// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package testing provides support for automated testing of Go packages. // It is intended to be used in concert with the ``go test'' utility, which automates // execution of any function of the form // func TestXxx(*testing.T) // where Xxx can be any alphanumeric string (but the first letter must not be in // [a-z]) and serves to identify the test routine. // These TestXxx routines should be declared within the package they are testing. // // Functions of the form // func BenchmarkXxx(*testing.B) // are considered benchmarks, and are executed by go test when the -test.bench // flag is provided. // // A sample benchmark function looks like this: // func BenchmarkHello(b *testing.B) { // for i := 0; i < b.N; i++ { // fmt.Sprintf("hello") // } // } // The benchmark package will vary b.N until the benchmark function lasts // long enough to be timed reliably. The output // testing.BenchmarkHello 10000000 282 ns/op // means that the loop ran 10000000 times at a speed of 282 ns per loop. // // If a benchmark needs some expensive setup before running, the timer // may be stopped: // func BenchmarkBigLen(b *testing.B) { // b.StopTimer() // big := NewBig() // b.StartTimer() // for i := 0; i < b.N; i++ { // big.Len() // } // } package testing import ( "flag" "fmt" "os" "runtime" "runtime/pprof" "strconv" "strings" "time" ) var ( // The short flag requests that tests run more quickly, but its functionality // is provided by test writers themselves. The testing package is just its // home. The all.bash installation script sets it to make installation more // efficient, but by default the flag is off so a plain "go test" will do a // full test of the package. short = flag.Bool("test.short", false, "run smaller test suite to save time") // Report as tests are run; default is silent for success. chatty = flag.Bool("test.v", false, "verbose: print additional output") match = flag.String("test.run", "", "regular expression to select tests to run") memProfile = flag.String("test.memprofile", "", "write a memory profile to the named file after execution") memProfileRate = flag.Int("test.memprofilerate", 0, "if >=0, sets runtime.MemProfileRate") cpuProfile = flag.String("test.cpuprofile", "", "write a cpu profile to the named file during execution") timeout = flag.Duration("test.timeout", 0, "if positive, sets an aggregate time limit for all tests") cpuListStr = flag.String("test.cpu", "", "comma-separated list of number of CPUs to use for each test") parallel = flag.Int("test.parallel", runtime.GOMAXPROCS(0), "maximum test parallelism") cpuList []int ) // common holds the elements common between T and B and // captures common methods such as Errorf. type common struct { output []byte // Output generated by test or benchmark. failed bool // Test or benchmark has failed. start time.Time // Time test or benchmark started duration time.Duration self interface{} // To be sent on signal channel when done. signal chan interface{} // Output for serial tests. } // Short reports whether the -test.short flag is set. func Short() bool { return *short } // decorate inserts the final newline if needed and indentation tabs for formatting. // If addFileLine is true, it also prefixes the string with the file and line of the call site. func decorate(s string, addFileLine bool) string { if addFileLine { _, file, line, ok := runtime.Caller(3) // decorate + log + public function. if ok { // Truncate file name at last file name separator. if index := strings.LastIndex(file, "/"); index >= 0 { file = file[index+1:] } else if index = strings.LastIndex(file, "\\"); index >= 0 { file = file[index+1:] } } else { file = "???" line = 1 } s = fmt.Sprintf("%s:%d: %s", file, line, s) } s = "\t" + s // Every line is indented at least one tab. n := len(s) if n > 0 && s[n-1] != '\n' { s += "\n" n++ } for i := 0; i < n-1; i++ { // -1 to avoid final newline if s[i] == '\n' { // Second and subsequent lines are indented an extra tab. return s[0:i+1] + "\t" + decorate(s[i+1:n], false) } } return s } // T is a type passed to Test functions to manage test state and support formatted test logs. // Logs are accumulated during execution and dumped to standard error when done. type T struct { common name string // Name of test. startParallel chan bool // Parallel tests will wait on this. } // Fail marks the function as having failed but continues execution. func (c *common) Fail() { c.failed = true } // Failed reports whether the function has failed. func (c *common) Failed() bool { return c.failed } // FailNow marks the function as having failed and stops its execution. // Execution will continue at the next Test. func (c *common) FailNow() { c.Fail() // Calling runtime.Goexit will exit the goroutine, which // will run the deferred functions in this goroutine, // which will eventually run the deferred lines in tRunner, // which will signal to the test loop that this test is done. // // A previous version of this code said: // // c.duration = ... // c.signal <- c.self // runtime.Goexit() // // This previous version duplicated code (those lines are in // tRunner no matter what), but worse the goroutine teardown // implicit in runtime.Goexit was not guaranteed to complete // before the test exited. If a test deferred an important cleanup // function (like removing temporary files), there was no guarantee // it would run on a test failure. Because we send on c.signal during // a top-of-stack deferred function now, we know that the send // only happens after any other stacked defers have completed. runtime.Goexit() } // log generates the output. It's always at the same stack depth. func (c *common) log(s string) { c.output = append(c.output, decorate(s, true)...) } // Log formats its arguments using default formatting, analogous to Println(), // and records the text in the error log. func (c *common) Log(args ...interface{}) { c.log(fmt.Sprintln(args...)) } // Logf formats its arguments according to the format, analogous to Printf(), // and records the text in the error log. func (c *common) Logf(format string, args ...interface{}) { c.log(fmt.Sprintf(format, args...)) } // Error is equivalent to Log() followed by Fail(). func (c *common) Error(args ...interface{}) { c.log(fmt.Sprintln(args...)) c.Fail() } // Errorf is equivalent to Logf() followed by Fail(). func (c *common) Errorf(format string, args ...interface{}) { c.log(fmt.Sprintf(format, args...)) c.Fail() } // Fatal is equivalent to Log() followed by FailNow(). func (c *common) Fatal(args ...interface{}) { c.log(fmt.Sprintln(args...)) c.FailNow() } // Fatalf is equivalent to Logf() followed by FailNow(). func (c *common) Fatalf(format string, args ...interface{}) { c.log(fmt.Sprintf(format, args...)) c.FailNow() } // Parallel signals that this test is to be run in parallel with (and only with) // other parallel tests in this CPU group. func (t *T) Parallel() { t.signal <- (*T)(nil) // Release main testing loop <-t.startParallel // Wait for serial tests to finish } // An internal type but exported because it is cross-package; part of the implementation // of go test. type InternalTest struct { Name string F func(*T) } func tRunner(t *T, test *InternalTest) { t.start = time.Now() // When this goroutine is done, either because test.F(t) // returned normally or because a test failure triggered // a call to runtime.Goexit, record the duration and send // a signal saying that the test is done. defer func() { t.duration = time.Now().Sub(t.start) t.signal <- t }() test.F(t) } // An internal function but exported because it is cross-package; part of the implementation // of go test. func Main(matchString func(pat, str string) (bool, error), tests []InternalTest, benchmarks []InternalBenchmark, examples []InternalExample) { flag.Parse() parseCpuList() before() startAlarm() testOk := RunTests(matchString, tests) exampleOk := RunExamples(examples) if !testOk || !exampleOk { fmt.Println("FAIL") os.Exit(1) } fmt.Println("PASS") stopAlarm() RunBenchmarks(matchString, benchmarks) after() } func (t *T) report() { tstr := fmt.Sprintf("(%.2f seconds)", t.duration.Seconds()) format := "--- %s: %s %s\n%s" if t.failed { fmt.Printf(format, "FAIL", t.name, tstr, t.output) } else if *chatty { fmt.Printf(format, "PASS", t.name, tstr, t.output) } } func RunTests(matchString func(pat, str string) (bool, error), tests []InternalTest) (ok bool) { ok = true if len(tests) == 0 { fmt.Fprintln(os.Stderr, "testing: warning: no tests to run") return } for _, procs := range cpuList { runtime.GOMAXPROCS(procs) // We build a new channel tree for each run of the loop. // collector merges in one channel all the upstream signals from parallel tests. // If all tests pump to the same channel, a bug can occur where a test // kicks off a goroutine that Fails, yet the test still delivers a completion signal, // which skews the counting. var collector = make(chan interface{}) numParallel := 0 startParallel := make(chan bool) for i := 0; i < len(tests); i++ { matched, err := matchString(*match, tests[i].Name) if err != nil { fmt.Fprintf(os.Stderr, "testing: invalid regexp for -test.run: %s\n", err) os.Exit(1) } if !matched { continue } testName := tests[i].Name if procs != 1 { testName = fmt.Sprintf("%s-%d", tests[i].Name, procs) } t := &T{ common: common{ signal: make(chan interface{}), }, name: testName, startParallel: startParallel, } t.self = t if *chatty { fmt.Printf("=== RUN %s\n", t.name) } go tRunner(t, &tests[i]) out := (<-t.signal).(*T) if out == nil { // Parallel run. go func() { collector <- <-t.signal }() numParallel++ continue } t.report() ok = ok && !out.failed } running := 0 for numParallel+running > 0 { if running < *parallel && numParallel > 0 { startParallel <- true running++ numParallel-- continue } t := (<-collector).(*T) t.report() ok = ok && !t.failed running-- } } return } // before runs before all testing. func before() { if *memProfileRate > 0 { runtime.MemProfileRate = *memProfileRate } if *cpuProfile != "" { f, err := os.Create(*cpuProfile) if err != nil { fmt.Fprintf(os.Stderr, "testing: %s", err) return } if err := pprof.StartCPUProfile(f); err != nil { fmt.Fprintf(os.Stderr, "testing: can't start cpu profile: %s", err) f.Close() return } // Could save f so after can call f.Close; not worth the effort. } } // after runs after all testing. func after() { if *cpuProfile != "" { pprof.StopCPUProfile() // flushes profile to disk } if *memProfile != "" { f, err := os.Create(*memProfile) if err != nil { fmt.Fprintf(os.Stderr, "testing: %s", err) return } if err = pprof.WriteHeapProfile(f); err != nil { fmt.Fprintf(os.Stderr, "testing: can't write %s: %s", *memProfile, err) } f.Close() } } var timer *time.Timer // startAlarm starts an alarm if requested. func startAlarm() { if *timeout > 0 { timer = time.AfterFunc(*timeout, alarm) } } // stopAlarm turns off the alarm. func stopAlarm() { if *timeout > 0 { timer.Stop() } } // alarm is called if the timeout expires. func alarm() { panic("test timed out") } func parseCpuList() { if len(*cpuListStr) == 0 { cpuList = append(cpuList, runtime.GOMAXPROCS(-1)) } else { for _, val := range strings.Split(*cpuListStr, ",") { cpu, err := strconv.Atoi(val) if err != nil || cpu <= 0 { fmt.Fprintf(os.Stderr, "testing: invalid value %q for -test.cpu", val) os.Exit(1) } cpuList = append(cpuList, cpu) } } }