipeRunner runner(program, program_args, performance); std::string output; all_ok = all_ok && suite->RunSuite(&runner, &output, failure_list_filename, &failure_list); names_to_test = suite->GetExpectedTestsNotRun(); fwrite(output.c_str(), 1, output.size(), stderr); } if (!names_to_test.empty()) { fprintf(stderr, "These tests were requested to be ran isolated, but they do " "not exist. Revise the test names:\n\n"); for (const string &test_name : names_to_test) { fprintf(stderr, " %s\n", test_name.c_str()); } fprintf(stderr, "\n\n"); } return all_ok ? EXIT_SUCCESS : EXIT_FAILURE; } // TODO: make this work on Windows, instead of using these // UNIX-specific APIs. // // There is a platform-agnostic API in // src/google/protobuf/compiler/subprocess.h // // However that API only supports sending a single message to the subprocess. // We really want to be able to send messages and receive responses one at a // time: // // 1. Spawning a new process for each test would take way too long for thousands // of tests and subprocesses like java that can take 100ms or more to start // up. // // 2. Sending all the tests in one big message and receiving all results in one // big message would take away our visibility about which test(s) caused a // crash or other fatal error. It would also give us only a single failure // instead of all of them. void ForkPipeRunner::SpawnTestProgram() { int toproc_pipe_fd[2]; int fromproc_pipe_fd[2]; if (pipe(toproc_pipe_fd) < 0 || pipe(fromproc_pipe_fd) < 0) { perror("pipe"); exit(1); } pid_t pid = fork(); if (pid < 0) { perror("fork"); exit(1); } if (pid) { // Parent. CHECK_SYSCALL(close(toproc_pipe_fd[0])); CHECK_SYSCALL(close(fromproc_pipe_fd[1])); write_fd_ = toproc_pipe_fd[1]; read_fd_ = fromproc_pipe_fd[0]; child_pid_ = pid; } else { // Child. CHECK_SYSCALL(close(STDIN_FILENO)); CHECK_SYSCALL(close(STDOUT_FILENO)); CHECK_SYSCALL(dup2(toproc_pipe_fd[0], STDIN_FILENO)); CHECK_SYSCALL(dup2(fromproc_pipe_fd[1], STDOUT_FILENO)); CHECK_SYSCALL(close(toproc_pipe_fd[0])); CHECK_SYSCALL(close(fromproc_pipe_fd[1])); CHECK_SYSCALL(close(toproc_pipe_fd[1])); CHECK_SYSCALL(close(fromproc_pipe_fd[0])); std::unique_ptr executable(new char[executable_.size() + 1]); memcpy(executable.get(), executable_.c_str(), executable_.size()); executable[executable_.size()] = '\0'; std::vector argv; argv.push_back(executable.get()); ABSL_LOG(INFO) << argv[0]; for (size_t i = 0; i < executable_args_.size(); ++i) { argv.push_back(executable_args_[i].c_str()); ABSL_LOG(INFO) << executable_args_[i]; } argv.push_back(nullptr); // Never returns. CHECK_SYSCALL(execv(executable.get(), const_cast(argv.data()))); } } void ForkPipeRunner::CheckedWrite(int fd, const void *buf, size_t len) { if (static_cast(write(fd, buf, len)) != len) { ABSL_LOG(FATAL) << current_test_name_ << ": error writing to test program: " << strerror(errno); } } bool ForkPipeRunner::TryRead(int fd, void *buf, size_t len) { size_t ofs = 0; while (len > 0) { std::future future = std::async( std::launch::async, [](int fd, void *buf, size_t ofs, size_t len) { return read(fd, (char *)buf + ofs, len); }, fd, buf, ofs, len); std::future_status status; if (performance_) { status = future.wait_for(std::chrono::seconds(5)); if (status == std::future_status::timeout) { ABSL_LOG(ERROR) << current_test_name_ << ": timeout from test program"; kill(child_pid_, SIGQUIT); // TODO: Only log in flag-guarded mode, since reading output // from SIGQUIT is slow and verbose. std::vector err; err.resize(5000); ssize_t err_bytes_read; size_t err_ofs = 0; do { err_bytes_read = read(fd, (void *)&err[err_ofs], err.size() - err_ofs); err_ofs += err_bytes_read; } while (err_bytes_read > 0 && err_ofs < err.size()); ABSL_LOG(ERROR) << "child_pid_=" << child_pid_ << " SIGQUIT: \n" << &err[0]; return false; } } else { future.wait(); } ssize_t bytes_read = future.get(); if (bytes_read == 0) { ABSL_LOG(ERROR) << current_test_name_ << ": unexpected EOF from test program"; return false; } else if (bytes_read < 0) { ABSL_LOG(ERROR) << current_test_name_ << ": error reading from test program: " << strerror(errno); return false; } len -= bytes_read; ofs += bytes_read; } return true; } void ForkPipeRunner::CheckedRead(int fd, void *buf, size_t len) { if (!TryRead(fd, buf, len)) { ABSL_LOG(FATAL) << current_test_name_ << ": error reading from test program: " << strerror(errno); } } } // namespace protobuf } // namespace google