//! Support code for rustc's built in unit-test and micro-benchmarking //! framework. //! //! Almost all user code will only be interested in `Bencher` and //! `black_box`. All other interactions (such as writing tests and //! benchmarks themselves) should be done via the `#[test]` and //! `#[bench]` attributes. //! //! See the [Testing Chapter](../book/ch11-00-testing.html) of the book for more //! details. // Currently, not much of this is meant for users. It is intended to // support the simplest interface possible for representing and // running tests while providing a base that other test frameworks may // build off of. #![unstable(feature = "test", issue = "50297")] #![doc(test(attr(deny(warnings))))] #![feature(internal_output_capture)] #![feature(staged_api)] #![feature(process_exitcode_internals)] #![feature(panic_can_unwind)] #![feature(test)] #![allow(internal_features)] // Public reexports pub use self::bench::{black_box, Bencher}; pub use self::console::run_tests_console; pub use self::options::{ColorConfig, Options, OutputFormat, RunIgnored, ShouldPanic}; pub use self::types::TestName::*; pub use self::types::*; pub use self::ColorConfig::*; pub use cli::TestOpts; // Module to be used by rustc to compile tests in libtest pub mod test { pub use crate::{ assert_test_result, bench::Bencher, cli::{parse_opts, TestOpts}, filter_tests, helpers::metrics::{Metric, MetricMap}, options::{Options, RunIgnored, RunStrategy, ShouldPanic}, run_test, test_main, test_main_static, test_result::{TestResult, TrFailed, TrFailedMsg, TrIgnored, TrOk}, time::{TestExecTime, TestTimeOptions}, types::{ DynTestFn, DynTestName, StaticBenchFn, StaticTestFn, StaticTestName, TestDesc, TestDescAndFn, TestId, TestName, TestType, }, }; } use std::{ collections::VecDeque, env, io, io::prelude::Write, mem::ManuallyDrop, panic::{self, catch_unwind, AssertUnwindSafe, PanicInfo}, process::{self, Command, Termination}, sync::mpsc::{channel, Sender}, sync::{Arc, Mutex}, thread, time::{Duration, Instant}, }; pub mod bench; mod cli; mod console; mod event; mod formatters; mod helpers; mod options; pub mod stats; mod term; mod test_result; mod time; mod types; #[cfg(test)] mod tests; use core::any::Any; use event::{CompletedTest, TestEvent}; use helpers::concurrency::get_concurrency; use helpers::exit_code::get_exit_code; use helpers::shuffle::{get_shuffle_seed, shuffle_tests}; use options::RunStrategy; use test_result::*; use time::TestExecTime; // Process exit code to be used to indicate test failures. const ERROR_EXIT_CODE: i32 = 101; const SECONDARY_TEST_INVOKER_VAR: &str = "__RUST_TEST_INVOKE"; const SECONDARY_TEST_BENCH_BENCHMARKS_VAR: &str = "__RUST_TEST_BENCH_BENCHMARKS"; // The default console test runner. It accepts the command line // arguments and a vector of test_descs. pub fn test_main(args: &[String], tests: Vec, options: Option) { let mut opts = match cli::parse_opts(args) { Some(Ok(o)) => o, Some(Err(msg)) => { eprintln!("error: {msg}"); process::exit(ERROR_EXIT_CODE); } None => return, }; if let Some(options) = options { opts.options = options; } if opts.list { if let Err(e) = console::list_tests_console(&opts, tests) { eprintln!("error: io error when listing tests: {e:?}"); process::exit(ERROR_EXIT_CODE); } } else { if !opts.nocapture { // If we encounter a non-unwinding panic, flush any captured output from the current test, // and stop capturing output to ensure that the non-unwinding panic message is visible. // We also acquire the locks for both output streams to prevent output from other threads // from interleaving with the panic message or appearing after it. let builtin_panic_hook = panic::take_hook(); let hook = Box::new({ move |info: &'_ PanicInfo<'_>| { if !info.can_unwind() { std::mem::forget(std::io::stderr().lock()); let mut stdout = ManuallyDrop::new(std::io::stdout().lock()); if let Some(captured) = io::set_output_capture(None) { if let Ok(data) = captured.lock() { let _ = stdout.write_all(&data); let _ = stdout.flush(); } } } builtin_panic_hook(info); } }); panic::set_hook(hook); } match console::run_tests_console(&opts, tests) { Ok(true) => {} Ok(false) => process::exit(ERROR_EXIT_CODE), Err(e) => { eprintln!("error: io error when listing tests: {e:?}"); process::exit(ERROR_EXIT_CODE); } } } } /// A variant optimized for invocation with a static test vector. /// This will panic (intentionally) when fed any dynamic tests. /// /// This is the entry point for the main function generated by `rustc --test` /// when panic=unwind. pub fn test_main_static(tests: &[&TestDescAndFn]) { let args = env::args().collect::>(); let owned_tests: Vec<_> = tests.iter().map(make_owned_test).collect(); test_main(&args, owned_tests, None) } /// A variant optimized for invocation with a static test vector. /// This will panic (intentionally) when fed any dynamic tests. /// /// Runs tests in panic=abort mode, which involves spawning subprocesses for /// tests. /// /// This is the entry point for the main function generated by `rustc --test` /// when panic=abort. pub fn test_main_static_abort(tests: &[&TestDescAndFn]) { // If we're being run in SpawnedSecondary mode, run the test here. run_test // will then exit the process. if let Ok(name) = env::var(SECONDARY_TEST_INVOKER_VAR) { env::remove_var(SECONDARY_TEST_INVOKER_VAR); // Convert benchmarks to tests if we're not benchmarking. let mut tests = tests.iter().map(make_owned_test).collect::>(); if env::var(SECONDARY_TEST_BENCH_BENCHMARKS_VAR).is_ok() { env::remove_var(SECONDARY_TEST_BENCH_BENCHMARKS_VAR); } else { tests = convert_benchmarks_to_tests(tests); }; let test = tests .into_iter() .find(|test| test.desc.name.as_slice() == name) .unwrap_or_else(|| panic!("couldn't find a test with the provided name '{name}'")); let TestDescAndFn { desc, testfn } = test; match testfn.into_runnable() { Runnable::Test(runnable_test) => { if runnable_test.is_dynamic() { panic!("only static tests are supported"); } run_test_in_spawned_subprocess(desc, runnable_test); } Runnable::Bench(_) => { panic!("benchmarks should not be executed into child processes") } } } let args = env::args().collect::>(); let owned_tests: Vec<_> = tests.iter().map(make_owned_test).collect(); test_main(&args, owned_tests, Some(Options::new().panic_abort(true))) } /// Clones static values for putting into a dynamic vector, which test_main() /// needs to hand out ownership of tests to parallel test runners. /// /// This will panic when fed any dynamic tests, because they cannot be cloned. fn make_owned_test(test: &&TestDescAndFn) -> TestDescAndFn { match test.testfn { StaticTestFn(f) => TestDescAndFn { testfn: StaticTestFn(f), desc: test.desc.clone() }, StaticBenchFn(f) => TestDescAndFn { testfn: StaticBenchFn(f), desc: test.desc.clone() }, _ => panic!("non-static tests passed to test::test_main_static"), } } /// Invoked when unit tests terminate. Returns `Result::Err` if the test is /// considered a failure. By default, invokes `report()` and checks for a `0` /// result. pub fn assert_test_result(result: T) -> Result<(), String> { let code = result.report().to_i32(); if code == 0 { Ok(()) } else { Err(format!( "the test returned a termination value with a non-zero status code \ ({code}) which indicates a failure" )) } } struct FilteredTests { tests: Vec<(TestId, TestDescAndFn)>, benches: Vec<(TestId, TestDescAndFn)>, next_id: usize, } impl FilteredTests { fn add_bench(&mut self, desc: TestDesc, testfn: TestFn) { let test = TestDescAndFn { desc, testfn }; self.benches.push((TestId(self.next_id), test)); self.next_id += 1; } fn add_test(&mut self, desc: TestDesc, testfn: TestFn) { let test = TestDescAndFn { desc, testfn }; self.tests.push((TestId(self.next_id), test)); self.next_id += 1; } fn total_len(&self) -> usize { self.tests.len() + self.benches.len() } } pub fn run_tests( opts: &TestOpts, tests: Vec, mut notify_about_test_event: F, ) -> io::Result<()> where F: FnMut(TestEvent) -> io::Result<()>, { use std::collections::{self, HashMap}; use std::hash::BuildHasherDefault; use std::sync::mpsc::RecvTimeoutError; struct RunningTest { join_handle: Option>, } impl RunningTest { fn join(self, completed_test: &mut CompletedTest) { if let Some(join_handle) = self.join_handle { if let Err(_) = join_handle.join() { if let TrOk = completed_test.result { completed_test.result = TrFailedMsg("panicked after reporting success".to_string()); } } } } } // Use a deterministic hasher type TestMap = HashMap>; struct TimeoutEntry { id: TestId, desc: TestDesc, timeout: Instant, } let tests_len = tests.len(); let mut filtered = FilteredTests { tests: Vec::new(), benches: Vec::new(), next_id: 0 }; for test in filter_tests(opts, tests) { let mut desc = test.desc; desc.name = desc.name.with_padding(test.testfn.padding()); match test.testfn { DynBenchFn(benchfn) => { if opts.bench_benchmarks { filtered.add_bench(desc, DynBenchFn(benchfn)); } else { filtered.add_test(desc, DynBenchAsTestFn(benchfn)); } } StaticBenchFn(benchfn) => { if opts.bench_benchmarks { filtered.add_bench(desc, StaticBenchFn(benchfn)); } else { filtered.add_test(desc, StaticBenchAsTestFn(benchfn)); } } testfn => { filtered.add_test(desc, testfn); } }; } let filtered_out = tests_len - filtered.total_len(); let event = TestEvent::TeFilteredOut(filtered_out); notify_about_test_event(event)?; let shuffle_seed = get_shuffle_seed(opts); let event = TestEvent::TeFiltered(filtered.total_len(), shuffle_seed); notify_about_test_event(event)?; let concurrency = opts.test_threads.unwrap_or_else(get_concurrency); let mut remaining = filtered.tests; if let Some(shuffle_seed) = shuffle_seed { shuffle_tests(shuffle_seed, &mut remaining); } // Store the tests in a VecDeque so we can efficiently remove the first element to run the // tests in the order they were passed (unless shuffled). let mut remaining = VecDeque::from(remaining); let mut pending = 0; let (tx, rx) = channel::(); let run_strategy = if opts.options.panic_abort && !opts.force_run_in_process { RunStrategy::SpawnPrimary } else { RunStrategy::InProcess }; let mut running_tests: TestMap = HashMap::default(); let mut timeout_queue: VecDeque = VecDeque::new(); fn get_timed_out_tests( running_tests: &TestMap, timeout_queue: &mut VecDeque, ) -> Vec { let now = Instant::now(); let mut timed_out = Vec::new(); while let Some(timeout_entry) = timeout_queue.front() { if now < timeout_entry.timeout { break; } let timeout_entry = timeout_queue.pop_front().unwrap(); if running_tests.contains_key(&timeout_entry.id) { timed_out.push(timeout_entry.desc); } } timed_out } fn calc_timeout(timeout_queue: &VecDeque) -> Option { timeout_queue.front().map(|&TimeoutEntry { timeout: next_timeout, .. }| { let now = Instant::now(); if next_timeout >= now { next_timeout - now } else { Duration::new(0, 0) } }) } if concurrency == 1 { while !remaining.is_empty() { let (id, test) = remaining.pop_front().unwrap(); let event = TestEvent::TeWait(test.desc.clone()); notify_about_test_event(event)?; let join_handle = run_test(opts, !opts.run_tests, id, test, run_strategy, tx.clone()); // Wait for the test to complete. let mut completed_test = rx.recv().unwrap(); RunningTest { join_handle }.join(&mut completed_test); let fail_fast = match completed_test.result { TrIgnored | TrOk | TrBench(_) => false, TrFailed | TrFailedMsg(_) | TrTimedFail => opts.fail_fast, }; let event = TestEvent::TeResult(completed_test); notify_about_test_event(event)?; if fail_fast { return Ok(()); } } } else { while pending > 0 || !remaining.is_empty() { while pending < concurrency && !remaining.is_empty() { let (id, test) = remaining.pop_front().unwrap(); let timeout = time::get_default_test_timeout(); let desc = test.desc.clone(); let event = TestEvent::TeWait(desc.clone()); notify_about_test_event(event)?; //here no pad let join_handle = run_test(opts, !opts.run_tests, id, test, run_strategy, tx.clone()); running_tests.insert(id, RunningTest { join_handle }); timeout_queue.push_back(TimeoutEntry { id, desc, timeout }); pending += 1; } let mut res; loop { if let Some(timeout) = calc_timeout(&timeout_queue) { res = rx.recv_timeout(timeout); for test in get_timed_out_tests(&running_tests, &mut timeout_queue) { let event = TestEvent::TeTimeout(test); notify_about_test_event(event)?; } match res { Err(RecvTimeoutError::Timeout) => { // Result is not yet ready, continue waiting. } _ => { // We've got a result, stop the loop. break; } } } else { res = rx.recv().map_err(|_| RecvTimeoutError::Disconnected); break; } } let mut completed_test = res.unwrap(); let running_test = running_tests.remove(&completed_test.id).unwrap(); running_test.join(&mut completed_test); let fail_fast = match completed_test.result { TrIgnored | TrOk | TrBench(_) => false, TrFailed | TrFailedMsg(_) | TrTimedFail => opts.fail_fast, }; let event = TestEvent::TeResult(completed_test); notify_about_test_event(event)?; pending -= 1; if fail_fast { // Prevent remaining test threads from panicking std::mem::forget(rx); return Ok(()); } } } if opts.bench_benchmarks { // All benchmarks run at the end, in serial. for (id, b) in filtered.benches { let event = TestEvent::TeWait(b.desc.clone()); notify_about_test_event(event)?; let join_handle = run_test(opts, false, id, b, run_strategy, tx.clone()); // Wait for the test to complete. let mut completed_test = rx.recv().unwrap(); RunningTest { join_handle }.join(&mut completed_test); let event = TestEvent::TeResult(completed_test); notify_about_test_event(event)?; } } Ok(()) } pub fn filter_tests(opts: &TestOpts, tests: Vec) -> Vec { let mut filtered = tests; let matches_filter = |test: &TestDescAndFn, filter: &str| { let test_name = test.desc.name.as_slice(); match opts.filter_exact { true => test_name == filter, false => test_name.contains(filter), } }; // Remove tests that don't match the test filter if !opts.filters.is_empty() { filtered.retain(|test| opts.filters.iter().any(|filter| matches_filter(test, filter))); } // Skip tests that match any of the skip filters if !opts.skip.is_empty() { filtered.retain(|test| !opts.skip.iter().any(|sf| matches_filter(test, sf))); } // Excludes #[should_panic] tests if opts.exclude_should_panic { filtered.retain(|test| test.desc.should_panic == ShouldPanic::No); } // maybe unignore tests match opts.run_ignored { RunIgnored::Yes => { filtered.iter_mut().for_each(|test| test.desc.ignore = false); } RunIgnored::Only => { filtered.retain(|test| test.desc.ignore); filtered.iter_mut().for_each(|test| test.desc.ignore = false); } RunIgnored::No => {} } filtered } pub fn convert_benchmarks_to_tests(tests: Vec) -> Vec { // convert benchmarks to tests, if we're not benchmarking them tests .into_iter() .map(|x| { let testfn = match x.testfn { DynBenchFn(benchfn) => DynBenchAsTestFn(benchfn), StaticBenchFn(benchfn) => StaticBenchAsTestFn(benchfn), f => f, }; TestDescAndFn { desc: x.desc, testfn } }) .collect() } pub fn run_test( opts: &TestOpts, force_ignore: bool, id: TestId, test: TestDescAndFn, strategy: RunStrategy, monitor_ch: Sender, ) -> Option> { let TestDescAndFn { desc, testfn } = test; // Emscripten can catch panics but other wasm targets cannot let ignore_because_no_process_support = desc.should_panic != ShouldPanic::No && cfg!(target_family = "wasm") && !cfg!(target_os = "emscripten"); if force_ignore || desc.ignore || ignore_because_no_process_support { let message = CompletedTest::new(id, desc, TrIgnored, None, Vec::new()); monitor_ch.send(message).unwrap(); return None; } match testfn.into_runnable() { Runnable::Test(runnable_test) => { if runnable_test.is_dynamic() { match strategy { RunStrategy::InProcess => (), _ => panic!("Cannot run dynamic test fn out-of-process"), }; } let name = desc.name.clone(); let nocapture = opts.nocapture; let time_options = opts.time_options; let bench_benchmarks = opts.bench_benchmarks; let runtest = move || match strategy { RunStrategy::InProcess => run_test_in_process( id, desc, nocapture, time_options.is_some(), runnable_test, monitor_ch, time_options, ), RunStrategy::SpawnPrimary => spawn_test_subprocess( id, desc, nocapture, time_options.is_some(), monitor_ch, time_options, bench_benchmarks, ), }; // If the platform is single-threaded we're just going to run // the test synchronously, regardless of the concurrency // level. let supports_threads = !cfg!(target_os = "emscripten") && !cfg!(target_family = "wasm"); if supports_threads { let cfg = thread::Builder::new().name(name.as_slice().to_owned()); let mut runtest = Arc::new(Mutex::new(Some(runtest))); let runtest2 = runtest.clone(); match cfg.spawn(move || runtest2.lock().unwrap().take().unwrap()()) { Ok(handle) => Some(handle), Err(e) if e.kind() == io::ErrorKind::WouldBlock => { // `ErrorKind::WouldBlock` means hitting the thread limit on some // platforms, so run the test synchronously here instead. Arc::get_mut(&mut runtest).unwrap().get_mut().unwrap().take().unwrap()(); None } Err(e) => panic!("failed to spawn thread to run test: {e}"), } } else { runtest(); None } } Runnable::Bench(runnable_bench) => { // Benchmarks aren't expected to panic, so we run them all in-process. runnable_bench.run(id, &desc, &monitor_ch, opts.nocapture); None } } } /// Fixed frame used to clean the backtrace with `RUST_BACKTRACE=1`. #[inline(never)] fn __rust_begin_short_backtrace T>(f: F) -> T { let result = f(); // prevent this frame from being tail-call optimised away black_box(result) } fn run_test_in_process( id: TestId, desc: TestDesc, nocapture: bool, report_time: bool, runnable_test: RunnableTest, monitor_ch: Sender, time_opts: Option, ) { // Buffer for capturing standard I/O let data = Arc::new(Mutex::new(Vec::new())); if !nocapture { io::set_output_capture(Some(data.clone())); } let start = report_time.then(Instant::now); let result = fold_err(catch_unwind(AssertUnwindSafe(|| runnable_test.run()))); let exec_time = start.map(|start| { let duration = start.elapsed(); TestExecTime(duration) }); io::set_output_capture(None); let test_result = match result { Ok(()) => calc_result(&desc, Ok(()), &time_opts, &exec_time), Err(e) => calc_result(&desc, Err(e.as_ref()), &time_opts, &exec_time), }; let stdout = data.lock().unwrap_or_else(|e| e.into_inner()).to_vec(); let message = CompletedTest::new(id, desc, test_result, exec_time, stdout); monitor_ch.send(message).unwrap(); } fn fold_err( result: Result, Box>, ) -> Result> where E: Send + 'static, { match result { Ok(Err(e)) => Err(Box::new(e)), Ok(Ok(v)) => Ok(v), Err(e) => Err(e), } } fn spawn_test_subprocess( id: TestId, desc: TestDesc, nocapture: bool, report_time: bool, monitor_ch: Sender, time_opts: Option, bench_benchmarks: bool, ) { let (result, test_output, exec_time) = (|| { let args = env::args().collect::>(); let current_exe = &args[0]; let mut command = Command::new(current_exe); command.env(SECONDARY_TEST_INVOKER_VAR, desc.name.as_slice()); if bench_benchmarks { command.env(SECONDARY_TEST_BENCH_BENCHMARKS_VAR, "1"); } if nocapture { command.stdout(process::Stdio::inherit()); command.stderr(process::Stdio::inherit()); } let start = report_time.then(Instant::now); let output = match command.output() { Ok(out) => out, Err(e) => { let err = format!("Failed to spawn {} as child for test: {:?}", args[0], e); return (TrFailed, err.into_bytes(), None); } }; let exec_time = start.map(|start| { let duration = start.elapsed(); TestExecTime(duration) }); let std::process::Output { stdout, stderr, status } = output; let mut test_output = stdout; formatters::write_stderr_delimiter(&mut test_output, &desc.name); test_output.extend_from_slice(&stderr); let result = match (|| -> Result { let exit_code = get_exit_code(status)?; Ok(get_result_from_exit_code(&desc, exit_code, &time_opts, &exec_time)) })() { Ok(r) => r, Err(e) => { write!(&mut test_output, "Unexpected error: {e}").unwrap(); TrFailed } }; (result, test_output, exec_time) })(); let message = CompletedTest::new(id, desc, result, exec_time, test_output); monitor_ch.send(message).unwrap(); } fn run_test_in_spawned_subprocess(desc: TestDesc, runnable_test: RunnableTest) -> ! { let builtin_panic_hook = panic::take_hook(); let record_result = Arc::new(move |panic_info: Option<&'_ PanicInfo<'_>>| { let test_result = match panic_info { Some(info) => calc_result(&desc, Err(info.payload()), &None, &None), None => calc_result(&desc, Ok(()), &None, &None), }; // We don't support serializing TrFailedMsg, so just // print the message out to stderr. if let TrFailedMsg(msg) = &test_result { eprintln!("{msg}"); } if let Some(info) = panic_info { builtin_panic_hook(info); } if let TrOk = test_result { process::exit(test_result::TR_OK); } else { process::exit(test_result::TR_FAILED); } }); let record_result2 = record_result.clone(); panic::set_hook(Box::new(move |info| record_result2(Some(info)))); if let Err(message) = runnable_test.run() { panic!("{}", message); } record_result(None); unreachable!("panic=abort callback should have exited the process") }