/* * Copyright (C) 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef TEST_TEST_HELPER_H_ #define TEST_TEST_HELPER_H_ #include #include #include #include "perfetto/base/build_config.h" #include "perfetto/ext/base/file_utils.h" #include "perfetto/ext/base/scoped_file.h" #include "perfetto/ext/base/subprocess.h" #include "perfetto/ext/base/thread_task_runner.h" #include "perfetto/ext/base/utils.h" #include "perfetto/ext/tracing/core/consumer.h" #include "perfetto/ext/tracing/core/shared_memory_arbiter.h" #include "perfetto/ext/tracing/core/trace_packet.h" #include "perfetto/ext/tracing/core/tracing_service.h" #include "perfetto/ext/tracing/ipc/consumer_ipc_client.h" #include "perfetto/ext/tracing/ipc/service_ipc_host.h" #include "perfetto/tracing/core/trace_config.h" #include "perfetto/tracing/default_socket.h" #include "src/base/test/test_task_runner.h" #include "test/fake_producer.h" #if PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) #include "src/tracing/ipc/shared_memory_windows.h" #else #include #include "src/traced/probes/probes_producer.h" #include "src/tracing/ipc/posix_shared_memory.h" #endif #include "protos/perfetto/trace/trace_packet.gen.h" namespace perfetto { // This value has been bumped to 10s in Oct 2020 because the GCE-based emulator // can be sensibly slower than real hw (more than 10x) and caused flakes. // See bugs duped against b/171771440. constexpr uint32_t kDefaultTestTimeoutMs = 30000; inline const char* GetTestProducerSockName() { // If we're building on Android and starting the daemons ourselves, // create the sockets in a world-writable location. #if PERFETTO_BUILDFLAG(PERFETTO_OS_ANDROID) && \ PERFETTO_BUILDFLAG(PERFETTO_START_DAEMONS) return "/data/local/tmp/traced_producer"; #else return ::perfetto::GetProducerSocket(); #endif } // Captures the values of some environment variables when constructed and // restores them when destroyed. class TestEnvCleaner { public: TestEnvCleaner() {} TestEnvCleaner(std::initializer_list env_vars) { prev_state_.reserve(env_vars.size()); for (const char* name : env_vars) { prev_state_.emplace_back(); Var& var = prev_state_.back(); var.name = name; const char* prev_value = getenv(name); if (prev_value) { var.value.emplace(prev_value); } } } ~TestEnvCleaner() { Clean(); } TestEnvCleaner(const TestEnvCleaner&) = delete; TestEnvCleaner(TestEnvCleaner&& obj) noexcept { *this = std::move(obj); } TestEnvCleaner& operator=(const TestEnvCleaner&) = delete; TestEnvCleaner& operator=(TestEnvCleaner&& obj) noexcept { PERFETTO_CHECK(prev_state_.empty()); this->prev_state_ = std::move(obj.prev_state_); obj.prev_state_.clear(); return *this; } void Clean() { for (const Var& var : prev_state_) { if (var.value) { base::SetEnv(var.name, *var.value); } else { base::UnsetEnv(var.name); } } prev_state_.clear(); } private: struct Var { const char* name; std::optional value; }; std::vector prev_state_; }; // This is used only in daemon starting integrations tests. class ServiceThread { public: ServiceThread(const std::string& producer_socket, const std::string& consumer_socket, bool enable_relay_endpoint = false) : producer_socket_(producer_socket), consumer_socket_(consumer_socket), enable_relay_endpoint_(enable_relay_endpoint) {} ~ServiceThread() { Stop(); } TestEnvCleaner Start() { TestEnvCleaner env_cleaner( {"PERFETTO_PRODUCER_SOCK_NAME", "PERFETTO_CONSUMER_SOCK_NAME"}); runner_ = base::ThreadTaskRunner::CreateAndStart("perfetto.svc"); runner_->PostTaskAndWaitForTesting([this]() { TracingService::InitOpts init_opts = {}; if (enable_relay_endpoint_) init_opts.enable_relay_endpoint = true; svc_ = ServiceIPCHost::CreateInstance(runner_->get(), init_opts); auto producer_sockets = TokenizeProducerSockets(producer_socket_.c_str()); for (const auto& producer_socket : producer_sockets) { // In some cases the socket is a TCP or abstract unix. if (!base::FileExists(producer_socket)) continue; if (remove(producer_socket.c_str()) == -1) { if (errno != ENOENT) PERFETTO_FATAL("Failed to remove %s", producer_socket_.c_str()); } } if (remove(consumer_socket_.c_str()) == -1) { if (errno != ENOENT) PERFETTO_FATAL("Failed to remove %s", consumer_socket_.c_str()); } base::SetEnv("PERFETTO_PRODUCER_SOCK_NAME", producer_socket_); base::SetEnv("PERFETTO_CONSUMER_SOCK_NAME", consumer_socket_); bool res = svc_->Start(producer_socket_.c_str(), consumer_socket_.c_str()); if (!res) { PERFETTO_FATAL("Failed to start service listening on %s and %s", producer_socket_.c_str(), consumer_socket_.c_str()); } }); return env_cleaner; } void Stop() { if (!runner_) return; runner_->PostTaskAndWaitForTesting([this]() { svc_.reset(); }); runner_.reset(); } base::ThreadTaskRunner* runner() { return runner_ ? &*runner_ : nullptr; } private: std::optional runner_; // Keep first. std::string producer_socket_; std::string consumer_socket_; bool enable_relay_endpoint_ = false; std::unique_ptr svc_; }; // This is used only in daemon starting integrations tests. #if PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) // On Windows we don't have any traced_probes, make this a no-op to avoid // propagating #ifdefs to the outer test. class ProbesProducerThread { public: ProbesProducerThread(const std::string& /*producer_socket*/) {} void Connect() {} }; #else class ProbesProducerThread { public: ProbesProducerThread(const std::string& producer_socket) : producer_socket_(producer_socket) {} ~ProbesProducerThread() { if (!runner_) return; runner_->PostTaskAndWaitForTesting([this]() { producer_.reset(); }); } void Connect() { runner_ = base::ThreadTaskRunner::CreateAndStart("perfetto.prd.probes"); runner_->PostTaskAndWaitForTesting([this]() { producer_.reset(new ProbesProducer()); producer_->ConnectWithRetries(producer_socket_.c_str(), runner_->get()); }); } private: std::optional runner_; // Keep first. std::string producer_socket_; std::unique_ptr producer_; }; #endif // !OS_WIN class FakeProducerThread { public: FakeProducerThread(const std::string& producer_socket, std::function connect_callback, std::function setup_callback, std::function start_callback, const std::string& producer_name) : producer_socket_(producer_socket), connect_callback_(std::move(connect_callback)), setup_callback_(std::move(setup_callback)), start_callback_(std::move(start_callback)) { runner_ = base::ThreadTaskRunner::CreateAndStart("perfetto.prd.fake"); runner_->PostTaskAndWaitForTesting([this, producer_name]() { producer_.reset(new FakeProducer(producer_name, runner_->get())); }); } ~FakeProducerThread() { runner_->PostTaskAndWaitForTesting([this]() { producer_.reset(); }); } void Connect() { runner_->PostTaskAndWaitForTesting([this]() { producer_->Connect(producer_socket_.c_str(), std::move(connect_callback_), std::move(setup_callback_), std::move(start_callback_), std::move(shm_), std::move(shm_arbiter_)); }); } base::ThreadTaskRunner* runner() { return runner_ ? &*runner_ : nullptr; } FakeProducer* producer() { return producer_.get(); } void CreateProducerProvidedSmb() { #if PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) SharedMemoryWindows::Factory factory; #else PosixSharedMemory::Factory factory; #endif shm_ = factory.CreateSharedMemory(1024 * 1024); shm_arbiter_ = SharedMemoryArbiter::CreateUnboundInstance( shm_.get(), 4096, SharedMemoryABI::ShmemMode::kDefault); } void ProduceStartupEventBatch(const protos::gen::TestConfig& config, std::function callback) { PERFETTO_CHECK(shm_arbiter_); producer_->ProduceStartupEventBatch(config, shm_arbiter_.get(), callback); } private: std::optional runner_; // Keep first. std::string producer_socket_; std::unique_ptr producer_; std::function connect_callback_; std::function setup_callback_; std::function start_callback_; std::unique_ptr shm_; std::unique_ptr shm_arbiter_; }; class TestHelper : public Consumer { public: enum class Mode { kStartDaemons, kUseSystemService, }; static Mode kDefaultMode; static const char* GetDefaultModeConsumerSocketName(); static const char* GetDefaultModeProducerSocketName(); explicit TestHelper(base::TestTaskRunner* task_runner) : TestHelper(task_runner, kDefaultMode) {} explicit TestHelper(base::TestTaskRunner* task_runner, Mode mode); explicit TestHelper(base::TestTaskRunner* task_runner, Mode mode, const char* producer_socket, bool enable_relay_endpoint = false); // Consumer implementation. void OnConnect() override; void OnDisconnect() override; void OnTracingDisabled(const std::string& error) override; virtual void ReadTraceData(std::vector packets); void OnTraceData(std::vector packets, bool has_more) override; void OnDetach(bool) override; void OnAttach(bool, const TraceConfig&) override; void OnTraceStats(bool, const TraceStats&) override; void OnObservableEvents(const ObservableEvents&) override; void OnSessionCloned(const OnSessionClonedArgs&) override; // Starts the tracing service if in kStartDaemons mode. void StartServiceIfRequired(); // Restarts the tracing service. Only valid in kStartDaemons mode. void RestartService(); // Connects the producer and waits that the service has seen the // RegisterDataSource() call. FakeProducer* ConnectFakeProducer(size_t idx = 0); void ConnectConsumer(); void StartTracing(const TraceConfig& config, base::ScopedFile = base::ScopedFile()); void DisableTracing(); void FlushAndWait(uint32_t timeout_ms, FlushFlags = FlushFlags()); void ReadData(uint32_t read_count = 0); void FreeBuffers(); void DetachConsumer(const std::string& key); bool AttachConsumer(const std::string& key); void CreateProducerProvidedSmb(); bool IsShmemProvidedByProducer(size_t idx = 0); void ProduceStartupEventBatch(const protos::gen::TestConfig& config); void WaitFor(std::function predicate, const std::string& error_msg, uint32_t timeout_ms = kDefaultTestTimeoutMs); void WaitForConsumerConnect(); void WaitForProducerSetup(size_t idx = 0); void WaitForProducerEnabled(size_t idx = 0); void WaitForDataSourceConnected(const std::string& ds_name); void WaitForTracingDisabled(uint32_t timeout_ms = kDefaultTestTimeoutMs); void WaitForReadData(uint32_t read_count = 0, uint32_t timeout_ms = kDefaultTestTimeoutMs); void WaitForAllDataSourceStarted(uint32_t timeout_ms = kDefaultTestTimeoutMs); void SyncAndWaitProducer(size_t idx = 0); TracingServiceState QueryServiceStateAndWait(); std::string AddID(const std::string& checkpoint) { return checkpoint + "." + std::to_string(instance_num_); } std::function CreateCheckpoint(const std::string& checkpoint) { return task_runner_->CreateCheckpoint(AddID(checkpoint)); } void RunUntilCheckpoint(const std::string& checkpoint, uint32_t timeout_ms = kDefaultTestTimeoutMs) { return task_runner_->RunUntilCheckpoint(AddID(checkpoint), timeout_ms); } std::function WrapTask(const std::function& function); base::ThreadTaskRunner* service_thread() { return service_thread_.runner(); } base::ThreadTaskRunner* producer_thread(size_t i = 0) { PERFETTO_DCHECK(i < fake_producer_threads_.size()); return fake_producer_threads_[i]->runner(); } size_t num_producers() { return fake_producer_threads_.size(); } const std::vector& full_trace() { return full_trace_; } const std::vector& trace() { return trace_; } // Some fixtures want to reuse a global TestHelper in different testcases // without destroying and recreating it, but they still need to avoid // polluting environment variables. // // This restores the previous environment variables. void CleanEnv() { env_cleaner_.Clean(); } private: static uint64_t next_instance_num_; uint64_t instance_num_; base::TestTaskRunner* task_runner_ = nullptr; int cur_consumer_num_ = 0; uint64_t trace_count_ = 0; std::function on_all_ds_started_callback_; std::function on_connect_callback_; std::function on_packets_finished_callback_; std::function on_stop_tracing_callback_; std::function on_detach_callback_; std::function on_attach_callback_; std::vector full_trace_; std::vector trace_; Mode mode_; const char* producer_socket_; const char* consumer_socket_; ServiceThread service_thread_; std::vector> fake_producer_threads_; TestEnvCleaner env_cleaner_; std::unique_ptr endpoint_; // Keep last. }; #if !PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) // This class is a reference to a child process that has in essence been execv // to the requested binary. The process will start and then wait for Run() // before proceeding. We use this to fork new processes before starting any // additional threads in the parent process (otherwise you would risk // deadlocks), but pause the forked processes until remaining setup (including // any necessary threads) in the parent process is complete. class Exec { public: // Starts the forked process that was created. If not null then |stderr_out| // will contain the stderr of the process. int Run(std::string* stderr_out = nullptr) { // We can't be the child process. PERFETTO_CHECK(getpid() != subprocess_.pid()); // Will cause the entrypoint to continue. PERFETTO_CHECK(write(*sync_pipe_.wr, "1", 1) == 1); sync_pipe_.wr.reset(); subprocess_.Wait(); if (stderr_out) { *stderr_out = std::move(subprocess_.output()); } else { PERFETTO_LOG("Child proc %d exited with stderr: \"%s\"", subprocess_.pid(), subprocess_.output().c_str()); } return subprocess_.returncode(); } Exec(const std::string& argv0, std::initializer_list args, std::string input = "") { subprocess_.args.stderr_mode = base::Subprocess::OutputMode::kBuffer; subprocess_.args.stdout_mode = base::Subprocess::OutputMode::kDevNull; subprocess_.args.input = input; #if PERFETTO_BUILDFLAG(PERFETTO_START_DAEMONS) constexpr bool kUseSystemBinaries = false; #else constexpr bool kUseSystemBinaries = true; #endif auto pass_env = [](const std::string& var, base::Subprocess* proc) { const char* val = getenv(var.c_str()); if (val) proc->args.env.push_back(var + "=" + val); }; std::vector& cmd = subprocess_.args.exec_cmd; if (kUseSystemBinaries) { PERFETTO_CHECK(TestHelper::kDefaultMode == TestHelper::Mode::kUseSystemService); cmd.push_back("/system/bin/" + argv0); cmd.insert(cmd.end(), args.begin(), args.end()); } else { PERFETTO_CHECK(TestHelper::kDefaultMode == TestHelper::Mode::kStartDaemons); subprocess_.args.env.push_back( std::string("PERFETTO_PRODUCER_SOCK_NAME=") + TestHelper::GetDefaultModeProducerSocketName()); subprocess_.args.env.push_back( std::string("PERFETTO_CONSUMER_SOCK_NAME=") + TestHelper::GetDefaultModeConsumerSocketName()); pass_env("TMPDIR", &subprocess_); pass_env("TMP", &subprocess_); pass_env("TEMP", &subprocess_); pass_env("LD_LIBRARY_PATH", &subprocess_); cmd.push_back(base::GetCurExecutableDir() + "/" + argv0); cmd.insert(cmd.end(), args.begin(), args.end()); } if (!base::FileExists(cmd[0])) { PERFETTO_FATAL( "Cannot find %s. Make sure that the target has been built and, on " "Android, pushed to the device.", cmd[0].c_str()); } // This pipe blocks the execution of the child process until the main test // process calls Run(). There are two conflicting problems here: // 1) We can't fork() subprocesses too late, because the test spawns threads // for hosting the service. fork+threads = bad (see aosp/1089744). // 2) We can't run the subprocess too early, because we need to wait that // the service threads are ready before trying to connect from the child // process. sync_pipe_ = base::Pipe::Create(); int sync_pipe_rd = *sync_pipe_.rd; subprocess_.args.preserve_fds.push_back(sync_pipe_rd); // This lambda will be called on the forked child process after having // setup pipe redirection and closed all FDs, right before the exec(). // The Subprocesss harness will take care of closing also |sync_pipe_.wr|. subprocess_.args.posix_entrypoint_for_testing = [sync_pipe_rd] { // Don't add any logging here, all file descriptors are closed and trying // to log will likely cause undefined behaviors. char ignored = 0; PERFETTO_CHECK(PERFETTO_EINTR(read(sync_pipe_rd, &ignored, 1)) > 0); PERFETTO_CHECK(close(sync_pipe_rd) == 0 || errno == EINTR); }; subprocess_.Start(); sync_pipe_.rd.reset(); } void SendSigterm() { #ifdef SIGTERM kill(subprocess_.pid(), SIGTERM); #else // This code is never used on Windows tests, not bothering. if (subprocess_.pid()) // Always true, but avoids Wnoreturn compile errors. PERFETTO_FATAL("SendSigterm() not implemented on this platform"); #endif } private: base::Subprocess subprocess_; base::Pipe sync_pipe_; }; #endif // !PERFETTO_BUILDFLAG(PERFETTO_OS_WIN) } // namespace perfetto #endif // TEST_TEST_HELPER_H_