// Copyright 2020 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 import ( "errors" "flag" "fmt" "io" "os" "path/filepath" "reflect" "runtime" "strings" "time" ) func initFuzzFlags() { matchFuzz = flag.String("test.fuzz", "", "run the fuzz test matching `regexp`") flag.Var(&fuzzDuration, "test.fuzztime", "time to spend fuzzing; default is to run indefinitely") flag.Var(&minimizeDuration, "test.fuzzminimizetime", "time to spend minimizing a value after finding a failing input") fuzzCacheDir = flag.String("test.fuzzcachedir", "", "directory where interesting fuzzing inputs are stored (for use only by cmd/go)") isFuzzWorker = flag.Bool("test.fuzzworker", false, "coordinate with the parent process to fuzz random values (for use only by cmd/go)") } var ( matchFuzz *string fuzzDuration durationOrCountFlag minimizeDuration = durationOrCountFlag{d: 60 * time.Second, allowZero: true} fuzzCacheDir *string isFuzzWorker *bool // corpusDir is the parent directory of the fuzz test's seed corpus within // the package. corpusDir = "testdata/fuzz" ) // fuzzWorkerExitCode is used as an exit code by fuzz worker processes after an // internal error. This distinguishes internal errors from uncontrolled panics // and other failures. Keep in sync with internal/fuzz.workerExitCode. const fuzzWorkerExitCode = 70 // InternalFuzzTarget is an internal type but exported because it is // cross-package; it is part of the implementation of the "go test" command. type InternalFuzzTarget struct { Name string Fn func(f *F) } // F is a type passed to fuzz tests. // // Fuzz tests run generated inputs against a provided fuzz target, which can // find and report potential bugs in the code being tested. // // A fuzz test runs the seed corpus by default, which includes entries provided // by (*F).Add and entries in the testdata/fuzz/ directory. After // any necessary setup and calls to (*F).Add, the fuzz test must then call // (*F).Fuzz to provide the fuzz target. See the testing package documentation // for an example, and see the [F.Fuzz] and [F.Add] method documentation for // details. // // *F methods can only be called before (*F).Fuzz. Once the test is // executing the fuzz target, only (*T) methods can be used. The only *F methods // that are allowed in the (*F).Fuzz function are (*F).Failed and (*F).Name. type F struct { common fuzzContext *fuzzContext testContext *testContext // inFuzzFn is true when the fuzz function is running. Most F methods cannot // be called when inFuzzFn is true. inFuzzFn bool // corpus is a set of seed corpus entries, added with F.Add and loaded // from testdata. corpus []corpusEntry result fuzzResult fuzzCalled bool } var _ TB = (*F)(nil) // corpusEntry is an alias to the same type as internal/fuzz.CorpusEntry. // We use a type alias because we don't want to export this type, and we can't // import internal/fuzz from testing. type corpusEntry = struct { Parent string Path string Data []byte Values []any Generation int IsSeed bool } // Helper marks the calling function as a test helper function. // When printing file and line information, that function will be skipped. // Helper may be called simultaneously from multiple goroutines. func (f *F) Helper() { if f.inFuzzFn { panic("testing: f.Helper was called inside the fuzz target, use t.Helper instead") } // common.Helper is inlined here. // If we called it, it would mark F.Helper as the helper // instead of the caller. f.mu.Lock() defer f.mu.Unlock() if f.helperPCs == nil { f.helperPCs = make(map[uintptr]struct{}) } // repeating code from callerName here to save walking a stack frame var pc [1]uintptr n := runtime.Callers(2, pc[:]) // skip runtime.Callers + Helper if n == 0 { panic("testing: zero callers found") } if _, found := f.helperPCs[pc[0]]; !found { f.helperPCs[pc[0]] = struct{}{} f.helperNames = nil // map will be recreated next time it is needed } } // Fail marks the function as having failed but continues execution. func (f *F) Fail() { // (*F).Fail may be called by (*T).Fail, which we should allow. However, we // shouldn't allow direct (*F).Fail calls from inside the (*F).Fuzz function. if f.inFuzzFn { panic("testing: f.Fail was called inside the fuzz target, use t.Fail instead") } f.common.Helper() f.common.Fail() } // Skipped reports whether the test was skipped. func (f *F) Skipped() bool { // (*F).Skipped may be called by tRunner, which we should allow. However, we // shouldn't allow direct (*F).Skipped calls from inside the (*F).Fuzz function. if f.inFuzzFn { panic("testing: f.Skipped was called inside the fuzz target, use t.Skipped instead") } f.common.Helper() return f.common.Skipped() } // Add will add the arguments to the seed corpus for the fuzz test. This will be // a no-op if called after or within the fuzz target, and args must match the // arguments for the fuzz target. func (f *F) Add(args ...any) { var values []any for i := range args { if t := reflect.TypeOf(args[i]); !supportedTypes[t] { panic(fmt.Sprintf("testing: unsupported type to Add %v", t)) } values = append(values, args[i]) } f.corpus = append(f.corpus, corpusEntry{Values: values, IsSeed: true, Path: fmt.Sprintf("seed#%d", len(f.corpus))}) } // supportedTypes represents all of the supported types which can be fuzzed. var supportedTypes = map[reflect.Type]bool{ reflect.TypeOf(([]byte)("")): true, reflect.TypeOf((string)("")): true, reflect.TypeOf((bool)(false)): true, reflect.TypeOf((byte)(0)): true, reflect.TypeOf((rune)(0)): true, reflect.TypeOf((float32)(0)): true, reflect.TypeOf((float64)(0)): true, reflect.TypeOf((int)(0)): true, reflect.TypeOf((int8)(0)): true, reflect.TypeOf((int16)(0)): true, reflect.TypeOf((int32)(0)): true, reflect.TypeOf((int64)(0)): true, reflect.TypeOf((uint)(0)): true, reflect.TypeOf((uint8)(0)): true, reflect.TypeOf((uint16)(0)): true, reflect.TypeOf((uint32)(0)): true, reflect.TypeOf((uint64)(0)): true, } // Fuzz runs the fuzz function, ff, for fuzz testing. If ff fails for a set of // arguments, those arguments will be added to the seed corpus. // // ff must be a function with no return value whose first argument is *T and // whose remaining arguments are the types to be fuzzed. // For example: // // f.Fuzz(func(t *testing.T, b []byte, i int) { ... }) // // The following types are allowed: []byte, string, bool, byte, rune, float32, // float64, int, int8, int16, int32, int64, uint, uint8, uint16, uint32, uint64. // More types may be supported in the future. // // ff must not call any *F methods, e.g. (*F).Log, (*F).Error, (*F).Skip. Use // the corresponding *T method instead. The only *F methods that are allowed in // the (*F).Fuzz function are (*F).Failed and (*F).Name. // // This function should be fast and deterministic, and its behavior should not // depend on shared state. No mutatable input arguments, or pointers to them, // should be retained between executions of the fuzz function, as the memory // backing them may be mutated during a subsequent invocation. ff must not // modify the underlying data of the arguments provided by the fuzzing engine. // // When fuzzing, F.Fuzz does not return until a problem is found, time runs out // (set with -fuzztime), or the test process is interrupted by a signal. F.Fuzz // should be called exactly once, unless F.Skip or [F.Fail] is called beforehand. func (f *F) Fuzz(ff any) { if f.fuzzCalled { panic("testing: F.Fuzz called more than once") } f.fuzzCalled = true if f.failed { return } f.Helper() // ff should be in the form func(*testing.T, ...interface{}) fn := reflect.ValueOf(ff) fnType := fn.Type() if fnType.Kind() != reflect.Func { panic("testing: F.Fuzz must receive a function") } if fnType.NumIn() < 2 || fnType.In(0) != reflect.TypeOf((*T)(nil)) { panic("testing: fuzz target must receive at least two arguments, where the first argument is a *T") } if fnType.NumOut() != 0 { panic("testing: fuzz target must not return a value") } // Save the types of the function to compare against the corpus. var types []reflect.Type for i := 1; i < fnType.NumIn(); i++ { t := fnType.In(i) if !supportedTypes[t] { panic(fmt.Sprintf("testing: unsupported type for fuzzing %v", t)) } types = append(types, t) } // Load the testdata seed corpus. Check types of entries in the testdata // corpus and entries declared with F.Add. // // Don't load the seed corpus if this is a worker process; we won't use it. if f.fuzzContext.mode != fuzzWorker { for _, c := range f.corpus { if err := f.fuzzContext.deps.CheckCorpus(c.Values, types); err != nil { // TODO(#48302): Report the source location of the F.Add call. f.Fatal(err) } } // Load seed corpus c, err := f.fuzzContext.deps.ReadCorpus(filepath.Join(corpusDir, f.name), types) if err != nil { f.Fatal(err) } for i := range c { c[i].IsSeed = true // these are all seed corpus values if f.fuzzContext.mode == fuzzCoordinator { // If this is the coordinator process, zero the values, since we don't need // to hold onto them. c[i].Values = nil } } f.corpus = append(f.corpus, c...) } // run calls fn on a given input, as a subtest with its own T. // run is analogous to T.Run. The test filtering and cleanup works similarly. // fn is called in its own goroutine. run := func(captureOut io.Writer, e corpusEntry) (ok bool) { if e.Values == nil { // The corpusEntry must have non-nil Values in order to run the // test. If Values is nil, it is a bug in our code. panic(fmt.Sprintf("corpus file %q was not unmarshaled", e.Path)) } if shouldFailFast() { return true } testName := f.name if e.Path != "" { testName = fmt.Sprintf("%s/%s", testName, filepath.Base(e.Path)) } if f.testContext.isFuzzing { // Don't preserve subtest names while fuzzing. If fn calls T.Run, // there will be a very large number of subtests with duplicate names, // which will use a large amount of memory. The subtest names aren't // useful since there's no way to re-run them deterministically. f.testContext.match.clearSubNames() } // Record the stack trace at the point of this call so that if the subtest // function - which runs in a separate stack - is marked as a helper, we can // continue walking the stack into the parent test. var pc [maxStackLen]uintptr n := runtime.Callers(2, pc[:]) t := &T{ common: common{ barrier: make(chan bool), signal: make(chan bool), name: testName, parent: &f.common, level: f.level + 1, creator: pc[:n], chatty: f.chatty, }, context: f.testContext, } if captureOut != nil { // t.parent aliases f.common. t.parent.w = captureOut } t.w = indenter{&t.common} if t.chatty != nil { t.chatty.Updatef(t.name, "=== RUN %s\n", t.name) } f.common.inFuzzFn, f.inFuzzFn = true, true go tRunner(t, func(t *T) { args := []reflect.Value{reflect.ValueOf(t)} for _, v := range e.Values { args = append(args, reflect.ValueOf(v)) } // Before resetting the current coverage, defer the snapshot so that // we make sure it is called right before the tRunner function // exits, regardless of whether it was executed cleanly, panicked, // or if the fuzzFn called t.Fatal. if f.testContext.isFuzzing { defer f.fuzzContext.deps.SnapshotCoverage() f.fuzzContext.deps.ResetCoverage() } fn.Call(args) }) <-t.signal if t.chatty != nil && t.chatty.json { t.chatty.Updatef(t.parent.name, "=== NAME %s\n", t.parent.name) } f.common.inFuzzFn, f.inFuzzFn = false, false return !t.Failed() } switch f.fuzzContext.mode { case fuzzCoordinator: // Fuzzing is enabled, and this is the test process started by 'go test'. // Act as the coordinator process, and coordinate workers to perform the // actual fuzzing. corpusTargetDir := filepath.Join(corpusDir, f.name) cacheTargetDir := filepath.Join(*fuzzCacheDir, f.name) err := f.fuzzContext.deps.CoordinateFuzzing( fuzzDuration.d, int64(fuzzDuration.n), minimizeDuration.d, int64(minimizeDuration.n), *parallel, f.corpus, types, corpusTargetDir, cacheTargetDir) if err != nil { f.result = fuzzResult{Error: err} f.Fail() fmt.Fprintf(f.w, "%v\n", err) if crashErr, ok := err.(fuzzCrashError); ok { crashPath := crashErr.CrashPath() fmt.Fprintf(f.w, "Failing input written to %s\n", crashPath) testName := filepath.Base(crashPath) fmt.Fprintf(f.w, "To re-run:\ngo test -run=%s/%s\n", f.name, testName) } } // TODO(jayconrod,katiehockman): Aggregate statistics across workers // and add to FuzzResult (ie. time taken, num iterations) case fuzzWorker: // Fuzzing is enabled, and this is a worker process. Follow instructions // from the coordinator. if err := f.fuzzContext.deps.RunFuzzWorker(func(e corpusEntry) error { // Don't write to f.w (which points to Stdout) if running from a // fuzz worker. This would become very verbose, particularly during // minimization. Return the error instead, and let the caller deal // with the output. var buf strings.Builder if ok := run(&buf, e); !ok { return errors.New(buf.String()) } return nil }); err != nil { // Internal errors are marked with f.Fail; user code may call this too, before F.Fuzz. // The worker will exit with fuzzWorkerExitCode, indicating this is a failure // (and 'go test' should exit non-zero) but a failing input should not be recorded. f.Errorf("communicating with fuzzing coordinator: %v", err) } default: // Fuzzing is not enabled, or will be done later. Only run the seed // corpus now. for _, e := range f.corpus { name := fmt.Sprintf("%s/%s", f.name, filepath.Base(e.Path)) if _, ok, _ := f.testContext.match.fullName(nil, name); ok { run(f.w, e) } } } } func (f *F) report() { if *isFuzzWorker || f.parent == nil { return } dstr := fmtDuration(f.duration) format := "--- %s: %s (%s)\n" if f.Failed() { f.flushToParent(f.name, format, "FAIL", f.name, dstr) } else if f.chatty != nil { if f.Skipped() { f.flushToParent(f.name, format, "SKIP", f.name, dstr) } else { f.flushToParent(f.name, format, "PASS", f.name, dstr) } } } // fuzzResult contains the results of a fuzz run. type fuzzResult struct { N int // The number of iterations. T time.Duration // The total time taken. Error error // Error is the error from the failing input } func (r fuzzResult) String() string { if r.Error == nil { return "" } return r.Error.Error() } // fuzzCrashError is satisfied by a failing input detected while fuzzing. // These errors are written to the seed corpus and can be re-run with 'go test'. // Errors within the fuzzing framework (like I/O errors between coordinator // and worker processes) don't satisfy this interface. type fuzzCrashError interface { error Unwrap() error // CrashPath returns the path of the subtest that corresponds to the saved // crash input file in the seed corpus. The test can be re-run with go test // -run=$test/$name $test is the fuzz test name, and $name is the // filepath.Base of the string returned here. CrashPath() string } // fuzzContext holds fields common to all fuzz tests. type fuzzContext struct { deps testDeps mode fuzzMode } type fuzzMode uint8 const ( seedCorpusOnly fuzzMode = iota fuzzCoordinator fuzzWorker ) // runFuzzTests runs the fuzz tests matching the pattern for -run. This will // only run the (*F).Fuzz function for each seed corpus without using the // fuzzing engine to generate or mutate inputs. func runFuzzTests(deps testDeps, fuzzTests []InternalFuzzTarget, deadline time.Time) (ran, ok bool) { ok = true if len(fuzzTests) == 0 || *isFuzzWorker { return ran, ok } m := newMatcher(deps.MatchString, *match, "-test.run", *skip) var mFuzz *matcher if *matchFuzz != "" { mFuzz = newMatcher(deps.MatchString, *matchFuzz, "-test.fuzz", *skip) } for _, procs := range cpuList { runtime.GOMAXPROCS(procs) for i := uint(0); i < *count; i++ { if shouldFailFast() { break } tctx := newTestContext(*parallel, m) tctx.deadline = deadline fctx := &fuzzContext{deps: deps, mode: seedCorpusOnly} root := common{w: os.Stdout} // gather output in one place if Verbose() { root.chatty = newChattyPrinter(root.w) } for _, ft := range fuzzTests { if shouldFailFast() { break } testName, matched, _ := tctx.match.fullName(nil, ft.Name) if !matched { continue } if mFuzz != nil { if _, fuzzMatched, _ := mFuzz.fullName(nil, ft.Name); fuzzMatched { // If this will be fuzzed, then don't run the seed corpus // right now. That will happen later. continue } } f := &F{ common: common{ signal: make(chan bool), barrier: make(chan bool), name: testName, parent: &root, level: root.level + 1, chatty: root.chatty, }, testContext: tctx, fuzzContext: fctx, } f.w = indenter{&f.common} if f.chatty != nil { f.chatty.Updatef(f.name, "=== RUN %s\n", f.name) } go fRunner(f, ft.Fn) <-f.signal if f.chatty != nil && f.chatty.json { f.chatty.Updatef(f.parent.name, "=== NAME %s\n", f.parent.name) } ok = ok && !f.Failed() ran = ran || f.ran } if !ran { // There were no tests to run on this iteration. // This won't change, so no reason to keep trying. break } } } return ran, ok } // runFuzzing runs the fuzz test matching the pattern for -fuzz. Only one such // fuzz test must match. This will run the fuzzing engine to generate and // mutate new inputs against the fuzz target. // // If fuzzing is disabled (-test.fuzz is not set), runFuzzing // returns immediately. func runFuzzing(deps testDeps, fuzzTests []InternalFuzzTarget) (ok bool) { if len(fuzzTests) == 0 || *matchFuzz == "" { return true } m := newMatcher(deps.MatchString, *matchFuzz, "-test.fuzz", *skip) tctx := newTestContext(1, m) tctx.isFuzzing = true fctx := &fuzzContext{ deps: deps, } root := common{w: os.Stdout} if *isFuzzWorker { root.w = io.Discard fctx.mode = fuzzWorker } else { fctx.mode = fuzzCoordinator } if Verbose() && !*isFuzzWorker { root.chatty = newChattyPrinter(root.w) } var fuzzTest *InternalFuzzTarget var testName string var matched []string for i := range fuzzTests { name, ok, _ := tctx.match.fullName(nil, fuzzTests[i].Name) if !ok { continue } matched = append(matched, name) fuzzTest = &fuzzTests[i] testName = name } if len(matched) == 0 { fmt.Fprintln(os.Stderr, "testing: warning: no fuzz tests to fuzz") return true } if len(matched) > 1 { fmt.Fprintf(os.Stderr, "testing: will not fuzz, -fuzz matches more than one fuzz test: %v\n", matched) return false } f := &F{ common: common{ signal: make(chan bool), barrier: nil, // T.Parallel has no effect when fuzzing. name: testName, parent: &root, level: root.level + 1, chatty: root.chatty, }, fuzzContext: fctx, testContext: tctx, } f.w = indenter{&f.common} if f.chatty != nil { f.chatty.Updatef(f.name, "=== RUN %s\n", f.name) } go fRunner(f, fuzzTest.Fn) <-f.signal if f.chatty != nil { f.chatty.Updatef(f.parent.name, "=== NAME %s\n", f.parent.name) } return !f.failed } // fRunner wraps a call to a fuzz test and ensures that cleanup functions are // called and status flags are set. fRunner should be called in its own // goroutine. To wait for its completion, receive from f.signal. // // fRunner is analogous to tRunner, which wraps subtests started with T.Run. // Unit tests and fuzz tests work a little differently, so for now, these // functions aren't consolidated. In particular, because there are no F.Run and // F.Parallel methods, i.e., no fuzz sub-tests or parallel fuzz tests, a few // simplifications are made. We also require that F.Fuzz, F.Skip, or F.Fail is // called. func fRunner(f *F, fn func(*F)) { // When this goroutine is done, either because runtime.Goexit was called, a // panic started, or fn returned normally, record the duration and send // t.signal, indicating the fuzz test is done. defer func() { // Detect whether the fuzz test panicked or called runtime.Goexit // without calling F.Fuzz, F.Fail, or F.Skip. If it did, panic (possibly // replacing a nil panic value). Nothing should recover after fRunner // unwinds, so this should crash the process and print stack. // Unfortunately, recovering here adds stack frames, but the location of // the original panic should still be // clear. f.checkRaces() if f.Failed() { numFailed.Add(1) } err := recover() if err == nil { f.mu.RLock() fuzzNotCalled := !f.fuzzCalled && !f.skipped && !f.failed if !f.finished && !f.skipped && !f.failed { err = errNilPanicOrGoexit } f.mu.RUnlock() if fuzzNotCalled && err == nil { f.Error("returned without calling F.Fuzz, F.Fail, or F.Skip") } } // Use a deferred call to ensure that we report that the test is // complete even if a cleanup function calls F.FailNow. See issue 41355. didPanic := false defer func() { if !didPanic { // Only report that the test is complete if it doesn't panic, // as otherwise the test binary can exit before the panic is // reported to the user. See issue 41479. f.signal <- true } }() // If we recovered a panic or inappropriate runtime.Goexit, fail the test, // flush the output log up to the root, then panic. doPanic := func(err any) { f.Fail() if r := f.runCleanup(recoverAndReturnPanic); r != nil { f.Logf("cleanup panicked with %v", r) } for root := &f.common; root.parent != nil; root = root.parent { root.mu.Lock() root.duration += time.Since(root.start) d := root.duration root.mu.Unlock() root.flushToParent(root.name, "--- FAIL: %s (%s)\n", root.name, fmtDuration(d)) } didPanic = true panic(err) } if err != nil { doPanic(err) } // No panic or inappropriate Goexit. f.duration += time.Since(f.start) if len(f.sub) > 0 { // Unblock inputs that called T.Parallel while running the seed corpus. // This only affects fuzz tests run as normal tests. // While fuzzing, T.Parallel has no effect, so f.sub is empty, and this // branch is not taken. f.barrier is nil in that case. f.testContext.release() close(f.barrier) // Wait for the subtests to complete. for _, sub := range f.sub { <-sub.signal } cleanupStart := time.Now() err := f.runCleanup(recoverAndReturnPanic) f.duration += time.Since(cleanupStart) if err != nil { doPanic(err) } } // Report after all subtests have finished. f.report() f.done = true f.setRan() }() defer func() { if len(f.sub) == 0 { f.runCleanup(normalPanic) } }() f.start = time.Now() f.resetRaces() fn(f) // Code beyond this point will not be executed when FailNow or SkipNow // is invoked. f.mu.Lock() f.finished = true f.mu.Unlock() }